bims-tumime Biomed News
on Tumor microenvironment and metabolism
Issue of 2024‒06‒16
five papers selected by
Alex Muir, University of Chicago
  1. Metabolic Signaling in Cancer.
  2. Electron transport chain inhibition increases cellular dependence on purine transport and salvage.
  3. Targeting metabolic pathways to counter cancer immunotherapy resistance.
  4. Adipocytes and metabolism: Contributions to multiple myeloma.
  5. The Role and Treatment Strategies of Ammonia-Related Metabolism in Tumor Microenvironment.
  1. Cold Spring Harb Perspect Med. 2024 Jun 10. pii: a041544. [Epub ahead of print]
    Metabolic Signaling in Cancer.
    Laura V Pinheiro, Pedro Costa-Pinheiro, Kathryn E Wellen.
      Metabolic reprogramming in cancer allows cells to survive in harsh environments and sustain macromolecular biosynthesis to support proliferation. In addition, metabolites play crucial roles as signaling molecules. Metabolite fluctuations are detected by various sensors in the cell to regulate gene expression, metabolism, and signal transduction. Metabolic signaling mechanisms contribute to tumorigenesis by altering the physiology of cancer cells themselves, as well as that of neighboring cells in the tumor microenvironment. In this review, we discuss principles of metabolic signaling and provide examples of how cancer cells take advantage of metabolic signals to promote cell proliferation and evade the immune system, thereby contributing to tumor growth and progression.
    DOI:  https://doi.org/10.1101/cshperspect.a041544
  2. Cell Metab. 2024 Jun 07. pii: S1550-4131(24)00190-6. [Epub ahead of print]
    Electron transport chain inhibition increases cellular dependence on purine transport and salvage.
    Zheng Wu, Divya Bezwada, Feng Cai, Robert C Harris, Bookyung Ko, Varun Sondhi, Chunxiao Pan, Hieu S Vu, Phong T Nguyen, Brandon Faubert, Ling Cai, Hongli Chen, Misty Martin-Sandoval, Duyen Do, Wen Gu, Yuanyuan Zhang, Yuannyu Zhang, Bailey Brooks, Sherwin Kelekar, Lauren G Zacharias, K Celeste Oaxaca, Joao S Patricio, Thomas P Mathews, Javier Garcia-Bermudez, Min Ni, Ralph J DeBerardinis.
      Mitochondria house many metabolic pathways required for homeostasis and growth. To explore how human cells respond to mitochondrial dysfunction, we performed metabolomics in fibroblasts from patients with various mitochondrial disorders and cancer cells with electron transport chain (ETC) blockade. These analyses revealed extensive perturbations in purine metabolism, and stable isotope tracing demonstrated that ETC defects suppress de novo purine synthesis while enhancing purine salvage. In human lung cancer, tumors with markers of low oxidative mitochondrial metabolism exhibit enhanced expression of the salvage enzyme hypoxanthine phosphoribosyl transferase 1 (HPRT1) and high levels of the HPRT1 product inosine monophosphate. Mechanistically, ETC blockade activates the pentose phosphate pathway, providing phosphoribosyl diphosphate to drive purine salvage supplied by uptake of extracellular bases. Blocking HPRT1 sensitizes cancer cells to ETC inhibition. These findings demonstrate how cells remodel purine metabolism upon ETC blockade and uncover a new metabolic vulnerability in tumors with low respiration.
    Keywords:  HPRT1; NAD(+):NADH ratio; electron transport chain; metabolomics; purine metabolism; stable isotopes
    DOI:  https://doi.org/10.1016/j.cmet.2024.05.014
  3. Trends Immunol. 2024 Jun 13. pii: S1471-4906(24)00120-0. [Epub ahead of print]
    Targeting metabolic pathways to counter cancer immunotherapy resistance.
    Yuki Agarwala, Timothy A Brauns, Ann E Sluder, Mark C Poznansky, Yohannes Gemechu.
      Immunotherapies have revolutionized the treatment of certain cancers, but challenges remain in overcoming immunotherapy resistance. Research shows that metabolic modulation of the tumor microenvironment can enhance antitumor immunity. Here, we discuss recent preclinical and clinical evidence for the efficacy of combining metabolic modifiers with immunotherapies. While this combination holds great promise, a few key areas must be addressed, which include identifying the effects of metabolic modifiers on immune cell metabolism, the putative biomarkers of therapeutic efficacy, the efficacy of modifiers on tumors harboring metabolic heterogeneity, and the potential development of resistance due to tumor reliance on alternative metabolic pathways. We propose solutions to these problems and posit that assessing these parameters is crucial for considering the potential of metabolic modifiers in sensitizing tumors to immunotherapies.
    Keywords:  immunotherapy; immunotherapy resistance; metabolic reprogramming
    DOI:  https://doi.org/10.1016/j.it.2024.05.006
  4. J Bone Oncol. 2024 Jun;46 100609
    Adipocytes and metabolism: Contributions to multiple myeloma.
    Heather Fairfield, Michelle Karam, Allyson Schimelman, Ya-Wei Qiang, Michaela R Reagan.
      Obesity contributes to many cancers, including breast cancer and multiple myeloma, two cancers that often colonize the bone marrow (BM). Obesity often causes metabolic disease, but at the cellular level, there is uncertainty regarding how these shifts affect cellular phenotypes. Evidence is building that different types of fuel affect tumor cell metabolism, mitochondrial function, and signaling pathways differently, but tumor cells are also flexible and adapt to less-than ideal metabolic conditions, suggesting that single-pronged attacks on tumor metabolism may not be efficacious enough to be effective clinically. In this review, we describe the newest research at the pre-clinical level on how tumor metabolic pathways and energy sources affect cancer cells, with a special focus on multiple myeloma (MM). We also describe the known forward-feedback loops between bone marrow adipocytes (BMAds) and local tumor cells that support tumor growth. We describe how metabolic targets and transcription factors related to fatty acid (FA) oxidation, FA biosynthesis, glycolysis, oxidative phosphorylation (OXPHOS), and other pathways hold great promise as new vulnerabilities in myeloma cells. Specifically, we describe the importance of the acetyl-CoA synthetase (ACSS) and the acyl-CoA synthetase long chain (ACSL) families, which are both involved in FA metabolism. We also describe new data on the importance of lactate metabolism and lactate transporters in supporting the growth of tumor cells in a hypoxic BM microenvironment. We highlight new data showing the dependency of myeloma cells on the mitochondrial pyruvate carrier (MPC), which transports pyruvate to the mitochondria to fuel the tricarboxylic acid (TCA) cycle and electron transport chain (ETC), boosting OXPHOS. Inhibiting the MPC affects myeloma cell mitochondrial metabolism and growth, and synergizes with proteosome inhibitors in killing myeloma cells. We also describe how metabolic signaling pathways intersect established survival and proliferation pathways; for example, the fatty acid binding proteins (FABPs) affect MYC signaling and support growth, survival, and metabolism of myeloma cells. Our goal is to review the current the field so that novel, metabolic-focused therapeutic interventions and treatments can be imagined, developed and tested to decrease the burden of MM and related cancers.
    Keywords:  Adipocytes; Drug resistance; Fatty acids; Metabolism; Multiple myeloma
    DOI:  https://doi.org/10.1016/j.jbo.2024.100609
  5. Curr Gene Ther. 2024 Jun 10.
    The Role and Treatment Strategies of Ammonia-Related Metabolism in Tumor Microenvironment.
    Qizhen Ye, Dan Li, Yi Zou, Ying Yuan.
      Tumor cells achieve their adaptability through various metabolic reprogramming processes. Among them, ammonia, as a traditional metabolic waste, plays an increasingly important role in the tumor microenvironment along with its associated metabolites. Other cells in the microenvironment can also reshape the immune status of the microenvironment by regulating ammonia-related metabolism, and targeting this metabolic aspect has emerged as a potential strategy for tumor treatment. In this study, we have systematically reviewed the source and destination of ammonia in tumor cells, as well as the links between ammonia and other biological processes. We have also analyzed the ammonia-related metabolic regulation of other cells (including T cells, macrophages, dendritic cells, natural killer cells, myeloid-derived suppressor cells, and stromal cells) in the tumor microenvironment, and summarized the tumor treatment methods that target this metabolism. Through ammonia-related metabolic reprogramming, tumor cells obtain the energy they need for rapid growth and proliferation. Multiple immune cells and stromal cells in the microenvironment also interact with each other through this metabolic regulation, ultimately leading to immune suppression. Despite the heterogeneity of tumors and the complexity of cellular functions, further research into therapeutic interventions targeting ammonia-related metabolism is warranted. This review has focused on the role and regulation of ammonia-related metabolism in tumor cells and other cells in the microenvironment, and highlighted the efficacy and prospects of targeted ammonia-related metabolism therapy.
    Keywords:  Ammonia; Anti-tumor therapy; Immune cell; Metabolism; Reprogramming; Tumor microenvironment
    DOI:  https://doi.org/10.2174/0115665232301222240603100840
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