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Record Information
Version2.0
Created at2022-09-07 20:35:04 UTC
Updated at2022-09-07 20:35:04 UTC
NP-MRD IDNP0255919
Secondary Accession NumbersNone
Natural Product Identification
Common Name(3e,5e,7z)-8-{[(4z,6z,8e,10e,12z,14e)-16-[(1,2-dihydroxy-4-methylpentylidene)amino]-1,3-dihydroxy-4,9-dimethylhexadeca-4,6,8,10,12,14-hexaen-1-ylidene]amino}-2-methylnona-3,5,7-trienoic acid
DescriptionBacillaene belongs to the class of organic compounds known as medium-chain fatty acids. These are fatty acids with an aliphatic tail that contains between 4 and 12 carbon atoms. (3e,5e,7z)-8-{[(4z,6z,8e,10e,12z,14e)-16-[(1,2-dihydroxy-4-methylpentylidene)amino]-1,3-dihydroxy-4,9-dimethylhexadeca-4,6,8,10,12,14-hexaen-1-ylidene]amino}-2-methylnona-3,5,7-trienoic acid was first documented in 2021 (PMID: 34298216). Based on a literature review a significant number of articles have been published on bacillaene (PMID: 34451760) (PMID: 35107331) (PMID: 35056513) (PMID: 34550751) (PMID: 35938811) (PMID: 35935203).
Structure
Thumb
SynonymsNot Available
Chemical FormulaC34H48N2O6
Average Mass580.7660 Da
Monoisotopic Mass580.35124 Da
IUPAC Name(3E,5E,7Z)-8-{[(4Z,6Z,8E,10E,12Z,14E)-16-[(1,2-dihydroxy-4-methylpentylidene)amino]-1,3-dihydroxy-4,9-dimethylhexadeca-4,6,8,10,12,14-hexaen-1-ylidene]amino}-2-methylnona-3,5,7-trienoic acid
Traditional Name(3E,5E,7Z)-8-{[(4Z,6Z,8E,10E,12Z,14E)-16-[(1,2-dihydroxy-4-methylpentylidene)amino]-1,3-dihydroxy-4,9-dimethylhexadeca-4,6,8,10,12,14-hexaen-1-ylidene]amino}-2-methylnona-3,5,7-trienoic acid
CAS Registry NumberNot Available
SMILES
CC(C)CC(O)C(O)=NC\C=C\C=C/C=C/C(/C)=C/C=C\C=C(\C)C(O)CC(O)=N\C(C)=C/C=C/C=C/C(C)C(O)=O
InChI Identifier
InChI=1S/C34H48N2O6/c1-25(2)23-31(38)33(40)35-22-16-9-7-8-11-17-26(3)18-14-15-19-27(4)30(37)24-32(39)36-29(6)21-13-10-12-20-28(5)34(41)42/h7-21,25,28,30-31,37-38H,22-24H2,1-6H3,(H,35,40)(H,36,39)(H,41,42)/b8-7-,13-10+,15-14-,16-9+,17-11+,20-12+,26-18+,27-19-,29-21-
InChI KeyKDQMRYTZELJKOB-MAHROAIDSA-N
Experimental Spectra
Not Available
Predicted Spectra
Spectrum TypeDescriptionDepositor IDDepositor OrganizationDepositorDeposition DateView
1D NMR13C NMR Spectrum (1D, 25 MHz, H2O, predicted)Wishart LabWishart LabDavid Wishart2021-06-20View Spectrum
1D NMR1H NMR Spectrum (1D, 100 MHz, H2O, predicted)Wishart LabWishart LabDavid Wishart2021-06-20View Spectrum
1D NMR13C NMR Spectrum (1D, 252 MHz, H2O, predicted)Wishart LabWishart LabDavid Wishart2021-06-20View Spectrum
1D NMR1H NMR Spectrum (1D, 1000 MHz, H2O, predicted)Wishart LabWishart LabDavid Wishart2021-06-20View Spectrum
1D NMR13C NMR Spectrum (1D, 50 MHz, H2O, predicted)Wishart LabWishart LabDavid Wishart2021-06-20View Spectrum
1D NMR1H NMR Spectrum (1D, 200 MHz, H2O, predicted)Wishart LabWishart LabDavid Wishart2021-06-20View Spectrum
1D NMR13C NMR Spectrum (1D, 75 MHz, H2O, predicted)Wishart LabWishart LabDavid Wishart2021-06-20View Spectrum
1D NMR1H NMR Spectrum (1D, 300 MHz, H2O, predicted)Wishart LabWishart LabDavid Wishart2021-06-20View Spectrum
1D NMR13C NMR Spectrum (1D, 101 MHz, H2O, predicted)Wishart LabWishart LabDavid Wishart2021-06-20View Spectrum
1D NMR1H NMR Spectrum (1D, 400 MHz, H2O, predicted)Wishart LabWishart LabDavid Wishart2021-06-20View Spectrum
1D NMR13C NMR Spectrum (1D, 126 MHz, H2O, predicted)Wishart LabWishart LabDavid Wishart2021-06-20View Spectrum
1D NMR1H NMR Spectrum (1D, 500 MHz, H2O, predicted)Wishart LabWishart LabDavid Wishart2021-06-20View Spectrum
1D NMR13C NMR Spectrum (1D, 151 MHz, H2O, predicted)Wishart LabWishart LabDavid Wishart2021-06-20View Spectrum
1D NMR1H NMR Spectrum (1D, 600 MHz, H2O, predicted)Wishart LabWishart LabDavid Wishart2021-06-20View Spectrum
1D NMR13C NMR Spectrum (1D, 176 MHz, H2O, predicted)Wishart LabWishart LabDavid Wishart2021-06-20View Spectrum
1D NMR1H NMR Spectrum (1D, 700 MHz, H2O, predicted)Wishart LabWishart LabDavid Wishart2021-06-20View Spectrum
1D NMR13C NMR Spectrum (1D, 201 MHz, H2O, predicted)Wishart LabWishart LabDavid Wishart2021-06-20View Spectrum
1D NMR1H NMR Spectrum (1D, 800 MHz, H2O, predicted)Wishart LabWishart LabDavid Wishart2021-06-20View Spectrum
1D NMR13C NMR Spectrum (1D, 226 MHz, H2O, predicted)Wishart LabWishart LabDavid Wishart2021-06-20View Spectrum
1D NMR1H NMR Spectrum (1D, 900 MHz, H2O, predicted)Wishart LabWishart LabDavid Wishart2021-06-20View Spectrum
Chemical Shift Submissions
Not Available
Species
Species of OriginNot Available
Chemical Taxonomy
Description Belongs to the class of organic compounds known as medium-chain fatty acids. These are fatty acids with an aliphatic tail that contains between 4 and 12 carbon atoms.
KingdomOrganic compounds
Super ClassLipids and lipid-like molecules
ClassFatty Acyls
Sub ClassFatty acids and conjugates
Direct ParentMedium-chain fatty acids
Alternative Parents
Substituents
  • Medium-chain fatty acid
  • Amino fatty acid
  • Branched fatty acid
  • Hydroxy fatty acid
  • Methyl-branched fatty acid
  • Fatty amide
  • Unsaturated fatty acid
  • N-acyl-amine
  • Carboxamide group
  • Secondary carboxylic acid amide
  • Secondary alcohol
  • Carboxylic acid derivative
  • Carboxylic acid
  • Monocarboxylic acid or derivatives
  • Hydrocarbon derivative
  • Organic oxide
  • Alcohol
  • Organopnictogen compound
  • Carbonyl group
  • Organic oxygen compound
  • Organic nitrogen compound
  • Organooxygen compound
  • Organonitrogen compound
  • Aliphatic acyclic compound
Molecular FrameworkAliphatic acyclic compounds
External Descriptors
Physical Properties
StateNot Available
Experimental Properties
PropertyValueReference
Melting PointNot AvailableNot Available
Boiling PointNot AvailableNot Available
Water SolubilityNot AvailableNot Available
LogPNot AvailableNot Available
Predicted Properties
PropertyValueSource
logP3.43ChemAxon
pKa (Strongest Acidic)2.91ChemAxon
pKa (Strongest Basic)6.27ChemAxon
Physiological Charge-1ChemAxon
Hydrogen Acceptor Count8ChemAxon
Hydrogen Donor Count5ChemAxon
Polar Surface Area142.94 ŲChemAxon
Rotatable Bond Count18ChemAxon
Refractivity180.88 m³·mol⁻¹ChemAxon
Polarizability68.49 ųChemAxon
Number of Rings0ChemAxon
BioavailabilityNoChemAxon
Rule of FiveNoChemAxon
Ghose FilterNoChemAxon
Veber's RuleNoChemAxon
MDDR-like RuleNoChemAxon
HMDB IDNot Available
DrugBank IDNot Available
Phenol Explorer Compound IDNot Available
FoodDB IDNot Available
KNApSAcK IDNot Available
Chemspider ID28284618
KEGG Compound IDNot Available
BioCyc IDNot Available
BiGG IDNot Available
Wikipedia LinkNot Available
METLIN IDNot Available
PubChem Compound25144999
PDB IDNot Available
ChEBI ID71623
Good Scents IDNot Available
References
General References
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  2. Nifakos K, Tsalgatidou PC, Thomloudi EE, Skagia A, Kotopoulis D, Baira E, Delis C, Papadimitriou K, Markellou E, Venieraki A, Katinakis P: Genomic Analysis and Secondary Metabolites Production of the Endophytic Bacillus velezensis Bvel1: A Biocontrol Agent against Botrytis cinerea Causing Bunch Rot in Post-Harvest Table Grapes. Plants (Basel). 2021 Aug 20;10(8):1716. doi: 10.3390/plants10081716. [PubMed:34451760 ]
  3. Zaid DS, Cai S, Hu C, Li Z, Li Y: Comparative Genome Analysis Reveals Phylogenetic Identity of Bacillus velezensis HNA3 and Genomic Insights into Its Plant Growth Promotion and Biocontrol Effects. Microbiol Spectr. 2022 Feb 23;10(1):e0216921. doi: 10.1128/spectrum.02169-21. Epub 2022 Feb 2. [PubMed:35107331 ]
  4. Liang L, Fu Y, Deng S, Wu Y, Gao M: Genomic, Antimicrobial, and Aphicidal Traits of Bacillus velezensis ATR2, and Its Biocontrol Potential against Ginger Rhizome Rot Disease Caused by Bacillus pumilus. Microorganisms. 2021 Dec 29;10(1):63. doi: 10.3390/microorganisms10010063. [PubMed:35056513 ]
  5. Han X, Shen D, Xiong Q, Bao B, Zhang W, Dai T, Zhao Y, Borriss R, Fan B: The Plant-Beneficial Rhizobacterium Bacillus velezensis FZB42 Controls the Soybean Pathogen Phytophthora sojae Due to Bacilysin Production. Appl Environ Microbiol. 2021 Nov 10;87(23):e0160121. doi: 10.1128/AEM.01601-21. Epub 2021 Sep 22. [PubMed:34550751 ]
  6. Erega A, Stefanic P, Danevcic T, Smole Mozina S, Mandic Mulec I: Impact of Bacillus subtilis Antibiotic Bacilysin and Campylobacter jejuni Efflux Pumps on Pathogen Survival in Mixed Biofilms. Microbiol Spectr. 2022 Aug 31;10(4):e0215622. doi: 10.1128/spectrum.02156-22. Epub 2022 Aug 8. [PubMed:35938811 ]
  7. Li P, Feng B, Yao Z, Wei B, Zhao Y, Shi S: Antifungal Activity of Endophytic Bacillus K1 Against Botrytis cinerea. Front Microbiol. 2022 Jul 22;13:935675. doi: 10.3389/fmicb.2022.935675. eCollection 2022. [PubMed:35935203 ]
  8. Ahmed W, Dai Z, Zhang J, Li S, Ahmed A, Munir S, Liu Q, Tan Y, Ji G, Zhao Z: Plant-Microbe Interaction: Mining the Impact of Native Bacillus amyloliquefaciens WS-10 on Tobacco Bacterial Wilt Disease and Rhizosphere Microbial Communities. Microbiol Spectr. 2022 Aug 31;10(4):e0147122. doi: 10.1128/spectrum.01471-22. Epub 2022 Aug 1. [PubMed:35913211 ]
  9. Wang KX, Xu WH, Chen ZN, Hu JL, Luo SQ, Wang ZG: Complete genome sequence of Bacillus velezensis WB, an isolate from the watermelon rhizosphere: genomic insights into its antifungal effects. J Glob Antimicrob Resist. 2022 Sep;30:442-444. doi: 10.1016/j.jgar.2022.05.010. Epub 2022 May 23. [PubMed:35618208 ]
  10. Tsalgatidou PC, Thomloudi EE, Baira E, Papadimitriou K, Skagia A, Venieraki A, Katinakis P: Integrated Genomic and Metabolomic Analysis Illuminates Key Secreted Metabolites Produced by the Novel Endophyte Bacillus halotolerans Cal.l.30 Involved in Diverse Biological Control Activities. Microorganisms. 2022 Feb 9;10(2):399. doi: 10.3390/microorganisms10020399. [PubMed:35208854 ]
  11. Kamali M, Guo D, Naeimi S, Ahmadi J: Perception of Biocontrol Potential of Bacillus inaquosorum KR2-7 against Tomato Fusarium Wilt through Merging Genome Mining with Chemical Analysis. Biology (Basel). 2022 Jan 14;11(1):137. doi: 10.3390/biology11010137. [PubMed:35053135 ]
  12. Li Y, Xia M, He P, Yang Q, Wu Y, He P, Ahmed A, Li X, Wang Y, Munir S, He Y: Developing Penicillium digitatum Management Strategies on Post-Harvest Citrus Fruits with Metabolic Components and Colonization of Bacillus subtilis L1-21. J Fungi (Basel). 2022 Jan 14;8(1):80. doi: 10.3390/jof8010080. [PubMed:35050020 ]
  13. Maan H, Povolotsky TL, Porat Z, Itkin M, Malitsky S, Kolodkin-Gal I: Imaging flow cytometry reveals a dual role for exopolysaccharides in biofilms: To promote self-adhesion while repelling non-self-community members. Comput Struct Biotechnol J. 2021 Dec 4;20:15-25. doi: 10.1016/j.csbj.2021.11.043. eCollection 2022. [PubMed:34976308 ]
  14. Rungsirivanich P, Parlindungan E, O'Connor PM, Field D, Mahony J, Thongwai N, van Sinderen D: Simultaneous Production of Multiple Antimicrobial Compounds by Bacillus velezensis ML122-2 Isolated From Assam Tea Leaf [Camellia sinensis var. assamica (J.W.Mast.) Kitam.]. Front Microbiol. 2021 Nov 24;12:789362. doi: 10.3389/fmicb.2021.789362. eCollection 2021. [PubMed:34899671 ]
  15. Pramod S, Thommana RT, Kulanthaivelu Kanagam H, Suresh Kumar A, S SK, Elangovan E, Perumal K: Data on the genome of Bacillus subtilis A1- Midalam from beach soil. Data Brief. 2021 Nov 7;39:107552. doi: 10.1016/j.dib.2021.107552. eCollection 2021 Dec. [PubMed:34820494 ]
  16. Ji C, Zhang M, Kong Z, Chen X, Wang X, Ding W, Lai H, Guo Q: Genomic Analysis Reveals Potential Mechanisms Underlying Promotion of Tomato Plant Growth and Antagonism of Soilborne Pathogens by Bacillus amyloliquefaciens Ba13. Microbiol Spectr. 2021 Dec 22;9(3):e0161521. doi: 10.1128/Spectrum.01615-21. Epub 2021 Nov 10. [PubMed:34756081 ]
  17. Maan H, Gilhar O, Porat Z, Kolodkin-Gal I: Bacillus subtilis Colonization of Arabidopsis thaliana Roots Induces Multiple Biosynthetic Clusters for Antibiotic Production. Front Cell Infect Microbiol. 2021 Sep 3;11:722778. doi: 10.3389/fcimb.2021.722778. eCollection 2021. [PubMed:34557426 ]
  18. Molina-Santiago C, Vela-Corcia D, Petras D, Diaz-Martinez L, Perez-Lorente AI, Sopena-Torres S, Pearson J, Caraballo-Rodriguez AM, Dorrestein PC, de Vicente A, Romero D: Chemical interplay and complementary adaptative strategies toggle bacterial antagonism and co-existence. Cell Rep. 2021 Jul 27;36(4):109449. doi: 10.1016/j.celrep.2021.109449. [PubMed:34320359 ]
  19. Tenorio-Salgado S, Castelan-Sanchez HG, Davila-Ramos S, Huerta-Saquero A, Rodriguez-Morales S, Merino-Perez E, Roa de la Fuente LF, Solis-Pereira SE, Perez-Rueda E, Lizama-Uc G: Metagenomic analysis and antimicrobial activity of two fermented milk kefir samples. Microbiologyopen. 2021 Mar;10(2):e1183. doi: 10.1002/mbo3.1183. [PubMed:33970536 ]
  20. Erega A, Stefanic P, Dogsa I, Danevcic T, Simunovic K, Klancnik A, Smole Mozina S, Mandic Mulec I: Bacillaene Mediates the Inhibitory Effect of Bacillus subtilis on Campylobacter jejuni Biofilms. Appl Environ Microbiol. 2021 May 26;87(12):e0295520. doi: 10.1128/AEM.02955-20. Epub 2021 May 26. [PubMed:33837012 ]
  21. LOTUS database [Link]