Project description:Background: Monocytes contribute to atherosclerosis (AS) by migrating into inflamed endothelium and differentiating into foam cells. In people living with HIV (PLWH), chronic inflammation increases AS risk, yet the role of specific monocyte clusters remains unclear. We investigated how distinct monocyte populations contribute to vascular pathology in early HIV-associated AS. Methods: We profiled 123,965 circulating monocytes using single-cell RNA-seq and integrated plasma microparticle proteomics in 32 individuals stratified by HIV and AS status. Supervised learning identified cluster- and disease-specific signatures, validated by platelet-monocyte co-cultures, RT-qPCR, bulk RNA-seq, flow cytometry and ELISA. Results: Seven monocyte clusters were identified, including a subset characterized by platelet–monocyte complexes (PMCs). Bulk RNA-seq of platelet–monocyte co-cultures revealed platelet-driven upregulation of genes involved in inflammation, lipid metabolism, oxidative stress, and endothelial adhesion. PMC-derived macrophages secreted higher levels of TGF-β and IL-10, displayed decreased CD14 and increased CD80/CD86 while retaining CD36, and promoted endothelial-to-mesenchymal transition (decreased CDH5, PECAM1; increased S100A4) and vascular inflammation (increased ICAM1, VCAM and IL-6, CCL2 secretion). Additionally, CD14+ monocytes from HIV+AS- and HIV+AS+ groups showed enhanced ROS-NRF2 pathway activities, supported by increased basal and H2O2-induced p90RSK phosphorylation, indicating oxidative stress priming. Conclusions: Two monocyte clusters contribute independently to vascular immune dysregulation in PLWH. PMC-derived macrophages promote endothelial dysfunction while adopting a profibrotic cytokine profile. CD14+ monocytes show heightened oxidative signaling and stress responses, consistent with vascular activation. Together, these mechanisms may accelerate AS development in HIV, even in the absence of traditional cardiovascular risk factors.

Project description:CD14+ monocytes, the predominant population in human blood, are primarily engaged in host defense and pro-inflammatory cytokine responses. Aberrant monocyte activity causes life-threatening cytokine storms, while dysfunctional monocytes lead to 'immunoparalysis.' Understanding the mechanisms controlling monocyte functions is therefore paramount. Here, we reveal platelets' vital role in human monocytes' pro-inflammatory responses. Natural low platelet counts in patients with immune thrombocytopenia (ITP) , platelet depletion in healthy human monocytes, or in vivo platelet depletion in mice, result in monocyte immunoparalysis, characterized by reduced pro-inflammatory gene expression and weakened cytokine responses to immune challenge. Remarkably, supplementation with fresh platelets reverses monocyte immunoparalysis. In mice, thrombocytopenia results in down-regulation of myeloid innate immune genes, and compromised host defense transcriptional programs in monocytes despite normal responses to LPS. Platelets control monocyte cytokines independently of traditional cross-talk pathways, acting as reservoirs of transcription factors like NF?B and MAPK p38. We pinpointed a vesicle-derived NF?B2 transfer to human monocytes by mass spectrometry-based proteomics. Functionally, platelets proportionally restored impaired cytokine secretion in human monocytes lacking MAPK p38a and NF?B p65 and NF?B2. We unveil the intercellular transfer of inflammatory regulators, positioning platelets as central checkpoints in monocyte-mediated inflammation.

Project description:Persistent and elevated systemic inflammation contributes to the increased risk of cardiovascular and metabolic diseases in persons with HIV (PWH). , but aspects of the innate and adaptive immune response to HIV and other chronic co-infections that promote the development of these comorbid conditions remain unclear. We used mass cytometry and the tracking responders expanding (T-REX) workflow to define differences in circulating cells of the innate and adaptive immune arms, which differentiate non-diabetic and prediabetic/diabetic persons with HIV (PWH) on long-term antiretroviral therapy (ART). We found a significantly higher proportion of circulating CD14+ monocytes complexed with T cells, B cells, and NK cells among PWH with diabetes. The CD3+ T cells in these complexes were predominantly CD8+ memory T cells. The CD3+ CD14+ T cell-monocyte complexes are pro-inflammatory and negatively associated with plasma interleukin-10 levels and circulating CD4+ T regulatory cells. Using transmission electron microscopy, we observed heterogeneous interactions between CD3+ T cells and monocytes within the complexes, including formation of immune synapses and phagocytosis. 10x Chromium single-cell sequencing RNA transcriptomic analysis of CD3+ CD14+ doublets showed differential expression of genes involved in T cell activation and the adaptive immune response compared to monocytes that were not complexed with other immune cells. Notably, there were significantly more copies of HIV RNA per cell in the CD3+ CD14+ T cell-monocyte complexes compared to CD14+ monocytes or CD3+ CD4+ T cells alone, and HIV virions were observed in both T cells and monocytes within the doublets?. Metabolically, CD3+ CD14+ T cell-monocyte complexes had high glucose-dependence with minimal mitochondrial dependence. Taken together, CD3+ CD14+ T cell-monocyte pairs are functional and physically interacting immune cell complexes which might be enriched with HIV. These complexesare increased among individuals with diabetes and may be a target for future HIV cure studies and diseases of aging.

Project description:We report ChIP-sequencing data obtained of freshly isolated human CD14+ monocytes obtained from 3 HIV- controls and 6 HIV+ subjects. Persons living with HIV (PLWH) are at higher risk of developing secondary illnesses than their uninfected counterparts, suggestive of a dysfunctional immune system in these individuals. Upon exposure to pathogens, monocytes undergo epigenetic remodeling that results in either a trained or a tolerant phenotype, characterized by hyper-responsiveness or hypo-responsiveness to secondary stimuli, respectively. We utilized CD14+ monocytes from virally suppressed HIV+ patients and healthy controls for in vitro analysis following polarization of these cells toward a pro-inflammatory monocyte-derived macrophage (MDM) phenotype. We found that in HIV-derived MDMs, pro-inflammatory signals (TNFA, IL6, IL1B, miR-155-5p, and IDO1) dominate over negative feedback signals (NCOR2, GSN, MSC, BIN1, and miR-146a-5p), favoring an abnormally trained phenotype. The mechanism of this reduction in negative feedback involves the attenuated expression of IKZF1, a transcription factor required for de novo synthesis of RELA during LPS-induced inflammatory responses. Furthermore, restoring IKZF1 expression in HIV-MDMs partially reinstated expression of negative regulators of inflammation and lowered the expression of pro-inflammatory cytokines. Overall, this mechanism may provide a link between dysfunctional immune responses and susceptibility to co-morbidities in HIV+ individuals with low or undetectable viral load.

Project description:Persistent systemic inflammation in persons with HIV (PWH) is accompanied by an increased risk of metabolic and cardiovascular diseases. Yet, changes in the innate and the adaptive immune in PWH who develop cardiometabolic disease remain insufficiently defined. Using mass cytometry we showed that PWH with prediabetes/diabetes had a significantly higher proportion of circulating CD14+ monocytes complexed with T cells. The CD3+ T cells and CD14+ monocytes consisted of dynamic heterogeneous complexes. Furthermore, we detected more HIV DNA in T cell-monocyte complexes compared to CD14+ monocytes or CD4+ T cells alone. Our results demonstrate that CD3+ CD14+ T cell-monocyte pairs are functional and physically interacting immune cell complexes that are higher among PWH with diabetes, suggesting that they may contribute to metabolic disease pathogenesis, and provide a strong incentive for future studies to investigate T cell-monocyte immune complexes as mechanistic in HIV cure reservoir and other diseases of aging.

Project description:The goal of this experiment was to explore how human platelets affect the transcriptional responses of primary human CD14+ blood monocytes to lipopolysaccharide (LPS), and NLRP3 activation with Nigericin. For this purpose, we analyzed the mRNA expression of 770 myeloid-specific transcripts using the nCounter® Nanostring Human Myeloid Innate Immunity Panel v2. We isolated classical monocytes (CD14+CD16−) from the peripheral blood of healthy volunteers. Monocytes were derived from PBMCs using negative selection with the EasySep™ Human Monocyte Isolation Kit from STEMCELLTM Technologies. We modified this process by either including or excluding a platelet-depleting cocktail, creating two groups: \\"Standard Monocytes (StdMo)\\" and \\"Platelet-depleted Monocytes (PdMo).\\" To examine the impact of platelets further, we supplemented PdMos with fresh autologous platelets at a ratio of 50 platelets per monocyte, resulting in a third group, \\"PdMo + Plts.\\" StdMos were prepared according to the standard protocol provided by the EasySep™ Kit. For the PdMos, a Platelet Removal Component (50 µl ml−1) from the kit was used during isolation. We also reconstituted platelet-depleted monocytes with platelets and analyzed platelets alone to determine their specific mRNA contributions. The groups—StdMo, PdMo, PdMo + Plts, and platelets alone—were then exposed to 2 ng/ml of Ultrapure LPS (from E. coli O111:B4) for 4.5 hours, or stimulated with LPS for 3 hours followed by inflammasome activation with Nigericin (10 µM) for 90 min before extracting RNA for analysis.

Project description:Abstract Objectives: HIV infection dysregulates the innate immune system and alters leukocyte gene expression. The objectives were two fold: to characterize the impact of HIV infection on peripheral monocyte gene expression and to identify the predominant factor(s) responsible for altered gene expression. Design and methods: In a cross-sectional study, CD14+ monocytes were isolated from 11 HIV seronegative controls, 22 HIV seropositive subjects with low viral loads (LVL, <= 10,000 RNA copies/ml) and 22 HIV seropositive subjects with high viral loads (HVL, > 10,000 RNA/copies/ml). Total monocyte RNA was hybridized to 55K probes on high-density microarrays to obtained detailed gene expression profiles from control, LVL and HVL subjects. As potential candidates for immune disruption, we evaluated three HIV-related peripheral factors, interferon (IFN)-a, IFN-a and lipopolysaccharide (LPS) by treating HIV seronegative CD14+ monocytes for 48h and then analyzing gene expression. Plasma collected from the HIV subjects were quantified for LPS using a Pyrogene assay and for soluble (s) CD14 by ELISA. Results: In this cross-sectional study of HIV subjects (n=44), viral loads above 10,000 RNA copies/ml were associated with an activated phenotype. Characterization of the gene expression pattern by Gene Ontology reveals an ongoing immune response to viral infection including inflammation and chemotaxis. Gene expression analysis of in vitro treated HIV seronegative monocytes with IFN-a, IFN-g or LPS demonstrated that IFN-a most accurately recapitulated the HIV HVL profile. There was no detectable LPS signature even in those HIV subjects with the highest LPS and sCD14 levels. Conclusions: Monocyte gene expression in subjects with viremia is predominantly due to IFN-a, while subjects with LVL have a non-activated phenotype. In monocytes, there was no discernible expression profile linked to LPS exposure.

Project description:Kawasaki disease (KD) is characterized by a disorder of immune response, and its etiology remains unknown. Monocyte is an important member of body's innate immune system, however its role in KD is still elusive due to its ambiguous heterogeneity and complex functions. Here, scRNA-seq was performed to reveal monocytes heterogeneity in healthy and KD infants. Circulating monocytes were separated from peripheral blood and scRNA-seq was used to transcriptionally profile the monocytes in both healthy and KD infants. Four monocyte subsets are identified in infants, in which three clusters are mainly CD14+CD16- monocytes and one cluster is mainly CD14-CD16+ monocytes. The four monocyte subsets possess different biological functions and represent a relatively linear differentiation. CD14+ monocyte subsets in KD are distinct from that of healthy infants, including one subset expressing FOLR3, S100A12 and IL1R2 and the other expressing MT-TN specifically. Moreover, the CD14+ monocyte subsets in KD are poorly differentiated, and their functions mainly involve neutrophil activation. In conclusion, a relatively comprehensive map of circulating monocyte subsets was plotted for the first time in healthy infants. CD14+ monocyte subsets that are distinct from healthy infants were revealed in KD, which may serve as a target for KD treatment in the future.

Project description:Monocytes are a heterogeneous cell population with subset-specific functions and phenotypes. The differential expression of CD14 and CD16 distinguishes classical CD14++CD16-, intermediate CD14++CD16+ and non-classical CD14+CD16++ monocytes. However, CD14++CD16+ monocytes remain the most poorly characterized subset so far. Therefore we analyzed the transcriptomes of the three monocyte subsets using SuperSAGE in combination with high-throughput sequencing. Analysis of 5,487,603 tags revealed unique identifiers of CD14++CD16+ monocytes, delineating these cells from the two other monocyte subsets. CD14++CD16+ monocytes were linked to antigen processing and presentation (e.g. CD74, HLA-DR, IFI30, CTSB), to inflammation and monocyte activation (e.g. TGFB1, AIF1, PTPN6), and to angiogenesis (e.g. TIE2, CD105). Therefore we provide genetic evidence for a distinct role of CD14++CD16+ monocytes in human immunity. Human monocyte subsets (CD14++CD16-, CD14++CD16+, CD14+CD16++) were isolated from 12 healthy volunteers based on MACS technology. Total RNA from monocyte subsets was isolated and same aliquots from each donor and monocyte subset were matched for SuperSAGE. Three SuperSAGE libraries (CD14++CD16-, CD14++CD16+ and CD14+CD16++) were generated.

Project description:HIV reservoirs persist despite successful antiretroviral therapy (ART) and are a major obstacle to the eradication and cure of HIV. The mature monocyte subset, CD14+CD16+, contributes to viral reservoirs and HIV-associated comorbidities. Only a subset of monocytes harbors HIV (HIV+), while the rest remain uninfected, exposed cells (HIVexp). We developed an innovative single cell RNA sequencing (scRNAseq) pipeline that detects HIV and host transcripts simultaneously, enabling us to examine differences between HIV+ and HIVexp mature monocytes. Using this, we characterized uninfected, HIV+, and HIVexp primary human mature monocytes with and without ART. We showed that HIV+ mature monocytes do not form their own cluster separately from HIVexp but can be distinguished by significant differential gene expression. We found that ART decreased levels of unspliced HIV transcripts potentially by modulating host transcriptional regulators shown to decrease viral infection and replication. We also identified and characterized mature monocyte subpopulations differentially impacted by HIV and ART. We identified genes dysregulated by ART in HIVexp monocytes compared to their uninfected counterpart and, of interest, the junctional protein ALCAM, suggesting that ART impacts monocyte functions. Our data provide a novel method for simultaneous detection of HIV and host transcripts. We identify potential targets, such as those genes whose expression is increased in HIV+ mature monocytes compared to HIVexp, to block their entry into tissues, preventing establishment/replenishment of HIV reservoirs even with ART, thereby reducing and/or eliminating viral burden and HIV-associated comorbidities. Our data also highlight the heterogeneity of mature monocyte subsets and their potential contributions to HIV pathogenesis in the ART era.