1. Structure of subtilosin A, a cyclic antimicrobial peptide from Bacillus subtilis with unusual sulfur to alpha-carbon cross-links: formation and reduction of alpha-thio-alpha-amino acid derivatives
Karen E Kawulka, Tara Sprules, Christopher M Diaper, Randy M Whittal, Ryan T McKay, Pascal Mercier, Peter Zuber, John C Vederas Biochemistry. 2004 Mar 30;43(12):3385-95. doi: 10.1021/bi0359527.
The complete primary and three-dimensional solution structures of subtilosin A (1), a bacteriocin from Bacillus subtilis, were determined by multidimensional NMR studies on peptide produced using isotopically labeled [(13)C,(15)N]medium derived from Anabaena sp. grown on sodium [(13)C]bicarbonate and [(15)N]nitrate. Additional samples of 1 were also generated by separate incorporations of [U-(13)C,(15)N]-L-phenylalanine and [U-(13)C,(15)N]-L-threonine using otherwise unlabeled media. The results demonstrate that in addition to having a cyclized peptide backbone (amide between N and C termini), three cross-links are formed between the sulfurs of Cys13, Cys7, and Cys4 and the alpha-positions of Phe22, Thr28, and Phe31, respectively. The stereochemistry of all residues in 1 except for the three modified ones was confirmed to be L by complete desulfurization with nickel boride, acid hydrolysis to the constituent amino acids, and conversion of these to the corresponding pentafluoropropanamide isopropyl esters for chiral GC MS analysis. The stereochemistry at the modified residues was determined by subjecting each of the eight possible stereoisomers of 1 to eight rounds of ARIA structure calculations, starting with the same NMR peak files and assignments. The stereoisomer with the l stereochemistry at Phe22 (alpha-R) and d stereochemistry at Thr28 (alpha-S) and Phe31 (alpha-S) (LDD isomer) fit the NMR data, giving the lowest energy family of structures with the best rmsd. Thus, biochemical formation of the unusual thio links proceeds with net retention of configuration at Phe22, and inversion at Thr28 and Phe31. Model amino acid derivatives bearing a sulfide moiety at the alpha-carbon were synthesized by reaction of the corresponding alpha-alkoxy compounds with benzyl thiol and SnCl(4). Separation of their pure stereoisomers and desulfurization with nickel boride demonstrated that the reduction of such compounds proceeds with epimerization, in contrast to the previously reported retention of stereochemistry for analogous reaction of steroidal sulfides. However, desulfurization of subtilosin A to cyclic peptide 14, which is inactive as an antimicrobial agent, occurs with inversion of stereochemistry at the alpha-carbons of Phe22 and Thr28 and with 4:1 retention at Phe31. This indicates that the desulfurization reaction proceeds via an N-acyl imine and that the structure of the surrounding peptide controls the geometry of reduction. Posttranslational linkage of a thiol to the alpha-carbon of an amino acid residue is unprecedented in ribosomally synthesized peptides or proteins, and very rare in secondary metabolites. Subtilosin A (1) represents a new class of bacteriocins.
2. Isolation of a variant of subtilosin A with hemolytic activity
Tai Huang, Hao Geng, Venugopal R Miyyapuram, Clarissa S Sit, John C Vederas, Michiko M Nakano J Bacteriol. 2009 Sep;191(18):5690-6. doi: 10.1128/JB.00541-09. Epub 2009 Jul 24.
Bacillus subtilis produces an anionic bacteriocin called subtilosin A that possesses antibacterial activity against certain gram-positive bacteria. In this study, we uncovered a hemolytic mutant of B. subtilis that produces an altered form of subtilosin A. The mutant bacteriocin, named subtilosin A1, has a replacement of threonine at position 6 with isoleucine. In addition to the hemolytic activity, subtilosin A1 was found to exhibit enhanced antimicrobial activity against specific bacterial strains. The B. subtilis albB mutant that does not produce a putative immunity peptide was more sensitive to both subtilosin A and subtilosin A1. A spontaneous suppressor mutation of albB that restored resistance to subtilosin A and subtilosin A1 was obtained. The sbr (subtilosin resistance) mutation conferring the resistance is not linked to the sboA-alb locus. The sbr mutation does not increase the resistance of B. subtilis to other cell envelope-targeted antimicrobial agents, indicating that the mutation specifically confers the resistance to subtilosins. The findings suggest possible bioengineering approaches for obtaining anionic bacteriocins with enhanced and/or altered bactericidal activity. Furthermore, future identification of the subtilosin-resistant mutation could provide insights into the mechanism of subtilosin A activity.
3. Data on the genome of Bacillus subtilis A1- Midalam from beach soil
Sneha Pramod, Rhea Thomas Thommana, Harini Kulanthaivelu Kanagam, Ashmita Suresh Kumar, Santha Kalaikumari S, Elavarashi Elangovan, Kumar Perumal Data Brief. 2021 Nov 7;39:107552. doi: 10.1016/j.dib.2021.107552. eCollection 2021 Dec.
The draft genome sequence of Bacillus subtilis A1, isolated from beach soil, has been shown to produce biofilm. The genome size is 4,215,114 bp with an average G+C content of 43.5%. The genome of Bacillus subtilis A1 has 4413 total genes which include 4166 protein-coding sequences, 126 pseudo genes, 10 rRNA genes with 3 operons (5S, 16S and 23S), 86 tRNA genes and 5 noncoding RNA (ncRNA) genes. The genome contains genes coding for surfactin, fengycin, bacillaene, sublancin 168, bacillibactin, subtilosin A, bacilysin. The whole genome project has been deposited in GenBank under the accession number CP075344.1. The raw data is available at https://www.ncbi.nlm.nih.gov/nuccore/CP075344.1.
