Integrating rare genetic variants into DPYD pharmacogenetic testing may help preventing fluoropyrimidine-induced toxicity.
Romain LarrueSandy FellahBenjamin HennartNaoual SabaouniNihad BoukroutCynthia Van der HauwaertClément DelageMeyling H CheokMichaël PerraisChristelle CauffiezDelphine AllorgeNicolas PottierPublished in: The pharmacogenomics journal (2024)
Variability in genes involved in drug pharmacokinetics or drug response can be responsible for suboptimal treatment efficacy or predispose to adverse drug reactions. In addition to common genetic variations, large-scale sequencing studies have uncovered multiple rare genetic variants predicted to cause functional alterations in genes encoding proteins implicated in drug metabolism, transport and response. To understand the functional importance of rare genetic variants in DPYD, a pharmacogene whose alterations can cause severe toxicity in patients exposed to fluoropyrimidine-based regimens, massively parallel sequencing of the exonic regions and flanking splice junctions of the DPYD gene was performed in a series of nearly 3000 patients categorized according to pre-emptive DPD enzyme activity using the dihydrouracil/uracil ([UH 2 ]/[U]) plasma ratio as a surrogate marker of DPD activity. Our results underscore the importance of integrating next-generation sequencing-based pharmacogenomic interpretation into clinical decision making to minimize fluoropyrimidine-based chemotherapy toxicity without altering treatment efficacy.
Keyphrases
- prognostic factors
- adverse drug
- genome wide
- oxidative stress
- decision making
- drug induced
- copy number
- single cell
- emergency department
- chronic kidney disease
- end stage renal disease
- ejection fraction
- transcription factor
- early onset
- newly diagnosed
- clinical decision support
- replacement therapy
- patient reported outcomes
- locally advanced
- diabetic rats
- rectal cancer
- oxide nanoparticles
- case control
- genome wide analysis