Aims: Chemoresistance results in poor outcomes of patients with gastric cancer (GC). This study aims to identify oxaliplatin resistance-related cell subpopulations in the tumor microenvironment (TME) and decipher the involved molecular mechanisms.
Methods: Through single-cell RNA sequencing, a unique ONECUT2+TFPI+ GC cell subset was identified in the oxaliplatin-resistant TME. The functional roles and molecular mechanisms of ONECUT2 in oxaliplatin resistance were investigated in cellular and mouse models. Therapeutic efficacy of small molecule inhibitor of ONECUT2 was also evaluated.
Results: The abundance of ONECUT2+TFPI+ GC cell subset was elevated in oxaliplatin-resistant GC tumors. ONECUT2 was up-regulated and associated with undesirable prognostic outcomes of patients with GC. ONECUT2 facilitated GC cell migration, stemness properties and oxaliplatin resistance. YTHDF2, an m6A "reader", was down-regulated in GC, and its overexpression facilitated ONECUT2 mRNA degradation through m6A modification. Furthermore, ONECUT2 transcriptionally activated TFPI through binding to its promoter. Small molecule inhibitor CSRM617 targeting ONECUT2 was well tolerated in GC mouse models, and could effectively improve therapeutic efficacy of oxaliplatin against GC.
Conclusions: Our study demonstrates that YTHDF2-mediated m6A modification of ONECUT2 results in stemness and oxaliplatin resistance in GC through transcriptionally activating TFPI, which provides a novel therapeutic target against oxaliplatin-resistant GC.
Keywords: Gastric cancer; ONECUT2; Oxaliplatin resistance; Stemness; m(6)A modification.
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