bims-meprid Biomed News
on Metabolic-dependent epigenetic reprogramming in differentiation and disease
Issue of 2023‒04‒02
six papers selected by
Alessandro Carrer
Veneto Institute of Molecular Medicine
  1. Sirtuin-dependent metabolic and epigenetic regulation of macrophages during tuberculosis.
  2. Coenzyme A binding sites induce proximal acylation across protein families.
  3. Mapping the Metabolic Niche of Citrate Metabolism and SLC13A5.
  4. Decoding the crosstalk between mevalonate metabolism and T cell function.
  5. Malonylation of Acetyl-CoA carboxylase 1 promotes hepatic steatosis and is attenuated by ketogenic diet in NAFLD.
  6. Immunogenetic metabolomics revealed key enzymes that modulate CAR-T metabolism and function.
  1. Front Immunol. 2023 ;14 1121495
    Sirtuin-dependent metabolic and epigenetic regulation of macrophages during tuberculosis.
    Kangling Zhang, Mark L Sowers, Ellie I Cherryhomes, Vipul K Singh, Abhishek Mishra, Blanca I Restrepo, Arshad Khan, Chinnaswamy Jagannath.
      Macrophages are the preeminent phagocytic cells which control multiple infections. Tuberculosis a leading cause of death in mankind and the causative organism Mycobacterium tuberculosis (MTB) infects and persists in macrophages. Macrophages use reactive oxygen and nitrogen species (ROS/RNS) and autophagy to kill and degrade microbes including MTB. Glucose metabolism regulates the macrophage-mediated antimicrobial mechanisms. Whereas glucose is essential for the growth of cells in immune cells, glucose metabolism and its downsteam metabolic pathways generate key mediators which are essential co-substrates for post-translational modifications of histone proteins, which in turn, epigenetically regulate gene expression. Herein, we describe the role of sirtuins which are NAD+-dependent histone histone/protein deacetylases during the epigenetic regulation of autophagy, the production of ROS/RNS, acetyl-CoA, NAD+, and S-adenosine methionine (SAM), and illustrate the cross-talk between immunometabolism and epigenetics on macrophage activation. We highlight sirtuins as emerging therapeutic targets for modifying immunometabolism to alter macrophage phenotype and antimicrobial function.
    Keywords:  SIRTUIN; autophagy; glycolysis; histone modifications; human macrophages; metabolism
    DOI:  https://doi.org/10.3389/fimmu.2023.1121495
  2. Sci Rep. 2023 Mar 28. 13(1): 5029
    Coenzyme A binding sites induce proximal acylation across protein families.
    Chris Carrico, Andrew Cruz, Marius Walter, Jesse Meyer, Cameron Wehrfritz, Samah Shah, Lei Wei, Birgit Schilling, Eric Verdin.
      Lysine Nɛ-acylations, such as acetylation or succinylation, are post-translational modifications that regulate protein function. In mitochondria, lysine acylation is predominantly non-enzymatic, and only a specific subset of the proteome is acylated. Coenzyme A (CoA) can act as an acyl group carrier via a thioester bond, but what controls the acylation of mitochondrial lysines remains poorly understood. Using published datasets, here we found that proteins with a CoA-binding site are more likely to be acetylated, succinylated, and glutarylated. Using computational modeling, we show that lysine residues near the CoA-binding pocket are highly acylated compared to those farther away. We hypothesized that acyl-CoA binding enhances acylation of nearby lysine residues. To test this hypothesis, we co-incubated enoyl-CoA hydratase short chain 1 (ECHS1), a CoA-binding mitochondrial protein, with succinyl-CoA and CoA. Using mass spectrometry, we found that succinyl-CoA induced widespread lysine succinylation and that CoA competitively inhibited ECHS1 succinylation. CoA-induced inhibition at a particular lysine site correlated inversely with the distance between that lysine and the CoA-binding pocket. Our study indicated that CoA acts as a competitive inhibitor of ECHS1 succinylation by binding to the CoA-binding pocket. Together, this suggests that proximal acylation at CoA-binding sites is a primary mechanism for lysine acylation in the mitochondria.
    DOI:  https://doi.org/10.1038/s41598-023-31900-5
  3. Metabolites. 2023 Feb 23. pii: 331. [Epub ahead of print]13(3):
    Mapping the Metabolic Niche of Citrate Metabolism and SLC13A5.
    Fangfang Chen, Hanna Friederike Willenbockel, Thekla Cordes.
      The small molecule citrate is a key molecule that is synthesized de novo and involved in diverse biochemical pathways influencing cell metabolism and function. Citrate is highly abundant in the circulation, and cells take up extracellular citrate via the sodium-dependent plasma membrane transporter NaCT encoded by the SLC13A5 gene. Citrate is critical to maintaining metabolic homeostasis and impaired NaCT activity is implicated in metabolic disorders. Though citrate is one of the best known and most studied metabolites in humans, little is known about the consequences of altered citrate uptake and metabolism. Here, we review recent findings on SLC13A5, NaCT, and citrate metabolism and discuss the effects on metabolic homeostasis and SLC13A5-dependent phenotypes. We discuss the "multiple-hit theory" and how stress factors induce metabolic reprogramming that may synergize with impaired NaCT activity to alter cell fate and function. Furthermore, we underline how citrate metabolism and compartmentalization can be quantified by combining mass spectrometry and tracing approaches. We also discuss species-specific differences and potential therapeutic implications of SLC13A5 and NaCT. Understanding the synergistic impact of multiple stress factors on citrate metabolism may help to decipher the disease mechanisms associated with SLC13A5 citrate transport disorders.
    Keywords:  NaCT; SLC13A5; TCA cycle; citrate metabolism; citrate transport; compartmentalization; mass spectrometry; metabolic niche; mitochondria; tracing
    DOI:  https://doi.org/10.3390/metabo13030331
  4. Immunol Rev. 2023 Mar 31.
    Decoding the crosstalk between mevalonate metabolism and T cell function.
    Kelly T Kennewick, Steven J Bensinger.
      The mevalonate pathway is an essential metabolic pathway in T cells regulating development, proliferation, survival, differentiation, and effector functions. The mevalonate pathway is a complex, branched pathway composed of many enzymes that ultimately generate cholesterol and nonsterol isoprenoids. T cells must tightly control metabolic flux through the branches of the mevalonate pathway to ensure sufficient isoprenoids and cholesterol are available to meet cellular demands. Unbalanced metabolite flux through the sterol or the nonsterol isoprenoid branch is metabolically inefficient and can have deleterious consequences for T cell fate and function. Accordingly, there is tight regulatory control over metabolic flux through the branches of this essential lipid synthetic pathway. In this review we provide an overview of how the branches of the mevalonate pathway are regulated in T cells and discuss our current understanding of the relationship between mevalonate metabolism, cholesterol homeostasis and T cell function.
    Keywords:  T cells; cholesterol; isoprenoids; mevalonate pathway; statins
    DOI:  https://doi.org/10.1111/imr.13200
  5. Cell Rep. 2023 Mar 31. pii: S2211-1247(23)00330-3. [Epub ahead of print]42(4): 112319
    Malonylation of Acetyl-CoA carboxylase 1 promotes hepatic steatosis and is attenuated by ketogenic diet in NAFLD.
    Huanyi Cao, Qingxian Cai, Wanrong Guo, Qiao Su, Hancheng Qin, Tian Wang, Yingxin Xian, Longyi Zeng, Mengyin Cai, Haixia Guan, Sifan Chen, Hua Liang, Fen Xu.
      Protein post-translational modifications (PTMs) participate in important bioactive regulatory processes and therefore can help elucidate the pathogenesis of non-alcoholic fatty liver disease (NAFLD). Here, we investigate the involvement of PTMs in ketogenic diet (KD)-improved fatty liver by multi-omics and reveal a core target of lysine malonylation, acetyl-coenzyme A (CoA) carboxylase 1 (ACC1). ACC1 protein levels and Lys1523 malonylation are significantly decreased by KD. A malonylation-mimic mutant of ACC1 increases its enzyme activity and stability to promote hepatic steatosis, whereas the malonylation-null mutant upregulates the ubiquitination degradation of ACC1. A customized Lys1523ACC1 malonylation antibody confirms the increased malonylation of ACC1 in the NAFLD samples. Overall, the lysine malonylation of ACC1 is attenuated by KD in NAFLD and plays an important role in promoting hepatic steatosis. Malonylation is critical for ACC1 activity and stability, highlighting the anti-malonylation effect of ACC1 as a potential strategy for treating NAFLD.
    Keywords:  CP: Metabolism; Lysine malonylation; acetyl-CoA carboxylase 1; hepatic steatosis; ketogenic diet; non-alcoholic fatty liver disease
    DOI:  https://doi.org/10.1016/j.celrep.2023.112319
  6. bioRxiv. 2023 Mar 15. pii: 2023.03.14.532663. [Epub ahead of print]
    Immunogenetic metabolomics revealed key enzymes that modulate CAR-T metabolism and function.
    Paul Renauer, Jonathan J Park, Meizhu Bai, Arianny Acosta, Won-Ho Lee, Guang Han Lin, Yueqi Zhang, Xiaoyun Dai, Guangchuan Wang, Youssef Errami, Terence Wu, Paul Clark, Lupeng Ye, Quanjun Yang, Sidi Chen.
      Immune evasion is a critical step of cancer progression that remains a major obstacle for current T cell-based immunotherapies. Hence, we seek to genetically reprogram T cells to exploit a common tumor-intrinsic evasion mechanism, whereby cancer cells suppress T cell function by generating a metabolically unfavorable tumor microenvironment (TME). Specifically, we use an in silico screen to identify ADA and PDK1 as metabolic regulators, in which gene overexpression (OE) enhances the cytolysis of CD19-specific CD8 CAR-T cells against cognate leukemia cells, and conversely, ADA or PDK1 deficiency dampens such effect. ADA -OE in CAR-T cells improves cancer cytolysis under high concentrations of adenosine, the ADA substrate and an immunosuppressive metabolite in the TME. High-throughput transcriptomics and metabolomics in these CAR-Ts reveal alterations of global gene expression and metabolic signatures in both ADA- and PDK1- engineered CAR-T cells. Functional and immunological analyses demonstrate that ADA -OE increases proliferation and decreases exhaustion in α-CD19 and α-HER2 CAR-T cells. ADA-OE improves tumor infiltration and clearance by α-HER2 CAR-T cells in an in vivo colorectal cancer model. Collectively, these data unveil systematic knowledge of metabolic reprogramming directly in CAR-T cells, and reveal potential targets for improving CAR-T based cell therapy.Synopsis: The authors identify the adenosine deaminase gene (ADA) as a regulatory gene that reprograms T cell metabolism. ADA-overexpression (OE) in α-CD19 and α-HER2 CAR-T cells increases proliferation, cytotoxicity, memory, and decreases exhaustion, and ADA-OE α-HER2 CAR-T cells have enhanced clearance of HT29 human colorectal cancer tumors in vivo .
    DOI:  https://doi.org/10.1101/2023.03.14.532663
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