Rajendra J. Redkar

Utilization of the rpoB Gene as a Specific Chromosomal Marker for Real-Time PCR Detection of Bacillus anthracis

ABSTRACT The potential use of Bacillus anthracis as a weapon of mass destruction poses a threat to humans, domesticated animals, and wildlife and necessitates the need for a rapid and highly specific detection assay. We have developed a real-time PCR-based assay for the specific detection of B. anthracis by taking advantage of the unique nucleotide sequence of the B. anthracis rpoBgene. Variable region 1 of the rpoB gene was sequenced from 36 Bacillus strains, including 16 B. anthracisstrains and 20 other related bacilli, and four nucleotides specific forB. anthracis were identified. PCR primers were selected so that two B. anthracis-specific nucleotides were at their 3′ ends, whereas the remaining bases were specific to the probe region. This format permitted the PCR reactions to be performed on a LightCycler via fluorescence resonance energy transfer (FRET). The assay was found to be specific for 144 B. anthracis strains from different geographical locations and did not cross-react with other related bacilli (175 strains), with the exception of one strain. The PCR assay can be performed on isolated DNA as well as crude vegetative cell lysates in less than 1 h. Therefore, therpoB-FRET assay could be used as a new chromosomal marker for rapid detection of B. anthracis.

Use of Long-Range Repetitive Element Polymorphism-PCR To Differentiate Bacillus anthracis Strains

ABSTRACT The genome of Bacillus anthracis is extremely monomorphic, and thus individual strains have often proven to be recalcitrant to differentiation at the molecular level. Long-range repetitive element polymorphism-PCR (LR REP-PCR) was used to differentiate various B. anthracis strains. A single PCR primer derived from a repetitive DNA element was able to amplify variable segments of a bacterial genome as large as 10 kb. We were able to characterize five genetically distinct groups by examining 105B. anthracis strains of diverse geographical origins. AllB. anthracis strains produced fingerprints comprising seven to eight bands, referred to as “skeleton” bands, while one to three “diagnostic” bands differentiated between B. anthracisstrains. LR REP-PCR fingerprints of B. anthracis strains showed very little in common with those of other closely related species such as B. cereus, B. thuringiensis, and B. mycoides, suggesting relative heterogeneity among the non-B. anthracis strains. Fingerprints from transitional non-B. anthracis strains, which possessed the B. anthracis chromosomal marker Ba813, scarcely resembled those observed for any of the five distinct B. anthracis groups that we have identified. The LR REP-PCR method described in this report provides a simple means of differentiating B. anthracisstrains.

Rapid genotyping of Bacillus anthracis strains by real-time polymerase chain reaction.

Abstract: Rapid and accurate identification of Bacillus anthracis is critical for patient care as well as outbreak control. We have developed 3 separate PCR based assays using fluorescence resonance energy transfer (FRET) to detect the presence of pXO1, pXO2 plasmids and a chromosomal marker. A set of amplification primers and probes were used in each assay. The probes were ad jacently placed inside the primer sites and were 1‐bp apart. The upstream probe was labeled with fluorescein at the 3′ end, and the downstream probe had Cy5 attached at the 5′ end. The probes are included in the PCR reactions and hybridize with the PCR products as they are formed. Binding of probes to PCR products results in transfer of energy from fluorescein to Cy5, resulting in emission from Cy5. Increase in fluorescence, indicating amplification, was monitored in real time on a LightCycler™ LC24. Initial denaturation of target sequences was accomplished at 95°C for 1 min, followed by 28 cycles of denaturation at 95°C for 0 sec, annealing at 58°C for 15 sec, and elongation at 72°C for 5 sec. These assays are specific and can be performed on as little as 25 ng of total DNA or crude cell lysate a from fresh colony. It is thus possible to deter mine the genotype of B. anthracis strains in less than 1 hour.

Isolation of differentially expressed cDNA clones from salt-adaptedAspergillus nidulans

Differentially expressed cDNA clones were isolated from salt-adaptedAspergillus nidulans (FGSC #359). Poly (A)+ RNA from adapted mycelia was used to construct a λ Uni-ZAP cDNA library. The library was screened with mixed subtracted cDNA probes. Three-hundred and fifty-seven positive plaques were isolated in the primary screening. Sixty-two randomly selected plaques were purified and placed into eight different cross-hybridization groups. A representative cDNA from each group was used to study expression under unadapted, salt-adapted and salt-shock conditions. These clones, representing eight different genes, displayed enhanced expression under salt stress. Exploratory nucleotide sequencing was performed, and the predicted amino-acid sequence was compared with known gene sequences in the data-bank. Five of the cDNA clones were identified as a mitochondrial (mt) ATPase β subunit, a mt ATPase subunit 9, a mt transport protein, a ubiquitin-extension protein and a ribosomal protein. Three cDNA clones could not be identified due to lack of adequate homology with known sequences. These results suggest that at least five genes with known function in cellular processes like ATP generation and protein synthesis, and three other genes of unknown identity, are greatly induced in salt-adapted conditions.