MS023

PRMT1 inhibitor MS023 reduces xenograft metastasis with low toxicity. These findings establish a hypoxia-PRMT1-vimentin axis, identifying vimentin R64 aDMA as a metastatic regulator. Inhibiting PRMT1 represents a promising anti-metastasis strategy.

The PRMT1 inhibitor, MS023, effectively cured this PRMT1-driven leukemia...Furthermore, administering the glucose analog 2-deoxy-D-glucose delayed AMKL progression and promoted cell differentiation. Ectopic expression of Cpt1a rescued the proliferation of 6133 cells ectopically expressing PRMT1 in the glucose-minus medium. In conclusion, PRMT1 upregulates glycolysis and downregulates fatty acid oxidation to enhance the proliferation capability of AMKL cells. .

Inhibiting PRMT6 with MS023 or mutating the RBM39 methylation site enhances Indisulam sensitivity in NSCLC and significantly improves its anti-tumor efficacy. Our findings identify methylated RBM39 as a key biomarker of Indisulam resistance and suggest a potential therapeutic strategy for NSCLC.

Among these, MS023, a PRMT inhibitor, showed the greatest synergy with cisplatin and etoposide across various SCLC cell lines. Additionally, MS023 enhanced the effects of IR and the PARP inhibitor talazoparib, both in vitro and in vivo. Therefore, targeting PRMT1 in combination with DNA-damaging therapies presents a promising strategy to improve treatment outcomes for SCLC.

Among them, only GSK3368715 advanced to clinical trials but was discontinued in phase I due to inadequate efficacy and thrombosis toxicity. Notably, as anticipated, CM112 could target PRMT1's nonenzymatic function by downregulating the stability of the orphan receptor TR3, an effect not observed with the PRMT1 inhibitor MS023, that is in consistence with the previous findings. Taken together, CM112 represents a valuable tool for elucidating the unknown, methyltransferase-independent roles of PRMT1 in disease progression and pave the way for developing more potent and drug like PRMT1 degraders in future.

Pharmacological inhibition of PRMT1 activity by MS023 remarkably eliminates LSCs and prolongs the survival of CML mice...PRMT1 augments the global protein synthesis via RPL29 in CML LSCs. Taken together, the findings provide new evidence that histone arginine methylation modification regulates protein synthesis in LSCs and highlight PRMT1 as a valuable druggable target for patients with CML.

PRMT1-specific proteomics reveals an interactome rich in RNA binding proteins and further investigation indicates significant widespread disruptions in mRNA metabolism with both MS023 treatment and PRMT1 knockdown, resulting in R-loop accumulation and DNA damage over time. Our data supports PRMT1 as a target in ccRCC and informs a mechanism-based strategy for translational development.

Targeting type-I PRMT can potentially improve immunotherapeutic efficacies in patients with TNBC. By enhancing the tumor immunogenicity and promoting a more favorable immune microenvironment, this combined approach may enable more patients with TNBC to benefit from immunotherapies.

The elevated expression of PRMT1 in relapsed/refractory patients underscores its potential as a target for overcoming treatment resistance. Moreover, our results highlight the efficacy of MS023 as a promising therapeutic agent against MM, offering new avenues for therapeutic approaches in relapsed/refractory MM.

High-risk genotypes maintained elevated sensitivity to SF3B inhibition, but conferred differential response to novel classes of spliceosome modulators, with STAG2 but not RUNX1 loss selectively promoting response to type I PRMTs inhibitor MS023. By contrast, CHK1 inhibitor Prexasertib was highly selective for SF3B1-mutant cells irrespective of co-mutations, inhibiting growth and cell cycle progression...In conclusion, progression from low-risk SF3B1-mutant MDS to high-risk disease is mediated by molecularly distinct trajectories driven by RUNX1 and STAG2 mutations that converge on expansion of the HSC compartment. Moreover, clonal progression is associated with genotype-specific drug responses and increased resistance to standard agents, and ongoing studies are elucidating how genetic and epigenetic states affect therapeutic responses.