Mutational mechanisms shaping the coding and noncoding genome of germinal center derived B-cell lymphomas

Daniel Hübschmann,Peter Möller,Lorenz Trümper,Christoph Borst,Renée Beekman,Julia Richter,Ralf Küppers,Jules N A Kerssemakers,Enrique Carrillo De Santa Pau,Siegfried Haas,Christina Jäger-Schmidt,Cristina López,Wolfram Klapper,Helene Kretzmer,Alexander Claviez,Dieter Kube,Umut Toprak ,Jessica I Hoell,German Ott,Stéphanie Sungalee ,Benedikt Brors,Dido Lenze,Joost H.a Martens ,Chris Lawerenz,Volker Hovestadt,M Schillhabel ,Ole Ammerpohl,Sebastian M Waszak,Philipp Bruns,Andreas Rosenwald,Peter F Stadler,Stephan Stilgenbauer,Peter Lichter,Gero Doose,Stephan H Bernhart,Eva Reisinger,Martin‐Leo Hansmann ,Hans Binder,Matthias Bieg,Kortine Kleinheinz,Jan O Korbel,Daniel Rico,Dennis Karsch,Gregor Warsow,Nagarajan Paramasivam,Michael Hummel,Andrea Haake,Monika Szczepanowski,Sietse M Aukema,Hendrik G Stunnenberg,Bernhard Radlwimmer,Alfonso Valencia,Arndt Borkhardt,Marc A Weniger,Roland Eils,José I Martín‐Subero ,Anke Bergmann ,Marc Zapatka,Rabea Wagener,Steve Hoffmann,Naveed Ishaque,Markus Kreuz,Matthias Schlesner,Philip Rosenstiel,Markus Loeffler,Bingding Huang,Reiner Siebert

doi:10.1038/s41375-021-01251-z

Abstract

B cells have the unique property to somatically alter their immunoglobulin (IG) genes by V(D)J recombination, somatic hypermutation (SHM) and class-switch recombination (CSR). Aberrant targeting of these mechanisms is implicated in lymphomagenesis, but the mutational processes are poorly understood. By performing whole genome and transcriptome sequencing of 181 germinal center derived B-cell lymphomas (gcBCL) we identified distinct mutational signatures linked to SHM and CSR. We show that not only SHM, but presumably also CSR causes off-target mutations in non-IG genes. Kataegis clusters with high mutational density mainly affected early replicating regions and were enriched for SHM- and CSR-mediated off-target mutations. Moreover, they often co-occurred in loci physically interacting in the nucleus, suggesting that mutation hotspots promote increased mutation targeting of spatially co-localized loci (termed hypermutation by proxy). Only around 1% of somatic small variants were in protein coding sequences, but in about half of the driver genes, a contribution of B-cell specific mutational processes to their mutations was found. The B-cell-specific mutational processes contribute to both lymphoma initiation and intratumoral heterogeneity. Overall, we demonstrate that mutational processes involved in the development of gcBCL are more complex than previously appreciated, and that B cell-specific mutational processes contribute via diverse mechanisms to lymphomagenesis.

Highlights

B-cell neoplasms encompass more than 80% of lymphoid malignancies worldwide [1]
Whole genome sequencing data were obtained with a median coverage of 36.4 and 37.0 in tumors and controls, respectively, and interrogated for somatic mutations including single nucleotide variants (SNVs), insertions and deletions, structural variants (SVs), and copy number aberrations (CNAs)
Most B-cell lymphomas derive from germinal center (GC) B cells [15]

Summary

Introduction

The most common types of mature B-cell neoplasms are diffuse large B-cell lymphoma (DLBCL) and follicular lymphoma (FL), accounting for more than 50% of adult B-cell lymphomas Both are germinal center (GC)-derived B-cell lymphomas (gcBCL). Activated B cells can change the antibody isotype via class-switch recombination (CSR), which involves excision of a DNA fragment [9]. Both SHM and CSR are initiated by activation-induced cytidine deaminase (AID), which deaminates cytosine (C) to uracil (U) [10]. SHM introduces single nucleotide variants (SNVs) in the IG variable regions due to diverse errorprone DNA repair processes activated in response to AID activity. We dissect the mutational mechanisms shaping their genomes and use a comprehensive approach to elucidate how these mutate the driver genes

Material and methods

Results

Discussion

Compliance with ethical standards