Bacillus anthracis, Bacillus cereus, and Bacillus thuringiensis are closely related gram-positive, spore-forming bacteria of the B. cereus sensu lato group. While independently derived strains of B. anthracis reveal conspicuous sequence homogeneity, environmental isolates of B. cereus and B. thuringiensis exhibit extensive genetic diversity. Here we report the sequencing and comparative analysis of the genomes of two members of the B. cereus group, B. thuringiensis 97-27 subsp. konkukian serotype H34, isolated from a necrotic human wound, and B. cereus E33L, which was isolated from a swab of a zebra carcass in Namibia. These two strains, when analyzed by amplified fragment length polymorphism within a collection of over 300 of B. cereus, B. thuringiensis, and B. anthracis isolates, appear closely related to B. anthracis. The B. cereus E33L isolate appears to be the nearest relative to B. anthracis identified thus far. Whole-genome sequencing of B. thuringiensis 97-27and B. cereus E33L was undertaken to identify shared and unique genes among these isolates in comparison to the genomes of pathogenic strains B. anthracis Ames and B. cereus G9241 and nonpathogenic strains B. cereus ATCC 10987 and B. cereus ATCC 14579. Comparison of these genomes revealed differences in terms of virulence, metabolic competence, structural components, and regulatory mechanisms.While Bacillus anthracis, Bacillus cereus, and Bacillus thuringiensis are closely related members of the B. cereus group (22), individual isolates exhibit differences in terms of host range and virulence. B. anthracis is the causal agent of anthrax, a zoonotic disease that can be lethal to humans. B. cereus is a ubiquitous soil organism and an opportunistic human pathogen most commonly associated with food poisoning (10). B. thuringiensis is an insect pathogen that is widely used as a biopesticide (36). Here we report the sequencing and comparative analysis of the genomes of two members of the B. cereus group, B. thuringiensis 97-27 subsp. konkukian serotype H34, isolated from a necrotic human wound (17), and B. cereus E33L, which was isolated from a swab of a zebra carcass in Namibia (P. C. B. Turnbull, personal communication). To facilitate the comparison of these two isolates with other members of the B. cereus group, we compiled a core genome of over 3,900 B. cereus group genes. Comparison of these genomes revealed differences in terms of virulence, metabolic competence, structural components, and regulatory mechanisms (see Table 1, below), supporting the idea that differential regulation modulates virulence rather than simple acquisition of virulence factor genes. Our analysis of the genome sequences of B. thuringiensis 97-27 and B. cereus E33L provides insight into the evolutionary relationships among these B. cereus group organisms, as well as the molecular mechanisms contributing to their host range and virulence. MATERIALS AND METHODSSequencing of the B. thuringiensis 97-27 and B. cereus E33L genomes. The random shotgun method of cloning, sequencing, an...
We have used sequence-based markers from an integrated YAC STS-content/somatic cell hybrid breakpoint physical map and radiation hybrid maps of human chromosome 16 to construct a new sequence-ready BAC map of the long arm of this chromosome. The integrated physical map was generated previously in our laboratory and contains 1150 STSs, providing a marker on average every 78 kb on the euchromatic arms of chromosome 16. The other two maps used for this effort were the radiation hybrid maps of chromosome 16 from Whitehead Institute and Stanford University. To create large sequenceable targets of this chromosome, we used a systematic approach to screen high-density BAC filters with probes generated from overlapping oligonucleotides (overgos). We first identified all available sequences in the three maps. These include sequences from genes, ESTs, STSs, and cosmid end sequences. We then used BLASTto identify 36-bp unique fragments of DNA for overgo probes. A total of 906 overgos were selected from the long arm of chromosome 16. Hybridizations occurred in three stages: (1) superpool hybridizations against the 12× coverage human BAC library (RPCI-11); (2) two-dimensional hybridizations against rearrayed positive BACs identified in the superpool hybridizations; and (3) pooled tertiary hybridizations for those overgos that had ambiguous positives remaining after the two-dimensional hybridization. For the superpool hybridizations, up to 236 overgos have been pooled in a single hybridization against the 12× BAC library. A total of 5187 positive BACs from chromosome 16q were identified as a result of five superpool hybridizations. These positive clones were rearrayed on membranes and hybridized with 161 two-dimensional subpools of overgos to determine which BAC clones were positive for individual overgos. An additional 46 tertiary hybridizations were required to resolve ambiguous overgo-BAC relationships. Thus, after a total of 212 hybridizations, we have constructed an initial probe-content BAC map of chromosome 16q consisting of 828 overgo markers and 3363 BACs providing >85% coverage of the long arm of this chromosome. The map has been confirmed by the fingerprinting data and BAC end PCR screening.
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