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Lactate reprograms glioblastoma immunity through CBX3-regulated histone lactylation
Shuai Wang, Tengfei Huang, Qiulian Wu, Huairui Yuan, Xujia Wu, Fanen Yuan, Tingting Duan, Suchet Taori, Yingming Zhao, Nathaniel W. Snyder, Dimitris G. Placantonakis, Jeremy N. Rich
Shuai Wang, Tengfei Huang, Qiulian Wu, Huairui Yuan, Xujia Wu, Fanen Yuan, Tingting Duan, Suchet Taori, Yingming Zhao, Nathaniel W. Snyder, Dimitris G. Placantonakis, Jeremy N. Rich
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Research Article Metabolism Oncology

Lactate reprograms glioblastoma immunity through CBX3-regulated histone lactylation

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Abstract

Glioblastoma (GBM), an aggressive brain malignancy with a cellular hierarchy dominated by GBM stem cells (GSCs), evades antitumor immunity through mechanisms that remain incompletely understood. Like most cancers, GBMs undergo metabolic reprogramming toward glycolysis to generate lactate. Here, we show that lactate production by patient-derived GSCs and microglia/macrophages induces tumor cell epigenetic reprogramming through histone lactylation, an activating modification that leads to immunosuppressive transcriptional programs and suppression of phagocytosis via transcriptional upregulation of CD47, a “don’t eat me” signal, in GBM cells. Leveraging these findings, pharmacologic targeting of lactate production augments efficacy of anti-CD47 therapy. Mechanistically, lactylated histone interacts with the heterochromatin component chromobox protein homolog 3 (CBX3). Although CBX3 does not possess direct lactyltransferase activity, CBX3 binds histone acetyltransferase (HAT) EP300 to induce increased EP300 substrate specificity toward lactyl-CoA and a transcriptional shift toward an immunosuppressive cytokine profile. Targeting CBX3 inhibits tumor growth by both tumor cell–intrinsic mechanisms and increased tumor cell phagocytosis. Collectively, these results suggest that lactate mediates metabolism-induced epigenetic reprogramming in GBM that contributes to CD47-dependent immune evasion, which can be leveraged to augment efficacy of immuno-oncology therapies.

Authors

Shuai Wang, Tengfei Huang, Qiulian Wu, Huairui Yuan, Xujia Wu, Fanen Yuan, Tingting Duan, Suchet Taori, Yingming Zhao, Nathaniel W. Snyder, Dimitris G. Placantonakis, Jeremy N. Rich

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Figure 4

Histone lactylation regulates phagocytosis of GSCs by microglia and macrophages in vivo.

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Histone lactylation regulates phagocytosis of GSCs by microglia and macr...
(A) Representative bioluminescent images on days 7 and 21 of mice bearing tumors derived from CW468. Mice were treated with vehicle (PBS), NaLac (1 g/kg/d), DCA (150 mg/kg/d), or DCA (150 mg/kg/d) plus NaLac (1 g/kg/d) from day 7 until the experimental endpoint. (B) Quantification of bioluminescent signals in CW468 tumor-bearing mice at days 7 and 21 (n = 5/group; 2-way ANOVA, F[3, 32] = 17.19). (C) Kaplan-Meier survival curves of tumor-bearing mice implanted with CW468 cells treated with PBS vehicle, NaLac, DCA, or DCA plus NaLac from day 7 (n = 5/group; log-rank tests). (D) Representative flow cytometry plot of in vivo GSC phagocytosis by microglia in CW468 tumor-bearing mice treated with either vehicle (PBS), NaLac, DCA, or DCA plus NaLac. Tumor cells were identified with staining for human CD147. Murine microglia/macrophages were identified with CD11b. (E) Quantification of in vivo phagocytosis in CW468 tumor-bearing mice treated with either vehicle (PBS), NaLac, DCA, or DCA plus NaLac (n = 5/group; 1-way ANOVA; F[3, 8] = 114.4). **P < 0.01; ***P < 0.001; ****P < 0.0001.

Copyright © 2026 American Society for Clinical Investigation
ISSN: 0021-9738 (print), 1558-8238 (online)

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