Project description:Lysine lactylation is a lactate-induced post-translational modification that links cellular metabolism to biological processes. However, the functional role of this histone mark in cancers remains largely unexplored, partly due to a lack of knowledge about its reader proteins. Here, we identify SMARCA5 as a bona fide effector of H3K18la. Transcriptomics, metabolomics and epigenetics analyses reveal numerous SMARCA5 target genes, enriched for metabolic regulators including HK2, PFKM, and LDHA. We further demonstrate that SMARCA5 facilitates glycolytic activity by recruiting MYC to the promoters of glycolytic genes. Elevated lactate derived from tumor glycolysis similarly increases H3K18la levels in CD8+ T cells and induces inhibitory receptor expression. Consequently, the glycolysis/H3K18la/SMARCA5/MYC positive feedback loop exacerbates tumor metabolism and promotes immune evasion. Pharmacologic inhibitor of LDHA that interrupts this loop attenuates immune evasion and sensitizes cancer cells to immunotherapy. Collectively, we propose SMARCA5 as a bona fide H3K18la reader that promotes tumor progression and immune escape by coupling cellular metabolism to epigenetic regulation.

Project description:The efficacy of immune checkpoint blockade (ICB) therapy in hepatocellular carcinoma (HCC) patients remains poor. This article aims to uncover the role and mechanism of SRSF10 in HCC immunotherapy. SRSF10 is upregulated in a variety of tumors and is associated with poor prognosis. SRSF10 binds to the 3’UTR region of MYB and enhances the stability of MYB RNA levels. This activation leads to increased transcriptional expression of key enzymes associated with glycolysis, such as GLUT1, HK1, and LDHA, resulting in higher lactate content in tumor cells. The lactate in tumor cells inside can increase histone lactylation so as to upregulated the expression of SRSF10. Besides, the lactate produced by tumors promotes lactylation of the histone H3K18la site upon transport into macrophages, which could activate transcription of M2 macrophage genes and increase protumour macrophage activity, so as to creating a suppressive immune microenvironment. Clinically, SRSF10 can be utilized as a biomarker to assess the resistance to immunotherapy in different types of solid tumors. The pharmacological targeting of SRSF10 with 1C8 has been shown to be effective in both murine and human preclinical models. In conclusion, we prove that the SRSF10/MYB/glycolysis/lactate axis is critical for triggering immune evasion and anti-PD-1 resistance.

Project description:T helper (Th) cell differentiation is driven by antigen and accessory signals that activate phosphoinositide 3-kinase (PI3K) to induce transcriptional and metabolic reprogramming including aerobic glycolysis (the Warburg effect). Here, we show that ATP generated through glycolysis fuels PI3K signaling to promote pathogenic Th17 cell responses. Mice with T cell-specific ablation of the glycolytic enzyme lactate dehydrogenase A (LDHA) were resistant to Th17 cell-mediated experimental autoimmune encephalomyelitis in association with defective T cell activation, migration, proliferation, and differentiation. LDHA deficiency crippled the cellular redox balance and inhibited ATP production causing attenuated phosphoinositide (3,4,5)-trisphosphate generation, and diminished activation of the Akt kinase and phosphorylation of its transcription factor target Foxo1. Th17 cell-specific expression of an Akt-insensitive Foxo1 mutant recapitulated the Th17 cell differentiation defects caused by LDHA deficiency. Thus, PI3K signaling and glycolytic bioenergetics constitute a positive feedback regulatory circuit essential for Th17 cell-mediated autoimmunity.

Project description:The “Warburg effect” describes the use of aerobic glycolysis by cancer cells to fuel their growth. Lactate dehydrogenase-A (LDHA) is key to this process and catalyzes the interconversion of pyruvate and lactate. Here we used a proteomic approach to identify LDHA as a binding partner of the tumor suppressor FLCN. Canonically, LDHA is thought to be a substrate-regulated enzyme, however our data show that FLCN uncompetitively inhibits LDHA activity by restricting movement of its active site loop. This inhibition appears to be critical in normal cells, as we show FLCN binds to and tightly regulates LDHA activity in order to preserve metabolic homeostasis. Pathogenic mutations of FLCN are associated with LDHA hyperactivity and kidney tumor formation, suggesting a mechanism for FLCN tumor suppressive function. We have identified a cell-permeant ten amino acid peptide based on the FLCN sequence that enters these tumors and inhibits LDHA ex vivo. In a broader context, renal cell carcinomas experience the Warburg effect and show FLCN dissociation from LDHA. Cells that experience this metabolic shift depend on the hyperactivity of LDHA, as previous work has shown attenuation or inhibition of LDHA leads to programmed cell death. Treating these cells with the FLCN-derived peptide causes apoptosis, strongly suggesting that the glycolytic shift of cancer cells is the result of FLCN inactivation or disassociation from LDHA. Taken together, FLCN-mediated inhibition of LDHA provides a new paradigm for the regulation of glycolysis.

Project description:Background: In acute kidney injury, macrophages play a major role in regulating inflammation. Classically activated macrophages (M1) undergo drastic metabolic reprogramming during their differentiation and upregulate the aerobic glycolysis pathway to fulfill their pro-inflammatory functions. NAD+ regeneration is crucial for the maintenance of glycolysis and the most direct pathway by which this occurs is via the fermentation of pyruvate to lactate, catalyzed by lactate dehydrogenase A (LDHA). Our previous study determined that LDHA is predominantly expressed in the proximal segments of the nephron in the mouse kidney and increases with hypoxia. This study investigates the potential of LDHA as a therapeutic target for inflammation by exploring its role in macrophage function in vitro. Methods: Bone-marrow-derived macrophages (BMDMs) were isolated from myeloid-specific LDHA knockout mice derived from crossbreeding LysM-Cre transgenic mice and LDHA floxed mice. RNA sequencing and LC-MS/MS metabolomics analyses were used in this study to determine the effect of LDHA deletion on BMDM following stimulation with IFN-γ. Results: LDHA deletion in IFN-γ BMDMs resulted in a significant alteration of the macrophage activation and functional pathways, and change in glycolytic, cytokine, and chemokine gene expression. Metabolite concentrations associated with pro-inflammatory macrophage profiles were diminished while anti-inflammatory-associated ones were increased in LDHA KO BMDMs. Glutamate and amino sugars metabolic pathways were significantly affected by the LDHA deletion. A combined muti-omics analysis highlighted changes in Rap1 signaling, cytokine-cytokine receptor interaction, focal adhesion, and MAPK signaling metabolism pathways. Conclusions: Deletion of LDHA in macrophages results in a notable reduction in the pro-inflammatory profile and concurrent upregulation of anti-inflammatory pathways. These findings suggest that LDHA could serve as a promising therapeutic target for inflammation, a key contributor to the pathogenesis of acute kidney injury.

Project description:Histone lysine lactylation is a physiologically relevant epigenetic pathway that can be stimulated by the Warburg effect and hypoxia-associated L-lactate. Nevertheless, the mechanism by which cells use L-lactate to generate lactyl-CoA, the cofactor for the modification, and how this process is regulated remain unknown. Here, we report the identification of GTPSCS as a lactyl-CoA ligase using biochemistry and cell biology approaches. The mechanism of this catalytic activity was elucidated using the crystallographic structure of GTPSCS in complex with L-lactate, followed by mutagenesis experiments. GTPSCS translocates into the nucleus and interacts with p300 to form a functional lactyltransferase to elevate histone H3 lysine 18 lactylation (H3K18la). This process is dependent on not only a nuclear localization signal in the GTPSCS G1 subunit but also acetylation at the G2 subunit residue K73 (for the interaction between GTPSCS and p300). GTPSCS-p300-mediated histone H3K18la promotes glioma cell proliferation and tumor formation in mice. In addition, histone H3K18la is positively associated with glioma grade and poor prognosis in glioma patients. The LDHA-GTPSCS-lactyltransferase-histone Kla axis thus represents a signal-stimulated epigenetic pathway that mediates the downstream impact of the Warburg effect and hypoxia

Project description:L-lactate was reported as a precursor that can label and stimulate histone lysine-N-L-lactylation (Kla), which represents a new epigenetic mark affecting gene expression directly via histone PTMs under conditions of high glycolysis, such as the Warburg effect. To investigate the genome-wide targeting of H3K18la, we performed ChIP-seq in H1299 cells using anti-H3K18la antibody. 50.6% of the H3K18la binding sites displayed enrichment close to -1kb promoter of genes. More importantly, our ChIP-seq data showed that H3K18la is enriched in many genes that related with replication processes, highlighted the importance of histone Kla involved in DNA replication.

Project description:Many cancers rely on glycolytic metabolism to fuel rapid proliferation. This has spurred interest in designing drugs that target tumor glycolysis such as AZD3965, a small molecule inhibitor of Monocarboxylate Transporter 1 (MCT1) currently undergoing Phase I evaluation for cancer treatment. Since MCT1 mediates proton-linked transport of monocarboxylates such as lactate and pyruvate across the plasma membrane (Halestrap and Meredith, 2004), AZD3965 is thought to block tumor growth through disruption of lactate transport and glycolysis. Here we show that MCT1 inhibition impairs proliferation of glycolytic breast cancer cells that express MCT4 via disruption of pyruvate rather than lactate export. We found that MCT1 expression is elevated in glycolytic breast tumors and cell lines as well as in malignant breast and lung tissues. High MCT1 expression predicts poor prognosis in breast and lung cancer patients. Stable knockdown and AZD3965-mediated inhibition of MCT1 promote oxidative metabolism. Acute inhibition of MCT1 reduces pyruvate export rate but does not consistently alter lactate transport or glycolytic flux in breast cancer cells that also express MCT4. Despite the lack of glycolysis impairment, MCT1 loss-of-function decreases breast cancer cell proliferation and blocks growth of mammary fat pad xenograft tumors. Our data suggest that MCT1 expression is elevated in glycolytic cancers to promote pyruvate export, which when inhibited enhances oxidative metabolism and reduces proliferation. This study presents an alternative molecular consequence of MCT1 inhibitors that further supports their use as anti-cancer therapeutics. Since MCT1 levels are elevated in glycolytic and malignant breast tumors, we hypothesized that MCT1 may contribute to the Warburg effect metabolic phenotype. To test this hypothesis, we generated whole genome microarray data from breast cancer cell lines either a) expressing a short hairpin (sh)RNA-mediated stable knockdown of MCT1; or b) treated for 24 hours with an MCT1 inhibitor (AZD3965). Scramble shRNA or DMSO were used as controls, and all conditions were analzed in triplicate. The cell lines used – HS578T, SUM149PT, and SUM159PT – are among the most glycolytic in a panel of 31 breast cancer cell lines.

Project description:Hexokinase catalyzes the first committed step in glucose metabolism by phosphorylating glucose to produce glucose-6-phosphate. Highly glycolytic proliferating cells such as cancer cells take advantage of HK2 expression to accelerate glucose metabolism even in the presence of oxygen. This acceleration not only provides sufficient glycolytic intermediates to support the anabolic demands of the cells but also inevitably accompanies increased formation of metabolic end products such as lactate. Currently, the effect of lactate caused by HK2-mediated metabolic alteration is largely unknown. A recent study found that lactate plays a role in an epigenetic alteration known as histone lactylation. Here, using RNA-seq and CUT&Tag chromatin profiling, we study the effect of HK2 and lactate on gene expression via histone lactylation (H3K18la).

Project description:Hexokinase catalyzes the first committed step in glucose metabolism by phosphorylating glucose to produce glucose-6-phosphate. Highly glycolytic proliferating cells such as cancer cells take advantage of HK2 expression to accelerate glucose metabolism even in the presence of oxygen. This acceleration not only provides sufficient glycolytic intermediates to support the anabolic demands of the cells but also inevitably accompanies increased formation of metabolic end products such as lactate. Currently, the effect of lactate caused by HK2-mediated metabolic alteration is largely unknown. A recent study found that lactate plays a role in an epigenetic alteration known as histone lactylation. Here, using RNA-seq and CUT&Tag chromatin profiling, we study the effect of HK2 and lactate on gene expression via histone lactylation (H3K18la).