Project description:Non-alcoholic steatohepatitis (NASH)-related hepatocellular carcinoma (HCC) is increasing globally, but its molecular features are not well defined. We aimed to identify unique molecular traits characterizing NASH-HCC compared to other HCC aetiologies. We collected 80 NASH-HCC and 125 NASH samples from 5 institutions. Expression array (n=53 NASH-HCC; n=74 NASH) and whole exome sequencing (n=50 NASH-HCC) data were compared to HCCs of other aetiologies (n=184). Three NASH-HCC mouse models were analysed with RNAseq/expression-array (n=20). ACVR2A was silenced in HCC cells and proliferation assessed by MTT and colony formation assays. Mutational profiling of NASH-HCC tumours revealed TERT-promoter (56%), CTNNB1 (28%), TP53 (18%) and ACVR2A (10%) as the most-frequently mutated genes. ACVR2A mutation rates were higher in NASH-HCC than in other HCC aetiologies (10% versus 3%, p<0.05). In vitro, ACVR2A silencing prompted a significant increase in cell proliferation in HCC cells. We identified a novel mutational signature (MutSig-NASH-HCC) significantly associated with NASH-HCC (16% vs 2% in viral/alcohol-HCC, p=0.03). Tumour mutational burden (TMB) was higher in non-cirrhotic than in cirrhotic NASH-HCCs (1.45 versus 0.94 mutations/Mb; p<0.0017). Compared to other aetiologies of HCC, NASH-HCCs were enriched in bile and fatty acid signalling, oxidative stress and inflammation, and presented a higher fraction of Wnt/TGF-β proliferation subclass tumours (42% versus 26%, p=0.01) and a lower prevalence of the CTNNB1 subclass. Compared to other aetiologies, NASH-HCC showed a significantly higher prevalence of immunosuppressive cancer field. In three murine models of NASH-HCC key features of human NASH-HCC were preserved. NASH-HCCs display unique molecular features including higher rates of ACVR2A mutations and the presence of a newly identified mutational signature.

Project description:Histone acetylation involves the transfer of a two-carbon unit to nucleus as embedded in low-concentration metabolites. We find that lactate, a high-concentration metabolic by-product, can be a major carbon source for histone acetylation, through oxidation-dependent metabolism. Both in cells and in purified nucleus, 13C3-lactate carbons are incorporated into histone H4 (maximum incorporation: ~60%). In purified nucleus, this process depends on nucleus-localized lactate dehydrogenase (LDHA), the knockout of which abrogates the incorporation. Heterologous expression of nucleus-localized LDHA rescues the KO effect. Lactate itself increases histone acetylation, whereas inhibition of LDHA reduces the acetylation. In vitro and in vivo settings exhibit different lactate incorporation patterns, suggesting an influence of the microenvironment. Higher nuclear LDHA localization is observed in pancreatic cancer than in normal tissues, showing the disease relevance. Overall, lactate and nuclear LDHA can be major structural and regulatory players in the metabolism-epigenetics axis controlled by cell’s own or environmental status.

Project description:Monocarboxylate Transporter 4 (MCT4) is important for H+/lactate efflux from nucleus pulposus cells in the intervertebral disc of mice. We examined the transcriptomic profile of nucleus pulposus cells in wild-type and MCT4 global knock-out mice using microarrays.

Project description:ACVR2A attenuation impacts lactate production and hyperglycolytic conditions attracting regulatory T cells in hepatocellular carcinoma

Project description:Background: Exercise mimetics is a proposed class of therapeutics that specifically mimics or enhances the therapeutic effects of exercise. Muscle glycogen and lactate extrusion are critical for physical performance. The mechanism by which glycogen and lactate metabolism are manipulated during exercise remains unclear. This study aimed to assess the effect of miR-92b on the upregulation of exercise training-induced physical performance. Methods: Adeno-associated virus (AAV)-mediated skeletal muscle miR-92b overexpression in C57BLKS/J mice, and global knockout of miR-92b mice were used to explore the function of miR-92b in glycogen and lactate metabolism in skeletal muscle. AAV-mediated UGP2 or MCT4 knockdown in WT or miR-92 knockout mice was used to confirm whether miR-92b regulates glycogen and lactate metabolism in skeletal muscle through UGP2 and MCT4. Body weight, muscle weight, grip strength, running time and distance to exhaustion, and muscle histology were assessed. The expression levels of muscle mass-related and functionrelated proteins were analysed by immunoblotting or immunostaining. Results: Global knockout of miR-92b resulted in normal body weight and insulin sensitivity, but higher glycogen content before exercise exhaustion (0.8538 ± 0.0417 vs 1.043 ± 0.040, **P=0.0087), lower lactate levels after exercise exhaustion (4.133 ± 0.2589 vs 3.207 ± 0.2511, *P=0.0279), and better exercise capacity (running distance to exhaustion, 3616 ± 86.71 vs 4231 ± 90.29, ***P=0.0006; running time to exhaustion, 186.8 ± 8.027 vs 220.8 ± 3.156, **P=0.0028), as compared to those observed in the control mice. Mice skeletal muscle overexpressing miR-92b (both miR-92b-3p and miR-92b-5p) displayed lower glycogen content before exercise exhaustion (0.6318 ± 0.0231 vs 0.535 ± 0.0194, **P=0.0094), and higher lactate accumulation after exercise exhaustion (4.5 ± 0.2394 vs 5.467 ± 0.1892, *P=0.01), and poorer exercise capacity (running distance to exhaustion, 4005 ± 81.65 vs 3228 ± 149.8, ***P＜0.0001; running time to exhaustion, 225.5 ± 7.689 vs 163 ± 6.476, **P=0.001). Mechanistic analysis revealed that miR-92b-3p targets UDP-glucose pyrophosphorylase 2 (UGP2) expression to inhibit glycogen synthesis, while miR-92b-5p represses lactate extrusion by directly target monocarboxylate transporter 4 (MCT4). Knockdown of UGP2 and MCT4 reversed the effects observed in the absence of miR-92b in vivo. Conclusions: This study revealed regulatory pathways, including miR-92b-3p/UGP2/glycogen synthesis and miR-92b-5p/MCT4/lactate extrusion, which could be targeted to control exercise capacity.

Project description:LC3-associated phagocytosis (LAP) is critical in host defense against invading pathogens, but the molecular mechanism for LAP activation is still unclear. Here, we find programmed cell death 6 (PDCD6) as a negative regulator of LAP. PDCD6 deficiency in mice and macrophages induces enhanced bactericidal activity and LAP formation. In parallel, lactate dehydrogenase A (LDHA) activity and lactate production is induced in macrophages challenged with bacteria, Zymosan or Pam3CSK4, while genetic ablation or pharmacological inhibition of LDHA reduces lactate levels and impairs bactericidal activity in vivo and in vitro. Mechanistically, PDCD6 interacts with LDHA to downregulate lactate metabolism, leading to reduced RUBCN lactylation at lysine33 (K33). By contrast, PDCD6-deficiency increases RUBCN lactylation, thereby promotes RUBCN interaction with VPS34, LAP formation, and protective responses. Our results thus suggest a PDCD6-LDHA-lactate-RUBCN axis of innate immunity regulation that may both contribute to protection from infectious diseases and serve as targets for therapeutic development.

Project description:Sorafenib, the first targeted therapy for hepatocellular carcinoma (HCC), has been utilized in clinics over a decade. However, its effectiveness is severely hindered by the acquired drug resistance, the mechanisms of which remain largely elusive. In this study, we identify that carbonic anhydrase 2 (CA2) is a key regulator of sorafenib resistance. Mechanistically, sorafenib treatment decreases intracellular pH (pHi) by suppressing monocarboxylate transporter 4 (MCT4) expression, while high levels of CA2 counteract MCT4-mediated pHi dysregulation upon sorafenib treatment, maintaining pHi homeostasis to facilitate cell survival and sorafenib resistance. Targeting CA2 re-sensitizes resistant HCC cells to sorafenib both in vitro and in vivo. Importantly, analysis of clinical samples demonstrates a strong correlation between CA2 expression levels and the therapeutic efficacy of sorafenib in HCC patients. Our findings highlight the significance of CA2 in facilitating sorafenib resistance and propose targeting CA2 as a potential strategy for overcoming sorafenib resistance in HCC patients.

Project description:Higher 13C-lactate labeling was seen in the more aggressive tumors, including all triple negative breast cancers. There was a significant correlation between lactate labeling and expression of the monocarboxylate transporter (MCT1), which mediates tumor cell pyruvate uptake, and a weaker correlation with expression of LDHA, which catalyzes label exchange between the injected pyruvate and the endogenous lactate pool.

Project description:Monodelphis domestica LDHA, Monodelphis domestica lactate dehydrogenase A (LDHA), mRNA. [Source:RefSeq mRNA;Acc:NM_001032975], is expressed in 2 baseline experiment(s);

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.