A Multiple Myeloma-specific Capture Sequencing Platform Discovers Novel Translocations and Frequent, Risk-associated Point Mutations in IGLL5

Overview

Journal Blood Cancer J

Date 2018 Mar 23

PMID 29563506

Citations 30

Authors

Brian S White

Irena Lanc

Julie ONeal

Harshath Gupta

Robert S Fulton

Heather Schmidt

Catrina Fronick

Edward A Belter Jr

Mark Fiala

Justin King

Greg J Ahmann

Mary DeRome

Elaine R Mardis

Ravi Vij

John F Dipersio

Joan Levy

Daniel Auclair

Michael H Tomasson

Affiliations

Soon will be listed here.

Abstract

Multiple myeloma (MM) is a disease of copy number variants (CNVs), chromosomal translocations, and single-nucleotide variants (SNVs). To enable integrative studies across these diverse mutation types, we developed a capture-based sequencing platform to detect their occurrence in 465 genes altered in MM and used it to sequence 95 primary tumor-normal pairs to a mean depth of 104×. We detected cases of hyperdiploidy (23%), deletions of 1p (8%), 6q (21%), 8p (17%), 14q (16%), 16q (22%), and 17p (4%), and amplification of 1q (19%). We also detected IGH and MYC translocations near expected frequencies and non-silent SNVs in NRAS (24%), KRAS (21%), FAM46C (17%), TP53 (9%), DIS3 (9%), and BRAF (3%). We discovered frequent mutations in IGLL5 (18%) that were mutually exclusive of RAS mutations and associated with increased risk of disease progression (p = 0.03), suggesting that IGLL5 may be a stratifying biomarker. We identified novel IGLL5/IGH translocations in two samples. We subjected 15 of the pairs to ultra-deep sequencing (1259×) and found that although depth correlated with number of mutations detected (p = 0.001), depth past ~300× added little. The platform provides cost-effective genomic analysis for research and may be useful in individualizing treatment decisions in clinical settings.

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