Combined inhibition of CTPS1 and ATR is a metabolic vulnerability in p53-deficient myeloma cells

Romane Durand; Céline Bellanger; Géraldine Descamps; Christelle Dousset; Sophie Maïga; Jennifer Derrien; Laura Thirouard; Louise Bouard; Hélène Asnagli; Philip Beer; Andrew Parker; Patricia Gomez-Bougie; Marie-Claire Devilder; Philippe Moreau; Cyrille Touzeau; Agnès Moreau-Aubry; David Chiron; Catherine Pellat-Deceunynck

doi:10.1002/hem3.70016

Combined inhibition of CTPS1 and ATR is a metabolic vulnerability in p53-deficient myeloma cells

Hemasphere. 2024 Oct 8;8(10):e70016. doi: 10.1002/hem3.70016. eCollection 2024 Oct.

Authors

Romane Durand¹, Céline Bellanger¹, Géraldine Descamps¹, Christelle Dousset¹, Sophie Maïga¹, Jennifer Derrien¹, Laura Thirouard¹, Louise Bouard¹, Hélène Asnagli², Philip Beer², Andrew Parker², Patricia Gomez-Bougie¹, Marie-Claire Devilder¹, Philippe Moreau¹, Cyrille Touzeau¹, Agnès Moreau-Aubry¹, David Chiron¹, Catherine Pellat-Deceunynck¹

Affiliations

¹ Nantes Université, INSERM, CHU Nantes CNRS, Université d'Angers, CRCI2NA Nantes France.
² Step Pharma Saint-Genis-Pouilly France.

Abstract

In multiple myeloma, as in B-cell malignancies, mono- and especially bi-allelic TP53 gene inactivation is a high-risk factor for treatment resistance, and there are currently no therapies specifically targeting p53 deficiency. In this study, we evaluated if the loss of cell cycle control in p53-deficient myeloma cells would confer a metabolically actionable vulnerability. We show that CTP synthase 1 (CTPS1), which encodes a CTP synthesis rate-limiting enzyme essential for DNA and RNA synthesis in lymphoid cells, is overexpressed in samples from myeloma patients displaying a high proliferation rate (high MKI67 expression) or a low p53 score (synonymous with TP53 deletion and/or mutation). This overexpression of CTPS1 was associated with reduced survival in two cohorts. Using scRNA-seq analysis in 24 patient samples, we further demonstrate that myeloma cells in the S or G2/M phase display high CTPS1 expression. Pharmacological inhibition of CTPS1 by STP-B induced cell cycle arrest in early S phase in isogenic NCI-H929 or XG7 TP53 ^+/+, TP53 ^-/-, and TP53 ^R175H/R175H cells and in a TP53 ^-/R123STOP patient sample. The functional annotation of transcriptional changes in 10 STP-B-treated myeloma cell lines revealed a decrease in protein translation and confirmed the blockade of cells into the S phase. The pharmacological inhibition of ATR, which governs the intrinsic S/G2 checkpoint, in STP-B-induced S-phase arrested cells synergistically induced cell death in TP53 ^+/+, TP53 ^-/-, and TP53 ^R175H/R175H isogenic cell lines (Bliss score >15). This combination induced replicative stress and caspase-mediated cell death and was highly effective in resistant/refractory patient samples with TP53 deletion and/or mutation and in TP53 ^-/- NCI-H929 xenografted NOD-scid IL2Rgamma mice. Our in vitro, ex vivo, and in vivo data provide the rationale for combined CTPS1 and ATR inhibition for the treatment of p53-deficient patients.