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Cancer-associated fibroblast-derived acetate promotes pancreatic cancer development by altering polyamine metabolism via the ACSS2-SP1-SAT1 axis.

Divya MurthyKuldeep S AttriSurendra K ShuklaRavi ThakurNina V ChaikaChunbo HeDezhen WangKanupriya JhaAneesha DasguptaRyan J KingScott E MulderJoshua SouchekTeklab GebregiworgisVikrant RaiRohit PatelTuo HuSandeep RanaSai Sundeep KollalaCamila PachecoPaul M GrandgenettFang YuVikas KumarAudrey J LazenbyAdrian R BlackSusanna V UlahannanAjay JainBarish H EdilDavid L KlinkebielRobert PowersAmarnath NatarajanMichael A HollingsworthKamiya MehlaQuan LySarika ChaudharyRosa F HwangKathryn E WellenPankaj K Singh
Published in: Nature cell biology (2024)
The ability of tumour cells to thrive in harsh microenvironments depends on the utilization of nutrients available in the milieu. Here we show that pancreatic cancer-associated fibroblasts (CAFs) regulate tumour cell metabolism through the secretion of acetate, which can be blocked by silencing ATP citrate lyase (ACLY) in CAFs. We further show that acetyl-CoA synthetase short-chain family member 2 (ACSS2) channels the exogenous acetate to regulate the dynamic cancer epigenome and transcriptome, thereby facilitating cancer cell survival in an acidic microenvironment. Comparative H3K27ac ChIP-seq and RNA-seq analyses revealed alterations in polyamine homeostasis through regulation of SAT1 gene expression and enrichment of the SP1-responsive signature. We identified acetate/ACSS2-mediated acetylation of SP1 at the lysine 19 residue that increased SP1 protein stability and transcriptional activity. Genetic or pharmacologic inhibition of the ACSS2-SP1-SAT1 axis diminished the tumour burden in mouse models. These results reveal that the metabolic flexibility imparted by the stroma-derived acetate enabled cancer cell survival under acidosis via the ACSS2-SP1-SAT1 axis.
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