Results for:
Species: Fusarium proliferatum

2,4-dimethylfuran

Mass-Spectra

Compound Details

Synonymous names
2,4-DIMETHYLFURAN
3710-43-8
Furan, 2,4-dimethyl-
2,4-dimethyl-furan
3,5-dimethylfuran
WWC3WDX33J
2,4-Dimethylfuran #
UNII-WWC3WDX33J
CHEBI:89526
DTXSID50190602
MFCD00511327
AKOS015905551
DB-355241
EN300-325734
F87949
Q27161722
Microorganism:

Yes

IUPAC name2,4-dimethylfuran
SMILESCC1=CC(=CO1)C
InchiInChI=1S/C6H8O/c1-5-3-6(2)7-4-5/h3-4H,1-2H3
FormulaC6H8O
PubChem ID19462
Molweight96.13
LogP1.8
Atoms7
Bonds0
H-bond Acceptor1
H-bond Donor0
Chemical Classificationaromatic compounds ethers heterocyclic compounds furan derivatives
CHEBI-ID89526
Supernatural-IDSN0000062

Species emitting the compound
Method
KingdomSpeciesGrowth MediumApplied MethodVerification
ProkaryotaPseudomonas AeruginosaLB-LennoxSPME/GC-MSno
ProkaryotaPseudomonas AeruginosaLB brothSPME/GCxGC-MSno
EukaryotaCandida AlbicansSDATD/GC-MSno
EukaryotaCandida TropicalisSDATD/GC-MSno
EukaryotaCandida KruseiSDATD/GC-MSno
EukaryotaCandida GlabrataSDATD/GC-MSno
EukaryotaFusarium OxysporumLiquid onion extract medium (LOM)SPME, GC-MSno
EukaryotaFusarium ProliferatumLiquid onion extract medium (LOM)SPME, GC-MSno
ProkaryotaCollimonas Fungivoranssand supplemented with artificial root exudatesHeadspace trapping/GC-MSno
ProkaryotaCollimonas Pratensissand supplemented with artificial root exudatesHeadspace trapping/GC-MSno
EukaryotaFusarium Sp.no
EukaryotaPaecilomyces VariotiiMEAGC/MSno
EukaryotaFusarium Culmorumpotato dextrose agarGC/MS-Q-TOFno


2,5-dimethylthiophene

Compound Details

Synonymous names
2,5-DIMETHYLTHIOPHENE
638-02-8
Thiophene, 2,5-dimethyl-
2,5-dimethyl-thiophene
MFCD00005452
V6DDX6WB12
NSC-60689
UNII-V6DDX6WB12
NSC60689
EINECS 211-313-9
2,5 Dimethylthiophene
Thiophene,5-dimethyl-
2,5-dimethyl thiophene
SCHEMBL64283
2 pound not5-Dimethylthiophene
DTXSID2074295
2,5-Dimethylthiophene, >=98%
2,5-Dimethylthiophene, 98.5%
CHEBI:167073
NSC 60689
AKOS000121512
AKOS016017809
PS-3263
AC-18077
SY018010
2,5-Dimethylthiophene, analytical standard
DB-054553
CS-0022382
D1591
NS00022605
EN300-21089
F11266
2,5-Dimethylthiophene, purum, >=98.0% (GC)
A834530
W-104874
Q27291590
F0001-1465
InChI=1/C6H8S/c1-5-3-4-6(2)7-5/h3-4H,1-2H
Microorganism:

No

IUPAC name2,5-dimethylthiophene
SMILESCC1=CC=C(S1)C
InchiInChI=1S/C6H8S/c1-5-3-4-6(2)7-5/h3-4H,1-2H3
FormulaC6H8S
PubChem ID12514
Molweight112.19
LogP2.4
Atoms7
Bonds0
H-bond Acceptor1
H-bond Donor0
Chemical Classificationaromatic compounds sulfur compounds heterocyclic compounds thioethers
CHEBI-ID167073
Supernatural-IDSN0117347

mVOC Specific Details

Boiling Point
DegreeReference
135 median

Species emitting the compound
KingdomSpeciesBiological FunctionOrigin/HabitatReference
EukaryotaFusarium OxysporumonionWang et al. 2018
EukaryotaFusarium ProliferatumonionWang et al. 2018
Method
KingdomSpeciesGrowth MediumApplied MethodVerification
EukaryotaFusarium OxysporumLiquid onion extract medium (LOM)SPME, GC-MSyes
EukaryotaFusarium ProliferatumLiquid onion extract medium (LOM)SPME, GC-MSyes


(Z)-but-2-ene

Compound Details

Synonymous names
cis-2-Butene
590-18-1
(Z)-But-2-ene
cis-Butene
(Z)-2-Butene
cis-But-2-ene
beta-cis-Butylene
cis-1,2-Dimethylethylene
High-boiling butene-2
(2Z)-2-Butene
(2Z)-but-2-ene
2-BUTENE, (Z)-
2-Butene, (2Z)-
cis-Butylene
cis-But-2-en
2-Butene, cis-
(Z)-2-C4H8
L35ORC9C05
2-Butene-cis
2-BUTENE
UNII-L35ORC9C05
MFCD00064458
cis-2-butylene
HSDB 5704
EINECS 209-673-7
z-but-2-ene
Butene-2, cis-
Z-.BETA.-BUTYLENE
2-BUTENE (Z)-FORM
cis-2-Butene, >=99%
.BETA.-BUTYLENE, Z-
CIS-2-BUTENE [HSDB]
DTXSID0027224
CHEBI:48366
107-01-7
2-BUTENE (Z)-FORM [MI]
MFCD00009294
ethyl2-(6-aminopyrazin-2-yl)acetate
DB-369927
B0690
Q11855353
Microorganism:

Yes

IUPAC name(Z)-but-2-ene
SMILESCC=CC
InchiInChI=1S/C4H8/c1-3-4-2/h3-4H,1-2H3/b4-3-
FormulaC4H8
PubChem ID5287573
Molweight56.11
LogP2.3
Atoms4
Bonds0
H-bond Acceptor0
H-bond Donor0
Chemical Classificationalkenes unsaturated hydrocarbons
CHEBI-ID48366

mVOC Specific Details

Boiling Point
DegreeReference
3.73 °C peer reviewed
Volatilization
The Henry's Law constant for 2-butene is estimated as 1.54X10-1 atm-cu m/mole(SRC) using a fragment constant estimation method(1). This Henry's Law constant indicates that 2-butene is expected to volatilize rapidly from water surfaces(2). Based on this Henry's Law constant, the volatilization half-life from a model river (1 m deep, flowing 1 m/sec, wind velocity of 3 m/sec)(2) is estimated as 2 hours(SRC). The volatilization half-life from a model lake (1 m deep, flowing 0.05 m/sec, wind velocity of 0.5 m/sec)(2) is estimated as 3 days(SRC). 2-Butene's Henry's Law constant indicates that volatilization from moist soil surfaces may occur(SRC). 2-Butene is expected to volatilize from dry soil surfaces(SRC) based upon a vapor pressure of 1600 mm Hg at 25 °C(3).
Soil Adsorption
The Koc of 2-butene is estimated as 40(SRC), using a log Kow of 1.85(1) and a regression-derived equation(2). According to a classification scheme(3), this estimated Koc value suggests that 2-butene is expected to have very high mobility in soil.

Species emitting the compound
KingdomSpeciesBiological FunctionOrigin/HabitatReference
ProkaryotaStreptococcus PneumoniaeNANAFilipiak et al. 2012
EukaryotaFusarium OxysporumonionWang et al. 2018
EukaryotaFusarium ProliferatumonionWang et al. 2018
Method
KingdomSpeciesGrowth MediumApplied MethodVerification
ProkaryotaStreptococcus PneumoniaeTryptic soyaTD/GC-MSno
EukaryotaFusarium OxysporumLiquid onion extract medium (LOM)SPME, GC-MSno
EukaryotaFusarium ProliferatumLiquid onion extract medium (LOM)SPME, GC-MSno


Prop-2-ene-1-thiol

Compound Details

Synonymous names
ALLYL MERCAPTAN
2-Propene-1-thiol
870-23-5
prop-2-ene-1-thiol
Allylthiol
Allylmercaptan
Allyl sulfhydrate
FEMA No. 2035
2-Propenyl mercaptan
2-Propenyl-1-thiol
CH2=CHCH2SH
CHEBI:89888
1X587IBY09
NSC-6744
allyl thiol
UNII-1X587IBY09
allyl thioalcohol
3-Mercaptopropene
NSC 6744
EINECS 212-792-7
MFCD00004894
AI3-23286
Allyl mercaptan, >=70%
Allyl mercaptan, >=90%
Allyl Mercaptan (>75%)
1-PROPENE-3-THIOL
ALLYL MERCAPTAN [FHFI]
CHEMBL3222024
DTXSID2061226
FEMA 2035
ULIKDJVNUXNQHS-UHFFFAOYSA-
NSC6744
AKOS000120943
DB-003583
A0777
NS00022848
2-Propene-1-thiol, technical, ~60% (GC)
D88323
A841917
InChI=1/C3H6S/c1-2-3-4/h2,4H,1,3H2
Q25104273
Microorganism:

No

IUPAC nameprop-2-ene-1-thiol
SMILESC=CCS
InchiInChI=1S/C3H6S/c1-2-3-4/h2,4H,1,3H2
FormulaC3H6S
PubChem ID13367
Molweight74.15
LogP1.2
Atoms4
Bonds1
H-bond Acceptor1
H-bond Donor1
Chemical Classificationsulfur compounds thiols
CHEBI-ID59723
Supernatural-IDSN0373494

mVOC Specific Details

Boiling Point
DegreeReference
65 median

Species emitting the compound
KingdomSpeciesBiological FunctionOrigin/HabitatReference
EukaryotaFusarium OxysporumonionWang et al. 2018
EukaryotaFusarium ProliferatumonionWang et al. 2018
Method
KingdomSpeciesGrowth MediumApplied MethodVerification
EukaryotaFusarium OxysporumLiquid onion extract medium (LOM)SPME, GC-MSno
EukaryotaFusarium ProliferatumLiquid onion extract medium (LOM)SPME, GC-MSno


Propane-1-thiol

Mass-Spectra

Compound Details

Synonymous names
1-Propanethiol
Propane-1-thiol
Propanethiol
107-03-9
PROPYL MERCAPTAN
n-Propylmercaptan
n-Propyl mercaptan
n-Propylthiol
1-Mercaptopropane
1-Propylmercaptan
Propylthiol
1-Propyl mercaptan
Thiopropyl alcohol
n-Thiopropyl alcohol
1-propylthiol
Mercaptan C3
FEMA No. 3521
79869-58-2
n-C3H7SH
4AB0N08V2H
CHEBI:8473
MFCD00004900
propylmercaptan
n-propanethiol
propan-1-thiol
CCRIS 1246
HSDB 1037
propanethiol, sodium salt
EINECS 203-455-5
BRN 1696860
propanthiol
UNII-4AB0N08V2H
Propanethiols
propane thiol
propyl thiol
1-propanthiol
1-Propanethoil
1-propane thiol
1-propyl thiol
n-PrSH
1-Propanethiol, 99%
51285-52-0
Propyl mercaptan, >=97%
3-Mercaptopropyl Silica Gel
4-01-00-01449 (Beilstein Handbook Reference)
PROPYL MERCAPTAN [FCC]
PROPYL MERCAPTAN [FHFI]
PROPYL MERCAPTAN [HSDB]
CHEMBL1236818
DTXSID5026750
FEMA 3521
DTXSID30198121
Propyl mercaptan, analytical standard
AKOS000121933
MCULE-8267649092
1-Propanethiol, natural, >=98%, FG
M1979
NS00020137
P0488
Propanethiols [UN2402] [Flammable liquid]
EN300-31221
C08390
A801560
Q161679
InChI=1/C3H8S/c1-2-3-4/h4H,2-3H2,1H
J-001693
F8880-8482
Microorganism:

Yes

IUPAC namepropane-1-thiol
SMILESCCCS
InchiInChI=1S/C3H8S/c1-2-3-4/h4H,2-3H2,1H3
FormulaC3H8S
PubChem ID7848
Molweight76.16
LogP1.8
Atoms4
Bonds1
H-bond Acceptor1
H-bond Donor1
Chemical Classificationsulfur compounds thiols
CHEBI-ID8473
Supernatural-IDSN0355954

mVOC Specific Details

Boiling Point
DegreeReference
67.8 °C peer reviewed
Volatilization
The Henry's Law constant for propyl mercaptan is 4.08X10-3 atm-cu m/mole(SRC) using a fragment constant estimation method(1). This Henry's Law constant indicates that propyl mercaptan is expected to volatilize rapidly from water surfaces(2). Based on this Henry's Law constant, the volatilization half-life from a model river (1 m deep, flowing 1 m/sec, wind velocity of 3 m/sec)(2) is estimated as 2.6 hours(SRC). The volatilization half-life from a model lake (1 m deep, flowing 0.05 m/sec, wind velocity of 0.5 m/sec)(2) is estimated as 3.5 days(SRC). Propyl mercaptan's Henry's Law constant indicates that volatilization from moist soil surfaces may occur(SRC). Propyl mercaptan is expected to volatilize from dry soil surfaces(SRC) based upon a vapor pressure of 154 mm Hg(3).
Literature: (1) Przyjazny A et al; J Chromatog 280: 249-260 (1983) (2) Lyman WJ et al; Handbook of Chemical Property Estimation Methods. Washington, DC: Amer Chem Soc pp. 15-1 to 15-29 (1990) (3) Daubert TE, Danner RP; Physical and Thermodynamic Properties of Pure Chemicals: Data Compilation. Design Inst Phys Prop Data, Amer Inst Chem Eng. NY, NY: Hemisphere Pub Corp. 4 vol (1989)
Soil Adsorption
The Koc of propyl mercaptan is estimated as 230(SRC), using a log Kow of 1.81(1) and a regression-derived equation(2). According to a classification scheme(3), this estimated Koc value suggests that propyl mercaptan is expected to have moderate mobility in soil.
Literature: (1) Hansch C et al; Exploring QSAR. Hydrophobic, Electronic, and Steric Constants. ACS Prof Ref Book. Heller SR, consult. ed., Washington, DC: Amer Chem Soc p. 7 (1995) (2) Lyman WJ et al; Handbook of Chemical Property Estimation Methods. Washington, DC: Amer Chem Soc pp. 4-9 (1990) (3) Swann RL et al; Res Rev 85: 17-28 (1983)
Vapor Pressure
PressureReference
154.2 mm Hg at 25 deg C /Extrapolated/Daubert, T.E., R.P. Danner. Physical and Thermodynamic Properties of Pure Chemicals Data Compilation. Washington, D.C.: Taylor and Francis, 1989.
MS-Links
1D-NMR-Links
Massbank-Links

Species emitting the compound
Method
KingdomSpeciesGrowth MediumApplied MethodVerification
EukaryotaFusarium OxysporumLiquid onion extract medium (LOM)SPME, GC-MSyes
EukaryotaFusarium ProliferatumLiquid onion extract medium (LOM)SPME, GC-MSyes
ProkaryotaSerratia Proteamaculansn/an/ano
ProkaryotaCarnobacterium Divergensn/an/ano
Lactobacillus PlantarumHabanero pepperGC–IMSno


Methanethiol

Mass-Spectra

Compound Details

Synonymous names
methanethiol
METHYL MERCAPTAN
Methylmercaptan
Mercaptomethane
74-93-1
Methyl sulfhydrate
Thiomethanol
Methanthiol
Thiomethyl alcohol
Metilmercaptano
Methvtiolo
Methylmercaptaan
Mercaptan methylique
Methaanthiol
Thiomethane
RCRA waste number U153
FEMA No. 2716
Methanethiole
CH3SH
methyl-mercaptan
Methyl thioalcohol
MeSH
UN 1064
2X8406WW9I
Methaanthiol [Dutch]
Methanthiol [German]
Methvtiolo [Italian]
Methylmercaptaan [Dutch]
Metilmercaptano [Italian]
Metilmercaptano [Spanish]
SCH 54292
Methyl mercaptan (natural)
Mercaptan methylique [French]
HSDB 813
EINECS 200-822-1
UN1064
RCRA waste no. U153
BRN 1696840
methylsulfanyl
methane thiol
methyl sulfides
methyl thiol
methyl-thiol
UNII-2X8406WW9I
(methyl)sulfane
Methylthioalcohol
a methyl thioether
sulfonium methylide
Methanethiol, purum
Methanethiol, 98.0%
METHANETHIOL [MI]
EC 200-822-1
Methanethiol, >=98.0%
4-01-00-01273 (Beilstein Handbook Reference)
METHYL MERCAPTAN [FHFI]
METHYL MERCAPTAN [HSDB]
DTXSID5026382
CHEBI:16007
CHEBI:86315
DTXSID10168842
DTXSID60992376
InChI=1/CH4S/c1-2/h2H,1H
NSC229573
AKOS009157032
NSC-229573
Methyl mercaptan [UN1064] [Poison gas]
NS00020025
C00409
Q409309
17719-48-1
Z22
Microorganism:

Yes

IUPAC namemethanethiol
SMILESCS
InchiInChI=1S/CH4S/c1-2/h2H,1H3
FormulaCH4S
PubChem ID878
Molweight48.11
LogP0.5
Atoms2
Bonds0
H-bond Acceptor1
H-bond Donor1
Chemical Classificationsulfur compounds thiols
CHEBI-ID16007
Supernatural-IDSN0213930

mVOC Specific Details

Boiling Point
DegreeReference
5.95 °C peer reviewed
Volatilization
The Henry's Law constant for methyl mercaptan is estimated as 0.0031 atm-cu m/mole(SRC) derived from its vapor pressure, 1,510 mm Hg(1), and water solubility, 15,400 mg/L(2). This Henry's Law constant indicates that methyl mercaptan is expected to volatilize rapidly from water surfaces(3). Based on this Henry's Law constant, the volatilization half-life from a model river (1 m deep, flowing 1 m/sec, wind velocity of 3 m/sec)(3) is estimated as 0.8 hours(SRC). The volatilization half-life from a model lake (1 m deep, flowing 0.05 m/sec, wind velocity of 0.5 m/sec)(3) is estimated as 2.8 days(SRC). Methyl mercaptan's Henry's Law constant indicates that volatilization from moist soil surfaces is expected to occur(SRC). Methyl mercaptan is expected to volatilize rapidly from dry soil surfaces based upon its vapor pressure and because it is a gas a temperatures above 6 deg C(SRC). However, gaseous methyl mercaptan gas has been found to strongly adsorb to moist and dry soil surfaces suggesting that adsorption might be an environmental sink for methyl mercaptan(4). Therefore, the importance of volatilization from soil surfaces may be attenuated by adsorption(SRC).
Literature: (1) Daubert TE, Danner RP; Physical and Thermodynamic Properties of Pure Chemicals Data Compilation. Washington, DC: Taylor and Francis (1989) (2) Hine J, Mookerjee PK; J Org Chem 40: 292-8 (1975) (3) Lyman WJ et al; Handbook of Chemical Property Estimation Methods. Washington, DC: Amer Chem Soc pp. 15-1 to 15-29 (1990) (4) Smith KA et al; Soil Sci 116: 313-9 (1973)
Soil Adsorption
Using a structure estimation method based on molecular connectivity indices(1), the Koc of methyl mercaptan can be estimated to be 13(SRC). According to a classification scheme(2), this estimated Koc value suggests that methyl mercaptan is expected to have very high mobility in soil. Gaseous methyl mercaptan has been observed to partition to soils(3). For example, when gaseous methyl mercaptan was passed over six air-dried and moist (50% field capacity) soils, 2.4-32.1 mg/g and 2.2-21.4 mg/g of methyl mercaptan rapidly adsorbed to the dry and moist soils, respectively(3). Neither the capacity or rate of sorption was correlated to soil pH, organic matter content, or clay content; sterile controls ruled out the involvement of microorganisms(3); it was suggested that adsorption to soil surfaces might be an environmental sink for gaseous methyl mercaptan(3).
Literature: (1) US EPA; Estimation Program Interface (EPI) Suite. Ver. 4.1. Jan, 2011. Available from, as of July 19, 2012: http://www.epa.gov/oppt/exposure/pubs/episuitedl.htm (2) Swann RL et al; Res Rev 85: 17-28 (1983) (3) Smith KA et al; Soil Sci 116: 313-9 (1973)
Vapor Pressure
PressureReference
1,510 mm Hg at 25 deg CDaubert, T.E., R.P. Danner. Physical and Thermodynamic Properties of Pure Chemicals Data Compilation. Washington, D.C.: Taylor and Francis, 1989.
MS-Links
MS-Links

Species emitting the compound
KingdomSpeciesBiological FunctionOrigin/HabitatReference
EukaryotaAspergillus FumigatusNANAChippendale et al. 2014
ProkaryotaEscherichia ColiNANADolch et al. 2012
ProkaryotaPseudomonas AeruginosaNANADolch et al. 2012
ProkaryotaBurkholderia CepaciaNANAThorn et al. 2011
ProkaryotaBurkholderia CepaciaNANADryahina et al. 2016
ProkaryotaEnterococcus FaecalisNANAThorn et al. 2011
ProkaryotaEscherichia ColiNANAAllardyce et al. 2006
ProkaryotaEscherichia ColiNANAAllardyce et al. 2006
ProkaryotaEscherichia ColiNANAScotter et al. 2006
ProkaryotaEscherichia ColiNANAThorn et al. 2011
ProkaryotaNeisseria MeningitidisNANAScotter et al. 2006
ProkaryotaProteus MirabilisNANAThorn et al. 2011
ProkaryotaPseudomonas AeruginosaNANACarroll et al. 2005
ProkaryotaPseudomonas AeruginosaNANAAllardyce et al. 2006
ProkaryotaPseudomonas AeruginosaNANAThorn et al. 2011
ProkaryotaPseudomonas AeruginosaNANADryahina et al. 2016
ProkaryotaStaphylococcus AureusNANAAllardyce et al. 2006
ProkaryotaStaphylococcus AureusNANAAllardyce et al. 2006
ProkaryotaStaphylococcus AureusNANAThorn et al. 2011
ProkaryotaStaphylococcus AureusNANADryahina et al. 2016
ProkaryotaStenotrophomonas MaltophiliaNANADryahina et al. 2016
ProkaryotaStreptococcus PneumoniaeNANAAllardyce et al. 2006
ProkaryotaStreptococcus PneumoniaeNANAScotter et al. 2006
ProkaryotaStreptococcus PyogenesNANAThorn et al. 2011
ProkaryotaHaemophilus InfluenzaeNANAFilipiak et al. 2012
ProkaryotaPseudomonas AeruginosaNANANA
ProkaryotaPseudomonas AeruginosaNANAFilipiak et al. 2012
ProkaryotaStaphylococcus AureusNANAFilipiak et al. 2012
ProkaryotaStreptococcus PneumoniaeNANAFilipiak et al. 2012
ProkaryotaKlebsiella PneumoniaeNARees et al. 2017
EukaryotaFusarium OxysporumonionWang et al. 2018
EukaryotaFusarium ProliferatumonionWang et al. 2018
ProkaryotaPseudomonas Fluorescens0Medicago spp. plant rhizospheresHernández-León et al. 2015
ProkaryotaPseudomonas Sp.antifungal activity against Thielaviopsis ethacetica mycelial growthBrazilian Biorenewables National Laboratory – LNBR/CNPEM Microorganism Collection, Campinas, SP; isolatedfrom soil and roots of highly productive sugarcane-producing regions; BrazilFreitas et al. 2022
ProkaryotaPaenibacillus PolymyxaNAMülner et al. 2021
EukaryotaCandida AlbicansATCC MYA-2876, American Type Culture CollectionCosta et al. 2020
EukaryotaCandida GlabrataATCC 90030, American Type Culture CollectionCosta et al. 2020
EukaryotaCandida TropicalisATCC 750, American Type Culture CollectionCosta et al. 2020
ProkaryotaBacillus AtrophaeusLeibnitz Institute DSMZ-German Collection of Microorganisms and Cell Cultures GmbHMülner et al. 2020
ProkaryotaBacillus AmyloliquefaciensLeibnitz Institute DSMZ-German Collection of Microorganisms and Cell Cultures GmbHMülner et al. 2020
ProkaryotaBacillus LicheniformisLeibnitz Institute DSMZ-German Collection of Microorganisms and Cell Cultures GmbHMülner et al. 2020
ProkaryotaBacillus PumilusLeibnitz Institute DSMZ-German Collection of Microorganisms and Cell Cultures GmbHMülner et al. 2020
EukaryotaTuber Magnatumcollected from natural truffle orchards in Istria (Croatia) during one truffle season (October 2018–January 2019)Niimi et al. 2021
EukaryotaTuber Magnatumcollected from natural truffle orchards in Baranya (Hungary) during one truffle season (October 2018–January 2019)Niimi et al. 2021
EukaryotaTuber Magnatumcollected from natural truffle orchards in Somogy (Hungary) during one truffle season (October 2018–January 2019)Niimi et al. 2021
EukaryotaTuber Magnatumcollected from natural truffle orchards in Abruzzo (Italy) during one truffle season (October 2018–January 2019)Niimi et al. 2021
EukaryotaTuber Magnatumcollected from natural truffle orchards in Kalubara (Serbia) during one truffle season (October 2018–January 2019)Niimi et al. 2021
EukaryotaTuber Magnatumcollected from natural truffle orchards in Srem (Serbia) during one truffle season (October 2018–January 2019)Niimi et al. 2021
ProkaryotaBacillus Amyloliquefaciensn/aNALee et al. 2012
ProkaryotaBacillus Subtilisn/aNALee et al. 2012
ProkaryotaPaenibacillus Polymyxan/aNALee et al. 2012
ProkaryotaAlpha Proteobacterian/aNASchulz and Dickschat 2007
ProkaryotaGamma Proteobacterian/aNASchulz and Dickschat 2007
ProkaryotaAlcaligenes Faecalisn/aNASchulz and Dickschat 2007
ProkaryotaDesulfovibrio Acrylicusn/aNASchulz and Dickschat 2007
ProkaryotaParasporobacterium Paucivoransn/aNASchulz and Dickschat 2007
ProkaryotaLactococcus Sp.n/aNASchulz and Dickschat 2007
ProkaryotaLactobacillus Sp.n/aNASchulz and Dickschat 2007
ProkaryotaLactobacillus Lactisn/aNASchulz and Dickschat 2007
ProkaryotaBrevibacterium Linensn/aNASchulz and Dickschat 2007
ProkaryotaOenococcus Oenin/aNASchulz and Dickschat 2007
ProkaryotaLactobacillus Brevisn/aNASchulz and Dickschat 2007
ProkaryotaLactobacillus Hilgardiin/aNASchulz and Dickschat 2007
ProkaryotaLactobacillus Plantarumn/aNASchulz and Dickschat 2007
ProkaryotaPorphyromonas Gingivalisn/aNASchulz and Dickschat 2007
ProkaryotaFusobacterium Nucleatumn/aNASchulz and Dickschat 2007
ProkaryotaTreponema Denticolan/aNASchulz and Dickschat 2007
ProkaryotaCitrobacter Freundiin/aNASchulz and Dickschat 2007
ProkaryotaEscherichia Colin/aNABunge et al. 2008
ProkaryotaShigella Flexnerin/aNABunge et al. 2008
ProkaryotaSalmonella Enterican/aNABunge et al. 2008
EukaryotaCandida Tropicalisn/aNABunge et al. 2008
EukaryotaTuber Magnatumn/aItalian geographical areas (Piedmont, Marche, Emilia Romagna, Border region area between Emilia Romagna and Marche)Gioacchini et al. 2008
ProkaryotaPseudomonas PutidananaSchöller et al. 1997
ProkaryotaPseudomonas TolaasiinanaLo Cantore et al. 2015
ProkaryotaPseudomonas Putidanarhizosphere of bean plants, southern ItalyGiorgio et al. 2015
ProkaryotaRalstonia SolanacearumnanaSpraker et al. 2014
ProkaryotaKlebsiella PneumoniaeNARees et al. 2016a
EukaryotaSchizophyllum Communen/aNAStotzky and Schenck 1976
ProkaryotaStreptococcus PneumoniaeclinicPreti et al. 2009
ProkaryotaPseudomonas Perolensnasterile fish muscle (Sebastes melanops)Miller et al. 1973
ProkaryotaAchromobacter Sp.NANAAlmeida et al. 2022
ProkaryotaSerratia Sp.NANAAlmeida et al. 2022
ProkaryotaEnterobacter Sp.NANAAlmeida et al. 2022
ProkaryotaEscherichia ColiNANAAlmeida et al. 2022
ProkaryotaPeribacillus Sp.NANAToral et al. 2021
ProkaryotaPsychrobacillus VulpisNANAToral et al. 2021
MicrobacteriumBallot et al. 2023
Method
KingdomSpeciesGrowth MediumApplied MethodVerification
EukaryotaAspergillus FumigatusBHIGC-MSno
ProkaryotaEscherichia ColiLBIMR-MSno
ProkaryotaPseudomonas AeruginosaLBIMR-MSno
ProkaryotaBurkholderia CepaciaTYESIFT-MSno
ProkaryotaBurkholderia CepaciaMHBSIFT-MSno
ProkaryotaBurkholderia CepaciaNBSIFT-MSno
ProkaryotaBurkholderia CepaciaBHISIFT-MSno
ProkaryotaEnterococcus FaecalisTYESIFT-MSno
ProkaryotaEscherichia Colihuman bloodSIFT-MSno
ProkaryotaEscherichia ColiBacT/ALERT FASIFT-MSno
ProkaryotaEscherichia ColiTYESIFT-MSno
ProkaryotaNeisseria Meningitidishuman bloodSIFT-MSno
ProkaryotaProteus MirabilisTYESIFT-MSno
ProkaryotaPseudomonas AeruginosaPseudomonas selectiveSIFT-MSno
ProkaryotaPseudomonas AeruginosaBlood agarSIFT-MSno
ProkaryotaPseudomonas AeruginosaBacT/ALERT FASIFT-MSno
ProkaryotaPseudomonas AeruginosaTYESIFT-MSno
ProkaryotaPseudomonas AeruginosaBHISIFT-MSno
ProkaryotaPseudomonas AeruginosaMHBSIFT-MSno
ProkaryotaPseudomonas AeruginosaNBSIFT-MSno
ProkaryotaStaphylococcus Aureushuman bloodSIFT-MSno
ProkaryotaStaphylococcus AureusBacT/ALERT FASIFT-MSno
ProkaryotaStaphylococcus AureusTYESIFT-MSno
ProkaryotaStaphylococcus AureusNBSIFT-MSno
ProkaryotaStaphylococcus AureusMHBSIFT-MSno
ProkaryotaStaphylococcus AureusBHISIFT-MSno
ProkaryotaStenotrophomonas MaltophiliaMHBSIFT-MSno
ProkaryotaStenotrophomonas MaltophiliaBHISIFT-MSno
ProkaryotaStenotrophomonas MaltophiliaNBSIFT-MSno
ProkaryotaStreptococcus Pneumoniaehuman bloodSIFT-MSno
ProkaryotaStreptococcus PyogenesTYESIFT-MSno
ProkaryotaHaemophilus InfluenzaeTryptic soya supp. factors X&VTD/GC-MSno
ProkaryotaPseudomonas Aeruginosatrypticase soy agarTD/GC-MSno
ProkaryotaPseudomonas Aeruginosatryptic soy brothTD/GC-MSno
ProkaryotaStaphylococcus Aureustryptic soy brothTD/GC-MSno
ProkaryotaStreptococcus PneumoniaeTryptic soyaTD/GC-MSno
ProkaryotaKlebsiella PneumoniaeLBSPME / GCxGC-TOFMSno
EukaryotaFusarium OxysporumLiquid onion extract medium (LOM)SPME, GC-MSyes
EukaryotaFusarium ProliferatumLiquid onion extract medium (LOM)SPME, GC-MSyes
ProkaryotaPseudomonas FluorescensNutrient AgarSPME-GC-MSno
ProkaryotaPseudomonas Sp.LB media, DYGS mediaHS-SPME/GC-MSno
ProkaryotaPseudomonas Sp.LB mediaHS-SPME/GC-MSno
ProkaryotaPaenibacillus PolymyxaNA media, TSA mediaHS-SPME/GC-MSno
ProkaryotaPaenibacillus PolymyxaTSA mediaHS-SPME/GC-MSno
EukaryotaCandida AlbicansYGC mediaHS-SPME/GC-GC-ToFMSno
EukaryotaCandida GlabrataYGC mediaHS-SPME/GC-GC-ToFMSno
EukaryotaCandida TropicalisYGC mediaHS-SPME/GC-GC-ToFMSno
ProkaryotaBacillus Atrophaeusnutrient agarHS-SPME/GC-MSno
ProkaryotaBacillus Amyloliquefaciensnutrient agarHS-SPME/GC-MSno
ProkaryotaBacillus Licheniformisnutrient agarHS-SPME/GC-MSno
ProkaryotaBacillus Pumilusnutrient agarHS-SPME/GC-MSno
EukaryotaTuber MagnatumGC-MS-Ono
ProkaryotaBacillus AmyloliquefaciensTryptic soy agarSPME coupled with GC-MSno
ProkaryotaBacillus SubtilisTryptic soy agarSPME coupled with GC-MSno
ProkaryotaPaenibacillus PolymyxaTryptic soy agarSPME coupled with GC-MSno
ProkaryotaAlpha Proteobacterian/an/ano
ProkaryotaGamma Proteobacterian/an/ano
ProkaryotaAlcaligenes Faecalisn/an/ano
ProkaryotaDesulfovibrio Acrylicusn/an/ano
ProkaryotaParasporobacterium Paucivoransn/an/ano
ProkaryotaLactococcus Sp.n/an/ano
ProkaryotaLactobacillus Sp.n/an/ano
ProkaryotaLactobacillus Lactisn/an/ano
ProkaryotaBrevibacterium Linensn/an/ano
ProkaryotaOenococcus Oenin/an/ano
ProkaryotaLactobacillus Brevisn/an/ano
ProkaryotaLactobacillus Hilgardiin/an/ano
ProkaryotaLactobacillus Plantarumn/an/ano
ProkaryotaPorphyromonas Gingivalisn/an/ano
ProkaryotaFusobacterium Nucleatumn/an/ano
ProkaryotaTreponema Denticolan/an/ano
ProkaryotaCitrobacter Freundiin/an/ano
ProkaryotaEscherichia Colin/an/ano
ProkaryotaShigella Flexnerin/an/ano
ProkaryotaSalmonella Enterican/an/ano
EukaryotaCandida Tropicalisn/an/ano
EukaryotaTuber Magnatumn/amicroextraction-gas chromatography-mass spectrometry analysis (SPME-GC-MS)no
ProkaryotaPseudomonas PutidaAB medium + 1% citrate or 0,02% citrate or 1% glucose +1% casaminoacid GC-FID,GC/MSno
ProkaryotaPseudomonas TolaasiiKBSPME-GCno
ProkaryotaPseudomonas PutidaKing's B AgarSPME-GC/MSno
ProkaryotaRalstonia SolanacearumCasamino Acid Peptone Glucose agarSPME-GC/MSno
ProkaryotaKlebsiella PneumoniaeLB GCxGC-TOF-MSno
EukaryotaSchizophyllum Communen/an/ano
ProkaryotaStreptococcus PneumoniaeBlood agar/chocolate blood agaHS-SPME/GC-MS no
ProkaryotaPseudomonas PerolensTrypticase soil agar (BBL)GC/MSno
ProkaryotaAchromobacter Sp.LB broth supplemented with cryoprotectant solution (25 g L−1 gelatin, 50 g L−1 lactose, 10 g L−1 peptone, and 250 g L−1 glycerol)SPME with gas chromatograph (Agilent 7890A, Agilent Technologies) connected to a mass spectrometer (Pegasus® HT TOFMS, LECO Corporation)no
ProkaryotaSerratia Sp.LB broth supplemented with cryoprotectant solution (25 g L−1 gelatin, 50 g L−1 lactose, 10 g L−1 peptone, and 250 g L−1 glycerol)SPME with gas chromatograph (Agilent 7890A, Agilent Technologies) connected to a mass spectrometer (Pegasus® HT TOFMS, LECO Corporation)no
ProkaryotaEnterobacter Sp.LB broth supplemented with cryoprotectant solution (25 g L−1 gelatin, 50 g L−1 lactose, 10 g L−1 peptone, and 250 g L−1 glycerol)SPME with gas chromatograph (Agilent 7890A, Agilent Technologies) connected to a mass spectrometer (Pegasus® HT TOFMS, LECO Corporation)no
ProkaryotaEscherichia ColiLB broth supplemented with cryoprotectant solution (25 g L−1 gelatin, 50 g L−1 lactose, 10 g L−1 peptone, and 250 g L−1 glycerol)SPME with gas chromatograph (Agilent 7890A, Agilent Technologies) connected to a mass spectrometer (Pegasus® HT TOFMS, LECO Corporation)no
ProkaryotaPeribacillus Sp.tryptic soy agar (TSA, Panreac Applichem) mediumHS-SPME-GC/MSno
ProkaryotaPsychrobacillus VulpisMOLPHS-SPME-GC/MSno
ProkaryotaPsychrobacillus VulpisSchaeffer’s growth (SG) mediumHS-SPME-GC/MSno
ProkaryotaPsychrobacillus Vulpistryptic soy agar (TSA, Panreac Applichem) mediumHS-SPME-GC/MSno
Microbacteriumtryptone soy (TS medium; Carl Roth, Karlsruhe, Germany)GC-QQQ-MSno


1-(methyldisulfanyl)propane

Compound Details

Synonymous names
Methyl propyl disulfide
2179-60-4
1-(Methyldisulfanyl)propane
Disulfide, methyl propyl
Methyldithiopropane
2,3-Dithiahexane
Propyl methyl disulfide
Methyl propyl disulphide
Methylpropyldisulfide
Methyl n-propyl disulfide
FEMA No. 3201
8M12K3FU0T
1-methyl-2-propyldisulfane
UNII-8M12K3FU0T
SCHEMBL441902
1-(Methyldisulfanyl)propane #
Methyl propyl disulfide, 90%
CCRIS 3268
DTXSID8062234
CHEBI:89629
FEMA 3201
HY-N7436
EINECS 218-551-2
MFCD00013400
AKOS015897368
METHYL PROPYL DISULFIDE [FHFI]
Methyl propyl disulfide, >=95%, FG
LS-13015
AI3-38157
DB-003725
CS-0128937
M1781
NS00021856
D91531
A815669
J-014295
Q27161826
Microorganism:

No

IUPAC name1-(methyldisulfanyl)propane
SMILESCCCSSC
InchiInChI=1S/C4H10S2/c1-3-4-6-5-2/h3-4H2,1-2H3
FormulaC4H10S2
PubChem ID16592
Molweight122.3
LogP1.8
Atoms6
Bonds3
H-bond Acceptor2
H-bond Donor0
Chemical Classificationsulfides sulfur compounds thioethers
CHEBI-ID89629
Supernatural-IDSN0295228

mVOC Specific Details


Species emitting the compound
KingdomSpeciesBiological FunctionOrigin/HabitatReference
EukaryotaFusarium OxysporumonionWang et al. 2018
EukaryotaFusarium ProliferatumonionWang et al. 2018
Method
KingdomSpeciesGrowth MediumApplied MethodVerification
EukaryotaFusarium OxysporumLiquid onion extract medium (LOM)SPME, GC-MSyes
EukaryotaFusarium ProliferatumLiquid onion extract medium (LOM)SPME, GC-MSyes


O-methyl Ethanethioate

Compound Details

Synonymous names
Methyl thioacetate
O-methyl ethanethioate
CH3C(S)OCH3
21119-13-1
CH3C(=S)OCH3
thioacetic acid methyl ester
CHEBI:51281
DTXSID10334161
Q27122504
Microorganism:

Yes

IUPAC nameO-methyl ethanethioate
SMILESCC(=S)OC
InchiInChI=1S/C3H6OS/c1-3(5)4-2/h1-2H3
FormulaC3H6OS
PubChem ID519840
Molweight90.15
LogP0.7
Atoms5
Bonds1
H-bond Acceptor2
H-bond Donor0
Chemical Classificationthioesters sulfur compounds
CHEBI-ID51280

mVOC Specific Details


Species emitting the compound
KingdomSpeciesBiological FunctionOrigin/HabitatReference
ProkaryotaPseudomonas AeruginosaNANADavis et al. 2020
EukaryotaFusarium OxysporumonionWang et al. 2018
EukaryotaFusarium ProliferatumonionWang et al. 2018
ProkaryotaBurkholderia PyrrociniaRhizosphere soil samples from roots of maize (Zea mays L.) grown in Gongju, South KoreaLuo et al. 2022
ProkaryotaChryseobacterium Sp.nanaTyc et al. 2015
ProkaryotaJanthinobacterium Sp.nanaTyc et al. 2015
Method
KingdomSpeciesGrowth MediumApplied MethodVerification
ProkaryotaPseudomonas AeruginosaLB brothSPME/GCxGC-MSno
EukaryotaFusarium OxysporumLiquid onion extract medium (LOM)SPME, GC-MSyes
EukaryotaFusarium ProliferatumLiquid onion extract medium (LOM)SPME, GC-MSyes
ProkaryotaBurkholderia PyrrociniaNA mediaSPME/GC-MSyes
ProkaryotaChryseobacterium Sp.Tryptic soy broth agarGC/MS-Q-TOFno
ProkaryotaJanthinobacterium Sp.Tryptic soy broth agarGC/MS-Q-TOFno


1-methylsulfanylpropane

Compound Details

Synonymous names
Methyl propyl sulfide
3877-15-4
Propane, 1-(methylthio)-
2-Thiapentane
Methyl propyl sulphide
1-methylsulfanylpropane
Sulfide, methyl propyl
METHYL N-PROPYL SULFIDE
1-(Methylthio)propane
1-(Methylthio)-propane
NXA8RQ27B3
METHYLPROPYLSULFIDE
UNII-NXA8RQ27B3
N-PROPYLMETHYLSULFIDE
EINECS 223-403-5
methyl(propyl)sulfane
propyl methyl sulfide
1-(Methylsulfanyl)propane
n-C3H7SCH3
1-(Methylsulfanyl)propane #
DTXSID9073969
FEMA NO. 4889
CHEBI:88383
MFCD00015219
AKOS015897459
M2285
NS00022135
D91585
A824275
Q27160229
Microorganism:

No

IUPAC name1-methylsulfanylpropane
SMILESCCCSC
InchiInChI=1S/C4H10S/c1-3-4-5-2/h3-4H2,1-2H3
FormulaC4H10S
PubChem ID19754
Molweight90.19
LogP1.8
Atoms5
Bonds2
H-bond Acceptor1
H-bond Donor0
Chemical Classificationsulfides sulfur compounds
CHEBI-ID88383
Supernatural-IDSN0475638

mVOC Specific Details

Massbank-Links

Species emitting the compound
KingdomSpeciesBiological FunctionOrigin/HabitatReference
EukaryotaFusarium OxysporumonionWang et al. 2018
EukaryotaFusarium ProliferatumonionWang et al. 2018
Method
KingdomSpeciesGrowth MediumApplied MethodVerification
EukaryotaFusarium OxysporumLiquid onion extract medium (LOM)SPME, GC-MSyes
EukaryotaFusarium ProliferatumLiquid onion extract medium (LOM)SPME, GC-MSyes


(methyldisulfanyl)methane

Mass-Spectra

Compound Details

Synonymous names
Dimethyl disulfide
624-92-0
METHYL DISULFIDE
Dimethyldisulfide
Dimethyl disulphide
DMDS
Disulfide, dimethyl
2,3-Dithiabutane
(Methyldisulfanyl)methane
Methyldisulfide
Methyldithiomethane
(Methyldithio)methane
Sulfa-hitech
dimethyldisulphide
FEMA No. 3536
NSC 9370
1,2-Dimethyldisulfane
CCRIS 2939
HSDB 6400
EINECS 210-871-0
UNII-3P8D642K5E
CHEBI:4608
Dimethyl-d6 disulfide
AI3-25305
3P8D642K5E
NSC-9370
MFCD00008561
DTXSID4025117
(CH3S)2
EC 210-871-0
Paladin
UN2381
dimethydisulfide
methyl disulphide
Dimethyl disulfane
Disulfide dimethyl
MeS-SMe
Disulfide, dimethyl-
methyldisulfanyl methane
Dimethyl disulfide, 98%
Dimethyl disulfide, 99%
(Methyldisulfanyl)methane #
Dimethyl disulfide, >=99%
WLN: 1SS1
DTXCID805117
METHYL DISULFIDE [HSDB]
CHEMBL1347061
Dimethyl disulfide, >=99.0%
DIMETHYL DISULFIDE [FHFI]
NSC9370
BDBM233038
Dimethyl disulfide, >=98%, FG
AMY39506
EINECS 272-923-9
Tox21_201525
AKOS009157459
Dimethyl disulfide, analytical standard
MCULE-7451882535
UN 2381
NCGC00091798-01
NCGC00091798-02
NCGC00259075-01
CAS-624-92-0
Dimethyl disulfide, natural, >=98%, FG
D0714
Dimethyl disulfide, purum, >=98.0% (GC)
NS00001484
EN300-36043
InChI=1/C2H6S2/c1-3-4-2/h1-2H
C08371
E78981
A833808
Dimethyl disulfide [UN2381] [Flammable liquid]
Q419800
Q-100719
F0001-1676
Microorganism:

Yes

IUPAC name(methyldisulfanyl)methane
SMILESCSSC
InchiInChI=1S/C2H6S2/c1-3-4-2/h1-2H3
FormulaC2H6S2
PubChem ID12232
Molweight94.2
LogP1.8
Atoms4
Bonds1
H-bond Acceptor2
H-bond Donor0
Chemical Classificationsulfides sulfur compounds
CHEBI-ID4608
Supernatural-IDSN0417328

mVOC Specific Details

Boiling Point
DegreeReference
109.72 °C peer reviewed
Volatilization
The Henry's Law constant for dimethyl disulfide is reported as 1.21X10-3 atm-cu m/mole(1). This Henry's Law constant indicates that dimethyl disulfide is expected to volatilize rapidly from water surfaces(2). Based on this Henry's Law constant, the volatilization half-life from a model river (1 m deep, flowing 1 m/sec, wind velocity of 3 m/sec)(2) is estimated as 3.5 hours(SRC). The volatilization half-life from a model lake (1 m deep, flowing 0.05 m/sec, wind velocity of 0.5 m/sec)(2) is estimated as 4.1 days(SRC). Dimethyl disulfide's Henry's Law constant indicates that volatilization from moist soil surfaces may occur(SRC). In a laboratory study, the volatilization rate of dimethyl disulfide from a tidal marsh soil (at field capacity or 1.5 field capacity) ranged from 0.1 to 0.4 ng (sulfur basis)/min(3). Dimethyl disulfide is expected to volatilize from dry soil surfaces(SRC) based upon a vapor pressure of 28.7 mm Hg(4).
Literature: (1) Vitenberg AG et al; J Chromatography 112: 319-27 (1975) (2) Lyman WJ et al; Handbook of Chemical Property Estimation Methods. Washington, DC: Amer Chem Soc pp. 15-1 to 15-29 (1990) (3) Farwell SO et al; Soil Biol Biochem 11: 411-5 (1979) (4) Daubert TE, Danner RP; Physical & Thermodynamic Properties of Pure Chemicals: Data Compilation. New York, NY: Hemisphere Pub Corp (1989)
Soil Adsorption
Using a structure estimation method based on molecular connectivity indices(1), the Koc of dimethyl disulfide can be estimated to be 40(SRC). According to a classification scheme(2), this estimated Koc value suggests that dimethyl disulfide is expected to have very high mobility in soil. Gas chromatographic studies with various air-dry and moist soils have shown that soil can sorb atmospheric, gas phase dimethyl disulfide(3). In one closed-system test, 17-94% of input dimethyl disulfide was sorbed by the soil in 10 min(3); in a 15-day test, dimethyl disulfide sorption was 101-306 ug sorbed/g soil(3). Soil microbes were found to be important for the gas phase sorption of dimethyl disulfide as 15-day sorption in sterilized soil was only 9-98 ug sorbed/g soil(3).
Literature: (1) US EPA; Estimation Program Interface (EPI) Suite. Ver. 4.1. Jan, 2011. Available from, as of Nov 7, 2013: http://www.epa.gov/oppt/exposure/pubs/episuitedl.htm (2) Swann RL et al; Res Rev 85: 17-28 (1983) (3) Bremner JM, Banwart WL; Soil Biol Biochem 8: 79-83 (1976)
Vapor Pressure
PressureReference
28.7 mm Hg at 25 deg CDaubert, T.E., R.P. Danner. Physical and Thermodynamic Properties of Pure Chemicals Data Compilation. Washington, D.C.: Taylor and Francis, 1989.
MS-Links
Massbank-Links

Species emitting the compound
KingdomSpeciesBiological FunctionOrigin/HabitatReference
EukaryotaAspergillus FumigatusNANAChippendale et al. 2014
ProkaryotaBurkholderia CepaciaNANADryahina et al. 2016
ProkaryotaEnterococcus FaecalisNANAThorn et al. 2011
ProkaryotaEscherichia ColiNANAAllardyce et al. 2006
ProkaryotaEscherichia ColiNANAAllardyce et al. 2006
ProkaryotaEscherichia ColiNANAThorn et al. 2011
ProkaryotaNeisseria MeningitidisNANAAllardyce et al. 2006
ProkaryotaProteus MirabilisNANAThorn et al. 2011
ProkaryotaPseudomonas AeruginosaNANACarroll et al. 2005
ProkaryotaPseudomonas AeruginosaNANAAllardyce et al. 2006
ProkaryotaPseudomonas AeruginosaNANAThorn et al. 2011
ProkaryotaPseudomonas AeruginosaNANADryahina et al. 2016
ProkaryotaStaphylococcus AureusNANAAllardyce et al. 2006
ProkaryotaStaphylococcus AureusNANADryahina et al. 2016
ProkaryotaStenotrophomonas MaltophiliaNANADryahina et al. 2016
ProkaryotaStenotrophomonas MaltophiliaNANAShestivska et al. 2015
ProkaryotaStenotrophomonas RhizophilaNANAShestivska et al. 2015
ProkaryotaStreptococcus PneumoniaeNANAAllardyce et al. 2006
ProkaryotaStreptococcus PneumoniaeNANAScotter et al. 2006
ProkaryotaEscherichia ColiNANAAhmed et al. 2023
ProkaryotaKlebsiella PneumoniaeNANAAhmed et al. 2023
ProkaryotaPseudomonas AeruginosaNANAAhmed et al. 2023
ProkaryotaStaphylococcus AureusNANAAhmed et al. 2023
ProkaryotaEscherichia ColiNANAHewett et al. 2020
ProkaryotaPseudomonas AeruginosaNANABean et al. 2016
ProkaryotaPseudomonas AeruginosaNANADavis et al. 2020
ProkaryotaBurkholderia CepaciaNANANA
EukaryotaCandida KruseiNANAHertel et al. 2016a
EukaryotaCandida AlbicansNANAHertel et al. 2016a
EukaryotaCandida GlabrataNANAHertel et al. 2016a
EukaryotaCandida TropicalisNANAHertel et al. 2016a
ProkaryotaEscherichia ColiNANALawal et al. 2018a
ProkaryotaEscherichia ColiNANADixon et al. 2022
ProkaryotaHaemophilus InfluenzaeNANAFilipiak et al. 2012
ProkaryotaKlebsiella PneumoniaeNANAZechman et al. 1986
ProkaryotaPseudomonas AeruginosaNANAZechman et al. 1986
ProkaryotaPseudomonas AeruginosaNANANeerincx et al. 2016
ProkaryotaPseudomonas AeruginosaNANALawal et al. 2018a
ProkaryotaPseudomonas AeruginosaNANANA
ProkaryotaPseudomonas PutidaNANANA
ProkaryotaPseudomonas AeruginosaNANAFilipiak et al. 2012
ProkaryotaShewanella PutrefaciensNANANA
ProkaryotaStaphylococcus AureusNANAZechman et al. 1986
ProkaryotaStaphylococcus AureusNANABoots et al. 2014
ProkaryotaStaphylococcus AureusNANALawal et al. 2018a
ProkaryotaStenotrophomonas MaltophiliaNANANA
ProkaryotaStreptococcus PneumoniaeNANAFilipiak et al. 2012
ProkaryotaEnterobacter CloacaeNANAJünger et al. 2012
ProkaryotaEscherichia ColiNANAJünger et al. 2012
ProkaryotaProteus MirabilisNANAJünger et al. 2012
ProkaryotaPseudomonas AeruginosaNANAJünger et al. 2012
ProkaryotaSerratia MarcescensNANAJünger et al. 2012
ProkaryotaEnterobacter CloacaeNALawal et al. 2018
ProkaryotaPseudomonas AeruginosaNALawal et al. 2018
EukaryotaEurotium Amstelodamiwild strainsSchleibinger et al. 2005
EukaryotaPenicillium Brevicompactumwild strainsSchleibinger et al. 2005
ProkaryotaBacillus AcidicelerNAMéndez-Bravo et al. 2018
ProkaryotaShigella SonneiChina Center of Industrial Culture collectionWang et al. 2018
EukaryotaFusarium OxysporumonionWang et al. 2018
EukaryotaFusarium ProliferatumonionWang et al. 2018
ProkaryotaBacillus Sp.antifungal activity against Fusarium solaniRhizosphere soil of avocadoGuevara-Avendaño et al. 2019
ProkaryotaIgnatzschineria Indicapig (Sus scrofa domesticus) carcassCernosek et al. 2020
ProkaryotaPseudomonas Fluorescens0Medicago spp. plant rhizospheresHernández-León et al. 2015
ProkaryotaHyphomonas Sp.swine wastewaterCho et al. 2019
ProkaryotaRhizobium Sp.swine wastewaterCho et al. 2019
ProkaryotaPseudomonas ProtegensNAMannaa et al. 2018
ProkaryotaSerratia Marcescensantifungal activity against Aspergillus flavustea rhizosphere in Xinyang, Henan province, ChinaGong et al. 2022
ProkaryotaBacillus Muralisantifungal activity against mycelial growth and spore germination of phytopathogenic Moniliophtora roreriphytopathology strain collection of El Colegio de la Frontera Sur (ECOSUR), Tapachula, Chiapas, MexicoDe la Cruz-López et al. 2022
ProkaryotaBacillus Pumilusantifungal activity against mycelial growth and spore germination of phytopathogenic Moniliophtora roreriphytopathology strain collection of El Colegio de la Frontera Sur (ECOSUR), Tapachula, Chiapas, MexicoDe la Cruz-López et al. 2022
ProkaryotaNovosphingobium Lindaniclasticumantifungal activity against mycelial growth and spore germination of phytopathogenic Moniliophtora roreriphytopathology strain collection of El Colegio de la Frontera Sur (ECOSUR), Tapachula, Chiapas, MexicoDe la Cruz-López et al. 2022
ProkaryotaBacillus Subtilisantifungal activity against mycelial growth and spore germination of phytopathogenic Moniliophtora roreriphytopathology strain collection of El Colegio de la Frontera Sur (ECOSUR), Tapachula, Chiapas, MexicoDe la Cruz-López et al. 2022
ProkaryotaBacillus Amyloliquefaciensantifungal activity against mycelial growth and spore germination of phytopathogenic Moniliophtora roreriphytopathology strain collection of El Colegio de la Frontera Sur (ECOSUR), Tapachula, Chiapas, MexicoDe la Cruz-López et al. 2022
ProkaryotaBacillus Megateriumantifungal activity against mycelial growth and spore germination of phytopathogenic Moniliophtora roreriphytopathology strain collection of El Colegio de la Frontera Sur (ECOSUR), Tapachula, Chiapas, MexicoDe la Cruz-López et al. 2022
ProkaryotaBacillus Subtilisantibacterial activity against growth of Ralstonia solanacearumPlant Bacteriology Lab, Division of Plant Pathology, Indian Council of Agricultural Research - Indian Agricultural Research Institute, New DelhiKashyap et al. 2022
ProkaryotaPseudomonas Fluorescensantibacterial activity against growth of Ralstonia solanacearumPlant Bacteriology Lab, Division of Plant Pathology, Indian Council of Agricultural Research - Indian Agricultural Research Institute, New DelhiKashyap et al. 2022
ProkaryotaPseudomonas Sp.antifungal activity against Thielaviopsis ethacetica mycelial growthBrazilian Biorenewables National Laboratory – LNBR/CNPEM Microorganism Collection, Campinas, SP; isolatedfrom soil and roots of highly productive sugarcane-producing regions; BrazilFreitas et al. 2022
ProkaryotaBacillus Mycoidesisolate from Irish potato soilsHeenan-Daly et al. 2021
ProkaryotaPseudomonas Pseudoalcaligenespromotes the growth of Zea mays L. and confer the resistance to drought stress in this maizeApplied Microbiology and Biotechnology lab, Department of Biosciences, Comsats University IslamabadYasmin et al. 2021
EukaryotaCandida AlbicansATCC MYA-2876, American Type Culture CollectionCosta et al. 2020
EukaryotaCandida GlabrataATCC 90030, American Type Culture CollectionCosta et al. 2020
EukaryotaCandida TropicalisATCC 750, American Type Culture CollectionCosta et al. 2020
ProkaryotaStaphylococcus AureusLeibnitz Institute DSMZ-German Collection of Microorganisms and Cell Cultures GmbHFitzgerald et al. 2020
ProkaryotaPseudomonas AeruginosaLeibnitz Institute DSMZ-German Collection of Microorganisms and Cell Cultures GmbHFitzgerald et al. 2020
ProkaryotaEscherichia ColiLeibnitz Institute DSMZ-German Collection of Microorganisms and Cell Cultures GmbHFitzgerald et al. 2020
ProkaryotaStaphylococcus Epidermidisstrains were provided by Prof. O'Gara at NUI GalwayFitzgerald et al. 2020
ProkaryotaBacillus Subtilisgrowth stimulation effects on Solanum tuberosum tubers (potato) and Zea mays seeds (maize)NAMülner et al. 2020
ProkaryotaBacillus SubtilisNAMülner et al. 2020
ProkaryotaBacillus Atrophaeusgrowth stimulation effects on Solanum tuberosum tubers (potato) and Zea mays seeds (maize)NAMülner et al. 2020
ProkaryotaBacillus AmyloliquefaciensLeibnitz Institute DSMZ-German Collection of Microorganisms and Cell Cultures GmbHMülner et al. 2020
ProkaryotaBacillus Velezensisgrowth stimulation effects on Solanum tuberosum tubers (potato) and Zea mays seeds (maize)Leibnitz Institute DSMZ-German Collection of Microorganisms and Cell Cultures GmbHMülner et al. 2020
ProkaryotaBacillus Velezensisgrowth stimulation effects on Solanum tuberosum tubers (potato) and Zea mays seeds (maize)NAMülner et al. 2020
ProkaryotaBacillus VelezensisNAMülner et al. 2020
ProkaryotaBacillus LicheniformisLeibnitz Institute DSMZ-German Collection of Microorganisms and Cell Cultures GmbHMülner et al. 2020
ProkaryotaBacillus LicheniformisNAMülner et al. 2020
ProkaryotaPseudomonas AeruginosaNational Collections of Industrial Food and Marine Bacteria, American Type Culture CollectionSlade et al. 2022
ProkaryotaChromobacterium Vacciniiantifungal activity against Trichoderma sp. MWU14-9201, Phoma sp. MWU-UMCS9302, Colletotrichum sp. MWU-UMCS9301, Coleophoma sp. MWU-UMCS9305 and Phytophthora cinnamomi R001isolate from cultivated cranberry bog soils in Massachusetts (USA)Ebadzadsahrai et al. 2020
ProkaryotaStaphylococcus EpidermidisAmerican Type Culture CollectionJenkins and Bean 2020
ProkaryotaStreptomyces GriseusNARiu et al. 2022
EukaryotaChromera VeliaCulture Collection of Algae and Protozoa (CCAP) at the SAMS Limited Scottish Marine Institute (Oban, Argyll, Scotland, UK)Koteska et al. 2023
ProkaryotaBacillus Cereuspromote fungal hypocrellin A production in Shiraia sp. S9isolate and deposite at the China General Microbiological Culture Collection Center (CGMCC)Xu et al. 2022
ProkaryotaBurkholderia Pyrrociniapromote aerial and root growth in Arabidopsis thaliana seedlingsRhizosphere soil samples from roots of maize (Zea mays L.) grown in Gongju, South KoreaLuo et al. 2022
ProkaryotaStreptomyces Alboflavusn/aNAWang et al. 2013
ProkaryotaStreptomyces Albidoflavusn/aNASchöller et al. 2002
ProkaryotaStreptomyces Sp.n/aNASchöller et al. 2002
ProkaryotaStreptomyces Rishiriensisn/aNASchöller et al. 2002
ProkaryotaStreptomyces Albusn/aNASchöller et al. 2002
ProkaryotaStreptomyces Antibioticusn/aNASchöller et al. 2002
ProkaryotaStreptomyces Aureofaciensn/aNASchöller et al. 2002
ProkaryotaStreptomyces Coelicolorn/aNASchöller et al. 2002
ProkaryotaStreptomyces Diastatochromogenesn/aNASchöller et al. 2002
ProkaryotaStreptomyces Griseusn/aNASchöller et al. 2002
ProkaryotaStreptomyces Hirsutusn/aNASchöller et al. 2002
ProkaryotaStreptomyces Hygroscopicusn/aNASchöller et al. 2002
ProkaryotaStreptomyces Murinusn/aNASchöller et al. 2002
ProkaryotaStreptomyces Olivaceusn/aNASchöller et al. 2002
ProkaryotaStreptomyces Thermoviolaceusn/aNASchöller et al. 2002
ProkaryotaSerratia Proteamaculansn/aNAWeise et al. 2014
ProkaryotaSerratia Plymuthican/aNAWeise et al. 2014
ProkaryotaLactococcus Sp.This compound is assumed to have an antagonistic effect against sapstain fungi.NASchulz and Dickschat 2007
ProkaryotaLactobacillus Sp.This compound is assumed to have an antagonistic effect against sapstain fungi.NASchulz and Dickschat 2007
ProkaryotaOenococcus OeniThis compound is assumed to have an antagonistic effect against sapstain fungi.NASchulz and Dickschat 2007
ProkaryotaLactobacillus BrevisThis compound is assumed to have an antagonistic effect against sapstain fungi.NASchulz and Dickschat 2007
ProkaryotaLactobacillus HilgardiiThis compound is assumed to have an antagonistic effect against sapstain fungi.NASchulz and Dickschat 2007
ProkaryotaLactobacillus PlantarumThis compound is assumed to have an antagonistic effect against sapstain fungi.NASchulz and Dickschat 2007
ProkaryotaStreptomyces Sp.This compound is assumed to have an antagonistic effect against sapstain fungi.NASchulz and Dickschat 2007
ProkaryotaActinomycetes Sp.This compound is assumed to have an antagonistic effect against sapstain fungi.NASchulz and Dickschat 2007
ProkaryotaAlcaligenes Sp.This compound is assumed to have an antagonistic effect against sapstain fungi.NASchulz and Dickschat 2007
ProkaryotaBacillus Sp.This compound is assumed to have an antagonistic effect against sapstain fungi.NASchulz and Dickschat 2007
ProkaryotaCitrobacter Sp.This compound is assumed to have an antagonistic effect against sapstain fungi.NASchulz and Dickschat 2007
ProkaryotaEnterobacter Sp.This compound is assumed to have an antagonistic effect against sapstain fungi.NASchulz and Dickschat 2007
ProkaryotaKlebsiella Sp.This compound is assumed to have an antagonistic effect against sapstain fungi.NASchulz and Dickschat 2007
ProkaryotaKlebsiella OxytocaThis compound is assumed to have an antagonistic effect against sapstain fungi.NASchulz and Dickschat 2007
ProkaryotaSerratia Sp.This compound is assumed to have an antagonistic effect against sapstain fungi.NASchulz and Dickschat 2007
ProkaryotaAeromonas VeroniiThis compound is assumed to have an antagonistic effect against sapstain fungi.NASchulz and Dickschat 2007
ProkaryotaStenotrophomonas Maltophilian/aNAZou et al. 2007
ProkaryotaAlcaligenes Faecalisn/aNAZou et al. 2007
ProkaryotaArthrobacter Nitroguajacolicusn/aNAZou et al. 2007
ProkaryotaLysobacter Gummosusn/aNAZou et al. 2007
ProkaryotaSporosarcina Ginsengisolin/aNAZou et al. 2007
ProkaryotaBacillus SimplexReduction of movement or death of Panagrelleus redivivus and Bursaphelenchus xylophilus.NAGu et al. 2007
ProkaryotaBacillus SubtilisReduction of movement or death of Panagrelleus redivivus and Bursaphelenchus xylophilus.NAGu et al. 2007
ProkaryotaBacillus WeihenstephanensisReduction of movement or death of Panagrelleus redivivus and Bursaphelenchus xylophilus.NAGu et al. 2007
ProkaryotaMicrobacterium OxydansReduction of movement or death of Panagrelleus redivivus and Bursaphelenchus xylophilus.NAGu et al. 2007
ProkaryotaStreptomyces LateritiusReduction of movement or death of Panagrelleus redivivus and Bursaphelenchus xylophilus.NAGu et al. 2007
ProkaryotaSerratia MarcescensReduction of movement or death of Panagrelleus redivivus and Bursaphelenchus xylophilus.NAGu et al. 2007
ProkaryotaStreptomyces Sp.n/aNADickschat et al. 2005_2
ProkaryotaCytophaga-Flavobacterium-Bacteroidesn/aNADickschat et al. 2005_3
ProkaryotaCollimonas Fungivoransn/aNAGarbeva et al. 2014
EukaryotaTuber Magnatumn/aItalian geographical areas ( Umbria, Piedmont, Marche, Emilia Romagna, Border region area between Emilia Romagna and Marche, Tuscany, Molise)Gioacchini et al. 2008
EukaryotaTuber Melanosporumn/aT. melanosporum was from the cultivated truffle zones in the province and T. aestivum from the natural truffle zones in the same regionCullere et al. 2010
EukaryotaTuber Aestivumn/aT. melanosporum was from the cultivated truffle zones in the province and T. aestivum from the natural truffle zones in the same regionCullere et al. 2010
ProkaryotaBurkholderia Ambifarian/aBurkholderia ambifaria LMG 17828 from root, LMG 19182 from rhizosphere and LMG 19467 from clinical.Groenhagen et al. 2013
ProkaryotaBurkholderia Glumaen/aNABlom et al. 2011
ProkaryotaBurkholderia Caribensisn/aNABlom et al. 2011
ProkaryotaBurkholderia Latan/aNABlom et al. 2011
ProkaryotaBurkholderia Phenaziniumn/aNABlom et al. 2011
ProkaryotaBurkholderia Phenoliruptrixn/aNABlom et al. 2011
ProkaryotaBurkholderia Pyrrocinian/aNABlom et al. 2011
ProkaryotaBurkholderia Saccharin/aNABlom et al. 2011
ProkaryotaBurkholderia Terricolan/aNABlom et al. 2011
ProkaryotaBurkholderia Xenovoransn/aNABlom et al. 2011
ProkaryotaChromobacterium Violaceumn/aNABlom et al. 2011
ProkaryotaCupriavidus Necatorn/aNABlom et al. 2011
ProkaryotaLimnobacter Thiooxidansn/aNABlom et al. 2011
ProkaryotaPandoraea Norimbergensisn/aNABlom et al. 2011
ProkaryotaPseudomonas Aeruginosan/aNABlom et al. 2011
ProkaryotaPseudomonas Fluorescensn/aNABlom et al. 2011
ProkaryotaPseudomonas Putidan/aNABlom et al. 2011
ProkaryotaSerratia Entomophilan/aNABlom et al. 2011
ProkaryotaSerratia Marcescensn/aNABlom et al. 2011
ProkaryotaSerratia Plymuthican/aNABlom et al. 2011
ProkaryotaSerratia Proteamaculansn/aNABlom et al. 2011
ProkaryotaBurkholderia Tropican/aNATenorio-Salgado et al. 2013
ProkaryotaBacillus Amyloliquefaciensn/aNALee et al. 2012
ProkaryotaBacillus Subtilisn/aNALee et al. 2012
ProkaryotaPaenibacillus Polymyxan/aNALee et al. 2012
ProkaryotaCollimonas Pratensisn/aNAGarbeva et al. 2014
ProkaryotaStaphylococcus Aureusn/aNAElgaali et al. 2002
ProkaryotaEscherichia Colin/aNASiripatrawan et al. 2008
ProkaryotaBurkholderia Sp.bacterial interationsrhizosphere and bulk soil of Carex arenariaTyc et al. 2017
ProkaryotaPaenibacillus Sp.bacterial interationsrhizosphere and bulk soil of Carex arenariaTyc et al. 2017
ProkaryotaEscherichia ColiAmerican Type Culture Collection (ATCC), Rockville, MD or wild strains identified at the University of Kentucky Dept. of Animal Sciences Food Microbiology LaboratoryElgaali et al. 2002
ProkaryotaBacillus CereusAmerican Type Culture Collection (ATCC), Rockville, MD or wild strains identified at the University of Kentucky Dept. of Animal Sciences Food Microbiology LaboratoryElgaali et al. 2002
ProkaryotaBacillus PolymyxaAmerican Type Culture Collection (ATCC), Rockville, MD or wild strains identified at the University of Kentucky Dept. of Animal Sciences Food Microbiology LaboratoryElgaali et al. 2002
ProkaryotaEnterococcus DuransAmerican Type Culture Collection (ATCC), Rockville, MD or wild strains identified at the University of Kentucky Dept. of Animal Sciences Food Microbiology LaboratoryElgaali et al. 2002
ProkaryotaEnterococcus FaeciumAmerican Type Culture Collection (ATCC), Rockville, MD or wild strains identified at the University of Kentucky Dept. of Animal Sciences Food Microbiology LaboratoryElgaali et al. 2002
ProkaryotaLactobacillus LactisAmerican Type Culture Collection (ATCC), Rockville, MD or wild strains identified at the University of Kentucky Dept. of Animal Sciences Food Microbiology LaboratoryElgaali et al. 2002
ProkaryotaLeuconostoc MesenteroidesAmerican Type Culture Collection (ATCC), Rockville, MD or wild strains identified at the University of Kentucky Dept. of Animal Sciences Food Microbiology LaboratoryElgaali et al. 2002
ProkaryotaStreptococcus AgalactiaeAmerican Type Culture Collection (ATCC), Rockville, MD or wild strains identified at the University of Kentucky Dept. of Animal Sciences Food Microbiology LaboratoryElgaali et al. 2002
ProkaryotaStreptococcus ThermophilusAmerican Type Culture Collection (ATCC), Rockville, MD or wild strains identified at the University of Kentucky Dept. of Animal Sciences Food Microbiology LaboratoryElgaali et al. 2002
EukaryotaFusarium Sp.NABrock et al. 2011
EukaryotaPenicillium Sp.NALarsen 1998
ProkaryotaPseudomonas Perolensnasterile fish muscle (Sebastes melanops)Miller et al. 1973
ProkaryotaPseudomonas TolaasiinanaLo Cantore et al. 2015
ProkaryotaPseudonocardia ThermophilanasoilWilkins 1996
ProkaryotaSaccharomonospora RectivirgulanasoilWilkins 1996
ProkaryotaSaccharomonospora ViridisnasoilWilkins 1996
ProkaryotaThermoactinomyces VulgarisnasoilWilkins 1996
ProkaryotaThermomonospora FuscanasoilWilkins 1996
ProkaryotaStreptomyces GriseusnasoilWilkins 1996
ProkaryotaStreptomyces Sp.nabreathing zone of a waste collection workerWilkins 1996
ProkaryotaPseudochrobactrum SaccharolyticumNematicidal activitycow dungXU et al. 2015
ProkaryotaProteus HauseriNematicidal activitycow dungXU et al. 2015
ProkaryotaWautersiella FalseniiNematicidal activitycow dungXU et al. 2015
ProkaryotaArthrobacter NicotianaeNematicidal activitycow dungXU et al. 2015
ProkaryotaAchromobacter XylosoxidansNematicidal activitycow dungXU et al. 2015
ProkaryotaPseudomonas Putidareduces mycelium growth and sclerotia germination of Sclerotinia sclerotiorum USB-F593; lyses red blood cellsrhizosphere of bean plants, southern ItalyGiorgio et al. 2015
ProkaryotaPseudomonas Vranovensisnarhizosphere of field-grown potato plantsHunziker et al. 2015
ProkaryotaPseudomonas Veroniinarhizosphere of field-grown potato plantsHunziker et al. 2015
ProkaryotaPseudomonas Chlororaphisnarhizosphere of field-grown potato plantsHunziker et al. 2015
ProkaryotaPseudomonas Fluorescensnarhizosphere of field-grown potato plantsHunziker et al. 2015
ProkaryotaPseudomonas Frederiksbergensisnaphyllosphere of field-grown potato plantsHunziker et al. 2015
ProkaryotaPseudomonas Syringaenaphyllosphere of field-grown potato plantsHunziker et al. 2015
ProkaryotaPseudomonas Jesseniinaphyllosphere of field-grown potato plantsHunziker et al. 2015
ProkaryotaPseudomonas AeruginosananaBriard et al. 2016
ProkaryotaPseudomonas Chlororaphisbacteriostatic on Agrobacterium tumefaciens C58, suppresses growth of cyanobacterium strain Synechococcus sp. PCC 7942, kills Caenorhabditis elegansRhizosphere of maize, Kiev region, UkrainePopova et al. 2014
ProkaryotaSerratia Proteamaculansbacteriostatic on Agrobacterium tumefaciens C58, suppresses growth of cyanobacterium strain Synechococcus sp. PCC 7942, kills Caenorhabditis elegansspoiled meatPopova et al. 2014
ProkaryotaSerratia Plymuthicastimulates growth of Pseudomonas fluorescens Pf0-1maize rhizosphere, NetherlandsGarbeva et al. 2014
ProkaryotaChryseobacterium Sp.nanaTyc et al. 2015
ProkaryotaTsukamurella Sp.nanaTyc et al. 2015
ProkaryotaDyella Sp.nanaTyc et al. 2015
ProkaryotaJanthinobacterium Sp.nanaTyc et al. 2015
ProkaryotaRalstonia SolanacearumnanaSpraker et al. 2014
EukaryotaAspergillus Versicolornadamp indoor environments, food productsSunesson et al. 1995
EukaryotaPenicillium Communenain dry-cured meat products, cheeseSunesson et al. 1995
EukaryotaPhialophora FastigiatananaSunesson et al. 1995
ProkaryotaLeuconostoc Mesenteroidescan be used to modify or intensify the flavour of industrial cheeses or fermented milks or to preserve the peculiar flavour of traditional dairy productsNAPogačić et al. 2016
ProkaryotaSerratia Sp.n/aNABruce et al. 2004
EukaryotaSaccharomyces Cerevisiaen/aNABruce et al. 2004
ProkaryotaStaphylococcus AureusNational collection of type cultures (NCTC) UKTait et al. 2014
ProkaryotaEscherichia ColiNational collection of type cultures (NCTC) UKTait et al. 2014
ProkaryotaPseudomonas PutidananaSchöller et al. 1997
ProkaryotaPseudomonas Fluorescensnasoil, water, plantsSchöller et al. 1997
ProkaryotaPseudomonas Aeruginosanasoil, water, skin floraSchöller et al. 1997
ProkaryotaSerratia Liquefaciensnasoil, water, plants; digestive tracts of rodents, insects, fish, humansSchöller et al. 1997
ProkaryotaEnterobacter Cloacaenaubiquitary,intestinalSchöller et al. 1997
ProkaryotaLeuconostoc MesenteroidesnaCantal cheesePogačić et al. 2016
ProkaryotaAlcaligenes FaecalisnanaSu et al. 2016
ProkaryotaBacillus CereusnanaSu et al. 2016
ProkaryotaBrevibacterium EpidermidisnanaSu et al. 2016
ProkaryotaProteus PennerinanaSu et al. 2016
ProkaryotaProteus VulgarisnanaSu et al. 2016
ProkaryotaProvidencia RettgerinanaSu et al. 2016
ProkaryotaPseudochrobactrum AsaccharolyticumnanaSu et al. 2016
EukaryotaTuber Magnatumn/aFortywoodland of the Basilicata regionMauriello et al. 2004
EukaryotaTuber Panniferumn/aFortywoodland of the Basilicata regionMauriello et al. 2004
EukaryotaPenicillium Clavigerumcompost Fischer et al. 1999
ProkaryotaPseudomonas AeruginosaclinicPreti et al. 2009
ProkaryotaCitrobacter FreundiiAmerican Type Culture Collection Robacker and Bartelt 1997
ProkaryotaKlebsiella PneumoniaeAmerican Type Culture Collection Robacker and Bartelt 1997
ProkaryotaStreptomyces Sp.NAJones et al. 2017
ProkaryotaPseudomonas Putidapositive influence of the plant root growth and protection against soil-borne pathogensNASheoran et al. 2015
ProkaryotaPseudomonas Putidanablack pepper rootSheoran et al. 2015
EukaryotaTuber BorchiiNoneT. melanosporum, T. borchii were collected from northern Italy (Piedmont) and T. indicum from Yunnan and Sichuan Provinces (China). Splivallo et al. 2007b
EukaryotaTuber MelanosporumNoneT. melanosporum, T. borchii were collected from northern Italy (Piedmont) and T. indicum from Yunnan and Sichuan Provinces (China). Splivallo et al. 2007b
ProkaryotaPeribacillus Sp.NANAToral et al. 2021
ProkaryotaPseudomonas SegetisNANAToral et al. 2021
ProkaryotaPsychrobacillus VulpisNANAToral et al. 2021
ProkaryotaBacillus SubtilisNANALee et al. 2023
EukaryotaPhytophthora CinnamomiN/APhytophthora cinnamomiQiu R et al. 2014
EukaryotaPhytophthora CactorumN/APhytophthora cactorum Loulier et al. 2020
Lentinula EdodesGeng et al. 2024
MicrobacteriumBallot et al. 2023
Mycobacterium UlceransChudy et al. 2024
Method
KingdomSpeciesGrowth MediumApplied MethodVerification
EukaryotaAspergillus FumigatusBHIGC-MSno
ProkaryotaBurkholderia CepaciaBHISIFT-MSno
ProkaryotaBurkholderia CepaciaNBSIFT-MSno
ProkaryotaBurkholderia CepaciaMHBSIFT-MSno
ProkaryotaEnterococcus FaecalisTYESIFT-MSno
ProkaryotaEscherichia Colihuman bloodSIFT-MSno
ProkaryotaEscherichia ColiBacT/ALERT FASIFT-MSno
ProkaryotaEscherichia ColiTYESIFT-MSno
ProkaryotaNeisseria Meningitidishuman bloodSIFT-MSno
ProkaryotaProteus MirabilisTYESIFT-MSno
ProkaryotaPseudomonas AeruginosaPseudomonas selectiveSIFT-MSno
ProkaryotaPseudomonas AeruginosaBlood agarSIFT-MSno
ProkaryotaPseudomonas Aeruginosahuman bloodSIFT-MSno
ProkaryotaPseudomonas AeruginosaTYESIFT-MSno
ProkaryotaPseudomonas AeruginosaNBSIFT-MSno
ProkaryotaPseudomonas AeruginosaMHBSIFT-MSno
ProkaryotaPseudomonas AeruginosaBHISIFT-MSno
ProkaryotaStaphylococcus Aureushuman bloodSIFT-MSno
ProkaryotaStaphylococcus AureusNBSIFT-MSno
ProkaryotaStaphylococcus AureusMHBSIFT-MSno
ProkaryotaStaphylococcus AureusBHISIFT-MSno
ProkaryotaStenotrophomonas MaltophiliaNBSIFT-MSno
ProkaryotaStenotrophomonas MaltophiliaBHISIFT-MSno
ProkaryotaStenotrophomonas MaltophiliaMHBSIFT-MSno
ProkaryotaStenotrophomonas RhizophilaMHBSIFT-MSno
ProkaryotaStreptococcus Pneumoniaehuman bloodSIFT-MSno
ProkaryotaEscherichia ColiNBTD/GC-MSno
ProkaryotaKlebsiella PneumoniaeNBTD/GC-MSno
ProkaryotaPseudomonas AeruginosaNBTD/GC-MSno
ProkaryotaStaphylococcus AureusNBTD/GC-MSno
ProkaryotaEscherichia ColiLBSPME/GC-MSno
ProkaryotaPseudomonas AeruginosaLB-LennoxSPME/GC-MSno
ProkaryotaPseudomonas AeruginosaLB brothSPME/GCxGC-MSno
ProkaryotaBurkholderia Cepaciatrypticase soy agarTD/GC-MSno
EukaryotaCandida KruseiSDATD/GC-MSno
EukaryotaCandida AlbicansSDATD/GC-MSno
EukaryotaCandida GlabrataSDATD/GC-MSno
EukaryotaCandida TropicalisSDATD/GC-MSno
ProkaryotaEscherichia ColiASMTD/GC-MSno
ProkaryotaEscherichia ColiLBTD/GC-MSno
ProkaryotaHaemophilus InfluenzaeTryptic soya supp. factors X&VTD/GC-MSno
ProkaryotaKlebsiella PneumoniaeTSBTD/GC-MSno
ProkaryotaPseudomonas AeruginosaTSBTD/GC-MSno
ProkaryotaPseudomonas AeruginosaBrain Heart InfusionTD/GC-MSno
ProkaryotaPseudomonas AeruginosaASMTD/GC-MSno
ProkaryotaPseudomonas Aeruginosatrypticase soy agarTD/GC-MSno
ProkaryotaPseudomonas Putidatrypticase soy agarTD/GC-MSno
ProkaryotaPseudomonas Aeruginosatryptic soy brothTD/GC-MSno
ProkaryotaShewanella Putrefacienstrypticase soy agarTD/GC-MSno
ProkaryotaStaphylococcus AureusTSBTD/GC-MSno
ProkaryotaStaphylococcus AureusMueller–HintonTD/GC-MSno
ProkaryotaStaphylococcus AureusASMTD/GC-MSno
ProkaryotaStenotrophomonas Maltophiliatrypticase soy agarTD/GC-MSno
ProkaryotaStreptococcus PneumoniaeTryptic soyaTD/GC-MSno
ProkaryotaEnterobacter CloacaeColumbia sheep bloodTD/GC-MS and MCC-IMSno
ProkaryotaEscherichia ColiColumbia sheep bloodTD/GC-MS and MCC-IMSno
ProkaryotaProteus MirabilisColumbia sheep bloodTD/GC-MS and MCC-IMSno
ProkaryotaPseudomonas AeruginosaColumbia sheep bloodTD/GC-MS and MCC-IMSno
ProkaryotaSerratia MarcescensColumbia sheep bloodTD/GC-MS and MCC-IMSno
ProkaryotaEnterobacter CloacaeLevine EMB agar (LEA) (Fluka Analytical, UK)GC-MSno
ProkaryotaPseudomonas AeruginosaLevine EMB agar (LEA) (Fluka Analytical, UK)GC-MSno
EukaryotaEurotium Amstelodamiingrain (woodchip)SIM/GCMS / Tenaxno
EukaryotaPenicillium Brevicompactumingrain (woodchip)SIM/GCMS / Tenaxno
ProkaryotaBacillus AcidicelerLB agarSPME / GS-MSno
ProkaryotaShigella SonneiSodium chloride brothSPME, GC-MSno
EukaryotaFusarium OxysporumLiquid onion extract medium (LOM)SPME, GC-MSyes
EukaryotaFusarium ProliferatumLiquid onion extract medium (LOM)SPME, GC-MSyes
ProkaryotaBacillus Sp.LB agarSPME-GC-MSno
ProkaryotaIgnatzschineria IndicaNutrient AgarSPME-GC-MSno
ProkaryotaPseudomonas FluorescensNutrient AgarSPME-GC-MSno
ProkaryotaHyphomonas Sp.Luria-Bertani (LB)SPME, GC-MSno
ProkaryotaRhizobium Sp.Luria-Bertani (LB)SPME, GC-MSno
ProkaryotaPseudomonas Protegenstryptic soy broth (TSB)gastight syringe, GC-MSno
ProkaryotaSerratia MarcescensNA mediaGC-MS/MSno
ProkaryotaBacillus MuralisNA mediaSPME/GC-MSyes
ProkaryotaBacillus PumilusNA mediaSPME/GC-MSyes
ProkaryotaNovosphingobium LindaniclasticumNA mediaSPME/GC-MSyes
ProkaryotaBacillus SubtilisNA mediaSPME/GC-MSyes
ProkaryotaBacillus AmyloliquefaciensNA mediaSPME/GC-MSyes
ProkaryotaBacillus MegateriumNA mediaSPME/GC-MSyes
ProkaryotaBacillus SubtilisLB agarGC-MSno
ProkaryotaPseudomonas FluorescensLB agarGC-MSno
ProkaryotaPseudomonas Sp.LB mediaHS-SPME/GC-MSno
ProkaryotaPseudomonas Sp.LB media, DYGS mediaHS-SPME/GC-MSno
ProkaryotaBacillus MycoidesTSB mediaSPME/GC-MSno
ProkaryotaPseudomonas PseudoalcaligenesLB mediaSPME/GC-MSno
EukaryotaCandida AlbicansYGC mediaHS-SPME/GC-GC-ToFMSno
EukaryotaCandida GlabrataYGC mediaHS-SPME/GC-GC-ToFMSno
EukaryotaCandida TropicalisYGC mediaHS-SPME/GC-GC-ToFMSno
ProkaryotaStaphylococcus AureusTSB mediaHS-SPME/GC-MSno
ProkaryotaPseudomonas AeruginosaTSB mediaHS-SPME/GC-MSno
ProkaryotaEscherichia ColiTSB mediaHS-SPME/GC-MSno
ProkaryotaStaphylococcus EpidermidisTSB mediaHS-SPME/GC-MSno
ProkaryotaBacillus Subtilisnutrient agarHS-SPME/GC-MSno
ProkaryotaBacillus Atrophaeusnutrient agarHS-SPME/GC-MSno
ProkaryotaBacillus Amyloliquefaciensnutrient agarHS-SPME/GC-MSno
ProkaryotaBacillus Velezensisnutrient agarHS-SPME/GC-MSno
ProkaryotaBacillus Licheniformisnutrient agarHS-SPME/GC-MSno
ProkaryotaPseudomonas AeruginosaTS agar/blood agarHS-SPME/GC-MSno
ProkaryotaChromobacterium VacciniiKing media B (KMB)SBSE-TD-GC×GC-TOF-MSno
ProkaryotaStaphylococcus EpidermidisBHI media, LB mediaHS-SPME/GC×GC-TOFMSno
ProkaryotaStreptomyces GriseusTSA mediaSPME/GC-MSno
EukaryotaChromera Veliaseawater media L1OSSA/GC-MSno
ProkaryotaBacillus CereusLB agarHS-SPME/GC-MSyes
ProkaryotaBurkholderia PyrrociniaNA mediaSPME/GC-MSyes
ProkaryotaStreptomyces AlboflavusGause's synthetic mediumHeadspace, solid-phase microextractionno
ProkaryotaStreptomyces AlbidoflavusEmmerson's yeast starch agarHeadspace trapping, GC-FID/GC-MSno
ProkaryotaStreptomyces Sp.Emmerson's yeast starch agarHeadspace trapping, GC-FID/GC-MSno
ProkaryotaStreptomyces RishiriensisEmmerson's yeast starch agarHeadspace trapping, GC-FID/GC-MSno
ProkaryotaStreptomyces AlbusEmmerson's yeast starch agarHeadspace trapping, GC-FID/GC-MSno
ProkaryotaStreptomyces AntibioticusEmmerson's yeast starch agarHeadspace trapping, GC-FID/GC-MSno
ProkaryotaStreptomyces AureofaciensEmmerson's yeast starch agarHeadspace trapping, GC-FID/GC-MSno
ProkaryotaStreptomyces CoelicolorEmmerson's yeast starch agarHeadspace trapping, GC-FID/GC-MSno
ProkaryotaStreptomyces DiastatochromogenesEmmerson's yeast starch agarHeadspace trapping, GC-FID/GC-MSno
ProkaryotaStreptomyces GriseusEmmerson's yeast starch agarHeadspace trapping, GC-FID/GC-MSno
ProkaryotaStreptomyces HirsutusEmmerson's yeast starch agarHeadspace trapping, GC-FID/GC-MSno
ProkaryotaStreptomyces HygroscopicusEmmerson's yeast starch agarHeadspace trapping, GC-FID/GC-MSno
ProkaryotaStreptomyces MurinusEmmerson's yeast starch agarHeadspace trapping, GC-FID/GC-MSno
ProkaryotaStreptomyces OlivaceusEmmerson's yeast starch agarHeadspace trapping, GC-FID/GC-MSno
ProkaryotaStreptomyces ThermoviolaceusEmmerson's yeast starch agarHeadspace trapping, GC-FID/GC-MSno
ProkaryotaSerratia ProteamaculansNBIIHeadspace trapping/ GC-MSno
ProkaryotaSerratia PlymuthicaNBIIHeadspace trapping/ GC-MSno
ProkaryotaLactococcus Sp.n/an/ano
ProkaryotaLactobacillus Sp.n/an/ano
ProkaryotaOenococcus Oenin/an/ano
ProkaryotaLactobacillus Brevisn/an/ano
ProkaryotaLactobacillus Hilgardiin/an/ano
ProkaryotaLactobacillus Plantarumn/an/ano
ProkaryotaStreptomyces Sp.n/an/ano
ProkaryotaActinomycetes Sp.n/an/ano
ProkaryotaAlcaligenes Sp.n/an/ano
ProkaryotaBacillus Sp.n/an/ano
ProkaryotaCitrobacter Sp.n/an/ano
ProkaryotaEnterobacter Sp.n/an/ano
ProkaryotaKlebsiella Sp.n/an/ano
ProkaryotaKlebsiella Oxytocan/an/ano
ProkaryotaSerratia Sp.n/an/ano
ProkaryotaAeromonas Veroniin/an/ano
ProkaryotaStenotrophomonas Maltophilian/an/ano
ProkaryotaAlcaligenes Faecalisn/an/ano
ProkaryotaArthrobacter Nitroguajacolicusn/an/ano
ProkaryotaLysobacter Gummosusn/an/ano
ProkaryotaSporosarcina Ginsengisolin/an/ano
ProkaryotaBacillus Simplexn/an/ano
ProkaryotaBacillus Subtilisn/an/ano
ProkaryotaBacillus Weihenstephanensisn/an/ano
ProkaryotaMicrobacterium Oxydansn/an/ano
ProkaryotaStreptomyces Lateritiusn/an/ano
ProkaryotaSerratia Marcescensn/an/ano
ProkaryotaCytophaga-Flavobacterium-Bacteroidesn/an/ano
ProkaryotaCollimonas Fungivoranssand supplemented with artificial root exudatesHeadspace trapping/GC-MSno
EukaryotaTuber Magnatumn/amicroextraction-gas chromatography-mass spectrometry analysis (SPME-GC-MS)no
EukaryotaTuber Melanosporumn/aGas chromatography-olfactometry (GC-O)no
EukaryotaTuber Aestivumn/aGas chromatography-olfactometry (GC-O)no
ProkaryotaBurkholderia AmbifariaLuria-Bertani medium, Malt Extractn/ano
ProkaryotaBurkholderia GlumaeLB Headspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaBurkholderia CaribensisLB and MR-VP Headspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaBurkholderia LataLB Headspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaBurkholderia PhenaziniumMR-VPHeadspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaBurkholderia PhenoliruptrixLB and MR-VPHeadspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaBurkholderia PyrrociniaLB and MR-VPHeadspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaBurkholderia SacchariLB Headspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaBurkholderia TerricolaLB Headspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaBurkholderia XenovoransLB Headspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaChromobacterium ViolaceumLB and MR-VPHeadspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaCupriavidus NecatorMR-VPHeadspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaLimnobacter ThiooxidansAngleHeadspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaPandoraea NorimbergensisLB and MR-VPHeadspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaPseudomonas AeruginosaLB Headspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaPseudomonas FluorescensLB and MR-VPHeadspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaPseudomonas PutidaLB and MR-VPHeadspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaSerratia EntomophilaLB and MR-VPHeadspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaSerratia MarcescensLB Headspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaSerratia PlymuthicaLB Headspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaSerratia ProteamaculansLB and MR-VPHeadspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaBurkholderia TropicaPotato dextrose agarHeadspace trapping/ GC-MSno
ProkaryotaBacillus AmyloliquefaciensTryptic soy agarSPME coupled with GC-MSno
ProkaryotaBacillus SubtilisTryptic soy agarSPME coupled with GC-MSno
ProkaryotaPaenibacillus PolymyxaTryptic soy agarSPME coupled with GC-MSno
ProkaryotaCollimonas Pratensissand supplemented with artificial root exudatesHeadspace trapping/GC-MSno
ProkaryotaStaphylococcus AureusTS brothHS-SPME/GC-MS no
ProkaryotaEscherichia ColiSuper broth made up of tryptone, yeast, NaClHS-SPME/GC-MS no
ProkaryotaBurkholderia Sp.TSBAGC-Q-TOFno
ProkaryotaPaenibacillus Sp.TSBAGC-Q-TOFno
ProkaryotaEscherichia ColiTS brothGC-MS Super Qno
ProkaryotaBacillus CereusTS brothGC-MS SPMEyes
ProkaryotaBacillus PolymyxaTS brothGC-MS SPMEyes
ProkaryotaEnterococcus DuransTS brothGC-MS SPMEyes
ProkaryotaEnterococcus FaeciumTS brothGC-MS SPMEyes
ProkaryotaLactobacillus LactisTS brothGC-MS SPMEyes
ProkaryotaLeuconostoc MesenteroidesTS brothGC-MS SPMEyes
ProkaryotaStreptococcus AgalactiaeTS brothGC-MS SPMEyes
ProkaryotaStreptococcus ThermophilusTS brothGC-MS SPMEyes
EukaryotaFusarium Sp.no
EukaryotaPenicillium Sp.no
ProkaryotaPseudomonas PerolensTrypticase soil agar (BBL)GC/MSno
ProkaryotaPseudomonas TolaasiiKBSPME-GCno
ProkaryotaPseudonocardia ThermophilaNutrient agar CM3GC/MSno
ProkaryotaSaccharomonospora RectivirgulaNutrient agar CM3GC/MSno
ProkaryotaSaccharomonospora ViridisNutrient agar CM3GC/MSno
ProkaryotaThermoactinomyces VulgarisNutrient agar CM3GC/MSno
ProkaryotaThermomonospora FuscaNutrient agar CM3GC/MSno
ProkaryotaStreptomyces GriseusNutrient agar CM3GC/MSno
ProkaryotaStreptomyces Sp.Nutrient agar CM3 + 50mg/l actidioneGC/MSno
ProkaryotaPseudochrobactrum SaccharolyticumLB liquidSPME-GC/MSno
ProkaryotaProteus HauseriLB liquidSPME-GC/MSno
ProkaryotaWautersiella FalseniiLB liquidSPME-GC/MSno
ProkaryotaArthrobacter NicotianaeLB liquidSPME-GC/MSno
ProkaryotaAchromobacter XylosoxidansLB liquidSPME-GC/MSno
ProkaryotaPseudomonas PutidaKing's B AgarSPME-GC/MSno
ProkaryotaPseudomonas VranovensisLB mediumGC/MSyes
ProkaryotaPseudomonas VeroniiLB mediumGC/MSyes
ProkaryotaPseudomonas ChlororaphisLB mediumGC/MSyes
ProkaryotaPseudomonas FluorescensLB mediumGC/MSyes
ProkaryotaPseudomonas FrederiksbergensisLB mediumGC/MSyes
ProkaryotaPseudomonas SyringaeLB mediumGC/MSyes
ProkaryotaPseudomonas JesseniiLB mediumGC/MSyes
ProkaryotaPseudomonas Aeruginosaminimal medium/ Brian mediumSPME-GC/MSno
ProkaryotaPseudomonas ChlororaphisLB mediumSPME-GC/MSno
ProkaryotaSerratia ProteamaculansLB mediumSPME-GC/MSno
ProkaryotaSerratia Plymuthicasand containing artificial root exudatesGC/MSno
ProkaryotaChryseobacterium Sp.Tryptic soy broth agarGC/MS-Q-TOFno
ProkaryotaTsukamurella Sp.Tryptic soy broth agarGC/MS-Q-TOFno
ProkaryotaDyella Sp.Tryptic soy broth agarGC/MS-Q-TOFno
ProkaryotaJanthinobacterium Sp.Tryptic soy broth agarGC/MS-Q-TOFno
ProkaryotaRalstonia SolanacearumCasamino Acid Peptone Glucose agarSPME-GC/MSno
EukaryotaAspergillus VersicolorDG18GC/MSno
EukaryotaPenicillium CommuneMEAGC/MSno
EukaryotaPhialophora FastigiataDG18GC/MSno
ProkaryotaLeuconostoc MesenteroidesMan Rogosa Sharpe broth (MRS)Tenax-trap/GC-MSno
EukaryotaSaccharomyces Cerevisiaen/an/ano
ProkaryotaStaphylococcus AureusTS brothGC-FIDno
ProkaryotaEscherichia Colitryptone, yeast extractGC-MS (SPB-5)no
ProkaryotaPseudomonas PutidaAB medium + 1% citrate or 0,02% citrate or 1% glucose +1% casaminoacid GC-FID,GC/MSno
ProkaryotaPseudomonas FluorescensAB medium + 1% citrateGC-FID,GC/MSno
ProkaryotaPseudomonas AeruginosaAB medium + 1% citrateGC-FID,GC/MSno
ProkaryotaSerratia LiquefaciensAB medium + 1% citrateGC-FID,GC/MSno
ProkaryotaEnterobacter CloacaeAB medium + 1% citrateGC-FID,GC/MSno
ProkaryotaLeuconostoc Mesenteroidescurd-based broth mediumGC/MSyes
ProkaryotaAlcaligenes FaecalisLB mediumSPME-GC/MSno
ProkaryotaBacillus CereusLB mediumSPME-GC/MSno
ProkaryotaBrevibacterium EpidermidisLB mediumSPME-GC/MSno
ProkaryotaProteus PenneriLB mediumSPME-GC/MSno
ProkaryotaProteus VulgarisLB mediumSPME-GC/MSno
ProkaryotaProvidencia RettgeriLB mediumSPME-GC/MSno
ProkaryotaPseudochrobactrum AsaccharolyticumLB mediumSPME-GC/MSno
EukaryotaTuber Panniferumn/amicroextraction-gas chromatography-mass spectrometry analysis (SPME-GC-MS)no
EukaryotaPenicillium Clavigerumyest extract sucroseTenax/GC-MSno
ProkaryotaPseudomonas AeruginosaBlood agar/chocolate blood agaHS-SPME/GC-MS no
ProkaryotaCitrobacter Freundiitryptic soy broth SPME, GC-MSyes
ProkaryotaKlebsiella Pneumoniaetryptic soy broth SPME, GC-MSyes
ProkaryotaStreptomyces Sp.YPD agarGCxGC-TOFMSno
ProkaryotaPseudomonas PutidaTSBPropak Q adsorbent trap/GC-MSno
ProkaryotaPseudomonas PutidaLuria Bertani AgarHeadspace GC/MSno
EukaryotaTuber BorchiiNoneNoneyes
EukaryotaTuber MelanosporumNoneNoneyes
ProkaryotaPeribacillus Sp.Schaeffer’s growth (SG) mediumHS-SPME-GC/MSno
ProkaryotaPeribacillus Sp.tryptic soy agar (TSA, Panreac Applichem) mediumHS-SPME-GC/MSno
ProkaryotaPseudomonas SegetisMOLPHS-SPME-GC/MSno
ProkaryotaPseudomonas SegetisSchaeffer’s growth (SG) mediumHS-SPME-GC/MSno
ProkaryotaPseudomonas Segetistryptic soy agar (TSA, Panreac Applichem) mediumHS-SPME-GC/MSno
ProkaryotaPsychrobacillus VulpisMOLPHS-SPME-GC/MSno
ProkaryotaPsychrobacillus VulpisSchaeffer’s growth (SG) mediumHS-SPME-GC/MSno
ProkaryotaPsychrobacillus Vulpistryptic soy agar (TSA, Panreac Applichem) mediumHS-SPME-GC/MSno
ProkaryotaBacillus SubtilisTryptone soy broth (TSB)HPLCno
EukaryotaPhytophthora CinnamomiPotato Dextrose Agar,V8 juice agarSPME/GC-MS/MSno
EukaryotaPhytophthora CactorumPotato Dextrose AgarSPME/GC-MS/MSno
Lentinula EdodesJiuqu (traditional wheat Qu)GC-IMSno
Microbacteriumtryptone soy (TS medium; Carl Roth, Karlsruhe, Germany)GC-QQQ-MSno
Mycobacterium UlceransNAGCMS–GP2010no


Compound Details

Synonymous names
CARBONYL SULFIDE
Carbon oxysulfide
Carbon oxide sulfide
Carbonyl sulphide
463-58-1
Oxycarbon sulfide
carbonylsulfide
Carbon monoxide monosulfide
oxidosulfidocarbon
C(O)S
O=C=S
Oxo(thioxo)methane
871UI0ET21
COS
Carbon oxide sulfide (COS)
HSDB 6127
EINECS 207-340-0
UN2204
Carbon oxide sulfide(COS)
BRN 1697284
UNII-871UI0ET21
Carbon oxide sulphide
Oxo(thioxo)methane #
InChI=1/COS/c2-1-
4-03-00-00271 (Beilstein Handbook Reference)
CARBONYL SULFIDE [MI]
Carbonyl sulfide, >=97.5%
CARBONYL SULFIDE [HSDB]
DTXSID6023949
CHEBI:16573
UN 2204
Carbonyl sulfide [UN2204] [Poison gas]
NS00080515
C07331
Q412371
Microorganism:

No

IUPAC name
SMILESC(=O)=S
InchiInChI=1S/COS/c2-1-3
FormulaCOS
PubChem ID10039
Molweight60.08
LogP1.5
Atoms3
Bonds0
H-bond Acceptor2
H-bond Donor0
Chemical Classificationsulfides sulfur compounds
CHEBI-ID16573
Supernatural-IDSN0167452

mVOC Specific Details

Boiling Point
DegreeReference
50 °C peer reviewed
Volatilization
The Henry's Law constant for carbonyl sulfide is estimated as 0.61 atm-cu m/mole(SRC) derived from its extrapolated vapor pressure, 9.41X10+3 mm Hg(1), and water solubility, 1.22X10+3 mg/L(2). This Henry's Law constant indicates that carbonyl sulfide is expected to volatilize rapidly from water surfaces(3). Based on this Henry's Law constant, the volatilization half-life from a model river (1 m deep, flowing 1 m/sec, wind velocity of 3 m/sec)(3) is estimated as 2 hours(SRC). The volatilization half-life from a model lake (1 m deep, flowing 0.05 m/sec, wind velocity of 0.5 m/sec)(3) is estimated as 3 days(SRC). Carbonyl sulfide's Henry's Law constant indicates that volatilization from moist soil surfaces may occur(SRC). The potential for volatilization of carbonyl sulfide from dry soil surfaces will exist(SRC) based upon its vapor pressure(1).
Soil Adsorption
Using a structure estimation method based on molecular connectivity indices(1), the Koc of carbonyl sulfide can be estimated to be 1(SRC). According to a classification scheme(2), this estimated Koc value suggests that carbonyl sulfide is expected to have very high mobility in soil(SRC).

Species emitting the compound
KingdomSpeciesBiological FunctionOrigin/HabitatReference
EukaryotaFusarium OxysporumonionWang et al. 2018
EukaryotaFusarium ProliferatumonionWang et al. 2018
Method
KingdomSpeciesGrowth MediumApplied MethodVerification
EukaryotaFusarium OxysporumLiquid onion extract medium (LOM)SPME, GC-MSyes
EukaryotaFusarium ProliferatumLiquid onion extract medium (LOM)SPME, GC-MSyes


3-methylsulfanylprop-1-ene

Mass-Spectra

Compound Details

Synonymous names
Allyl methyl sulfide
10152-76-8
1-Propene, 3-(methylthio)-
3-methylsulfanylprop-1-ene
Allyl methyl sulphide
3-methylthio-1-propene
3-(methylthio)-1-propene
Sulfide, allyl methyl
allyl(methyl)sulfane
Methyl allyl sulfide
3-(methylsulfanyl)prop-1-ene
3-(Methylthio)propene
Methyl 2-propenyl sulfide
CH3SCH2CH=CH2
3-(Methylsulfanyl)-1-propene
V7QI1R316C
MFCD00008657
CCRIS 7066
EINECS 233-422-0
UNII-V7QI1R316C
Methylallyl sulphide
Methyl allyl sulphide
Allyl methyl sulfide, 8CI
Allyl methyl sulfide, 98%
NCIOpen2_003675
DTXSID9064976
CHEBI:89856
s6204
AKOS015852530
MCULE-4452023915
HY-128447
A1117
CS-0099196
NS00021440
D88380
EN300-1721010
A800399
Q-100024
Q2652757
Z1137179168
Microorganism:

No

IUPAC name3-methylsulfanylprop-1-ene
SMILESCSCC=C
InchiInChI=1S/C4H8S/c1-3-4-5-2/h3H,1,4H2,2H3
FormulaC4H8S
PubChem ID66282
Molweight88.17
LogP1.5
Atoms5
Bonds2
H-bond Acceptor1
H-bond Donor0
Chemical Classificationsulfides thioethers sulfur compounds
CHEBI-ID89856
Supernatural-IDSN0256356

Species emitting the compound
KingdomSpeciesBiological FunctionOrigin/HabitatReference
EukaryotaFusarium OxysporumonionWang et al. 2018
EukaryotaFusarium ProliferatumonionWang et al. 2018
EukaryotaTuber Magnatumn/aItalian geographical areas ( Umbria)Gioacchini et al. 2008
EukaryotaTuber Excavatumn/aFortywoodland of the Basilicata regionMauriello et al. 2004
Method
KingdomSpeciesGrowth MediumApplied MethodVerification
EukaryotaFusarium OxysporumLiquid onion extract medium (LOM)SPME, GC-MSno
EukaryotaFusarium ProliferatumLiquid onion extract medium (LOM)SPME, GC-MSno
EukaryotaTuber Magnatumn/amicroextraction-gas chromatography-mass spectrometry analysis (SPME-GC-MS)no
EukaryotaTuber Excavatumn/amicroextraction-gas chromatography-mass spectrometry analysis (SPME-GC-MS)no


Methylsulfanylmethane

Mass-Spectra

Compound Details

Synonymous names
dimethyl sulfide
Methyl sulfide
75-18-3
Methane, thiobis-
dimethyl sulphide
dimethylsulfide
Methyl thioether
Dimethylsulphide
2-Thiapropane
Dimethyl thioether
Methyl sulphide
METHYLSULFANYLMETHANE
Methylthiomethane
Dimethylsulfid
(Methylsulfanyl)methane
Methyl monosulfide
Dimethyl monosulfide
Thiobismethane
2-Thiopropane
Methanethiomethane
Thiobis(methane)
Exact-S
Sulfure de methyle
Dimethyl sulfide (natural)
dimethylsulfane
FEMA No. 2746
Methylthiomethyl radical
MFCD00008562
Methane, 1,1'-thiobis-
[SMe2]
QS3J7O7L3U
CHEBI:17437
(CH3)2S
31533-72-9
methylsulfide
Dimethylsulfid [Czech]
Sulfure de methyle [French]
HSDB 356
EINECS 200-846-2
UN1164
UNII-QS3J7O7L3U
BRN 1696847
Methylsulphide
Thiopropane
Thiobis-methane
di-methylsulfide
AI3-25274
Dimethyl sulfane
Sulfide, methyl-
(methylthio)methane
Me2S
REDUCED-DMSO
SMe2
Dimethyl sulfide, 98%
reduced dimethyl sulfoxide
(Methylsulfanyl)methane #
Dimethyl sulfide [UN1164] [Flammable liquid]
Dimethyl sulfoxide(Reduced)
EC 200-846-2
(Me)2S
Dimethyl sulfide, >=99%
4-01-00-01275 (Beilstein Handbook Reference)
CHEMBL15580
DIMETHYL SULFIDE [MI]
METHYL SULFIDE [FHFI]
DIMETHYL SULFIDE [FCC]
DIMETHYL SULFIDE [HSDB]
DTXSID9026398
S(CH3)2
Dimethyl sulfide, >=99%, FCC
Dimethyl sulfide, analytical standard
STL481894
Dimethyl sulfide, >=95.0% (GC)
AKOS009031411
MCULE-4525381422
UN 1164
Dimethyl sulfide, anhydrous, >=99.0%
InChI=1/C2H6S/c1-3-2/h1-2H
M0431
NS00005000
NS00124710
Dimethyl sulfide, puriss., >=99.0% (GC)
C00580
Dimethyl sulfide, natural, >=99%, FCC, FG
Dimethyl sulfide [UN1164] [Flammable liquid]
A838342
Dimethyl sulfide, redistilled, >=99%, FCC, FG
Q423133
Q-100810
Microorganism:

Yes

IUPAC namemethylsulfanylmethane
SMILESCSC
InchiInChI=1S/C2H6S/c1-3-2/h1-2H3
FormulaC2H6S
PubChem ID1068
Molweight62.14
LogP0.9
Atoms3
Bonds0
H-bond Acceptor1
H-bond Donor0
Chemical Classificationsulfides thioethers sulfur compounds
CHEBI-ID17437
Supernatural-IDSN0309416

mVOC Specific Details

Boiling Point
DegreeReference
37.3 °C peer reviewed
Volatilization
The Henry's Law constant for dimethyl sulfide has been measured as 1.61X10-3 atm-cu m/mole(1). This Henry's Law constant indicates that dimethyl sulfide is expected to volatilize rapidly from water surfaces(2). Based on this Henry's Law constant, the volatilization half-life from a model river (1 m deep, flowing 1 m/sec, wind velocity of 3 m/sec)(2) is estimated as 3 hours(SRC). The volatilization half-life from a model lake (1 m deep, flowing 0.05 m/sec, wind velocity of 0.5 m/sec)(2) is estimated as 3 days(SRC). Dimethyl sulfides's Henry's Law constant indicates that volatilization from moist soil surfaces may occur(SRC). The potential for volatilization of dimethyl sulfide from dry soil surfaces may exist(SRC) based upon a vapor pressure of 502 mm Hg(3).
Literature: (1) Gaffney, JS et al; Env Sci Tech 21: 519-23 (1987) (2) Lyman WJ et al; Handbook of Chemical Property Estimation Methods. Washington, DC: Amer Chem Soc pp. 15-1 to 15-29 (1990) (3) Daubert TE, Danner RP; Physical and Thermodynamic Properties of Pure Chemicals: Data Compilation. Vol 4. Design Inst Phys Prop Data, Amer Inst Chem Eng, NY, NY: Hemisphere Pub Corp (1989)
Soil Adsorption
The Koc of dimethyl sulfide is estimated as 6.3(SRC), using a water solubility of 22,000 mg/L(1) and a regression-derived equation(2). According to a classification scheme(3), this estimated Koc value suggests that dimethyl sulfide is expected to have very high mobility in soil.
Literature: (1) Suzuki T; J Comp-Aided Molec Des 5: 149-66 (1991) (2) US EPA; Estimation Program Interface (EPI) Suite. Ver. 4.0. Jan, 2009. Available from http://www.epa.gov/oppt/exposure/pubs/episuitedl.htm as of Oct 1, 2009. (3) Swann RL et al; Res Rev 85: 17-28 (1983)
Literature: #Air-dried, unsterilized moist, and sterilized moist soils exposed to air initially containing 500 ppm dimethyl sulfide adsorbed an avg of 32, 308, and 10 ug dimethyl sulfide/g soil, respectively, in 15 days(1). Time required for complete sorption of dimethyl sulfide by moist soil from air initially containing 100 ppm dimethyl sulfide: soil 1 (Weller) - 1st exposure 150 min, 2nd exposure 100 min, 3rd exposure 95 min; soil 2 (Harps) - 1st exposure 45 min, 2nd exposure 24 min, 3rd exposure 19 min(1). These data suggest that moist soils have a greater tendency to adsorb dimethyl sulfide than dry soils, and that microbial activity in moist soils may be responsible for greater adsorption(1). When natural gas containing 0.5 pounds of dimethyl sulfide per million cubic feet of gas was passed through a bed of pulverized, dry, montmorillonite clay, dimethyl sulfide exhibited a fast breakthrough (2 hours) and a fast build-up rate in effluent gas (85% of influent concn 4 hours after breakthrough), suggesting that dimethyl sulfide does not adsorb to dry soils(2).
Literature: (1) Bremner JM, Banwart WL; Soil Biol Biochem 8: 79-83 (1976) (2) Williams RP; Oper Sect Proc - Am Gas Assoc pp. T29-T37 (1976)
Vapor Pressure
PressureReference
502 mm Hg at 25 deg CDaubert, T.E., R.P. Danner. Physical and Thermodynamic Properties of Pure Chemicals Data Compilation. Washington, D.C.: Taylor and Francis, 1989.
MS-Links
1D-NMR-Links
Massbank-Links

Species emitting the compound
KingdomSpeciesBiological FunctionOrigin/HabitatReference
EukaryotaAspergillus FumigatusNANAChippendale et al. 2014
ProkaryotaBurkholderia CepaciaNANADryahina et al. 2016
ProkaryotaEscherichia ColiNANAAllardyce et al. 2006
ProkaryotaEscherichia ColiNANAAllardyce et al. 2006
ProkaryotaNeisseria MeningitidisNANAAllardyce et al. 2006
ProkaryotaPseudomonas AeruginosaNANAAllardyce et al. 2006
ProkaryotaPseudomonas AeruginosaNANAAllardyce et al. 2006
ProkaryotaPseudomonas AeruginosaNANADryahina et al. 2016
ProkaryotaStaphylococcus AureusNANAAllardyce et al. 2006
ProkaryotaStaphylococcus AureusNANADryahina et al. 2016
ProkaryotaStenotrophomonas MaltophiliaNANADryahina et al. 2016
ProkaryotaStreptococcus PneumoniaeNANAAllardyce et al. 2006
ProkaryotaStreptococcus PneumoniaeNANAAllardyce et al. 2006
ProkaryotaEscherichia ColiNANAHewett et al. 2020
ProkaryotaPseudomonas AeruginosaNANABean et al. 2016
ProkaryotaKlebsiella PneumoniaeNANARees et al. 2016a
ProkaryotaPseudomonas AeruginosaNANABean et al. 2012
ProkaryotaPseudomonas AeruginosaNANADavis et al. 2020
ProkaryotaEscherichia ColiNANADixon et al. 2022
ProkaryotaHaemophilus InfluenzaeNANAFilipiak et al. 2012
ProkaryotaPseudomonas AeruginosaNANAFilipiak et al. 2012
ProkaryotaPseudomonas AeruginosaNANAAhmed et al. 2023
ProkaryotaStreptococcus PneumoniaeNANAFilipiak et al. 2012
ProkaryotaMycobacterium BovisNANAMcNerney et al. 2012
ProkaryotaEnterobacter CloacaeNALawal et al. 2018
EukaryotaAspergillus Versicolorwild strainsSchleibinger et al. 2005
EukaryotaChaetomium Globosumwild strainsSchleibinger et al. 2005
EukaryotaEurotium Amstelodamiwild strainsSchleibinger et al. 2005
ProkaryotaShigella SonneiChina Center of Industrial Culture collectionWang et al. 2018
ProkaryotaVibrio ParahaemolyticusChina Center of Industrial Culture collectionWang et al. 2018
EukaryotaFusarium OxysporumonionWang et al. 2018
EukaryotaFusarium ProliferatumonionWang et al. 2018
ProkaryotaPseudomonas Fluorescens0Medicago spp. plant rhizospheresHernández-León et al. 2015
ProkaryotaPseudomonas Sp.antifungal activity against Thielaviopsis ethacetica mycelial growthBrazilian Biorenewables National Laboratory – LNBR/CNPEM Microorganism Collection, Campinas, SP; isolatedfrom soil and roots of highly productive sugarcane-producing regions; BrazilFreitas et al. 2022
ProkaryotaPseudomonas AeruginosaNational Collections of Industrial Food and Marine Bacteria, American Type Culture CollectionSlade et al. 2022
EukaryotaTuber Magnatumcollected from natural truffle orchards in Istria (Croatia) during one truffle season (October 2018–January 2019)Niimi et al. 2021
EukaryotaTuber Magnatumcollected from natural truffle orchards in Baranya (Hungary) during one truffle season (October 2018–January 2019)Niimi et al. 2021
EukaryotaTuber Magnatumcollected from natural truffle orchards in Somogy (Hungary) during one truffle season (October 2018–January 2019)Niimi et al. 2021
EukaryotaTuber Magnatumcollected from natural truffle orchards in Abruzzo (Italy) during one truffle season (October 2018–January 2019)Niimi et al. 2021
EukaryotaTuber Magnatumcollected from natural truffle orchards in Kalubara (Serbia) during one truffle season (October 2018–January 2019)Niimi et al. 2021
EukaryotaTuber Magnatumcollected from natural truffle orchards in Srem (Serbia) during one truffle season (October 2018–January 2019)Niimi et al. 2021
EukaryotaSerendipita IndicaInstitute of Phytopathology, Justus-Liebig-Universität, Gießen, Germany; origin: isolates from sudangrass roots growing in soil-based trap systemsVenneman et al. 2020
EukaryotaSerendipita WilliamsiiInstitute of Phytopathology, Justus-Liebig-Universität, Gießen, Germany; origin: isolates from sudangrass roots growing in soil-based trap systemsVenneman et al. 2020
ProkaryotaAlpha Proteobacterian/aNASchulz and Dickschat 2007
ProkaryotaGamma Proteobacterian/aNASchulz and Dickschat 2007
ProkaryotaAlcaligenes Faecalisn/aNASchulz and Dickschat 2007
ProkaryotaDesulfovibrio Acrylicusn/aNASchulz and Dickschat 2007
ProkaryotaParasporobacterium Paucivoransn/aNASchulz and Dickschat 2007
ProkaryotaLactococcus Sp.n/aNASchulz and Dickschat 2007
ProkaryotaLactobacillus Sp.n/aNASchulz and Dickschat 2007
ProkaryotaClostridium Sp.n/aNAStotzky and Schenck 1976
ProkaryotaCollimonas Fungivoransn/aNAGarbeva et al. 2014
EukaryotaTuber Magnatumn/aItalian geographical areas ( Umbria, Piedmont, Marche, Emilia Romagna, Border region area between Emilia Romagna and Marche, Tuscany, Molise)Gioacchini et al. 2008
EukaryotaTuber Simonean/aAyme Truffe of Grignan, 26230 FranceMarch et al. 2006
EukaryotaTuber Rufumn/aAyme Truffe of Grignan, 26230 FranceMarch et al. 2006
EukaryotaTuber Mesentericumn/aAyme Truffe of Grignan, 26230 FranceMarch et al. 2006
EukaryotaTuber Melanosporumn/aAyme Truffe of Grignan, 26230 FranceMarch et al. 2006
EukaryotaTuber Aestivumn/aAyme Truffe of Grignan, 26230 FranceMarch et al. 2006
EukaryotaTuber Uncinatumn/aFrance, Italy, Switzerland, the UK, Austria, Romania, and HungarySplivallo et al. 2012
ProkaryotaCollimonas Pratensisn/aNAGarbeva et al. 2014
ProkaryotaPseudomonas FluorescensNACheng et al. 2016
EukaryotaFusarium Sp.NABrock et al. 2011
EukaryotaPenicillium Sp.NALarsen 1998
ProkaryotaPseudonocardia ThermophilanasoilWilkins 1996
ProkaryotaSaccharomonospora RectivirgulanasoilWilkins 1996
ProkaryotaStreptomyces Sp.nabreathing zone of a waste collection workerWilkins 1996
ProkaryotaPseudomonas Aeruginosastimulates growth of Aspergillus fumigatusnaBriard et al. 2016
ProkaryotaSerratia Plymuthicanamaize rhizosphere, NetherlandsGarbeva et al. 2014
ProkaryotaPaenibacillus Sp.narhizosphere of Marram grass in sandy dune soils, NetherlandsGarbeva et al. 2014
ProkaryotaPedobacter Sp.narhizosphere of Marram grass in sandy dune soils, NetherlandsGarbeva et al. 2014
ProkaryotaRalstonia SolanacearumnanaSpraker et al. 2014
EukaryotaPenicillium Communenain dry-cured meat products, cheeseSunesson et al. 1995
ProkaryotaSerratia Sp.the results led us to propose a possible new direct long-distance mechanism of action for WT antagonistic F. oxysporum that is mediated by vocsNAMinerdi et al. 2009
EukaryotaTuber Aestivumn/aT. melanosporum was from the cultivated truffle zones in the province and T. aestivum from the natural truffle zones in the same regionCullere et al. 2010
EukaryotaTuber Melanosporumn/aT. melanosporum was from the cultivated truffle zones in the province and T. aestivum from the natural truffle zones in the same regionCullere et al. 2010
ProkaryotaPseudomonas PutidananaSchöller et al. 1997
EukaryotaTuber Mesentericumn/aProf. Mattia Bentivenga (Università di Perugia, Perugia, Italy) and in the fortywoodland of the Basilicata regionMauriello et al. 2004
EukaryotaTuber Excavatumn/aProf. Mattia Bentivenga (Università di Perugia, Perugia, Italy) and in the fortywoodland of the Basilicata regionMauriello et al. 2004
EukaryotaTuber Magnatumn/aProf. Mattia Bentivenga (Università di Perugia, Perugia, Italy) and in the fortywoodland of the Basilicata regionMauriello et al. 2004
EukaryotaTuber Aestivumn/aProf. Mattia Bentivenga (Università di Perugia, Perugia, Italy) and in the fortywoodland of the Basilicata regionMauriello et al. 2004
EukaryotaTuber Brumalen/aProf. Mattia Bentivenga (Università di Perugia, Perugia, Italy) and in the fortywoodland of the Basilicata regionMauriello et al. 2004
EukaryotaTuber Melanosporumn/aProf. Mattia Bentivenga (Università di Perugia, Perugia, Italy) and in the fortywoodland of the Basilicata regionMauriello et al. 2004
ProkaryotaPseudomonas AeruginosaclinicPreti et al. 2009
ProkaryotaEnterobacter AgglomeransNARobacker and Lauzon 2002
ProkaryotaClostridium Difficilenastool specimens, from patients infected with clostridium difficileKuppusami et al. 2015
ProkaryotaClostridium DifficilenanaKuppusami et al. 2015
EukaryotaTuber MesentericumNoneNoneMarch et al. 2006
ProkaryotaSerratia Sp.NANAAlmeida et al. 2022
ProkaryotaEnterobacter Sp.NANAAlmeida et al. 2022
ProkaryotaEscherichia ColiNANAAlmeida et al. 2022
ProkaryotaPseudomonas SegetisNANAToral et al. 2021
Method
KingdomSpeciesGrowth MediumApplied MethodVerification
EukaryotaAspergillus FumigatusBHIGC-MSno
ProkaryotaBurkholderia CepaciaMHBSIFT-MSno
ProkaryotaBurkholderia CepaciaNBSIFT-MSno
ProkaryotaBurkholderia CepaciaBHISIFT-MSno
ProkaryotaEscherichia Colihuman bloodSIFT-MSno
ProkaryotaEscherichia ColiBacT/ALERT FASIFT-MSno
ProkaryotaNeisseria Meningitidishuman bloodSIFT-MSno
ProkaryotaPseudomonas Aeruginosahuman bloodSIFT-MSno
ProkaryotaPseudomonas AeruginosaBacT/ALERT FASIFT-MSno
ProkaryotaPseudomonas AeruginosaNBSIFT-MSno
ProkaryotaPseudomonas AeruginosaBHISIFT-MSno
ProkaryotaPseudomonas AeruginosaMHBSIFT-MSno
ProkaryotaStaphylococcus Aureushuman bloodSIFT-MSno
ProkaryotaStaphylococcus AureusMHBSIFT-MSno
ProkaryotaStaphylococcus AureusNBSIFT-MSno
ProkaryotaStaphylococcus AureusBHISIFT-MSno
ProkaryotaStenotrophomonas MaltophiliaNBSIFT-MSno
ProkaryotaStenotrophomonas MaltophiliaMHBSIFT-MSno
ProkaryotaStenotrophomonas MaltophiliaBHISIFT-MSno
ProkaryotaStreptococcus Pneumoniaehuman bloodSIFT-MSno
ProkaryotaStreptococcus PneumoniaeBacT/ALERT FASIFT-MSno
ProkaryotaEscherichia ColiLBSPME/GC-MSno
ProkaryotaPseudomonas AeruginosaLB-LennoxSPME/GC-MSno
ProkaryotaKlebsiella Pneumoniaehuman bloodSPME/GCxGC-MSno
ProkaryotaPseudomonas Aeruginosalysogeny brothSPME/GCxGC-MSno
ProkaryotaPseudomonas AeruginosaLB brothSPME/GCxGC-MSno
ProkaryotaEscherichia ColiLBTD/GC-MSno
ProkaryotaHaemophilus InfluenzaeTryptic soya supp. factors X&VTD/GC-MSno
ProkaryotaPseudomonas Aeruginosatryptic soy brothTD/GC-MSno
ProkaryotaPseudomonas AeruginosaNBTD/GC-MSno
ProkaryotaStreptococcus PneumoniaeTryptic soyaTD/GC-MSno
ProkaryotaMycobacterium BovisLG + glycerolTD/GC-MS and SIFT-MSno
ProkaryotaEnterobacter CloacaeLevine EMB agar (LEA) (Fluka Analytical, UK)GC-MSno
EukaryotaAspergillus Versicoloringrain (woodchip)SIM/GCMS / Tenaxno
EukaryotaChaetomium Globosumingrain (woodchip)SIM/GCMS / Tenaxno
EukaryotaEurotium Amstelodamiingrain (woodchip)SIM/GCMS / Tenaxno
ProkaryotaShigella SonneiSodium chloride brothSPME, GC-MSno
ProkaryotaVibrio ParahaemolyticusSodium chloride brothSPME, GC-MSno
EukaryotaFusarium OxysporumLiquid onion extract medium (LOM)SPME, GC-MSyes
EukaryotaFusarium ProliferatumLiquid onion extract medium (LOM)SPME, GC-MSyes
ProkaryotaPseudomonas FluorescensNutrient AgarSPME-GC-MSno
ProkaryotaPseudomonas Sp.LB media, DYGS media, ANGLE mediaHS-SPME/GC-MSno
ProkaryotaPseudomonas AeruginosaTS agar/blood agarHS-SPME/GC-MSno
EukaryotaTuber MagnatumGC-MS-Ono
EukaryotaSerendipita IndicaPD agarPTR-TOF-MSno
EukaryotaSerendipita WilliamsiiPD agarPTR-TOF-MSno
ProkaryotaAlpha Proteobacterian/an/ano
ProkaryotaGamma Proteobacterian/an/ano
ProkaryotaAlcaligenes Faecalisn/an/ano
ProkaryotaDesulfovibrio Acrylicusn/an/ano
ProkaryotaParasporobacterium Paucivoransn/an/ano
ProkaryotaLactococcus Sp.n/an/ano
ProkaryotaLactobacillus Sp.n/an/ano
ProkaryotaClostridium Sp.n/an/ano
ProkaryotaCollimonas Fungivoranssand supplemented with artificial root exudatesHeadspace trapping/GC-MSno
EukaryotaTuber Magnatumn/amicroextraction-gas chromatography-mass spectrometry analysis (SPME-GC-MS)no
EukaryotaTuber Simonean/aPressure balanced head-space sampling and GC/TOF-MSno
EukaryotaTuber Rufumn/aPressure balanced head-space sampling and GC/TOF-MSno
EukaryotaTuber Mesentericumn/aPressure balanced head-space sampling and GC/TOF-MSno
EukaryotaTuber Melanosporumn/aPressure balanced head-space sampling and GC/TOF-MSno
EukaryotaTuber Aestivumn/aPressure balanced head-space sampling and GC/TOF-MSno
EukaryotaTuber Uncinatumn/aSPME-GC-MSno
ProkaryotaCollimonas Pratensissand supplemented with artificial root exudatesHeadspace trapping/GC-MSno
ProkaryotaPseudomonas FluorescensKings B + rif,+kann; PDA GC-Q-TOF-MSno
EukaryotaFusarium Sp.no
EukaryotaPenicillium Sp.no
ProkaryotaPseudonocardia ThermophilaNutrient agar CM3GC/MSno
ProkaryotaSaccharomonospora RectivirgulaNutrient agar CM3GC/MSno
ProkaryotaStreptomyces Sp.Nutrient agar CM3 + 50mg/l actidioneGC/MSno
ProkaryotaPseudomonas Aeruginosaminimal medium/ Brian mediumSPME-GC/MSno
ProkaryotaSerratia Plymuthicasand containing artificial root exudatesGC/MSno
ProkaryotaPaenibacillus Sp.sand containing artificial root exudatesGC/MSno
ProkaryotaPedobacter Sp.sand containing artificial root exudatesGC/MSno
ProkaryotaRalstonia SolanacearumCasamino Acid Peptone Glucose agarSPME-GC/MSno
EukaryotaPenicillium CommuneMEAGC/MSno
ProkaryotaSerratia Sp.LB mediumSPME/GC-MS no
EukaryotaTuber Aestivumn/aGas chromatography-olfactometry (GC-O)no
EukaryotaTuber Melanosporumn/aGas chromatography-olfactometry (GC-O)no
ProkaryotaPseudomonas PutidaAB medium + 1% citrate or 0,02% citrate or 1% glucose +1% casaminoacid GC-FID,GC/MSno
EukaryotaTuber Mesentericumn/amicroextraction-gas chromatography-mass spectrometry analysis (SPME-GC-MS)no
EukaryotaTuber Excavatumn/amicroextraction-gas chromatography-mass spectrometry analysis (SPME-GC-MS)no
EukaryotaTuber Aestivumn/amicroextraction-gas chromatography-mass spectrometry analysis (SPME-GC-MS)no
EukaryotaTuber Brumalen/amicroextraction-gas chromatography-mass spectrometry analysis (SPME-GC-MS)no
EukaryotaTuber Melanosporumn/amicroextraction-gas chromatography-mass spectrometry analysis (SPME-GC-MS)no
ProkaryotaPseudomonas AeruginosaBlood agar/chocolate blood agaHS-SPME/GC-MS no
ProkaryotaEnterobacter Agglomeransno
ProkaryotaClostridium Difficilebrain heart infusion agar with 7% horse bloodPTR-ToF-MSno
EukaryotaTuber MesentericumNonePressure balanced head-space sampling and GC/TOF-MSno
ProkaryotaSerratia Sp.LB broth supplemented with cryoprotectant solution (25 g L−1 gelatin, 50 g L−1 lactose, 10 g L−1 peptone, and 250 g L−1 glycerol)SPME with gas chromatograph (Agilent 7890A, Agilent Technologies) connected to a mass spectrometer (Pegasus® HT TOFMS, LECO Corporation)no
ProkaryotaEnterobacter Sp.LB broth supplemented with cryoprotectant solution (25 g L−1 gelatin, 50 g L−1 lactose, 10 g L−1 peptone, and 250 g L−1 glycerol)SPME with gas chromatograph (Agilent 7890A, Agilent Technologies) connected to a mass spectrometer (Pegasus® HT TOFMS, LECO Corporation)no
ProkaryotaEscherichia ColiLB broth supplemented with cryoprotectant solution (25 g L−1 gelatin, 50 g L−1 lactose, 10 g L−1 peptone, and 250 g L−1 glycerol)SPME with gas chromatograph (Agilent 7890A, Agilent Technologies) connected to a mass spectrometer (Pegasus® HT TOFMS, LECO Corporation)no
ProkaryotaPseudomonas SegetisMOLPHS-SPME-GC/MSno
ProkaryotaPseudomonas SegetisSchaeffer’s growth (SG) mediumHS-SPME-GC/MSno
ProkaryotaPseudomonas Segetistryptic soy agar (TSA, Panreac Applichem) mediumHS-SPME-GC/MSno


(Z)-1-methylsulfanylprop-1-ene

Compound Details

Synonymous names
1-Propene, 1-(methylthio)-, (Z)-
52195-40-1
Z-1-Methylthio-1-propene
(Z)-Methyl 1-propenyl sulfide
(Z)-1-methylsulfanylprop-1-ene
(Z)-2-Thia-3-pentene
Methyl 1-propenyl sulfide, (1Z)-
Methyl 1-propenyl sulfide, (2Z)-
UNII-JL63YZ7G96
FEMA No. 4574, (1Z)-
JL63YZ7G96
1-Propene, 1-(methylthio)-, (1Z)-
(Z)-1-(Methylthio)-1-propene
(1Z)-1-(Methylsulfanyl)-1-propene
cis-Methyl propenyl sulfide
(1Z)-methyl 1-propenyl sulfide
CHEBI:88380
YJOGCMRDEUBRJD-ARJAWSKDSA-N
DTXSID501015958
DB-290327
Q27160225
Microorganism:

No

IUPAC name(Z)-1-methylsulfanylprop-1-ene
SMILESCC=CSC
InchiInChI=1S/C4H8S/c1-3-4-5-2/h3-4H,1-2H3/b4-3-
FormulaC4H8S
PubChem ID5364225
Molweight88.17
LogP1.6
Atoms5
Bonds1
H-bond Acceptor1
H-bond Donor0
Chemical Classificationsulfur compounds thioethers sulfides
CHEBI-ID88380

mVOC Specific Details


Species emitting the compound
KingdomSpeciesBiological FunctionOrigin/HabitatReference
EukaryotaFusarium OxysporumonionWang et al. 2018
EukaryotaFusarium ProliferatumonionWang et al. 2018
Method
KingdomSpeciesGrowth MediumApplied MethodVerification
EukaryotaFusarium OxysporumLiquid onion extract medium (LOM)SPME, GC-MSno
EukaryotaFusarium ProliferatumLiquid onion extract medium (LOM)SPME, GC-MSno


2-methylpentane

Mass-Spectra

Compound Details

Synonymous names
2-METHYLPENTANE
Isohexane
107-83-5
Pentane, 2-methyl-
73513-42-5
Hexanes
2-Methyl pentane
1,1-Dimethylbutane
2-Methyl-pentane
64742-49-0
Methyl pentane
SOLVENT DEGREASER
49IB0U6MLD
43133-95-5
DTXSID4029143
CHEBI:88374
NSC-66496
Dimethylpropylmethane
iso-hexane
2-Methylpentane, analytical standard
MFCD02179311
Pentane, methyl-
HSDB 1125
EINECS 203-523-4
NSC 66496
UNII-49IB0U6MLD
i-hexane
AI3-28851
MFCD00009406
2-Methylpentane, 5.0%
KYOWASOL C 600M
KYOWAZOL C 600
2-Methylpentane, >=99%
Hexanes, Environmental Grade
Hexanes, (60% n-hexane)
CHEMBL30909
DTXCID509143
2-METHYLPENTANE [HSDB]
DTXSID20175284
(CH3)2CH(CH2)2CH3
NSC66496
Tox21_200470
WLN: 3Y1 & 1
2-Methylpentane, >=95.0% (GC)
AKOS015907782
MCULE-9604552974
NCGC00248641-01
NCGC00258024-01
CAS-107-83-5
M0382
NS00005206
A801767
Q209445
Isohexane (mixture of isomeric branched chain Hexanes)
ASTM Method D5191 Vapor Pressure - 46.7 kPa (6.77 psi)
InChI=1/C6H14/c1-4-5-6(2)3/h6H,4-5H2,1-3H
Isohexane, mixture of isomeric branched chain hexanes, < 5% n-hexane
Microorganism:

No

IUPAC name2-methylpentane
SMILESCCCC(C)C
InchiInChI=1S/C6H14/c1-4-5-6(2)3/h6H,4-5H2,1-3H3
FormulaC6H14
PubChem ID7892
Molweight86.18
LogP3.2
Atoms6
Bonds2
H-bond Acceptor0
H-bond Donor0
Chemical Classificationalkanes saturated hydrocarbons
CHEBI-ID88374
Supernatural-IDSN0003875

mVOC Specific Details

Boiling Point
DegreeReference
60.21 °C peer reviewed
Volatilization
The Henry's Law constant for 2-methylpentane is estimated as 1.7 atm-cu m/mole(SRC) derived from its vapor pressure, 211 mm Hg(1), and water solubility, 14.2 mg/L(2). This Henry's Law constant indicates that 2-methylpentane is expected to volatilize rapidly from water surfaces(3). Based on this Henry's Law constant, the volatilization half-life from a model river (1 m deep, flowing 1 m/sec, wind velocity of 3 m/sec)(3) is estimated as 3 hours(SRC). The volatilization half-life from a model lake (1 m deep, flowing 0.05 m/sec, wind velocity of 0.5 m/sec)(3) is estimated as 4 days(SRC). 2-Methylpentane's estimated Henry's Law constant indicates that volatilization from moist soil surfaces may occur(SRC). The potential for volatilization of 2-methylpentane from dry soil surfaces may exist (SRC) based upon a vapor pressure of 211 mm Hg(1).
Literature: (1) Daubert TE, Danner RP; Physical and Thermodynamic Properties of Pure Chemicals: Data Compilation. Design Institute for Physical Property Data, American Institute of Chemical Engineers. New York, NY: Hemisphere Pub. Corp., 4 Vol. (1989) (2) Yalkowsky SH et al; Handbook of Aqueous Solubility Data. 2nd ed. Boca Raton, FL: CRC Press p. 320 (2010) (3) Lyman WJ et al; Handbook of Chemical Property Estimation Methods. Washington, DC: Amer Chem Soc pp. 15-1 to 15-29 (1990)
Soil Adsorption
Using a structure estimation method based on molecular connectivity indices(1), the Koc of 2-methylpentane can be estimated to be 610(SRC). According to a classification scheme(2), this estimated Koc value suggests that 2-methylpentane is expected to have low mobility in soil. A sorption experiment using lignite samples resulted in a log Kd of 2.92 for 2-methylpentane(3).
Literature: (1) US EPA; Estimation Program Interface (EPI) Suite. Ver. 4.1. Nov, 2012. Available from, as of Nov 20, 2013: http://www.epa.gov/oppt/exposure/pubs/episuitedl.htm (2) Swann RL et al; Res Rev 85: 17-28 (1983) (3) Endo S et al; Environ Sci Technol 42: 5897-5903 (2008)
Vapor Pressure
PressureReference
211 mm Hg at 25 deg CDaubert, T.E., R.P. Danner. Physical and Thermodynamic Properties of Pure Chemicals Data Compilation. Washington, D.C.: Taylor and Francis, 1989.
MS-Links
1D-NMR-Links
Massbank-Links

Species emitting the compound
KingdomSpeciesBiological FunctionOrigin/HabitatReference
EukaryotaFusarium OxysporumonionWang et al. 2018
EukaryotaFusarium ProliferatumonionWang et al. 2018
EukaryotaTrichoderma Pseudokoningiin/aNAWheatley et al. 1997
Method
KingdomSpeciesGrowth MediumApplied MethodVerification
EukaryotaFusarium OxysporumLiquid onion extract medium (LOM)SPME, GC-MSyes
EukaryotaFusarium ProliferatumLiquid onion extract medium (LOM)SPME, GC-MSyes
EukaryotaTrichoderma PseudokoningiiMalt extractGC/MSno


Butane-2,3-dione

Mass-Spectra

Compound Details

Synonymous names
2,3-butanedione
diacetyl
biacetyl
Butane-2,3-dione
431-03-8
dimethylglyoxal
Butanedione
dimethyl diketone
2,3-diketobutane
Dimethyl glyoxal
2,3-Butadione
2,3-dioxobutane
butadione
Glyoxal, dimethyl-
2,3-butandione
Diacetyl (natural)
FEMA No. 2370
Butan-2,3-dione
CCRIS 827
HSDB 297
NSC 8750
MFCD00008756
UN2346
2,3-Butanedione-13C2
AI3-03313
K324J5K4HM
DTXSID6021583
CHEBI:16583
NSC-8750
2.3-butanedione
EINECS 207-069-8
BRN 0605398
UNII-K324J5K4HM
butane 2
butane-2
Biacetyl; BDM
2,3 butandione
Buta-2,3-dione
DIACETYL [FHFI]
DIACETYL [HSDB]
DIACETYL [FCC]
Butanedione [UN2346] [Flammable liquid]
DIACETYL [MI]
Lopac-D-3634
Butanedione [UN2346]
2,3-Butanedione, 97%
Lopac0_000387
4-01-00-03644 (Beilstein Handbook Reference)
Diacetyl, natural, >=95%
WLN: 1VV1
(CH3CO)2
CHEMBL365809
DTXCID701583
SGCUT00113
2,3-Butanedione (8CI,9CI)
BDBM22725
NSC8750
HMS3261M15
to_000005
Tox21_201218
Tox21_500387
LMFA12000012
2,3-Butanedione, analytical standard
AKOS000118816
Diacetyl 1000 microg/mL in Methanol
CCG-204481
LP00387
MCULE-5742661187
SDCCGSBI-0050374.P002
NCGC00015336-01
NCGC00015336-02
NCGC00015336-03
NCGC00015336-04
NCGC00015336-05
NCGC00015336-06
NCGC00015336-07
NCGC00090746-01
NCGC00090746-02
NCGC00090746-03
NCGC00258770-01
NCGC00261072-01
CAS-431-03-8
DB-003226
B0682
Butanedione [UN2346] [Flammable liquid]
EU-0100387
NS00003558
EN300-19494
C00741
D 3634
W18292
A826155
Q408916
SR-01000075811
InChI=1/C4H6O2/c1-3(5)4(2)6/h1-2H
SR-01000075811-1
DEE64962-0BD5-454C-8BDA-FDBD33C47181
F0001-1188
BUO
Microorganism:

Yes

IUPAC namebutane-2,3-dione
SMILESCC(=O)C(=O)C
InchiInChI=1S/C4H6O2/c1-3(5)4(2)6/h1-2H3
FormulaC4H6O2
PubChem ID650
Molweight86.09
LogP-1.3
Atoms6
Bonds1
H-bond Acceptor2
H-bond Donor0
Chemical Classificationalcohols ketones
CHEBI-ID16583
Supernatural-IDSN0313939

mVOC Specific Details

Boiling Point
DegreeReference
87.5 °C peer reviewed
Volatilization
The Henry's Law constant for diacetyl is 1.33X10-5 atm-cu m/mole(1). This Henry's Law constant indicates that diacetyl is expected to volatilize from water surfaces(2). Based on this Henry's Law constant, the volatilization half-life from a model river (1 m deep, flowing 1 m/sec, wind velocity of 3 m/sec)(2) is estimated as 2.7 days(SRC). The volatilization half-life from a model lake (1 m deep, flowing 0.05 m/sec, wind velocity of 0.5 m/sec)(2) is estimated as 22 days(SRC). Diacetyl's Henry's Law constant indicates that volatilization from moist soil surfaces may occur(SRC). Diacetyl is expected to volatilize from dry soil surfaces(SRC) based upon a vapor pressure of 56.8 mm Hg(3).
Literature: (1) Betterton EA; Atmos Environ 25A:1473-7 (1991) (2) Lyman WJ et al; Handbook of Chemical Property Estimation Methods. Washington, DC: Amer Chem Soc pp. 15-1 to 15-29 (1990) (3) Boublik T et al; The vapor pressures of pure substances. Vol. 17. Amsterdam, Netherlands: Elsevier Sci. Publ (1984)
Soil Adsorption
The Koc of diacetyl is estimated as 1(SRC), using a log Kow of -1.34(1) and a regression-derived equation(2). According to a classification scheme(3), this estimated Koc value suggests that diacetyl is expected to have very mobility in soil.
Literature: (1) Hansch C et al; Exploring QSAR. Hydrophobic, Electronic, and Steric Constants. ACS Prof Ref Book. Heller SR, consult. ed., Washington, DC: Amer Chem Soc p. 9 (1995) (2) US EPA; Estimation Program Interface (EPI) Suite. Ver. 4.1. Nov, 2012. Available from, as of May 31, 2016: http://www2.epa.gov/tsca-screening-tools (3) Swann RL et al; Res Rev 85: 17-28 (1983)
Vapor Pressure
PressureReference
56.8 mm Hg at 25 deg CBoublik, T., Fried, V., and Hala, E., The Vapour Pressures of Pure Substances. Second Revised Edition. Amsterdam: Elsevier, 1984.
MS-Links
1D-NMR-Links
Massbank-Links

Species emitting the compound
KingdomSpeciesBiological FunctionOrigin/HabitatReference
ProkaryotaKlebsiella PneumoniaeNANARees et al. 2016a
ProkaryotaPseudomonas AeruginosaNANABean et al. 2012
ProkaryotaStreptococcus PneumoniaeNANAMellors et al. 2018
ProkaryotaHaemophilus InfluenzaeNANAFilipiak et al. 2012
ProkaryotaStaphylococcus AureusNANAFilipiak et al. 2012
ProkaryotaStreptococcus PneumoniaeNANAFilipiak et al. 2012
ProkaryotaErwinia AmylovoraNACellini et al. 2018
ProkaryotaKlebsiella PneumoniaeNARees et al. 2017
EukaryotaFusarium OxysporumonionWang et al. 2018
EukaryotaFusarium ProliferatumonionWang et al. 2018
ProkaryotaBacillus AmyloliquefaciensLeibnitz Institute DSMZ-German Collection of Microorganisms and Cell Cultures GmbHMülner et al. 2020
ProkaryotaBacillus VelezensisNAMülner et al. 2020
ProkaryotaBacillus LicheniformisLeibnitz Institute DSMZ-German Collection of Microorganisms and Cell Cultures GmbHMülner et al. 2020
EukaryotaFusarium OxysporumNAMoisan et al. 2021
ProkaryotaBacillus Velezensisinhibite the growth of Botrytis cinerea VG1, Monilinia fructicola VG 104, Monilinia laxa VG 105, Penicillium digitatum VG 20, Penicillium expansum CECT 20140, Penicillium italicum VG 102NACalvo et al. 2020
ProkaryotaBacillus Velezensisinhibite the growth of Botrytis cinerea VG1, Monilinia fructicola VG 104, Monilinia laxa VG 105, Penicillium digitatum VG 20, Penicillium expansum CECT 20140, Penicillium italicum VG 111NACalvo et al. 2020
ProkaryotaStreptococcus PyogenesNational Collection of Type CulturesSlade et al. 2022
ProkaryotaStaphylococcus AureusNational Collections of Industrial Food and Marine Bacteria, American Type Culture Collection, Southmead HospitalSlade et al. 2022
EukaryotaTuber Magnatumcollected from natural truffle orchards in Istria (Croatia) during one truffle season (October 2018–January 2019)Niimi et al. 2021
EukaryotaTuber Magnatumcollected from natural truffle orchards in Baranya (Hungary) during one truffle season (October 2018–January 2019)Niimi et al. 2021
EukaryotaTuber Magnatumcollected from natural truffle orchards in Somogy (Hungary) during one truffle season (October 2018–January 2019)Niimi et al. 2021
EukaryotaTuber Magnatumcollected from natural truffle orchards in Abruzzo (Italy) during one truffle season (October 2018–January 2019)Niimi et al. 2021
EukaryotaTuber Magnatumcollected from natural truffle orchards in Kalubara (Serbia) during one truffle season (October 2018–January 2019)Niimi et al. 2021
EukaryotaTuber Magnatumcollected from natural truffle orchards in Srem (Serbia) during one truffle season (October 2018–January 2019)Niimi et al. 2021
ProkaryotaStaphylococcus AureusAmerican Type Culture CollectionJenkins and Bean 2020
ProkaryotaStaphylococcus EpidermidisAmerican Type Culture CollectionJenkins and Bean 2020
EukaryotaMalassezia RestrictaFungal Biodiversity Center (WesterdijkInstitute, Utrecht, The Netherlands)Rios-Navarro et al. 2023
EukaryotaMalassezia SympodialisFungal Biodiversity Center (WesterdijkInstitute, Utrecht, The Netherlands)Rios-Navarro et al. 2023
ProkaryotaStaphylococcus EpidermidisDSMZVerhulst et al. 2010
ProkaryotaStreptococcus Uberisn/aNAHettinga et al. 2008
ProkaryotaStreptococcus Dysgalactiaen/aNAHettinga et al. 2008
ProkaryotaCoagulase-negative Staphylococcin/aNAHettinga et al. 2008
ProkaryotaEscherichia ColiNational collection of type cultures (NCTC) UKTait et al. 2014
ProkaryotaStaphylococcus AureusNational collection of type cultures (NCTC) UKTait et al. 2014
EukaryotaTuber Aestivumn/aT. melanosporum was from the cultivated truffle zones in the province and T. aestivum from the natural truffle zones in the same regionCullere et al. 2010
EukaryotaTuber Melanosporumn/aT. melanosporum was from the cultivated truffle zones in the province and T. aestivum from the natural truffle zones in the same regionCullere et al. 2010
ProkaryotaBacillus Amyloliquefaciensn/aNALee et al. 2012
ProkaryotaBacillus Subtilisn/aNALee et al. 2012
ProkaryotaPaenibacillus Polymyxan/aNALee et al. 2012
ProkaryotaStaphylococcus Aureusn/aNAHettinga et al. 2008
ProkaryotaEscherichia Colin/aNAHettinga et al. 2008
ProkaryotaStaphylococcus Sciurinafrom the gut flora of pea aphid Acyrthosiphon pisum honeydewLeroy et al. 2011
ProkaryotaBacillus AmyloliquefaciensnanaAsari et al. 2016
ProkaryotaLactobacillus Rhamnosuscan be used to modify or intensify the flavour of industrial cheeses or fermented milks or to preserve the peculiar flavour of traditional dairy productsNAPogačić et al. 2016
ProkaryotaLactobacillus RhamnosusnanaPogačić et al. 2016
EukaryotaTuber BorchiiAroma active compound in Tuber melanosporum and Tuber aestivum syn Tuber uncinatumnaSplivallo and Ebeler 2015
ProkaryotaStaphylococcus Sp.n/aNASchulz and Dickschat 2007
ProkaryotaPaenibacillus Polymyxacollection TU GrazRybakova et al. 2017
ProkaryotaLentilactobacillus BuchneriNANASquara et al. 2022
ProkaryotaBacillus AtrophaeusNANAToral et al. 2021
ProkaryotaPeribacillus Sp.NANAToral et al. 2021
ProkaryotaBacillus VelezensisNANAToral et al. 2021
Bacillus ThuringiensisKoilybayeva et al. 2023
Bacillus ToyonensisKoilybayeva et al. 2023
Bacillus SafensisKoilybayeva et al. 2023
Saccharomyces CerevisiaePeng et al. 2023
Staphylococcus AureusWang et al. 2023
Method
KingdomSpeciesGrowth MediumApplied MethodVerification
ProkaryotaKlebsiella Pneumoniaehuman bloodSPME/GCxGC-MSno
ProkaryotaPseudomonas Aeruginosalysogeny brothSPME/GCxGC-MSno
ProkaryotaStreptococcus PneumoniaeModified Lacks MediaSPME/GCxGC-MSno
ProkaryotaHaemophilus InfluenzaeTryptic soya supp. factors X&VTD/GC-MSno
ProkaryotaStaphylococcus Aureustryptic soy brothTD/GC-MSno
ProkaryotaStreptococcus PneumoniaeTryptic soyaTD/GC-MSno
ProkaryotaErwinia AmylovoraLuria-Bertani (LB)PTR-MS / SPME / GC-MSno
ProkaryotaKlebsiella PneumoniaeLBSPME / GCxGC-TOFMSno
EukaryotaFusarium OxysporumLiquid onion extract medium (LOM)SPME, GC-MSyes
EukaryotaFusarium ProliferatumLiquid onion extract medium (LOM)SPME, GC-MSyes
ProkaryotaBacillus Amyloliquefaciensnutrient agarHS-SPME/GC-MSno
ProkaryotaBacillus Velezensisnutrient agarHS-SPME/GC-MSno
ProkaryotaBacillus Licheniformisnutrient agarHS-SPME/GC-MSno
EukaryotaFusarium Oxysporum1/5th PDA mediumGC-MSno
ProkaryotaBacillus VelezensisMOLP mediaSPME/GC-MSyes
ProkaryotaStreptococcus PyogenesTS agar/blood agarHS-SPME/GC-MSno
ProkaryotaStaphylococcus AureusTS agar/blood agarHS-SPME/GC-MSno
EukaryotaTuber MagnatumGC-MS-Ono
ProkaryotaStaphylococcus AureusBHI media, TSB mediaHS-SPME/GC×GC-TOFMSno
ProkaryotaStaphylococcus EpidermidisLB mediaHS-SPME/GC×GC-TOFMSno
EukaryotaMalassezia Restrictamodified Dixon agarHS-SPME/GC-MSno
EukaryotaMalassezia Sympodialismodified Dixon agarHS-SPME/GC-MSno
ProkaryotaStaphylococcus EpidermidisCLSA, charcoal, GC-MSno
ProkaryotaStreptococcus UberisMilkHS-SPME/GC-MS no
ProkaryotaStreptococcus DysgalactiaeMilkHS-SPME/GC-MS no
ProkaryotaCoagulase-negative StaphylococciMilkHS-SPME/GC-MS no
ProkaryotaEscherichia Colimilk samplesGC-MS(BPX-5)no
ProkaryotaStaphylococcus Aureusmilk samplesGC-MS(BPX-5)no
EukaryotaTuber Aestivumn/aGas chromatography-olfactometry (GC-O)no
EukaryotaTuber Melanosporumn/aGas chromatography-olfactometry (GC-O)no
ProkaryotaBacillus AmyloliquefaciensTryptic soy agarSPME coupled with GC-MSno
ProkaryotaBacillus SubtilisTryptic soy agarSPME coupled with GC-MSno
ProkaryotaPaenibacillus PolymyxaTryptic soy agarSPME coupled with GC-MSno
ProkaryotaStaphylococcus AureusMilkHS-SPME/GC-MS no
ProkaryotaEscherichia ColiMilkHS-SPME/GC-MS no
ProkaryotaStaphylococcus Sciuri864 liquid mediumSPME-GC/MSno
ProkaryotaBacillus AmyloliquefaciensM9AGC/MSno
ProkaryotaLactobacillus RhamnosusMan Rogosa Sharpe broth (MRS)Tenax-trap/GC-MSno
ProkaryotaLactobacillus Rhamnosuscurd-based broth mediumGC/MSyes
EukaryotaTuber BorchiinaSPME-GC/MS/O); GC-Ryes
ProkaryotaStaphylococcus Sp.n/an/ano
ProkaryotaPaenibacillus PolymyxaGC-MS / SPMEno
ProkaryotaLentilactobacillus Buchnerimaize silageHS-SPME coupled with GC-TOF MSno
ProkaryotaBacillus AtrophaeusMOLPHS-SPME-GC/MSno
ProkaryotaBacillus AtrophaeusSchaeffer’s growth (SG) mediumHS-SPME-GC/MSno
ProkaryotaBacillus Atrophaeustryptic soy agar (TSA, Panreac Applichem) mediumHS-SPME-GC/MSno
ProkaryotaPeribacillus Sp.MOLPHS-SPME-GC/MSno
ProkaryotaPeribacillus Sp.Schaeffer’s growth (SG) mediumHS-SPME-GC/MSno
ProkaryotaBacillus VelezensisMOLPHS-SPME-GC/MSno
ProkaryotaBacillus VelezensisSchaeffer’s growth (SG) mediumHS-SPME-GC/MSno
ProkaryotaBacillus Velezensistryptic soy agar (TSA, Panreac Applichem) mediumHS-SPME-GC/MSno
Bacillus Thuringiensisbacteriological agar (BA, 15 g/L), gelatin peptone (GP, 5 g/L), and meat extract (ME, 3 g/L)GC–MSno
Bacillus Toyonensisbacteriological agar (BA, 15 g/L), gelatin peptone (GP, 5 g/L), and meat extract (ME, 3 g/L)GC–MSno
Bacillus Safensisbacteriological agar (BA, 15 g/L), gelatin peptone (GP, 5 g/L), and meat extract (ME, 3 g/L)GC–MSno
Saccharomyces Cerevisiaesea buckthorn juiceHS-SPME-GC–MS/UHPLC–MSno
Staphylococcus Aureusraw Shiyang chickenHS-GC-IMS/HS-SPME-GC-MSno


3,4-dimethylthiophene

Compound Details

Synonymous names
3,4-Dimethylthiophene
632-15-5
Thiophene, 3,4-dimethyl-
3,4-dimethyl-thiophene
MFCD01764731
96Q084Q43E
UNII-96Q084Q43E
SCHEMBL129408
3 pound not4-Dimethylthiophene
FEMA NO. 4645
CHEBI:89511
DTXSID40212549
AMY10944
GEO-01227
AKOS006229686
CS-W005271
AS-47616
SY100626
DB-024759
DB-193555
A8719
NS00121690
EN300-86409
F14672
Q27161705
Methyl-5-deoxy-2,3-O Cisopropylidene-|A-D-ribofuranoside
Microorganism:

No

IUPAC name3,4-dimethylthiophene
SMILESCC1=CSC=C1C
InchiInChI=1S/C6H8S/c1-5-3-7-4-6(5)2/h3-4H,1-2H3
FormulaC6H8S
PubChem ID79089
Molweight112.19
LogP2.3
Atoms7
Bonds0
H-bond Acceptor1
H-bond Donor0
Chemical Classificationsulfur compounds heterocyclic compounds thioethers aromatic compounds
CHEBI-ID89511
Supernatural-IDSN0112081

mVOC Specific Details

Boiling Point
DegreeReference
144 median

Species emitting the compound
KingdomSpeciesBiological FunctionOrigin/HabitatReference
EukaryotaFusarium OxysporumonionWang et al. 2018
EukaryotaFusarium ProliferatumonionWang et al. 2018
Method
KingdomSpeciesGrowth MediumApplied MethodVerification
EukaryotaFusarium OxysporumLiquid onion extract medium (LOM)SPME, GC-MSyes
EukaryotaFusarium ProliferatumLiquid onion extract medium (LOM)SPME, GC-MSyes


(E)-but-2-ene

Compound Details

Synonymous names
trans-2-Butene
2-BUTENE
624-64-6
(E)-But-2-ene
Pseudobutylene
Butene-2
but-2-ene
beta-Butylene
trans-Butene
(E)-2-Butene
Butylene-2
2-BUTENE, (E)-
2-trans-Butene
trans-but-2-ene
beta-trans-Butylene
107-01-7
Low-boiling butene-2
2-Butene, (2E)-
trans-1,2-Dimethylethylene
(2E)-2-Butene
(2E)-but-2-ene
CH3CH=CHCH3
017NGL487F
68956-54-7
Dimethylethylene
beta-Butene
.beta.-Butylene
Butene, 2-
2-Butene-trans
CCRIS 8971
HSDB 180
EINECS 203-452-9
BRN 1718755
UNII-017NGL487F
UNII-S1SK37516R
MFCD00064458
HSDB 5723
trans-But-2-en
2-Buten
e-but-2-ene
EINECS 210-855-3
EINECS 273-307-2
2-Butene, trans-
2-Butene,(2E)-
2-Butenes, cis & trans
E-2-BUTENE
E-.BETA.-BUTYLENE
EC 203-452-9
2-BUTENE (E)-FORM
trans-2-Butene, >=99%
3-01-00-00732 (Beilstein Handbook Reference)
.BETA.-BUTYLENE, E-
TRANS-2-BUTENE [HSDB]
DTXSID7027255
CHEBI:48363
CHEBI:48365
S1SK37516R
2-BUTENE (E)-FORM [MI]
AKOS025295555
(E)-2-C4H8
B0691
NS00007689
Q27121170
Microorganism:

Yes

IUPAC name(E)-but-2-ene
SMILESCC=CC
InchiInChI=1S/C4H8/c1-3-4-2/h3-4H,1-2H3/b4-3+
FormulaC4H8
PubChem ID62695
Molweight56.11
LogP2.3
Atoms4
Bonds0
H-bond Acceptor0
H-bond Donor0
Chemical Classificationunsaturated hydrocarbons alkenes
CHEBI-ID48363

mVOC Specific Details

Boiling Point
DegreeReference
3.73 °C peer reviewed
Volatilization
The Henry's Law constant for 2-butene is estimated as 1.54X10-1 atm-cu m/mole(SRC) using a fragment constant estimation method(1). This Henry's Law constant indicates that 2-butene is expected to volatilize rapidly from water surfaces(2). Based on this Henry's Law constant, the volatilization half-life from a model river (1 m deep, flowing 1 m/sec, wind velocity of 3 m/sec)(2) is estimated as 2 hours(SRC). The volatilization half-life from a model lake (1 m deep, flowing 0.05 m/sec, wind velocity of 0.5 m/sec)(2) is estimated as 3 days(SRC). 2-Butene's Henry's Law constant indicates that volatilization from moist soil surfaces may occur(SRC). 2-Butene is expected to volatilize from dry soil surfaces(SRC) based upon a vapor pressure of 1600 mm Hg at 25 °C(3).
Soil Adsorption
The Koc of 2-butene is estimated as 40(SRC), using a log Kow of 1.85(1) and a regression-derived equation(2). According to a classification scheme(3), this estimated Koc value suggests that 2-butene is expected to have very high mobility in soil.

Species emitting the compound
KingdomSpeciesBiological FunctionOrigin/HabitatReference
ProkaryotaStreptococcus PneumoniaeNANAFilipiak et al. 2012
EukaryotaFusarium OxysporumonionWang et al. 2018
EukaryotaFusarium ProliferatumonionWang et al. 2018
Method
KingdomSpeciesGrowth MediumApplied MethodVerification
ProkaryotaStreptococcus PneumoniaeTryptic soyaTD/GC-MSno
EukaryotaFusarium OxysporumLiquid onion extract medium (LOM)SPME, GC-MSno
EukaryotaFusarium ProliferatumLiquid onion extract medium (LOM)SPME, GC-MSno


2-methylprop-1-ene

Compound Details

Synonymous names
ISOBUTYLENE
Isobutene
2-methylprop-1-ene
2-Methylpropene
115-11-7
2-Methyl-1-propene
2-Methylpropylene
1,1-Dimethylethylene
1-Propene, 2-methyl-
Isopropylidenemethylene
Methylpropene
gamma-Butylene
Propene, 2-methyl-
9003-27-4
1,1-Dimethylethene
iso-butene
i-butene
unsym. dimethylethylene
CCRIS 2281
HSDB 613
UNII-QA2LMR467H
EINECS 204-066-3
QA2LMR467H
2-METHYL-D3-PROPENE
DTXSID9020748
CHEBI:43907
Isobutene (ca. 9% in Hexane)
Isobutene (ca. 6% in Toluene)
EC 204-066-3
Isobutene (ca. 8% in Dichloromethane)
Isobutene (ca. 15% in Tetrahydrofuran)
Isobutene (ca. 10% in Isopropyl Ether)
2-METHYL-D3-PROPENE-3,3,3-D3
42278-27-3
68037-14-9
sym-Dimethylethylene
MFCD00008898
2-methyl-2-propene
UN1055
isobutylene, various grades
iso-butylene
Isobutene trimer
2-Methylpropyline
.gamma.-Butylene
2-methyl-l-propene
2-methyl-2 propene
iso-C4H8
2-Methylpropene, 99%
ISOBUTYLENE [MI]
ISOBUTYLENE [HSDB]
Unsymmetrical dimethylethylene
ISOBUTYLENE [WHO-DD]
DTXCID90748
Propene, 2-methyl-, tetramer
1-Propene, 2-methyl-, trimer
1,3-Propanediyl, 2-methylene-
DTXSID50164803
DTXSID601307041
2-Methylpropene, purum, >=99.5%
AKOS000121111
UN 1055
I0091
I0909
I0910
I0911
I1082
I1083
NS00007976
InChI=1/C4H8/c1-4(2)3/h1H2,2-3H
A803373
Q776976
13001-05-3
68606-25-7
Microorganism:

Yes

IUPAC name2-methylprop-1-ene
SMILESCC(=C)C
InchiInChI=1S/C4H8/c1-4(2)3/h1H2,2-3H3
FormulaC4H8
PubChem ID8255
Molweight56.11
LogP2.1
Atoms4
Bonds0
H-bond Acceptor0
H-bond Donor0
Chemical Classificationunsaturated hydrocarbons alkenes
CHEBI-ID43907
Supernatural-IDSN0397579

mVOC Specific Details

Boiling Point
DegreeReference
7 °C peer reviewed
Volatilization
The Henry's Law constant for isobutylene is 0.218 atm-cu m/mole(1). This Henry's Law constant indicates that isobutylene is expected to volatilize rapidly from water surfaces(2). Based on this Henry's Law constant, the volatilization half-life from a model river (1 m deep, flowing 1 m/sec, wind velocity of 3 m/sec)(2) is estimated as 2 hours(SRC). The volatilization half-life from a model lake (1 m deep, flowing 0.05 m/sec, wind velocity of 0.5 m/sec)(2) is estimated as 71 hours(SRC). Isobutylene's Henry's Law constant indicates that volatilization from moist soil surfaces may occur(SRC). Isobutylene is expected to volatilize from dry soil surfaces(SRC) based upon a vapor pressure of 2,308 mm Hg mm Hg(3).
Soil Adsorption
Using a structure estimation method based on molecular connectivity indices(1), the Koc of isobutylene can be estimated to be 32(SRC). According to a classification scheme(2), this estimated Koc value suggests that isobutylene is expected to have very high mobility in soil(SRC).
Massbank-Links

Species emitting the compound
KingdomSpeciesBiological FunctionOrigin/HabitatReference
ProkaryotaStreptococcus PneumoniaeNANAFilipiak et al. 2012
EukaryotaFusarium OxysporumonionWang et al. 2018
EukaryotaFusarium ProliferatumonionWang et al. 2018
Method
KingdomSpeciesGrowth MediumApplied MethodVerification
ProkaryotaStreptococcus PneumoniaeTryptic soyaTD/GC-MSno
EukaryotaFusarium OxysporumLiquid onion extract medium (LOM)SPME, GC-MSno
EukaryotaFusarium ProliferatumLiquid onion extract medium (LOM)SPME, GC-MSno


Prop-1-ene

Mass-Spectra

Compound Details

Synonymous names
PROPYLENE
Propene
prop-1-ene
1-Propene
Methylethylene
Methylethene
1-Propylene
115-07-1
Propene, pure
NCI-C50077
CCRIS 1356
HSDB 175
UNII-AUG1H506LY
EINECS 204-062-1
AUG1H506LY
CH2=CH-CH3
R 1270
25085-53-4
CHEBI:16052
Propene-1-13C (gas)
CH3CH=CH2
Propene (3,3,3-D3)
Propene (2.0-3.5% in Hexane)
Propene (2.0-3.5% in Heptane)
PROPYLENE (IARC)
PROPYLENE [IARC]
R-1270
MFCD00009279
MFCD00084447
UN1077
Polipropene 25
68606-26-8
EINECS 292-050-7
prop-1-en-3-yl
Propylene, >=99%
PROPYLENE [MI]
PROPYLENE [HSDB]
90530-12-4
97102-85-7
Propene (1-2% in Toluene)
CHEMBL117213
DTXSID5021205
DTXSID70941638
c0067
UN2850
AKOS009156831
UN 1077
Propylene, 99.5%, Messer(R) CANGas
NS00001068
P2816
P2817
InChI=1/C3H6/c1-3-2/h3H,1H2,2H
Propylene tetramer [UN2850] [Flammable liquid]
Q151324
1-Propene,ammoxidized,by-products from,thermal-cracked
Microorganism:

Yes

IUPAC nameprop-1-ene
SMILESCC=C
InchiInChI=1S/C3H6/c1-3-2/h3H,1H2,2H3
FormulaC3H6
PubChem ID8252
Molweight42.08
LogP1.4
Atoms3
Bonds0
H-bond Acceptor0
H-bond Donor0
Chemical Classificationunsaturated hydrocarbons alkenes
CHEBI-ID16052
Supernatural-IDSN0312517

mVOC Specific Details

Boiling Point
DegreeReference
47.68 °C peer reviewed
Volatilization
The experimental Henry's Law constant for propylene is 1.96X10-1 atm-cu m/mole(1). This Henry's Law constant indicates that propylene is expected to volatilize rapidly from water surfaces(2). Based on this Henry's Law constant, the volatilization half-life from a model river (1 m deep, flowing 1 m/sec, wind velocity of 3 m/sec)(3) is estimated as 0.7 hours(SRC). The volatilization half-life from a model lake (1 m deep, flowing 0.05 m/sec, wind velocity of 0.5 m/sec)(2) is estimated as 3 days(SRC). Propylene's measured Henry's Law constant indicates that volatilization from moist soil surfaces will occur(SRC). The potential for volatilization of propylene from dry soil surfaces exists based upon a vapor pressure of 8690 mm Hg(3).
Literature: (1) Wasik SP, Tsang W; J Phys Chem 74: 2970-76 (1970) (2) Lyman WJ et al; Handbook of Chemical Property Estimation Methods. Washington, DC: Amer Chem Soc pp. 15-1 to 15-29 (1990) (3) Daubert TE, Danner RP; Physical and Thermodynamic Properties of Pure Chemicals Data Compilation. Washington, DC: Taylor and Francis (1989)
Soil Adsorption
The Koc of propylene is estimated as 220(SRC), using a log Kow of 1.77(1) and a regression-derived equation(2). According to a classification scheme(3), this estimated Koc value suggests that propylene is expected to have moderate mobility in soil.
Literature: (1) Hansch C et al; Exploring QSAR. Hydrophobic, Electronic, and Steric Constants. ACS Prof Ref Book. Heller SR, consult. ed., Washington, DC: Amer Chem Soc p. 6 (1995) (2) Lyman WJ et al; Handbook of Chemical Property Estimation Methods. Washington, DC: Amer Chem Soc pp. 4-9 (1990) (3) Swann RL et al; Res Rev 85: 17-28 (1983)
Vapor Pressure
PressureReference
8.69X10+3 mm Hg at 25 deg C /Extrapolated/Daubert, T.E., R.P. Danner. Physical and Thermodynamic Properties of Pure Chemicals Data Compilation. Washington, D.C.: Taylor and Francis, 1989.
Massbank-Links

Species emitting the compound
Method
KingdomSpeciesGrowth MediumApplied MethodVerification
ProkaryotaEscherichia Colihuman bloodSIFT-MSno
ProkaryotaPseudomonas Aeruginosahuman bloodSIFT-MSno
EukaryotaFusarium OxysporumLiquid onion extract medium (LOM)SPME, GC-MSyes
EukaryotaFusarium ProliferatumLiquid onion extract medium (LOM)SPME, GC-MSyes
EukaryotaPenicillium Digitatumn/an/ano