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Abstract
Innate immunity and chronic inflammation are involved in atherosclerosis and atherothrombosis leading to target organ damage in essential hypertension (EH). However, the role of neutrophils in EH is still elusive. We investigated the association between angiotensin II (Ang II) and neutrophil extracellular traps (NETs) in pathogenesis of EH. Plasma samples, kidney biopsies and surgical specimens of abdominal aortic aneurysms (AAA) from EH patients were used. Cell-based assays, NETs/human aortic endothelial cells co-cultures and in situ studies were performed. Increased plasma levels of NETs and tissue factor (TF) activity were detected in untreated, newly-diagnosed, EH patients. Stimulation of control neutrophils with plasma from untreated EH patients generated TF-enriched NETs promoting endothelial collagen production. Ang II induced NETosis in vitro via a reactive oxygen species (ROS)/peptidylarginine deiminase type 4 and autophagy-dependent pathway. Circulating NETs and thrombin generation levels were reduced significantly in EH patients starting treatment with Ang II receptor blockers, whereas their plasma was unable to trigger procoagulant NETs. Moreover, TF-bearing NETotic neutrophils/remnants were accumulated in sites of interstitial renal fibrosis and in the subendothelial layer of AAA. These data reveal the important pathogenic role of Ang II/ROS/NETs/TF axis in EH, linking thromboinflammation with endothelial dysfunction and fibrosis.
Authors
Akrivi Chrysanthopoulou, Eugenia Gkaliagkousi, Antonios Lazaridis, Stella Arelaki, Panagiotis Pateinakis, Maria Ntinopoulou, Alexandros Mitsios, Christina Antoniadou, Christos Argyriou, George S. Georgiadis, Vasileios Papadopoulos, Alexandra Giatromanolaki, Konstantinos Ritis, Panagiotis Skendros
Abstract
Creatine transporter (CrT) upholds the brain creatine (Cr) levels, but the impacts of its deficiency on energetics adaptation under stress remain unclear. There are also no effective treatments of CrT-deficiency, the second most common cause of X-linked intellectual disabilities. Herein we examined the consequences of CrT-deficiency in brain energetics and stress-adaptation responses plus the effects of intranasal Cr supplement. We found that CrT-deficient (CrT-/y) mice harbored dendritic spine and synaptic dysgenesis. Nurtured newborn CrT-/y mice maintained the baseline brain ATP level with a tendency towards the pAMPK/autophagy from mTOR signaling activity. Starvation elevated the signaling imbalance and reduced the brain ATP level in P3 CrT-/y mice. Similarly, CrT-/y neurons and P10 CrT-/y mice showed an imbalance between autophagy/mTOR signaling pathways and greater susceptibility to cerebral hypoxia-ischemia and ischemic insults. Notably, intranasal administration of Cr after cerebral ischemia increased the brain Cr/NAA (N-acetylaspartate) ratio, partially averted the signaling imbalance, and reduced the infarct size more potently than intraperitoneal Cr injection. These findings suggest important functions of CrT and Cr in preserving the homeostasis of brain energetics in stress conditions. Moreover, intranasal Cr supplement may be an effective treatment of congenital CrT-deficiency and acute brain injury.
Authors
Hong-Ru Chen, Xiaohui Zhang-Brotzge, Yury M. Morozov, Yuancheng Li, Siming Wang, Helen Zhang, Irena S. Kuan, Elizabeth M. Fugate, Hui Mao, Yu-Yo Sun, Pasko Rakic, Diana M. Lindquist, Ton DeGrauw, Chia-Yi Kuan
Abstract
Mitochondrial biogenesis and function are controlled by anterograde regulatory pathways involving more than one thousand nuclear-encoded proteins. Transcriptional networks controlling the nuclear-encoded mitochondrial genes remain to be fully elucidated. Here we show that histone demethylase LSD1 knockout from adult mouse liver (LSD1-LKO) reduces the expression of one-third of all nuclear-encoded mitochondrial genes and decreases mitochondrial biogenesis and function. LSD1-modulated histone methylation epigenetically regulates nuclear-encoded mitochondrial genes. Furthermore, LSD1 regulates gene expression and protein methylation of nicotinamide mononucleotide adenylyltransferase 1 (NMNAT1), which controls the final step of NAD+ synthesis and limits NAD+ availability in nucleus. Lsd1 knockout reduces NAD+-dependent SIRT1 and SIRT7 deacetylase activity, leading to hyperacetylation and hypofunctioning of GABPβ and PGC-1α, the major transcriptional factor/cofactor for nuclear-encoded mitochondrial genes. Despite the reduced mitochondrial function in liver, LSD1-LKO mice are protected from diet-induced hepatic steatosis and glucose intolerance, partially due to induction of hepatokine FGF21. Thus, LSD1 orchestrates a core regulatory network involving epigenetic modifications and NAD+ synthesis to control mitochondrial function and hepatokine production.
Authors
Yang Cao, Lingyi Tang, Kang Du, Kitt Paraiso, Qiushi Sun, Zhengxia Liu, Xiaolong Ye, Yuan Fang, Fang Yuan, Yu-Han Chen, Yumay Chen, Xiaorong Wang, Clinton Yu, Ira L. Blitz, Ping H. Wang, Lan Huang, Haibo Cheng, Xiang Lu, Ken W.Y Cho, Marcus Seldin, Zhuyuan Fang, Qin Yang
Abstract
Vascular injury has emerged as a complication contributing to morbidity in coronavirus disease 2019 (COVID-19). The glycosaminoglycan hyaluronan (HA) is a major component of the glycocalyx, a protective layer of glycoconjugates that lines the vascular lumen and regulates key endothelial cell functions. During critical illness as in the case of sepsis, enzymes degrade the glycocalyx, releasing fragments with pathologic activities into circulation and thereby exacerbate disease. Here, we analyzed levels of circulating glycosaminoglycans in 46 patients with COVID-19 ranging from moderate to severe clinical severity and measured activities of corresponding degradative enzymes. This report provides evidence that the glycocalyx becomes significantly damaged in COVID-19 patients and corresponds with severity of disease. Circulating HA fragments and hyaluronidase, two signatures of glycocalyx injury, strongly associate with sequential organ failure assessment scores and with increased inflammatory cytokine levels in COVID-19 patients. Pulmonary microvascular endothelial cells exposed to COVID-19 milieu show dysregulated HA biosynthesis and degradation leading to production of pathological HA fragments which are released into circulation. Finally, we show that HA fragments present at high levels in COVID-19 patient plasma can directly induce endothelial barrier dysfunction in ROCK- and CD44-dependent manner, indicating a role for HA in the vascular pathology of COVID-19.
Authors
Kimberly A. Queisser, Rebecca A. Mellema, Elizabeth A. Middleton, Irina Portier, Bhanu Kanth Manne, Frederik Denorme, Ellen J. Beswick, Matthew T. Rondina, Robert A. Campbell, Aaron C. Petrey
Abstract
Macrophage activation syndrome (MAS) is a life-threatening cytokine storm complicating systemic juvenile idiopathic arthritis (SJIA) driven by IFNγ. SJIA and MAS are associated with an unexplained emerging lung disease (SJIA-LD), with our recent work supporting pulmonary activation of IFNγ pathways pathologically linking SJIA-LD and MAS. Our objective was to mechanistically define the novel observation of pulmonary inflammation in the TLR9 mouse model of MAS. In acute MAS, lungs exhibit mild but diffuse CD4-predominant, perivascular interstitial inflammation with elevated IFNγ, IFN-induced chemokines, and AMΦ expression of IFNγ-induced genes. Single-cell RNA-sequencing confirmed IFN-driven transcriptional changes across lung cell types with myeloid expansion and detection of MAS-specific macrophage populations. Systemic MAS resolution was associated with increased AMΦ and interstitial lymphocytic infiltration. AMΦ transcriptomic analysis confirmed IFNγ-induced proinflammatory polarization during acute MAS, which switches towards an anti-inflammatory phenotype after systemic MAS resolution. Interestingly, recurrent MAS led to increased alveolar inflammation and lung injury, and reset AMΦ polarization towards a proinflammatory state. Furthermore, in mice bearing macrophages insensitive to IFNγ, both systemic feature of MAS and pulmonary inflammation were attenuated. These findings demonstrate that experimental MAS induces IFNγ-driven pulmonary inflammation replicating key features of SJIA-LD, and provides a model system for testing novel treatments directed towards SJIA-LD.
Authors
Denny K. Gao, Nathan Salomonis, Maggie Henderlight, Christopher Woods, Kairavee Thakkar, Alexei A. Grom, Sherry Thornton, Michael B. Jordan, Kathryn A. Wikenheiser-Brokamp, Grant S. Schulert
Abstract
The mechanism controlling long-chain fatty acid (LCFA) mobilization from adipose tissue (AT) is not well understood. Here, we investigated how the LCFA transporter CD36 regulates this process. By using tissue-specific knockout mouse models, we show that CD36 in both adipocytes and endothelial cells mediates both LCFA deposition into and release from AT. We demonstrate the role of adipocytic and endothelial CD36 in promoting tumor growth and chemoresistance conferred by AT-derived LCFA. We show that dynamic cysteine S-acylation of CD36 in adipocytes, endothelial cells, and cancer cells mediates intercellular LCFA transport. We demonstrate that lipolysis induction in adipocytes triggers CD36 de-acylation and deglycosylation, as well as its dissociation from interacting proteins, prohibitin-1 (PHB), and annexin 2 (ANX2). Our data indicate that lipolysis triggers caveolar endocytosis and translocation of CD36 from the cell membrane to lipid droplets. This study suggests a mechanism for both outside-in and inside-out cellular LCFA transport regulated by CD36 S- acylation and its interactions with PHB and ANX2.
Authors
Alexes C. Daquinag, Zhanguo Gao, Cale Fussell, Linnet Immaraj, Renata Pasqualini, Wadih Arap, Askar M. Akimzhanov, Maria Febbraio, Mikhail G. Kolonin
Abstract
Immunotherapies are needed in the clinic that effectively suppress beta cell autoimmunity and reestablish long-term self-tolerance in type 1 diabetes. We previously demonstrated that nondepleting αCD4 and αCD8α antibodies establish rapid and indefinite remission in recent-onset diabetic NOD mice. Diabetes reversal by coreceptor therapy (CoRT) is induced by suppression of pathogenic effector T cells (Teff) and the selective egress of T cells from the pancreatic lymph nodes and islets that remain free of infiltration long-term. Here, we defined CoRT-induced events regulating early Teff function and pancreatic residency, and long-term tolerance. TCR-driven gene expression controlling autoreactive Teff expansion and proinflammatory activity was suppressed by CoRT, and islet T cell egress was sphingosine-1 phosphate-dependent. In both murine and human T cells, CoRT upregulated the Foxo1 transcriptional axis, which in turn was required for suppression and efficient pancreatic egress of Teff. Interestingly, long-term tolerance induced in late-preclinical NOD mice was marked by reseeding of the pancreas by a reduced CD8+ Teff pool exhibiting an exhausted phenotype. Notably, PD-1 blockade, which rescues exhausted Teff, resulted in diabetes onset in protected animals. These findings demonstrate that CoRT has distinct intrinsic effects on Teff that impact events early in induction and later in maintenance of self-tolerance.
Authors
Matthew Clark, Charles J. Kroger, Qi Ke, Rui Zhang, Karen Statum, J. Justin Milner, Aaron J. Martin, Bo Wang, Roland Tisch
Abstract
Hyperstimulation of the cholecystokinin receptor (CCK1R), a Gq-protein coupled receptor (GPCR), in pancreatic acinar cells is commonly used to induce pancreatitis in rodents. Human pancreatic acinar cells lack CCK1R but express cholinergic receptor muscarinic 3 (M3R), another GPCR. To test whether M3R activation is involved in pancreatitis, a mutant M3R was conditionally expressed in pancreatic acinar cells in mice. This mutant receptor loses responsiveness to its native ligand acetylcholine but can be activated by an inert small molecule, clozapine-N-oxide (CNO). Intracellular calcium and amylase were elicited by CNO in pancreatic acinar cells isolated from mutant M3R mice but not WT mice. Similarly, acute pancreatitis (AP) could be induced by a single injection of CNO in the transgenic mice but not WT mice. Compared with the cerulein-induced AP, CNO caused more widespread acinar cell death and inflammation. Furthermore, chronic pancreatitis developed at 4 weeks after 3 episodes of CNO-induced AP. In contrast, in mice with three recurrent episodes of cerulein-included AP, pancreas histology was restored in 4 weeks. Furthermore, the M3R antagonist ameliorated the severity of cerulein-induced AP in WT mice. We conclude that M3R activation can cause the pathogenesis of pancreatitis. This model may provide an alternative approach for pancreatitis research.
Authors
Jianhua Wan, Jiale Wang, Larry E. Wagner II, Oliver H. Wang, Fu Gui, Jiaxiang Chen, Xiaohui Zhu, Ashley N. Haddock, Brandy H. Edenfield, Brian Haight, Debabrata Mukhopadhyay, Ying Wang, David I. Yule, Yan Bi, Baoan Ji
Abstract
Lack of sustained response to therapeutic agents in patients with KRAS mutant lung cancer poses a major challenge and arises partly due to intratumor heterogeneity that defines phenotypically distinct tumor subpopulations. To attain better therapeutic outcomes it is important to understand the differential therapeutic sensitivities of tumor cell subsets. Epithelial-to-mesenchymal transition (EMT) is a biologic phenomenon that can alter the state of cells along a phenotypic spectrum and cause transcriptional rewiring to produce distinct tumor cell subpopulations. We utilized functional shRNA screens, in vitro and in vivo models to identify and confirm an increased dependence of mesenchymal tumor cells on CDK4 for survival, as well as a mechanism of resistance to MEK inhibitors. High ZEB1 levels in mesenchymal tumor cells repressed p21, leading to perturbed CDK4 pathway activity. Increased dependence on CDK4 rendered mesenchymal cancer cells particularly vulnerable to selective CDK4 inhibitors. Co-administration of CDK4 and MEK inhibitors in heterogeneous tumors effectively targeted different tumor subpopulations, subverting the resistance to either single agent treatment.
Authors
Aparna Padhye, Jessica M. Konen, B. Leticia Rodriguez, Jared J. Fradette, Joshua K. Ochieng, Lixia Diao, Jing Wang, Wei Lu, Luisa S. Solis, Harsh Batra, Maria G. Raso, Michael D. Peoples, Rosalba Minelli, Alessandro Carugo, Christopher A. Bristow, Don L. Gibbons
Abstract
The metabolic environment is important for neuronal cells, such as photoreceptors. When photoreceptors undergo degeneration, as occurs during retinitis pigmentosa (RP), patients have progressive loss of vision that proceeds to full blindness. Currently, there are no available treatments for the majority of RP diseases. We performed metabolic profiling of the neural retina in a preclinical model of RP and found that tricarboxylic acid (TCA) cycle intermediates were reduced during disease. We then determined that, 1) promoting citrate production within the TCA cycle in retinal neurons during disease progression protects the photoreceptors from cell death and prolongs visual function, 2) that supplementation with single metabolites within the TCA cycle can provide this therapeutic effect in vivo over time, and, 3) that this therapeutic effect is not specific to a particular genetic mutation but has broad applicability for patients with RP and other retinal degenerative diseases. Overall, targeting TCA cycle activity in the neural retina promotes photoreceptor survival and visual function during neurodegenerative disease.
Authors
Ashley A. Rowe, Pinkal D. Patel, Ruth Gordillo, Katherine J. Wert
Abstract
Aging is associated with chronic oxidative stress and inflammation that impact the tissue repair and regeneration capacity. MG53 is a TRIM family protein that facilitates repair of cell membrane injury in a redox-dependent manner. Here we demonstrate that the expression of MG53 is reduced in failing human heart and aging mouse heart, concomitant with elevated NFκB activation. We evaluate the safety and efficacy of longitudinal, systemic administration of recombinant human MG53 (rhMG53) protein in aged mice. Echocardiography and pressure-volume loop measurements reveal beneficial effects of rhMG53 treatment in improving heart function of aging mice. Biochemical and histological studies demonstrate the cardioprotective effects of rhMG53 are linked to suppression of NFκB-mediated inflammation, reducing apoptotic cell death and oxidative stress in the aged heart. Repetitive administrations of rhMG53 in aged mice do not have adverse effects on major vital organ functions. These findings support the therapeutic value of rhMG53 in treating age-related decline in cardiac function.
Authors
Xiaoliang Wang, Xiuchun Li, Hannah Ong, Tao Tan, Ki Ho Park, Zehua Bian, Xunchang Zou, Erin Haggard, Paul M. Janssen, Robert E. Merritt, Timothy M. Pawlik, Bryan A. Whitson, Nahush A. Mokadam, Lei Cao, Hua Zhu, Chuanxi Cai, Jianjie Ma
Abstract
Retinoic Acid (RA) signaling has long been speculated to regulate embryo implantation, because many enzymes and proteins responsible for maintaining RA homeostasis and transducing RA signals are tightly regulated in the endometrium during this critical period. However, due to lack of genetic data, it was unclear whether RA signaling is truly required for implantation, and which specific RA signaling cascades are at play. Herein we utilize a genetic murine model that expresses a dominant negative form of RA receptor specifically in female reproductive organs to show that functional RA signaling is fundamental to female fertility, particularly implantation and decidualization. Reduction in RA signaling activity severely affects the ability of the uterus to achieve receptive status and decidualize, partially through dampening follistatin expression and downstream activin B/BMP2 signaling. To confirm translational relevance of these findings to humans, human endometrial stromal cells (hESCs) were treated with pan-RAR antagonist to show that in vitro decidualization is impaired. RNAi perturbation of individual RAR transcripts in hESCs revealed that RARα in particular is essential for proper decidualization. These data provide direct functional evidence that uterine RAR-mediated RA signaling is crucial for mammalian embryo implantation, and its disruption leads to failure of uterine receptivity and decidualization resulting in severely compromised fertility.
Authors
Yan Yin, Meade E. Haller, Sangappa B. Chadchan, Ramakrishna Kommagani, Liang Ma
Abstract
BACKGROUND. Epicardial adipose tissue (EAT) directly overlies the myocardium with changes in its morphology and volume associated with myriad cardiovascular and metabolic diseases. However, EAT’s immune structure and cellular characterization remain incompletely described. This study aimed to define the immune phenotype of EAT in humans, and compare such profiles across lean, obese and diabetic patients. METHODS. A total of 152 adult patients undergoing open chest coronary artery bypass grafting (CABG), valve repair/replacement (VR) surgery or combined CABG/valve surgery were recruited to the study. Patients’ clinical and biochemical data alongside epicardial adipose tissue (EAT), subcutaneous adipose tissue (SAT) and pre-operative blood samples were collected. Immune cell profiling was evaluated by flow cytometry and complemented by gene expression studies of immune mediators. Bulk RNA-seq was performed in EAT across different metabolic profiles to assess whole transcriptome changes observed in these groups. RESULTS. Flow cytometry analysis demonstrated that EAT is highly enriched in adaptive immune (T and B) cells. Whilst overweight/obese and diabetic patients had similar EAT cellular profiles to lean control patients, the EAT exhibited significantly (P≤.01) raised expression of immune mediators including: interleukin1 (IL1), IL6, tumour necrosis factorα (TNFα) and interferonγ (IFNγ). These changes were not observed in either SAT or blood. Neither underlying coronary artery disease nor the presence of hypertension significantly altered the immune profiles observed. Bulk RNA-seq demonstrated significant alterations in metabolic and inflammatory pathways in the EAT of overweight/obese patients compared with lean controls. CONCLUSIONS. Adaptive immune cells are the predominant immune cell constituent in human EAT and SAT. The presence of underlying cardiometabolic conditions, specifically obesity and diabetes, rather than cardiac disease phenotype appears to alter the inflammatory profile of EAT. Obese states markedly alter EAT metabolic and inflammatory signalling genes, underlining the impact of obesity on the EAT transcriptome profile.
Authors
Vishal Vyas, Hazel Blythe, Elizabeth G. Wood, Balraj Sandhar, Shah-Jalal Sarker, Damian Balmforth, Shirish G. Ambekar, John Yap, Stephen J. Edmondson, Carmelo Di Salvo, Kit Wong, Neil Roberts, Rakesh Uppal, Ben Adams, Alex Shipolini, Aung Y. Oo, David Lawrence, Shyam Kolvekar, Kulvinder S. Lall, Malcolm C. Finlay, M. Paula Longhi
Abstract
Host genes define the severity of inflammation and immunity but specific loci doing so are unknown. Here we show that TNFRSF13B variants which enhance defense against certain pathogens, also control immune-mediated injury of transplants, by regulating innate B cells’ functions. Analysis of TNFRSF13B in human kidney transplant recipients revealed that 33% of the subjects with antibody-mediated rejection (AMR) but less than 6% of those with stable graft function had TNFRSF13B missense mutations. To explore mechanisms underlying aggressive immune responses we investigated allo-immunity and rejection in mice. Cardiac allografts in Tnfrsf13b-mutant mice underwent early and severe AMR. The dominance and precocity of AMR in Tnfrsf13b-deficient mice was not caused by increased alloantibodies. Rather, Tnfrsf13b mutations decreased “natural” IgM and compromised complement regulation leading to complement deposition in allografted hearts and autogenous kidneys. Thus, wild type TNFRSF13B and Tnfrsf13b support innate B cell functions that limit complement-associated inflammation; in contrast, common variants of these genes, intensify inflammatory responses that help clear microbial infections but allow inadvertent tissue injury to ensue. The wide variation in inflammatory reactions associated with TNFRSF13B diversity suggests polymorphisms could underlie variation in host defense and explosive inflammatory responses that sometimes enhances morbidity associated with immune responses.
Authors
Mayara Garcia de Mattos Barbosa, Adam R. Lefferts, Daniel Huynh, Hui Liu, Yu Zhang, Beverly Fu, Jenna Barnes, Milagros Samaniego, Richard J. Bram, Raif Geha, Ariella Shikanov, Eline T. Luning Prak, Evan A. Farkash, Jeffrey L. Platt, Marilia Cascalho
Abstract
Rationale. The importance of the adaptative T cell response in the control and resolution of viral infection has been well-established. However, the nature of T cell-mediated viral control mechanisms in life-threatening stages of COVID-19 has yet to be determined. Objective. The aim of the present study was to determine the function and phenotype of T cell populations associated with survival or death of COVID-19 patients under intensive care as a result of phenotypic and functional profiling by mass cytometry. Findings. Increased frequencies of circulating, polyfunctional, CD4+CXCR5+HLA-DR+ stem cell memory T cells (TSCM) and decreased proportions of Granzyme-B and Perforin-expressing effector memory T cells (TEM) were detected in recovered and deceased patients, respectively. The higher abundance of polyfunctional CD8+PD-L1+CXCR3+ T effector cells, CXCR5+HLA-DR+ TSCM, as well as anti-nucleocapsid (NC) cytokine-producing T cells permitted to differentiate between recovered and deceased patients. The results from a principal component analysis showed an imbalance in the T cell compartment allowed for the separation of recovered and deceased patients. The paucity of circulating CD8+PD-L1+CXCR3+ Teff-cells and NC-specific CD8+ T-cells accurately forecasts fatal disease outcome. Conclusion. This study provides insight into the nature of the T cell populations involved in the control of COVID-19 and therefor might impact T cell-based vaccine designs for this infectious disease.
Authors
Lucille Adam, Pierre Rosenbaum, Paul Quentric, Christophe Parizot, Olivia Bonduelle, Noëlline Guillou, Aurelien Corneau, Karim Dorgham, Makoto Miyara, Charles-Edouard Luyt, Amélie Guihot, Guy Gorochov, Christophe Combadière, Behazine Combadière
Abstract
γδ T cell is a promising candidate cell in tumor immunotherapy. However, γδ T cells polarized to CD39+γδ Tregs upon colorectal cancer (CRC) induction and the underlying mechanism remains unclear. Here, we discovered that the frequency of CD39+γδ Tregs, which positively correlated with poor prognosis, was significantly higher in right-sided CRC (RSCRC) than in the left-sided CRC (LSCRC). Interestingly, CD39+γδ Tregs from RSCRC showed stronger immunosuppressive phenotype and function than LSCRC. Further, the quantitative mass spectrometry data showed that CD39+γδ Tregs polarization was related to the abnormal activation of the PLA2G4A/AA metabolic pathway in RSCRC. Using an in vitro co-culture system and an orthotopic murine model of CRC, we proved that the overexpression of Pla2g4a in CT26 cells induced CD39+γδ Tregs inhibiting the anti-tumor immune response. Finally, we found that the overall survival of the PLA2G4Ahigh group was significantly shortened compared to PLA2G4Alow RSCRC, while the survival of LSCRC was on the contrary. Collectively, RSCRC with abnormal PLA2G4A expression educates γδ T cells into CD39+γδ Tregs to promote tumor progression and metastasis. Our work highlights the interaction between cancer cells and immune cells by distinguishing the primary tumor site and deepens the understanding of tumor microenvironment and immunosuppression.
Authors
Yang Zhan, Lei Zheng, Jia Liu, Dongzhi Hu, Junfeng Wang, Kai Liu, Jiansheng Guo, Ti Zhang, Dalu Kong
Abstract
Energy balance is controlled by interconnected brain regions in the hypothalamus, brain stem, cortex and limbic system. Gene expression signatures of these regions can help elucidate the pathophysiology underlying obesity. RNA sequencing was conducted on P56 C57BL/6NTac male mice and E14.5 C57BL/6NTac embryos punch-biopsies in 16 obesity-relevant brain regions. The expression of 190 known obesity-associated genes (monogenic, rare and low-frequency coding variants, genome-wide association studies (GWAS), syndromic) were analyzed in each anatomical region. Genes associated with these genetic categories of obesity had localized expression patterns across brain regions. Known monogenic obesity causal genes were highly enriched in the arcuate nucleus of the hypothalamus and developing hypothalamus. The obesity-associated genes clustered into distinct ‘modules’ of similar expression profile and these are distinct from expression ‘modules’ formed by similar analysis with genes known to be associated with other disease phenotypes (type 1 and type 2 diabetes, autism, breast cancer) in the same energy balance-relevant brain regions.
Authors
Maria Caterina De Rosa, Hannah J. Glover, George Stratigopoulos, Charles A. LeDuc, Qi Su, Yufeng Shen, Mark W. Sleeman, Wendy K. Chung, Rudolph L. Leibel, Judith Y. Altarejos, Claudia A. Doege
Abstract
Type-2 dendritic cells (DC2s) comprise the majority of conventional DCs within most tumors; however, little is known about their ability to initiate and sustain anti-tumor immunity as most studies have focused on antigen cross-presenting Type-1 DCs (DC1s). Here we report that DC2 infiltration identified by analysis of multiple human cancer data sets showed a significant correlation with survival across multiple human cancers, with the benefit being seen in tumors resistant to cytotoxic T cell control. Characterization of DC subtype infiltration into an immunotherapy-resistant model of breast cancer revealed that impairment of DC1s through two unique models resulted in enhanced DC2 functionality and improved tumor control. Batf3-deficiency depleted intratumoral DC1s led to increased DC2 lymph node migration and CD4+ T cell activation. Enhancing DC2 stimulatory potential by genetic deletion of Hsp90b1 (encoding molecular chaperon GP96) led to a similar enhancement of T cell immunity and improved survival in a spontaneous breast cancer model. This data highlights the therapeutic and prognostic potential of DC2s within checkpoint blockade-resistant tumors.
Authors
Stephen Iwanowycz, Soo Ngoi, Yingqi Li, Megan Hill, Christopher Koivisto, Melodie Parrish, Beichu Guo, Zihai Li, Bei Liu
Abstract
BACKGROUND. Naturally acquired immunity to malaria is incompletely understood. We used controlled human malaria infection (CHMI) to study the impact of past exposure to malaria in Kenyan adults in relation to infection with a non-Kenyan parasite strain. METHODS. We administered 3.2x103 aseptic, purified, cryopreserved Plasmodium falciparum (Pf) sporozoites (SPZ) [Sanaria® PfSPZ Challenge, NF54 West African strain] by direct venous inoculation and undertook clinical monitoring and serial quantitative PCR (qPCR) of the 18S ribosomal RNA gene. The study endpoint was met when either: parasitaemia reached ≥500 parasites/μl blood; clinically significant symptoms were seen; or at 21 days after inoculation. All volunteers received antimalarial drug treatment on meeting the endpoint. RESULTS. One hundred and sixty-one (161) volunteers underwent CHMI between Aug 4, 2016, and Feb 14, 2018. CHMI was well tolerated with no severe or serious adverse events. Nineteen volunteers (11.8%) were excluded from the analysis based on detection of antimalarial drugs above the minimal inhibitory concentration or parasites genotyped as non-NF54. Of the 142 volunteers who were eligible for analysis: 26 (18.3%) had febrile symptoms and were treated; 30 (21.1%) reached ≥500 parasites/μl and were treated; 53 (37.3%) had parasitaemia without meeting thresholds for treatment and; 33 (23.2%) remained qPCR negative. CONCLUSION. We find that past exposure to malaria, as evidenced by location of residence, in some Kenyan adults can completely suppress in vivo growth of a parasite strain originating from outside Kenya. TRAIL REGISTRATION. The study was registered on ClinicalTrials.gov (NCT02739763). FUNDING. Wellcome Trust
Authors
Melissa C. Kapulu, Patricia Njuguna, Mainga Hamaluba, Domtila Kimani, Joyce M. Ngoi, Janet Musembi, Omar Ngoto, Edward Otieno, Peter F. Billingsley
Abstract
Neutrophil-mediated activation and injury of the endothelium play a role in the pathogenesis of diverse disease states ranging from autoimmunity to cancer to COVID-19. Neutralization of cationic proteins (such as neutrophil extracellular trap/NET-derived histones) with polyanionic compounds has been suggested as a potential strategy for protecting the endothelium from such insults. Here, we report that the FDA-approved polyanionic agent defibrotide (a pleotropic mixture of oligonucleotides) directly engages histones and thereby blocks their pathological effects on endothelium. In vitro, defibrotide counteracted endothelial cell activation and pyroptosis-mediated cell death, whether triggered by purified NETs or recombinant histone H4. In vivo, defibrotide stabilized the endothelium and protected against histone-accelerated inferior vena cava thrombosis in mice. Mechanistically, defibrotide demonstrated direct and tight binding to histone H4 as detected by both electrophoretic mobility shift assay and surface plasmon resonance. Taken together, these data provide insights into the potential role of polyanionic compounds in protecting the endothelium from thromboinflammation with potential implications for myriad NET- and histone-accelerated disease states.
Authors
Hui Shi, Alex A. Gandhi, Stephanie A. Smith, Qiuyu Wang, Diane Chiang, Srilakshmi Yalavarthi, Ramadan A. Ali, Chao Liu, Gautam Sule, Pei-Suen Tsou, Yu Zuo, Yogendra Kanthi, Evan A. Farkash, Jiandie D. Lin, James H. Morrissey, Jason S. Knight
