Project description:This SuperSeries is composed of the SubSeries listed below.

Project description:Background: In ~50% of Lynch syndrome (LS)-suspected patients (also called Lynch-like syndrome, LLS), the causal mechanism for cancer predisposition remains unknown. Our aim was to elucidate the constitutional basis of mismatch repair (MMR) deficiency in LLS patients throughout a comprehensive genetic and epigenetic analysis. Methods: One hundred and fifteen LLS patients harboring MMR deficient tumors and no pathogenic germline MMR gene mutations were included in this study. Mutational analysis of 26 colorectal cancer associated genes was performed by using a customized multigene panel and massively parallel sequencing. Pathogenicity of MMR variants was assessed by mRNA analysis and multifactorial likelihood calculations. Genome-wide methylome analysis was perfomed by using the Infinium HumanMethylation450K BeadChip. Results: The multigene panel analysis revealed the presence of two MMR gene truncating mutations not found in previous analysis. Of a total of 15 MMR variants of unknown significance identified, five - present in 6 unrelated individuals- were reclassified as pathogenic. In addition, 13 predicted deleterious variants in other CRC-predisposing genes (MSH3, MUTYH, POLD1, APC, EPCAM, BUB1, FAN1, EXO1 or PSM1) were found in 12 probands. Methylome analysis detected one constitutional MLH1 epimutation in an individual diagnosed with CRC at age 42, but no additional differentially methylated regions were identified in LLS compared to LS patients or healthy individuals. Conclusions: In conclusion, the use of an ad-hoc designed gene panel combined with pathogenicity assessment of variants allows the identification of deleterious MMR mutations as well as new LLS candidate genes. Moreover, constitutional epimutations in non-LS-associated genes are not responsible for the MMR-deficient phenotype observed in LLS patients.

Project description:Background: In ~50% of Lynch syndrome (LS)-suspected patients (also called Lynch-like syndrome, LLS), the causal mechanism for cancer predisposition remains unknown. Our aim was to elucidate the constitutional basis of mismatch repair (MMR) deficiency in LLS patients throughout a comprehensive genetic and epigenetic analysis. Methods: One hundred and fifteen LLS patients harboring MMR deficient tumors and no pathogenic germline MMR gene mutations were included in this study. Mutational analysis of 26 colorectal cancer associated genes was performed by using a customized multigene panel and massively parallel sequencing. Pathogenicity of MMR variants was assessed by mRNA analysis and multifactorial likelihood calculations. Genome-wide methylome analysis was perfomed by using the Infinium HumanMethylation450K BeadChip. Results: The multigene panel analysis revealed the presence of two MMR gene truncating mutations not found in previous analysis. Of a total of 15 MMR variants of unknown significance identified, five - present in 6 unrelated individuals- were reclassified as pathogenic. In addition, 13 predicted deleterious variants in other CRC-predisposing genes (MSH3, MUTYH, POLD1, APC, EPCAM, BUB1, FAN1, EXO1 or PSM1) were found in 12 probands. Methylome analysis detected one constitutional MLH1 epimutation in an individual diagnosed with CRC at age 42, but no additional differentially methylated regions were identified in LLS compared to LS patients or healthy individuals. Conclusions: In conclusion, the use of an ad-hoc designed gene panel combined with pathogenicity assessment of variants allows the identification of deleterious MMR mutations as well as new LLS candidate genes. Moreover, constitutional epimutations in non-LS-associated genes are not responsible for the MMR-deficient phenotype observed in LLS patients.

Project description:Comprehensive constitutional genetic and epigenetic characterization of Lynch-like individuals

Project description:Comprehensive constitutional genetic and epigenetic characterization of Lynch-like individuals [FFPE]

Project description:Comprehensive constitutional genetic and epigenetic characterization of Lynch-like individuals [Blood]

Project description:There are more than 4,000 phenotypes for which the molecular basis is at least partly known. Though defects in primary DNA structure constitute a major cause of these disorders, epigenetic disruption is emerging as an important alternative mechanism in the etiology of a broad range of congenital and developmental conditions. These include epigenetic defects caused by either localized (in cis) genetic alterations or more distant (in trans) genetic events but can also include environmental effects. Emerging evidence suggests interplay between genetic and environmental factors in the epigenetic etiology of several constitutional "epi/genetic" conditions. This review summarizes our broadening understanding of how epigenetics contributes to pediatric disease by exploring different classes of epigenomic disorders. It further challenges the simplistic dogma of "DNA encodes RNA encodes protein" to best understand the spectrum of factors that can influence genetic traits in a pediatric population.

Project description:Lynch-like syndrome (LLS) is an increasingly common clinical challenge with an underlying molecular basis mostly unknown. To shed light onto it, we focused on a very young LLS early-onset colorectal cancer (CRC) cohort (diagnosis ≤ 40 y.o.), performing germline and tumor whole-exome sequencing (WES) of 15 patients, and additionally analyzing their corresponding tumor mutational burden (TMB) and mutational signatures. We identified four cases (27%) with double somatic putative variants in mismatch repair (MMR) core genes, as well as three additional cases (20%) with double MSH3 somatic alterations in tumors with unexplained MSH2/MSH6 loss of expression, and two cases (13%) with POLD1 potential biallelic alterations. Average TMB was significantly higher for LLS cases with double somatic alterations. Lastly, nine predicted deleterious variants in genes involved in the DNA repair functions and/or previously associated with CRC were found in nine probands, four of which also showed MMR biallelic somatic inactivation. In conclusion, we contribute new insights into LLS CRC, postulating MSH3 and POLD1 double somatic alterations as an underlying cause of a microsatellite instability (MSI) phenotype, proposing intrinsic biological differences between LLS with and without somatic alterations, and suggesting new predisposing candidate genes in this scenario.

Project description:Lynch syndrome (LS) and constitutional mismatch repair deficiency (CMMRD) are hereditary disorders characterised by a highly increased risk of cancer development. This is due to germline aberrations in the mismatch repair (MMR) genes, which results in a high mutational load in tumours of these patients, including insertions and deletions in genes bearing microsatellites. This generates microsatellite instability and cause reading frameshifts in coding regions that could lead to the generation of neoantigens and opens up avenues for neoantigen targeting immune therapies prophylactically and therapeutically. However, major obstacles need to be overcome, such as the heterogeneity in tumour formation within and between LS and CMMRD patients, which results in considerable variability in the genes targeted by mutations, hence challenging the choice of suitable neoantigens. The machine-learning methods such as NetMHC and MHCflurry that predict neoantigen- human leukocyte antigen (HLA) binding affinity provide little information on other aspects of neoantigen presentation. Immune escape mechanisms that allow MMR-deficient cells to evade surveillance combined with the resistance to immune checkpoint therapy make the neoantigen targeting regimen challenging. Studies to delineate shared neoantigen profiles across patient cohorts, precise HLA binding algorithms, additional therapies to counter immune evasion and evaluation of biomarkers that predict the response of these patients to immune checkpoint therapy are warranted.

Project description:BACKGROUND:Constitutional MLH1 epimutations are characterised by monoallelic methylation of the MLH1 promoter throughout normal tissues, accompanied by allele-specific silencing. The mechanism underlying primary MLH1 epimutations is currently unknown. The aim of this study was to perform an in-depth characterisation of constitutional MLH1 epimutations targeting the aberrantly methylated region around MLH1 and other genomic loci. METHODS:Twelve MLH1 epimutation carriers, 61 Lynch syndrome patients, and 41 healthy controls, were analysed by Infinium 450?K array. Targeted molecular techniques were used to characterise the MLH1 epimutation carriers and their inheritance pattern. RESULTS:No nucleotide or structural variants were identified in-cis on the epimutated allele in 10 carriers, in which inter-generational methylation erasure was demonstrated in two, suggesting primary type of epimutation. CNVs outside the MLH1 locus were found in two cases. EPM2AIP1-MLH1 CpG island was identified as the sole differentially methylated region in MLH1 epimutation carriers compared to controls. CONCLUSION:Primary constitutional MLH1 epimutations arise as a focal epigenetic event at the EPM2AIP1-MLH1 CpG island in the absence of cis-acting genetic variants. Further molecular characterisation is needed to elucidate the mechanistic basis of MLH1 epimutations and their heritability/reversibility.