AbstractCereulide-producing members of Bacillus cereus sensu lato (B. cereus s.l.) Group III, also known as “emetic B. cereus”, possess cereulide synthetase, a plasmid-encoded, non-ribosomal peptide synthetase encoded by the ces gene cluster. Despite the documented risks that cereulide-producing strains pose to public health, the level of genomic diversity encompassed by “emetic B. cereus” has never been evaluated at a whole-genome scale. Here, we employ a phylogenomic approach to characterize Group III B. cereus s.l. genomes which possess ces (ces-positive) alongside their closely related ces-negative counterparts to (i) assess the genomic diversity encompassed by “emetic B. cereus”, and (ii) identify potential ces loss and/or gain events within the evolutionary history of the high-risk and medically relevant sequence type (ST) 26 lineage often associated with emetic foodborne illness. Using all publicly available ces-positive Group III B. cereus s.l. genomes and the ces-negative genomes interspersed among them (n = 150), we show that “emetic B. cereus” is not clonal; rather, multiple lineages within Group III harbor cereulide-producing strains, all of which share a common ancestor incapable of producing cereulide (posterior probability [PP] 0.86-0.89). The ST 26 common ancestor was predicted to have emerged as ces-negative (PP 0.60-0.93) circa 1904 (95% highest posterior density [HPD] interval 1837.1-1957.8) and first acquired the ability to produce cereulide before 1931 (95% HPD 1893.2-1959.0). Three subsequent ces loss events within ST 26 were observed, including among isolates responsible for B. cereus s.l. toxicoinfection (i.e., “diarrheal” illness).Importance“B. cereus” is responsible for thousands of cases of foodborne disease each year worldwide, causing two distinct forms of illness: (i) intoxication via cereulide (i.e., “emetic” syndrome) or (ii) toxicoinfection via multiple enterotoxins (i.e., “diarrheal” syndrome). Here, we show that “emetic B. cereus” is not a clonal, homogenous unit that resulted from a single cereulide synthetase gain event followed by subsequent proliferation; rather, cereulide synthetase acquisition and loss is a dynamic, ongoing process that occurs across lineages, allowing some Group III B. cereus s.l. populations to oscillate between diarrheal and emetic foodborne pathogen over the course of their evolutionary histories. We also highlight the care that must be taken when selecting a reference genome for whole-genome sequencing-based investigation of emetic B. cereus s.l. outbreaks, as some reference genome selections can lead to a confounding loss of resolution and potentially hinder epidemiological investigations.
Dynamic evolution of Panax species
