A sensitive and scalable microsatellite instability assay to diagnose constitutional mismatch repair deficiency by sequencing of peripheral blood leukocytes.

Richard Gallon,Tim Ripperger,Amedeo A Azizi,Harsh Sheth,Christian P Kratz,Daniel Rueda,Stefan Aretz,Barbara Mühlegger,Christine Hayes,John Burn,Iman Ragab,Gillian M Borthwick,Markus G Seidel,Michaela Nathrath,Johannes Zschocke,Karin Dahan,Benoît Florkin,Julia Taeubner,Stephan Lobitz,Katharina Wimmer,Thorsten Rosenbaum,Claudia Perne,Hagit Baris Feldman,Thomas Imschweiler,Manon Suerink,Michael S Jackson,Anne‐Laure Chong ,William D Foulkes ,Danuta Januszkiewicz‐Lewandowska ,Uğur Demırsoy ,Hans‐Jürgen Pander ,Stefanie‐Yvonne Zimmermann ,Sören‐Sebastian Wenzel ,Vanesa Pérez‐Alonso ,Mauro Santibanez‐Koref

doi:10.1002/humu.23721

Abstract

Constitutional mismatch repair deficiency (CMMRD) is caused by germline pathogenic variants in both alleles of a mismatch repair gene. Patients have an exceptionally high risk of numerous pediatric malignancies and benefit from surveillance and adjusted treatment. The diversity of its manifestation, and ambiguous genotyping results, particularly from PMS2, can complicate diagnosis and preclude timely patient management. Assessment of low‐level microsatellite instability in nonneoplastic tissues can detect CMMRD, but current techniques are laborious or of limited sensitivity. Here, we present a simple, scalable CMMRD diagnostic assay. It uses sequencing and molecular barcodes to detect low‐frequency microsatellite variants in peripheral blood leukocytes and classifies samples using variant frequencies. We tested 30 samples from 26 genetically‐confirmed CMMRD patients, and samples from 94 controls and 40 Lynch syndrome patients. All samples were correctly classified, except one from a CMMRD patient recovering from aplasia. However, additional samples from this same patient tested positive for CMMRD. The assay also confirmed CMMRD in six suspected patients. The assay is suitable for both rapid CMMRD diagnosis within clinical decision windows and scalable screening of at‐risk populations. Its deployment will improve patient care, and better define the prevalence and phenotype of this likely underreported cancer syndrome.

Highlights

Constitutional mismatch repair deficiency (CMMRD) is a highly penetrant cancer‐predisposition syndrome, caused by biallelic germline pathogenic variants affecting one of the four mismatch repair (MMR) genes: MLH1, MSH2, MSH6, or PMS2
To assess whether or not the assay would be able to discriminate between Lynch syndrome and CMMRD, we tested DNA extracted from the peripheral blood leukocytes (PBLs) of 40 adult patients with confirmed pathogenic variants in one allele of an MMR gene
We have previously shown that short (7–12 bp) mononucleotide repeats facilitate highly accurate microsatellite instability (MSI) testing of colorectal cancers (CRCs) (Redford et al, 2018), and here show that they can detect low‐frequency microsatellite length variants in PBLs to diagnose CMMRD, using a single molecule molecular inversion probes (smMIPs)‐ based assay

Summary

METHODS

A sensitive and scalable microsatellite instability assay to diagnose constitutional mismatch repair deficiency by sequencing of peripheral blood leukocytes. Funding information Cancer Research UK, Grant/Award Number: C569/A24991; The Barbour Foundation, Grant/Award Numbers: 328081, NA; AsCaP Catalyst Award; CaPP3 Clinical Research Committee Late Phase Award, Grant/Award Number: A15934; Dutch Cancer Society, Grant/Award Number: UL‐2012–5515

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CONFLICT OF INTERESTS