Use of Single Nucleotide Polymorphisms in the plcR Gene for Specific Identification of Bacillus anthracis
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微生物临床杂志 2005年第4期
Department of Biological Sciences, Northern Arizona University, Flagstaff, AZ 86011-5640
The Translational Genomics Research Institute (TGen), 445 N. Fifth Street, Phoenix, AZ 85004
ABSTRACT
A TaqMan-minor groove binding assay designed around a nonsense mutation in the plcR gene was used to genotype Bacillus anthracis, B. cereus, and B. thuringiensis isolates. The assay differentiated B. anthracis from these genetic near-neighbors and determined that the nonsense mutation is ubiquitous across 89 globally and genetically diverse B. anthracis strains.
TEXT
The genetic similarities among the pathogenic, spore-forming soil bacteria Bacillus cereus, B. thuringiensis, and B. anthracis have resulted in the suggestion that they be considered members of the same species (3). Interestingly, these bacteria exhibit phenotypic differences and express virulence in diverse ways. B. cereus and B. thuringiensis are opportunistic pathogens in mammals due to the secretion of nonspecific virulence factors, such as hemolysins, the expression of which is regulated by the transcriptional activator PlcR (8). In B. anthracis, PlcR is inactivated due to a nonsense mutation in the plcR gene (1), and its virulence in mammals is attributed to the expression of specific toxins under the control of the AtxA regulator (2).
The nonsense mutation in the plcR gene of B. anthracis may represent an evolutionarily stable, species-specific marker. Research by Mignot et al. (8), in which a functional PlcR was expressed in B. anthracis, demonstrated that PlcR- and AtxA-controlled regulons were incompatible, as plcR expression interfered with sporulation in B. anthracis. Since sporulation is a critical component of the ecology of B. anthracis, the authors speculated that a functional PlcR is counterselected in this species. Recent sequence comparisons of the plcR genes of two phylogenetically distinct B. anthracis lineages revealed the same nonsense mutation in the plcR gene (9), providing additional evidence to support the species specificity of this mutation.
To initially test the utility of the nonsense mutation in plcR as a species-specific marker for B. anthracis, we examined the plcR gene fragments that surround the nonsense mutation in several Bacillus spp. The strains examined included nine genetically diverse B. anthracis strains, nine B. cereus strains, six B. thuringiensis strains, and one unidentified near-neighbor (TET 2b-3) (4). Sequences obtained either from GenBank or from sequencing efforts in our laboratory were compared using MegAlign (Fig. 1). The nonsense mutation was present in all nine of the B. anthracis sequences and was absent in the 16 near-neighbor sequences.
Based upon these sequences, we designed a TaqMan-minor groove binding (MGB) allelic discrimination assay around the nonsense mutation. The TaqMan-MGB probes were designed using Primer Express software (Applied Biosystems, Foster City, CA). One probe was designed to specifically hybridize to the B. anthracis sequence (5'-VIC-CAAAGCGCTTATTCGTATT-3'-MGB), and the other was designed to hybridize to the alternate allele (5'-FAM-AAAGCGCTTCTTCGTATT-3'-MGB) (Fig. 1 shows probe locations). Real-time PCRs were conducted in 10.0-μl reaction mixtures that contained 600 nM of both forward (5'-CCAATCAATGTCATACTATTAATTTGACAC-3') and reverse (5'-ATGCAAAAGCATTATACTTGGACAAT-3') primers (Fig. 1 shows primer locations), 250 nM of each probe, 1x Invitrogen Platinum qPCR SuperMix-UDG, and 1.0 μl of template. Thermal cycling was performed on an ABI 7900 HT sequence detection system (Applied Biosystems) under the following conditions: 50°C for 2 min, 95°C for 2 min, and 40 cycles of 95°C for 15 s and 60°C for 1 min.
To further evaluate the nonsense mutation in plcR as a species-specific marker for B. anthracis, we used the assay described above to genotype a collection of B. anthracis strains representing 89 unique genetic lineages (6). In addition, we genotyped 29 strains that were identified by amplified fragment length polymorphism analysis as genetic near-neighbors of B. anthracis (4) (Table 1 shows strain list). All of the B. anthracis isolates supported amplification and were shown to have the plcR nonsense mutation genotype (T allele). Not surprisingly, genetic near-neighbors that had mutations in the priming site either failed to exhibit amplification or amplified with lower efficiency relative to the four strains that had complete sequence identity to B. anthracis except for the nonsense mutation (Table 1; Fig. 1). Of the 29 near-neighbors, 16 failed to exhibit amplification and the remaining 13 exhibited the G allele genotype (Table 1). The presence of the G allele in 5 of the 16 isolates that failed to amplify in the assay was confirmed via sequencing with flanking primers (Fig. 1).
To test the limit of detection of the assay, we utilized a dilution series generated from DNAs from three diverse B. anthracis isolates (Ames [A0462], Kruger B1 [A0442], and Vollum [A0488]). DNA was quantified using a Pico Green assay, and template levels ranging from 100 pg to 10.0 fg were used in the plcR TaqMan assay. The assay reliably detected and genotyped Bacillus anthracis DNA template at levels as low as 100 fg, with 10-fg samples exhibiting sporadic amplification (Fig. 2).
Our data provide further evidence that the nonsense mutation in the plcR gene of B. anthracis is an evolutionarily stable, species-specific marker. Although additional genetic changes, such as deletions, could produce a nonfunctional PlcR in B. anthracis and potentially cause false-negative results in our assay, this was not observed. The presence of this mutation in the 89 genetically diverse B. anthracis lineages examined here, as well as the known genetic homogeneity of the species (5), limits the likelihood of alternate genetic mechanisms for plcR inactivation in B. anthracis. The recent findings of Slamti et al. (9), which demonstrated that this specific plcR nonsense mutation was not responsible for the nonhemolytic properties of B. cereus and B. thuringiensis strains, further support the concept that this nonsense mutation is a defining or canonical single nucleotide polymorphism (7) for B. anthracis.
The real-time assay presented here represents a potentially valuable diagnostic tool in the event of a future bioterrorist attack. From a biodefense perspective, diagnostic assays allowing rapid and specific identification of B. anthracis are critical to initiate appropriate first-response actions, such as remediation measures and prophylactic therapies. As our assay targets a well-characterized, biologically relevant single nucleotide polymorphism, it limits the likelihood of false-negative or -positive results, which can lead to misallocation of resources during an attack scenario. Furthermore, this assay is amenable to high-throughput real-time PCR platforms that are currently used in homeland defense initiatives, such as BioWatch.
In summary, our results indicate that the plcR nonsense mutation is ubiquitous in globally and genetically diverse B. anthracis isolates and, thereby, represents an excellent target for diagnostic assays. Future studies will involve genotyping more extensive collections of B. anthracis and genetic near-neighbors, as well as the optimization and validation of this assay for the specific, low-level detection of B. anthracis in complex environmental samples.
ACKNOWLEDGMENTS
This work was supported by grants from the National Institutes of Health, the Department of Homeland Security, and the Cowden Endowment at Northern Arizona University.
We thank Jeff Henrickson for his technical assistance; Jason Farlow for his thoughtful review of the manuscript; and Paul Jackson, Karen Hill, and their colleagues at Los Alamos National Laboratory for providing the near-neighbor strains.
W.R.E. and M.N.V. contributed equally to the research described in this paper.
REFERENCES
Agaisse, H., M. Gominet, O. A. kstad, A. Kolst, and D. Lereclus. 1999. PlcR is a pleiotropic regulator of extracellular virulence factor gene expression in Bacillus thuringiensis. Mol. Microbiol. 32:1043-1053.
Guignot, J., M. Mock, and A. Fouet. 1997. AtxA activates the transcription of genes harbored by both Bacillus anthracis virulence plasmids. FEMS Microbiol. Lett. 147:203-207.
Helgason, E., O. A. kstad, D. A. Caugant, H. A. Johansen, A. Fouet, M. Mock, I. Hegna, and A. Kolst. 2000. Bacillus anthracis, Bacillus cereus, and Bacillus thuringiensis—one species on the basis of genetic evidence. Appl. Environ. Microbiol. 66:2627-2630.
Hill, K. K., L. O. Ticknor, R. T. Okinaka, M. Asay, H. Blair, K. A. Bliss, M. Laker, P. E. Pardington, A. P. Richardson, M. Tonks, D. J. Beecher, J. D. Kemp, A. Kolst, A. C. L. Wong, P. Keim, and P. J. Jackson. 2004. Fluorescent amplified fragment length polymorphism analysis of Bacillus anthracis, Bacillus cereus, and Bacillus thuringiensis isolates. Appl. Environ. Microbiol. 70:1068-1080.
Keim, P., A. Kalif, J. Schupp, K. Hill, S. E. Travis, K. Richmond, D. M. Adair, M. Hugh-Jones, C. Kuske, and P. Jackson. 1997. Molecular evolution and diversity in Bacillus anthracis as detected by amplified fragment length polymorphism markers. J. Bacteriol. 179:818-824.
Keim, P., L. B. Price, A. M. Klevytska, K. L. Smith, J. M. Schupp, R. Okinaka, P. J. Jackson, and M. E. Hugh-Jones. 2000. Multiple-locus variable-number tandem repeat analysis reveals genetic relationships within Bacillus anthracis. J. Bacteriol. 182:2928-2936.
Keim, P., M. N. Van Ert, T. Pearson, A. J. Vogler, L. Y. Huynh, and D. M. Wagner. 2004. Anthrax molecular epidemiology and forensics: using the appropriate marker for different evolutionary scales. Infect. Genet. Evol. 4:205-213.
Mignot, T., M. Mock, D. Robichon, A. Landier, D. Lereclus, and A. Fouet. 2001. The incompatibility between the PlcR- and AtxA-controlled regulons may have selected a nonsense mutation in Bacillus anthracis. Mol. Microbiol. 42:1189-1198.
Slamti, L., S. Perchat, M. Gominet, G. Vilas-Bas, A. Fouet, M. Mock, V. Sanchis, J. Chaufaux, M. Gohar, and D. Lereclus. 2004. Distinct mutations in PlcR explain why some strains of the Bacillus cereus group are nonhemolytic. J. Bacteriol. 186:3531-3538.(W. Ryan Easterday, Matthe)
The Translational Genomics Research Institute (TGen), 445 N. Fifth Street, Phoenix, AZ 85004
ABSTRACT
A TaqMan-minor groove binding assay designed around a nonsense mutation in the plcR gene was used to genotype Bacillus anthracis, B. cereus, and B. thuringiensis isolates. The assay differentiated B. anthracis from these genetic near-neighbors and determined that the nonsense mutation is ubiquitous across 89 globally and genetically diverse B. anthracis strains.
TEXT
The genetic similarities among the pathogenic, spore-forming soil bacteria Bacillus cereus, B. thuringiensis, and B. anthracis have resulted in the suggestion that they be considered members of the same species (3). Interestingly, these bacteria exhibit phenotypic differences and express virulence in diverse ways. B. cereus and B. thuringiensis are opportunistic pathogens in mammals due to the secretion of nonspecific virulence factors, such as hemolysins, the expression of which is regulated by the transcriptional activator PlcR (8). In B. anthracis, PlcR is inactivated due to a nonsense mutation in the plcR gene (1), and its virulence in mammals is attributed to the expression of specific toxins under the control of the AtxA regulator (2).
The nonsense mutation in the plcR gene of B. anthracis may represent an evolutionarily stable, species-specific marker. Research by Mignot et al. (8), in which a functional PlcR was expressed in B. anthracis, demonstrated that PlcR- and AtxA-controlled regulons were incompatible, as plcR expression interfered with sporulation in B. anthracis. Since sporulation is a critical component of the ecology of B. anthracis, the authors speculated that a functional PlcR is counterselected in this species. Recent sequence comparisons of the plcR genes of two phylogenetically distinct B. anthracis lineages revealed the same nonsense mutation in the plcR gene (9), providing additional evidence to support the species specificity of this mutation.
To initially test the utility of the nonsense mutation in plcR as a species-specific marker for B. anthracis, we examined the plcR gene fragments that surround the nonsense mutation in several Bacillus spp. The strains examined included nine genetically diverse B. anthracis strains, nine B. cereus strains, six B. thuringiensis strains, and one unidentified near-neighbor (TET 2b-3) (4). Sequences obtained either from GenBank or from sequencing efforts in our laboratory were compared using MegAlign (Fig. 1). The nonsense mutation was present in all nine of the B. anthracis sequences and was absent in the 16 near-neighbor sequences.
Based upon these sequences, we designed a TaqMan-minor groove binding (MGB) allelic discrimination assay around the nonsense mutation. The TaqMan-MGB probes were designed using Primer Express software (Applied Biosystems, Foster City, CA). One probe was designed to specifically hybridize to the B. anthracis sequence (5'-VIC-CAAAGCGCTTATTCGTATT-3'-MGB), and the other was designed to hybridize to the alternate allele (5'-FAM-AAAGCGCTTCTTCGTATT-3'-MGB) (Fig. 1 shows probe locations). Real-time PCRs were conducted in 10.0-μl reaction mixtures that contained 600 nM of both forward (5'-CCAATCAATGTCATACTATTAATTTGACAC-3') and reverse (5'-ATGCAAAAGCATTATACTTGGACAAT-3') primers (Fig. 1 shows primer locations), 250 nM of each probe, 1x Invitrogen Platinum qPCR SuperMix-UDG, and 1.0 μl of template. Thermal cycling was performed on an ABI 7900 HT sequence detection system (Applied Biosystems) under the following conditions: 50°C for 2 min, 95°C for 2 min, and 40 cycles of 95°C for 15 s and 60°C for 1 min.
To further evaluate the nonsense mutation in plcR as a species-specific marker for B. anthracis, we used the assay described above to genotype a collection of B. anthracis strains representing 89 unique genetic lineages (6). In addition, we genotyped 29 strains that were identified by amplified fragment length polymorphism analysis as genetic near-neighbors of B. anthracis (4) (Table 1 shows strain list). All of the B. anthracis isolates supported amplification and were shown to have the plcR nonsense mutation genotype (T allele). Not surprisingly, genetic near-neighbors that had mutations in the priming site either failed to exhibit amplification or amplified with lower efficiency relative to the four strains that had complete sequence identity to B. anthracis except for the nonsense mutation (Table 1; Fig. 1). Of the 29 near-neighbors, 16 failed to exhibit amplification and the remaining 13 exhibited the G allele genotype (Table 1). The presence of the G allele in 5 of the 16 isolates that failed to amplify in the assay was confirmed via sequencing with flanking primers (Fig. 1).
To test the limit of detection of the assay, we utilized a dilution series generated from DNAs from three diverse B. anthracis isolates (Ames [A0462], Kruger B1 [A0442], and Vollum [A0488]). DNA was quantified using a Pico Green assay, and template levels ranging from 100 pg to 10.0 fg were used in the plcR TaqMan assay. The assay reliably detected and genotyped Bacillus anthracis DNA template at levels as low as 100 fg, with 10-fg samples exhibiting sporadic amplification (Fig. 2).
Our data provide further evidence that the nonsense mutation in the plcR gene of B. anthracis is an evolutionarily stable, species-specific marker. Although additional genetic changes, such as deletions, could produce a nonfunctional PlcR in B. anthracis and potentially cause false-negative results in our assay, this was not observed. The presence of this mutation in the 89 genetically diverse B. anthracis lineages examined here, as well as the known genetic homogeneity of the species (5), limits the likelihood of alternate genetic mechanisms for plcR inactivation in B. anthracis. The recent findings of Slamti et al. (9), which demonstrated that this specific plcR nonsense mutation was not responsible for the nonhemolytic properties of B. cereus and B. thuringiensis strains, further support the concept that this nonsense mutation is a defining or canonical single nucleotide polymorphism (7) for B. anthracis.
The real-time assay presented here represents a potentially valuable diagnostic tool in the event of a future bioterrorist attack. From a biodefense perspective, diagnostic assays allowing rapid and specific identification of B. anthracis are critical to initiate appropriate first-response actions, such as remediation measures and prophylactic therapies. As our assay targets a well-characterized, biologically relevant single nucleotide polymorphism, it limits the likelihood of false-negative or -positive results, which can lead to misallocation of resources during an attack scenario. Furthermore, this assay is amenable to high-throughput real-time PCR platforms that are currently used in homeland defense initiatives, such as BioWatch.
In summary, our results indicate that the plcR nonsense mutation is ubiquitous in globally and genetically diverse B. anthracis isolates and, thereby, represents an excellent target for diagnostic assays. Future studies will involve genotyping more extensive collections of B. anthracis and genetic near-neighbors, as well as the optimization and validation of this assay for the specific, low-level detection of B. anthracis in complex environmental samples.
ACKNOWLEDGMENTS
This work was supported by grants from the National Institutes of Health, the Department of Homeland Security, and the Cowden Endowment at Northern Arizona University.
We thank Jeff Henrickson for his technical assistance; Jason Farlow for his thoughtful review of the manuscript; and Paul Jackson, Karen Hill, and their colleagues at Los Alamos National Laboratory for providing the near-neighbor strains.
W.R.E. and M.N.V. contributed equally to the research described in this paper.
REFERENCES
Agaisse, H., M. Gominet, O. A. kstad, A. Kolst, and D. Lereclus. 1999. PlcR is a pleiotropic regulator of extracellular virulence factor gene expression in Bacillus thuringiensis. Mol. Microbiol. 32:1043-1053.
Guignot, J., M. Mock, and A. Fouet. 1997. AtxA activates the transcription of genes harbored by both Bacillus anthracis virulence plasmids. FEMS Microbiol. Lett. 147:203-207.
Helgason, E., O. A. kstad, D. A. Caugant, H. A. Johansen, A. Fouet, M. Mock, I. Hegna, and A. Kolst. 2000. Bacillus anthracis, Bacillus cereus, and Bacillus thuringiensis—one species on the basis of genetic evidence. Appl. Environ. Microbiol. 66:2627-2630.
Hill, K. K., L. O. Ticknor, R. T. Okinaka, M. Asay, H. Blair, K. A. Bliss, M. Laker, P. E. Pardington, A. P. Richardson, M. Tonks, D. J. Beecher, J. D. Kemp, A. Kolst, A. C. L. Wong, P. Keim, and P. J. Jackson. 2004. Fluorescent amplified fragment length polymorphism analysis of Bacillus anthracis, Bacillus cereus, and Bacillus thuringiensis isolates. Appl. Environ. Microbiol. 70:1068-1080.
Keim, P., A. Kalif, J. Schupp, K. Hill, S. E. Travis, K. Richmond, D. M. Adair, M. Hugh-Jones, C. Kuske, and P. Jackson. 1997. Molecular evolution and diversity in Bacillus anthracis as detected by amplified fragment length polymorphism markers. J. Bacteriol. 179:818-824.
Keim, P., L. B. Price, A. M. Klevytska, K. L. Smith, J. M. Schupp, R. Okinaka, P. J. Jackson, and M. E. Hugh-Jones. 2000. Multiple-locus variable-number tandem repeat analysis reveals genetic relationships within Bacillus anthracis. J. Bacteriol. 182:2928-2936.
Keim, P., M. N. Van Ert, T. Pearson, A. J. Vogler, L. Y. Huynh, and D. M. Wagner. 2004. Anthrax molecular epidemiology and forensics: using the appropriate marker for different evolutionary scales. Infect. Genet. Evol. 4:205-213.
Mignot, T., M. Mock, D. Robichon, A. Landier, D. Lereclus, and A. Fouet. 2001. The incompatibility between the PlcR- and AtxA-controlled regulons may have selected a nonsense mutation in Bacillus anthracis. Mol. Microbiol. 42:1189-1198.
Slamti, L., S. Perchat, M. Gominet, G. Vilas-Bas, A. Fouet, M. Mock, V. Sanchis, J. Chaufaux, M. Gohar, and D. Lereclus. 2004. Distinct mutations in PlcR explain why some strains of the Bacillus cereus group are nonhemolytic. J. Bacteriol. 186:3531-3538.(W. Ryan Easterday, Matthe)