Identification of chromosomal markers for rapid detection of Bacillus anthracis is difficult because significant chromosomal homology exists among B. anthracis, Bacillus cereus, and Bacillus thuringiensis. We evaluated the bacterial gyrA gene as a potential chromosomal marker for B. anthracis. A real-time PCR assay was developed for the detection of B. anthracis. After analysis of the unique nucleotide sequence of the B. anthracis gyrA gene, a fluorescent 3' minor groove binding probe was tested with 171 organisms from 29 genera of bacteria, including 102 Bacillus strains. The assay was found to be specific for all 43 strains of B. anthracis tested. In addition, a test panel of 105 samples was analyzed to evaluate the potential diagnostic capability of the assay. The assay showed 100% specificity, demonstrating the usefulness of the gyrA gene as a specific chromosomal marker for B. anthracis.
Real-time PCR has become an important method for the rapid identification of Bacillus anthracis since the 2001 anthrax mailings. Most real-time PCR assays for B. anthracis have been developed to detect virulence genes located on the pXO1 and pXO2 plasmids. In contrast, only two published chromosomal targets exist, the rpoB gene and the gyrA gene. In the present study, subtraction-hybridization with a plasmid-cured B. anthracis tester strain and a Bacillus cereus driver was used to find a unique chromosomal sequence. By targeting this region, a real-time assay was developed with the Ruggedized Advanced Pathogen Identification Device. Further testing has revealed that the assay has 100% sensitivity and 100% specificity, with a limit of detection of 50 fg of DNA. The results of a search for sequences with homology with the BLAST program demonstrated significant alignment to the recently published B. anthracis Ames strain, while an inquiry for protein sequence similarities indicated homology with an abhydrolase from B. anthracis strain A2012. The importance of this chromosomal assay will be to verify the presence of B. anthracis independently of plasmid occurrence.Bacillus anthracis is a spore-forming gram-positive bacterium well known for its recent use as a bioterrorist agent. Identification of B. anthracis can be done clinically by Gram stain, colony morphology, and various biochemical tests (19). However, these methods are time-consuming, and more rapid tests, such as PCR, have been used to detect B. anthracis in clinical samples (20). Real-time PCR is preferred over conventional PCR methods for the identification of organisms because it is fast, is less labor-intensive, and adds the specificity of a probe. While real-time PCR assays have been used to identify B. anthracis on the basis of the virulence genes associated with the toxin-encoding plasmid (pXO1) and the capsule-encoding plasmid (pXO2) (11,20,22), a reliable chromosomal assay has not been developed. Chromosomal assays can be valuable tools when they are used in conjunction with virulence gene assays because they provide information on the genetic contexts of the pXO1 and pXO2 plasmids. While the chromosomal assays may not prove useful as initial screening assays, they can certainly have a significant role in confirmatory testing as part of an integrated diagnostic approach.Past attempts to develop a chromosomal real-time PCR assay have failed due to the close genetic relationship of Bacillus species. B. anthracis, Bacillus cereus, and Bacillus thuringiensis have very little variability and are genetically indistinguishable by multilocus enzyme electrophoresis (10). Recent work by repetitive PCR has shown that the previously listed species of Bacillus, as well as Bacillus mycoides, Bacillus pseudomycoides, and Bacillus weihenstephanensis, do have some genetic differences (3). Real-time PCR assays based on the chromosomal rpoB and gyrA genes of B. anthracis have been developed (5, 13, 25). However, these assays are based on single-nucleotide differences...
The foot-and-mouth disease virus (FMDV) afflicts livestock in more than 80 countries, limiting food production and global trade. Production of foot-and-mouth disease (FMD) vaccines requires cytosolic expression of the FMDV 3C protease to cleave the P1 polyprotein into mature capsid proteins, but the FMDV 3C protease is toxic to host cells. To identify less-toxic isoforms of the FMDV 3C protease, we screened 3C mutants for increased transgene output in comparison to wild-type 3C using a Gaussia luciferase reporter system. The novel point mutation 3C(L127P) increased yields of recombinant FMDV subunit proteins in mammalian and bacterial cells expressing P1-3C transgenes and retained the ability to process P1 polyproteins from multiple FMDV serotypes. The 3C(L127P) mutant produced crystalline arrays of FMDV-like particles in mammalian and bacterial cells, potentially providing a practical method of rapid, inexpensive FMD vaccine production in bacteria.IMPORTANCE The mutant FMDV 3C protease L127P significantly increased yields of recombinant FMDV subunit antigens and produced virus-like particles in mammalian and bacterial cells. The L127P mutation represents a novel advancement for economical FMD vaccine production.
Denaturing HPLC (DHPLC) is used in a wide variety of genetic applications. Here we introduce a new application for this technique, the identification of bacteria. We combined the capability of DHPLC to detect sequence variation with the principles of rRNA genotyping analysis to develop a high-throughput method of identifying microorganisms. Thirty-nine bacterial species from a broad spectrum of genera were tested to determine if DHPLC could be usedfor identification. Most (36 of 39) species of bacteria had a unique peak profile that could be used as a molecular fingerprint. Furthermore, a blind panel of 65 different bacterial isolates was analyzed to demonstrate the diagnostic capability of this method to specifically identify Yersinia pestis and Bacillus anthracis. All the Y. pestis samples (10 of 10) and the majority of B. anthracis samples (12 of 14) were correctly identified. The procedure had an overall specificity of 100%, overall sensitivity of 91.7%, and a predictive value of 96.9%. The data suggest that DHPLC of products spanning regions of genetic variability will be a useful application for bacterial identification.
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