Cytidine analogs are synthetic lethal with base excision repair default due to MBD4 deficiency.
Thomas ChabotFariba NematiAurélie HerbetteAlexandre DemeyerStéphane DayotOlivier GanierSamar AlsafadiSophie GardratPascale MarianiMarie LuporsiMaxime CorbéVincent ServoisNathalie CassouxDidier DecaudinSergio Roman RomanElaine Del NerySophie Piperno-NeumannMarc-Henri SternManuel J RodriguesPublished in: NPJ precision oncology (2022)
Inactivating mutations of MBD4 have been reported in subsets of various tumors. A deficiency of this DNA glycosylase, recognizing specifically T:G mismatch resulting from the deamination of methyl-cytosine, results in a hypermutated phenotype due to the accumulation of CpG>TpG transitions. Here, we hypothesize that the difference in DNA metabolism consecutive to MBD4 deficiency may result in specific cytotoxicities in MBD4-deficient tumor cells in a synthetic lethality fashion. After a large-scale drug repurposing screen, we show in two isogenic MBD4 knock-out cell models that the inactivation of MBD4 sensitizes cancer cells to cytidine analogs. We further confirm the exquisite activity of gemcitabine in an MBD4-deficient co-clinical model as (i) it completely prevented the development of an MBD4-deficient uveal melanoma patient-derived xenograft and (ii) treatment in the corresponding patient resulted in an exceptional tumor response. These data suggest that patients harboring MBD4-deficient tumors may be treated efficiently by cytidine analogs.
Keyphrases
- end stage renal disease
- chronic kidney disease
- emergency department
- dna methylation
- squamous cell carcinoma
- replacement therapy
- stem cells
- circulating tumor
- functional connectivity
- ejection fraction
- single cell
- gene expression
- prognostic factors
- radiation therapy
- cell free
- machine learning
- cell therapy
- rectal cancer
- endoplasmic reticulum stress
- smoking cessation
- adverse drug
- deep learning
- structure activity relationship