The genus Bacillus is widely recognized for its metabolic versatility, enabling it to colonize extreme environments, including sites contaminated with metals. In this study, we report the genome of B. velezensis strain HM1, isolated from sulfur-rich mine tailings from silver mining activities in southwestern Mexico. Isolation was performed by heat treatment followed by selective cultivation in a medium enriched with mine tailings extract (metals and sulfates), resulting in a single dominant morphotype corresponding to strain HM1. Whole-genome sequencing was carried out using the Illumina NovaSeq platform (2 × 250 bp). The assembled genome of strain HM1 has a size of 4,044,128 bp, distributed across 20 contigs, with an N50 of 700,388 bp and an L50 of 3, and an average coverage of 66.8×. The GC content was 46.31%, with an estimated completeness of 99.81% and contamination of 0.01%. Genome analyses indicate that the assembly corresponds to a single chromosome, with no evidence of plasmid replicons. Genome annotation identified 3950 coding sequences (CDSs), 83 tRNAs, 11 rRNAs, 26 ncRNAs, and 4 sORFs. Phylogenomic analysis, together with genomic similarity metrics (ANI > 98.6%, AAI > 98.8%, dDDH > 87%), confirms its classification as Bacillus velezensis. Functionally, the genome encodes multiple genes involved in resistance to metals and metalloids (including ABC transporters, efflux pumps, and biotransformation enzymes), as well as a complete pathway for sulfate assimilation. Collectively, these genomic features reveal a broad repertoire of adaptive strategies employed by strain HM1 to thrive in metal-contaminated environments.
Cuaxinque-Flores et al. (Fri,) studied this question.