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JMD 2006, Vol. 8, No. 1
Copyright © 2006 American Society for Investigative Pathology & Association for Molecular Pathology

Multiplexed Detection of Anthrax-Related Toxin Genes

Michael J. Moser^*, Deanna R. Christensen, David Norwood and James R. Prudent^*

From the Eragen Biosciences, Inc., * Madison, Wisconsin; and the Diagnostic Systems Division, U.S. Army Medical Research Institute of Infectious Diseases, Fort Detrick, Maryland

	Abstract

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Simultaneous analysis of three targets in three colors on any real-time polymerase chain reaction (PCR) instrument would increase the flexibility of real-time PCR. For the detection of Bacillus strains that can cause inhalation anthrax-related illness, this ability would be valuable because two plasmids confer virulence, and internal positive controls are needed to monitor the testing in cases lacking target-specific signals. Using a real-time PCR platform called MultiCode-RTx, multiple assays were developed that specifically monitor the presence of Bacillus anthracis-specific virulence plasmid-associated genes. In particular for use on LightCycler-1, two triplex RTx systems demonstrated high sensitivity with limits of detection nearing single-copy levels for both plasmids. Specificity was established using a combination of Ct values and correct amplicon melting temperatures. All reactions were further verified by detection of an internal positive control. For these two triplex RTx assays, the analytical detection limit was one to nine plasmid copy equivalents, 100% analytical specificity with a 95% confidence interval (CI) of 9%, and 100% analytical sensitivity with a CI of 2%. Although further testing using clinical or environmental samples will be required to assess diagnostic sensitivity and specificity, the RTx platform achieves similar results to those of probe-based real-time systems.

	Introduction

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Traditionally, Bacillus anthracis has been distinguished from other members of the Bacillus cereus group by time-consuming techniques such as colony morphology, penicillin susceptibility, -phage susceptibility, lack of hemolysis, and motility.¹ These methods are giving way to more rapid and quantifiable nucleic acid-based assays. Since the publication of the polymerase chain reaction (PCR) in 1985, applications involving this technology have revolutionized molecular medicine.² More recently, real-time PCR is becoming a preferred approach. This is mainly due to the intrinsic benefits of real-time PCR such as quick amplification and detection of target nucleic acids, quantitative accuracy, single-copy sensitivity, and a high level of specificity. Additionally, real-time PCR can be multiplexed to allow multiple target analysis in a single reaction. In the case of anthrax toxin gene detection, multiplexing is clearly beneficial because there are two virulence plasmids (pX01 and pX02) required for full virulence.

In a recent study by Hoffmaster et al,³ high-coverage draft genome sequence of a B. cereus isolate (G9241) revealed the presence of a circular plasmid named pBCX01 with 99.6% similarity with the B. anthracis toxin-encoding plasmid pX01. In addition, this isolate was found to be 100% lethal in mice with symptoms similar to inhalation anthrax. The presence of a plasmid in a strain of B. cereus with a 99.6% homology to a toxin-encoding plasmid found in B. anthracis indicates that genetic diagnosis is more complicated than once thought.³ Genes specifically associated with inhalation anthrax are located on two plasmids, pX01 and pX02.^{4, 5, 6} The 182-kb pX01 plasmid harbors the structural genes for the anthrax toxin proteins (cya [edema factor], lef [lethal factor], and pagA [protective antigen]), as well as two trans-acting regulatory genes (atxA and pagR). The 96-kb pX02 plasmid carries three genes required for capsule synthesis (capB, capC, and capA), a gene associated with capsule degradation (dep), and a trans-acting regulatory gene (acpA). Another recent study by Pannucci et al⁷ showed a high degree of sequence conservation between plasmid pX01 and the chromosome of some members of the B. cereus group, with several strains showing 80 to 98% homology. Therefore, a simplified multiplexed chemistry that specifically detects these plasmids or genes associated with these plasmids may prove to be as or more important than identification of the organism itself.

To this end, we developed two triplex assays using the MultiCode-RTx platform. MultiCode-RTx uses an expanded genetic base pair constructed from 2'-deoxy-5-methyl-isocytidine (iC) and 2'-deoxy-isoguanosine (iG). In natural DNA, two complementary strands are joined by a sequence of Watson-Crick base pairs using the four standard nucleotides A, G, C, and T. However, the DNA alphabet need not be limited to the four standard nucleotides known in nature.^{8, 9} In fact, expanded nucleotide pairs have been chemically produced. In particular, the chemistries to produce phosphoramidite and triphosphate reagents of iC and iG have been optimized and are now commercially available. We previously reported this new chemistry (MultiCode-RTx) that uses iC and iG to incorporate site-specifically a quencher in close proximity to a fluorescent molecule during PCR¹⁰ (Figure 1) . Before running MultiCode-RTx, target-specific forward PCR primers carrying single iC bases near distinct 5' fluorescent reporters and standard reverse primers are constructed using standard oligonucleotide chemical synthesis. Using a commercially available reaction mix containing iGTP-dabcyl, iC directs specific enzymatic incorporation of the iGTP-dabcyl in close proximity to each fluorophore. This incorporation reduces the fluorescence of reporters attached to the extended primers and is monitored using standard real-time PCR instrumentation. As the reaction proceeds, the instrument collects data (each target is analyzed using a distinct fluorophore and data collected in distinct channels). As more and more of the labeled primers are used up, the fluorescence signal specific for that primer goes down. As with all other real-time chemistries, standard curves constructed from Ct data from known concentrations of each target are used to determine concentrations within unknown samples. Additionally, the reaction can be analyzed for correct product formation after cycling is complete by melting the amplicons and determining their melting temperatures. This melt analysis can be used to verify that the anticipated amplicon was created.

View larger version (26K): [in this window] [in a new window]   Figure 1. MultiCode-RTx system schematic. Targets are amplified with a standard reverse primer and a forward primer that contains a single iC nucleotide and a fluorescent reporter. Amplification is performed in the presence of dabcyl-diGTP. Site-specific incorporation places the quencher in close proximity to the reporter, leading to a decrease in fluorescence that can be observed during real-time PCR.10

	Materials and Methods

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Bacterial Growth and Extraction
The bacterial strains analyzed in this study were acquired from the American Type Culture Collection (Manassas, VA), clinics, or entries from previous U.S. Army Medical Research Institute of Infectious Diseases (Fort Detrick, Frederick, MD) collections. Either Bactozol kits (Molecular Research Center, Inc., Cincinnati, OH) or QIAamp DNA minikits (Qiagen, Valencia, CA) were used to extract DNA. Bactozol kits were used in accordance with the manufacturer’s recommendations. QIAamp kits were used as follows. Cells were pelleted and resuspended in 180 µl of Dulbecco’s phosphate-buffered saline (GibcoBRL, Rockville, MD). Twenty microliters of proteinase K and 200 µl of AL buffer (Qiagen) were added and mixed by vortexing. The mixture was incubated for 60 minutes at 55°C to lyse the cells. After incubation, 210 µl of 100% ethanol was added to the sample. The mixture was subject to RNase digestion, transferred to a QIAamp spin column, and centrifuged at 6000 x g for 2 minutes. Next, 500 µl of AW1 buffer (Qiagen) was added to the column, and the sample was centrifuged for 2 minutes at 6000 x g. After this centrifugation step, 500 µl of AW2 buffer (Qiagen) was added to the column, and the sample was centrifuged at 6000 x g for 2 minutes. Finally, 100 µl of AE buffer (Qiagen) preheated to 70°C was applied to the column, and the sample was centrifuged at 6000 x g for 1 minute to elute the DNA. The DNA concentration was determined by measuring the absorption of each sample at 260 nm with a DU series 7500 spectrometer (Beckman Instruments, Fullerton, CA).

Primers
All primer designations, sequence make-up, design software implemented, and concentrations used can be found in Table 1 . Primer design packages used for this study were Primer Express (Applied Biosystems, Foster City, CA), Primer3,¹¹ and Visual OMP (DNA Software, Inc., Ann Arbor, MI). Primers AS005 through 008 were initially designed for Taqman use. Incorporation of the iC (X) nucleotides during synthesis was accomplished using standard coupling conditions.¹² All synthetic DNAs were quantitated by using extinction coefficients corresponding to the nucleotide makeup and examining initial stocks by OD 260. The DNAs were diluted to appropriate working concentrations in 10 mmol/L 3-(N-morpholino) propanesulfonic acid and 0.1 mmol/L ethylenediamine tetraacetic acid. BLASTN (http://www.ncbi.nlm.nih.gov/BLAST/) searches were performed for all primers and probes to eliminate priming to sequences other than those specified. All oligonucleotides were manufactured and purified by IDT (Coralville, IA). Both cya- and pagA-specific primer pair sets have a 100% match to B. cereus isolate G9241 pBCX01 plasmid DNA.³ The capB primer pairs are not complementary to any known sequence within the G9241 isolate.

Color Compensation
Color compensation is required for multicolor analysis on the LightCycler-1 instrument. We found that a single compensation file could be used to correct data sets acquired from multiple instruments. This is performed by analyzing the contribution of each single type of labeled DNA oligonucleotide to the signal obtained in each of the three detection channels of the LightCycler-1. The fluorophore set (6-carboxyfluorescein [FAM], hexachlorofluorescein [HEX], and cyanine 5 [Cy5]) that we used is not used by the standard color compensation reagents supplied by the instrument manufacturer. To compensate our data, we used solutions of oligonucleotides labeled with these dyes in 1x ISOlution 1147 without enzyme at the following concentrations: 300 nmol/L FAM, 1000 nmol/L HEX, and 1000 nmol/L Cy5. The instrument manufacturers compensation instructions were then followed to obtain compensation data capable of correcting for the spectral properties of our dye set.

Testing Parameters
All developed assays included the detection of an IPC (DM155) that was added at a level of 1000 copies per reaction and detected with primers 1139 and 1140. The fluorescence change of IPC reaction was monitored in the F3 channel (690–730 nm) of the LightCycler-1 instrument. Performance of the IPC reaction was analyzed by determining the mean Ct, SD, and percent coefficient of variation (%CV) for 218 total reactions each for both of the final triplex assays.

Synthetic oligonucleotide targets corresponding to the anthrax toxin-specific plasmid-associated gene targets were used to develop our assays. Standard curves (Ct versus copy number) were constructed from runs using 10-fold dilution series of these synthetic targets from 3 to 3 x 10⁵ copies per reaction. Analytical specificity (true negatives/true negatives plus false positives) and sensitivity testing (true positives/true positive plus false negatives) was conducted using 100 pg of total extracted DNA from 38 strains of B. anthracis, 34 strains of B. cereus, 13 strains of Bacillus thuringiensis, and 1 strain each of 4 other Bacillus sp., as well as a cross-reactivity panel consisting of 72 different strains of other bacterial species (supplemental table at http://jmd.amjpathol.org/). Some B. anthracis strains contained copies of only one of the two anthrax toxin-specific plasmids. Each 32-capillary LightCycler-1 run included at least one reaction in which a positive control of 1 pg of extracted B. anthracis Ames DNA was added and at least one reaction in which no target was added. The analytical limit of detection and limit of quantitation were determined by analyzing (in duplicate) serial 10-fold dilutions of extracted DNA from the Ames strain of B. anthracis starting at 1 pg and ending at 1 fg.

Analysis Software
Commercially available real-time thermal cyclers use software designed to analyze reactions in which fluorescence increases with PCR product accumulation. To analyze decreasing fluorescence results, analysis software was developed that imports RTx raw data and performs cycle threshold and melt curve analyses. Raw F1, F2, and F3 component fluorescence data for both amplification and melt programs were exported from the LightCycler-1 Analysis software (Version 5.32) as text files and analyzed with EraGen Real-time Run Importer and Analysis Desktop v0.9.8 (EraGen).

	Results

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Initial Assay Development
Initial studies focused on four duplex assays. Each duplex assay contained one set of primers specific to a plasmid target with the other primer set specific to the IPC. Two assays were specific to plasmid pXO1, whereas the other two were specific to plasmid pXO2. The two assays specific to pXO1 targeted two sequences found in the capB gene region using primer pairs 1141/1142 or 007/008. The two assays specific to pX02 targeted either cya using primer pair 1143/1144 or pagA using primer pairs 005/006. Standard curves (log copy number versus Ct) constructed from assays using a series of synthetic target dilutions were linear down to three copies for all duplexed systems (data not shown). With more than 100 reactions performed, 20 copies of synthetic DNA matching the correct gene target regions were detected 100% of the time.

Because we set out to develop assays that could simultaneously detect both plasmids, we combined the primer sets from the duplex assays to create two triplex assays, pagA:capB:IPC and cya:capB:IPC, using primer sets 005 to 008 and 1141 to 1144, respectively. After the cycling parameters were optimized using synthetic targets, we tested their analytical specificity using the DNA extracted from our panel of organisms (supplemental table at http://jmd.amjpathol.org/). Well-characterized strains from the U.S. Army Medical Research Institute of Infectious Diseases repository were used for this study. Strain plasmid profile analysis included historical PCR analysis for multiple targets with a variety of real-time and standard PCR primers. In addition, the strains were characterized for capsule and protective antigen production. When tested samples contained DNA extracted from organisms other than B. anthracis, which should not have contained either plasmid, we observed product formation in the channels specific to the pagA and capB primer sets. When the products were melted, the unidentified products differed in melting temperature (T_m) from the positive controls and suggested template independent amplification. We then decided to redesign the assays to eliminate these artifacts.

Optimized Assay Development
Because the approach of mixing primer sets from separate assays was unsuccessful, we decided to construct new assays using new multiplex primer design software called Visual OMP. Because the cya primer set 1143/1144 was sensitive down to the single-copy level and did not cross-react with the other panel strains tested (data not shown), we decided to incorporate the set into one of the new assays. Visual OMP design parameters for both assays also included the IPC primer set. The new designs obtained, pagA:capB:IPC (containing primers 1323, 1324, 698, and 699) and cya:capB:IPC (containing primers 1143, 1144, 698, and 699), demonstrated similar limits of detection yet a noticeable improvement in sensitivity and specificity over the previously developed triplex assays. Like the previous triplexes, standard curves for the new systems were linear down to three copies with R² values greater than 0.99 (Figure 2) .

View larger version (25K): [in this window] [in a new window]   Figure 2. Real-time PCR detection and linear standard curve analysis of anthrax-related toxin genes. The two triplex MultiCode-RTx systems designed using Visual OMP, pagA:capB:IPC (A, pagA; B, capB) and cya:capB:IPC (C, cya; D, capB), were tested for linearity for both corresponding synthetic targets using 10-fold dilution series from 3 to 3 x 105 copies in duplicate on different days. Top panels show the decrease in fluorescence as relative fluorescence units (RFU) versus PCR cycles for all samples as they appear during the real time PCR reactions. As the fluorescence decrease passes the cycle threshold (Ct) line, a cycle number is tabulated and used to generate standard curves. Reactions containing larger target copy numbers yield a detectable decrease in RFU in fewer rounds of PCR corresponding to smaller Ct values. Bottom panels show linear curve analyses of log copy number versus Ct with best fit equation and R2 values. Internal positive control is not shown.

View larger version (33K): [in this window] [in a new window]   Figure 3. Limit of detection (LOD) for B. anthracis Ames genomic DNA. Representative data determining LOD using 10-fold dilution series from 1 pg to 1 fg of B. anthracis Ames total genomic DNA in duplicate. A: Real-time PCR data of decreasing relative fluorescence units (RFU) versus PCR cycle number. B: Postamplification thermal melt analysis of PCR products as the negative first derivative of RFU with respect to temperature (–d(RFU)/dT) versus temperature in °C. Data are from the cya:capB:IPC multiplex. LOD for cya primer set was 10 fg or 2 copies.

View larger version (30K): [in this window] [in a new window]   Figure 4. Detection of nonspecific amplification by Tm. For both A and B, the top amplification curves show real-time PCR data in relative fluorescence units (RFU) versus PCR cycle number, and the bottom panels show postamplification melt data as the negative first derivative of RFU with respect to temperature (–d(RFU)/dT) versus temperature in °C. A representative data set using a series of unrelated organisms along with 1 pg of Ames DNA control was amplified by the pagA:capB:IPC triplex primer set. A: Real-time and amplicon melt data from the pagA read in F1 channel. B: Data from capB read in F2 channel. The Salmonella choleraesius 9150 sample (*) amplified weakly in the F1 channel with a Ct of 42.2 compared with 34.4 for the Ames control (+). The F1 Melt Tm for the S. choleraesius amplicon was significantly different at 76.0°C compared with 79.3°C for the control (A, bottom), indicating that the S. choleraesius amplification product observed during real-time PCR was nonspecific. Triplicate re-testing of the S. choleraesius sample gave no detectable amplification (data not shown).

	Discussion

Top Abstract Introduction Materials and Methods Results Discussion References

 
Since 2001, when letters containing highly processed anthrax spores from the Ames strain of B. anthracis were found addressed to members of Congress and the media, public health diagnostic labs around the United States have become equipped with real-time PCR instruments and associated testing kits used to assay for the presence of anthrax. Real-time PCR has been chosen as the prime screening method for rapid identification because of its intrinsic benefits such as enhanced sensitivity and shortened analytical turnaround times when compared with the more standard culturing techniques.

The two MultiCode-RTx triplex designs presented in this study may provide an alternative to the single-plex anthrax-specific assays now used at many public health labs. Clinical studies are required to validate our systems for direct detection of anthrax toxin-specific plasmid-associated genes in human specimens. These studies may be difficult in view of the very low incidence of human anthrax infections. Yet presuming that these assays can be applied directly to human specimens or environmental testing, the specificity and sensitivity demonstrated analytically here should increase the level of accuracy to that obtained using the current single-plex assays. The final RTx triplex systems developed reliably detected 10 to 100 fg of total B. anthracis-extracted DNA. These amounts translated into a copy number limit of detection of one to nine anthrax toxin-specific plasmids. Although the exact number of virulence plasmids per B. anthracis cell can vary (as many as 243 copies of pX01 and 32 copies of pX02 per cell can exist), typically more than one copy of each per cell exists.^{13, 14} This fact would further improve the limit of detection of B. anthracis cells. Analytical specificity and sensitivity were comparable with reported single-plex real-time assays.^{4, 15}

The data presented also show for the first time simultaneous quantitative detection of three independent targets using three colors on the LightCycler-1. Previous usage of three-color detection on the LightCycler was used for genotyping via melt analysis.¹⁶ Unlike this multicolor system and many other real-time PCR chemistries, RTx does not use probes.^{17, 18, 19} There are perceived benefits to using probes in PCR real-time detection, with the most important being specificity. Yet, probe-based systems are clearly more difficult to design and are complicated by the inherent fact that single-stranded DNA targets form intramolecular structures that interfere with probe binding.²⁰ Many primer design software programs have been developed to compensate for this by focusing on the probe region and probe design, while relaxing primer restraints. When proper primer design software is used, we do not believe probes are needed for specificity, as our data demonstrate. There are other real-time PCR technologies that do not use probes.^{21, 22, 23} Compared with these systems, RTx does not require incorporation of hairpins in the primer design nor does it require special base sequence make-up near the 3' ends. This allows for easy use of previously designed primer pairs. The RTx technology also allows multiplexing to assay multiple targets or to include internal controls. Real-time multiplexing is not an option with SYBR Green, although postreaction melt analysis multiplexing can be implemented.²⁴ The current availability of RTx reagents and Visual OMP design software should allow others to compare multiplexed probe-based systems with the RTx probe-free system.

Finally for bioweapon detection, the use of the LightCycler-1 instrument is important because it is essentially the same instrument as the R.A.P.I.D. For this reason, our successful multiplex results using the LightCycler-1 suggest that the RTx system would work equally well on the R.A.P.I.D. system. This device was recently chosen by the U.S. Army Space and Missile Defense Command Joint Biological Agent Identification and Diagnostic System for biothreat sample processing. The R.A.P.I.D. is a specialty instrument for military field hospitals, first responders, and use in other rough environments. The ability to test for multiple targets and internal control targets simultaneously should allow increased throughput and more consistent and controllable results.

We have demonstrated a simple closed-tube real-time PCR method to specifically detect genes associated with anthrax. The methodology involves the use of an expanded genetic alphabet to site-specifically incorporate a reporter into an amplification product. This method has several benefits such as rapid development due to ease of design, postreaction melt analysis, multiplex capability, large and consistent change in fluorescence output, long-term storage (no probe breakdown possible), and the ability to confirm the reactions by internal controls. The use of expanded base methodology is not limited to PCR.^{25, 26, 27} There are other detection methods that could benefit from this chemistry such as oligo ligation assay, restriction fragment length polymorphism, single-stranded conformational polymorphism, or molecular beacons. With such a fundamental paradigm shift, we envision that additional base pairs will change the way scientists build new testing systems.

	Acknowledgments

 
We thank Christine Larsen for assistance with assay development and Giancarlo Espinoza for help with graphics preparation and design.

	Footnotes

 
Address reprint requests to James R. Prudent, Eragen Biosciences, Inc., 918 Deming Way, Madison, WI, 53717-1944. E-mail: jprudent{at}eragen.com

Supported by Small Business Innovation Research grant AI052898 from the National Institute of Health and the National Institute of Allergy and Infectious Disease. U.S. Army Medical Research Institute of Infectious Diseases was supported by the U.S. Army Medical Research and Materiel Command (research plan 04-4-8I-015).

Supplemental material for this article can be found on http://jmd.amjpathol.org.

Accepted for publication August 31, 2005.

	References

Top Abstract Introduction Materials and Methods Results Discussion References

 

1. Logan NA, Carman JA, Melling J, Berkeley RC: Identification of Bacillus anthracis by API tests. J Med Microbiol 1985, 20:75-85[Abstract/Free Full Text]
2. Saiki RK, Scharf S, Faloona F, Mullis KB, Horn GT, Erlich HA, Arnheim N: Enzymatic amplification of beta-globin genomic sequences and restriction site analysis for diagnosis of sickle cell anemia. Science 1985, 230:1350-1354[Abstract/Free Full Text]
3. Hoffmaster AR, Ravel J, Rasko DA, Chapman GD, Chute MD, Marston CK, De BK, Sacchi CT, Fitzgerald C, Mayer LW, Maiden MC, Priest FG, Barker M, Jiang L, Cer RZ, Rilstone J, Peterson SN, Weyant RS, Galloway DR, Read TD, Popovic T, Fraser CM: Identification of anthrax toxin genes in a Bacillus cereus associated with an illness resembling inhalation anthrax. Proc Natl Acad Sci USA 2004, 101:8449-8454[Abstract/Free Full Text]
4. Bell CA, Uhl JR, Hadfield TL, David JC, Meyer RF, Smith TF, Cockerill FR, III: Detection of Bacillus anthracis DNA by LightCycler PCR. J Clin Microbiol 2002, 40:2897-2902[Abstract/Free Full Text]
5. Beyer W, Glockner P, Otto J, Bohm R: A nested PCR method for the detection of Bacillus anthracis in environmental samples collected from former tannery sites. Microbiol Res 1995, 150:179-186[Medline]
6. Reif TC, Johns M, Pillai SD, Carl M: Identification of capsule-forming Bacillus anthracis spores with the PCR and a novel dual-probe hybridization format. Appl Environ Microbiol 1994, 60:1622-1625[Abstract/Free Full Text]
7. Pannucci J, Okinaka RT, Sabin R, Kuske CR: Bacillus anthracis pXO1 plasmid sequence conservation among closely related bacterial species. J Bacteriol 2002, 184:134-141[Abstract/Free Full Text]
8. Piccirilli JA, Krauch T, Moroney SE, Benner SA: Enzymatic incorporation of a new base pair into DNA and RNA extends the genetic alphabet. Nature 1990, 343:33-37[CrossRef][Medline]
9. Switzer CY, Moroney SE, Benner SA: Enzymatic incorporation of a new base pair into DNA and RNA. J Am Chem Soc 1989, 111:8322-8323[CrossRef]
10. Sherrill CB, Marshall DJ, Moser MJ, Larsen CA, Daude-Snow L, Prudent JR: Nucleic acid analysis using an expanded genetic alphabet to quench fluorescence. J Am Chem Soc 2004, 126:4550-4556[CrossRef][Medline]
11. Rozen S, Skaletsky H: Primer3 on the WWW for general users and for biologist programmers. Methods Mol Biol 2000, 132:365-386[Medline]
12. Andrus A, Wright P, Wang J, Mullah B, Baier J, Mason J, Kaufman G: Synthesis and purification in a single column on a high-throughput automated oligonucleotide production system. Nucleic Acids Symp Ser 1995, :183-184
13. Coker PR, Smith KL, Fellows PF, Rybachuck G, Kousoulas KG, Hugh-Jones ME: Bacillus anthracis virulence in guinea pigs vaccinated with anthrax vaccine adsorbed is linked to plasmid quantities and clonality. J Clin Microbiol 2003, 41:1212-1218[Abstract/Free Full Text]
14. Read TD, Salzberg SL, Pop M, Shumway M, Umayam L, Jiang L, Holtzapple E, Busch JD, Smith KL, Schupp JM, Solomon D, Keim P, Fraser CM: Comparative genome sequencing for discovery of novel polymorphisms in Bacillus anthracis. Science 2002, 296:2028-2033[Abstract/Free Full Text]
15. Ellerbrok H, Nattermann H, Ozel M, Beutin L, Appel B, Pauli G: Rapid and sensitive identification of pathogenic and apathogenic Bacillus anthracis by real-time PCR. FEMS Microbiol Lett 2002, 214:51-59[CrossRef][Medline]
16. Schutz E, von Ahsen N, Oellerich M: Genotyping of eight thiopurine methyltransferase mutations: three-color multiplexing, "two-color/shared" anchor, and fluorescence-quenching hybridization probe assays based on thermodynamic nearest-neighbor probe design. Clin Chem 2000, 46:1728-1737[Abstract/Free Full Text]
17. Tyagi S, Kramer FR: Molecular beacons: probes that fluoresce upon hybridization. Nat Biotechnol 1996, 14:303-308[CrossRef][Medline]
18. Livak KJ, Flood SJ, Marmaro J, Giusti W, Deetz K: Oligonucleotides with fluorescent dyes at opposite ends provide a quenched probe system useful for detecting PCR product and nucleic acid hybridization. PCR Methods Appl 1995, 4:357-362[Medline]
19. Holland PM, Abramson RD, Watson R, Gelfand DH: Detection of specific polymerase chain reaction product by utilizing the 5' 3' exonuclease activity of Thermus aquaticus DNA polymerase. Proc Natl Acad Sci USA 1991, 88:7276-7280[Abstract/Free Full Text]
20. Dong F, Allawi HT, Prudent JR, Anderson T, Neri BP, Lyamichev VI: Secondary structure prediction and structure-specific sequence analysis of single-stranded DNA. Nucleic Acids Res 2001, 29:3248-3257[Abstract/Free Full Text]
21. Nazarenko IA, Bhatnagar SK, Hohman RJ: A closed tube format for amplification and detection of DNA based on energy transfer. Nucleic Acids Res 1997, 25:2516-2521[Abstract/Free Full Text]
22. Winn-Deen ES: Direct fluorescence detection of allele-specific PCR products using novel energy-transfer labeled primers. Mol Diagn 1998, 3:217-221[CrossRef][Medline]
23. Whitcombe D, Theaker J, Guy SP, Brown T, Little S: Detection of PCR products using self-probing amplicons and fluorescence. Nat Biotechnol 1999, 17:804-807[CrossRef][Medline]
24. Wittwer CT, Ririe KM, Andrew RV, David DA, Gundry RA, Balis UJ: The LightCycler: a microvolume multisample fluorimeter with rapid temperature control. Biotechniques 1997, 22:176-181[Medline]
25. Collins ML, Irvine B, Tyner D, Fine E, Zayati C, Chang C, Horn T, Ahle D, Detmer J, Shen LP, Kolberg J, Bushnell S, Urdea MS, Ho DD: A branched DNA signal amplification assay for quantification of nucleic acid targets below 100 molecules/ml. Nucleic Acids Res 1997, 25:2979-2984[Abstract/Free Full Text]
26. Moser MJ, Prudent JR: Enzymatic repair of an expanded genetic information system. Nucleic Acids Res 2003, 31:5048-5053[Abstract/Free Full Text]
27. Johnson SC, Marshall DJ, Harms G, Miller CM, Sherrill CB, Beaty EL, Lederer SA, Roesch EB, Madsen G, Hoffman GL, Laessig RH, Kopish GJ, Baker MW, Benner SA, Farrell PM, Prudent JR: Multiplexed genetic analysis using an expanded genetic alphabet. Clin Chem 2004, 50:2019-2027[Abstract/Free Full Text]

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