Antiretroviral therapy duration and immunometabolic state determine efficacy of ex vivo dendritic cell-based treatment restoring functional HIV-specific CD8+ T cells in people living with HIV.

BACKGROUND: Dysfunction of CD8+ T cells in people living with HIV-1 (PLWH) receiving anti-retroviral therapy (ART) has restricted the efficacy of dendritic cell (DC)-based immunotherapies against HIV-1. Heterogeneous immune exhaustion and metabolic states of CD8+ T cells might differentially associate with dysfunction. However, specific parameters associated to functional restoration of CD8+ T cells after DC treatment have not been investigated.
METHODS: We studied association of restoration of functional HIV-1-specific CD8+ T cell responses after stimulation with Gag-adjuvant-primed DC with ART duration, exhaustion, metabolic and memory cell subsets profiles.
FINDINGS: HIV-1-specific CD8+ T cell responses from a larger proportion of PLWH on long-term ART (more than 10 years; LT-ARTp) improved polyfunctionality and capacity to eliminate autologous p24+ infected CD4+ T cells in vitro. In contrast, functional improvement of CD8+ T cells from PLWH on short-term ART (less than a decade; ST-ARTp) after DC treatment was limited. This was associated with lower frequencies of central memory CD8+ T cells, increased co-expression of PD1 and TIGIT and reduced mitochondrial respiration and glycolysis induction upon TCR activation. In contrast, CD8+ T cells from LT-ARTp showed increased frequencies of TIM3+ PD1- cells and preserved induction of glycolysis. Treatment of dysfunctional CD8+ T cells from ST-ARTp with combined anti-PD1 and anti-TIGIT antibodies plus a glycolysis promoting drug restored their ability to eliminate infected CD4+ T cells.
INTERPRETATION: Together, our study identifies specific immunometabolic parameters for different PLWH subgroups potentially useful for future personalized DC-based HIV-1 vaccines. FUNDING: NIH (R21AI140930), MINECO/FEDER RETOS (RTI2018-097485-A-I00) and CIBERINF grants.

Evidence before this study

Current antiretroviral therapies available for people living with HIV-1 (PLWH) are unable to eliminate persistently infected CD4+ T cells and eradicate the infection. For this reason, different immunotherapeutic strategies aiming to boost antiviral immunity and to reduce HIV-1 reservoirs have been tested during the last decade. However, none of these immunotherapies have been effective and prevented viral rebound after treatment interruption in clinical trials. Such negative results are in part due to heterogeneous dysfunctional states in immune cells with antiviral activity, such as CD8+ T cells. Thus, it is critical to better understand mechanisms regulating functionality of CD8+ T cells to develop personalized strategies to more efficiently reinvigorate the function of these immune cells and to reduce HIV-1 reservoirs.

Added value of this study

We identified two subgroups of PLWH characterized by significant differences in CD8+ T cell immunometabolic phenotypes and their ability to respond to adjuvant-primed dendritic cell (DC) immunotherapy. CD8+ T cells capable of improving cytotoxic activity against HIV-1 infected cells after DC immunotherapy, were enriched for PLWH in treatment for more than a decade, exhibited low levels of co-expression of PD1 and TIGIT checkpoint inhibitory receptors, and preserved metabolism and memory cell subsets. In contrast, dysfunctional CD8+ T cells unable to respond to adjuvant-activated DC therapy were enriched with PLWH in treatment for less than ten years, displaying high proportions of PD1+ TIGIT+ cells and reduced mitochondrial fitness. We were able to restore functionality of CD8+ T cells from this group by combining DC therapy with the use of blocking antibodies against PD1 and TIGIT combined with the glycolysis-promoting drug Metformin.

Implications of all the available evidence

Our study identifies specific groups of PLWH with a higher probability of responding to dendritic cell immunotherapy, key CD8+ T cell patterns differentially contributing to immune dysfunction and validates new approaches to restore the function of dysfunctional cells from non-responding individuals. Therefore, these data might provide new tools to improve and personalize these treatments in PLWH characterized by elevated levels of immune exhaustion and metabolic dysfunction and increase efficacy of immunotherapies against HIV-1 infection.

Alt-text: Unlabelled box

Introduction

Antiretroviral therapy (ART) does not eradicate chronic HIV-1 infection due to persistent HIV-1 reservoir cells maintained through homeostatic proliferation of long-lived latently infected memory CD4+ T cells, residual viral replication in tissues and dysfunctionality of the immune response.1, 2, 3, 4 Therefore, additional strategies to eradicate the latent reservoir are required. Strategies directed to improve viral reactivation of latently HIV-1 infected cells and the use of immunotherapy to boost their elimination by immune cytotoxic cell subsets have been investigated., Cytotoxic CD8+ T lymphocytes are immune cells crucial for restraining the size of the reservoir in the initial phases of the infection and for natural control of HIV-1 replication in elite controller (EC) individuals. Several therapeutic strategies have focused on enhancing the magnitude and polyfunctionality of HIV-1-specific CD8+ T cell responses in people living with HIV-1 (PLWH), to mimic the effective and durable immune responses of EC. However, none of the tested candidates prevented viral rebound following treatment interruption in clinical trials., Thus, new personalized strategies that take into consideration complex factors contributing to CD8+ T cell dysfunction are needed.

A potential strategy is to improve antigen-presenting cell function of dendritic cells (DC), which could be compromised in PLWH. Previous studies on HIV-1 infected EC identified a DC activation state dependent on the TANK-Binding Kinase 1 (TBK-1) which is characterized by highly functional capacities to activate polyfunctional HIV-specific CD8+ T cell responses., TBK-1 is a master regulator downstream of multiple intracellular nucleic acid sensors, which leads to the production of type I and II interferons. We previously showed that activation of DC through agonists of nucleic acid sensors upstream of TBK-1 potentiate the acquisition of EC-like functional profiles and their ability to increase polyfunctional HIV-1-specific CD8+ T cell responses in lymphoid tissues in humanized mice. Also, DC might be intrinsically useful to more efficiently reactivate the latent HIV-1 reservoir.,

On the other hand, basal hyperactivation and immune exhaustion compromise the maintenance and effector function of HIV-1 specific CD8+ T in PLWH.20, 21, 22, 23 Recent studies have shown that exhaustion of CD8+ T cells is a dynamic process involving expression of multiple checkpoint inhibitory receptors that drive the transition, survival and function of distinct memory cell subsets.,, Importantly, expression of checkpoint inhibitory receptors such as Programmed cell death protein 1 (PD1), T cell immunoreceptor with Ig and ITIM domains (TIGIT) and T cell immunoglobulin and mucin domain-containing protein 3 (TIM3) in T cells is also associated with deregulated glucose metabolism,26, 27, 28 potentially affecting the effector function and longevity of HIV-1-specific CD8+ T cells.29, 30, 31 Consistently, compromise of metabolic fitness has been reported in PLWH and suggested to affect CD8+ T cell function., In addition, prolonged ART might restore some of these defects and facilitate post-treatment immunological control of viral replication., However, it is unknown whether specific expression patterns of checkpoint inhibitory receptors might differentially associate with efficacy of DC immunotherapy restoring functionality of HIV-1-specific CD8+ T cells in PLWH on ART.

Here, we evaluated the efficacy of adjuvant-primed DC reinvigorating polyfunctional and cytotoxic HIV-1-specific CD8+ T cells, and its association with the immunometabolic state in different subgroups of PLWH at different times since ART initiation. We report enhanced response of CD8+ T cells to DC treatment in PLWH on ART for more than a decade, which associates with higher central memory (CM) frequencies, enrichment on TIM3+ PD1− cells and the ability to induce glycolysis upon TCR stimulation. In contrast, CD8+ T cells from PLWH under ART for less than 10 years were characterized by decreased frequency of CM, increased proportions of exhausted PD1+ TIGIT+ memory CD8+ T cells, impaired glycolytic metabolism and inability to reinvigorate cytotoxic function of CD8+ T cells after DC stimulation. Importantly, combined blockade of PD1 and TIGIT receptors and the use of the pro-glycolytic drug Metformin more consistently restored cytotoxic capabilities of dysfunctional CD8+ T cells from PLWH. Collectively, our study uncovers immunometabolic parameters associated with response of CD8+ T cells to DC-based HIV-1 vaccine in PLWH, which might be useful for future personalized treatments.

Methods

Experimental design

Peripheral blood mononuclear cells (PBMC) were isolated from n=49 PLWH on ART with clinical characteristics summarized in Table 1, provided by the Infectious Diseases Unit from Hospital de La Princesa, Madrid, Spain. N=12 HIV negative donors were provided either by the Immunology Service from Hospital de La Princesa or Centro de Transfusión of Comunidad de Madrid, Spain (Table 2). Samples were cryopreserved upon collection and used in parallel in our study.

Table 1

Clinical characteristics of ART-treated HIV-1 chronic patient cohort.

	Total HIV chronic patient cohort	ST-ARTp	LT-ARTp	p-values
Patient cohort individuals (n)	49	31	18
Age at sample collection Median (1st- 3rd quartile); stdev p	48 (39-56); 12	40 (37-51); 9	55.5(51-67); 10	<0.0001
Sex M: male (%); F: female (%)	M: 42 (86%);F: 7 (14%)	M: 30 (97%);F: 1(3%)	M: 12 (67%);F: 6 (33%)	0.013
NADIR circulating CD4+ T cell countsMedian (1st- 3rd quartile); stdev p	420 (265-504);222.292 ND	480.5(340-555); 219.861 ND	318 (117-434); 171.441 ND	0.0039
Circulating CD4+ T cell counts at sample collectionMedian (1st- 3rd quartile); stdev p	866 (659-1194); 3301 ND	1016 (728-1277); 3571 ND	777(634-1086); 225	0.039
Circulating CD8+ T cell counts at sample collectionMedian (1st- 3rd quartile); stdev p	900 (651-1350); 489 1 ND	993(684-1400); 527 1ND	833(525-1301); 383	ns
CD4+/CD8+ T cell ratio in the blood at sample collection Median (1st- 3rd quartile); stdev p	1.00 (1-1); 0.46 1 ND	1.06(1-1); 0.41 1 ND	0.97(1-1); 0.53	ns
BLIPS 0: patients (%); 1: patients (%); ND: patients (%)	0: 34 (69.4%); 1: 8 (16.3%); ND: 7 (14.3%)	0: 23 (74%); 1: 5 (16%); ND: 3 (10%)	0: 11 (61%); 1: 3 (17%); ND: 4 (22%)	ns
Years under treatment Median (1st- 3rd quartile); stdev p	8 (4-15); 6	5.5 (3-8); 3	15(14-19); 3	<0.0001
Months from HIV detection to ART initiation Median (1st- 3rd quartile); stdev p	1ss); 51.57	3 (0-66); 44.23	22.5(1-99); 61.35	ns
Treatment [number of patients]	ABC/3TC/DTG [9]; ABC/3TC/LPV/r [1]; DRV/c [6]; DRV/c/DTG/3TC [1]; DRV/c/TDF/AZT [1]; DRV/RPV/FTC [1]; DTG/RPV [1]; DTG/3TC [2]; TAF/FTC/BIC [5]; TAF/FTC/DRV/c [9]; TAF/FTC/DRV/c/DTG [1]; TAF/FTC/EVG/c [5]; TAF/FTC/RPV [2]; TAF/FTC/NVP [1]; TDF/FTC/EFV [4]	ABC/3TC/DTG [6]; ABC/3TC/LPV/r [0]; DRV/c [2]; DRV/c/DTG/3TC [0]; DRV/c/TDF/AZT [1]; DRV/RPV/FTC [0]; DTG/RPV [1]; DTG/3TC [2]; TAF/FTC/BIC [5]; TAF/FTC/DRV/c [6]; TAF/FTC/DRV/c/DTG [0]; TAF/FTC/EVG/c [3]; TAF/FTC/RPV [2]; TAF/FTC/NVP [0]; TDF/FTC/EFV [3]	ABC/3TC/DTG [3]; ABC/3TC/LPV/r [1]; DRV/c [4]; DRV/c/DTG/3TC [1]; DRV/c/TDF/AZT [0]; DRV/RPV/FTC [1]; DTG/RPV [0]; DTG/3TC [0]; TAF/FTC/BIC [0]; TAF/FTC/DRV/c [3]; TAF/FTC/DRV/c/DTG [1]; TAF/FTC/EVG/c [2]; TAF/FTC/RPV [0]; TAF/FTC/NVP [1]; TDF/FTC/EFV [1]

*ND = non determined.

Statistical significances were calculated using two-tailed Wilcoxon test and Chi-square test with Yates correction.

Table 2

HIV negative donor cohort.

	p-values vs.
		Total ART (all; metab)	ST-ARTp (all; metab)	LT-ARTp (all; metab)
Healthy control cohort individuals (n)	12
Age at simple collection Median (1st- 3rd quartile); stdev p	45.5(28-57.75); 15	0.6966; 0.5074	0.4571; 0.4658	0.0335; 0.0567
Sex M: male (%); F: female (%)	M: 7 (64%); F: 4 (36%)	0.2009; 0.5705	0.0176; 0.3661	0.8134; 0.8772

*metab = samples used for metabolism assays.

Statistical significances were calculated using two-tailed Wilcoxon test and Chi-square test with Yates correction.

Ethics statement

All participating subjects received and signed an informed consent, approved by the Ethics committee from Hospital Universitario de La Princesa (Register Number 3518), following the Helsinki declaration. We tried to include the same donors in all the analyses but in some cases, this was not possible due to sample availability. Number of individuals from our cohort used for each experiment is specified on the figure legends. The study was designed in accordance with the STROBE guidelines (see supplementary STROBE checklist and Figure 1).

Figure 1

STROBE flow chart. Flow chart indicating the number of donors used for each assay. PLWH are indicated in dark grey and HIV negative controls in green.

DC generation and in vitro stimulation

Monocyte-derived DCs (MDDCs) were generated from circulating monocytes enriched by adherence and cultured in RPMI 1640 media supplemented with 10% Fetal Bovine Serum (HyClone) in the presence of 100 IU/mL of GM-CSF and 100 IU/mL of IL4 (Peprotech) for 6 days. Subsequently, MDDCs were harvested and cultured over-night in media alone or in the presence of 5 μg/mL of a pool of 15-mer overlapping HIV-1 Gag peptides provided by the NIH AIDS Reagent Program (#11057) either individually or in combination with 1 μg/mL of 2’3’-c'diAM(PS)2 (Invivogen) STING agonist and 2.5 μg/mL of Poly I:C (SIGMA) TLR3 ligand as adjuvant treatment. Maturation of MDDC after treatment with Gag-peptides and/or adjuvants was assessed by flow cytometry analysis of CD40 expression (see Flow cytometry).

Isolation of human peripheral blood T lymphocyte populations

Total or individual CD8+ or CD4+ T cells were purified from PBMC suspensions from our PLWH and HIV-1 negative control study cohorts by negative immunomagnetic selection (purity >90%) using the Untouched Human T cell and CD4 T cell Dynabeads Kits (Invitrogen) and the MojoSort Human CD8 T cell (BioLegend) isolation kits. Memory CD45RA− CD8+ T cells from PLWH and HIV-1 negative controls were isolated from CD8+ T cells by negative immunomagnetic selection after treatment with mouse anti-human CD45RA mAbs (Biolegend) and Goat anti-Mouse IgG covered Dynabeads (Invitrogen).

In vitro activation of HIV-1 specific CD8+ T cells from PLWH

MDDCs pre-treated with media only or either with HIV-1 Gag peptides alone or incubated with the adjuvants, were co-cultured with purified autologous T cells in a 1:5 ratio. After 5 h incubation of MDDC and autologous T cells, 0.25 μg/mL Brefeldin A (SIGMA), 0.0025 mM Monensin (SIGMA) and 0.2 μg/mL anti-CD107a-APC antibody (Biolegend) were added to the media and then cultured over-night. Analysis of total IFNγ expression and co-expression with CD107a (polyfunctionality) in CD8+ T cells was performed by flow cytometry.

In vitro analysis of CD8+ T cells functionality

CD4+ T cells were purified from PLWH, stained with 5 μM violet cell trace tracker (Invitrogen), and cultured in the presence of 30 μM Raltegravir (Selleck Chemicals) alone, to prevent new rounds of infections in culture, or in combination with 50 nM Romidepsin (Selleck Chemicals), as a latency reversal agent, in the absence or the presence of autologous CD8+ T cells treated with MDDC pre-treated under different conditions at a 2:1 ratio.

In some functional experiments, we evaluated the impact of blocking different checkpoint inhibitory receptors and/or stimulating glycolysis in CD8+ T cells during co-culture with the activated MDDCs. In these assays, media was supplemented with 2 μg/mL of mouse IgG1 K anti-human PD-1 antibody (Biolegend) either alone or in combination with 1 μg/mL mouse IgG2 B anti-human TIGIT (R&D systems) or 1 μg/mL goat IgG anti-human TIM-3 (R&D systems) and alone or in combination of 5 mM Metformin (SIGMA) consistent with concentration ranges used in previous studies.36, 37, 38, 39 As a control, we used corresponding isotype control antibodies (mouse IgG1 K and mouse IgG2 B, both from Biolegend; goat IgG from SIGMA) and Metformin´s carrier.

Flow cytometry and fluorometric analyses

Analysis of cell viability ex vivo or after culture was performed using APC-H7 (Tonbo Biosciences) or LIVE/DEAD Fixable Yellow 405 (Invitrogen) viability dye, in the presence of different panels of monoclonal antibodies. Clones, fluorochromes and commercial information of antibodies used are detailed in Supplementary Table 1. For analysis of MDDC activation we used mAbs against lineage markers (CD3, CD19, CD56), CD11c, CD40, and HLA-DR. For analysis of in vitro activation of HIV-1 specific CD8+ T cell responses, anti-human CD3, CD8, CD107a and IFNγ mAbs were used. For functional assays with CD8+ T cells anti-human CD3, CD4, CD8, and anti-HIV-1 p24 mAbs were used. CD8+ T cell memory and exhaustion phenotypes were defined using anti-human CD3, CD8, CD45RO, PD1, TIGIT, TIM3, and CCR7 mAbs. PBMC from PLWH and HIV-1 negative individuals were also stained using a combination of anti-CD3, CD8, CD11c, CD14, HLA-DR mAbs and intracellular anti-IDO-1 mAb. Samples were analysed on a FACS Canto II cytometer (BD Biosciences). Analysis of individual and Boolean multiparametric flow cytometry data was performed using FlowJo v10.6 software (Tree Star).

Fluorometric quantification of tryptophan levels in plasma from PLWH was performed using the Tryptophan Assay kit (Abcam), following manufacturer´s instruction, and analysed with a GloMax Discover instrument (Promega).

RNA extraction and qPCR mRNA quantification

Total RNA was isolated using the RNeasy Micro Kit (Qiagen) either from MDDCs from HIV-1 negative donors or from memory CD45RA− CD8+ T cells from PLWH and HIV-1 negative controls. cDNA was then synthesized and transcriptional levels of PD-L1, CD155 and Gal-9 on MDDC, and HIF1α, GLUT1, PDK1 and GAPDH on memory CD8 T cells were quantified by qRT-PCR. Primers sequences are detailed in Supplementary Table 2. Amplifications were performed in a StepOne Plus Real time PCR system (Applied Biosystems). Finally, relative mRNA expression was determined after normalization of each transcript to endogenous β-actin expression.

Analysis of metabolic activity

CD8+ T cells from HIV-1 negative donors or PLWH on ART at different times since treatment initiation were isolated as previously described and cultured for 2 h in the presence of IL-2 (10 IU/ml). Subsequently, 3 × 105 cells from each donor were plated per replicate in DMED media adjusted to a pH of 7.4 in a p96 well plate (Seahorse XFe96 FluxPak Agilent Technologies 102416-100) in the presence of 1 mM Sodium pyruvate, 25 mM Glucose and 1 mM Glutamine. Cells were left unstimulated or activated using Immunocult human CD3/CD28 T Cell Activator (Stem Cell Technologies) for 27 min; and 1 μM oligomycin, 1.5 μM CCCP, and 1 μM Rotenone plus 1 μM Antimycin A were sequentially injected following the Seahorse XF96 Analyzer protocol specifications. Oxygen consumption rate (OCR) and extracellular acidification rate (ECAR) was measured using XF96 Extracellular Flux Analyzers (Seahorse); three measures (5 min) were obtained for each condition. Mitochondrial mass was evaluated as a control by flow cytometry using the MitoTracker Green staining probe (Invitrogen) at a concentration of 6.25 nM per million of cells. In some experiments, incorporation of glucose was determined by flow cytometry analysis using 2-NBDG (Invitrogen) fluorescent probe.

Statistical analysis

Statistical significance of differences between cells from different or within the same patient cohort under different treatments were assessed using Mann Whitney U or Wilcoxon matched-pairs signed-rank tests. Multiple comparison correction using a Kruskal-Wallis test with post-hoc Dunn's test correction method was applied when appropriate. Chi-square with Yate's correction was used to compare differences in proportions of some parameters within different cell/subject populations. Non-parametric Spearman correlations were performed to test both individual correlations and to generate a correlation network. Association of individual phenotypical and functional data with clinical parameters (years under ART, age at sample collection (y), sex, NADIR CD4+ T cell counts, current CD4+ T cell counts, current CD8+ T cell counts, months from HIV-1 detection to ART initiation) was evaluated using a multiple linear regression model based on a backward elimination technique. Potential confounding variables were gradually removed from the model when they did not modify the β-standardised coefficient of years under ART in more than 10% after their removal. In order to check if the model fulfilled the assumptions for multiple linear regression, several previous analyses were performed. First, an analysis of the standardised residuals was carried out to test for normality, linearity and homogeneity of variances. The dependent variable was transformed to a logarithmic scale in cases it did not follow a normal distribution. To check the absence of autocorrelation, Durbin-Watson index was employed. Finally, the presence of collinearity was evaluated by means of the Tolerance, Variance Inflation Factor (VIF) and Condition Index. Bivariate statistical analyses were performed using GraphPad Prism 7.0 software and multivariate analysis with IBM SPSS Statistics v20.

Role of funders

Funding sources were not involved in any decision regarding this manuscript; including study design, data collection, data analyses, interpretation, or writing of the manuscript.

Results

ART duration determines basal and DC-induced magnitude and polyfunctionality of HIV-specific CD8+ T cell in PLWH

We recruited for our study a cohort of n=49 PLWH who had been under ART for at least 1 year and were characterized by undetectable HIV-1 plasma viremia in blood (Table 1, Figure 1). We evaluated associations between ART duration and detection of HIV-1-specific CD8+ T cells from n=35 individuals in response to autologous monocyte derived dendritic cells (MDDCs) loaded with HIV-1 Gag peptides in vitro (Figure 1, Supplementary Figure 1a). As shown in Figure 2a, we observed a significant positive correlation (p=0.0239) between the proportions of IFNγ+ CD8+ T cells induced in the presence of MDDC loaded with Gag peptides and the number of years on ART. This association was further confirmed using a multivariate model (Table 3). A ROC curve analysis predicted 10.5 years of ART as a cut-off point classifying two PLWH subgroups with different intrinsic optimal induction of HIV-1 specific CD8+T cells (defined as a minimum of 2.5 fold-change in IFNγ expression from baseline) in response to MDDC (Figure 2b). Therefore, we defined two PLWH subgroups of individuals who had been under either long-term ART, for more than a decade (from hereafter, LT-ARTp), or short-term ART, for less than 10 years (from hereafter, ST-ARTp). These two groups were defined by intrinsic differences in age and in NADIR CD4+ T cell counts (p<0.0001 age; p=0.0039 NADIR; Table 1). Consistently, we observed significant differences (p=0.0006) in proportions of IFNγ+ CD8+ T cells exposed to MDDC loaded with Gag peptides in these two PLWH subgroups (Figure 2b, pie charts). Next, we further assessed whether MDDC primed with 2’3’-c'diAM(PS)2 agonist for Stimulator of Interferon genes (STING) and the Toll like receptor 3 (TLR3) ligand Poly I:C adjuvants and loaded with HIV-1 Gag peptides could potentiate the magnitude and polyfunctionality of autologous HIV-1-specific CD8+ T cells responses in these two separate PLWH subgroups (Supplementary Figure 1a,c). First, we confirmed that MDDCs from each PLWH subgroup were able to similarly and significantly increase CD40 expression after exposure to adjuvants, despite a tendency to higher basal levels on ST-ARTp (Supplementary Figure 1b). In terms of magnitude, co-culture with Gag adjuvant-primed MDDCs significantly increased proportions of INFγ+ CD8+ T cells from baseline in both ST-ARTp (p=0.0049) and LT-ARTp (p=0.0001) (Figure 2c).

Figure 2

Magnitude and polyfunctionality of HIV-specific CD8T cell responses in PLWH on ART. N=35 PLWH (a) Spearman correlation of fold-change in IFNγ expression from total live CD8+ T cells after Gag-peptide presentation by MDDCs, highlighting optimal response established as a minimum of 2.5 fold-change in IFNγ from baseline. Spearman r and p values are shown on the left for each correlation. (b) Left panel showing ROC curve for classification of our cohort based on CD8+ T cell IFNγ response to Gag-loaded MDDC and years under treatment of each individual; and right panel showing pie-charts of the stratification of PLWH based on less than 10 years (ST-ARTp, light grey), or equal or more than 10 years (LT-ARTp, dark grey) of ART duration. ROC curve was calculated with SPSS v20 and statistical significances of pie charts was calculated using a Chi-square test with Yates’ correction (***p<0.001). (c-d) Fold-change in IFNγ expression (c) and fold-change in polyfunctional responses (CD107a+ IFNγ+ cells) (d) from total live CD8+ T cells after stimulation of MDDCs in ST-ARTp (left plots, in light grey) and LT-ARTp (right plots, in dark gray). Statistical significance was calculated using two-tailed Wilcoxon test (*p<0.05; **p<0.01; ***p<0.001; ****p<0.0001).

Table 3

Multiple linear regression model for Fold-change on IFNγ+ CD8+ T cells after priming with Gag-loaded MDDC Initial model.

	Coefficientsa
	Model	Standardized Coefficients	Sig.	95% Confidence Interval for B
				Lower Bound	Upper Bound
	(Constant)		.773	-3.016	2.267
	YEARS_UNDER_ART	.554	.060	-.004	.202
	AGE (y)	.030	.908	-.046	.051
	SEX	-.143	.443	-1.712	.772
	CD4 NADIR	.557	.029	.000	.005
	CUR_CD4	-.253	.253	-.003	.001
	CUR_CD8	.170	.387	.000	.001
	DTC_ART(m)	-.196	.277	-.014	.004
	Dependent Variable: log_fcmddcgag
	Final model

log_fcmddcgag=logarithm of Fold-change on IFNγ+ CD8+ T cells after priming with Gag-loaded MDDC; YEARS_UNDER_ART=years under antiretroviral treatment; AGE (y)=age at sample collection (years); NADIR_CD4=NADIR CD4+ T cell count; CUR_CD4=current CD4+ T cell count; CUR_CD8=current CD8+ T cell count; DTC_ART (m)=months from HIV-1 detection to ART initiation.

Importantly, Gag-loaded adjuvant-primed MDDCs also significantly increased the frequencies of polyfunctional IFNγ+ CD107a+ CD8+ T cells in both ST-ARTp (p=0.0012) and LT-ARTp (p=0.0017) compared to baseline (Figure 2d). No association between ART duration and polyfunctionality of HIV-1-specific T cell detection after DC treatment was observed using a multivariate model (Supplementary Table 3). Together, our results indicate that prolonged ART restores intrinsic abilities of HIV-1-specific CD8+ T cells to respond to DC treatment, while adjuvant stimulation enhances polyfunctionality of activated T cells.

Differential restoration of cytotoxic function after DC treatment in CD8+ T cells from LT-ARTp and ST-ARTp

Next, we assessed whether changes on the magnitude and polyfunctionality of HIV-1 Gag-specific CD8+ T cell response after treatment with adjuvant-matured Gag-loaded MDDCs correlated with an increase in their cytotoxic capacity to eliminate HIV-1-infected CD4+ T cells (Figure 1). To address this, CD8+ T cells from ST-ARTp and LT-ARTp pre-stimulated with MDDCs primed in the absence or the presence of Gag peptides and adjuvants were subsequently co-cultured in bulk with autologous CD4+ T cells treated with Raltegavir and Romidepsin (Supplementary Figure 1a). After 24 h, frequencies of cells expressing intracellular HIV-1 p24 were evaluated by FACS (Supplementary Figure 1a,d). As shown in Supplementary Figure 2a, basal detection of HIV-1 p24+ CD4+ T cells cultured with Raltegavir tended to be higher in ST-ARTp compared to LT-ARTp (p=0.0575). Romidepsin treatment increased the frequencies of p24+ cells in 48% of PLWH, and more significantly in LT-ARTp (p=0.042; 53% Supplementary Figure 2b).

Notably, Gag-adjuvant-primed MDDCs enhanced cytotoxic capacities of CD8+ T cells to reduce frequencies of HIV-1 p24+ CD4+ T cells below baseline levels (p<0.0001) in a significantly higher proportion of LT-ARTp individuals compared to ST-ARTp (p=0.0062) (Figure 3a-b, in blue). Restoration of CD8+ T cell function in these PLWH tended to associate with higher levels of polyfunctional HIV-1-specific CD8+ T cells after adjuvant-primed Gag-MDDC (p=0.0294; Figure 3c, lower panel). In contrast, dysfunctional CD8+ T cells unable to reduce proportions of HIV-1 p24+ CD4+ T cells after receiving MDDC stimulation (p=0.0002) were more represented among ST-ARTp compared to the LT-ARTp group (p=0.0062) (Figure 3a-b). We also observed a significant inverse association between the increase of polyfunctional HIV-1-specific CD8+ T responses after MDDC treatment and p24+ cell detection in this PLWH group (p=0.0042; Figure 3c, upper panel). While no significant differences in proportions of p24+ CD4+ T cells induced by Romidepsin were observed between LT-ARTp and ST-ARTp (Supplementary Figure 2c), basal viral reactivation in patients exhibiting dysfunctional CD8+ T cells was significantly lower (p=0.0087; Supplementary Figure 2d) and tended to be induced in the presence of unstimulated MDDC and CD8+ T cells (Figure 3a). We also observed that proportions of IFNγ+ CD8+ T cells were higher in ST-ARTp in response to MDDC in the absence of HIV-1 Gag peptides (p=0.0317), and a similar non-significant trend was present in PLWH exhibiting dysfunctional CD8+ T cells (Supplementary Figure 3a-c). Therefore, functional restoration of HIV-1-specific CD8+ T cells from PLWH in response to Gag-adjuvant-primed MDDCs might be influenced by multiple parameters including their basal state, the increase in polyfunctionality after DC stimulation, the basal reactivation of p24+ cells and the number of years on ART.

Figure 3

Cytotoxic function of CD8T cells from PLWH after DC-treatment. N=31 (N=18 ST-ARTp; N=13 LT-ARTp). (a) Proportions of intracellular HIV-1 p24+ cells from CD4+ T cells cultured in media supplemented with Raltegavir and Romidepsin alone or in the presence of autologous CD8+ T cells and primed with MDDC pre-cultured under the indicated conditions. PLWH were stratified by enhanced (in blue) or dysfunctional (in red) cytotoxic activity of CD8+ T cells eliminating p24+ CD4+ T cell detection after DC treatment. ST-ARTp (light grey) and LT-ARTp (dark grey) PLWH are highlighted within each functional profile. Statistical significance was calculated using two-tailed Wilcoxon test (*p<0.05; **p<0.01; ****p<0.0001). (b) Pie-charts showing percentage of dysfunctional (red) and enhanced functionality (blue) profiles contained within the ST-ARTp and LT-ARTp subgroups. Statistical significance was calculated using a Chi-square test with Yates’ correction (**p<0.01). (c) Spearman correlation of proportions of IFNγ+ CD107a+ (polyfunctional) CD8+ T cells after priming with adjuvant-activated Gag-loaded MDDC vs p24+ T cells present in co-culture with these CD8+ T cells activated with adjuvant-primed Gag-loaded MDDC (N=14 enhanced functionality, and N=12 dysfunctional; Upper panel). P and r values are shown on the right, in black for total values, in red for dysfunctional, and in blue for enhanced functionality. Proportions of IFNγ+ CD107a+ (polyfunctional) CD8+ T cells after priming with adjuvant-activated Gag-loaded MDDC comparing enhanced functionality (EF) and dysfunctional (DF). Statistical significance was calculated using two-tailed Mann-Whitney U test after outlier removal using the ROUT method (*p<0.05).

Differential memory subset distribution and distinct patterns of co-expression of checkpoint inhibitory receptors in CD8+ T cells from ST-ARTp and LT-ARTp

Differences in basal response to HIV-1 Gag-peptide stimulation and functional enhancement of CD8+ T cells from ST-ARTp and LT-ARTp PLWH after treatment with Gag-adjuvant-primed MDDCs could be associated to either deficiency on DC activation, memory subset distribution or immune exhaustion of CD8+ T cells. We previously showed that our adjuvant combination similarly increased the percentage of CD40+ MDDCs in both ST-ARTp and LT-ARTp (Figure 1, Supplementary Figure 1b). Interestingly, lower plasma Tryptophan levels (p=0.0495) and higher expression of IDO-1 (p=0.0221) were present on LT-ARTp compared to ST-ARTp, suggesting that dysfunctional CD8+ T cells in the latter were not due to a tolerogenic environment (Supplementary Figure 4a).

Since dysfunction of HIV-1-specific CD8+ T cell responses has been linked to reduced percentages of central memory (CM) cells, we next analysed the proportions of different CD8+ T cell memory subsets in ST-ARTp and LT-ARTp (Figure 1). We observed that CD8+ T cells from LT-ARTp contained higher proportions of CCR7+ CD45RO+ CM cells than in ST-ARTp (p=0.0362), reaching similar percentages to HIV-1 negative controls (HC; Figure 4a). On the contrary, CD8+ T cells from ST-ARTp tended to present higher proportions of CCR7- CD45RO+ effector memory (EM) and CCR7− CD45RO− terminally differentiated (TD) cells (Figure 4a). Preservation of CM cells was most evident in LT-ARTp that had received treatment shortly after diagnosis (p=0.0239; Figure 4a, right plot).

Figure 4

Memory subset distribution and co-expression of checkpoint inhibitor receptors in CD8T cells from different PLWH subgroups. N=11 HIV-1 negative controls (HC); N=15 ST-ARTp; N=11 LT-ARTp. (a) Percentage of naïve, NA (CCR7+ CD45Ro−); central memory, CM (CCR7+ CD45Ro+); effector memory, EM (CCR7− CD45Ro+); and terminally differentiated, TD (CCR7− CD45Ro−) CD8+ T cells from HIV negative controls (HC; green bars), ST-ARTp (light grey bars) and LT-ARTp (dark grey bars). Statistical significance was calculated using two-tailed Mann-Whitney U test (*p<0.05). On the right, Spearman correlations between the percentage of CM CD8+ T cells and months since HIV-1 infection diagnosis to ART initiation for ST-ARTp (light grey) and LT-ARTp (dark grey dots). Spearman r and p values are shown on the left for each correlation. (b-e) Proportion of PD1+TIGIT+TIM3− (b-c; purple) or PD1+TIGIT−TIM3+ (d-e; green) populations from total TIGIT+ or TIM3+ cells, compared to PD1−TIGIT+TIM3− (B-C; red) or PD1-TIGIT−TIM3+ (D-E; yellow) population from total TIGIT+ or TIM3+ populations. Statistical significance between the mentioned double and single positive populations was calculated using two-tailed matched pairs Wilcoxon test (**p<0.01; ***p<0.001) within each participant group and using two-tailed Mann-Whitney U test (*p<0.05) between different individuals.

We next asked whether differences on proportions of CD8+ T cell memory subsets from LT-ARTp and ST-ARTp could also be associated with the immune exhaustion state of these lymphocytes (Figure 1). In addition to inducing maturation, adjuvant treatment also tends to increase expression of ligands for immunomodulatory checkpoint inhibitory receptors such as PD-L1, CD155 and Galectin-9 on MDDCs (Supplementary Figure 4b), suggesting that binding of these receptors might limit the functional improvement of CD8+ T cells from PLWH after MDDC stimulation. In addition, the co-expression of checkpoint inhibitory receptors has been previously associated to terminal exhaustion on T cells.,, Therefore, we determined the surface co-expression of PD1, TIGIT and TIM3 in memory CD8+ T cells from ST-ARTp, LT-ARTp and HC by flow cytometry (Supplementary Figs. 5a-b). Notably, CD8+ T cells from ST-ARTp were significantly enriched on PD1+ TIGIT+ TIM3− CM and EM cells in contrast to LT-ARTp, whose CD8+ T cells contained significantly higher proportions of the PD1− TIGIT+ TIM3− simple positive memory (CM, p=0.0049; EM, p=0.0061) cells, similarly to HC (Figure 4 b-c, Supplementary Figure 5a-b). CD8+ T cells from ST-ARTp also contained higher proportions of PD1+TIM3+ within the TIM3+ CM and EM populations compared to LT-ARTp, which were more enriched in PD1−TIM3+ cells (CM, p=0.001; EM, p=0.0059; Figure 4d-e, Supplementary Figure 5a-b). In addition, PD1+ TIGIT+ TIM3+ cells were infrequent but their proportions were significantly higher in EM CD8+ T cells from ST-ARTp, compared with LT-ARTp (p=0.0339) and HC (p=0.0506) (Supplementary Figure 5b). Notably, proliferating CM and EM CD8+ T cells stimulated with allogeneic adjuvant-primed MDDCs selectively induced TIM3 expression, whereas the induction of TIGIT and PD1 expression was weaker and not restricted to proliferating cells (Supplementary Figure 6a-c). Therefore, non-overlapping co-expression profiles of different checkpoint inhibitory receptors induced after MDDC treatment are present on CD8+ T cells from PLWH at different times since ART initiation.

Differential induction of glycolytic metabolic activity in CD8+ T cells from PLWH subgroups

Metabolic plasticity and glycolytic activity have been associated with exhaustion, effector function of CD8+ T cells and with their ability to mediate viral control., Thus, we focused on studying the metabolic profiles of CD8+ T cells from LT-ARTp and ST-ARTp with either high cytotoxic function or dysfunctional characteristic and displaying opposite co-expression profiles of checkpoint receptors. These patients were also matched by age and sex with cells from HIV negative donors (Tables 1 and 2). Then, we studied mitochondrial respiration and the glycolytic rate by determining oxygen consumption (OCR) and extracellular acidification rate (ECAR) on CD8+ T cells from these PLWH groups and HC at baseline and after TCR/CD28 stimulation (Figure 1, Figure 5a-b, Supplementary Figure 7a-b, also see Methods). While CD8+ T cells from HC induced significantly higher OCR after TCR stimulation (p=0.0222 at 83min), OCR values were significantly lower on stimulated CD8+ T cells from ST-ARTp compared to HC (p=0.0090 at 83min) and partially preserved in LT-ARTp (Figure 5a, Supplementary Figure 8a,c), suggesting potential defects on mitochondrial respiration on PLWH that were more marked in cells from ST-ARTp. In addition, TCR-stimulated CD8+ T cells from LT-ARTp showed significantly higher ECAR induction compared to HC (p=0.0201, 73min), suggesting increased ability to induce glycolysis (Figure 5b, Supplementary Figure 8b,d). CD8+ T cells from ST-ARTp were less efficient inducing ECAR after TCR stimulation and not significantly different from HC (Figure 5b, Supplementary Figure 8b,d). The observed changes were not due to differences in glucose uptake or total mitochondrial mass between ST-ARTp, LT-ARTp and HC subgroups (Supplementary Figure 8e-f). Alternatively, basal transcriptional levels of the glucose metabolism regulator HIF1α were increased on memory CD8+ T cells from ST-ARTp compared to HC (p=0.0106). Similar patterns of expression were observed for other glycolysis regulators such as PGK1 and GAPDH on ST-ARTp (Supplementary Figure 9a). In addition, mRNA levels of GLUT1 in memory CD8+ T cells from LT-ARTp were significantly lower compared to HC (p=0.0056; Figure 5c). Together, our results indicate that prolonged ART might preserve the ability to induce glycolysis and mitochondrial respiration after TCR stimulation in CD8+ T cells from PLWH.

Figure 5

CD8T cell oxidative and glycolytic metabolism in PLWH. (a-b) Oxygen consumption rate (a; OCR) and extracellular acidification rate (b; ECAR) in CD8+ T cells from PLWH comparing basal (light line) and TCR activated (dark line) cells from ST-ARTp (N=10; upper plots; light grey), LT-ARTp (N=10; middle plots; dark grey), and HIV-1 negative controls (HC; N=12; lower plots; green). Statistical significance per each timepoint was calculated with a multiple t test analysis. (c) RT-qPCR analysis of HIF1α (upper) and GLUT1 (lower) transcriptional expression normalized to β−actin mRNA levels in memory CD45RA− CD8+ T cells isolated from total PBMCs from HIV negative controls (HC; N=9; green) and PLWH (ST-ARTp; N=9; light grey, and LT-ARTp; N=9; dark grey). Statistical significance between double and single positive populations was calculated using two-tailed Wilcoxon test (*p<0.05).

Combined blockade of checkpoint inhibitory receptors and administration of glycolysis promoting drugs efficiently restores cytotoxic function of CD8+ T cell from ST-ARTp

Specific combinations of PD1, TIGIT and TIM3 checkpoint inhibitory receptors may differentially affect the glucose metabolism26, 27, 28 and function of CD8+ T cells from ST-ARTp and LT-ARTp (Figure 1). Supporting this possibility, we observed significant positive correlations between the increase on maximal glycolytic profiles after TCR activation on CD8+ T cells, and the percentages of single positive TIGIT (p=0.0094 CM; p=0.0872 EM) or TIM3 (p=0.0161 CM; p=0.0037 EM) cells within memory cell subsets (Figure 6a-b, upper panels; Supplementary Figure 9b). Opposite associations were observed between higher ratios of co-expression of PD1 and TIGIT (p=0.0401 CM; p=0.0623 EM) or TIM3 (p=0.0567 CM; p=0.0503 EM) and the induction of glycolysis in these memory CD8+ T cell subsets (Figure 6a-b, lower panels; Supplementary Figure 9b). Age also correlated with higher increase in ECAR (p=0.077), lower PD1 and TIGIT co-expression (p=0.058 CM, p=0.072 EM) and higher proportions of TIM3+ PD-1− cells (p=0.105 CM, p=0.013 EM) (Supplementary Figure 9b). Therefore, our data demonstrate that TIGIT and PD1 co-expression in CM and EM CD8+ T cells correlate with impaired ability to induce glycolysis in total CD8+ T cells from PLWH.

Fig. 6

Correlation and fine-tuning of glycolytic metabolism and memory exhaustion in CD8T cell from PLWH. (a-b) Spearman correlations between ΔECAR at maximal activation after TCR stimulation (73 minutes) and proportions of PD1−TIGIT+TIM3− (a, upper panel; N=14; red) or PD1-TIGIT−TIM3+ (b, upper panel; N=14; yellow) to total TIGIT+ or TIM3+ cells or ratios of the indicated populations (lower plots; PD1 vs TIGIT purple and red; PD1 vs TIM3 green and yellow; N=14 each) within central memory CD8+ T cells. Spearman r and p values are shown on the upper left area of each plot. (c) Proportions of p24+ cells from total live CD4+ T cells to basal CD4+ T cells p24+ detection to the different MDDC and CD8+ T cell treated conditions (N=8). Light purple bars indicate the use of anti-PD1 and anti-TIGIT blocking antibodies in combination; light green bars indicate the use of anti-PD1 and anti-TIM3 blocking antibodies combination. Stripped bars indicate the use of 5 mM Metformin, either alone or in combination with the blocking antibodies. Statistical significance to the CD4+ T cell basal condition was calculated using two-tailed Wilcoxon test (*p<0.05).

Finally, we asked whether simultaneous blockade of multiple checkpoint inhibitory receptors and/or treatment with pro-glycolytic drugs such as Metformin might more efficiently restore functional properties of CD8+ T cells from ST-ARTp after DC-treatment (Figure 1). To test these strategies, we stimulated dysfunctional CD8+ T cells from ST-ARTp with autologous adjuvant-primed and Gag-peptide loaded MDDCs in the presence of individual or a cocktail of antibodies specific for PD1, TIGIT and TIM3 alone or in combination with Metformin at a concentration capable of inducing ECAR without affecting viability (Supplemental Figure 9c). As shown in Figure 6c, the combined treatment of Metformin with anti-TIGIT and anti-PD1 mAbs was more efficient in restoring the cytotoxic capacities of CD8+ T cells from ST-ARTp and significantly reduced proportions of p24+ cells compared to CD4+ T cells alone (p=0.0156), in contrast to other combinations or corresponding isotype controls. Together, our data indicate that simultaneous blockade of TIGIT and PD1 combined with pro-glycolytic metabolism drugs can improve the functionality of HIV-1-specific CD8+ T cells from ST-ARTp after MDDC stimulation.

Discussion

The present study evaluated the efficacy of adjuvant-primed MDDC as a potential therapeutic candidate to restore cytotoxic capacities of CD8+ T cell from different groups of PLWH, who are under ART and characterized by undetectable plasma HIV-1 viral load. Previous studies have suggested that innate-specific adjuvant-mediated activation could be useful to potentiate HIV-1-specific CD8+ T cells., However, such systemic adjuvant administration approaches failed in preventing viral rebound after ART interruption.44, 45, 46, 47, 48, 49 Our therapeutic approach based on the activation of DCs has been previously associated with increased polyfunctional HIV-1-specific CD8+ T cell responses in lymphoid tissues in vivo. Thus, our immunotherapy strategy allows avoiding bystander activation of cells other than DCs in response to adjuvants. We have also shown that this method can also be useful to induce polyfunctional HIV-1-specific CD8+ T cell responses from PLWH resulting in reduction of HIV-infected CD4+ T cells in vitro.

We have also demonstrated that the years under ART determine the basal capacity of HIV-1 specific CD8+ T cells to respond to MDDC stimulation and antigen presentation. We have observed differences on checkpoint inhibitory receptor phenotypes and on frequencies of central and effector memory CD8+ T cells that are associated with the time since ART initiation. These results are in line with previous studies reporting the recovery from immune exhaustion upon HIV-1 pharmacological suppression, as well as differences in metabolism in these treated individuals.,50, 51, 52 Our study identifies immunological and metabolic patterns that are specifically associated with effective responses of CD8+T cells to DC-based treatment in different subgroups of PLWH. Our data might be useful to personalize immunotherapies in different groups of PLWH to more efficiently mimic CD8+ T cell responses observed in spontaneous HIV-1 controllers, or to increase the frequencies of suppressed individuals capable of controlling viral replication after treatment interruption.,55, 56, 57, 58

We have defined that prolonged treatment duration is required to restore phenotypical and effector capacities of CD8+ T cells and to respond to MDDC-based HIV-1 vaccines. Those results are in line with previous studies by Perdomo-Celis et al, demonstrating that CD8+ T cell cytotoxic and polyfunctional capacities are reduced in PLWH compared to HIV-1 negative individuals, and that ART only slightly reinvigorates the cytotoxic capacities after two years of treatment. We have found a negative correlation between the time from HIV diagnosis to ART initiation and preserved proportions of CM CD8+ T cell subpopulation in LT-ARTp. These findings are in agreement with previous studies suggesting heterogenic efficacy of immunotherapy boosting HIV-1 specific CD8+ T cells and the importance of early ART initiation preserving immune function of memory T cells., In addition, previous studies suggest that higher HIV-1 DNA is associated with increased detection of HIV-1 specific T cells; in our study, we have not observed significant differences between basal HIV-1 p24+ levels in ST-ARTp and LT-ARTp PLWH. However, higher basal p24 expression and differential efficacy of Romidepsin mediating effective viral reactivation in the presence of MDDC might be linked to dysfunctional response of CD8+ T cells. In fact, higher induction of IFNγ+ CD8+ T cells in the presence of MDDC without Gag peptide stimulation tended to be detected in ST-ARTp PLWH with dysfunctional response to immunotherapy. Therefore, inflammatory responses by DC or bystander cells might also affect antigen availability and functionality of HIV-1-specific cells as previously suggested in HIV-1, and HBV infections.

Limitations of the present study include the low sample size from our PLWH and HIV negative cohorts matched by age and sex and the unavailability to include all participants in every individual analysis performed, and finally considering IFNγ and CD107a co-expression as a readout of polyfunctional HIV-1-specific T cells without taking into account their co-expression with TNFα, which has been associated with durable and efficient CD8+ T cell responses., In addition, age was intrinsically higher in the LT-ARTp cohort due to prolonged treatment duration, leading to significant associations of multiple functional and phenotypical data with this parameter. Therefore, additional studies using a larger number of patients with similar demographic characteristics and analysing TCR specificity by tetramer staining should be conducted.

On the other hand, our study provides relevant information about the parameters determining the exhaustion and metabolic state of CD8+ T cells and their connection with the response to DC immunotherapy. We have described that ST-ARTp contain lower proportions of CM CD8+ T cells and that those cells are characterized by higher co-expression of TIGIT and PD1. Interestingly, LT-ARTp displayed higher percentages of CM CD8+ T cells, which were more enriched by single expression of TIGIT or TIM3. While previous studies had described that co-expression of checkpoint inhibitory receptors might be associated with reduced cytotoxic activity of HIV-1-specific CD8+ T cells in PLWH,66, 67, 68, our study provides new information suggesting that different combinations of specific checkpoint inhibitory receptors might differentially affect functional exhaustion of T cells. The role of PD1 limiting the development and effector function of memory CD8+ T cells, and the beneficial effect of PD1 blockade have already been described in cancer and also in other viral infections. Anti-PD1 mAb based therapies have yielded promising results in animal models of SIV-infection in macaques, enhancing specific CD8+ T cell responses and reducing the plasma viral load, resulting in enhanced survival of the animals. However, they were not sufficient to prevent viral rebound after treatment interruption.,, Thus, modulation of additional checkpoint inhibitory receptors and metabolic pathways might be required to more efficiently reinvigorate functional HIV-specific CD8+ T cells in PLWH. In this regard, we have demonstrated that the combined blockade of anti-PD1 and anti-TIGIT improves the cytotoxic capacities of CD8+ T cells from ST-ARTp against HIV-infected CD4+ T cells more effectively than anti-PD1 blockade alone. These data are supported by similar results in a gastric cancer animal model. Our results also indicate that combined TIM3 and PD-1 blockade seemed to disrupt cytotoxic function of CD8+ T cell from ST-ARTp individuals. Although TIM3 blockade inhibited T regulatory function and has yielded promising results on different cancer model, TIM3 has also been reported as a marker of proliferating IFNγ+ Th1 cells, key in the antiviral response. Thus, the effector function of these cells could be dependent on TIM3 expression., In this regard, CD8+ T cells co-expressing PD1 and TIM3 are more prone to respond to PD1 blockade in cancer therapies. Therefore, it is unclear whether TIM3 expression might be beneficial or detrimental for CD8+ T cell response generation in PLWH and different combinations with other checkpoint receptors should be further studied. In addition, myeloid cells from LT-ARTp are characterized by higher IDO-1 expression and lower plasma Tryptophan detection than ST-ARTp. IDO-1 is induced upon HIV-1 infection and its expression is reduced after ART initiation,, but long-term treatment or age might also affect the expression or function of this molecule., Despite these results, DC-therapy more efficiently restores HIV-1 specific CD8+ T cells in LT-ARTp. Thus, the impact of IDO-1 facilitating durable functional HIV-1 specific T cells should be investigated.

Another key aspect of our study is the fact that we have analysed the association between phenotypical and functional differences on CD8+ T cells from PLWH exposed to DC with checkpoint inhibitory markers expression and other processes associated to exhaustion, such as mitochondrial respiration and the glucose metabolism. Previous studies have reported a correlation between glycolysis increase and effective cytotoxic functions of CD8+ T cells against HIV-infected cells in treated PLWH. Reduced glycolysis has been associated to HIV-1 latency and oxidative stress in infected individuals. We reported higher induction of ECAR after TCR stimulation in CD8+ T cells from LT-ARTp displaying effective cytotoxic function against HIV-1-infected cells, whilst enrichment of TIGIT+ PD1+ in CD8+ T cells from ST-ARTp associated to reduced ability to increase ECAR upon TCR activation. We were able to describe a correlation between CD8+ T cell effector and cytotoxic functions upon MDDC activation, basal CD8+ T cell memory exhaustion phenotypes, metabolic dysfunctional state and years under ART in a cohort of PLWH. However, an important limitation from our study is that we did not directly address the metabolic and functional properties of CD8+ T cells from ST-ARTp and LT-ARTp isolated based on the differential expression of checkpoint receptors. In addition, immunosenescence has been described as a process affecting metabolism throughout adult life to elderly; however, CD8+ T cells from LT-ARTp characterized by older age, still displayed preserved function and metabolic properties similar to our HIV negative cohort. Oxidative metabolism seems to be largely altered in PLWH, however, the mechanisms leading to these observations have not been assessed. The role of T cell factor-1, which is expressed by effective long-lived PD1-low memory CD8+ T cells during chronic infections,, and mitochondrial fission and fusion, may be also playing a role in these processes, contributing to the differences on the metabolic dysfunction described in this study.

Our PLWH cohort was defined by individuals on ART, with undetectable plasma HIV-1 viral load (<20 mRNA copies/ml), with no co-infection with HCV, and CD4+ T cell counts higher than 400 cells/ml, since prolonged treatment in PLWH has been described to partially restore CD8+ T cell function and reduce exhaustion, compared to non-treated PLWH.80, 81, 82 This allowed us to evaluate the capacity of our adjuvant-DC strategy to induce CD8+ T cell responses in PLWH at different times since treatment initiation. However, some of the observed responses and differences might not be present in viremic PLWH with low CD4+ and CD8+ T cell counts. In these patients, memory CD8+ T cell populations could be more enriched in a terminally and exhausted memory phenotype, and therefore less capable of mediating competent cytotoxic effector responses even after DC stimulation. Therefore, further analysis should address the effectiveness of DC therapy and the proposed combined treatment with blocking antibodies and glycolysis inductors for these particular populations of PLWH reinvigorating their memory T cells. In conclusion, our study identifies specific immunometabolic parameters for different groups of PLWH defined by antiretroviral treatment duration, non-overlapping expression of checkpoint inhibitory receptors and metabolic state of CD8+ T cells that can be modulated through personalized therapies to fine-tune functional HIV-1 CD8+ T cell responses, providing new tools to advance and improve DC-based HIV-1 vaccines.

Contributors

EMG developed the research idea and study concept, designed, supervised the study and verified the underlying data. MCM designed and conducted most experiments of the study. ISC contributed to functional assays. IT, MCM, CDA performed analysis of checkpoint receptors and proliferation in MLR experiments from the study. NMC, MCM and EMG designed and performed Seahorse experiments. MCM, ISC, CDA processed peripheral blood samples from PLWH and HIV negative donors. MJB, HDF, NMC provided critical feedback during experimental design and execution phases of the studies and were directly involved in the experiments and verified the underlying data. MJC provided reagents for transcriptional analysis of metabolic regulators and provided critical feedback. PMF performed the ROC curve and multivariate analyses. FSM, AA, MAMF, IDS, LGF, and JS provided peripheral blood from PLWH and HIV negative controls, reagents, clinical expertise and participated on the analysis of the data. All authors have read and approved the final version of this manuscript.

Data sharing statement

The data that support the findings of this study will be available upon reasonable request to the corresponding author of the study.

Declaration of interests

The authors have declared that no conflict of interest exists.