Energy metabolism failure in proximal tubule cells (PTC) is a hallmark of chronic kidney injury. We combined transcriptomic, metabolomic and lipidomic approaches in experimental models and patient cohorts to investigate the molecular bases of the progression to chronic kidney allograft injury initiated by ischemia-reperfusion injury (IRI). The urinary metabolome of kidney transplant recipients with chronic allograft injury and who experienced severe IRI was significantly enriched with long chain fatty acids (FA). We identified a renal FA-related gene signature with low levels of Cpt2 and Acsm5 and high levels of Acsl4 and Acsm5 associated with IRI, transition to chronic injury, and established CKD in mouse models and kidney transplant recipients. The findings were consistent with the presence of Cpt2-, Acsl4+, Acsl5+, Acsm5- PTC failing to recover from IRI as identified by snRNAseq. In vitro experiments indicated that endoplasmic reticulum (ER) stress contributes to CPT2 repression, which, in turn, promotes lipids accumulation, drives profibrogenic epithelial phenotypic changes, and activates the unfolded protein response. ER stress through CPT2 inhibition and lipid accumulation, engages an auto-amplification loop leading to lipotoxicity and self-sustained cellular stress. Thus, IRI imprints a persistent FA metabolism disturbance in the proximal tubule sustaining the progression to chronic kidney allograft injury.
Anna Rinaldi, Hélène Lazareth, Virginie Poindessous, Ivan Nemazanyy, Julio L. Sampaio, Daniele Malpetti, Yohan Bignon, Maarten Naesens, Marion Rabant, Dany Anglicheau, Pietro E. Cippà, Nicolas Pallet
Macrophages in the tumor microenvironment have a significant impact on tumor progression. Depending on the signaling environment in the tumor, macrophages can either support or constrain tumor progression. It is therefore of therapeutic interest to identify the tumor-derived factors that control macrophage education. With this aim, we correlated the expression of ADAM proteases, which are key mediators of cell-cell signaling, to the expression of pro-tumorigenic macrophage markers in human cancer cohorts. We identified ADAM17, a sheddase upregulated in many cancer types, as a protein of interest. Depletion of ADAM17 in cancer cell lines reduced the expression of several pro-tumorigenic markers in neighboring macrophages in vitro as well as in mouse models. Moreover, ADAM17-/- educated macrophages demonstrated a reduced ability to induce cancer cell invasion. Using mass spectrometry-based proteomics and ELISA, we identified HB-EGF and AREG, shed by ADAM17 in the cancer cells, as the implicated molecular mediators of macrophage education. Additionally, RNA-seq and ELISA experiments revealed that ADAM17-dependent HB-EGF-ligand release induces the expression and secretion of CXCL chemokines in macrophages, which in turn stimulates cancer cell invasion. In conclusion, we provide evidence that ADAM17 mediates a paracrine EGFR-ligand-chemokine feedback loop, whereby cancer cells hijack macrophages to promote tumor progression.
Sebastian Gnosa, Laia Puig-Blasco, Krzysztof B. Piotrowski, Marie L. Freiberg, Simonas Savickas, Daniel H. Madsen, Ulrich auf dem Keller, Pauliina Kronqvist, Marie Kveiborg
Obesity is an important risk factor for atrial fibrillation (AF), but a better mechanistic understanding of obesity-related atrial fibrillation is required. Serum glucocorticoid kinase 1 (SGK1) is a kinase positioned within multiple obesity-related pathways, and prior work has shown a pathologic role of SGK1 signaling in ventricular arrhythmias. We validated a mouse model of obesity-related AF using wild type mice fed a high fat diet. RNA sequencing of atrial tissue demonstrated substantial differences in gene expression, with enrichment of multiple SGK1-related pathways, and we confirmed upregulated of SGK1 transcription, activation, and signaling in obese atria. Mice expressing a cardiac specific dominant negative SGK1 were protected from obesity-related AF, through effects on atrial electrophysiology, action potential characteristics, structural remodeling, inflammation, and sodium current. Overall, this study demonstrates the promise of targeting SGK1 in a mouse model of obesity-related AF.
Aneesh Bapat, Guoping Li, Ling Xiao, Ashish Yeri, Maarten Hulsmans, Jana Grune, Masahiro Yamazoe, Maximillian J. Schloss, Yoshiko Iwamoto, Justin G. Tedeschi, Xinyu Yang, Matthias Nahrendorf, Anthony Rosenzweig, Patrick T. Ellinor, Saumya Das, David Milan
The liver regulates energy partitioning and utilization in a sex-dependent manner, coupling hepatic substrate availability to female reproductive status. Fibroblast growth factor-21 (FGF21) is a hepatokine produced in response to metabolic stress that adaptively directs systemic metabolism and substrate utilization to reduce hepatic lipid storage. Here we report that FGF21 alters hepatic transcriptional and metabolic responses, and reduces liver triglycerides, in a sex-dependent manner. FGF21 decreased hepatic triglycerides in obese male mice in a weight loss-independent manner; this was abrogated among female littermates. The effect of FGF21 on hepatosteatosis is thought to derive, in part, from increased adiponectin secretion. Accordingly, plasma adiponectin and its upstream adrenergic receptor --> cAMP --> EPAC1 signaling pathway was stimulated by FGF21 in males and inhibited in females. Both ovariectomized and reproductively senescent, old females responded to FGF21 treatment by decreasing body weight, but liver triglycerides and adiponectin remained unchanged. Thus, the benefit of FGF21 treatment for improving hepatosteatosis depends on sex, but not on a functional female reproductive system. Because FGF21 provides a downstream mechanism contributing to several metabolic interventions, and given its direct clinical importance, these findings may have broad implications for the targeted application of nutritional and pharmacological treatments for metabolic disease.
Aki T. Chaffin, Karlton R. Larson, Kuei-Pin Huang, Chih-Ting Wu, Nadejda Godoroja, Yanbin Fang, Devi Jayakrishnan, Karla A. Soto Sauza, Landon C. Sims, Niloufar Mohajerani, Michael L. Goodson, Karen K. Ryan
New strategies that augment T-cell responses are required to broaden the therapeutic arsenal against cancer. CD96, TIGIT and CD226 are receptors that bind to a communal ligand, CD155, and transduce either inhibitory or activating signals. Whereas the function of TIGIT and CD226 is established, the role of CD96 remains ambiguous. Using a panel of engineered antibodies, we discovered that the T-cell stimulatory activity of anti-CD96 antibodies requires antibody crosslinking and is potentiated by Fc-gamma receptors. Thus, soluble ‘Fc silent’ anti-CD96 antibodies failed to stimulate human T cells, whereas the same antibodies were stimulatory after coating onto plastic surfaces. Remarkably, the activity of soluble anti-CD96 antibodies was reinstated by engineering the Fc domain to a human IgG1 isotype and was dependent on antibody trans-crosslinking by Fc-γRI. In contrast, neither human IgG2 nor variants with increased Fc-γ receptor IIB binding possessed stimulatory activity. Anti-CD96 antibodies acted directly on T cells and augmented gene expression networks associated with T-cell activation, leading to proliferation, cytokine secretion and resistance to regulatory T-cell suppression. Furthermore, CD96 expression correlated with survival in HPV+ head and neck squamous cell carcinoma and its crosslinking activated tumor-infiltrating T cells, thus highlighting the potential of anti-CD96 antibodies in cancer immunotherapy.
Anne Rogel, Fathima M. Ibrahim, Stephen M. Thirdborough, Florence Renart-Depontieu, Charles N. Birts, Sarah L. Buchan, Xavier Preville, Emma V. King, Aymen Al-Shamkhani
The (Pro)renin receptor ((P)RR), also known as ATP6AP2, is a single-transmembrane protein that is implicated in a multitude of biological processes. However, the exact role of ATP6AP2 during blood vessel development remains largely undefined. Here, we use an inducible endothelial cell (EC)-specific Atp6ap2 knockout mouse model to investigate the role of ATP6AP2 during both physiological and pathological angiogenesis in vivo. We observed that postnatal deletion of Atp6ap2 in ECs results in cell migration defects, loss of tip cell polarity and subsequent impairment of retinal angiogenesis. In vitro, Atp6ap2 deficient ECs similarly displayed reduced cell migration, impaired sprouting, and defective cell polarity. Transcriptional profiling of ECs isolated from Atp6ap2 mutant mice further indicated regulatory roles in angiogenesis, cell migration and extracellular matrix composition. Mechanistically, we provided evidence that expression of various extracellular matrix components is controlled by ATP6AP2 via the extracellular-signal-regulated kinase (ERK) pathway. Furthermore, Atp6ap2 deficient retinas exhibited reduced revascularization in an oxygen induced retinopathy model. Collectively, our results demonstrated a critical role of ATP6AP2 as a regulator of developmental and pathological angiogenesis.
Nehal R. Patel, Rajan K C, Avery E. Blanks, Yisu Li, Minolfa C. Prieto, Stryder M. Meadows
Development of resistance to chemo- and immuno- therapies often occurs following treatment of melanoma brain metastasis (MBM). In this scenario, astrocytes cooperate towards MBM progression by upregulating secreted-factors, amongst which we found that monocyte chemoattractant protein-1 (MCP-1) and its receptors, CCR2 and CCR4, are overexpressed in activated astrocytes and in brain metastatic melanoma cells compared to primary lesions. We show that melanoma cells alter astrocytes-secretome and evoke MCP-1 expression and secretion, which in turn enhance vascular hyperpermeability and proliferation, migration, and invasion of CCR2-expressing melanoma cells, while inhibiting MCP-1 rescued this phenotype. Pharmacological or molecular inhibition of MCP-1/CCR2 in MBM mouse model activates an anti-tumor immune-mediated response as revealed by the enhanced infiltration of cytotoxic CD8+ T cells, attenuated immunosuppressive phenotype of tumor-associated macrophages, and reduced infiltration of regulatory T cells, leading to inhibition of MBM progression and prolonged survival. In addition, blocking this key target in MBM, improved the therapeutic response of anti-PD-1 immunotherapy, regardless of the tumor mutational load. These results show that the MCP-1/CCR2 axis polarizes the brain microenvironment towards an anti-inflammatory/pro-tumorigenic phenotype, highlighting the therapeutic relevance of this pathway as a potential immune checkpoint in MBM.
Sabina Pozzi, Anna Scomparin, Dikla Ben-Shushan, Eilam Yeini, Paula Ofek, Alessio D. Nahmad, Shelly Soffer, Ariel Ionescu, Antonella Ruggiero, Adi Barzel, Henry Brem, Thomas M. Hyde, Iris Barshack, Sanju Sinha, Eytan Ruppin, Tomer Weiss, Asaf Madi, Eran Perlson, Inna Slutsky, Helena F. Florindo, Ronit Satchi-Fainaro
Accurate estimate of fetal maturity could provide individualized guidance for delivery of complicated pregnancies. However, current methods are invasive, have low accuracy, and are limited to fetal lung maturation. To identify diagnostic gestational biomarkers, we performed transcriptomic profiling of lung and brain, as well as cell-free RNA from amniotic fluid of preterm and term rhesus macaque fetuses. These data identify new and prior associated gestational age differences in distinct lung and neuronal cell populations when compared to existing single-cell and bulk RNA-Seq data. Comparative analyses found hundreds of genes coincidently induced in lung and amniotic fluid, and dozens in brain and amniotic fluid. This data enabled creation of computational models that accurately predicted lung compliance from amniotic fluid and lung transcriptome of preterm fetuses treated with antenatal corticosteroids. Importantly, antenatal steroids induced off target gene expression changes in the brain, impinging upon synaptic transmission, neuronal and glial maturation, which could have long term consequences on brain development. Cell-free RNA in amniotic fluid may provide a substrate of global fetal maturation markers for personalized management of at-risk pregnancies.
Augusto F. Schmidt, Daniel Schnell, Kenneth P. Eaton, Kashish Chetal, Paranthaman S. Kannan, Lisa A. Miller, Claire A. Chougnet, Daniel T. Swarr, Alan H. Jobe, Nathan Salomonis, Beena D. Kamath-Rayne
Lentiviral vector-based dendritic cell vaccines induce protective T cell responses against viral infection and cancer in animal models. In this study, we tested whether preventative and therapeutic vaccination could be achieved by direct injection of antigen expressing lentiviral vector, obviating the need for ex vivo transduction of dendritic cells. Injected lentiviral vector preferentially transduced splenic dendritic cells and resulted in long-term expression. Injection of a lentiviral vector encoding an MHC class I restricted T cell epitope of LCMV and CD40L induced an antigen-specific cytolytic CD8+ T lymphocyte response that protected the mice from infection. The injection of chronically infected mice with a lentiviral vector encoding LCMV MHC class I and II T cell epitopes and a soluble PD-1 microbody rapidly cleared the virus. Vaccination by direct injection of lentiviral vector was more effective in SAMHD1 knock-out mice, suggesting that lentiviral vectors containing Vpx, a lentiviral protein that increases the efficiency of dendritic cell transduction by inducing the degradation of SAMHD1, would be an effective strategy for the treatment of chronic disease in humans.
Takuya Tada, Thomas D. Norton, Rebecca Leibowitz, Nathaniel R. Landau
Cub domain-containing protein 1 (CDCP1) is a surface protein highly expressed on the surface of many cancer cells, however, the distribution of CDCP1 in normal tissues and its potential roles in non-tumor cells are poorly understood. We previously reported that CDCP1 interacts with CD6, a surface marker of T cells, suggesting that it is a novel immunoregulator, but the physiological significance of the newly discovered CDCP1-CD6 interaction remains unclear. In this report, we found that CDCP1 is present on both human and mouse retinal pigmented epithelial cells (RPEs), a component of the blood-retina barrier (BRB), using a new anti-CDCP1 monoclonal antibody that we developed. CDCP1 knockout (KO) mice on two different genetic backgrounds both developed significantly attenuated retinal T cell infiltration and uveitis after adoptive transfer of pre-activated pathogenic T cells in a model of autoimmune uveitis. We also found that tight junctions were severely disrupted with infiltrating T cells detected in the RPE flat mounts prepared from the WT but not CDCP1 KO mice during EAU development. Mechanistically, we discovered that CDCP1 on RPE was upregulated by IFNγ in vitro and after EAU induction in vivo. CD6 stimulation induced significantly increased RPE barrier permeability of WT, but not CDCP1 knockdown (KD) RPE, and activated T cells migrated through the WT RPE monolayes more efficiently than the CDCP1 KD RPE monolayers. In addition, CD6 stimulation of WT, but not the CDCP1 KD RPEs, induced massive stress fiber formation and focal adhesion disruption to reduce cell barrier tight junctions. These data suggest that CDCP1 on RPEs interacts with CD6 on T cells to induce RPE cytoskeleton remodeling and focal adhesion disruption, which open up the tight junctions to facilitate T cell infiltration for the development of uveitis.
Lingjun Zhang, Nozha Borjini, Yu Lun, Sweta Parab, Gospel Enyindah-Asonye, Rupesh Singh, Brent A. Bell, Vera L. Bonilha, Andrei I. Ivanov, David A. Fox, Rachel R. Caspi, Feng Lin
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