Clinical Validation of a Targeted Next-Generation Sequencing Panel for Lymphoid Malignancies.

Lymphoid malignancies are a heterogeneous group of hematological disorders characterized by a diverse range of morphologic, immunophenotypic, and clinical features. Next-generation sequencing (NGS) is increasingly being applied to delineate the complex nature of these malignancies and identify high-value biomarkers with diagnostic, prognostic, or therapeutic benefit. However, there are various challenges in using NGS routinely to characterize lymphoid malignancies, including pre-analytic issues, such as sequencing DNA from formalin-fixed, paraffin-embedded tissue, and optimizing the bioinformatic workflow for accurate variant calling and filtering. This study reports the clinical validation of a custom capture-based NGS panel to test for molecular markers in a range of lymphoproliferative diseases and histiocytic neoplasms. The fully validated clinical assay represents an accurate and sensitive tool for detection of single-nucleotide variants and small insertion/deletion events to facilitate the characterization and management of patients with hematologic cancers specifically of lymphoid origin.

MICon Contamination Detection Workflow for Next-Generation Sequencing Laboratories Using Microhaplotype Loci and Supervised Learning.

Innovation in sequencing instrumentation is increasing the per-batch data volumes and decreasing the per-base costs. Multiplexed chemistry protocols after the addition of index tags have further contributed to efficient and cost-effective sequencer utilization. With these pooled processing strategies, however, comes an increased risk of sample contamination. Sample contamination poses a risk of missing critical variants in a patient sample or wrongly reporting variants derived from the contaminant, which are particularly relevant issues in oncology specimen testing in which low variant allele frequencies have clinical relevance. Small custom-targeted next-generation sequencing (NGS) panels yield limited variants and pose challenges in delineating true somatic variants versus contamination calls. A number of popular contamination identification tools have the ability to perform well in whole-genome/exome sequencing data; however, in smaller gene panels, there are fewer variant candidates for the tools to perform accurately. To prevent clinical reporting of potentially contaminated samples in small next-generation sequencing panels, we have developed MICon (Microhaplotype Contamination detection), a novel contamination detection model that uses microhaplotype site variant allele frequencies. In a heterogeneous hold-out test cohort of 210 samples, the model displayed state-of-the-art performance with an area under the receiver-operating characteristic curve of 0.995.

SERPINA1 Full-Gene Sequencing Identifies Rare Mutations Not Detected in Targeted Mutation Analysis.

Genetic α-1 antitrypsin (AAT) deficiency is characterized by low serum AAT levels and the identification of causal mutations or an abnormal protein. It needs to be distinguished from deficiency because of nongenetic causes, and diagnostic delay may contribute to worse patient outcome. Current routine clinical testing assesses for only the most common mutations. We wanted to determine the proportion of unexplained cases of AAT deficiency that harbor causal mutations not identified through current standard allele-specific genotyping and isoelectric focusing (IEF). All prospective cases from December 1, 2013, to October 1, 2014, with a low serum AAT level not explained by allele-specific genotyping and IEF were assessed through full-gene sequencing with a direct sequencing method for pathogenic mutations. We reviewed the results using American Council of Medical Genetics criteria. Of 3523 cases, 42 (1.2%) met study inclusion criteria. Pathogenic or likely pathogenic mutations not identified through clinical testing were detected through full-gene sequencing in 16 (38%) of the 42 cases. Rare mutations not detected with current allele-specific testing and IEF underlie a substantial proportion of genetic AAT deficiency. Full-gene sequencing, therefore, has the ability to improve accuracy in the diagnosis of AAT deficiency.

Heterogenous MSH6 loss is a result of microsatellite instability within MSH6 and occurs in sporadic and hereditary colorectal and endometrial carcinomas.

Mismatch-repair (MMR) immunohistochemistry is used to detect tumor MMR deficiency associated with high-level microsatellite instability (MSI). Rare tumors show heterogenous loss of mutS homolog 6 (MSH6) with immunohistochemistry, defined by areas of retained staining and separate areas of complete loss of staining. To investigate the clinical interpretation of this phenomenon, we identified 22 cases of heterogenous MSH6 loss interpreted at Mayo Clinic from January 2001 through December 2012 and reviewed histologic features, MSH6 and other MMR immunohistochemistry, and accompanying MSI testing results (n=20). Heterogenous MSH6 loss was seen in colorectal carcinoma (n=18), endometrial carcinoma (n=3), and sebaceous neoplasm (n=1). In the 18 colorectal carcinoma cases, it accompanied complete loss of mutL homolog 1 (MLH1) or PMS2, or both. Heterogenous MSH6 loss was characterized by MSI and MSH6 C8 tract instability in treatment-naive cases and showed mucinous or signet-ring zones in one quarter of cases. Two cases status post neoadjuvant chemoradiation showed heterogenous MSH6 loss but were microsatellite and C8 tract stable. C8 tracts were unstable in 2 of 4 MSH6-associated Lynch syndrome (LS) tumors, but all 4 showed complete MSH6 loss on immunohistochemistry. Further, 12 such MSH6-associated LS cases showed complete MSH6 loss. In conclusion, heterogenous MSH6 loss is uncommon, usually caused by instability in MSH6 exon 5 polycytosine tract, and not associated with germline MSH6 mutation. Although heterogenous MSH6 loss provides evidence against germline MSH6 mutation, patients whose tumors exhibit this immunolabeling pattern may have LS due to a defect in a different MMR gene.

Systemic transthyretin amyloidosis in a patient with bent spine syndrome.

Wild-type and mutant transthyretin (TTR) are implicated in systemic amyloidosis (ATTR). Myopathy is a rare complication of ATTR amyloidosis, however no patient with bent spine syndrome secondary to ATTR amyloidosis has been reported so far. We present the first case of bent spine syndrome in a patient with wild-type ATTR amyloidosis who also had concomitant Alzheimer's disease.