Abstract
Translocated lipopolysaccharide (LPS) activates monocytes via TLR4 and is hypothesized to increase cardiovascular disease risk in persons living with HIV. We tested whether mTOR activity supports LPS-stimulated monocyte production of pro-inflammatory cytokines and tissue factor (TF), as it propels the inflammatory response in several immune cell types besides monocytes. However, multi-omics analyses here demonstrate that mTOR activates a metabolic pathway that limits abundance of these gene products in monocytes. Treatment of primary human monocytes with catalytic mTOR inhibitors (mTORi) increased LPS-induced polyfunctional responses, including production of IL-1β, IL-6, and the pro-coagulant, TF. NF-κB-driven transcriptional activity is enhanced with LPS stimulation after mTORi treatment to increase expression of F3 (TF). Moreover, intracellular NAD+ availability is restricted due to decreased salvage pathway synthesis. These results document mTOR-mediated restraint of the LPS-induced transcriptional response in monocytes and a metabolic mechanism informing strategies to reverse enhanced risk of coagulopathy in pro-inflammatory states.
Similar content being viewed by others
Introduction
Persons living with HIV (PLWH) now face a growing burden of non-AIDS co-morbidities, rather than progressive immunodeficiency. Co-morbidities include a range of cardiovascular disease (CVD) pathologies1,2,3,4. Excess risk for PLWH is in part attributed to persistent immune activation resulting from microbial translocation across an impaired gut barrier5,6,7,8,9. Translocated microbial products, including lipopolysaccharide (LPS), activate innate immune cells, leading to the production of inflammatory mediators and hemostatic factors10,11. Therapeutic interventions addressing aberrant immune activation and coagulation could reverse these healthy lifespan-limiting comorbidities that may persist during viremia-suppressing antiretroviral therapy (ART).
Immune function relies on rapid responses to antigenic and inflammatory signals by highly specialized cells. During an immune response, naïve and memory T cells shift from a resting catabolic state and oxidative phosphorylation (OXPHOS) to growth, proliferation, and glycolysis—the “Warburg effect”—fueling the energetic demands, differentiation, proliferation, and cytokine production of these specialized cells12,13. At the center of this shift is the mechanistic target of rapamycin (mTOR), a conserved serine/threonine kinase that forms two complexes (mTORC1 and mTORC2) with distinct functions regulating metabolic pathways14.
The metabolic consequences of CD4+ T cell activation also dictate susceptibility to HIV. We previously established that mTOR activity governs increased susceptibility to HIV-1 infection after T cell activation by up-regulating biosynthesis of macromolecules required for HIV reverse transcription (RT) and cytoplasmic transport of RT products; along with others, we find that ATP-competitive, catalytic mTOR inhibitors (mTORi) targeting both enzymatic complexes efficiently suppress HIV replication, providing support for further assessing mTOR inhibitors as an adjunct to current ART15,16,17,18.
Signaling through toll-like receptors (TLRs) in myeloid-lineage cells also results in cell type-dependent activation of both mTOR complexes. LPS, which engages TLR419, is found in blood at elevated concentrations in PLWH6. TLR4-activation of monocytes by LPS suppresses OXPHOS in favor of a glycolytic program that supports inflammatory cytokine production6,20. Congruently, compared to cells from uninfected subjects, monocytes obtained from virally suppressed PLWH show increased glucose transporter 1 (Glut1) expression and more readily differentiate to lipid-laden foam cells, attributed in part to mTOR-dependent accumulation of cellular cholesterol consequent to upregulated, receptor-mediated uptake of LDL21,22,23. Given the central role of mTOR in coordinating intracellular utilization of glucose and cholesterol, its inhibition could address aberrant monocyte activation, inflammatory cytokine production, and atherogenic activity. This hypothesis has already led to rapamycin, an allosteric mTORC1 inhibitor, being tested clinically as an adjunct to ART to evaluate potential benefits in mitigation of immune activation as well as viral control24.
However, there is laboratory evidence showing that inhibition of mTOR potentiates myeloid cell pro-inflammatory responses to LPS, raising the possibility of unintended exacerbation of inflammation with mTOR inhibition25. Here, we have characterized effects of mTORi in primary human monocytes stimulated with LPS ex vivo using flow cytometry, transcriptomics, and metabolomics. Results indicate that mTOR activity limits inflammatory and procoagulant responses to LPS in monocytes. mTORi treatment enhanced NF-κB-driven transcription and surface expression of the pro-coagulant tissue factor (TF) in LPS-stimulated monocytes, while concomitantly depleting NAD+ by impacting salvage pathway synthesis.
Results
mTORi pretreatment increased production of pro-inflammatory cytokines by primary human monocytes stimulated with LPS
To document the efficacy of suppression of mTOR activity in LPS-stimulated primary human monocytes isolated from peripheral blood mononuclear cells (PBMC), we probed for phosphorylated species of downstream mTOR targets ribosomal protein S6 and eukaryotic translation initiation factor 4E-binding protein 1 (4E-BP1) with and without pretreatment with two structurally distinct mTORi and the mTORC1 allosteric inhibitor, rapamycin (Fig. 1a). Both mTORi surpassed rapamycin in suppression of phosphorylation of these targets, which are critical to initiate translation downstream of mTOR activation. Despite the inhibition of these activities of mTOR that enable protein synthesis, and consistent with an earlier report25, pretreatment of monocytes with mTOR inhibitors did not decrease production of pro-inflammatory cytokines, including IL-1β and IL-6, following LPS exposure (Fig. 1b). Potentiation of IL-1β release by LPS after pretreatment with one mTORi studied here (AZD2014) exceeded that observed with LPS alone (Fig. 1b) and that mTORi was selected for further study. The same mTORi boosted IL-6 secretion by monocytes following LPS stimulation; LPS stimulation alone yielded variable increases in IL-6 production that did not reach significance (Fig. 1b). Pretreatment with other mTOR inhibitors trended similarly to AZD2014 (Fig. 1b). Increased IL-10 production, relative to unstimulated monocytes, was seen with LPS alone (Fig. 1b), but this anti-inflammatory cytokine was not increased by LPS following mTORi pretreatment. Pretreatment with either rapamycin or mTORi similarly suppressed LPS-mediated IL-10 increases, suggesting that this decrease in an anti-inflammatory cytokine may occur via mTORC1 (Fig. 1b). Neither rapamycin nor an mTORi suppressed TNF-α elicited by LPS stimulation in these experiments (Fig. 1b).
To confirm results from isolated monocytes with an independent method, we next performed intracellular cytokine staining of LPS-stimulated PBMC and gated on monocytes (Fig. 1c). Results confirmed that mTORi pretreatment enhanced IL-1β and IL-6 production by CD14+ cells exposed to LPS, relative to LPS exposure alone (Fig. 1c, d). Boolean gating analysis of cytokine production among these monocytes also revealed remarkably enhanced functionality (defined here as the number of different cytokines produced) in the context of mTOR inhibition. Monocytes among LPS-stimulated PBMC produced all three pro-inflammatory cytokines (IL-1β, IL-6, and TNF-α), representing 31.4% of the total monocyte population that was pretreated with an mTORi versus 0.8% among the control cells exposed only to LPS (Fig. 1e). Together, these data show that mTORi pretreatment of monocytes stimulated with LPS ex vivo result in robust increases in polyfunctionality and, particularly, production of IL-1β and IL-6 (Fig. 1c–e).
Inhibition of mTOR activity potentiated LPS-induced surface expression of TF on monocytes
Given the enhanced functionality of mTORi-pretreated monocytes demonstrated above (Fig. 1e), we tested whether mTORi pretreatment also modulated LPS-stimulated monocyte surface TF expression, a known driver of HIV coagulopathy even during viremia-suppressing ART and a marker associated with inflammatory, polyfunctional monocytes in HIV and SIV infection11. mTORi pretreatment led to significant increases in the proportion of TF-positive monocytes following LPS stimulation, as compared to DMSO-pretreated controls (Fig. 2a, b).
Inhibition of mTOR enhanced LPS-induced pro-inflammatory and pro-coagulant transcriptional responses
RNA sequencing was employed to independently evaluate the differential expression associated with LPS stimulation after mTORi pretreatment. Monocytes from six independent donors were each treated under three conditions. Monocytes were left unstimulated or stimulated with LPS ex vivo following either DMSO or mTORi pretreatment. Comparison of LPS-stimulated monocytes to unstimulated, paired samples using gene set enrichment analysis (GSEA) showed that mTORC1 signaling, and the glycolytic metabolic program it supports, were enhanced after LPS stimulation (Fig. 3a). Expression of genes associated with oxidative phosphorylation (OXPHOS) decreased after LPS exposure, relative to unstimulated cells (Fig. 3a). Changes in enrichment among the mTORC1, glycolysis, and OXPHOS programs observed with LPS stimulation were reversed by mTORi pretreatment (Fig. 3a, b). LPS stimulation yielded the most significant enrichment among genes related to ‘TNF signaling via NF-κB’ and the ‘inflammatory response’ (Fig. 3a, Supplementary Fig. 1a). Notably, pretreatment with an mTORi, relative to DMSO, resulted in additional enrichment of these two gene sets after LPS stimulation (Fig. 3b, Supplementary Fig. 1b).
Differential analysis also revealed significantly increased abundance of transcripts mapping to genes encoding IL-1β, IL-6, and TF (F3) following mTORi pretreatment, relative to LPS stimulation alone (Fig. 3c). Transcripts of additional pro-inflammatory mediators augmented by mTOR inhibition included IL1A, IL15, IL23A, CSF2, and IRF1. In addition, mTORi pretreatment, relative to DMSO pretreatment, downregulated monocyte expression of CCR2 and CD163 (Fig. 3c, d). Transcripts associated with ‘cholesterol homeostasis’ were also suppressed in mTORi-treated, LPS-stimulated monocytes, relative to DMSO-pretreated, LPS-stimulated monocytes (Supplementary Fig. 1b), consistent with prior reports linking macrophage cholesterol depletion with pro-inflammatory cytokine production26,27. In contrast, mTORi was not found to transcriptionally modulate TNF expression among LPS-stimulated monocytes (Fig. 3c). These results align with observations at the protein level in presented in Fig. 1, and further suggest involvement of a transcriptional mechanism that couples with well-established translational pathways governed by mTOR.
mTORi-mediated enhancement of surface TF expression among LPS-stimulated monocytes was NF-κB dependent
Promoters for IL1B, IL6, and F3, the gene encoding TF, bear κB binding sites. Thus, we tested mTORi effects on monocyte NF-κB activity. We found that mTORi did not decrease LPS-induced NF-κB activity in monocytes (Supplementary Fig. 2a). We next tested if NF-κB activity was required for enhanced F3 expression. We observed a significant diminution in the frequency of TF-expressing monocytes when an inhibitor of IκB kinase (ACHP) was added to pretreatment with an mTORi prior to LPS stimulation, relative to only mTORi pretreatment (Supplementary Fig. 2b, c). We noted also that surface expression of CD14 on monocytes is exquisitely sensitive to ACHP treatment (Supplementary Fig. 2d, e). Consequently, gating of monocytes in analysis of this experiment relied on CD64 expression. CD14 engagement is not strictly required for LPS to signal via TLR4 through downstream MyD88-dependent processes, although it is required for TRIF-IRF axis signaling after TLR4 engagement28. Consistent with reports that PD-L1 and CD80 are also inducible through NF-κB29,30, ACHP also diminished their expression (Supplementary Fig. 2f, g). Additionally, an independent experimental approach using conventional ChIP analysis identified increased occupancy of the NF-κB p65 subunit at κB sites in the promoter regions of F3 and IL6 with mTORi pretreatment, beyond that observed with LPS stimulation alone (Supplementary Fig. 2h). Amplification from DNase I-insensitive regions far upstream of either locus’ transcriptional start sites (TSS) did not show a similar degree of enrichment (Supplementary Fig. 2h).
Metabolomic analyses indicated that mTORi depletes NAD+ by limiting salvage pathway synthesis
We next studied the effects of mTORi pretreatment and LPS stimulation using steady-state metabolomics. We compared LC-MS-based hydrophilic metabolite profiling of lysates of monocytes isolated from seven independent donors that were each either usntimulated by LPS, DMSO-pretreated/LPS-stimulated, or mTORi-pretreated/LPS-stimulated. Partial least squares discriminant analysis (PLS-DA) of the clean data set found significant class differences, discriminating among the three treatment conditions (Fig. 4a). Distinct differences among these three conditions in major metabolities included an increased abundance of glycolytic intermediates observed among DMSO-pretreated, LPS-stimulated monocytes that was not observed among mTORi-pretreated, LPS-stimulated monocytes (Fig. 4b). This provides internal validation that mTORi pretreatment prevents an LPS-induced shift towards increased glucose utilization, but does not readily explain how mTORi can increase NF-κB-dependent transcription with LPS stimulation. However, we noted that intracellular pools of NAD+, a critical cofactor for activity of sirtuins that can down-modulate transcription via deacetylation of both histone and non-histone targets31, expanded following LPS stimulation and that mTORi may have restricted this expansion (Fig. 4c). Quantification of the absolute NAD+ concentration of monocyte lysates from four different donors (not used in experiments documented in Fig. 4a–c) with an independent method using an enzymatic assay added support (Fig. 4d). DMSO-pretreated, LPS-stimulated monocytes had a higher intracellular concentration of NAD+ than did mTORi-pretreated, LPS-stimulated monocytes in that assay (Fig. 4d).
Both de novo synthesis from tryptophan and salvage from either pentose phosphate pathway (PPP)-synthesized ribulose 5-phosphate (R5-P) or other sources of nicotinamide (NAM) can contribute to NAD+ pools (Fig. 4e). Immunoblots showed mTOR-dependent upregulation of the rate limiting enzymes in each of these two pathways, indolamine 2,3-dioxygenase (IDO) and nicotinamide phosphoribosyltransferase (NAMPT), in monocytes stimulated with LPS after DMSO (Fig. 4e, f). Although mTORi pretreatment decreased cellular abundance of both of these proteins after LPS for 3 or 6 h (Fig. 4f), transcription of IDO1 and NAMPT were not differentially regulated in comparison of mTORi-pretreated, LPS-stimulated monocytes to DMSO-pretreated, LPS-stimulated monocytes (Fig. 3c). This suggested translational or post-translational mechanism(s) downstream of mTOR underlying the observed decreases in IDO1 and NAMPT (Fig. 4f), and prompted study of contribution of each pathway.
To determine whether the de novo NAD+ synthesis pathway contributed to the observed increase in NAD+ after LPS stimulation for 18 h, we performed targeted analysis of tryptophan metabolism using 13C-labeled tryptophan (Fig. 4g). More than 75% of tryptophan was labeled in monocytes that were either unstimulated; DMSO-pretreated, LPS-stimulated; mTORi-pretreated, LPS-stimulated; IDO inhibitor-pretreated, LPS-stimulated; NAMPT inhibitor-pretreated, LPS-stimulated; or glucose-6-phosphate dehydrogenase (G6PD) inhibitor-pretreated, LPS-stimulated (Fig. 4g). We observed accumulation of tryptophan-derived 13C in kynurenine among LPS-stimulated monocytes, more so than among unstimulated monocytes (Fig. 4g). Accumulation of 13C in kynurenine was significantly impaired by IDO inhibitor pretreatment, documenting the functional activity of the IDO inhibitor; no other tested inhibitor diminished the increase in 13C-labled kynurenine after LPS stimulation (Fig. 4g). In contrast, no accumulation of 13C was seen in cellular NAD+ under any tested condition, demonstrating that tryptophan-derived carbons are not utilized for NAD+ synthesis in this system (Fig. 4g). This indicates the predominance of the salvage pathway in increasing intracellular NAD+ after LPS stimulation of monocytes.
We next independently interrogated the contribution of each pathway to the LPS-induced increase in NAD+ by pretreatment with inhibitors specific for either IDO in the de novo pathway, NAMPT in the salvage pathway, or G6PD catalyzing the first step in the PPP providing precursors for the salvage pathway. Pretreatment with an inhibitor of IDO did not restrict the increase in NAD+ pools following LPS-stimulation (Fig. 4h), consistent with the 13C-labeled tryptophan experiment. In contrast, we found severe restriction of LPS-stimulated increased monocyte NAD+ levels with pretreatment with an inhibitor of the rate-limiting enzyme in the salvage pathway, NAMPT (Fig. 4h). There was a lesser, statistically significant blunting of the NAD+ increase with a G6PD inhibitor (Fig. 4h). Expression of genes encoding the phosphoribosyl pyrophosphate synthetases (PRPS1 and PRPS2) was also suppressed by mTORi pretreatment, relative to DMSO-pretreated, LPS-stimulated controls (Fig. 3c). This is consistent with mTORi-restricted flow through the PPP in monocytes, as we previously reported in CD4 T cells18, that can also contribute to diminished NAD+ availability via the salvage pathway with mTORi pretreatment before LPS. mTORi pretreatment was also repeated and showed reproducible inhibition of LPS-induced increased NAD+ (Fig. 4h). Both the 13C-labeled tryptophan experiment (Fig. 4g) and the inhibitor experiment (Fig. 4h) indicate that mTORi pretreatment decreases NAD+ via effects on the salvage pathway.
LPS stimulation, which was shown above to enhance intracellular NAD+ pools, was associated with increased monocyte mitochondrial membrane potential (Supplementary Fig. 3a). Inhibition of either mTOR or NAMPT prior to LPS each prevented this increased monocyte mitochondrial membrane potential, whereas pretreatment with a selective IDO inhibitor did not (Supplementary Fig. 3a). None of these three inhibitors affected mitochondrial mass over the 24 h experiment (Supplementary Fig. 3b).
Inhibition of mTOR potentiated surface TF expression equivalently among LPS-stimulated monocytes from chronically SIV-infected and uninfected rhesus macaques
Pathogenic simian immunodeficiency virus (SIV) infection of macaques is an established model of HIV infection. SIV-infected and -uninfected rhesus macaque (Macaca mulatta) PBMCs were studied ex vivo here. Blood CD4/CD8 lymphocyte counts, viral load, and plasma cytokines were assessed at time of PBMC collection from the macaques (Supplementary Fig. 4a–d). These SIVmac239-infected animals showed varying degrees of disease progression, though all were chronically infected and had not progressed to AIDS. Pretreatment with mTORi before LPS stimulation of PBMCs ex vivo increased the proportion of TF-expressing monocytes from both uninfected and chronically SIVmac239-infected macaques relative to DMSO-pretreated, LPS-stimulated monocytes (Fig. 5a, b), paralleling our findings in human primary monocytes. There was no difference in the proportion of surface TF-expressing monocytes among PBMCs from SIV-infected versus uninfected animals under any condition tested (Fig. 5a, b).
Discussion
Chronic systemic inflammation likely accelerates a range of cardiovascular pathologies in PLWH on ART, including diatolic dysfunction, scarring following myocardial infarct, and stroke4. Inflammation is sustained during ART by multiple mechanisms, including pro-inflammatory and pro-coagulant mediators released by myeloid cells in response to translocated microbial products32. Given that LPS-activated TLR4 signaling in monocytes activates mTOR to coordinate metabolic reprogramming, inhibition of mTOR has been hypothesized as a potential intervention. There are also reports that metabolically-activated monocytes from ART-suppressed PLWH more readily migrate across endothelia to generate foam cells in an ex vivo model of atherogenesis22. The success of sirolimus-eluting stents for treating coronary artery disease (CAD)33, the documented anti-HIV effects of mTORi15,16,17,18,34,35, and their potential to reduce HIV reservoirs36,37,38,39 have added to interest in testing mTOR inhibitors as an adjunct to ART that may decrease monocyte-derived inflammatory mediators to ameliorate CVD risk in PLWH24.
However, some reports show mTOR inhibition may increase inflammation. A preliminary report of a trial of adjunctive sirolimus in ART-suppressed PLWH found that plasma biomarkers of systemic inflammation were increased, despite benefits in decreasing immune exhaustion and provirus load40. Inhibition of mTOR also enhanced procoagulant TF activity on murine peritoneal macrophages41 and increased NF-κB transcriptional activity in endothelial cells42. Also relevant is a study of human monocytes in which Weichhart et al. demonstrated that rapamycin potentiated their production of IL-12 in response to LPS ex vivo, and also increased NF-κB transcriptional activity25. However, that report did not note monocyte culture conditions. We have found that commonly used tissue culture plates cause contact-induced monocyte activation, as has been previously shown43, raising the possibility that there could have been an additional pathway to TLR4 signaling by which mTOR was activated in that study25. We documented that PTFE-coated plate inserts (Millipore Sigma) prevented contact-induced activation of the monocytes isolated by bead-based negative-selection and exclusively used them in all experiments reported here to ensure activation only by LPS.
The results here show that catalytic mTOR inhibition of primary human monocytes increased LPS-stimulated pro-inflammatory cytokine and TF transcriptional responses in primary human monocytes. Catalytic mTOR inhibitors led to a more accentuated pro-inflammatory and pro-coagulant response to LPS than did a rapalog (Figs. 1b and 2b), consistent with additional effects of mTORi on reversing anti-inflammatory mTORC2-Akt signals44,45. The use of these catalytic inhibitors targeting both mTOR complexes enhances the novelty of this work and extends beyond the one earlier report25. In depth analyses here focused on one mTORi (AZD2014), but similar responses seen with two mTORi and rapamycin support that this is a class-wide effect and not specific to a single inhibitor.
This work is limited by its consideration of the total monocyte population only, as opposed to disambiguation of responses among monocyte subtypes. This affords the benefit of approximating the in vivo monocyte population, which may offset the lost opportunity to pinpoint relevant subtypes. The implictions of the results here for mTORi to be used as a clinical treatment hold irrespective of which monocyte subtype may be primarily responsible for its effect to increase monocyte-derived pro-inflammatory and pro-coagulant responses after LPS.
RNA sequencing analyses conclusively supported our flow cytometry results and indicated a transcriptional mechanism underlying enhanced production of IL-1β, IL-6, and TF here. Combining treatment with an inhibitor of IκB kinase (ACHP) and an mTORi before LPS stimulation significantly diminished the potentiation of surface TF seen with pretreatment with only an mTORi. This demonstration of an NF-κB-dependent effect on transcription was supported by the observation of increased p65 occupancy at the κB sites in the promoter regions of F3 and IL6 with mTORi pretreatment, and not at upstream, control sites. Another observation that is consistent with NF-κB-dependence of the pro-coagulant effect seen with mTOR inhibition: expression of the serine/threonine kinase PIM1 and its semi-redundant isoform PIM2 was increased among mTORi-pretreated monocytes (Fig. 3c, d); PIM1 has been reported to both stabilize p6546 and control reactivation of latent HIV proviruses47.
Increased TF expression seen here on mTORi-pretreated, LPS-stimulated, monocytes suggests a risk of heightening a hypercoagulable state that could precipitate vaso-occlusive events. An earlier report of in vivo treatment of SIV-infected pigtailed macaques with an anticoagulant supported the concept that inhibiting the extrinsic, TF-dependent coagulation pathway can significantly decrease D-dimer and immune activation in vivo, without adversely impacting monocyte responses to TLR stimulation11. Of note, the finding here that mTORi increased the proportion of TF-expressing rhesus macaque monocytes after LPS exposure ex vivo, as in humans, supports future study of potential interventions to limit this pro-coagulant effect in this animal model. The fact that this mTORi effect was similar here in cells from both SIV-infected and uninfected macaques differs from a report using a related species of pigtail macaques infected with SIVsabBH66, a strain different than the one used here, that was selected by serial passage for increased virulence11,48. These contrasting results from different species and viruses suggest that studying both SIV-infected and uninfected animals may be optimal for future in vivo efforts to assess interventions to limit pro-coagulant responses to mTORi.
In contrast to the enhanced expression of F3 and pro-inflammatory cytokines, we observed suppression of CCR2 and CD163 expression with mTORi pretreatment (Fig. 3c), raising a hypothesis that mTORi may limit monocyte transmigration to the intima, even if enhanced TF expression is a separate factor increasing risk of vaso-occlusion on LPS exposure.
Metabolomic analyses here led to a hypothesized mechanism for mTORi-mediated NF-κB-dependent transcriptional upregulation of these pro-inflammatory and pro-coagulant genes that supports a role for mTOR in resolving this acute inflammatory response. LC-MS-based hydrophilic metabolite profiling suggested, and an independent method confirmed, that intracellular pools of NAD+ expanded following LPS stimulation and that mTORi restricted this expansion. Results here also show that mTORi blocks the increase in mitochondrial membrane potential after LPS seen here (Supplementary Fig. 3a) and earlier49. This is consistent with the pivotal role of NAD+/NADH in supporting mitochondrial function and extends earlier work by implicating mTOR in the mechanism underlying this previously reported effect of LPS on mitochondria49. NAD+ is also a critical cofactor essential for activity of the sirtuin family of deacetylases, which down-modulate NF-κB-dependent transcription by deacetylation of both histone and/or non-histone targets31. LPS-enhanced intracellular NAD+ may support sirtuin-mediated deacetylation at p65 K310; persistent acetylation at p65 K310 enhances inflammatory gene expression induced by LPS50,51,52,53,54. As noted before, we found increased occupancy of the NF-κB p65 subunit at κB sites in the promoter regions of F3 and IL6 with mTORi pretreatment, beyond that observed with LPS stimulation alone (Supplementary Fig. 2h). In addition, transcriptional activity at κB sites may be attenuated by p65-interacting sirtuin deacetylation of histone H3 lysine 9 (H3K9) at NF-kB target gene promoters55. Since a link to mTOR involvement in such immune responses has not previously been made, we explored how mTORi pretreatment impacted a global assessment of the transcription-activating mark, acetylated H3K9, after LPS stimulation. An accumulation of global acH3K9 was observed with mTORi treatment prior to LPS stimulation that could not be attributed to decreased methylation at H3K9 (Supplementary Fig. 6a–d). However, this experiment is not conclusive and more definitive address of potential sirtuin-dependent mechanisms is required; specifically, unbiased, genome-wide and confirmatory gene-targeted analyses are appropriate to rigorously evaluate mechanisms by which mTOR inhibition impacts NAD+-dependent epigenetic programming of monocytes. This includes evaluation of the alternative hypothesis that consumption of NAD+ may increase in mTORi pretreated, LPS-stimulated monocytes, as well as the hypothesis supported by results here of mTORi-mediated decreases in NAD+ synthesis1.
In addition, future work could explore whether other NAD+-related mechanisms may contribute to the transcriptional profile of the mTORi-pretreated, LPS-stimulated monocytes. For example, increased abundance of inflammatory transcripts observed here may reflect increased mRNA stability, as well as higher rates of transcription56,57. Modulation of the activity of RNA-binding proteins (RBP) through ADP-riboslyation, a NAD+-intensive process, may contribute to the enhanced inflammatory program observed among mTORi-treated monocytes. As demonstrated by by Ke et al., modification of the RBP HuR by poly-(ADP) ribosylase (PARP1) regulates the translation of inflammatory cytokines and chemokines in LPS-stimulated macrophages57. Of note, the F3 locus encodes an RBP-target adenylate-uridylate-rich element (ARE) at the 3’ UTR, also suggesting study of a role for NAD+-dependent PARylation in the coagulopathic phenotype exhibited by mTORi-pretreated, LPS-stimulated monocytes. Such a contribution of dysregulated PARP activity to enhancement of both NF-kB activity and oxidative damage was previously shown in cardiomyocytes and murine macrophages58,59,60.
Recent evidence indicates that extracellular NAMPT and extracellular NAPRT can each be endogenous ligands for TLR4, capable of activating NF-κB in a manner independent of their enzymatic activities61,62. Managó et al. also report an association between elevated levels of extracellular NAPRT (eNAPRT) and reduced survival among septic patients and suggest the use of eNAPRT as a clinical marker62. This prompts consideration of these noncanonical TLR4 ligands as potential markers of immune activation in HIV infection and, beyond this, exploration of a potential mechanistic role in accelerated CVD and other age-related conditions in PLWH. However, the finding here that intracellular NAMPT was decreased, not increased, by mTORi suggests that these noncanonical TLR4 ligands are not likely to explain the enhanced pro-inflammatory and pro-coagulant effects seen here. However, an unanticipated, paradoxical effect of mTORi to increase extracellular release of NAMPT or NAPRT cannot be excluded.
We next sought to determine whether de novo synthesis contributed to the increase in NAD+ by tracking flux of 13C-labeled tryptophan after LPS stimulation. Results indicated that tryptophan-derived carbons are not utilized for de novo synthesis of the bulk of this LPS-induced expansion of the NAD+ pool under the conditions studied here (Fig. 4g). One limitation of this analysis is that a contribution of a small proportion of NAD+ from de novo synthesis cannot be excluded since 25% of the carbons in the 13C-labeled-tryptophan remained unlabeled (Fig. 4g). However, other independent approaches confirmed the predominance of the salvage pathway in increasing intracellular NAD+ very soon after LPS stimulation of monocytes, and in restriction of this increase by mTORi-pretreatment. Inhibition of IDO did not impede the increase in monocyte NAD+ (Fig. 4h) or the increase in mitochiondrial membrane potential (Supplementary Fig. 3a), each observed following LPS stimulation. Inhibition of the rate-limiting enzyme, NAMPT, in the salvage pathway for NAD+ synthesis profoundly restricted the rapid expansion of the NAD+ pool following LPS stimulation of monocytes (Fig. 4h) and prevented LPS-induced increased mitochondrial membrane potential (Supplementary Fig. 3a). A lesser, statistically significant blunting of the LPS-sitmulated increase in monocyte NAD+ was seen following pretreatment with a G6PD inhibitor that diminished products of PPP available to enter the salvage pathway (Fig. 4h). Thus, the increase in the monocyte intracellular pool of NAD+ after LPS stimulation depends on mTOR impacting the salvage pathway rather than de novo synthesis (Fig. 4e, indicated by the bold arrow). Results here extend, and independently confirm, earlier work implicating rapid increases in NAD+ via the salvage pathway in resolution of LPS-induced, NF-κB-mediated monocyte inflammation via effects on sirtuins and NF-κB49.
The dominant role of the salvage pathway in LPS-induced and mTORi-restricted synthesis of NAD+ suggests future directions for more translational HIV-related research. Several dietary supplements can be studied for possible enhancement of salvage pathway synthesis in vivo, including nicotinic acid (vitamin B3), nicotinamide riboside (NR) and nicotinamide mononucleotide (NMN). In previous studies, supplementation with NR did not increase intracellular NAD+ in cell culture and murine models, and was efficiently hydrolyzed in cell cultures even with serum-free media63,64. Similarly, NR supplementation of cell cultures here did not decrease surface TF in mTORi-pretreated, LPS-stimulated monocytes (Supplementary Fig. 5c). We also found a small reversal of decreased surface TF with NMN in only one of several cultures with mTORi-pretreated, LPS-stimulated monocytes from different humans. This lack of reproducibility of NMN effect ex vivo may be related to variation in residual monocyte surface CD38-mediated degradation of NMN and/or activity of hydrolases degrading NMN in bovine serum present in the culture medium64. However, restoration of intracellular NAD+ is documented in animal models and humans using oral supplements of NR, NMN, or vitamin B365,66,67. NR has been reported to increase intracellular NAD+ in PBMCs obtained from study participants taking this supplement orally, and it was well-tolerated in vivo68. Recent work reports that NR supplementation in vivo reduced proinflammatory cytokine expression in four uninfected humans with heart failure69. Thus, one next step for research on how to prevent chronic inflammation-associated HIV comorbidities may be evaluation of an orally bioavailable NAD+ precursor given with an mTORi for mitigation of the mTORi’s pro-inflammatory and pro-coagulant effects; this combination can be studied as an adjunct to ART in SIV-infected rhesus macaques. A potential benefit of use of mTORi as an adjunct to ART, if its effect to decrease salvage synthesis of NAD+ can be countered by dietary supplementation, is that it may also help address the problem of latent and reactivatable provirus requiring life-long ART36,37,38,39. Such an experimental approach that maintains NAD+ pools during mTORi may potentially also have relevance for studying other inflammatory conditions in addition to lentivirus infection. For example, serious COVID-19 is associated with both an impaired gut barrier and depletion of NAD+ pools70,71,72.
Results here show that mTOR activities rapidly constrain pro-inflammatory transcriptional responses to LPS. In addition to the potential future directions above, further characterization of the mechanisms downstream of mTOR may discover targets for new therapeutic approaches to chronic inflammatory disorders that would not require NAD+-restoring supplements. Short-term mTOR inhibition could also be further studied with the intent to enhance pro-inflammatory responses to LPS as an intervention to sustain anti-bacterial mechanisms needed for recovery in acute sepsis models49,73.
Methods
Animal care and ethics
Rhesus macaques (Macaca mulatta) were housed and cared in accordance with American Association for Accreditation of Laboratory Animal Care standards in AAALAC accredited facilities, and all animal procedures were performed according to protocols approved by the Institutional Animal Care and Use Committees of the National Institute of Allergy and Infectious Diseases under animal study protocol LVD26. Experimental animals were infected intravenously with 2000 TCID50 SIVmac239. For study animal details, see Supplementary Table 1.
Cell culture
Peripheral blood mononuclear cells (PBMC) were isolated via density gradient centrifugation using Ficoll-Paque PLUS (GE Healthcare, Pittsburg, PA) from uninfected donors’ EDTA-coagulated leukopacks (Lifesource, Rosemont, IL and New York Blood Center, New York, NY). Monocytes were purified through negative selection via magnetic-assisted cell sorting (Pan-Monocyte Isolation Kit, Miltenyi Biotec, Bergisch Gladbach, Germany) and resuspended in complete RPMI plus 10% defined FBS (GE Healthcare) and penicillin/streptomycin. Using a within-donor design, monocytes were pretreated for six hours with an inhibitor of mTOR (either rapamycin (100 nM), AZD2014 (5 μM), or INK128 (5 μM)), an inhibitor of NAMPT (FK866 (100 nM)), an inhibitor of IDO1 (Epacadostat (1 μM)), or an inhibitor of G6PD74 (G6PDi-1 (100 μM)) (Cayman Chemical, Ann Arbor, MI) and stimulated with LPS isolated from E. coli O111:B4 (Millipore Sigma, Darmstadt, Germany) as indicated in figure legends. All culture was performed in PTFE-coated plate inserts (Millipore Sigma) to prevent contact-induced monocyte activation.
High sensitivity cytokine quantification
Supernatants were recovered from monocyte pellets and stored at −80 °C prior to assay. Briefly, thawed supernatants/plasma samples were diluted 1:4 prior to analysis using the MSD® MULTI-SPOT Assay system (Meso Scale Diagnostics, Rockville, MD).
Flow cytometry
Following recovery from culture, PBMCs or monocytes were washed once in ice cold PBS prior to staining with Live/Dead fixable red dead cell stain (Life Technologies, Carlsbad, CA) for 30 m at 4 °C. Cells were washed once in cold PBE (PBS with 0.5% BSA and 2 mM EDTA) and stained with antibodies for extracellular markers diluted in PBE for 30 m at 4 °C. For ICS, cells were treated with Cytofix/Cytoperm (BD Biosciences, San Jose, CA) for 20 m at 4 °C, washed, and stained with antibodies for intracellular markers at 1:100 for 30 m at 4 °C. Human Fc Block (BD Biosciences) was used in all staining buffers. For intracellular cytokine staining, Brefeldin A (Millipore Sigma) was added to the culture at 5 mg/mL 6 h prior to harvest. Single-stained controls were prepared using UltraComp eBeads (Invitrogen, Carlsbad, CA). Data was acquired on a BD LSR II cytometer (BD Biosciences). Compensation and gating were accomplished using FlowJo v10 (TreeStar, Ashland, OR). Gating strategies are included in the supplement (Supplementary Fig. 7). A complete list of conjugated clones may be found in Supplementary Table 2.
Mitochondrial mass and membrane potential (ΔΨm) analysis by flow cytometry
Primary monocytes were cultured and treated as indicated. Thirty minutes before harvest, cells were incubated at 37 °C with 100 nM MitoTracker Green FM probe (Life Technologies) and 100 nM MitoView 633 (Biotium) for 30 m in dark to evaluate mitochondrial mass and ΔΨm, respectively. After harvest, cells were stained with SYTOX Blue dead stain (Life Technologies) as recommened by vendor to monitor cell viability. Data were acquired on a BD LSRFortessa (BD Biosciences). Analysis of data was accomplished as indicated above.
Immunoblotting
Cell pellets were resuspended in RIPA buffer (ThermoFisher Scientific, Waltham, MA) with protease and phosphatase inhibitors at 1.0 × 106 cells/μL and permitted to lyse on ice for 30 m. After normalization by protein concentration, lysates were denatured and separated via SDS-PAGE and transferred to nitrocellulose membrane using a semi-dry system. After blocking, blots were probed with primary antibodies at 4 °C overnight, diluted in SuperBlock (ThermoFisher Scientific). Membranes were then washed and probed with HRP-conjugated secondary antibodies (ThermoFisher Scientific) prior to addition of substrate, film exposure, and development. A list of primary antibodies used for blotting may be found in Supplementary Table 3.
NAD+ quantification and hydrophilic metabolites profiling
Following recovery from culture, monocytes were placed on ice and counted. An aliquot (5 × 105) of monocytes were assayed using the NADglo assay (Promega, Madison, WI) according to manufacturer’s instructions. Remaining monocytes were washed twice in ice cold normal saline (0.9% NaCl) prior to application of extraction solution (80% methanol v/v) cooled to −80 °C. Pellets were incubated in extraction solution at −80 °C and then subjected to three freeze/thaw cycles, vortexing 30 s after each thaw. Following extraction of the metabolome to solution, debris was pelleted at 20,000 × g for 15 m at 4 °C and supernatant transferred to a fresh tube for drying using SpeedVac. 50% acetonitrile was added to the tube for reconstitution following by overtaxing for 30 s. Sample solution was then centrifuged for 15 m at 20,000 × g and 4 °C and supernatant was collected for LC-MS analysis.
Metabolomics services yielding data presented in Fig. 4a–c were performed by the Metabolomics Core Facility at Robert H. Lurie Comprehensive Cancer Center of Northwestern University. Samples were analyzed by High-Performance Liquid Chromatography and High-Resolution Mass Spectrometry and Tandem Mass Spectrometry (HPLC-MS/MS). Specifically, system consisted of a Thermo Q-Exactive in line with an electrospray source and an Ultimate3000 (Thermo) series HPLC consisting of a binary pump, degasser, and auto-sampler outfitted with a Xbridge Amide column (Waters; dimensions of 4.6 mm × 100 mm and a 3.5 µm particle size). The mobile phase A contained 95% (vol/vol) water, 5% (vol/vol) acetonitrile, 20 mM ammonium hydroxide, 20 mM ammonium acetate, pH = 9.0; B was 100% Acetonitrile. The gradient was as following: 0 min, 15% A; 2.5 min, 30% A; 7 min, 43% A; 16 min, 62% A; 16.1–18 min, 75% A; 18–25 min, 15% A with a flow rate of 400 μL/min. The capillary of the ESI source was set to 275 °C, with sheath gas at 45 arbitrary units, auxiliary gas at 5 arbitrary units and the spray voltage at 4.0 kV. In positive/negative polarity switching mode, an m/z scan range from 70 to 850 was chosen and MS1 data was collected at a resolution of 70,000. The automatic gain control (AGC) target was set at 1 × 106 and the maximum injection time was 200 ms. The top 5 precursor ions were subsequently fragmented, in a data-dependent manner, using the higher energy collisional dissociation (HCD) cell set to 30% normalized collision energy in MS2 at a resolution power of 17,500. Data acquisition and analysis were carried out by Xcalibur 4.1 software and Tracefinder 4.1 software, respectively (both from Thermo Fisher Scientific).
Additional metabolomics experiments and flux analysis of 13C-labeled tryptophan presented in Fig. 4g, h and Supplementary Fig. 3a, b were performed as follows: Water-soluble metabolites were extracted from primary monocytes via −80 °C 80:20 methanol:water with a volume of 75 μL solvent per 1-million cells, vortexed, incubated on dry ice for 10 min, and centrifuged at 16,000 × g for 20 min, with the supernatant used for LC-MS analysis. Extracts were analyzed within 24 h by liquid chromatography coupled to a mass spectrometer (LC-MS). The LC–MS method involved hydrophilic interaction chromatography (HILIC) coupled to the Q Exactive PLUS mass spectrometer (Thermo Scientific). The LC separation was performed on a XBridge BEH Amide column (150 mm 3 2.1 mm, 2.5 mm particle size, Waters, Milford, MA). Solvent A is 95%: 5% H2O: acetonitrile with 20 mM ammonium bicarbonate, and solvent B is acetonitrile. The gradient was 0 min, 85% B; 2 min, 85% B; 3 min, 80% B; 5 min, 80% B; 6 min, 75% B; 7 min, 75% B; 8 min, 70% B; 9 min, 70% B; 10 min, 50% B; 12 min, 50% B; 13 min, 25% B; 16 min, 25% B; 18 min, 0% B; 23 min, 0% B; 24 min, 85% B; 30 min, 85% B. Other LC parameters are: flow rate 150 ml/min, column temperature 25 °C, injection volume 10 μL and autosampler temperature was 5 °C. The mass spectrometer was operated in both negative and positive ion mode for the detection of metabolites. Other MS parameters are: resolution of 140,000 at m/z 200, automatic gain control (AGC) target at 3e6, maximum injection time of 30 ms and scan range of m/z 75–1000. Data were analyzed via the MAVEN software, and isotope labeling was corrected for natural 13C abundance in the tracer experiments75.
Isotope labeling
Human plasma-like medium (HPLM) with [U-13C]Trp (Cambridge Isotope Laboratories) was prepared as previously reported76 except without Trp and supplemented with isotopic Trp (25 μM). Isotope-labeled tryptophan HPLM was prepared and supplemented with 10% dialyzed FBS (Hyclone).Cells were cultured in isotopic Trp-containing medium for a total of 24 h prior to harvest and frozen at −80 °C prior to analysis.
RNA sequencing
RNA was extracted from cell pellets using the RNeasy Mini Kit (Qiagen, Hilden, Germany). The stranded mRNA-seq was conducted in the Northwestern University NUSeq Core Facility. Briefly, total RNA examples were checked for quality using RINs generated from Agilent Bioanalyzer 2100. RNA quantity was determined with Qubit fluorometer. The Illumina TruSeq Stranded mRNA Library Preparation Kit was used to prepare sequencing libraries from 200 ng of high-quality RNA samples (RIN > 7). The Kit procedure was performed without modifications. This procedure includes mRNA enrichment and fragmentation, cDNA synthesis, 3’ end adenylation, Illumina adapter ligation, library PCR amplification and validation. lllumina HiSeq 4000 NGS Sequencer was used to sequence the libraries with the production of single-end, 50 bp reads.
The quality of DNA reads, in FASTQ format, was evaluated using FastQC. Adapters were trimmed and aligned to the human genome (hg38) using STAR77. Read counts for each gene were calculated using htseq-count in conjunction with a gene annotation file for hg38 obtained from Ensembl (http://useast.ensembl.org/index.html)78. Normalization and differential expression were calculated using DESeq2 that employs the Wald test79. The cutoff for determining significantly differentially expressed genes was an FDR-adjusted p value less than 0.05 using the Benjamini-Hochberg method. A Gene Set Enrichment Analysis (GSEA) was performed to identify significantly enriched gene sets among the gene expression results80,81.
Chromatin immunoprecipitation
Primary human monocytes (2 × 107) were recovered from culture and pelleted prior to crosslinking, performed first in DSG/PBS solution for 30 min at RT, and then in 1% formaldehyde for 10 min at RT, quenched with glycine solution. Dual-crosslinked cells were washed twice in ice cold PBS, pelleted, and stored at −80 °C.
Pellets were thawed on ice and membranes disrupted using a syringe in the presence of protease inhibitors. Chromatin was sheared using a Bioruptor (Diagenode, Denville, NJ). Shearing conditions were optimized for the cell type and number. Sheared chromatin was clarified by centrifugation and immunoprecipitated in duplicate using rabbit anti-p65 (Abcam, Cambridge, UK) or normal rabbit IgG (Cell Signaling Technologies). Chromatin was reserved for normalization (10% of input). Bound chromatin was pulled down using Protein A-agarose beads pre-blocked with salmon sperm DNA (Millipore Sigma) and then de-crosslinked using Chelex 100 and Proteinase K. DNA cleanup was accomplished using a MinElute Kit (Qiagen) according to manufacturer’s instructions. Quantitative PCR was performed with iTaq Universal SYBR Green Supermix (Bio-Rad Laboratories, Hercules, CA). Primers were designed using the UCSC Human Genome Browser82. Primer sequences may be found in Supplementary Table 4.
Statistics and reproducibility
Analysis was performed using PRISM v8.0.1 (GraphPad Software, La Jolla, CA) and error bars represent mean ± SD unless otherwise noted. Replicates are biological, representing independent donors. Experiments were repeated at least three times. Sample size varied depending on methodology and is defined in figure legends. Normality of data series was assessed using the Shapiro–Wilk method. Unless otherwise stated, parametric analyses performed using a one-way ANOVA and Tukey’s multiple comparisons, using the Greenhouse–Geisser correcton. In lieu of a one-way ANOVA, given failure of a test of normality, Friedman tests and Dunn’s multiple comparisons were used. Statistical analysis of metabolomic data relied on the online R-based platform MetaboAnalyst83. Prior to statistical analysis, the metabolomic data set was cleaned by removing targets with less than 66% non-zero values, normalized to the median, and outliers were detected using a random forest based method. Differential gene expression was visualized using the R package ggplot284.
Reporting summary
Further information on research design is available in the Nature Research Reporting Summary linked to this article.
Data availability
All source data are available via the Northwestern University Digital Hub: https://digitalhub.northwestern.edu/collections/5f1b1739-512f-4015-98bc-22f37f42af7b?sort=label_si+asc The RNA sequencing data that support the findings of this study have been deposited in the NCBI GEO database (accession code: GSE187403). Metabolomic and metabolic tracing data can be found in Supplementary Data 1 and 2 files, respectively.
References
Shah, A. S. V. et al. Global burden of atherosclerotic cardiovascular disease in people living with HIV: systematic review and meta-analysis. Circulation 138, 1100–1112 (2018).
Feinstein, M. J. et al. HIV-related myocardial vulnerability to infarction and coronary artery disease. J. Am. Coll. Cardiol. 68, 2026–2027 (2016).
Butler, J. et al. Diastolic dysfunction in patients with human immunodeficiency virus receiving antiretroviral therapy: results from the CHART study. J. Card. Fail. 26, 371–380 (2020).
Feinstein Matthew, J. et al. Characteristics, prevention, and management of cardiovascular disease in people living with HIV: a scientific statement from the American Heart Association. Circulation 140, e98–e124 (2019).
Giorgi, J. V. et al. Shorter survival in advanced human immunodeficiency virus type 1 infection is more closely associated with T lymphocyte activation than with plasma virus burden or virus chemokine coreceptor usage. J. Infect. Dis. 179, 859–870 (1999).
Brenchley, J. M. et al. Microbial translocation is a cause of systemic immune activation in chronic HIV infection. Nat. Med. 12, 1365–1371 (2006).
Ancuta, P. et al. Microbial translocation is associated with increased monocyte activation and dementia in AIDS patients. PloS One 3, e2516 (2008).
Marchetti, G. et al. Microbial translocation is associated with sustained failure in CD4+ T-cell reconstitution in HIV-infected patients on long-term highly active antiretroviral therapy. AIDS Lond. Engl. 22, 2035–2038 (2008).
Estes, J. D. et al. Damaged intestinal epithelial integrity linked to microbial translocation in pathogenic simian immunodeficiency virus infections. PLoS Pathog. 6, e1001052 (2010).
Stoll, L. L., Denning, G. M. & Weintraub, N. L. Potential role of endotoxin as a proinflammatory mediator of atherosclerosis. Arterioscler. Thromb. Vasc. Biol. 24, 2227–2236 (2004).
Schechter, M. E. et al. Inflammatory monocytes expressing tissue factor drive SIV and HIV coagulopathy. Sci. Transl. Med. 9, eaam5441 (2017).
Warburg, O. On respiratory impairment in cancer cells. Science 124, 269–270 (1956).
Bental, M. & Deutsch, C. Metabolic changes in activated T cells: an NMR study of human peripheral blood lymphocytes. Magn. Reson. Med. 29, 317–326 (1993).
Chi, H. Regulation and function of mTOR signalling in T cell fate decisions. Nat. Rev. Immunol. 12, 325–338 (2012).
Taylor, H. E. et al. Phospholipase D1 couples CD4+ T cell activation to c-Myc-dependent deoxyribonucleotide pool expansion and HIV-1 replication. PLoS Pathog. 11, e1004864 (2015).
Clerc, I. et al. Entry of glucose- and glutamine-derived carbons into the citric acid cycle supports early steps of HIV-1 infection in CD4 T cells. Nat. Metab. 1, 717–730 (2019).
Heredia, A. et al. Targeting of mTOR catalytic site inhibits multiple steps of the HIV-1 lifecycle and suppresses HIV-1 viremia in humanized mice. Proc. Natl Acad. Sci. USA 112, 9412–9417 (2015).
Taylor, H. E. et al. mTOR overcomes multiple metabolic restrictions to enable HIV-1 reverse transcription and intracellular transport. Cell Rep. 31, 107810 (2020).
Takeda, K., Kaisho, T. & Akira, S. Toll-like receptors. Annu. Rev. Immunol. 21, 335–376 (2003).
Lachmandas, E. et al. Microbial stimulation of different Toll-like receptor signalling pathways induces diverse metabolic programmes in human monocytes. Nat. Microbiol. 2, 1–10 (2016).
Palmer, C. S. et al. Glucose transporter 1–expressing proinflammatory monocytes are elevated in combination antiretroviral therapy–treated and untreated HIV+ subjects. J. Immunol. 193, 5595–5603 (2014).
Maisa, A. et al. Monocytes from HIV-infected individuals show impaired cholesterol efflux and increased foam cell formation after transendothelial migration. AIDS Lond. Engl. 29, 1445–1457 (2015).
Zhang, Y., Ma, K. L., Ruan, X. Z. & Liu, B. C. Dysregulation of the low-density lipoprotein receptor pathway is involved in lipid disorder-mediated organ injury. Int. J. Biol. Sci. 12, 569–579 (2016).
Safety and efficacy of sirolimus for HIV reservoir reduction in individuals on suppressive antiretroviral therapy (ART) - Full Text View - ClinicalTrials.gov. https://clinicaltrials.gov/ct2/show/NCT02440789.
Weichhart, T. et al. The TSC-mTOR signaling pathway regulates the innate inflammatory response. Immunity 29, 565–577 (2008).
Goossens, P. et al. Membrane cholesterol efflux drives tumor-associated macrophage reprogramming and tumor progression. Cell Metab. 29, 1376–1389.e4 (2019).
van der Vorst, E. P. C. et al. High-density lipoproteins exert pro-inflammatory effects on macrophages via passive cholesterol depletion and PKC-NF-κB/STAT1-IRF1 signaling. Cell Metab. 25, 197–207 (2017).
Zanoni, I. et al. CD14 controls the LPS-induced endocytosis of Toll-like Receptor 4. Cell 147, 868–880 (2011).
Beswick, E. J. et al. TLR4 activation enhances the PD-L1-mediated tolerogenic capacity of colonic CD90+ stromal cells. J. Immunol. Baltim. Md 1950 193, 2218–2229 (2014).
Dissanayake, D. et al. Nuclear factor-κB1 controls the functional maturation of dendritic cells and prevents the activation of autoreactive T cells. Nat. Med. 17, 1663–1667 (2011).
Martínez-Redondo, P. & Vaquero, A. The diversity of histone versus nonhistone sirtuin substrates. Genes Cancer 4, 148–163 (2013).
Lacson, J. C. A., Barnes, R. P. & Bahrami, H. Coronary artery disease in HIV-infected patients: downside of living longer. Curr. Atheroscler. Rep. 19, 18 (2017).
Martinet, W., De Loof, H. & De Meyer, G. R. Y. mTOR inhibition: a promising strategy for stabilization of atherosclerotic plaques. Atherosclerosis 233, 601–607 (2014).
Heredia, A. et al. Rapamycin causes down-regulation of CCR5 and accumulation of anti-HIV β-chemokines: an approach to suppress R5 strains of HIV-1. Proc. Natl Acad. Sci. 100, 10411–10416 (2003).
Heredia, A. et al. Reduction of CCR5 with low-dose rapamycin enhances the antiviral activity of vicriviroc against both sensitive and drug-resistant HIV-1. Proc. Natl Acad. Sci. 105, 20476–20481 (2008).
Gramatica, A. et al. Evaluating a new class of AKT/mTOR activators for HIV latency reversing activity ex vivo and in vivo. J. Virol. JVI.02393-20 https://doi.org/10.1128/JVI.02393-20 (2021).
Henrich, T. J. et al. Everolimus, an mTORC1/2 inhibitor, in ART-suppressed individuals who received solid organ transplantation: A prospective study. Am. J. Transplant. J. Am. Soc. Transplant. Am. Soc. Transpl. Surg. 21, 1765–1779 (2021).
Planas, D. et al. LILAC pilot study: effects of metformin on mTOR activation and HIV reservoir persistence during antiretroviral therapy. EBioMedicine 65, 103270 (2021).
Besnard, E. et al. The mTOR complex controls HIV Latency. Cell Host Microbe 20, 785–797 (2016).
Sirolimus reduces T-cell cycling and immune checkpoint marker expression, ACTG A5337|CROI Conference. http://www.croiconference.org/sessions/sirolimus-reduces-t-cell-cycling-and-immune-checkpoint-marker-expression-actg-a5337.
Baker, A. K., Wang, R., Mackman, N. & Luyendyk, J. P. Rapamycin enhances LPS induction of tissue factor and tumor necrosis factor-α expression in macrophages by reducing IL-10 expression. Mol. Immunol. 46, 2249–2255 (2009).
Minhajuddin, M., Fazal, F., Bijli, K. M., Amin, M. R. & Rahman, A. Inhibition of mammalian target of rapamycin potentiates thrombin-induced intercellular adhesion molecule-1 expression by accelerating and stabilizing NF-kappa B activation in endothelial cells. J. Immunol. Baltim. Md 1950 174, 5823–5829 (2005).
Kelley, J. L., Rozek, M. M., Suenram, C. A. & Schwartz, C. J. Activation of human blood monocytes by adherence to tissue culture plastic surfaces. Exp. Mol. Pathol. 46, 266–278 (1987).
Brown, J., Wang, H., Suttles, J., Graves, D. T. & Martin, M. Mammalian target of rapamycin complex 2 (mTORC2) negatively regulates toll-like receptor 4-mediated inflammatory response via FoxO1. J. Biol. Chem. 286, 44295–44305 (2011).
Festuccia, W. T., Pouliot, P., Bakan, I., Sabatini, D. M. & Laplante, M. Myeloid-specific rictor deletion induces M1 macrophage polarization and potentiates in vivo pro-inflammatory response to lipopolysaccharide. PLoS One 9, e95432 (2014).
Nihira, K. et al. Pim-1 controls NF- κ B signalling by stabilizing RelA/p65. Cell Death Differ. 17, 689–698 (2010).
Duverger, A. et al. Kinase control of latent HIV-1 infection: PIM-1 kinase as a major contributor to HIV-1 reactivation. J. Virol. 88, 364–376 (2014).
Mandell, D. T. et al. Pathogenic features associated with increased virulence upon simian immunodeficiency virus cross-species transmission from natural hosts. J. Virol. 88, 6778–6792 (2014).
Zhang, J. et al. Switch of NAD salvage to de novo biosynthesis sustains SIRT1-RelB-dependent inflammatory tolerance. Front. Immunol. 10, 2358 (2019).
Van Gool, F. et al. Intracellular NAD levels regulate tumor necrosis factor protein synthesis in a sirtuin-dependent manner. Nat. Med. 15, 206–210 (2009).
Liu, T. F., Yoza, B. K., El Gazzar, M., Vachharajani, V. T. & McCall, C. E. NAD+-dependent SIRT1 deacetylase participates in epigenetic reprogramming during endotoxin tolerance. J. Biol. Chem. 286, 9856–9864 (2011).
Vachharajani, V. T. et al. SIRT1 inhibition during the hypoinflammatory phenotype of sepsis enhances immunity and improves outcome. J. Leukoc. Biol. 96, 785–796 (2014).
Yang, H. et al. SIRT1 activators suppress inflammatory responses through promotion of p65 deacetylation and inhibition of NF-κB activity. PLoS One 7, e46364 (2012).
Rothgiesser, K. M., Erener, S., Waibel, S., Lüscher, B. & Hottiger, M. O. SIRT2 regulates NF-κB-dependent gene expression through deacetylation of p65 Lys310. J. Cell Sci. 123, 4251–4258 (2010).
Kawahara, T. L. A. et al. SIRT6 links histone H3 lysine 9 deacetylation to NF-κB-dependent gene expression and organismal life span. Cell 136, 62–74 (2009).
Chang, C.-H. et al. Posttranscriptional control of T cell effector function by aerobic glycolysis. Cell 153, 1239–1251 (2013).
Ke, Y. et al. PARP1 promotes gene expression at the post-transcriptional level by modulating the RNA-binding protein HuR. Nat. Commun. 8, 1–16 (2017).
Ba, X., Gupta, S., Davidson, M. & Garg, N. J. Trypanosoma cruzi induces the reactive oxygen species-PARP-1-RelA pathway for up-regulation of cytokine expression in cardiomyocytes. J. Biol. Chem. 285, 11596–11606 (2010).
Liu, L. et al. Lipopolysaccharide activates ERK-PARP-1-RelA pathway and promotes nuclear factor-κB transcription in murine macrophages. Hum. Immunol. 73, 439–447 (2012).
Cohen, M. S. Interplay between compartmentalized NAD+ synthesis and consumption: a focus on the PARP family. Genes Dev. 34, 254–262 (2020).
Camp, S. M. et al. Unique toll-like receptor 4 activation by NAMPT/PBEF induces NFκB signaling and inflammatory lung injury. Sci. Rep. 5, 13135 (2015).
Managò, A. et al. Extracellular nicotinate phosphoribosyltransferase binds Toll like receptor 4 and mediates inflammation. Nat. Commun. 10, 4116 (2019).
Camacho-Pereira, J. et al. CD38 dictates age-related NAD decline and mitochondrial dysfunction through a SIRT3-dependent mechanism. Cell Metab. 23, 1127–1139 (2016).
Kulikova, V. et al. Degradation of extracellular NAD+ intermediates in cultures of human HEK293 cells. Metabolites 9, 293 (2019).
Hong, G. et al. Administration of nicotinamide riboside prevents oxidative stress and organ injury in sepsis. Free Radic. Biol. Med. 123, 125–137 (2018).
Zhao, W.-Y., Zhang, L., Sui, M.-X., Zhu, Y.-H. & Zeng, L. Protective effects of sirtuin 3 in a murine model of sepsis-induced acute kidney injury. Sci. Rep. 6, 33201 (2016).
Sauve, A. A. NAD+ and vitamin B3: from metabolism to therapies. J. Pharmacol. Exp. Ther. 324, 883–893 (2008).
Martens, C. R. et al. Chronic nicotinamide riboside supplementation is well-tolerated and elevates NAD+ in healthy middle-aged and older adults. Nat. Commun. 9, 1286 (2018).
Zhou, B. et al. Boosting NAD Level Suppresses Inflammatory Activation of PBMC in Heart Failure. J. Clin. Invest. https://doi.org/10.1172/JCI138538 (2020).
Hoel, H. et al. Elevated markers of gut leakage and inflammasome activation in COVID-19 patients with cardiac involvement. J. Intern. Med. https://doi.org/10.1111/joim.13178 (2020).
Heer, C. D. et al. Coronavirus infection and PARP expression dysregulate the NAD metabolome: an actionable component of innate immunity. J. Biol. Chem. https://doi.org/10.1074/jbc.RA120.015138 (2020).
Brenner, C. Viral infection as an NAD+ battlefield. Nat. Metab. 4, 2–3 (2022).
Soltani, A. et al. Therapeutic potency of mTOR signaling pharmacological inhibitors in the treatment of proinflammatory diseases, current status, and perspectives. J. Cell. Physiol. 233, 4783–4790 (2018).
Ghergurovich, J. M. et al. A small molecule G6PD inhibitor reveals immune dependence on pentose phosphate pathway. Nat. Chem. Biol. 16, 731–739 (2020).
Su, X., Lu, W. & Rabinowitz, J. D. Metabolite spectral accuracy on orbitraps. Anal. Chem. 89, 5940–5948 (2017).
Cantor, J. R. et al. Physiologic medium rewires cellular metabolism and reveals uric acid as an endogenous inhibitor of UMP synthase. Cell 169, 258–272.e17 (2017).
Dobin, A. et al. STAR: ultrafast universal RNA-seq aligner. Bioinforma. Oxf. Engl. 29, 15–21 (2013).
Anders, S., Pyl, P. T. & Huber, W. HTSeq—a Python framework to work with high-throughput sequencing data. Bioinforma. Oxf. Engl. 31, 166–169 (2015).
Love, M. I., Huber, W. & Anders, S. Moderated estimation of fold change and dispersion for RNA-seq data with DESeq2. Genome Biol. 15, 550 (2014).
Mootha, V. K. et al. PGC-1α-responsive genes involved in oxidative phosphorylation are coordinately downregulated in human diabetes. Nat. Genet. 34, 267–273 (2003).
Subramanian, A. et al. Gene set enrichment analysis: a knowledge-based approach for interpreting genome-wide expression profiles. Proc. Natl Acad. Sci. 102, 15545–15550 (2005).
Kent, W. J. et al. The human genome browser at UCSC. Genome Res. 12, 996–1006 (2002).
Xia, J., Psychogios, N., Young, N. & Wishart, D. S. MetaboAnalyst: a web server for metabolomic data analysis and interpretation. Nucleic Acids Res. 37, W652–W660 (2009).
Wickham, H. ggplot2: elegant graphics for data analysis. (Springer, 2016).
Acknowledgements
The authors would like to acknowledge the care provided by Heather Kendall, Joanna Swerczek, and their team at the NIH Animal Center. The authors are also grateful for the contributions of staff at the Third Coast CFAR Viral Pathogenesis Core, the Northwestern Metabolomics Developing Core, the RHLCCC Flow Cytometry Core Facility, and the NUSeq Core, with special thanks to Sixia Xiao, Peng Gao, Xinkun Wang, Ryan Embry, Matt Schipma, Alan Aalsburg, and Kara Pivarski. This work was supported by NIH grants, as follows: N.C. was supported by F30 AI131937 and T32GM008152, R.T.D. and H.E.T. were supported by P01 AI131346, H.K.H. and J.B. were supported by NIDDK grants R01DK090625, R01DK127800, R01DK050203, and R01DK113011, NIA grants P01AG011412 and R01AG065988, JDRF grant 17-2013-511, and the Chicago Biomedical Consortium S-007, and M.R.M. was supported by HHMI Hanna H. Gray Fellows program and Burroughs Wellcome Fund PDEP. Funding for this study was provided in part by the Division of Intramural Research/NIAID/NIH. The content of this publication does not necessarily reflect the views or policies of DHHS, nor does the mention of trade names, commercial products, or organizations imply endorsement by the U.S. Government. Additional support from the Third Coast Center for AIDS Research (CFAR), an NIH funded center (P30 AI117943), is appreciated. H.E.T. was also supported by start-up funds from the State of New York and the Research Foundation for SUNY.
Author information
Authors and Affiliations
Contributions
H.E.T., R.T.D., and N.C. conceptualized the project. N.C., H.E.T., R.T.D., M.R.M., H.K.H., J.M.B., and J.B. designed experiments. N.C., H.E.T., Y.K., M.R.M., D.C.C., H.K.H., H.H., and I.C. performed experiments and analyses. N.C., R.T.D., and H.E.T. wrote the paper and all authors were involved in the editing process. R.T.D., H.E.T., N.C., M.R.M., J.M.B., and J.B. acquired funding.
Corresponding authors
Ethics declarations
Competing interests
The authors declare no competing interests.
Peer review
Peer review information
Communications Biology thanks Brandt D. Pence, Valentina Audrito and the other, anonymous, reviewer(s) for their contribution to the peer review of this work. Primary Handling Editors: Christina Karlsson Rosenthal.
Additional information
Publisher’s note Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Rights and permissions
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made. The images or other third party material in this article are included in the article’s Creative Commons license, unless indicated otherwise in a credit line to the material. If material is not included in the article’s Creative Commons license and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this license, visit http://creativecommons.org/licenses/by/4.0/.
About this article
Cite this article
Lund, N.C., Kayode, Y., McReynolds, M.R. et al. mTOR regulation of metabolism limits LPS-induced monocyte inflammatory and procoagulant responses. Commun Biol 5, 878 (2022). https://doi.org/10.1038/s42003-022-03804-z
Received:
Accepted:
Published:
DOI: https://doi.org/10.1038/s42003-022-03804-z
- Springer Nature Limited