Enhanced specificity of TPMT*2 genotyping using unidirectional wild-type and mutant allele-specific scorpion primers in a single tube

Scorpion primer PCR analysis for genotyping of allele variants of thiopurine s‑methyltransferase*3

Thiopurine S-methyltransferase (TPMT) plays an important role in the metabolism of thiopurines. Mutations in the TPMT gene can affect drug activity, which may have adverse effects in humans. Thus, genotyping can help elucidate genetic determinants of drug response to thiopurines and optimize the selection of drug therapies for individual patients, effectively avoiding palindromia during maintenance treatment caused by insufficient dosing and the serious side effects caused by excessive doses. The current available detection methods used for TPMT*3B and TPMT*3C are complex, costly and time-consuming. Therefore, innovative detection methods for TPMT genotyping are urgently required. The aim of the present study was to establish and optimize a simple, specific and timesaving TPMT genotyping method. Using the principles of Web-based Allele-Specific PCR and competitive real-time fluorescent allele-specific PCR (CRAS-PCR), two pairs of Scorpion primers were designed for the detection of TPMT*3B and *3C, respectively, and a mutation in TPMT*3A was inferred based on data from TPMT*3B and *3C. In total, 226 samples from volunteers living in Chongqing were used for CRAS-PCR to detect TPMT*3 mutations. Results showed that nine (3.98%) were mutant (MT) heterozygotes and none were MT homozygotes for TPMT*3C, and no TPMT*3A and TPMT*3B mutations were found. Three TPMT*3C MT heterozygotes were randomly selected for DNA sequencing, and CRAS-PCR results were consistent with the sequencing results. In conclusion, in order to improve simplicity, specificity and efficiency, the present study established and optimized CRAS-PCR assays for commonly found mutant alleles of TPMT*3A (G460A and A719G), TPMT*3B (G460A), and TPMT*3C (A719G).

Sensitive detection of low-abundance in-frame deletions in EGFR exon 19 using novel wild-type blockers in real-time PCR

Epidermal growth factor receptor (EGFR) mutations are associated with response of tyrosine kinase inhibitors (TKIs) for patients with advanced non-small cell lung cancer (NSCLC). However, the existing methods for detection of samples having rare mutations(i.e. ~0.01%) have limits in terms of specificity, time consumption or cost. In the current study, novel wild-type blocking (WTB) oligonucleotides modified with phosphorothioate or inverted dT at the 5'-termini were designed to precisely detect 11 common deletion mutations in exon 19 of EGFR gene (E19del) using a WTB-PCR assay. And internal competitive leptin amplifications were further applied to enhance the specificity of the WTB-PCR system. Our results showed that WTB-PCR could completely block amplification of wild-type EGFR when 200 ng of DNA was used as template. Furthermore, the current WTB-PCR assay facilitated the detection of E19del mutations with a selectivity of 0.01% and sensitivity as low as a single copy. And, the results showed that the current WTB-PCR system exceeded detection limits afforded by the ARMS-PCR assay. In conclusion, the current WTB-PCR strategy represents a simple and cost-effective method to precisely detect various low-abundance deletion mutations.

Sensitive and selective detections of codon 12 and 13 KRAS mutations in a single tube using modified wild-type blocker

It was hypothesized that in the WTB-PCR system, the greater number of cycles, associated with the thermodynamic driving force of DNA polymerase resulted in artificial introduction of mutant nucleotides in amplicons. In the current study, universal WTB-PCR was developed to overcome these limitations, in which two strategies were used: phosphorothioate modifications were made at the 5'-termini bases of the WTB oligonucleotides, and amplification of referenced internal positive controller (RIPC) fragments was performed. The results showed that universal WTB-PCR could detect single-copy KRAS mutant alleles with higher selectivity (i.e., 0.01%), and with greater ability to eliminate non-specific amplification of KRAS wild-type alleles in amounts up to 200 ng. Moreover, the introduction of referenced internal positive controller (RIPC) fragments prevented false-negative results caused by inadequate amounts of input sample DNA, and allowed for quantitative analysis of the mutation levels in each FFPE sample. In clinical application in 50 samples of FFPE tissue sections from mCRC patients, 70% (35/50) showed various mutations at codons 12 and 13 of KRAS genes; 30% (15/50) could be detected by traditional PCR without WTB oligonucleotides. In conclusion, universal WTB-PCR is a rapid, simple and low-cost method for detection of low-abundance KRAS mutations in mCRC patients.

Improved detection of BRAF V600E using allele-specific PCR coupled with external and internal controllers

Although traditional allele-specific PCR (tAS-PCR) is a common screening method for BRAF V600E mutations, its lower amplification specificity and mutation selectivity have limited its clinical applications. We hypothesize that these limitations are associated with the weaker specificities of allele-specific primers and the thermodynamic driving forces of DNA polymerase. We used three strategies to circumvent these limitations, namely, modifying allele-specific primers, introducing a competitive external allele-specific controller (i.e., cAS-PCR), and introducing a referenced internal positive controller in the cAS-PCR (i.e., rcAS-PCR). The amplification sensitivities and specificities were influenced by the position of the artificially introduced mismatched nucleotide in the allele-specific primers. Moreover, both cAS-PCR and rcAS-PCR could detect single-copy BRAF V600E alleles with higher mutation selectivity (0.1%) than tAS-PCR. In addition, cAS-PCR eliminated false-negative results caused by various PCR inhibitors that might be present in the DNA solutions. The rcAS-PCR could also be employed to avoid the false-negative results caused by low-abundance input templates in cAS-PCR. In conclusion, rcAS-PCR provides a rapid, simple, and low-cost method for detecting low levels of the mutated BRAF V600E gene.

Wild‑type blocking pcr coupled with internal competitive amplified fragment improved the detection of rare mutation of KRAS

Mutant KRAS proto-oncogene GTPase (KRAS) serves an important role in predicting the development, diagnosis, treatment and efficacy of targeted drug therapies for colorectal cancer. To improve the detection efficacy of trace amount of mutant KRAS, the locked nucleic acid-based method was modified in the present study. Internal competitive amplification fragments were used to improve the inhibition of wild-type KRAS with a wild-type blocking (WTB) probe and specifically amplify the trace amounts of mutant KRAS. The modified method, quantitative clamp-based polymerase chain reaction technology using WTB coupled with internal competitive reference to enhance the amplification specificity, named WIRE-PCR, completely blocked the amplification of wild-type KRAS in 50–150 ng DNA templates. The added internal competitive amplified fragments were amplified together with the target gene, which were used to reduce base mismatch due to the high number of cycles in PCR and quantify the total amount of DNA. The results demonstrated that WIRE-PCR facilitated the detection of mutated alleles at a single molecular level. In the colorectal biopsies from 50 patients with suspected colorectal cancer, 18 cases (36%) contained mutant KRAS, and the amount of mutant DNA accounted for 18.6–64.2% of the total DNA. WIRE-PCR is a simple, rapid and low-cost quantitative analysis method for the detection of trace amounts of the mutant KRAS.

Development of a hydrolysis probe-based real-time assay for the detection of tropical strains of Fusarium oxysporum f. sp. cubense race 4

Fusarium oxysporum f. sp. cubense (Foc) is one of the most important threats to global banana production. Strategies to control the pathogen are lacking, with plant resistance offering the only long-term solution, if sources of resistance are available. Prevention of introduction of Foc into disease-free areas thus remains a key strategy to continue sustainable banana production. In recent years, strains of Foc affecting Cavendish bananas have destroyed plantations in a number of countries in Asia and in the Middle East, and one African country. One vegetative compatibility group (VCG), 01213/16, is considered the major threat to bananas in tropical and subtropical climatic conditions. However, other genetically related VCGs, such as 0121, may potentially jeopardize banana cultures if they were introduced into disease-free areas. To prevent the introduction of these VCGs into disease-free Cavendish banana-growing countries, a real-time PCR test was developed to accurately detect both VCGs. A previously described putative virulence gene was used to develop a specific combination of hydrolysis probe/primers for the detection of tropical Foc race 4 strains. The real-time PCR parameters were optimized by following a statistical approach relying on orthogonal arrays and the Taguchi method in an attempt to enhance sensitivity and ensure high specificity of the assay. This study also assessed critical performance criteria, such as repeatability, reproducibility, robustness, and specificity, with a large including set of 136 F. oxysporum isolates, including 73 Foc pathogenic strains representing 24 VCGs. The validation data demonstrated that the new assay could be used for regulatory testing applications on banana plant material and can contribute to preventing the introduction and spread of Foc strains affecting Cavendish bananas in the tropics.

Preparing Triple-Compound Heterozygous Control Material for Molecular Diagnostics of TPMT Allelic Variants

The aim of the study is to present a novel approach for preparing triple-compound heterozygous reference material (TCH-RM) for thiopurine S-methyltransferase (TPMT) genotyping by using the gene synthesis technology. The polynucleotide chain we prepared consisted of three wild-type and three mutant segments corresponding to the TPMT 238G>C, 460G>A, and 719A>G polymorphic sites. TCH-RM characteristics were assessed via four methods: reverse hybridization, real-time PCR with hydrolysis probes, real-time PCR followed by subsequent melting temperature analysis, and DNA sequencing. Consequently, we investigated the TPMT genotype of 371 patients suffering from autoimmune diseases requiring immunosuppressive therapy with thiopurine drugs, mostly inflammatory bowel disease. All methods confirmed the triple heterozygous character and commutability of TCH-RM. In evaluating its stability we obtained very comparable data before and after six months of storage at -80 °C. The determined genotypes were as follows: 352 wild-type subjects (94.8%), 17 TPMT*3A heterozygotes (460G>A and 719A>G, 4.6%), one patient heterozygous for the TPMT*2 allele (238G>C, 0.3%), and one TPMT*3C heterozygote (719A>G, 0.3%). The frequencies of TPMT*1, *3A, *3C, and *2 in the patients were 97.5%, 2.3%, 0.1%, and 0.1 %, respectively. Assembling segments of synthetic DNA into long polynucleotide chains is a universal way of obtaining compound heterozygous material for performing any simultaneous analysis of polymorphic sites in the human genome. The batches are manufactured with a perfect concentration match of wildtype and mutant fragments, and can be made in large quantities for most diagnostic techniques.