Splicing analysis of 24 potential spliceogenic variants in MMR genes and clinical interpretation based on refined ACMG/AMP criteria.

Lynch syndrome (LS) is a common hereditary cancer syndrome caused by heterozygous germline pathogenic variants in DNA mismatch repair (MMR) genes. Splicing defect constitutes one of the major mechanisms for MMR gene inactivation. Using RT-PCR based RNA analysis, we investigated 24 potential spliceogenic variants in MMR genes and determined their pathogenicity based on refined splicing-related American College of Medical Genetics and Genomics/Association for Molecular Pathology (ACMG/AMP) criteria. Aberrant transcripts were confirmed in 19 variants and 17 of which were classified as pathogenic including 11 located outside of canonical splice sites. Most of these variants were previously reported in LS patients without mRNA splicing assessment. Thus, our study provides crucial evidence for pathogenicity determination, allowing for appropriate clinical follow-up. We also found that computational predictions were globally well correlated with RNA analysis results and the use of both SPiP and SpliceAI software appeared more efficient for splicing defect prediction.

PMS2 or PMS2CL? Characterization of variants detected in the 3' of the PMS2 gene.

PMS2 germline pathogenic variants are one of the major causes for Lynch syndrome and constitutional mismatch repair deficiencies. Variant identification in the 3' region of this gene is complicated by the presence of the pseudogene PMS2CL which shares a high sequence homology with PMS2. Consequently, short-fragment screening strategies (NGS, Sanger) may fail to discriminate variant's gene localization. Using a comprehensive analysis strategy, we assessed 42 NGS-detected variants in 76 patients and found 32 localized on PMS2 while 6 on PMS2CL. Interestingly, four variants were detected in either of them in different patients. Clinical phenotype was well correlated to genotype, making it very helpful in variant assessment. Our findings emphasize the necessity of more specific complementary analyses to confirm the gene origin of each variant detected in different individuals in order to avoid variant misinterpretation. In addition, we characterized two PMS2 genomic alterations involving Alu-mediated tandem duplication and gene conversion. Those mechanisms seemed to be particularly favored in PMS2 which contribute to frequent genomic rearrangements in the 3' region of the gene.

Somatic MMR gene mutations as a cause for MSI-H sebaceous neoplasms in Muir-Torre syndrome-like patients.

Sebaceous neoplasms are a major clinical feature of Muir-Torre syndrome (MTS) associated with visceral malignancies, especially colorectal and endometrial tumors. The diagnosis of MTS relies largely on the microsatellite instability (MSI) phenotype in tumors, suggesting germline mutations in DNA mismatch repair (MMR) genes responsible for the inherited disease. We hypothesized that in some MSI-H sebaceous tumors, acquired rather than inherited mutations in MMR genes could be involved. Using next-generation sequencing, we screened MMR gene mutations in 18 MSI-H sebaceous tumors. We found mutations in 17 samples (94%). Indeed, 12/17 (71%) were shown to carry acquired somatic mutations and among 12 samples, seven were shown to be associated with additional somatic alterations like loss of heterozygosity or multiple mutations, suggesting somatic second hits. Our findings strongly suggest that somatic MMR deficiency is responsible for a proportion of MSI-H sebaceous tumors.

A chip-based assay for botulinum neurotoxin A activity in pharmaceutical preparations.

The production of botulinum neurotoxin A (BoNT/A) for therapeutic and cosmetic applications requires precise determination of batch potency, and the enzymatic activity of BoNT/A light chain is a crucial index that can be measured in vitro. We previously established a SNAP-25 chip-based assay using surface plasmon resonance (SPR) that is more sensitive than the standard mouse bioassay for the quantification of BoNT/A activity. We have now adapted this procedure for pharmaceutical preparations. The optimized SPR assay allowed multiple measurements on a single chip, including the kinetics of substrate cleavage. The activity of five different batches of a pharmaceutical BoNT/A preparation was determined in a blind study by SPR and found to be in agreement with data from the in vivo mouse lethality assay. Biosensor detection of specific proteolytic products has the potential to accurately monitor the activity of pharmaceutical BoNT/A preparations, and a single chip can be used to assay more than 100 samples.

From variant of unknown significance to likely pathogenic: Characterization and pathogenicity determination of a large genomic deletion in the MLH1 gene.

BACKGROUND: The MLH1 gene is one of the DNA mismatch repair genes (MMR), implicated in Lynch syndrome (LS), an autosomal dominant hereditary tumor susceptibility disease. The advent of next-generation sequencing (NGS) technologies has accelerated the diagnosis of inherited diseases and increased the percentage of diagnosis of inherited cancers. However, some complex genomic alterations require the combination of several analytical strategies to allow correct biological interpretations. Here, we describe a novel MLH1 deletion and its pathogenicity determination in a patient suspected of LS. METHODS: The index case was a French 73-year-old man diagnosed with colorectal cancer displaying microsatellite instability and the loss of MLH1 and PMS2 expression. NGS analysis was used as the primary method for MMR genes screening. Long-range PCR and reverse transcriptase polymerase chain reaction (RT-PCR) were used for breakpoints and pathogenicity determinations. RESULTS: A large genomic deletion was detected which removed the last six nucleotides of MLH1 exon 11 together with a large part of intron 11. It was initially considered as a variant of unknown significance (VUS). Genomic breakpoints were subsequently characterized defining the deletion as c.1033_1039-248del. Further RNA analysis demonstrated that this variant activated a cryptic donor splice site at the 5' of the breakpoint, leading to a premature truncated protein: p.Thr345Alafs*13. CONCLUSION: Our finding suggested that although NGS technologies have increased variant detection yield, combined approaches were still needed for complex variant characterization and pathogenicity assessment.

A PMS2 non-canonical splicing site variant leads to aberrant splicing in a patient suspected for lynch syndrome.

The PMS2 gene is one of the DNA mismatch repair genes (MMR) implicated in Lynch syndrome (LS). A subset of PMS2 pathogenic variants (PVs) are splice variants mostly affecting canonical GT/AG splicing sequences. However, the majority of the intronic variants outside canonical splice sites remained as variants of unknown significance, even though some of them would alter the splicing process. In this report, we describe the analysis of such an intronic variant (c.251-5T > C) detected in an 82-year-old patient diagnosed with endometrial cancer displaying microsatellite instability and the loss of PMS2 expression displayed. RNA analysis demonstrated that this variant lead to the complete exon 4 skipping, resulting in the synthesis of a truncated protein. This finding shows the relevance of functional RNA analysis in the non-canonical intronic variant assessment and the importance of systematic evaluation of MSI/loss of expression of MMR genes for LS screening in patients with endometrial cancers.

Acquired somatic MMR deficiency is a major cause of MSI tumor in patients suspected for "Lynch-like syndrome" including young patients.

Patients with tumors displaying high microsatellite instability (MSI-H) but no germline MMR inactivation are suspected for Lynch-like syndrome (LLS). To explore the involvement of acquired somatic MMR alteration as a cause, we screened 113 patient tumor samples for MMR gene variations and loss of heterozygosity. Somatic MMR alterations were found in 85.8% of patients including "double hits" in 63.7% of patients, mainly diagnosed with colon and endometrial cancers. Interestingly, 37.5% of them were under the age of 50, and seven patients were under 30. Somatic alterations were mainly attributed to the MLH1, MSH2 genes, likely reflecting the functional importance of these key MMR genes. Pathogenic variants co-existed in other cancer genes in particular the APC gene displaying a characteristic MMR deficiency-related "mutational signature", indicating that it may be inactivated owing to MMR deficiency. We speculated that APC inactivation could trigger an accelerated malignant transformation underlying early-onset cancers. Our findings provide further insight into the mechanisms underlying LLS, somatic MMR inactivation being a major cause for early-onset LLS through pathways differing from those involved in late-onset sporadic cases.

A substrate sensor chip to assay the enzymatic activity of Botulinum neurotoxin A.

Botulinum neurotoxin A (BoNT/A) induces muscle paralysis by enzymatically cleaving the presynaptic SNARE protein SNAP-25, which results in lasting inhibition of acetylcholine release at the neuromuscular junction. A rapid and sensitive in vitro assay for BoNT/A is required to replace the mouse lethality assay (LD50) in current use. We have developed a fully automated sensor to assay the endoprotease activity of BoNT/A. We produced monoclonal antibodies (mAbs) that recognize SNAP-25 neo-epitopes specifically generated by BoNT/A action. Recombinant SNAP-25 was coupled to the sensor surface of a surface plasmon resonance (SPR) system and samples containing BoNT/A were injected over the substrate sensor. Online substrate cleavage was monitored by measuring binding of mAb10F12 to a SNAP-25 neo-epitope. The SNAP-25-chip assay was toxin serotype-specific and detected 55 fM BoNT/A (1 LD50/ml) in 5 min and 0.4 fM (0.01 LD50/ml) in 5h. Time-course and dose-response curves were linear, yielding a limit of quantification of 0.03 LD50/ml. This label-free method is 100 times more sensitive than the mouse assay, potentially providing rapid read-out of small amounts of toxin for environmental surveillance and the quality control of pharmaceutical preparations.