Microsatellite Instability Is Associated With the Presence of Lynch Syndrome Pan-Cancer

Overview

Journal J Clin Oncol

Specialty Oncology

Date 2018 Oct 31

PMID 30376427

Citations 277

Authors

Alicia Latham

Preethi Srinivasan

Yelena Kemel

Jinru Shia

Chaitanya Bandlamudi

Diana Mandelker

Sumit Middha

Jaclyn Hechtman

Ahmet Zehir

Marianne Dubard-Gault

Christina Tran

Carolyn Stewart

Margaret Sheehan

Alexander Penson

Deborah DeLair

Rona Yaeger

Joseph Vijai

Semanti Mukherjee

Jesse Galle

Mark A Dickson

Yelena Janjigian

Eileen M OReilly

Neil Segal

Leonard B Saltz

Diane Reidy-Lagunes

Anna M Varghese

Dean Bajorin

Maria I Carlo

Karen Cadoo

Michael F Walsh

Martin Weiser

Julio Garcia Aguilar

David S Klimstra

Luis A Diaz Jr

Jose Baselga

Liying Zhang

Marc Ladanyi

David M Hyman

David B Solit

Mark E Robson

Barry S Taylor

Kenneth Offit

Michael F Berger

Zsofia K Stadler

Affiliations

Soon will be listed here.

Abstract

Purpose: Microsatellite instability (MSI) and/or mismatch repair deficiency (MMR-D) testing has traditionally been performed in patients with colorectal (CRC) and endometrial cancer (EC) to screen for Lynch syndrome (LS)-associated cancer predisposition. The recent success of immunotherapy in high-frequency MSI (MSI-H) and/or MMR-D tumors now supports testing for MSI in all advanced solid tumors. The extent to which LS accounts for MSI-H across heterogeneous tumor types is unknown. Here, we establish the prevalence of LS across solid tumors according to MSI status.

Methods: MSI status was determined using targeted next-generation sequencing, with tumors classified as MSI-H, MSI-indeterminate, or microsatellite-stable. Matched germline DNA was analyzed for mutations in LS-associated mismatch repair genes ( MLH1, MSH2, MSH6, PMS2, EPCAM). In patients with LS with MSI-H/I tumors, immunohistochemical staining for MMR-D was assessed.

Results: Among 15,045 unique patients (more than 50 cancer types), LS was identified in 16.3% (53 of 326), 1.9% (13 of 699), and 0.3% (37 of 14,020) of patients with MSI-H, MSI-indeterminate, and microsatellite-stable tumors, respectively ( P < .001). Among patients with LS with MSI-H/I tumors, 50% (33 of 66) had tumors other than CRC/EC, including urothelial, prostate, pancreas, adrenocortical, small bowel, sarcoma, mesothelioma, melanoma, gastric, and germ cell tumors. In these patients with non-CRC/EC tumors, 45% (15 of 33) did not meet LS genetic testing criteria on the basis of personal/family history. Immunohistochemical staining of LS-positive MSI-H/I tumors demonstrated MMR-D in 98.2% (56 of 57) of available cases.

Conclusion: MSI-H/MMR-D is predictive of LS across a much broader tumor spectrum than currently appreciated. Given implications for cancer surveillance and prevention measures in affected families, these data support germline genetic assessment for LS for patients with an MSI-H/MMR-D tumor, regardless of cancer type or family cancer history.

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