Discovering novel germline genetic variants linked to severe fluoropyrimidine-related toxicity in- and outside DPYD

Jonathan E. Knikman, Qinglian Zhai, Carin A.T.C. Lunenburg, Linda M. Henricks, Stefan Böhringer, Maaike van der Lee, Femke M. de Man, Steven M. Offer, Shikshya Shrestha, Geert Jan Creemers, Arnold Baars, Vincent O. Dezentjé, Alexander L.T. Imholz, Frank J.F. Jeurissen, Johanna E.A. Portielje, Rob L.H. Jansen, Paul Hamberg, Helga J. Droogendijk, Miriam Koopman, Peter NieboerMarlène H.W. van de Poel, Caroline M.P.W. Mandigers, Ron H.N. van Schaik, Hans Gelderblom, Ron H.J. Mathijssen, Jan H.M. Schellens, Annemieke Cats, Henk Jan Guchelaar*, Jesse J. Swen

*Corresponding author for this work

Research output: Contribution to journalArticleAcademicpeer-review

Abstract

Background: The Alpe-DPD study (NCT02324452) demonstrated that prospective genotyping and dose-individualization using four alleles in DPYD (DPYD*2A/rs3918290, c.1236G > A/rs75017182, c.2846A > T/rs67376798 and c.1679 T > G/rs56038477) can mitigate the risk of severe fluoropyrimidine toxicity. However, this could not prevent all toxicities. The goal of this study was to identify additional genetic variants, both inside and outside DPYD, that may contribute to fluoropyrimidine toxicity. Methods: Biospecimens and data from the Alpe-DPD study were used. Exon sequencing was performed to identify risk variants inside DPYD. In silico and in vitro analyses were used to classify DPYD variants. A genome-wide association study (GWAS) with severe fluoropyrimidine-related toxicity was performed to identify variants outside DPYD. Association with severe toxicity was assessed using matched-pair analyses for the exon sequencing and logistic, Cox, and ordinal regression analyses for GWAS. Results: Twenty-four non-synonymous, frameshift, and splice site DPYD variants were detected in ten of 986 patients. Seven of these variants (c.1670C > T, c.1913 T > C, c.1925 T > C, c.506delC, c.731A > C, c.1740 + 1G > T, c.763 − 2A > G) were predicted to be deleterious. The carriers of either of these variants showed a trend towards a 2.14-fold (95% CI, 0.41–11.3, P = 0.388) increased risk of severe toxicity compared to matched controls (N = 30). After GWAS of 942 patients, no individual single nucleotide polymorphisms achieved genome-wide significance (P ≤ 5 × 10−8), however, five variants were suggestive of association (P < 5 × 10−6) with severe toxicity. Conclusions: Results from DPYD exon sequencing and GWAS analysis did not identify additional genetic variants associated with severe toxicity, which suggests that testing for single markers at a population level currently has limited clinical value. Identifying additional variants on an individual level is still promising to explain fluoropyrimidine-related severe toxicity. In addition, studies with larger samples sizes, in more diverse cohorts are needed to identify potential clinically relevant genetic variants related to severe fluoropyrimidine toxicity.

Original languageEnglish
Article number101
Number of pages11
JournalGenome Medicine
Volume16
Issue number1
DOIs
Publication statusPublished - 15 Aug 2024

Keywords

  • Dihydropyrimidine dehydrogenase
  • DPYD
  • Fluoropyrimidines
  • Personalized medicine
  • Pharmacogenetics

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