Multiplex quantitative PCR using self-quenched primers labeled with a single fluorophore

Multiplex quantitative PCR based on novel design of fluorescent primers is described. Fluorogenic primers are labeled with a single fluorophore on a base close to the 3′ end with no quencher required. A tail of 5–7 nt is added to the 5′ end of the primer to form a blunt-end hairpin when the primer is not incorporated into a PCR product. This design provides a low initial fluorescence of the primers that increases up to 8-fold upon formation of the PCR product. The hairpin oligonucleotides (ΔG from –1.6 to –5.8 kcal/mol) may be as efficient as linear primers and provide additional specificity to the PCR by preventing primer-dimers and mispriming. Multiple fluorogenic primers were designed by specialized software and used for real-time quantitation of c-myc and IL-4 cDNAs in the presence of reference genes such as β-actin, GAPDH and 18S rRNA. Targets of 10–10⁷ copies were detected with precision in PCR using FAM-labeled primers for variable genes and JOE-labeled primers for the reference genes. This method was also used to detect single nucleotide polymorphism of the human retinal degeneration gene by allele-specific PCR with end-point detection using a fluorescent plate reader or a UV-transilluminator. We conclude that fluorogenic mono-labeled primers are an efficient and cost-effective alternative to FRET-labeled oligonucleotides.     

Edesign: Primer and Enhanced Internal Probe Design Tool for Quantitative PCR Experiments and Genotyping Assays

Analytical PCR experiments preferably use internal probes for monitoring the amplification reaction and specific detection of the amplicon. Such internal probes have to be designed in close context with the amplification primers, and may require additional considerations for the detection of genetic variations. Here we describe Edesign, a new online and stand-alone tool for designing sets of PCR primers together with an internal probe for conducting quantitative real-time PCR (qPCR) and genotypic experiments. Edesign can be used for selecting standard DNA oligonucleotides like for instance TaqMan probes, but has been further extended with new functions and enhanced design features for Eprobes. Eprobes, with their single thiazole orange-labelled nucleotide, allow for highly sensitive genotypic assays because of their higher DNA binding affinity as compared to standard DNA oligonucleotides. Using new thermodynamic parameters, Edesign considers unique features of Eprobes during primer and probe design for establishing qPCR experiments and genotyping by melting curve analysis. Additional functions in Edesign allow probe design for effective discrimination between wild-type sequences and genetic variations either using standard DNA oligonucleotides or Eprobes. Edesign can be freely accessed online at http://www.dnaform.com/edesign2/, and the source code is available for download.     

Universal PCR primers for detection of phytopathogenic Agrobacterium strains.

Two PCR primer pairs, based on the virD2 and ipt genes, detected a wide variety of pathogenic Agrobacterium strains. The endonuclease domain of VirD2 protein, which cleaves transferred DNA (T-DNA) border sequences, is highly conserved; primer oligonucleotides specific for the endonuclease portion of virD2 detected all pathogenic strains of Agrobacterium tested. PCR primers corresponding to conserved sequences in ipt, the T-DNA-borne cytokinin synthesis gene, detected only Agrobacterium tumefaciens and distinguished it from Agrobacterium rhizogenes. The virD2 and ipt primer pairs did not interfere with each other when included in the same PCR amplification, and this permitted simultaneous detection of both genes in a single reaction. One nonpathogenic Agrobacterium radiobacter strain contained virD2 but not ipt; we speculate that this strain arose from a pathogenic progenitor through a deletion in the T-DNA. The virD2 primer pair appears to be universal for all pathogenic Agrobacterium species; used together, the primer sets reported here should allow unambiguous identification of Ti plasmid DNA in bacteria isolated from soil and plants.     

PRISE2: Software for designing sequence-selective PCR primers and probes

Background

PRISE2 is a new software tool for designing sequence-selective PCR primers and probes. To achieve high level of selectivity, PRISE2 allows the user to specify a collection of target sequences that the primers are supposed to amplify, as well as non-target sequences that should not be amplified. The program emphasizes primer selectivity on the 3’ end, which is crucial for selective amplification of conserved sequences such as rRNA genes. In PRISE2, users can specify desired properties of primers, including length, GC content, and others. They can interactively manipulate the list of candidate primers, to choose primer pairs that are best suited for their needs. A similar process is used to add probes to selected primer pairs. More advanced features include, for example, the capability to define a custom mismatch penalty function. PRISE2 is equipped with a graphical, user-friendly interface, and it runs on Windows, Macintosh or Linux machines.

Results

PRISE2 has been tested on two very similar strains of the fungus Dactylella oviparasitica, and it was able to create highly selective primers and probes for each of them, demonstrating the ability to create useful sequence-selective assays.

Conclusions

PRISE2 is a user-friendly, interactive software package that can be used to design high-quality selective primers for PCR experiments. In addition to choosing primers, users have an option to add a probe to any selected primer pair, enabling design of Taqman and other primer-probe based assays. PRISE2 can also be used to design probes for FISH and other hybridization-based assays.     

Improvement of the dot-blot-SNP technique for efficient and cost-effective genotyping

Although the dot-blot-SNP technique is a laborsaving, cost-effective method for SNP genotyping of a large number of plants, the synthesis of 5′-digoxigenin (DIG)-labeled oligonucleotides for use as probes is still costly. We developed two probe-labeling methods for this technique, one being digoxigenin labeling of oligonucleotides by PCR (PCR-DIG labeling) and the other being hybridization using a bridge probe and a 5′-DIG-labeled oligonucleotide (bridge hybridization). Bridge hybridization detected allele-specific signals under hybridization conditions similar to those for the 5′-DIG-labeled oligonucleotides and biotin-labeled oligonucleotides, while signals were detected only under a lower stringency condition by PCR-DIG labeling. As a method for genotyping using many markers at one time, two methods, i.e., PCR using mixed primer pairs and hybridization using mixed probes, were examined with successful results. Eighty-five SNP markers designed for genotyping of rice cultivars detected allele-specific signals, the genotyping results corresponding to the previously reported ones.     

Reliable fusion PCR using Taq polymerases and pGEM-T easy vectors

We describe a reliable method for the production of fusion PCR products that can be used to transform the wild-type bacteria to replace target genes for mutagenesis studies. The relevant gene fragments and selective cassette are first amplified separately by PCR using primers that produce overlapping ends. As economic Taq DNA polymerase is disappointed in producing overlap ends due to adding an extra 3′-end ‘A’ base which potentially blocks the successful fusion of the amplified fragments, we use a new primer design strategy to overcome this disadvantage by introducing an additional ‘A’ base in the overlap primers. The amplified gene fragments were then separately cloned into a pGEM-T easy vector and re-amplified with the aid of a universal primer T7/SP6. This procedure enables performing nested PCR with the outmost primers in the fusion reaction to reliably splice the gene fragments into a single molecule with all sequences in the desired order.     

Efficient amplification of light and heavy chain variable regions and construction of a non-immune phage scFv library

Non-immune phage scFv library is one of the most attractive resources for therapeutics, diagnostics and basic research. As a matter of fact, quality of the library is limited by inefficient PCR cloning of antibody genes using degenerated primers. PCR using this type of primers is difficult to optimize conditions for efficient amplification, and therefore causes loss of antibody diversities. To overcome this problem, we described a novel two-step amplification of V_κ and V_H genes with newly designed primer sets. Initially, we amplified V_κ and V_H genes from their signal sequences to the joining region to keep antibody diversity as large as possible. Thereafter, highly degenerated primers were used to amplify the V_κ and V_H genes from the framework region 1 to the joining region. The V_κ and V_H genes from the second PCR then were linked by PCR overlapping extension to generate the scFv library. Fifteen clones from the library were randomly picked and sequenced, and the diversity of full-length scFvs was confirmed. Expression capability of clones in the library was 80% after confirmation using colony hybridization. The results demonstrated the efficiency of this strategy and the primer sets for construction of the scFv library.     

Synthesis and evaluation of phosphorescent oligonucleotide probes for hybridisation assays

Monofunctional, p-isothiocyanatophenyl-derivatives of platinum (II)-coproporphyrin-I (PtCP-NCS) were evaluated as phosphorescent labelling reagents for synthetic oligonucleotides containing a 3′- or 5′-amino modification. Synthesis and purification conditions were optimised to generate high yields and purity of PtCP-labelled oligonucleotide probes. Phosphorescent properties of the PtCP label have been shown to be largely unaffected by conjugation to oligonucleotides of various length, GC composition and label attachment site. 5′-PtCP-labelled oligonucleotides were shown to work efficiently as primers in a standard PCR. A dedicated 532 nm laser-based time-resolved fluorescence plate reader enabled highly sensitive detection of PtCP-labelled oligonucleotides and PCR products, both in solution and in agarose gels, with limits of detection in the order of 0.3 pM. A model system employing two complementary oligonucleotides labelled with PtCP and QSY® 7 dye (dark quencher) showed strong (~20-fold) and specific proximity quenching of PtCP label upon hybridisation in solution. The potential applications of PtCP-labelled probes in hybridisation assays were discussed.     

W (A or T) sequences as probes and primers suitable for genomic mapping and fingerprinting.

A limitation to the use of oligonucleotide probes as tools for genetic and physical mapping has been the low hybridization positive frequency obtained by oligonucleotides of sufficient length to hybridize preferentially to cloned insert DNA (and not host E. coli genomic DNA). Both computer and experimental results now indicate that oligonucleotide probes composed of W (A or T) sequence are preferentially found in eukaryotic DNA, and can be used to provide high frequency, discriminative hybridization. Such W sequences may be useful as either probes or PCR primers in molecular diagnostic applications as well as in genetic and physical mapping.     

A new diagnostic system for ultra-sensitive and specific detection and quantification of Candidatus Liberibacter asiaticus, the bacterium associated with citrus Huanglongbing

An ultra-sensitive and quantitative diagnostic system by combining nested PCR and TaqMan® PCR in a single tube was developed for detection of “Candidatus Liberibacter asiaticus”. The procedure involves two PCR steps using the species-specific outer and inner primer pairs. Different annealing temperatures allow both the first and the second rounds of PCR to be performed sequentially in the same closed tube. The first PCR with outer primers was performed at a higher annealing temperature and with limited amount of primers to prevent interference with the inner primers during the second round of PCR. The specificity of the dual primer TaqMan® is high because the fluorescent signal can only be generated from the TaqMan® probes that are homologous to the product amplified by the outer and inner primers. This new detection system can reliably detect as few as single copies of target DNA. The sensitivity of the dual primer system is comparable to the conventional two-tube nested PCR, but it eliminates the potential risk of cross contamination commonly associated with conventional nested PCR. This one-tube dual primer TaqMan® PCR method is gel-free with reduced handling time and is cost effective. At the same time, this system provides significantly increased sensitivity, improved reliability and high through-put capability suitable for routine, large scale diagnoses of clinical plant tissue and insect samples. The technique described here is generic and can be applied to the detection of other plant pathogenic bacteria.     

A modified procedure for PCR-based differential display and demonstration of use in plants for isolation of genes related to fruit ripening

We have modified and optimized PCR-based differential display for efficient identification and isolation of genes whose expression patterns are correlated with changes in growth, development, physiology, and/or environmental response. This protocol is general in nature and can be applied for analysis of virtually any plant tissues from which several μg of total RNA can be extracted. We report here the use of tomato fruit ripening as a model system in which to test and optimize differential display in plants. Specifically, mRNA from ripe, early breaker, mature green, and ethylene-treated mature green tomato fruit were examined to identify and distinguish non-ethylene-inducible from ethylene-inducible genes related to ripening. DNA-free total RNA was utilized as template for synthesis of first-strand complementary DNA using each of 12 possible 5′-T₁₁ XY-3′ anchor primers (X=A, C, or G; Y=A, C, G, or T). PCR amplification products of the resulting cDNA populations were generated via use of random primers in combination with the corresponding anchor primer employed for cDNA synthesis. We demonstrate that degenerative anchor primers are useful for making representative cDNA populations, but are not effective for representative display-PCR. cDNA, resulting from degenerative anchor primer synthesis, yielded substantially fewer ripening-related display-PCR products when amplified with the same degenerative anchor primer employed in cDNA synthesis, versus the corresponding set of specific anchor primers. Amplification products specific to ripe fruit cDNA were isolated directly from display gels, reamplified, cloned, and confirmed for ripening-related gene expression via RNA gel-blot analysis.     

DNA analysis with multiplex microarray-enhanced PCR

We have developed a highly sensitive method for DNA analysis on 3D gel element microarrays, a technique we call multiplex microarray-enhanced PCR (MME-PCR). Two amplification strategies are carried out simultaneously in the reaction chamber: on or within gel elements, and in bulk solution over the gel element array. MME-PCR is initiated by multiple complex primers containing gene-specific, forward and reverse, sequences appended to the 3′ end of a universal amplification primer. The complex primer pair is covalently tethered through its 5′ end to the polyacryl- amide backbone. In the bulk solution above the gel element array, a single pair of unattached universal primers simultaneously directs pseudo-monoplex PCR of all targets according to normal solution-phase PCR. The presence of a single universal PCR primer pair in solution accelerates amplification within gel elements and eliminates the problem of primer interference that is common to conventional multiplex PCR. We show 10⁶-fold amplification of targeted DNA after 50 cycles with average amplification efficiency 1.34 per cycle, and demonstrate specific on-chip amplification of six genes in Bacillus subtilis. All six genes were detected at 4.5 pg of bacterial genomic DNA (equivalent to 10³ genomes) in 60 independent amplification reactions performed simultaneously in single reaction chamber.     

Development of three allele-specific codominant rice <Emphasis Type="Italic">Waxy</Emphasis> gene PCR markers suitable for marker-assisted selection of amylose content and paste viscosity

Four Waxy haplotypes, previously identified as each having a different combination of three single nucleotide polymorphisms (SNPs) in the Waxy gene, were highly correlated with apparent amylose content and pasting properties, which are important grain quality traits for predicting cooked rice (Oryza sativa L.) texture and processing properties (Chen et al. in J Cereal Sci 47:536–545, 2008a; Chen et al. in J Cereal Sci 48:781–788, 2008b). Three allele-specific PCR markers were developed to genotype the three aforementioned functional SNPs in a single PCR amplification. Each marker contained two allele-specific primers and one common primer. For each marker, the two allele-specific primers differed by one base at the 3′-end to provide discrimination of SNP alleles, and were labeled with unique fluorescence probes. An additional mismatched base, the third base from the 3′-end, was inserted in some allele-specific primers to increase selectivity. The amplification step of the PCR thermal cycling program was initially set for 20× touch-down cycles with the annealing temperature of the first cycle approximately 6°C above the thermal melting temperature of all three primers at a touch-down rate of −0.3°C per cycle, and followed by 25× regular thermal cycles with the annealing temperature at their thermal melting temperature. The allelic genotypes for each SNP were distinguished from each other by both their differential primer-allele fluorescences and their amplification product lengths. The simplicity of these assays makes it easy to utilize these markers as part of a marker-assisted selection strategy in rice breeding programs selecting for these important grain quality traits.     

Construction and validation of a Sinorhizobium meliloti whole genome DNA microarray: genome-wide profiling of osmoadaptive gene expression

Based on the complete Sinorhizobium meliloti genome sequence we established DNA microarrays as a comprehensive tool for systematic genome-wide gene expression analysis in S. meliloti 1021. For these PCR fragment-based microarrays, called Sm6kPCR, a collection of probes for the 6207 predicted protein-coding genes consisting of 6046 gene-specific PCR fragments and 161 70 mer oligonucleotides was arrayed in high density on glass slides. To obtain these PCR fragments primer pairs were designed to amplify internal gene-specific DNA fragments of 80-350 bp. Additionally, these primers were characterized by a 5' extension that allowed for reamplification using standard primers after the first amplification employing the specific primers. In order to ascertain the quality of the Sm6kPCR microarrays and to validate gene expression studies in S. meliloti parallel hybridizations based on RNA samples obtained from cells cultured under identical conditions were performed. In addition, gene expression in S. meliloti in response to an osmotic upshift imposed by the addition of 0.38 M NaCl was monitored. 137 genes were identified showing significant changes in gene expression resulting from the osmotic upshift. From these genes 52 were induced and 85 genes were repressed. Among the genes displaying different RNA levels some functional groups could be identified that are particularly remarkable. Repression was observed for 8 genes related to motility and chemotaxis, 7 genes encoding amino acid biosynthesis enzymes and 15 genes involved in iron uptake whereas 14 genes involved in transport of small molecules and 4 genes related to polysaccharide biosynthesis were induced.     

Improved biplex quantitative real-time polymerase chain reaction with modified primers for gene expression analysis

Stabilizing modified bases incorporated in primers allows the reduction of housekeeping gene primer concentration not possible with regular primers without sacrificing amplification efficiency. Low primer concentration allows coamplification of the most abundant housekeeping genes with very rare templates without mutual inhibition. Real-time polymerase chain reaction (PCR) coamplification of 18S ribosomal RNA with several genes of interest was used in this study with MGB Eclipse (Nanogen, San Diego, CA) hybridization probes. The results may be useful for high throughput gene expression studies as they simplify validation experiments.     

Genome scanning for resistance-gene analogs in rice, barley, and wheat by high-resolution electrophoresis

 Genes cloned from diverse plants for resistance to different pathogens have sequence similarities in domains presumably involved in pathogen recognition and signal transduction in triggering the defense response. Primers based on the conserved regions of resistance genes often amplify multiple fragments that may not be separable in an agarose gel. We used denaturing polyacrylamide-gel electrophoresis to detect PCR products of plant genomic DNA amplified with primers based on conserved regions of resistance genes. Depending upon the primer pairs used, 30–130 bands were detected in wheat, rice, and barley. As high as 47%, 40%, and 27% of the polymorphic bands were detected in rice, barley, and wheat, respectively, and as high as 12.5% of the polymorphic bands were detected by certain primers in progeny from a cross of the wheat cultivars ‘Stephens’ and ‘Michigan Amber’. Using F₆ recombinant inbred lines from the ‘Stephens’בMichigan Amber’ cross, we demonstrated that polymorphic bands amplified with primers based on leucine-rich repeats, nucleotide-binding sites and protein kinase genes, were inherited as single loci. Linkages between molecular markers and stripe rust resistance genes were detected. This technique provides a new way to develop molecular markers for assessing the genetic diversity of germplasm based upon potential candidate resistance genes in diverse species. Received : 5 September 1997 / Accepted : 6 November 1997     

T-linker-specific ligation PCR (T-linker PCR): an advanced PCR technique for chromosome walking or for isolation of tagged DNA ends

Dozens of PCR-based methods are available for chromosome walking from a known sequence to an unknown region. These methods are of three types: inverse PCR, ligation-mediated PCR and randomly primed PCR. However, none of them has been generally applied for this purpose, because they are either difficult or inefficient. Here we describe a simple and efficient PCR strategy—T-linker-specific ligation PCR (T-linker PCR) for gene or chromosome walking. The strategy amplifies the template molecules in three steps. First, genomic DNA is digested with 3′ overhang enzymes. Secondly, primed by a specific primer, a strand of the target molecule is replicated by Taq DNA polymerase and a single A tail is generated on the 3′ unknown end of the target molecule, and then a 3′ overhang-T linker (named T-linker) is specifically ligated onto the target. Thirdly, the target is amplified by two rounds of nested PCR with specific primers and T-linker primers. T-linker PCR significantly improves the existing PCR methods for walking because it uses specific T/A ligation instead of arbitrary ligation or random annealing. To show the feasibility and efficiency of T-linker PCR, we have exploited this method to identify vector DNA or T-DNA insertions in transgenic plants.     

Molecular technologies used in detecting of sensitive and isoniazid-resistant <Emphasis Type="Italic">Mycobacterium tuberculosis</Emphasis>

Two variants for the detection of single nucleotide polymorphisms in codon 315 of the katG gene of Mycobacterium tuberculosis (MTB) (mutations in this gene are associated with resistance to isoniazid, which is an antituberculosis drug of the first line) have been developed. Two sets of primers, either of which included an additional competitive blocking primer with a 3′-terminal phosphate group (in order to prevent nonspecific amplification), permitted the identification of the most frequent AGC → ACC and AGC → AGA point mutations in codon 315 of the katG gene. Conduction of PCR with a set of two primers, one of which contained five LNA monomers, permitted the detection of any of the six known mutations in codon 315 of the katG gene and, thereby, for the discrimination between isoniazid-sensitive and isoniazid-resistant MTB. The purity and structure of the 17 bp long primers containing LNA-modified nucleotides were characterized by time-of-flight MALDI mass spectrometry, and the 17 bp duplex formed by two LNA-containing complementary oligonucleotides was analyzed by thermal denaturation. The molecular genetic test systems created for differentiating between the wild-type MTB isolates and isoniazid-resistant MTB (an antituberculosis drug of the first line) can be used in clinical laboratories equipped with standard PCR devices; such systems permit the shortening of the time required for the detection of isoniazid resistance of MTB: from 1–3 months by the standard bacteriological methods to 1–3 days by PCR.     

Traced orthologous amplified sequence tags (TOASTs) and mammalian comparative maps

Progress on mammalian comparative maps could be significantly accelerated by developing reagents defining orthologous landmarks in the genome of many mammalian species. Using the large databases of gene sequences, we designed 225 orthologous gene-specific primer pairs corresponding to 146 functional genes. Of these 225 primer pairs, 155 (68.9%), 182 (80.9%), 126 (56.0%), and 82 (36.4%) produced a single PCR product when tested against human, pig, dog, and hamster genomic DNA, respectively. In addition to the general rules of primer designing, particular factors must be taken into consideration when choosing gene-specific universal primers—for instance, preference for single-exon regions or highly conserved segments among species, avoidance of GC-rich regions. Sequencing all the canine PCR products traced by these primers demonstrated that of 123 traced canine fragments with readable and reliable sequences, 121 (98.4%) were found to match the GenBank orthologous sequences used for designing the primers, after a BLAST search. Comparative characterization of PCR fragments among human, pig, dog, and hamster revealed that the length of a single exon was much conserved among species, with few exceptions. As the fragments were traced with amplification by orthologous gene-specific primers, we suggest they be termed Traced Orthologous Amplified Sequence Tags (TOASTs). Received: 22 December 1997 / Accepted: 16 March 1998     

Gene synthesis by integrated polymerase chain assembly and PCR amplification using a high-speed thermocycler

Polymerase chain assembly (PCA) is a technique used to synthesize genes ranging from a few hundred base pairs to many kilobase pairs in length. In traditional PCA, equimolar concentrations of single stranded DNA oligonucleotides are repeatedly hybridized and extended by a polymerase enzyme into longer dsDNA constructs, with relatively few full-length sequences being assembled. Thus, traditional PCA is followed by a second primer-mediated PCR reaction to amplify the desired full-length sequence to useful, detectable quantities. Integration of assembly and primer-mediated amplification steps into a single reaction using a high-speed thermocycler is shown to produce similar results. For the integrated technique, the effects of oligo concentration, primer concentration, and number of oligonucleotides are explored. The technique is successfully demonstrated for the synthesis of two genes encoding EPCR-1 (653 bp) and pUC19 β-lactamase (929 bp) in under 20 min. However, rapid integrated PCA–PCR was found to be problematic when attempted with the TM-1 gene (1509 bp). Partial oligonucleotide sets of TM-1 could be assembled and amplified simultaneously, indicating that the technique may be limited to a maximum number of oligonucleotides due to competitive annealing and competition for primers.