| Record Information |
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| Version | 2.0 |
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| Created at | 2022-09-07 20:35:04 UTC |
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| Updated at | 2022-09-07 20:35:04 UTC |
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| NP-MRD ID | NP0255919 |
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| Secondary Accession Numbers | None |
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| Natural Product Identification |
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| 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 |
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| Description | Bacillaene 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). |
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| Structure | 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=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- |
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| Synonyms | Not Available |
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| Chemical Formula | C34H48N2O6 |
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| Average Mass | 580.7660 Da |
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| Monoisotopic Mass | 580.35124 Da |
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| 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 |
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| 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 |
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| CAS Registry Number | Not Available |
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| 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 |
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| 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- |
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| InChI Key | KDQMRYTZELJKOB-MAHROAIDSA-N |
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| Experimental Spectra |
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| Not Available | | Predicted Spectra |
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| | Spectrum Type | Description | Depositor ID | Depositor Organization | Depositor | Deposition Date | View |
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| 1D NMR | 13C NMR Spectrum (1D, 25 MHz, H2O, predicted) | Wishart Lab | Wishart Lab | David Wishart | 2021-06-20 | View Spectrum | | 1D NMR | 1H NMR Spectrum (1D, 100 MHz, H2O, predicted) | Wishart Lab | Wishart Lab | David Wishart | 2021-06-20 | View Spectrum | | 1D NMR | 13C NMR Spectrum (1D, 252 MHz, H2O, predicted) | Wishart Lab | Wishart Lab | David Wishart | 2021-06-20 | View Spectrum | | 1D NMR | 1H NMR Spectrum (1D, 1000 MHz, H2O, predicted) | Wishart Lab | Wishart Lab | David Wishart | 2021-06-20 | View Spectrum | | 1D NMR | 13C NMR Spectrum (1D, 50 MHz, H2O, predicted) | Wishart Lab | Wishart Lab | David Wishart | 2021-06-20 | View Spectrum | | 1D NMR | 1H NMR Spectrum (1D, 200 MHz, H2O, predicted) | Wishart Lab | Wishart Lab | David Wishart | 2021-06-20 | View Spectrum | | 1D NMR | 13C NMR Spectrum (1D, 75 MHz, H2O, predicted) | Wishart Lab | Wishart Lab | David Wishart | 2021-06-20 | View Spectrum | | 1D NMR | 1H NMR Spectrum (1D, 300 MHz, H2O, predicted) | Wishart Lab | Wishart Lab | David Wishart | 2021-06-20 | View Spectrum | | 1D NMR | 13C NMR Spectrum (1D, 101 MHz, H2O, predicted) | Wishart Lab | Wishart Lab | David Wishart | 2021-06-20 | View Spectrum | | 1D NMR | 1H NMR Spectrum (1D, 400 MHz, H2O, predicted) | Wishart Lab | Wishart Lab | David Wishart | 2021-06-20 | View Spectrum | | 1D NMR | 13C NMR Spectrum (1D, 126 MHz, H2O, predicted) | Wishart Lab | Wishart Lab | David Wishart | 2021-06-20 | View Spectrum | | 1D NMR | 1H NMR Spectrum (1D, 500 MHz, H2O, predicted) | Wishart Lab | Wishart Lab | David Wishart | 2021-06-20 | View Spectrum | | 1D NMR | 13C NMR Spectrum (1D, 151 MHz, H2O, predicted) | Wishart Lab | Wishart Lab | David Wishart | 2021-06-20 | View Spectrum | | 1D NMR | 1H NMR Spectrum (1D, 600 MHz, H2O, predicted) | Wishart Lab | Wishart Lab | David Wishart | 2021-06-20 | View Spectrum | | 1D NMR | 13C NMR Spectrum (1D, 176 MHz, H2O, predicted) | Wishart Lab | Wishart Lab | David Wishart | 2021-06-20 | View Spectrum | | 1D NMR | 1H NMR Spectrum (1D, 700 MHz, H2O, predicted) | Wishart Lab | Wishart Lab | David Wishart | 2021-06-20 | View Spectrum | | 1D NMR | 13C NMR Spectrum (1D, 201 MHz, H2O, predicted) | Wishart Lab | Wishart Lab | David Wishart | 2021-06-20 | View Spectrum | | 1D NMR | 1H NMR Spectrum (1D, 800 MHz, H2O, predicted) | Wishart Lab | Wishart Lab | David Wishart | 2021-06-20 | View Spectrum | | 1D NMR | 13C NMR Spectrum (1D, 226 MHz, H2O, predicted) | Wishart Lab | Wishart Lab | David Wishart | 2021-06-20 | View Spectrum | | 1D NMR | 1H NMR Spectrum (1D, 900 MHz, H2O, predicted) | Wishart Lab | Wishart Lab | David Wishart | 2021-06-20 | View Spectrum |
| | Chemical Shift Submissions |
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| Not Available | | Species |
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| Species of Origin | Not Available |
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| Chemical Taxonomy |
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| 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. |
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| Kingdom | Organic compounds |
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| Super Class | Lipids and lipid-like molecules |
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| Class | Fatty Acyls |
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| Sub Class | Fatty acids and conjugates |
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| Direct Parent | Medium-chain fatty acids |
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| Alternative Parents | |
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| 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
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| Molecular Framework | Aliphatic acyclic compounds |
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| External Descriptors | |
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| Physical Properties |
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| State | Not Available |
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| Experimental Properties | | Property | Value | Reference |
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| Melting Point | Not Available | Not Available | | Boiling Point | Not Available | Not Available | | Water Solubility | Not Available | Not Available | | LogP | Not Available | Not Available |
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| Predicted Properties | |
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| General References | - Villa-Rodriguez E, Moreno-Ulloa A, Castro-Longoria E, Parra-Cota FI, de Los Santos-Villalobos S: Integrated omics approaches for deciphering antifungal metabolites produced by a novel Bacillus species, B. cabrialesii TE3(T), against the spot blotch disease of wheat (Triticum turgidum L. subsp. durum). Microbiol Res. 2021 Oct;251:126826. doi: 10.1016/j.micres.2021.126826. Epub 2021 Jul 14. [PubMed:34298216 ]
- 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 ]
- 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 ]
- 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 ]
- 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 ]
- 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 ]
- 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 ]
- 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 ]
- 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 ]
- 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 ]
- 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 ]
- 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 ]
- 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 ]
- 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 ]
- 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 ]
- 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 ]
- 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 ]
- 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 ]
- 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 ]
- 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 ]
- LOTUS database [Link]
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