Glycolytic requirement for NK cell cytotoxicity and cytomegalovirus control
Annelise Y. Mah, Armin Rashidi, Molly P. Keppel, Nermina Saucier, Emily K. Moore, Joshua B. Alinger, Sandeep K. Tripathy, Sandeep K. Agarwal, Emily K. Jeng, Hing C. Wong, Jeffrey S. Miller, Todd A. Fehniger, Emily M. Mace, Anthony R. French, Megan A. Cooper
Annelise Y. Mah, Armin Rashidi, Molly P. Keppel, Nermina Saucier, Emily K. Moore, Joshua B. Alinger, Sandeep K. Tripathy, Sandeep K. Agarwal, Emily K. Jeng, Hing C. Wong, Jeffrey S. Miller, Todd A. Fehniger, Emily M. Mace, Anthony R. French, Megan A. Cooper
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Research Article Immunology

Glycolytic requirement for NK cell cytotoxicity and cytomegalovirus control

Abstract

NK cell activation has been shown to be metabolically regulated in vitro; however, the role of metabolism during in vivo NK cell responses to infection is unknown. We examined the role of glycolysis in NK cell function during murine cytomegalovirus (MCMV) infection and the ability of IL-15 to prime NK cells during CMV infection. The glucose metabolism inhibitor 2-deoxy-ᴅ-glucose (2DG) impaired both mouse and human NK cell cytotoxicity following priming in vitro. Similarly, MCMV-infected mice treated with 2DG had impaired clearance of NK-specific targets in vivo, which was associated with higher viral burden and susceptibility to infection on the C57BL/6 background. IL-15 priming is known to alter NK cell metabolism and metabolic requirements for activation. Treatment with the IL-15 superagonist ALT-803 rescued mice from otherwise lethal infection in an NK-dependent manner. Consistent with this, treatment of a patient with ALT-803 for recurrent CMV reactivation after hematopoietic cell transplant was associated with clearance of viremia. These studies demonstrate that NK cell–mediated control of viral infection requires glucose metabolism and that IL-15 treatment in vivo can reduce this requirement and may be effective as an antiviral therapy.

Authors

Annelise Y. Mah, Armin Rashidi, Molly P. Keppel, Nermina Saucier, Emily K. Moore, Joshua B. Alinger, Sandeep K. Tripathy, Sandeep K. Agarwal, Emily K. Jeng, Hing C. Wong, Jeffrey S. Miller, Todd A. Fehniger, Emily M. Mace, Anthony R. French, Megan A. Cooper

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Figure 7

2DG decreases human NK cell cytotoxicity.

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2DG decreases human NK cell cytotoxicity. Human NK cells were isolated f...
Human NK cells were isolated from healthy donors, enriched using RosetteSep, and cryopreserved. Cells were later thawed and activated in 100 ng/ml human IL-15 for 24 hours in various concentrations of 2DG. (A) NK cells were washed and cocultured with K562 targets for 4 hours at various E:T ratios; representative killing assay shown (n = technical duplicate, representative of 6 donors across 4 experiments, mean with replicates shown). (B and C) NK cells from control conditions and 20–40 mM 2DG were cultured at a 2:1 ratio with K562 cells and imaged after 40 minutes. (B) Quantification of actin accumulation by area × intensity of synapse – (NK + target) (n = 41–43 conjugates/group, 1 experiment). (C) Quantification of distance from the microtubule organizing center (MTOC) to synapse in μm (n = 67–61 conjugates/group, 2 experiments). Gray boxes show median, 25th, and 75th percentiles. Neither B nor C was significant by 2-tailed t test or Kolmogorov-Smirnov test.