Inhibitory Receptors Research Articles

Prognostic impact of enhanced CD96 expression on NK cells by TGF-β1 in AML

Acute myeloid leukemia (AML) is one of the most common types of blood cancer in adults and is associated with a poor survival rate. NK cells play a crucial role in combating AML, and alterations in immune checkpoint expression can impair NK cell function against AML. Targeting certain checkpoints may restore this function. CD96, an inhibitory immune checkpoint, has unclear expression and roles on NK cells in AML patients. In this study, we initially evaluated CD96 expression and compared CD96+ NK with the inhibitory receptor and stimulatory receptors on NK cells from AML patients at initial diagnosis. We observed increased CD96 expression on NK cells with dysfunctional phenotype. Further analysis revealed that CD96+ NK cells had lower IFN-γ production than CD96- NK cells. Blocking CD96 enhanced the cytotoxicity of primary NK and cord blood-derived NK (CB-NK) cells against leukemia cells. Notably, patients with a high frequency of CD96+ NK cells at initial diagnosis exhibited poorer clinical outcomes. Additionally, TGF-β1 was found to enhance CD96 expression on NK cells via SMAD3 signaling. These findings suggest that CD96 is invovled in NK dysfunction against AML blast, and might be a potential target for restoring NK cell function in the fight against AML.

High-throughput screen to identify and optimize NOT gate receptors for cell therapy.

Logic-gated engineered cells are an emerging therapeutic modality that can take advantage of molecular profiles to focus medical interventions on specific tissues in the body. However, the increased complexity of these engineered systems may pose a challenge for prediction and optimization of their behavior. Here we describe the design and testing of a flow cytometry-based screening system to rapidly select functional inhibitory receptors from a pooled library of candidate constructs. In proof-of-concept experiments, this approach identifies inhibitory receptors that can operate as NOT gates when paired with activating receptors. The method may be used to generate large datasets to train machine learning models to better predict and optimize the function of logic-gated cell therapeutics.

Transcriptomic observations of intra and extracellular immunotherapy targets for pediatric brain tumors

ABSTRACT Objectives Despite surgical resection, chemoradiation, and targeted therapy, brain tumors remain a leading cause of cancer-related death in children. Immunotherapy has shown some promise and is actively being investigated for treating childhood brain tumors. However, a critical step in advancing immunotherapy for these patients is to uncover targets that can be effectively translated into therapeutic interventions. Methods In this study, our team performed a transcriptomic analysis across pediatric brain tumor types to identify potential targets for immunotherapy. Additionally, we assessed components that may impact patient response to immunotherapy, including the expression of genes essential for antigen processing and presentation, inhibitory ligands and receptors, interferon signature, and overall predicted T cell infiltration. Results We observed distinct expression patterns across tumor types. These included elevated expression of antigen genes and antigen processing machinery in some tumor types while other tumors had elevated inhibitory checkpoint receptors, known to be associated with response to checkpoint inhibitor immunotherapy. Conclusion These findings suggest that pediatric brain tumors exhibit distinct potential for specific immunotherapies. We believe our findings can guide investigators in their assessment of appropriate immunotherapy classes and targets in pediatric brain tumors.

Mendelian randomization of plasma lipidome, inflammatory proteome and heart failure.

Heart failure (HF) is a global health issue, with lipid metabolism and inflammation critically implicated in its progression. This study harnesses cutting-edge, expanded genetic information for lipid and inflammatory protein profiles, employing Mendelian randomization (MR) to uncover genetic risk factors for HF. We assessed genetic susceptibility to HF across 179 lipidomes and 91 inflammatory proteins using instrumental variables (IVs) from recent genome-wide association studies (GWASs) and proteome-wide quantitative trait loci (pQTL) studies. GWASs involving 47309 HF cases and 930014 controls were obtained from the Heart Failure Molecular Epidemiology for Therapeutic Targets (HERMES) Consortium. Data on 179 lipids from 7174 individuals in a Finnish cohort and 91 inflammatory proteins from a European pQTL study involving 14824 individuals are available in the HGRI-EBI catalogue. A two-sample MR approach evaluated the associations, and a two-step mediation analysis explored the mediation role of inflammatory proteins in the lipid-HF pathway. Sensitivity analyses, including MR-RAPS (robust adjusted profile score) and MR-Egger, ensured result robustness. Genetic IVs for 162 lipids and 74 inflammatory proteins were successfully identified. MR analysis revealed a genetic association between HF and 31 lipids. Among them, 18 lipids, including sterol ester (27:1/18:0), cholesterol, 9 phosphatidylcholines, phosphatidylinositol (16:0_20:4) and 6 triacylglycerols, were identified as HF risk factors [odds ratio (OR)=1.037-1.368]. Cholesterol exhibited the most significant association with elevated HF risk [OR=1.368, 95% confidence interval (CI)=1.044-1.794, P=0.023]. In the inflammatory proteome, leukaemia inhibitory factor receptor (OR=0.841, 95% CI=0.789-0.897, P=1.08E-07), fibroblast growth factor 19 (OR=0.905, 95% CI=0.830-0.988, P=0.025) and urokinase-type plasminogen activator (OR=0.938, 95% CI=0.886-0.994, P=0.030) were causally negatively correlated with HF, whereas interleukin-20 receptor subunit alpha (OR=1.333, 95% CI=1.094-1.625, P=0.004) was causally positively correlated with HF. Mediation analysis revealed leukaemia inhibitory factor receptor (mediation proportion: 23.5%-25.2%) and urokinase-type plasminogen activator (mediation proportion: 9.5%-10.7%) as intermediaries in the lipid-inflammation-HF pathway. No evidence of directional horizontal pleiotropy was observed (P>0.05). This study identifies a genetic connection between certain lipids, particularly cholesterol, and HF, highlighting inflammatory proteins that influence HF risk and mediate this relationship, suggesting new therapeutic targets and insights into genetic drivers in HF.

LIFR regulates cholesterol-driven bidirectional hepatocyte-neutrophil cross-talk to promote liver regeneration.

Liver regeneration is under metabolic and immune regulation. Despite increasing recognition of the involvement of neutrophils in regeneration, it is unclear how the liver signals to the bone marrow to release neutrophils after injury and how reparative neutrophils signal to hepatocytes to reenter the cell cycle. Here we report that loss of the liver tumour suppressor Lifr in mouse hepatocytes impairs, whereas overexpression of leukaemia inhibitory factor receptor (LIFR) promotes liver repair and regeneration after partial hepatectomy or toxic injury. In response to physical or chemical damage to the liver, LIFR from hepatocytes promotes the secretion of cholesterol and CXCL1 in a STAT3-dependent manner, leading to the efflux of bone marrow neutrophils to the circulation and damaged liver. Cholesterol, via its receptor ERRα, stimulates neutrophils to secrete hepatocyte growth factor to accelerate hepatocyte proliferation. Altogether, our findings reveal a LIFR-STAT3-CXCL1-CXCR2 axis and a LIFR-STAT3-cholesterol-ERRα-hepatocyte growth factor axis that form bidirectional hepatocyte-neutrophil cross-talk to repair and regenerate the liver.

Leukemia inhibitory factor receptor inhibition reduces stenosis grade in LDLR-/- mice

Leukemia inhibitory factor receptor inhibition reduces stenosis grade in LDLR-/- mice

Disulfide bond-rich Nano-Silica for High-Efficiency cancer immunotherapy using synergistic endoplasmic reticulum stress cooperated mitochondrial dysfunction

In emerging cancer immunotherapy, the effectiveness of T lymphocytes is primarily hindered by elevated programmed cell death 1 ligand 1 (PD-L1) expression; simultaneously, the shift of tumor-associated macrophages (TAMs) towards tumorigenic M2-type macrophages further abrogates the efficacy of immunotherapy. Accordingly, we rationally designed a glutathione (GSH) responsive disulfide bond-rich nano-silica (DLC-HA) capable of efficient T cells infiltrating and TAMs re-polarization by encapsulating an endoplasmic reticulum (ER)-targeted photodynamic agent p-Ce6 and the glycolysis inhibitor lonidamine (LND), which works together to provoke ER stress and mitochondrial dysfunction. On the one hand, ER stress causes PD-L1 down-expression through ER-associated degradation (ERAD), while also stimulating the cyclic GMP-AMP synthase (cGAS)-stimulator of interferon genes (STING) signaling pathway. Meanwhile, LND alters mitochondrial dysfunction and activates the AMPK energy pathway, enhancing ER stress and facilitating PD-L1 degradation. On the other hand, ER stress upregulates calreticulin (CRT) expression and mitochondrial dysfunction alleviates hypoxia to downregulate TAMs inhibitory receptor CD47, all of which effectively promotes the phagocytosis and re-polarization of TAMs to anti-tumorigenic M1-type. As expected, this nanoplatform approach, not only activates the immune response of T cells but also facilitates the re-polarization of TAMs in vitro and in vivo assays, offering a novel strategy for efficient cancer immunotherapy using ER stress cooperated mitochondrial dysfunction.

Recognition and control of neutrophil extracellular trap formation by MICL

Regulation of neutrophil activation is critical for disease control. Neutrophil extracellular traps (NETs), which are web-like structures composed of DNA and neutrophil-derived proteins, are formed following pro-inflammatory signals; however, if this process is uncontrolled, NETs contribute to disease pathogenesis, exacerbating inflammation and host tissue damage1,2. Here we show that myeloid inhibitory C-type lectin-like (MICL), an inhibitory C-type lectin receptor, directly recognizes DNA in NETs; this interaction is vital to regulate neutrophil activation. Loss or inhibition of MICL functionality leads to uncontrolled NET formation through the ROS–PAD4 pathway and the development of an auto-inflammatory feedback loop. We show that in the context of rheumatoid arthritis, such dysregulation leads to exacerbated pathology in both mouse models and in human patients, where autoantibodies to MICL inhibit key functions of this receptor. Of note, we also detect similarly inhibitory anti-MICL autoantibodies in patients with other diseases linked to aberrant NET formation, including lupus and severe COVID-19. By contrast, dysregulation of NET release is protective during systemic infection with the fungal pathogen Aspergillus fumigatus. Together, we show that the recognition of NETs by MICL represents a fundamental autoregulatory pathway that controls neutrophil activity and NET formation.

HIV infection is associated with compromised tumor microenvironment adaptive immune reactivity in Hodgkin lymphoma

AbstractThe impact of HIV infection on the tumor microenvironment (TME) of classic Hodgkin lymphoma (cHL), one of the most common comorbidities after HIV infection, is not well understood. Here, we have used multiplexed immunofluorescence and spatial transcriptomic analysis to dissect the impact of viral infections (Epstein-Barr virus [EBV] and HIV/EBV) on cHL TME. HIV−EBV+ cHL TME was characterized by higher cell densities of CD8high T cells coexpressing inhibitory receptors (PD-1 and TIGIT), macrophage subsets, and an in situ inflammatory molecular profile associated with increased expression of T-cell receptor (TCR) and B-cell receptor cell signaling pathways than HIV−EBV− cHL TME. Compared with HIV−EBV+, HIV+EBV+ cHL TME was characterized by significantly less CD8high T cells coexpressing PD-1 and TIGIT, a profile concomitant with significantly increased cell densities of CD155high neoplastic cells. Significant downregulation of in situ TCR signaling and upregulation of extracellular matrix reorganization pathways were found in HIV+EBV+ cHL TME, in line with an altered topological organization of CXCL13 and heparan sulfate, an extracellular matrix glycosaminoglycan. Our data reveal the complexity of the cellular and molecular composition of cHL TME in the presence of viral infections, with possible implications for combinatorial immunotherapies. Furthermore, the data suggest specific molecular targets and pathways for further investigation that could improve our understanding of possible mechanistic links between HIV and lymphomagenesis.

Day 100 Recovery of Absolute Number of Inhibitory KIR2DL2 and Activating NKp30 Natural Killer Cells Predicts Survival Post-Autologous Stem Cell Transplantation in Lymphomas.

The infusion autograft absolute number of inhibitory killer immunoglobulin-like receptor (KIR) 2DL2 and activating natural killer (NK)p30 cells are predictors of clinical outcomes in lymphoma patients undergoing autologous peripheral blood hematopoietic stem cell transplantation (APBHSCT). To assess if the long-term recovery of these NK cell subsets still holds clinical relevance, we set up to investigate their prognostic ability at day 100 post-APBHSCT. This was a retrospective single-institution study including 107 patients from our prior phase III trial who had a clinical assessment at day 100 post-APBHSCT. The median follow-up from day 100 was 168.19 months (interquartile range: 156.85-181.28 months). Patients with day 100 inhibitory KIR2DL2 < 0.08 cells/µL and activating NKp30 ≥ 0.19 cells/µL experienced superior overall survival (OS) and progression-free survival (PFS). A multivariate analysis revealed both the day 100 inhibitory KIR2DL2 [OS: HR = 1.449, 95%CI, 1.231-1.895, p < 0.013; and PFS: HR = 2.069, 95%CI, 1.134-3.775, p < 0.021] and activating NKp30 [OS: HR = 4.985, 95%CI, 2.614-9.506, p < 0.0001; and PFS: HR = 4.661, 95%CI, 2.598-8.393, p < 0.0001] were independent predictors for OS and PFS. Inhibitory KIR2DL2 and activating NKp30 NK cells at day 100 are prognostic immune biomarkers in lymphoma patients treated with APBHSCT.

Local synthesis of estradiol in the rostral ventromedial medulla protects against widespread muscle pain in male mice.

Animal studies consistently demonstrate that testosterone is protective against pain in multiple models, including an animal model of activity-induced muscle pain. In this model, females develop widespread muscle hyperalgesia, and reducing testosterone levels in males results in widespread muscle hyperalgesia. Widespread pain is believed to be mediated by changes in the central nervous system, including the rostral ventromedial medulla (RVM). The enzyme that converts testosterone to estradiol, aromatase, is highly expressed in the RVM. Therefore, we hypothesized that testosterone is converted by aromatase to estradiol locally in the RVM to prevent development of widespread muscle hyperalgesia in male mice. This was tested through pharmacological inhibition of estrogen receptors (ER), aromatase, or ER-α in the RVM which resulted in contralateral hyperalgesia in male mice (C57BL/6J). ER inhibition in the RVM had no effect on hyperalgesia in female mice. As prior studies show modulation of estradiol signaling alters GABA receptor and transporter expression, we examined if removal of testosterone in males would decrease mRNA expression of GABA receptor subunits and vesicular GABA transporter (VGAT). However, there were no differences in mRNA expression of GABA receptor subunits of VGAT between gonadectomized and sham control males. Lastly, we used RNAscope to determine expression of ER-α in the RVM and show expression in inhibitory (VGAT+), serotonergic (tryptophan hydroxylase 2+), and μ-opioid receptor expressing (MOR+) cells. In conclusion, testosterone protects males from development of widespread hyperalgesia through aromatization to estradiol and activation of ER-α which is widely expressed in multiple cell types in the RVM.Significance Statement This study's findings reveal, for the first time, that testosterone protects males from development of widespread muscle hyperalgesia through aromatization to estradiol and activation of ER-α within the RVM. The findings also show, for the first time, ER-α expression in the RVM in male mice, and the distribution patterns of this expression among multiple cell types. Thus, together our data suggest a unique endogenous mechanism in the RVM for protection against widespread pain in males only.

Exhaustion of T cells after renal transplantation.

Renal transplantation is a life-saving treatment for patients with end-stage renal disease. However, the challenge of transplant rejection and the complications associated with immunosuppressants necessitates a deeper understanding of the underlying immune mechanisms. T cell exhaustion, a state characterized by impaired effector functions and sustained expression of inhibitory receptors, plays a dual role in renal transplantation. While moderate T cell exhaustion can aid in graft acceptance by regulating alloreactive T cell responses, excessive exhaustion may impair the recipient's ability to control viral infections and tumors, posing significant health risks. Moreover, drugs targeting T cell exhaustion to promote graft tolerance and using immune checkpoint inhibitors for cancer treatment in transplant recipients are areas deserving of further attention and research. This review aims to provide a comprehensive understanding of the changes in T cell exhaustion levels after renal transplantation and their implications for graft survival and patient outcomes. We discuss the molecular mechanisms underlying T cell exhaustion, the role of specific exhaustion markers, the potential impact of immunosuppressive therapies, and the pharmaceutical intervention on T cell exhaustion levels. Additionally, we demonstrate the potential to modulate T cell exhaustion favorably, enhancing graft survival. Future research should focus on the distinctions of T cell exhaustion across different immune states and subsets, as well as the interactions between exhausted T cells and other immune cells. Understanding these dynamics is crucial for optimizing transplant outcomes and ensuring long-term graft survival while maintaining immune competence.

Neu5Gc-mediated high-affinity interaction is dispensable for CD22 cis-ligands to regulate B cell signaling

CD22 (also known as Siglec-2) is an inhibitory receptor expressed in B cells. CD22 specifically recognizes α2,6 sialic acid and interacts with α2,6 sialylated membrane proteins expressed on the same cell (cis-ligands) and those derived from outside of the cell (trans-ligands). Previously, CD22 cis-ligands were shown to regulate the activity of CD22, thereby regulating both BCR ligation-induced signaling and low-level "tonic" signaling in the absence of BCR ligation that regulates the survival and differentiation of B cells. Mouse CD22 prefers Neu5Gc to Neu5Ac thereby binding to α2,6-linked Neu5Gc with high affinity. Although human CD22 binds to a distinct α2,6 sialylated glycan with high affinity, expression of high-affinity ligands is regulated in a conserved and stringent manner. However, how high- versus low-affinity CD22 ligands regulate B cells is poorly understood. Here we demonstrate that the interaction of CD22 with the endogenous ligands enhances BCR ligation-induced signaling but reduces tonic signaling in Cmah-/- mouse B cells deficient in Neu5Gc as well as wild-type B cells. Moreover, Cmah-/- B cells do not show alterations in the phenotypes correlated to tonic signaling. These results indicate that low-affinity interaction of the CD22 cis-ligands with CD22 is sufficient for the regulation of B cell signaling, and suggest that expression of high-affinity CD22 ligands might be involved in the regulation of B cells by competing for the binding of CD22 with exogenous trans-ligands of CD22.

The Projection-Specific Noradrenergic Modulation of Perseverative Spatial Behavior in Adult Male Rats.

Adaptive behavior relies on efficient cognitive control. The anterior cingulate cortex (ACC) is a key node within the executive prefrontal network. The reciprocal connectivity between the locus ceruleus (LC) and ACC is thought to support behavioral reorganization triggered by the detection of an unexpected change. We transduced LC neurons with either excitatory or inhibitory chemogenetic receptors in adult male rats and trained rats on a spatial task. Subsequently, we altered LC activity and confronted rats with an unexpected change of reward locations. In a new spatial context, rats with decreased noradrenaline (NA) in the ACC entered unbaited maze arms more persistently which was indicative of perseveration. In contrast, the suppression of the global NA transmission reduced perseveration. Neither chemogenetic manipulation nor inactivation of the ACC by muscimol affected the rate of learning, possibly due to partial virus transduction of the LC neurons and/or the compensatory engagement of other prefrontal regions. Importantly, we observed behavioral deficits in rats with LC damage caused by virus injection. The latter finding highlights the importance of careful histological assessment of virus-transduced brain tissue as inadvertent damage of the targeted cell population due to virus neurotoxicity or other factors might cause unwanted side effects. Although the specific role of ACC in the flexibility of spatial behavior has not been convincingly demonstrated, our results support the beneficial role of noradrenergic transmission for an optimal function of the ACC. Overall, our findings suggest the LC exerts the projection-specific modulation of neural circuits mediating the flexibility of spatial behavior.

Discovery of Multi-functional Lead Compounds Originating from Traditional Chinese Medicine for Developing Anti-depressive Agents via Virtual Screening

Background: The increasing prevalence of depression has become a global health issue. Currently approved anti-depressive including 5-hydroxytryptamine (5-HT), dopamine (DA), norepinephrine (NE), triple reuptake inhibitors (TRIs) and glutamate N-methyl-D-aspartate (NMDA) receptor antagonists have limited effects because of their insufficient efficacy and/or slow onset of action. Developing multifunctional antidepressants that can modulate 5-HT, DA, NE, and NMDA simultaneously can potentially overcome the current drug defects. Objective: This study aimed to explore leads for the development of multi-functional anti-depressive agents that simultaneous triple reuptake inhibitory and NMDA-GluN2B receptor antagonistic activities. Methods: Potential leads were screened virtually from the TCMSP database based on the 3DPharmacophore model of TRIs followed by the molecular docking into NMDA-GluN2B receptor, BBB score, and the in silico toxicity evaluation. The biological activities of discovered leads on 5-HT, NE, and DA reuptake and their effect on the NMDA-GluN2B receptor were evaluated via radio-labeled neurotransmitters and competition radio-ligand binding experiment with [3H] ifenprodil, respectively. Lastly, the antidepressant effect of these potential leads was determined in vivo through the forced swim test in mice. Results: Two compounds were attained as potential leads after the aforementioned experiments. Further in vitro biological evaluation identified Hit-2 as a promising lead that exerted favorable triple 5- HT/DA/NE reuptake inhibitory activity (66.98% inhibition rate at 10 μM against hNET, 73.01% inhibition rate at 1 μM against hDAT and 86.27% inhibition rate at 1 μM against hSERT), as well as potent NMDA-GluN2B receptor antagonistic activity (Ki=115.73 ± 3.54 nM). The antidepressant activity of Hit- 2 was confirmed through in vivo experiments Conclusion: Hit-2 not only simultaneously inhibited the reuptake of 5-HT, DA, and NE, and acted as an NMDA-GluN2B receptor antagonist in vitro but also showed in vivo antidepressant activity. These findings may serve as a structural basis for the further development of multi-functional anti-depressive agents.

The microenvironmental factors induced invasive tumor cells in glioblastoma

Glioblastoma (GBM) cells have the potential to switch from being “proliferative cells” to peritumoral “invasive cells”. Peritumoral GBM cells have highly invasive properties that allow them to survive surgery, leading to recurrence. The mechanisms underlying the manner in which the tumor microenvironment (TME) regulates the invasiveness of GBM remain unclear. Single-cell RNA sequencing analysis revealed heterogeneity in GBM cells, microglia and macrophages. In this study, the Oncostatin M receptor (OSMR) and leukemia inhibitory factor receptor (LIFR) expression indicated higher invasiveness in core GBM cells. Under environmental stress, the expression of OSMR and LIFR were up-regulated with the effect of hypoxic, acidic, and low-glucose conditions in vitro. Functional experiments revealed that TME stress significantly influences the proliferation, migration and invasion of GBM cells. The differences in core/peripheral TMEs in GBM affected the invasive properties, indicating the significant role of OSMR expression within the TME in tumor progression and postoperative therapy.

Potential mechanisms of cancer stem-like progenitor T-cell bio-behaviours.

In situations involving continuous exposure to antigens, such as chronic infections or cancer, antigen-specific CD8+ T cells can become dysfunctional or exhausted. This change is marked by increased expression levels of inhibitory receptors (PD-1 and Tim-3). Stem-like progenitor exhausted (Tpex) cells, a subset of exhausted cells that express TCF-1 and are mainly found in the lymph nodes, demonstrate the ability to self-renew and exhibit a high rate of proliferation. Tpex cells can further differentiate into transitional intermediate exhausted (Tex-int) cells and terminally exhausted (Tex-term) cells. Alternatively, they can directly differentiate into Tex-term cells. Tpex cells are the predominant subset that respond to immune checkpoint inhibitors (ICI), making them a prime candidate for improving the efficacy of ICI therapy. This review article aimed to present the latest developments in the field of Tpex formation, expansion, and differentiation in the context of cancer, as well as their responses to ICIs in cancer immunotherapy. Consequently, it may be possible to develop novel treatments that exclusively target Tpex cells, thus improving overall treatment outcomes. KEY POINTS: Tpex cells are located in lymph nodes and TLS. Several pathways control the differentiation trajectories of Tpex cells, including epigenetic factors, transcription factors, cytokines, age, sex, etc.

COVID-19 related myocardial injury is associated with immune dysregulation in symptomatic patients with cardiac MRI abnormalities.

While acute cardiovascular complications of COVID-19 are well-described, less is known about longer-term cardiac sequelae. For many individuals with cardiac signs or symptoms arising after COVID-19 infection, the aetiology remains unclear. We examined immune profiles associated with magnetic resonance imaging (MRI) abnormalities in patients with unexplained cardiac injury after COVID-19. Twenty-one participants (mean age 47 [SD 13] years, 71% female) with long COVID (n=17), raised troponin (n=2), or unexplained new-onset heart failure (n=2), who did not have pre-existing heart conditions or recent steroid/immunosuppression treatment were enrolled a mean 346 (SD 191) days after COVID-19 infection in a prospective observational study. Cardiac MRI and blood sampling for deep immunophenotyping using mass cytometry by time of flight and measurement of proteomic inflammatory markers was performed. Nine of 21 (43%) participants had MRI abnormalities (MRI(+)), including non-ischaemic patterns of late gadolinium enhancement and/or visually overt myocardial oedema in 8 people. One patient had mildly impaired biventricular function without fibrosis or oedema, and 2 had severe left ventricular impairment. MRI(+) individuals had higher blood CCL3, CCL7, FGF-23 and CD4 Th2 cells, and lower CD8 T effector memory (TEM) cells, than MRI(-). Cluster analysis revealed lower expression of inhibitory receptors PD1 and TIM3 in CD8 TEM cells from MRI(+) patients than MRI(-) patients, and functional studies of CD8 T αβ cells showed higher proportions of cytotoxic granzyme B+ secreting cells upon stimulation. CD8 TEM cells and CCL7 were the strongest predictors of MRI abnormalities in a LASSO regression model (composite AUC 0.96, 95%CI 0.88-1.0). CCL7 was correlated with diffuse myocardial fibrosis/oedema detected by quantitative T1 mapping (r=0.47, p=0.04). COVID-19 related cardiac injury in symptomatic patients with non-ischaemic myocarditis-like MRI abnormalities is associated with immune dysregulation, including decreased peripheral CD8 TEM cells and increased CCL7, persisting long after the initial infection.

Markers of CD4⁺ AND CD8⁺ T-cell exhaustion in hiv/hcv coinfected immunological non-responders to antiretroviral therapy

Coinfection with human immunodeficiency virus (HIV) and hepatitis C virus (HCV) is a risk factor for immunological non-response to antiretroviral therapy. In cases of immunological non-response, HIV viral load suppression occurs without an increase in CD4⁺ T-cell counts, heightening the risk of morbidity and mortality in infected individuals. T-cell exhaustion may hinder their regeneration in immunological non-responders. This study aimed to identify markers of CD4⁺ and CD8⁺ T-cell exhaustion in HIV/HCV coinfected immunological non-responders. The study examined three clinical groups: 1) HIV/HCV coinfected immunological non-responders (CD4⁺ T-cells 350/µl blood; n = 9), 2) HIV/HCV coinfected individuals with a standard response to therapy (CD4⁺ T-cells 500/µl blood; n = 9), and 3) relatively healthy volunteers without HIV and HCV infections (n = 9). Ex vivo, the number of CD4⁺ and CD8⁺ T-cells expressing the inhibitory receptor PD-1 was determined using multi-color flow cytometry. In the 7-day in vitro experiment, cell cultures were stimulated with phytohemagglutinin. The number of dying proliferated CD4⁺ and CD8⁺ T-cells (CFSElowZombieUV+) was determined using multi-color flow cytometry. The amount of interleukin-2 in the culture supernatants was measured using an enzyme-linked immunosorbent assay. It was found that in HIV/HCV coinfected immunological non-responders, there was a higher number of CD4⁺ and CD8⁺ T-cells expressing PD-1, a phenotypic marker of exhaustion, compared to the other two groups. Furthermore, the frequency of dying dividing T-cells was higher in immunological non-responders, with an increase in CD4⁺ T-cells but not CD8⁺ T-lymphocytes. Similarly, a decrease in interleukin-2 production was found in stimulated T-cells of HIV/HCV coinfected immunological non-responders in the CD4⁺ T-cell pool, but not in CD8⁺ T-lymphocytes. Thus, in HIV/HCV coinfected immunological non-responders, CD4⁺ T-cells appear exhausted both phenotypically and functionally. While CD8⁺ T-cells express inhibitory receptors, they do not show functional impairments. It appears that the specialized therapy for HIV/HCV coinfected immunological non-responders should aim to improve CD4⁺ T-cell function.

Evaluation of granulocyte colony-stimulating factor effect on the expression of inhibitory receptors by T cells in multiple myeloma

Evaluation of granulocyte colony-stimulating factor effect on the expression of inhibitory receptors by T cells in multiple myeloma