This study reveals that the abundance of 5'-tRF(Cys) increases during breast cancer metastasis, and this tRF promotes the oligomerization of Nucleolin and the formation of a transcript stabilizing ribonucleoprotein complex, protecting specific metabolic pathways and driving cancer progression.
Stress-induced cleavage of transfer RNAs (tRNAs) into tRNA-derived fragments (tRFs) occurs across organ-isms from yeast to humans; yet, its mechanistic underpinnings and pathological consequences remain poorly defined. Small RNA profiling revealed increased abundance of a cysteine tRNA fragment (5'-tRF(Cys)) during breast cancer metastatic progression. 5'-tRF(Cys) was required for efficient breast cancer metastatic lung colonization and cancer cell survival. We identified Nucleolin as the direct binding partner of 5'-tRF(Cys). 5'-tRF(Cys) promoted the oligomerization of Nucleolin and its bound metabolic transcripts Mthfd1l and Pafah1b1 into a higher-order transcript stabilizing ribonucleoprotein complex, which protected these transcripts from exonucleolytic degradation. Consistent with this, Mthfd1l and Pafah1b1 mediated pro-met-astatic and metabolic effects downstream of 5'-tRF(Cys)-impacting folate, one-carbon, and phosphatidylcho-line metabolism. Our findings reveal that a tRF can promote oligomerization of an RNA-binding protein into a transcript stabilizing ribonucleoprotein complex, thereby driving specific metabolic pathways underlying cancer progression.
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