Bacterial endospores are the most resistant cell type known to humans, as they are able to withstand extremes of temperature, pressure, chemical injury, and time. They are also of interest because the endospore is the infective particle in a variety of human and livestock diseases. Endosporulation is characterized by the morphogenesis of an endospore within a mother cell. Based on the genes known to be involved in endosporulation in the model organism Bacillus subtilis, a conserved core of about 100 genes was derived, representing the minimal machinery for endosporulation. The core was used to define a genomic signature of about 50 genes that are able to distinguish endospore-forming organisms, based on complete genome sequences, and we show this 50-gene signature is robust against phylogenetic proximity and other artifacts. This signature includes previously uncharacterized genes that we can now show are important for sporulation in B. subtilis and/or are under developmental control, thus further validating this genomic signature. We also predict that a series of polyextremophylic organisms, as well as several gut bacteria, are able to form endospores, and we identified 3 new loci essential for sporulation in B. subtilis: ytaF, ylmC, and ylzA. In all, the results support the view that endosporulation likely evolved once, at the base of the Firmicutes phylum, and is unrelated to other bacterial cell differentiation programs and that this involved the evolution of new genes and functions, as well as the cooption of ancestral, housekeeping functions.
Bacterial endospores, such as those formed by species of the Bacillus and Clostridium genera, are arguably the most resistant cellular structures known to scientists. Endospores resist physical and chemical changes, such as exposure to solvents, oxidizing agents, and lytic enzymes, high temperatures, vacuum, acceleration, and irradiation, that would rapidly destroy the vegetative form of the bacterium (1-3). The extreme conditions endured by bacterial endospores include simulated and actual extraterrestrial environments (2). The resilience of the endospore allows it to remain viable in the environment for long periods of time, contributing to the wide geographic distributions of spores in Earth's ecosystems (2). It also allows endospore formers to occupy niches in the gastrointestinal (GI) tract of metazoans, establishing either symbiotic or commensal relationships or pathogenic interactions, in which case the spore often serves as the infectious vehicle (4-7). The robustness of endospores is also the basis for several applications of endospores in biomedicine and biotechnology, including their use in probiotic formulations or as platforms for the display of enzymes or antigens (8-10).Most of the previously described endosporulating bacteria belong to the Clostridia (anaerobic) and Bacilli (aerobic) classes of the Firmicutes phylum, one of the two eubacterial phyla that groups Gram-positive organisms (11). However, endospore formers are found in other classes within t...
