mTORC1 and mTORC2 selectively regulate CD8+ T cell differentiation (original) (raw)
TSC2 integrates signals to regulate CD8+ effector function. TSC2 negatively regulates mTORC1 activity by acting as a GAP for the mTORC1-activitating GTPase RHEB (20). Upon phosphorylation by AKT or ERK, TSC2 is inactivated, thus leading to increased mTORC1 activity (8). In order to dissect how mTORC1 integrates signals in CD8+ T cells, we created mice in which TSC2 is selectively deleted in T cells (Cd4-Cre Tsc2fl/fl mice, herein referred to as T-Tsc2–/– mice) (Supplemental Figure 1A; supplemental material available online with this article; doi:10.1172/JCI77746DS1). Consistent with its role in negatively regulating mTORC1 activity, Tsc2 deletion in CD8+ T cells resulted in elevated phosphorylation of ribosomal S6 kinase 1 (S6K1), ribosomal S6, and 4E-BP1 under both unstimulated and TCR-stimulated conditions (Figure 1A and Supplemental Figure 1B) (21). mTORC2 activity, as assessed by phosphorylation of AKT at S473, was still intact in T-Tsc2–/– CD8+ T cells following TCR stimulation, albeit slightly reduced from WT levels (Figure 1A). Phenotypic analysis of T-Tsc2–/– mice revealed normal percentages and absolute numbers of T and B cells but a decreased CD8+ to CD4+ T cell ratio (Figure 1B and Supplemental Figure 1, C–E). As TSC2 is deleted after the double-positive stage of thymic development, we suspect that these altered CD4/CD8 ratios reflect post-thymic events. Further analysis revealed that T-Tsc2–/– CD8+ and CD4+ T cells have an increased CD44hiCD62Llo population, indicative of an activated phenotype (Figure 1C). Consistent with this activated phenotype, T-Tsc2–/– CD8+ and CD4+ T cells exhibited enhanced proliferation upon TCR engagement compared with WT cells (Figure 1D).
Tsc2 deletion in CD8+ T cells yields a hyperactivated phenotype. WT and T-Tsc2–/– splenocytes were harvested from 6-week-old mice. (A) mTORC1 and mTORC2 activity was assessed by immunoblot analysis from isolated CD8+ T cells left unstimulated or after 3-hour αCD3/αCD28 stimulation. (B) Flow cytometric analysis of CD4 and CD8 expression gated from CD3+ cells and the mean percentage and absolute number of CD8+ T cells (n = 9). (C) Flow cytometric analysis of CD44 and CD62L expression gated from the CD8+ population, with statistics shown to the right for both CD8+ and CD4+ T cells (n = 9). (D) CFSE-labeled splenocytes from WT and T-Tsc2–/– mice were stimulated with αCD3. CFSE dilution of CD8+ and CD4+ T cell populations was determined following 24, 48, and 72 hours of stimulation. Data are representative of at least 3 independent experiments. For the box-and-whiskers plots, the whiskers represent the minimum and maximum values, the box boundaries represent the 25th and 75th percentiles, and the middle line is the median value. *P < 0.05, **P < 0.01, ***P < 0.001, Mann-Whitney t tests.
The role of TSC2 in T cells has yet to be described. Recent reports have examined the role of TSC1 in T cells and have observed increases in apoptosis in TSC1-deficient T cells (13–16). The increased apoptosis was associated with decreased AKT activity and decreased expression of the antiapoptotic proteins, BCL-2 and BCL-XL. In contrast, ex vivo survival and activation-induced cell death were equivalent in T-Tsc2–/– and WT CD8+ T cells (Supplemental Figure 1, F and G). Unlike that observed in Tsc1–/– T cells, T-Tsc2–/– CD8+ T cells had equivalent levels of BCL-2 and BCL-XL when compared with those in WT CD8+ T cells (Supplemental Figure 1, H and I). Thus, while TSC1 deletion leads to increased cell death in T cells, TSC2 deletion results in enhanced proliferation and activation. Mechanistically, these differences seem to reflect the fact that the Tsc1–/– T cells lack mTORC2 activity, as indicated by impaired phosphorylation of AKT at S473 (13, 14, 16), while in T-Tsc2–/– CD8+ T cells, AKT activity was relatively intact (Figure 1A). Additionally, TSC1 deficiency resulted in a loss of TSC2 protein, while TSC1 expression was intact in T-Tsc2–/– cells (Supplemental Figure 1J) (22).
Next, we wanted to determine the effect of TSC2 deficiency on the function of CD8+ effector T cells. As expected, T-Tsc2–/– CD8+ T cells demonstrated enhanced mTORC1 activation but intact mTORC2 signaling (Figure 2, A and B). Furthermore, upon restimulation, T-Tsc2–/– CD8+ T cells exhibited enhanced production of IFN-γ and TNF-α, in addition to increased granzyme B expression (Figure 2C). This increase in IFN-γ production was detected in T-Tsc2–/– CD8+ T cells by 24 hours after initial stimulation (Supplemental Figure 2A). Furthermore, an increase in IFN-γ production was also detected in T-Tsc2–/– CD4+ T cells (Supplemental Figure 2B).
mTORC1 activity is required to promote CD8+ effector T cell responses in vitro. (A) mTORC1 activity was assessed by flow cytometric analysis of phosphorylated S6S235/236 expression from WT, T-Tsc2–/–, and T-Rheb–/– purified CD8+ T cells stimulated (+S) for 48 hours with αCD3/αCD28 compared with unstimulated WT controls (WT NS). The mean fluorescence intensity (MFI) for each genotype is shown in the upper corner. (B) Purified CD8+ T cells were collected from WT, T-Rheb–/–, or T-Tsc2–/– mice. mTORC2 activity was assessed by immunoblot analysis from unstimulated cells or after 1.5-hour stimulation with αCD3/αCD28. (C) Splenocytes were stimulated in vitro with αCD3 for 48 hours and then expanded in media supplemented with IL-2 for 5 days. On day 5, cells were restimulated and intracellular production of IFN-γ, TNF-α, and granzyme B (GzmB) was measured by flow cytometry. Plots are gated from the CD8+ population. (D) Cytokine production and (E) CFSE dilution were determined from purified naive CD8+ WT and T-Tsc2–/– CD8+ T cells stimulated in vitro. Plots were gated from the CD8+ population. CFSE expression was measured 48 hours after stimulation. Nonstimulated controls shown as gray histograms. (F) As in C, CD127 expression of the CD8+ population was assessed by flow cytometry prior to restimulation. Data are representative of at least 3 independent experiments.
To determine whether the enhanced effector function observed in T-Tsc2–/– CD8+ T cells was due to previous activation, we assessed cytokine production of sorted naive CD8+ T cells. Stimulation of naive T-Tsc2–/– CD8+ T cells resulted in elevated IFN-γ and TNF-α production, compared with that in stimulated naive WT CD8+ T cells (Figure 2D), in addition to increased proliferation (Figure 2E). Thus, while T cells from T-Tsc2–/– mice have a propensity to have an activated phenotype, the enhanced effector function and proliferative capacity of T-Tsc2–/– CD8+ T cells is not simply a consequence of previous activation.
As constitutive activation of mTORC1, through Tsc2 deletion, resulted in enhanced effector generation, we also wanted to determine whether mTORC1 activity was required for the generation of CD8+ effector T cells. To this end, we assessed effector function of T cells deficient in RHEB (Cd4-Cre Rhebfl/fl cells, herein referred to as T-Rheb–/– CD8+ T cells) (17, 23). RHEB is a small GTPase that is negatively regulated by the GAP activity of TSC2 and plays a critical role in the immediate activation of mTORC1 (10). T-Rheb–/– CD8+ T cells have reduced mTORC1 activity but intact mTORC2 signaling (Figure 2, A and B). Upon stimulation, T-Rheb–/– CD8+ T cells have markedly diminished expression of IFN-γ, TNF-α, and granzyme B when compared with that of WT T cells (Figure 2C). The inability of T-Rheb–/– CD8+ T cells to produce cytokines was not due to a proliferative defect, as T-Rheb–/– CD8+ T cells are capable of dividing, albeit at a delayed rate compared with that of WT cells, upon stimulation (Supplemental Figure 2A). T-Rheb–/– CD8+ T cells also demonstrated expression of activation markers CD69 and CD44 that was equivalent to that in WT and T-Tsc2–/– cells, suggesting that they do not have a defect in TCR stimulation (Supplemental Figure 2C). Interestingly, while T-Rheb–/– CD8+ T cells express decreased levels of effector molecules, they exhibited increased expression of CD127 (IL-7Rα receptor), which is critical for CD8+ memory survival (Figure 2F) (24).
Next, we moved to an in vivo model. WT, T-Rheb–/–, and T-Tsc2–/– mice were infected with a recombinant vaccinia virus that expresses ovalbumin (vaccinia-OVA), and 6 days later, the generation and function of OVA-specific CD8+ effector T cells was determined using OVA tetramer (H-2 kb/ SIINFEKL) staining. T-Tsc2–/– mice exhibited a robust increase in the number of activated antigen-specific CD8+ T cells compared with that of WT mice (Figure 3A). OVA-specific T-Tsc2–/– CD8+ T cells exhibited increased expression of KLRG1, a marker of terminally differentiated effector CD8+ T cells (Figure 3B and ref. 25), and robust IFN-γ and TNF-α production (Figure 3C). Consistent with an enhanced effector phenotype, OVA-specific CD8+ T cells from T-Tsc2–/– mice had markedly increased expression of T-bet, a transcription factor associated with CD8+ effector phenotype (Supplemental Figure 2D and ref. 26). Furthermore, T-Tsc2–/– CD8+ T cells demonstrated high cytolytic function, as determined by an in vivo cytotoxic T lymphocyte (CTL) assay (Figure 3D). In contrast, T-Rheb–/– CD8+ T cells, which have reduced mTORC1 signaling, have reduced numbers of antigen-specific T cells; expressed decreased levels of KLRG1, IFN-γ, TNF-α, and T-bet; and demonstrated decreased cytolytic function (Figure 3 and Supplemental Figure 2D). However, similar to our in vitro findings, OVA-specific T-Rheb–/– CD8+ T cells demonstrated elevated expression of CD127 compared with WT cells, while OVA-specific T-Tsc2–/– CD8+ T cells had the lowest expression (Supplemental Figure 2E). Thus, hyperactivation of mTORC1 leads to enhanced accumulation of potent CD8+ T effector cells in vivo_,_ while mTORC1 deficiency promotes CD127 expression.
mTORC1 activity is required for effector generation in vivo. WT, T-Rheb–/–, and T-Tsc2–/– mice were infected with 1 × 106 PFU vaccinia-OVA. On day 6, splenocytes were harvested. (A) Percentage of antigen-specific CD8+ T cells from day 6 infected mice was determined by flow cytometric analysis of H-2 kb/SIINFEKL tetramer staining (OVA tet). Plots were gated from the CD8+ population. Graphs depict the percentage of tetramer+ cells from the CD8+ population and the absolute number of tetramer+ cells (n = 16). (B) KLRG1 expression was assessed from the tetramer+ population, with statistics shown to the right (n = 16). (C) Cytokine production was assessed from the CD44+CD8+ splenic populations after ex vivo stimulation with SIINFEKL peptide. The graph depicts the percentage of double-producing cells (n = 16). (D) Functional analysis of CD8+ T cells by an in vivo CTL assay 6 days after vaccinia-OVA infection. Plots depict CFSEhi SIINFEKL peptide–pulsed targets and CFSElo control targets recovered from splenocytes harvested 10 hours after target transfer, with statistics shown to the right (n = 18). Data are representative of at least 3 independent experiments. For the box-and-whiskers plots, the whiskers represent the minimum and maximum values, the box boundaries represent the 25th and 75th percentiles, and the middle line is the median value. *P < 0.05, **P < 0.01, ***P < 0.001, ANOVA.
Next, we crossed all genotypes onto the OT-I background, so that the mice expressed a TCR specific for the OVA MHC class I peptide, SIINFEKL. OT-I+ WT, T-Rheb–/–, and T-Tsc2–/– mice all have similar development of SIINFEKL-specific CD8+ T cells, with 98% of CD8+ splenocytes expressing the Vβ5.1/Vβ5.2 TCR (Supplemental Figure 3A). OT-I+ WT, T-Rheb–/–, and T-Tsc2–/– CD8+ T cells congenically marked with CD90.1 were adoptively transferred into WT CD90.2+ recipients that were infected with vaccinia-OVA. Six days after infection, the percentage of OT-I+ splenocytes was assessed. Consistent with our endogenous findings, T-Tsc2–/– CD8+ T cells exhibited dramatically enhanced numbers of antigen-specific cells and increased BrdU uptake, in addition to increased KLRG1 expression and effector cytokine production (Figure 4A and Supplemental Figure 3B). In contrast, CD8+ T cells from T-Rheb–/– mice demonstrated markedly impaired expansion, diminished KLRG1 expression, reduced production of effector cytokines IFN-γ and TNF-α, and reduced BrdU uptake (Figure 4A and Supplemental Figure 3B). Overall, these findings demonstrate the ability of TSC2 to regulate CD8+ T cell effector generation through cell-intrinsic regulation of mTORC1.
The ability of hyperactive mTORC1 signaling to promote effector function is cell intrinsic. (A) OT-I+CD90.1+CD8+ T cells from WT, T-Rheb–/–, and T-Tsc2–/– mice were adoptively transferred into WT CD90.2+ recipient mice infected with vaccinia-OVA. Six days after infection, splenocytes were harvested. The percentage of splenic CD8+ CD90.1+ T cells, KLRG1 expression of CD8+CD90.1+ cells, and IFN-γ and TNF-α production after SIINFEKL peptide stimulation are shown, with statistics to the right (n = 10). For the box-and-whiskers plots, the whiskers represent the minimum and maximum values, the box boundaries represent the 25th and 75th percentiles, and the middle line is the median value. (B) WT and T-Tsc2–/– mice received s.q. EL4 thymoma cells expressing luciferase. Tumor burden was assessed by detection of luminescence (n = 16). (C–E) In vitro–activated T-Rheb–/– and T-Tsc2–/– and littermate control OT-I+CD8+ T cells were injected into WT recipients that had received B16-OVA cells 6 days prior (dashed line represents T cell transfer). “No transfer” indicates that mice did not receive OT-I+ cells. (C) Tumor volume was assessed every 2 to 3 days. Each symbol represents an average per genotype (n = 15). (D) Tumor volume shown at day 24 after tumor inoculation. Each dot represents a mouse. Data are derived from C. (E) Survival was assessed. Mice that received T-Tsc2–/– cells had enhanced survival compared with all other treatments, as determined by multiple comparisons Mantel-Cox tests. Statistics in A and D were determined by ANOVA and for B and C were determined by repeated-measures analysis. Data are representative of at least 3 independent experiments. *P < 0.05, **P < 0.01, ***P < 0.001
As with our in vitro experiments, we repeated the adoptive transfer with a starting population of sorted naive CD8+ T cells. Naive T-Tsc2–/– antigen-specific CD8+ T cells demonstrated increased cytokine production compared with WT cells after vaccinia-OVA infection (Supplemental Figure 3C). Interestingly, the adoptive transfer of naive T-Tsc2–/– OT-I+ T cells did not consistently display a proliferative advantage when compared with WT T cells (Supplemental Figure 3C). This is in contrast to our finding that naive T-Tsc2–/– CD8+ T cells proliferate to a greater extent than naive WT T cells after in vitro stimulation (Figure 2E). Thus, for unclear reasons, while in vivo endogenous and adoptively transferred T-Tsc2–/– CD8+ T cells (Figure 3A and Figure 4A) and in vitro naive T-Tsc2–/– CD8+ T cells (Figure 2E) proliferated to a greater extent than WT T cells, adoptively transferred naive OT-I+ T-Tsc2–/– CD8+ T cells did not.
Next, we wanted to determine the ability of such cells to reject tumors. To this end, T-Tsc2–/– and WT mice were challenged with a s.q. injection of an EL4 thymoma line engineered to express luciferase. T-Tsc2–/– mice cleared the tumor, while the tumors in WT mice had an exponential increase in growth, as indicated by luciferase signal (Figure 4B). Furthermore, when challenged with EL-4 tumor cells, 100% of the T-Tsc2–/– mice survived past day 40, while WT mice did not (Supplemental Figure 7F). The enhanced ability of T-Tsc2–/– CD8+ T cells to reject tumor was recapitulated in a B16 melanoma model. Adoptive transfer of in vitro–activated T-Tsc2–/– OT-I+ T cells into WT mice challenged with OVA-expressing B16 melanoma tumor cells resulted in slower tumor growth and a greater survival advantage than transfer of littermate control (Tsc2fl/fl or Rhebfl/fl) OT-I+ T cells (Figure 4, C–E, and Supplemental Figure 4A). In contrast, transfer of activated T-Rheb–/– OT-I+ cells offered the least protection (Figure 4, C–E). Tumor growth in Figure 4C is statistically significant, based on repeated-measures analysis with respect to group and time (see Statistics). Furthermore, T-Rheb–/– mice developed the greatest tumor burden compared with that of littermate controls in an EL4 tumor model (Supplemental Figure 4B).
Constitutive activation of mTORC1 yields terminally differentiated effector cells at the expense of memory formation. Although T-Tsc2–/– cells do not have a survival defect prior to or after acute stimulation, 6 days after vaccinia-OVA infection, OVA-specific T-Tsc2–/– CD8+ T cells have enhanced expression of active caspase-3 and low expression of BCL-2, while OVA-specific T-Rheb–/– CD8+ T cells have the highest BCL-2 expression (Supplemental Figure 5, A and B). Thus, we wanted to determine the potential role of TSC2 and RHEB in regulating T cell memory. WT, T-Rheb–/–, and T-Tsc2–/– mice were infected with vaccinia-OVA and tetramer-positive T cells were assessed 30 days following infection. In contrast to our findings during acute infection, 30 days after infection we observed a 2-fold increase of activated, antigen-specific CD8+ T cells in T-Rheb–/– mice compared with that in WT mice (Figure 5A and Supplemental Figure 5C). This result is consistent with previous studies demonstrating that rapamycin can promote the generation of memory cells (27, 28). There was a 2-fold reduction of antigen-specific cells in T-Tsc2–/– mice compared with that in WT mice (Figure 5A and Supplemental Figure 5C). Importantly, T-Rheb–/– T cells failed to respond to SIINFEKL upon rechallenge (Figure 5, B and C). Alternatively, the few T-Tsc2–/– CD8+ T cells that still remained at this late time point responded robustly. Thus, these data indicate that, while RHEB deficiency results in enhanced longevity of antigen-specific cells, these cells fail to respond upon rechallenge, suggesting that they do not possess true memory characteristics.
TSC2 inhibition results in terminally differentiated effector cells. WT, T-Rheb–/–, and T-Tsc2–/– mice were infected with vaccinia-OVA. Thirty days after infection splenocytes were harvested and (A) percentage and absolute number of antigen-specific splenocytes were determined by H-2 kb/SIINFEKL staining of CD44+CD8+ cells (n = 15). For the box-and-whiskers plots, the whiskers represent the minimum and maximum values, the box boundaries represent the 25th and 75th percentiles, and the middle line is the median value. (B) Splenocytes from day 30 infected mice were stimulated with SIINFEKL peptide, and cytolytic and T-bet protein expression were measured. Plots are gated from the CD8+ population. Shaded histograms show isotype controls. (C) Statistics for B (n = 9). Data are representative of at least 3 independent experiments. *P < 0.05, **P < 0.01, ***P < 0.001, ANOVA.
We hypothesized that the decrease in memory T cells observed in the T-Tsc2–/– mice was the result of persistent mTORC1 activation inhibiting the upregulation of the cellular programs necessary for long-term survival. To test this hypothesis, WT and T-Tsc2–/– OT-I+ T cells were adoptively transferred into WT mice infected with vaccinia-OVA, and a cohort of mice that received T-Tsc2–/– OT-I+ cells was treated daily with 100 μg/kg rapamycin, starting on day 5 after infection. Treatment with rapamycin markedly enhanced the survival of antigen-specific T-Tsc2–/– CD8+ T cells 21 days following infection (Figure 6, A and B). The increase in survival was associated with an increase in the expression of CD127 and eomesodermin, a transcription factor associated with CD8+ memory (ref. 29 and Figure 6, C and D). Consistent with the role of mTORC1 in enhancing effector cell generation, this treatment also led to a decrease in KLRG1 and T-bet expression in T-Tsc2–/– OT-I+ cells (Figure 6, A–D). Importantly, rapamycin treatment also promoted an enhanced recall response of T-Tsc2–/– OT-I+CD8+ T cells to a secondary infection with listeria-OVA (lm-OVA) (Figure 6E). This recall response was not observed in mice given T-Tsc2–/– cells without rapamycin. Thus, temporarily blocking mTORC1 activity in T-Tsc2–/– CD8+ T cells promotes the generation of functional memory T cells.
Rapamycin treatment can rescue the terminal effector differentiation of T-Tsc2–/– CD8+ T cells. WT and T-_Tsc2–/–_OT-I+CD8+CD90.1+ T cells were adoptively transferred into WT CD90.2+ recipients infected with vaccinia-OVA. A cohort of mice that received T-Tsc2–/– cells was treated with rapamycin. (A) FACS plots depict the percentage of splenic CD8+CD90.1+ (OT-I+) cells 21 days after infection (top). KLRG1 expression of gated CD90.1+ cells (bottom). Gray histogram depicts isotype control. (B) The percentage of recovered OT-I+ splenocytes 21 days after infection (n = 8). (C and D) Phenotypic analysis of recovered OT-I+ splenocytes demonstrating (C) changes in surface marker expression and (D) transcription factor expression between genotypes with or without rapamycin treatment (n = 8). (E) Recipient mice were infected with lm-OVA on day 21 after transfer. Six days after secondary infection with lm-OVA (day 27), splenocytes were harvested and the percentage of OT-I+ splenocytes was determined (n = 14). Data are representative of 3 independent experiments. For the box-and-whiskers plots, the whiskers represent the minimum and maximum values, the box boundaries represent the 25th and 75th percentiles, and the middle line is the median value. *P < 0.05, **P < 0.01, ***P < 0.001, ANOVA. Eomes, eomesodermin.
TSC2 regulates the activation-induced metabolic switch in T cells. We next assessed the metabolic flux of activated CD8+ T cells from WT, T-Tsc2–/–, and T-Rheb–/– mice. T-Tsc2–/– CD8+ T cells demonstrated a high extracellular acidification rate (ECAR), indicative of increased glycolysis, compared with WT T cells (Figure 7A). In support of this high glycolytic rate, activated T-Tsc2–/– cells have enhanced transcript expression of Slc2a1 (the glucose transporter GLUT1) and the key glycolytic enzyme phosphofructokinase (Pfk1) (Figure 7B). In contrast, T-Rheb–/– T cells demonstrated markedly decreased glycolytic activity and diminished expression of Slc2a1 and Pfk1. However, T-Rheb–/– CD8+ T cells have an increased spare respiratory capacity (SRC), an indicator of mitochondrial energy potential associated with long-term cellular survival (Figure 7C) (6). In support of this finding, previously activated T-Rheb–/– CD8+ T cells exhibited the highest mitochondrial mass, as indicated by MitoTracker Green staining (Figure 7D). Furthermore, T-Rheb–/– CD8+ T cells demonstrated a increase in expression of carnitine palmitoyltransferase 1 α (Cpt1a), the rate-limiting step of FAO (30, 31), which is also associated with the development of memory CD8+ T cells (ref. 6 and Figure 7E). In contrast, T-Tsc2–/– CD8+ T cells have the lowest SRC, mitochondrial mass, and Cpt1a expression (Figure 7, C–E). Thus, these data indicate that mTORC1 activity is a rheostat for CD8+ metabolic function. Tsc2 deletion results in enhanced glycolytic metabolism at the expense of oxidative phosphorylation, while loss of mTORC1 activity decreases glycolysis but promotes oxidative phosphorylation and FAO.
mTORC1 activity influences CD8+ T cell metabolism upon TCR stimulation. (A–E) Purified CD8+ T cells from WT, T-Rheb–/–, and T-Tsc2–/– mice were stimulated in vitro for 48 hours and cultured in IL-7 and IL-15 for 3 days. (A) Cells were run on an extracellular flux analyzer, and ECAR was determined. Data are mean ± SEM of 7 measurements. (B) RNA was extracted and relative expression of GLUT1 (Slc2a1) and Pfk1 transcripts was determined by qPCR. (C) As in A, SRC was determined. (D) MitoTracker Green staining was assessed by flow cytometry. (E) As in B, Cpt1a expression was measured. (F) T-Tsc2–/– OT-I+ T cells were transferred into congenically distinct recipients infected with vaccinia-OVA. A cohort of mice received 2DG daily. On day 6, splenocytes were harvested and the percentage of OT-I+ cells (n = 9) and percentage of IFN-γ–positive OT-I+ cells was determined after SIINFEKL stimulation (n = 5). For the box-and-whiskers plots, the whiskers represent the minimum and maximum values, the box boundaries represent the 25th and 75th percentiles, and the middle line is the median value. (G–J) Purified T-Tsc2–/–_CD8+ T cells were stimulated in vitro for 48 hours with or without 0.5 μM rapamycin. Cells were expanded in media supplemented with IL-7 and IL-15 with or without 0.5 μM rapamycin for 3 days. (G) As in A, ECAR was measured. Data are mean ± SEM of 4 measurements. (H) As in B, relative expression of S_lc2a1 and Pfk1 transcript was detected. (I) As in G, SRC was determined, and (J) relative expression of Cpt1a transcript was measured. Statistics for A–E were determined by ANOVA and those for F–J were measured by Mann-Whitney t tests. Data are representative of 3 independent experiments. *P < 0.05, **P < 0.01, ***P < 0.001
To determine whether the enhanced effector function of T-Tsc2–/– CD8+ T cells is dependent on an enhanced glycolytic metabolism, we assessed T-Tsc2–/– effector function in vivo after daily treatment with 2-deoxy-d-glucose (2DG), an inhibitor of glycolysis (32). 2DG treatment greatly reduced the percentage of recovered T-Tsc2–/– OT-I+CD8+ T cells and the IFN-γ production of OT-I+ T cells after vaccinia-OVA infection, thus proving a correlation between glycolytic metabolism and T-Tsc2–/– CD8+ T cell effector response (Figure 7F).
In as much as rapamycin was able to enhance memory generation in the T-Tsc2–/– CD8+ T cells, we next examined the effect of rapamycin on metabolism. Rapamycin treatment reduced glycolysis, as measured by ECAR, in T-Tsc2–/– CD8+ T cells (Figure 7G). This finding was associated with a decrease in Slc2a1 and Pfk1 (Figure 7H). In contrast, rapamycin promoted enhanced SRC (Figure 7I and Supplemental Figure 6A) and increased expression of Cpt1a in WT and T-Tsc2–/– CD8+ T cells (Figure 7J and Supplemental Figure 6B). Thus, inhibition of mTORC1 through rapamycin treatment decreases the glycolytic metabolism of activated T-Tsc2–/– cells, enabling the generation of memory cells.
A novel role for mTORC2 in regulating CD8+ T cell memory. We next wanted to determine whether mTORC2 activity is important for regulating CD8+ T cell fate decisions. To this end, we used mice in which RICTOR, a critical component of mTORC2, is conditionally deleted in T cells (Cd4-Cre Rictorfl/fl mice, herein referred to as T-Rictor–/– mice). Upon TCR stimulation, T-Rictor–/– CD8+ T cells have intact, if not slightly elevated, mTORC1 activity, consistent with the release of a mTORC2 feedback loop (33), and decreased mTORC2 activity (Figure 8A and Supplemental Figure 7A).
mTORC2 activity is not required for CD8+ T cell effector function. (A) Purified CD8+ T cells were collected from 6-week-old WT or T-Rictor–/– mice. mTORC1 and mTORC2 activity was assessed by immunoblot analysis from unstimulated cells or after 1-hour stimulation with αCD3/αCD28. (B and C) WT and T-Rictor–/– OT-I+CD8+CD90.1+ cells were adoptively transferred into WT CD90.2+ recipients infected with vaccinia-OVA. Six days after infection, splenocytes were harvested. (B) The percentage of OT-I+ splenocytes was determined. The graph depicts the absolute number of OT-I+ splenocytes (n = 12). (C) Surface staining of OT-I+ splenocytes 6 days after infection, with the percentage of recovered OT-I+ cells expressing CD127 (n = 12) (top). Cytokine production of OT-I+ splenocytes after SIINFEKL stimulation, with statistics shown to the right (n = 12) (bottom). (D and E) 1.5 × 105 naive sorted WT, T-Rheb–/–, and T-Rictor–/– OT-I+CD90.1+ T cells were adoptively transferred into WT CD90.2+ recipients infected with vaccinia-OVA. (D) The percentage of recovered OT-I+ T cells was determined from blood 6 days after infection, with statistics shown to the right (n = 15). (E) Surface marker and transcription factor expression were assessed from recovered OT-I+ splenocytes (n = 9). For the box-and-whiskers plots, the whiskers represent the minimum and maximum values, the box boundaries represent the 25th and 75th percentiles, and the middle line is the median value. Statistics for B and C were determined by Mann-Whitney t tests, while those for D and E were measured by ANOVA. Data are representative of 3 independent experiments. *P < 0.05, **P < 0.01, ***P < 0.001.
T-Rictor–/– CD8+ T cells have proliferative capacity and cytokine production equivalent to those of WT cells (Supplemental Figure 7B). To further understand the role of mTORC2 in CD8+ T cell effector function, we used the in vivo adoptive transfer model. Congenically marked WT and T-Rictor–/– OT-I+ T cells were adoptively transferred into recipient mice that were immediately infected with vaccinia-OVA. Unlike T cells derived from T-Rheb–/– mice, T-Rictor–/– cells generated a response to vaccinia-OVA infection similar to that of WT cells (Figure 8B). This response was observed and equivalent for antigen-specific cells derived from the blood and spleen (Supplemental Figure 7C). OVA-specific T-Rictor–/– cells expressed KLRG1 and produced robust amounts of IFN-γ and TNF-α, similar to WT cells, upon ex vivo restimulation (Figure 8C). Surprisingly, at this early time point (day 6 after infection), we also observed a substantial population of T-Rictor–/– cells expressing CD127 (Figure 8C). These findings were recapitulated after transfer of sorted naive cells. Six days after infection, transfer of naive T-Rictor–/– OT-I+CD8+ T cells resulted in equivalent, if not enhanced, accumulation of antigen-specific CD8+ T cells compared with transfer of WT cells, while T-Rheb–/– CD8+ T cell transfer yielded the lowest percentage of antigen-specific CD8+ T cells (Figure 8D). Additionally, T-Rictor–/– CD8+ T cells have an activated effector phenotype similar to that of WT cells, expressing high levels of CD44 and T-bet (Figure 8E). However, T-Rictor–/– CD8+ T cells also have enhanced expression of CD127 and eomesodermin, which were upregulated in T-Rheb–/– CD8+ T cells but not WT cells at this time point after infection (Figure 8E). Furthermore, antigen-specific T-Rictor–/– cells have low levels of caspase-3 activity, similar to WT and T-Rheb–/– CD8+ T cells, but the highest expression of BCL-2 (Supplemental Figure 7, D and E). Thus, CD8+ T cells with diminished mTORC2 activity generate robust effector responses, while simultaneously expressing markers of memory.
To further investigate the longevity of T-Rictor–/– CD8+ T cells, we tracked the frequency of WT and T-Rictor–/– OT-I+ T cells for 35 days after infection in the blood (Figure 9A). By day 12, the frequency of T-Rictor–/– OT-I+CD8+ T cells was higher than that of WT cells. Further assessment of splenocytes 26 days after infection revealed an increased frequency of T-Rictor–/– OT-I+ T cells compared with that of WT cells (Figure 9B). These cells expressed higher levels of the memory cell markers CD127 and CD122 (IL-2R/15Rβ) than WT T cells (Figure 9C). Thus, T-Rictor–/– CD8+ T cells have a survival advantage over memory cells generated from WT mice.
mTORC2 inhibition does not hinder CD8+ T cell acute effector function. (A) 1.5 × 105 naive sorted WT and T-Rictor–/– OT-I+CD8+CD90.1+ T cells were adoptively transferred into WT recipients infected with vaccinia-OVA, and the percentage of OT-I+ cells was monitored in the blood. The two groups are statistically significant during the memory phase, as assessed by repeated-measures analysis (see Statistics) (n = 9). (B–D) WT and T-Rictor–/– OT-I+CD8+CD90.1+ cells were adoptively transferred into WT recipients infected with vaccinia-OVA, and the number and phenotype of OT-I+ splenocytes were assessed 26 days after adoptive transfer and infection. (B) The percentage and absolute number of recovered OT-I+ splenocytes, and (C) surface marker expression of OT-I+ splenocytes was determined by flow cytometry. MFI and the percentage of antigen-specific cells expressing CD127 or CD122 are shown in plots. Gray histograms depict isotype controls (n = 12). (D) 26 days after infection, mice were given a secondary infection with lm-OVA, and 6 days later cytokine production of OT-I+ splenocytes was determined. For the box-and-whiskers plots, the whiskers represent the minimum and maximum values, the box boundaries represent the 25th and 75th percentiles, and the middle line is the median value. Statistics in A were determined by repeated-measures analysis and those in B and C were measured by Mann-Whitney t tests. Data are representative of at least 3 independent experiments. *P < 0.05, ***P < 0.001.
Having demonstrated that T-Rictor–/– T cells have prolonged survival with increased markers of memory CD8+ T cells, we next assessed their ability to respond upon rechallenge. To this end, 26 days after adoptive transfer and infection with vaccinia-OVA, recipient mice were rechallenged with lm-OVA, and the WT and T-Rictor–/– OT-I+ T cell response was determined 6 days later. T-Rictor–/– T cells demonstrated robust production of IFN-γ and TNF-α upon ex vivo stimulation (Figure 9D). Additionally, the enhanced generation of long-lived memory cells by T-Rictor–/– OT-I+ T cells was observed after rechallenge with lm-OVA 133 days after initial infection (Figure 10, A and B). To further demonstrate the enhanced ability of the T-Rictor–/– T cells to generate memory cells, we sorted WT and T-Rictor–/– OT-I+ T cells from mice 35 days after infection (Figure 10, C and D) and performed a second adoptive transfer of equivalent cell number into naive recipients. Infection of these mice with vaccinia-OVA resulted in enhanced expansion of the T-Rictor–/– OT-I+ T cells when compared with the adoptively transferred WT T cells (Figure 10D). Thus, T cells lacking mTORC2 signaling not only demonstrate enhanced differentiation into memory cells but also generate elevated responses upon rechallenge.
mTORC2 inhibition promotes memory generation. (A–E) 1.5 × 105 naive sorted OT-I+ T cells were transferred into WT CD90.2+ recipients infected with vaccinia-OVA. (A and B) Mice were given secondary infection of lm-OVA 133 days after initial infection, and 7 days later, the percentage and absolute number of recovered OT-I+ splenocytes was determined (n = 20). (C) Experimental schematic for D. (D) Flow cytometric analysis of the percentage of OT-I+ cells recovered from blood 35 days after primary infection, with statistics shown on the right (n = 9) (top). OT-I+ cells were purified after harvest on day 35, transferred into new recipients infected with vaccinia-OVA, and 6 days later, percentage of OT-I+ PBMCs was determined (labeled as “D6 after 2nd AT”), with statistics shown to the right (n = 7) (bottom). (E) CD62L and CD127 expression of recovered OT-I+ splenocytes 35 days after primary infection (n = 9). (F) p-FOXO1 protein expression was detected from in vitro–stimulated and IL-7– and IL-15–expanded CD8+ T cells with or without restimulation. Data are representative of at least 3 independent experiments. For the box-and-whiskers plots, the whiskers represent the minimum and maximum values, the box boundaries represent the 25th and 75th percentiles, and the middle line is the median value. **P < 0.01, ***P < 0.001, Mann-Whitney t tests.
We consistently found that long-lived T-Rictor–/– CD8+ T cells expressed increased levels of CD127, CD62L, and eomesodermin (Figure 8E and Figure 10E). The expression of these molecules is controlled in part by the transcription factor, FOXO1 (34). Phosphorylation of FOXO1 results in cytoplasmic retention and hence inhibits its function. This phosphorylation has previously been shown to be regulated in part by mTORC2 activity (35). Thus, we hypothesized that the deletion of RICTOR could enhance the generation of memory T cells in part by increasing the retention of FOXO1 in the nucleus. Consistent with this mechanism, FOXO1 phosphorylation was diminished in activated T-Rictor–/– CD8+ T cells (Figure 10F). Of note, in spite of their ability to generate robust memory responses, T-Rictor–/– T cells were no better at acutely rejecting tumors than WT T cells (Supplemental Figure 7, F and G).
Inhibition of mTORC2 promotes metabolism associated with both effector and memory CD8+ T cells. Next, we sought to determine whether the ability of mTORC2 to regulate memory cell generation was also linked to metabolism. WT and T-Rictor–/– CD8+ T cells were stimulated in vitro and expanded in the presence of IL-2 (to promote effector formation) or IL-7 and IL-15 (to promote memory differentiation) (6, 36). Regardless of the cytokine milieu, T-Rictor–/– CD8+ T cells demonstrated a marked increase in ECAR, indicative of a glycolytic metabolism when compared with WT T cells (Figure 11A). That is, even under in vitro conditions that mimic memory generation, the T-Rictor–/– CD8+ T cells have increased glycolytic flux. Additionally, the initial oxygen consumption rate (OCR) was elevated in T-Rictor–/– cells when compared with that in WT T cells in both the effector and memory culture conditions (Figure 11A). Furthermore, while WT and T-Rictor–/– cells have a similar SRC after culture in IL-7 and IL-15, culture in IL-2 did not diminish the SRC of T-Rictor–/– CD8+ T cells (Figure 11B). Therefore, under conditions that promote glycolysis and effector generation, T-Rictor–/– T cells still maintain a high SRC, which is associated with the development of memory.
mTORC2 inhibition leads to enhanced metabolic fitness. Purified CD8+ T cells from WT or T-Rictor–/– mice were stimulated in vitro for 48 hours and expanded for 3 days. (A) Initial ECAR, initial OCR, and (B) SRC were determined. Data are mean ± SEM of 7 measurements. (C) WT, T-Rheb–/–, and T-Rictor–/– CD8+ T cells were stimulated in vitro and cultured in IL-7 and IL-15 for 3 days. Cells were plated at equivalent cell number, and ECAR and OCR measurements were assayed upon stimulation in the Seahorse bioanalyzer. Data are mean ± SEM of 12 measurements. (D) SRC was determined after restimulation of WT, T-Rheb–/–, and T-Rictor–/– CD8+ T cells expanded in IL-7 and IL-15. Data are mean ± SEM of 10 measurements. Relative expression of Cpt1a transcript was determined from (E) stimulated cells expanded in IL-7 and IL-15 for 3 days (mean ± SEM of 3 measurements) or from (F) sorted WT, T-Rheb–/–, and T-Rictor–/– OT-I+ cells recovered 6 days after adoptive transfer into recipients infected with vaccinia-OVA (n = 3 mice per genotype). (G) OCR measurements of restimulated WT, T-Rheb–/–, and T-_Rictor–/–_CD8+ T cells during a FAO assay. BSA control shown in gray. Data are mean ± SEM of 4 measurements. Statistics in A, B, D, and F were determined by ANOVA; those in C were measured by repeated-measures analysis; and those in E were measured by Mann-Whitney t test. Data are representative of at least 3 independent experiments. For the box-and-whiskers plots, the whiskers represent the minimum and maximum values, the box boundaries represent the 25th and 75th percentiles, and the middle line is the median value. *P < 0.05, **P < 0.01, ***P < 0.001.
Unlike the T-Rictor–/– T cells, the T-Rheb–/– T cells fail to respond upon rechallenge. We hypothesized that this might be due to the differences in the ability of T-Rheb–/– and T-Rictor–/– memory CD8+ T cells to upregulate metabolic programs upon rechallenge. To this end, WT, T-Rheb–/–, and T-Rictor–/– CD8+ T cells were stimulated, cultured in IL-7 and IL-15, and then rechallenged with αCD3/αCD28, while simultaneously measuring ECAR and OCR. T-Rictor–/– CD8+ T cells displayed increased ECAR and OCR both at baseline and after restimulation (Figure 11C). In contrast, consistent with their inability to mount an effector response upon rechallenge, T-Rheb–/– T cells failed to increase glycolytic flux (Figure 11C). However, both T-Rictor–/– and T-Rheb–/– CD8+ T cells have increased SRC when compared with that of WT T cells (Figure 11D). Furthermore, both T-Rictor–/– and T-Rheb–/– CD8+ T cells expressed increased levels of Cpt1a after either in vitro or in vivo stimulation (Figure 7E and Figure 11, E and F). This correlated with an increase in OCR in response to palmitate, indicating that activated T-Rictor–/– and T-Rheb–/– CD8+ T cells can use FAO as an energy source (Figure 11G). Thus, loss of mTORC2 signaling promotes the upregulation of metabolic machinery necessary for development of both effector and memory responses.
Finally, we have consistently found that T cell–specific deletion of Tsc2 results in hyperactivated CD8+ T cells that have enhanced proliferation, cytokine secretion, and killing responses. However, these results are dramatically distinct from previously published findings with TSC1-deficient CD8+ T cells (13–16, 37). We thus speculated that the differences between the T-Tsc1–/– and T-Tsc2–/– CD8+ T cells might be accounted for in part by the presence or absence of mTORC2 activity. Recall that, unlike T-Tsc1–/– T cells, T-Tsc2–/– CD8+ T cells have relatively intact mTORC2 signaling (Figure 1A and Figure 2B) (13, 14, 16). To this end, we crossed T-Tsc2–/– mice with T-Rictor–/– mice to generate T-Tsc2–/– Rictor–/– (Cd4-Cre Tsc2fl/fl Rictorfl/fl, double-knockout [DKO]) mice. DKO mice have hyperactive mTORC1 signaling but ablated mTORC2 activation (Figure 12A). DKO cells have elevated activation-induced death compared with WT, T-Tsc2–/–, and T-Rictor–/– CD8+ T cells stimulated in vitro (Figure 12, B and C). We infected WT, T-Tsc2–/–, T-Rictor–/–, and DKO mice with vaccinia-OVA and assessed effector responses 6 days later. Similar to the reported T-Tsc1–/– T cells (13–16, 37), T cells lacking both TSC2 and RICTOR demonstrated decreased expansion in response to antigen, decreased KLRG1 and CD127 upregulation, and decreased cytokine production (Figure 12, D–F). Thus, we conclude that intact mTORC2 activity is critical for the hyperactive effector response detected in T-Tsc2–/– mice and further explains the difference in phenotype between T-Tsc1–/– and T-Tsc2–/– CD8+ T cells.
Inhibition of mTORC2 in the presence of hyperactive mTORC1 leads to enhanced cellular death. (A) Purified CD8+ T cells from WT, T-Tsc2–/–, T-Rictor–/–, and DKO mice were stimulated in vitro for 1 hour, and mTORC1 and mTORC2 activity was assessed by immunoblot. (B) Splenocytes from WT, T-Tsc2–/–, T-Rictor–/–, and DKO mice were stimulated in vitro for 24 hours prior to analysis of CD8+ T cell death by 7-AAD and annexin V staining. (C) Statistics for B (n = 4). (D–F) Mice of each genotype were infected with vaccinia-OVA. Six days later, (D) the percentage of antigen-specific CD44+CD8+ splenocytes and (E) surface marker expression of the antigen-specific CD8+ T cells were determined. (F) Cytokine production was assessed after ex vivo stimulation of splenocytes gated from CD44+CD8+ cells (n = 6). Data are representative of 3 independent experiments. For the box-and-whiskers plots, the whiskers represent the minimum and maximum values, the box boundaries represent the 25th and 75th percentiles, and the middle line is the median value. *P < 0.05, **P < 0.01, ***P < 0.001, ANOVA.