Short Commentary - (2024) Volume 10, Issue 2
Received: 25-Mar-2024, Manuscript No. icoa-24-135491;
Editor assigned: 27-Mar-2024, Pre QC No. P-135491;
Reviewed: 13-Apr-2024, QC No. Q-76780;
Revised: 20-Apr-2024, Manuscript No. R-65652;
Published:
27-Apr-2024
, DOI: 10.37421/2469-9756.2024.10.235
Citation: Sawdi, Woani. “Boosting Natural Killer Cell Efficacy via Glycolysis Inhibition: A New Strategy for Serial Killing.” Immunochem Immunopathol 10 (2024): 235.
Copyright: © 2024 Sawdi W. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Central to their function is their ability to execute "serial killing," whereby a single NK cell can eliminate multiple target cells successively, enhancing their cytotoxic potency. This phenomenon is tightly regulated by metabolic processes, particularly glycolysis and the primary energy-generating pathway in NK cells. Glycolysis, while essential for NK cell activation and effector functions, can also impose limitations on their longevity and serial killing capacity. The reliance on glycolysis for energy production leads to rapid depletion of metabolic intermediates, impairing NK cell persistence and functionality within the tumor microenvironment or during prolonged viral infections. Hence, modulating glycolytic metabolism emerges as a promising strategy to enhance NK cell-mediated immunity [1].
Enhancing Natural Killer (NK) cell efficiency through glycolysis restriction represents a ground-breaking paradigm shift in immunotherapy, offering a novel approach to bolstering the innate immune response against cancer and viral infections. Natural Killer cells, a subset of cytotoxic lymphocytes, play a pivotal role in immune surveillance, identifying and eliminating aberrant cells without the need for prior sensitization, thus serving as the body's first line of defense against malignant transformation and viral invasion. resulting in enhanced anti-tumor activity in preclinical models. These inhibitors disrupt glucose uptake or glycolytic flux, forcing NK cells to rely more on mitochondrial respiration for energy production. Consequently, NK cells exhibit increased persistence and cytotoxicity, leading to improved tumor control and immune surveillance. Furthermore, genetic manipulation of metabolic regulators offers another avenue to modulate NK cell metabolism and enhance their effector functions. By overexpressing or silencing key metabolic genes, researchers can fine-tune the balance between glycolysis and oxidative phosphorylation in NK cells, thereby optimizing their anti-tumor or anti-viral responses. For instance, knockout of the glycolytic enzyme Phosphofructokinase-2/Fructose- 2,6-Bisphosphatase 3 (PFKFB3) in NK cells has been shown to dampen glycolysis while promoting mitochondrial respiration, resulting in potentiated cytotoxicity and prolonged survival in tumor-bearing mice [2].
Recent studies have demonstrated that restricting glycolysis can potentiate NK cell effector functions and prolong their survival, thereby augmenting their ability to execute serial killing. By targeting key enzymes and transporters involved in glycolysis, such as hexokinase and glucose transporters, researchers have successfully manipulated NK cell metabolism to favor oxidative phosphorylation, a more sustainable energy-generating pathway. This metabolic reprogramming not only enhances NK cell longevity but also preserves their cytotoxic potential, enabling them to sustain prolonged attacks against tumor cells or virally infected targets. One approach to glycolysis restriction involves pharmacological interventions targeting glycolytic enzymes or metabolic checkpoints. Small molecule inhibitors, such as 2-Deoxyglucose (2-DG) and lonidamine, have been shown to suppress glycolysis in NK cells, Natural Killer (NK) cells, a critical component of the innate immune system, play a pivotal role in host defense against infected or malignant cells. Their ability to recognize and eliminate abnormal cells without prior sensitization makes them a promising target for immunotherapy against various diseases, including cancer. Recent studies have shed light on the metabolic regulation of NK cell function, highlighting the significance of glycolysis in dictating their effector responses [3].
Interestingly, restricting glycolysis has emerged as a novel strategy to enhance NK cell cytotoxicity and augment their serial killing capacity. Glycolysis, the metabolic pathway responsible for the conversion of glucose into pyruvate, serves as a major energy source for immune cells, including NK cells. Upon activation, NK cells rapidly up regulate glycolysis to meet their increased energy demands and support effector functions such as cytokine production and cytotoxicity. However, sustained glycolytic activity can lead to metabolic exhaustion and impair NK cell functionality, ultimately compromising their ability to eradicate target cells efficiently. The therapeutic potential of enhancing NK cell efficiency through glycolysis restriction extends beyond cancer immunotherapy to encompass viral infections, where NK cells serve as key players in the early defense against viral pathogens. By bolstering NK cell-mediated viral clearance, glycolysis restriction offers a promising strategy to combat emerging viral threats, including influenza, HIV and SARS-CoV-2. Preclinical studies have shown that manipulating NK cell metabolism can enhance their ability to control viral replication and reduce viral load, highlighting the translational relevance of metabolic immunotherapy in combating infectious diseases. Furthermore, recent advances in genetic engineering have enabled the development of Chimeric Antigen Receptor (CAR) NK cells with enhanced cytotoxicity and specificity against tumor cells. By incorporating glycolysis-targeting strategies into CAR NK cell design, researchers have demonstrated improved tumor killing and prolonged persistence in preclinical models, paving the way for the clinical translation of these engineered cells as a promising immunotherapy option [4,5].
Future studies aimed at elucidating the precise mechanisms underlying metabolic reprogramming in NK cells and optimizing therapeutic interventions hold immense promise for advancing the field of immunometabolism and translating these findings into clinical applications. By restricting glycolysis, either through pharmacological inhibition, metabolic reprogramming, or genetic engineering, researchers can potentiate NK cell cytotoxicity and improve their serial killing capacity against tumor cells. Future studies aimed at elucidating the underlying mechanisms and optimizing therapeutic strategies hold promise for the development of novel immunotherapies that harness the metabolic vulnerabilities of NK cells to combat cancer and other diseases.
None.
There are no conflicts of interest by author.
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