Accurate CpG and non-CpG cytosine methylation analysis by high-throughput locus-specific pyrosequencing in plants.

Pyrosequencing permits accurate quantification of DNA methylation of specific regions where the proportions of the C/T polymorphism induced by sodium bisulfite treatment of DNA reflects the DNA methylation level. The commercially available high-throughput locus-specific pyrosequencing instruments allow for the simultaneous analysis of 96 samples, but restrict the DNA methylation analysis to CpG dinucleotide sites, which can be limiting in many biological systems. In contrast to mammals where DNA methylation occurs nearly exclusively on CpG dinucleotides, plants genomes harbor DNA methylation also in other sequence contexts including CHG and CHH motives, which cannot be evaluated by these pyrosequencing instruments due to software limitations. Here, we present a complete pipeline for accurate CpG and non-CpG cytosine methylation analysis at single base-resolution using high-throughput locus-specific pyrosequencing. The devised approach includes the design and validation of PCR amplification on bisulfite-treated DNA and pyrosequencing assays as well as the quantification of the methylation level at every cytosine from the raw peak intensities of the Pyrograms by two newly developed Visual Basic Applications. Our method presents accurate and reproducible results as exemplified by the cytosine methylation analysis of the promoter regions of two Tomato genes (NOR and CNR) encoding transcription regulators of fruit ripening during different stages of fruit development. Our results confirmed a significant and temporally coordinated loss of DNA methylation on specific cytosines during the early stages of fruit development in both promoters as previously shown by WGBS. The manuscript describes thus the first high-throughput locus-specific DNA methylation analysis in plants using pyrosequencing.

Ultrasensitive detection and identification of BRAF V600 mutations in fresh frozen, FFPE, and plasma samples of melanoma patients by E-ice-COLD-PCR.

A number of molecular diagnostic methods have been developed for the detection and identification of mutations in tumor samples, which are important for the choice of treatment in the context of personalized medicine. For the treatment of metastatic melanoma, Vemurafenib is recommended for patients with BRAF V600 activating mutations. However, the different assays developed to date for the detection of these mutations lack sensitivity or specificity or do not allow a sequencing-based identification or validation of the mutation. Recently, enhanced improved and complete enrichment co-amplification at lower denaturation temperature-polymerase chain reaction (E-ice-COLD-PCR) has been developed as a sensitive method for the detection and identification of mutations in KRAS codons 12/13. Here, we present the first E-ice-COLD-PCR assay for the detection and identification of BRAF codon 600 mutations, which has a large dynamic range, as 25 pg to 25 ng can be used as DNA input without any reduction in mutation enrichment efficiency, and which can detect down to 0.01 % of mutated alleles in a wild-type background. The assay has been validated on fresh frozen, formalin-fixed paraffin-embedded (FFPE), and plasma samples of melanoma patients and has allowed the detection and identification of BRAF mutations present in samples appearing as wild type using standard pyrosequencing, endpoint genotyping, or Sanger sequencing. Thus, the BRAF V600 E-ice-COLD-PCR assay is currently one of the most powerful molecular diagnostic tools for the ultrasensitive detection and identification of BRAF codon 600 mutations.

Sensitive detection of KRAS mutations using enhanced-ice-COLD-PCR mutation enrichment and direct sequence identification.

A number of methods allowing the detection of low levels of KRAS mutations have been developed in the last years. However, although these methods have become increasingly sensitive, they can rarely identify the mutated base directly without prior knowledge on the mutated base and are often incompatible with a sequencing-based read-out desirable in clinical practice. Here, we present a modified version of the ice-COLD-PCR assay called Enhanced-ice-COLD-PCR (E-ice-COLD-PCR) for KRAS mutation detection and identification, which allows the enrichment of the six most frequent KRAS mutations. The method is based on a nonextendable chemically modified blocker sequence, complementary to the wild-type (WT) sequence leading to the enrichment of mutated sequences. This assay permits the reliable detection of down to 0.1% mutated sequences in a WT background. A single genotyping assay of the amplification product by pyrosequencing directly following the E-ice-COLD-PCR is performed to identify the mutated base. This developed two-step method is rapid and cost-effective, and requires only a small amount of starting material permitting the sensitive detection and sequence identification of KRAS mutations within 3 hr. This method is applied in the current study to clinical colorectal cancer samples and enables detection of mutations in samples, which appear as WT using standard detection technologies.