CD8 memory T cells have a bioenergetic advantage that underlies their rapid recall ability

A characteristic of memory T (TM) cells is their ability to mount faster and stronger responses to reinfection than naïve T (TN) cells do in response to an initial infection. However, the mechanisms that allow this rapid recall are not completely understood. We found that CD8 TM cells have more mitochondrial mass than CD8 TN cells and, that upon activation, the resulting secondary effector T (TE) cells proliferate more quickly, produce more cytokines, and maintain greater ATP levels than primary effector T cells. We also found that after activation, TM cells increase oxidative phosphorylation and aerobic glycolysis and sustain this increase to a greater extent than TN cells, suggesting that greater mitochondrial mass in TM cells not only promotes oxidative capacity, but also glycolytic capacity. We show that mitochondrial ATP is essential for the rapid induction of glycolysis in response to activation and the initiation of proliferation of both TN and TM cells. We also found that fatty acid oxidation is needed for TM cells to rapidly respond upon restimulation. Finally, we show that dissociation of the glycolysis enzyme hexokinase from mitochondria impairs proliferation and blocks the rapid induction of glycolysis upon T-cell receptor stimulation in TM cells. Our results demonstrate that greater mitochondrial mass endows TM cells with a bioenergetic advantage that underlies their ability to rapidly recall in response to reinfection.

[1]  D. Roos,et al.  Changes in the carbohydrate metabolism of mitogenically stimulated human peripheral lymphocytes. II. Relative importance of glycolysis and oxidative phosphorylation on phytohaemagglutinin stimulation. , 1973, Experimental cell research.

[2]  D. Roos,et al.  Changes in the carbohydrate metabolism of mitogenically stimulated human peripheral lymphocytes. 3. Stimulation by tuberculin and allogeneic cells. , 1973, Experimental Eye Research.

[3]  E. McCabe,et al.  Targeting of hexokinase 1 to liver and hepatoma mitochondria. , 1992, Proceedings of the National Academy of Sciences of the United States of America.

[4]  J. Wilson,et al.  Interaction of mitochondrially bound rat brain hexokinase with intramitochondrial compartments of ATP generated by oxidative phosphorylation and creatine kinase. , 1992, Archives of biochemistry and biophysics.

[5]  R. Beitner,et al.  Clotrimazole and bifonazole detach hexokinase from mitochondria of melanoma cells. , 1998, European journal of pharmacology.

[6]  John Eric Wilson,et al.  Further studies on the coupling of mitochondrially bound hexokinase to intramitochondrially compartmented ATP, generated by oxidative phosphorylation. , 1998, Archives of biochemistry and biophysics.

[7]  H. Eisen,et al.  Functional differences between memory and naive CD8 T cells. , 1999, Proceedings of the National Academy of Sciences of the United States of America.

[8]  A. Cerwenka,et al.  Naive, effector, and memory CD8 T cells in protection against pulmonary influenza virus infection: homing properties rather than initial frequencies are crucial. , 1999, Journal of immunology.

[9]  Henrique Veiga-Fernandes,et al.  Response of naïve and memory CD8+ T cells to antigen stimulation in vivo , 2000, Nature Immunology.

[10]  M. V. Vander Heiden,et al.  In the absence of extrinsic signals, nutrient utilization by lymphocytes is insufficient to maintain either cell size or viability. , 2000, Molecular cell.

[11]  S. Krauss,et al.  Signaling takes a breath--new quantitative perspectives on bioenergetics and signal transduction. , 2001, Immunity.

[12]  E. Wherry,et al.  Differential Sensitivity of Naive and Memory CD8+ T Cells to Apoptosis in Vivo1 , 2002, The Journal of Immunology.

[13]  Susan M. Kaech,et al.  Molecular and Functional Profiling of Memory CD8 T Cell Differentiation , 2002, Cell.

[14]  Rustom Antia,et al.  Lineage relationship and protective immunity of memory CD8 T cell subsets , 2003, Nature Immunology.

[15]  Susan M. Kaech,et al.  TCR Signal Transduction in Antigen-Specific Memory CD8 T Cells1 , 2003, The Journal of Immunology.

[16]  R. Ramsay,et al.  Carnitine acyltransferases and their influence on CoA pools in health and disease. , 2004, Molecular aspects of medicine.

[17]  O. Bathe,et al.  Initial Antigen Encounter Programs CD8+ T Cells Competent to Develop into Memory Cells That Are Activated in an Antigen-Free, IL-7- and IL-15-Rich Environment1 , 2004, The Journal of Immunology.

[18]  C. Thompson,et al.  Hexokinase-mitochondria interaction mediated by Akt is required to inhibit apoptosis in the presence or absence of Bax and Bak. , 2004, Molecular cell.

[19]  Craig B. Thompson,et al.  Fuel feeds function: energy metabolism and the T-cell response , 2005, Nature Reviews Immunology.

[20]  D. Brdiczka Interaction of mitochondrial porin with cytosolic proteins , 1990, Experientia.

[21]  A. Wells,et al.  Epigenetic Remodeling of the IL-2 and IFN-γ Loci in Memory CD8 T Cells Is Influenced by CD4 T Cells1 , 2006, The Journal of Immunology.

[22]  R. Ahmed,et al.  Rapid Demethylation of the IFN-γ Gene Occurs in Memory but Not Naive CD8 T Cells1 , 2006, The Journal of Immunology.

[23]  R. Deberardinis,et al.  Phosphatidylinositol 3-Kinase-dependent Modulation of Carnitine Palmitoyltransferase 1A Expression Regulates Lipid Metabolism during Hematopoietic Cell Growth* , 2006, Journal of Biological Chemistry.

[24]  R. Ahmed,et al.  Rapid demethylation of the IFN-gamma gene occurs in memory but not naive CD8 T cells. , 2006, Journal of immunology.

[25]  Russell G. Jones,et al.  Revving the engine: signal transduction fuels T cell activation. , 2007, Immunity.

[26]  M. Bevan,et al.  Requirements for CD8 T-cell priming, memory generation and maintenance. , 2007, Current opinion in immunology.

[27]  A. Wells,et al.  Cutting Edge: Chromatin Remodeling as a Molecular Basis for the Enhanced Functionality of Memory CD8 T Cells1 , 2008, The Journal of Immunology.

[28]  S. Jameson,et al.  The antigen-specific CD8+ T cell repertoire in unimmunized mice includes memory phenotype cells bearing markers of homeostatic expansion , 2009, The Journal of experimental medicine.

[29]  D. Farber Biochemical signaling pathways for memory T cell recall. , 2009, Seminars in immunology.

[30]  D. Nicholls,et al.  Neuronal Glutamate and Gabaa Receptor Function in Health and Disease Spare Respiratory Capacity, Oxidative Stress and Excitotoxicity Glutamate as an Excitotoxin the Role of Oxidative Stress , 2022 .

[31]  Hao Shen,et al.  Quick to remember, slow to forget: rapid recall responses of memory CD8+ T cells , 2010, Cell Research.

[32]  Min Wu,et al.  Bioenergetic profile experiment using C2C12 myoblast cells. , 2010, Journal of visualized experiments : JoVE.

[33]  R. Schnellmann,et al.  A high-throughput respirometric assay for mitochondrial biogenesis and toxicity. , 2010, Analytical biochemistry.

[34]  J. Harty,et al.  Naive, effector and memory CD8 T-cell trafficking: parallels and distinctions. , 2011, Immunotherapy.

[35]  G. V. D. Windt,et al.  Metabolic switching and fuel choice during T‐cell differentiation and memory development , 2012, Immunological reviews.

[36]  G. V. D. van der Windt,et al.  Mitochondrial respiratory capacity is a critical regulator of CD8+ T cell memory development. , 2012, Immunity.

[37]  Claire Redin,et al.  A Mitochondrial Pyruvate Carrier Required for Pyruvate Uptake in Yeast, Drosophila, and Humans , 2012, Science.

[38]  J. Harty,et al.  Population Dynamics of Naive and Memory CD8 T Cell Responses after Antigen Stimulations In Vivo , 2012, The Journal of Immunology.

[39]  B. Faubert,et al.  Posttranscriptional Control of T Cell Effector Function by Aerobic Glycolysis , 2013, Cell.

[40]  Pathophysiological Consequences of TAT-HKII Peptide Administration Are Independent of Impaired Vascular Function and Ensuing Ischemia , 2013, Circulation research.