Germline variants affecting the exonuclease domains of POLE and POLD1 predispose to multiple colorectal adenomas and/or colorectal cancer (CRC). The aim of this study was to estimate the prevalence of previously described heterozygous germline variants POLE c.1270C4G, p.(Leu424Val) and POLD1 c.1433G4A, p.(Ser478Asn) in a Dutch series of unexplained familial, early onset CRC and polyposis index cases. We examined 1188 familial CRC and polyposis index patients for POLE p.(Leu424Val) and POLD1 p.(Ser478Asn) variants using competitive allele-specific PCR. In addition, protein expression of the POLE and DNA mismatch repair genes was studied by immunohistochemistry in tumours from POLE carriers. Somatic mutations were screened using semiconductor sequencing. We detected three index patients (0.25%) with a POLE p.(Leu424Val) variant. In one patient, the variant was found to be de-novo. Tumours from three patients from two families were microsatellite instable, and immunohistochemistry showed MSH6/MSH2 deficiency suggestive of Lynch syndrome. Somatic mutations but no germline MSH6 and MSH2 variants were subsequently found, and one tumour displayed a hypermutator phenotype. None of the 1188 patients carried the POLD1 p.(Ser478Asn) variant. POLE germline variant carriers are also associated with a microsatellite instable CRC. POLE DNA analysis now seems warranted in microsatellite instable CRC, especially in the absence of a causative DNA mismatch repair gene germline variant. INTRODUCTIONFaithful DNA replication and the repair of errors are both essential for the maintenance of genomic stability and suppression of carcinogenesis. 1 Duplication of genomes with high accuracy is achieved through three mechanisms: the high selectivity of DNA polymerases; exonucleolytic proofreading; and post replication mismatch repair. 2 The DNA polymerases ε (POLε) and δ (POLδ) are required for the efficient genome replication in the eukaryotic replication fork. 3 Their major component proteins, encoded by POLE and POLD1, respectively, possess an intrinsic 3′-5′ proofreading domain that removes incorrectly inserted nucleotides during DNA synthesis. [4][5][6][7][8][9] Studies in the yeast have shown that mutations in the proofreading domains of POLε or POLδ increase spontaneous mutation rates. 8,9 In addition, somatic mutations in the proofreading domains of POLD1 and POLE have been identified in microsatellite instable (MSI) and hypermutated subgroups of colorectal cancers (CRCs). [10][11][12] Recently, Palles et al reported that heterozygous germline variants in the proofreading domain of the DNA polymerases POLE and POLD1 predispose, with a high penetrance, to multiple colorectal adenomas, early onset CRC (OMIM #114500) and endometrial cancer (OMIM #608089). These variants were found by whole-genome sequencing and linkage analysis in three large families with a dominant pattern of CRC and multiple adenomas. 13 Subsequent screening of 3805 CRC patients revealed that these variants are relatively rare: POLE
Endobronchial Ultrasound Guided Transbronchial Needle Aspiration (EBUS-TBNA) and Trans-esophageal Ultrasound Scanning with Fine Needle Aspiration (EUS-FNA) are important, novel techniques for the diagnosis and staging of non-small cell lung cancer (NSCLC) that have been incorporated into lung cancer staging guidelines. To guide and optimize treatment decisions, especially for NSCLC patients in stage III and IV, EGFR and KRAS mutation status is often required. The concordance rate of the mutation analysis between these cytological aspirates and histological samples obtained by surgical staging is unknown. Therefore, we studied the extent to which allele-specific quantitative real-time PCR with hydrolysis probes could be reliably performed on EBUS and EUS fine needle aspirates by comparing the results with histological material from the same patient. We analyzed a series of 43 NSCLC patients for whom cytological and histological material was available. We demonstrated that these standard molecular techniques can be accurately applied on fine needle cytological aspirates from NSCLC patients. Importantly, we show that all mutations detected in the histological material of primary tumor were also identified in the cytological samples. We conclude that molecular profiling can be reliably performed on fine needle cytology aspirates from NSCLC patients.
Mitochondrial-rich oncocytic thyroid tumors frequently show near-haploidization and endoreduplication (masked haploidization), which manifests as a near-homozygous genome (NHG). We now extend this investigation to include adrenocortical cancer and parathyroid carcinoma (PaTC), which we studied for a NHG in association with mitochondrial DNA mutations. Sixty endocrine tumors from 59 patients were studied, including 46 thyroid tumor samples of varying histology, 11 adrenocortical cancers, and 3 PaTCs. Genome-wide SNP array analysis and DNA content analysis were combined to determine the chromosomal dosage (allelic state). The entire mitochondrial genome was also studied for mutations. In addition, tumors were characterized for somatic mutations in a subset of genes that are directly or indirectly implicated in cellular metabolism. In addition to a subset of thyroid cancers (n = 5), a NHG was also observed in 1 of 3 PaTCs and 6 of 11 adrenocortical cancers. All but one of the tumors with a NHG (n = 12) showed oncocytic metaplasia (P = 0.0001, two-tailed Fisher's exact). One or more damaging or disrupting mtDNA mutations were found in 68% (41/60) of tumor samples. No correlation was found between mtDNA mutations and the oncocytic phenotype or a NHG, and none of the mutations in nuclear encoded genes correlated with the oncocytic phenotype or a NHG. A subset of oncocytic tumors of the thyroid, parathyroid, and adrenocortical carcinomas carries a NHG. Although damaging/disrupting mtDNA mutations are frequently found in oncocytic and nononcocytic endocrine tumors, neither correlates with a NHG phenotype nor with an oncocytic phenotype.
Background-Colorectal adenomatous polyposis is associated with a high risk of colorectal cancer (CRC) and is frequently caused by germline mutations in APC or MUTYH. However, in about 20-30% of patients no underlying gene defect can be identified. In this study, we tested if recently identified CRC risk variants play a role in patients with >10 adenomas.
Whilst common genetic variation in many non-coding genomic regulatory regions are known to impart risk of colorectal cancer (CRC), much of the heritability of CRC remains unexplained. To examine the role of recurrent coding sequence variation in CRC aetiology, we genotyped 12,638 CRCs cases and 29,045 controls from six European populations. Single-variant analysis identified a coding variant (rs3184504) in SH2B3 (12q24) associated with CRC risk (OR = 1.08, P = 3.9 × 10−7), and novel damaging coding variants in 3 genes previously tagged by GWAS efforts; rs16888728 (8q24) in UTP23 (OR = 1.15, P = 1.4 × 10−7); rs6580742 and rs12303082 (12q13) in FAM186A (OR = 1.11, P = 1.2 × 10−7 and OR = 1.09, P = 7.4 × 10−8); rs1129406 (12q13) in ATF1 (OR = 1.11, P = 8.3 × 10−9), all reaching exome-wide significance levels. Gene based tests identified associations between CRC and PCDHGA genes (P < 2.90 × 10−6). We found an excess of rare, damaging variants in base-excision (P = 2.4 × 10−4) and DNA mismatch repair genes (P = 6.1 × 10−4) consistent with a recessive mode of inheritance. This study comprehensively explores the contribution of coding sequence variation to CRC risk, identifying associations with coding variation in 4 genes and PCDHG gene cluster and several candidate recessive alleles. However, these findings suggest that recurrent, low-frequency coding variants account for a minority of the unexplained heritability of CRC.
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