Secondary mutation in a coding mononucleotide tract in MSH6 causes loss of immunoexpression of MSH6 in colorectal carcinomas with MLH1/PMS2 deficiency.

Immunohistochemical staining for DNA mismatch repair proteins may be affected by various biological and technical factors. Staining variations that could potentially lead to erroneous interpretations have been recognized. A recently recognized staining variation is the significant reduction of staining for MSH6 in some colorectal carcinomas. The frequency and specific characteristics of this aberrant MSH6 staining pattern, however, have not been well analyzed. In this study of 420 colorectal carcinoma samples obtained from patients fulfilling the Revised Bethesda Guidelines, we detected 9 tumors (2%) showing extremely limited staining for MSH6 with positive staining present in <5% of the tumor cells. Our analyses showed that these tumors belonged to two distinct categories: (1) MLH1 and/or PMS2 protein-deficient carcinomas (n=5, including 1 with a pathogenic mutation in PMS2); and (2) MLH1, PMS2 and MSH2 normal but with chemotherapy or chemoradiation therapy before surgery (n=4). To test our hypothesis that somatic mutation in the coding region microsatellite of the MSH6 gene might be a potential underlying mechanism for such limited MSH6 staining, we evaluated frameshift mutation in a (C)(8) tract in exon 5 of the MSH6 gene in seven tumors that had sufficient DNA for analysis, and detected mutation in four; all four tumors belonged to the MLH1/PMS2-deficient group. In conclusion, our data outline the main scenarios where significant reduction of MSH6 staining is more likely to occur in colorectal carcinoma, and suggest that somatic mutations of the coding region microsatellites of the MSH6 gene is an underlying mechanism for this staining phenomenon in MLH1/PMS2-deficient carcinomas.

Enhanced clinical assessment of hematologic malignancies through routine paired tumor and normal sequencing.

Genomic profiling of hematologic malignancies has augmented our understanding of variants that contribute to disease pathogenesis and supported development of prognostic models that inform disease management in the clinic. Tumor only sequencing assays are limited in their ability to identify definitive somatic variants, which can lead to ambiguity in clinical reporting and patient management. Here, we describe the MSK-IMPACT Heme cohort, a comprehensive data set of somatic alterations from paired tumor and normal DNA using a hybridization capture-based next generation sequencing platform. We highlight patterns of mutations, copy number alterations, and mutation signatures in a broad set of myeloid and lymphoid neoplasms. We also demonstrate the power of appropriate matching to make definitive somatic calls, including in patients who have undergone allogeneic stem cell transplant. We expect that this resource will further spur research into the pathobiology and clinical utility of clinical sequencing for patients with hematologic neoplasms.

BRCA1 R71K missense mutation contributes to cancer predisposition by increasing alternative transcript levels.

Mutation screening of the breast and ovarian cancer predisposition genes BRCA1 and BRCA2 is becoming an increasingly important part of clinical practice. Classification of rare non-truncating sequence variants in the BRCA1 and BRCA2 genes is problematic because it is not known whether these subtle changes alter function sufficiently to predispose cells to cancer development. The BRCA1 331G > A substitution mutation, which occurs at the last nucleotide of exon 5, results in an Arg-to-Lys change at codon 71 (R71K). cDNA analysis indicated that the R71K mutation significantly increases the level of a transcript, characterized by a 22 bp deletion in exon 5, which putatively produces a truncated BRCA1 protein of 63 amino acids. The mutation completely abolishes normal splicing as the mutant allele does not generate any normal transcript. Analysis of a tumor specimen indicates loss of heterozygosity. These results support the conclusion that BRCA1 331G > A (R71K) is a deleterious mutation.

cDNA analysis demonstrates that the BRCA2 intronic variant IVS4-12del5 is a deleterious mutation.

Mutation screening of the breast and ovarian cancer predisposition genes BRCA1 and BRCA2 is becoming an increasingly important part of clinical practice. Classification of rare non-truncating sequence variants in the BRCA1 and BRCA2 genes is problematic because it is not known whether these subtle changes alter function sufficiently to predispose cells to cancer development. Several studies have reported the biochemical analysis of BRCA2 variants, which disrupted the 5' and 3'splicing consensus elements (the GU-AG rule). However, little has been done to look into the consequences of variants located outside the 5' and 3' consensus splice sites. cDNA analysis demonstrates that the BRCA2*IVS4-12del5 splice site variant results in the deletion of exon 5, and the gene putatively produces a truncated BRCA2 protein of 164 amino acids instead of 3418 with the incorporation of 22 out of frame amino acids. The pattern of breast, melanoma, and pancreatic cancers in the paternal kindred is consistent with autosomal dominant inheritance of a deleterious BRCA2 mutation. Analysis of a tumor specimen indicates loss of heterozygosity (LOH). Sequence alignment indicates the deleted region is well conserved across different species. These results support the conclusion that BRCA2 IVS4-12del5 is a deleterious mutation. This study will shed light on the reclassification of intronic variants that do not disrupt the 5' and 3' splice sites (the GU-AG rule).

Mutational landscape of metastatic cancer revealed from prospective clinical sequencing of 10,000 patients.

Tumor molecular profiling is a fundamental component of precision oncology, enabling the identification of genomic alterations in genes and pathways that can be targeted therapeutically. The existence of recurrent targetable alterations across distinct histologically defined tumor types, coupled with an expanding portfolio of molecularly targeted therapies, demands flexible and comprehensive approaches to profile clinically relevant genes across the full spectrum of cancers. We established a large-scale, prospective clinical sequencing initiative using a comprehensive assay, MSK-IMPACT, through which we have compiled tumor and matched normal sequence data from a unique cohort of more than 10,000 patients with advanced cancer and available pathological and clinical annotations. Using these data, we identified clinically relevant somatic mutations, novel noncoding alterations, and mutational signatures that were shared by common and rare tumor types. Patients were enrolled on genomically matched clinical trials at a rate of 11%. To enable discovery of novel biomarkers and deeper investigation into rare alterations and tumor types, all results are publicly accessible.

CDH1 Missense Variant c.1679C>G (p.T560R) Completely Disrupts Normal Splicing through Creation of a Novel 5' Splice Site.

Disease-causing germline mutations in CDH1 cause Hereditary Diffuse Gastric Cancer (HDGC). For patients who meet the HDGC screening criteria, the identification and classification of the sequence variants found in CDH1 are critical for risk management of patients. In this report, we describe a germline CDH1 c.1679C>G (p.T560R) variant identified in a 50 year old man who was diagnosed with gastric cancer with a strong family history of gastric cancer (one living brother was diagnosed with gastric cancer at 63 and another brother died of gastric cancer at 45). cDNA analysis, involving fragment analysis and cloning, indicated that the p.T560R mutation created a novel 5' splice donor site, which led to a novel transcript with a 32 nucleotide deletion in exon 11. This abnormal transcript putatively produces a truncated CDH1 protein (E-cadherin) of 575 amino acids instead of 882. We also demonstrated that the variant completely abolishes normal splicing as the mutant allele does not generate any normal transcript. Furthermore, the CDH1 c.1679C>G (p.T560R) variant segregated with gastric cancer in all three family members affected with gastric cancer in this family. These results support the conclusion that CDH1 c.1679C>G (p.T560R) variant is a pathogenic mutation and contributes to HDGC through disruption of normal splicing.

BAP1 missense mutation c.2054 A>T (p.E685V) completely disrupts normal splicing through creation of a novel 5' splice site in a human mesothelioma cell line.

BAP1 is a tumor suppressor gene that is lost or deleted in diverse cancers, including uveal mela¬noma, malignant pleural mesothelioma (MPM), clear cell renal carcinoma, and cholangiocarcinoma. Recently, BAP1 germline mutations have been reported in families with combinations of these same cancers. A particular challenge for mutation screening is the classification of non-truncating BAP1 sequence variants because it is not known whether these subtle changes can affect the protein function sufficiently to predispose to cancer development. Here we report mRNA splicing analysis on a homozygous substitution mutation, BAP1 c. 2054 A&T (p.Glu685Val), identified in an MPM cell line derived from a mesothelioma patient. The mutation occurred at the 3rd nucleotide from the 3' end of exon 16. RT-PCR, cloning and subsequent sequencing revealed several aberrant splicing products not observed in the controls: 1) a 4 bp deletion at the end of exon 16 in all clones derived from the major splicing product. The BAP1 c. 2054 A&T mutation introduced a new 5' splice site (GU), which resulted in the deletion of 4 base pairs and presumably protein truncation; 2) a variety of alternative splicing products that led to retention of different introns: introns 14-16; introns 15-16; intron 14 and intron 16; 3) partial intron 14 and 15 retentions caused by activation of alternative 3' splice acceptor sites (AG) in the introns. Taken together, we were unable to detect any correctly spliced mRNA transcripts in this cell line. These results suggest that aberrant splicing caused by this mutation is quite efficient as it completely abolishes normal splicing through creation of a novel 5' splice site and activation of cryptic splice sites. These data support the conclusion that BAP1 c.2054 A&T (p.E685V) variant is a pathogenic mutation and contributes to MPM through disruption of normal splicing.

The germline CDH1 c.48 G>C substitution contributes to cancer predisposition through generation of a pro-invasive mutation.

Mutation screening of CDH1 is a standard of care for patients who meet criteria for Hereditary Diffuse Gastric Cancer (HDGC). In this setting, the classification of the sequence variants found in CDH1 is a critical step for risk management of patients with HDGC. In this report, we describe a germline CDH1 c.48 G>C variant found in a 21 year old woman and her living great uncle, who were both diagnosed with gastric cancer and belong to a family with high incidence of this type of cancer. This variant occurs at the last nucleotide of exon 1 and presumably results in a Gln-to-His change at codon 16 (Q16H). We used cloning strategies to evaluate the effects on mRNA stability and found that 5/27 and 0/17 clones have the "C" mutant allele in patient and her great uncle, respectively. In vitro functional studies revealed that the germline missense mutant (Q16H) had a pro-invasive cell behavior. Both results (functional and clinical) support the conclusion that the CDH1 c.48 G>C (Q16H) variant contributes to HDGC through the generation of a pathogenic missense mutation with loss of anti-invasive function.

Immunohistochemical detection of ARID1A in colorectal carcinoma: loss of staining is associated with sporadic microsatellite unstable tumors with medullary histology and high TNM stage.

AT-rich interactive domain-containing protein 1A (ARID1A), a chromatin remodeling gene recently discovered to be a tumor suppressor in ovarian cancers, has been found to be mutated at low frequencies in many other tumors including colorectal carcinoma (CRC). An association between ARID1A alteration and DNA mismatch repair (MMR) deficiency has been implicated; understanding this association may facilitate the understanding of the role of ARID1A in the various tumors. In this pilot study, we analyzed the immunohistochemical expression of ARID1A in a consecutive series of 257 CRCs that fulfilled a set of relaxed criteria for Lynch syndrome screening; 59 (23%) were MMR deficient by immunohistochemistry (44 MLH1/PMS2 deficient, 9 MSH2/MSH6 deficient, 4 MSH6 deficient, and 2 PMS2 deficient). ARID1A loss was observed in 9% (22/257) of the cohort: 24% of MMR-deficient tumors (14/59, 13 of the 14 being MLH1/PMS2 deficient) and 4% of MMR-normal tumors (8/198) (P < .05). MLH1 (mutL homolog 1) promoter hypermethylation was observed in 10 of the 13 MLH1/PMS2-deficient/ARID1A-loss tumors, indicating an association between ARID1A loss and sporadic microsatellite unstable CRCs. Among the MMR-deficient cases, ARID1A loss correlated with old age (P = .04), poor tumor differentiation (P < .01), medullary histology (P < .01), and an increased rate of nodal and distant metastasis (P = .03); these patients also trended toward a worse 5-year overall survival. Among MMR-normal tumors, no differences in clinicopathological features were detected between the groups stratified by ARID1A. In conclusion, our results suggest that ARID1A loss may be linked to a specific subset of sporadic microsatellite unstable CRCs that may be medullary but is more likely to present with metastatic disease, warranting further investigation.