The bromodomain and extraterminal (BET) family of epigenetic reader proteins are key regulators of inflammatory and hypertrophic gene expression in the heart. We previously identified the activation of pro-inflammatory gene networks as a key early driver of dilated cardiomyopathy (DCM) in transgenic mice expressing a mutant form of phospholamban (PLNR9C) – a genetic cause of DCM in humans. We hypothesized that BETs coactivate this inflammatory process, representing a critical node in the progression of DCM. To test this hypothesis, PLNR9C or age-matched wild type mice were treated longitudinally with the small molecule BET bromodomain inhibitor JQ1 or vehicle. BET inhibition abrogated adverse cardiac remodeling, reduced cardiac fibrosis, and prolonged survival in PLNR9C mice by inhibiting expression of pro-inflammatory gene networks at all stages of disease. Specifically, JQ1 had profound effects on pro-inflammatory gene network expression in cardiac fibroblasts, while having little effect on gene expression in cardiomyocytes. Cardiac fibroblast proliferation was also substantially reduced by JQ1. Mechanistically, we demonstrated that BRD4 serves as a direct and essential regulator of NFkB-mediated pro-inflammatory gene expression in cardiac fibroblasts. Interdicting pro-inflammatory gene expression via BET bromodomain inhibition could be a novel therapeutic strategy for chronic DCM in humans.
Andrew Antolic, Hiroko Wakimoto, Zhe Jiao, Joshua M. Gorham, Steven R. DePalma, Madeleine E. Lemieux, David A. Conner, Da Young Lee, Jun Qi, Jonathan G. Seidman, James E. Bradner, Jonathan D. Brown, Saptarsi M. Haldar, Christine E. Seidman, Michael A. Burke
Macrolide antibiotics exert anti-inflammatory effects; however, little is known regarding their immunomodulatory mechanisms. In this study, using two distinct mouse models of mucosal inflammatory disease (LPS-induced acute lung injury and ligature-induced periodontitis), we demonstrated that the anti-inflammatory action of erythromycin (ERM) is mediated through upregulation of the secreted homeostatic protein DEL-1. Consistent with the anti-neutrophil recruitment action of endothelial cell-derived DEL-1, ERM inhibited neutrophil infiltration in the lungs and the periodontium in a DEL-1-dependent manner. Whereas ERM (but not other antibiotics such as josamycin and penicillin) protected against lethal pulmonary inflammation and inflammatory periodontal bone loss, these protective effects of ERM were abolished in Del1-deficient mice. By interacting with the growth hormone secretagogue receptor (GHSR) and activating JAK2 in human lung microvascular endothelial cells, ERM induced C/EBPβ-dependent DEL-1 transcription, which was mediated by MAPK p38. Moreover, ERM reversed IL-17-induced inhibition of DEL-1 transcription, in a manner that was not only dependent on JAK2 but also on PI3K/AKT signaling. As DEL-1 levels are severely reduced in inflammatory conditions and with aging, the ability of ERM to upregulate DEL-1 may be a novel approach for the treatment of inflammatory and aging-related diseases.
Tomoki Maekawa, Hikaru Tamura, Hisanori Domon, Takumi Hiyoshi, Toshihito Isono, Daisuke Yonezawa, Naoki Hayashi, Naoki Takahashi, Koichi Tabeta, Takeyasu Maeda, Masataka Oda, Athanasios Ziogas, Vasileia Ι. Alexaki, Triantafyllos Chavakis, Yutaka Terao, George Hajishengallis
Dendritic cells (DCs) are critical component of immune responses in cancer primarily due to their ability to cross-present tumor associated antigens. Cross-presentation by DCs in cancer is impaired, which may represent one of the obstacles for the success of cancer immunotherapies. Here, we report that polymorphonuclear myeloid derived suppressor cells (PMN-MDSC) blocked cross-presentation by DCs without affecting direct presentation of antigens by these cells. This effect did not require direct cell-cell contact and was associated with transfer of lipids. Neutrophils (PMN) and PMN-MDSC transferred lipid to DCs equally well, however PMN did not affect DC cross-presentation. PMN-MDSC generate oxidatively truncated lipids previously shown to be involved in impaired cross-presentation by DCs. Accumulation of oxidized lipids in PMN-MDSC was dependent on myeloperoxidase (MPO). MPO deficient PMN-MDSC did not affect cross-presentation by DCs. Cross-presentation of tumor associated antigens in vivo by DCs was improved in MDSC depleted or tumor-bearing MPO KO mice. Pharmacological inhibition of MPO in combination with checkpoint blockade reduced tumor progression in different tumor models. These data suggest MPO-driven lipid peroxidation in PMN-MDSC as a possible non-cell autonomous mechanism of inhibition of antigen cross-presentation by DCs and propose MPO as potential therapeutic target to enhance the efficacy of current immunotherapies for cancer patients.
Alessio Ugolini, Vladimir Tyurin, Yulia Tyurina, Evgenii Tsyganov, Laxminarasimha Donthireddy, Valerian E Kagan, Dmitry I. Gabrilovich, Filippo Veglia
Noonan syndrome with multiple lentigines (NSML) is a rare autosomal dominant disorder that presents with cardio-cutaneous-craniofacial defects. Hypertrophic cardiomyopathy (HCM) represents the major life-threatening presentation in NSML. Mutations in the PTPN11 gene that encodes for the protein tyrosine phosphatase (PTP), SHP2, represents the predominant cause of HCM in NSML. NSML-associated PTPN11 mutations renders SHP2 catalytically inactive with an “open” conformation. NSML-associated PTPN11 mutations cause hypertyrosyl phosphorylation of the transmembrane glycoprotein, protein zero-related (PZR) resulting in increased SHP2 binding. Here we show that NSML mice harboring a tyrosyl phosphorylation-defective mutant of PZR (NSML/PZRY242F) that is defective for SHP2 binding fail to develop HCM. Enhanced AKT/S6K signaling in heart lysates of NSML mice was reversed in NSML/PZRY242F mice demonstrating that PZR/SHP2 interactions promote aberrant AKT/S6K activity in NSML. Enhanced PZR tyrosyl phosphorylation in the hearts of NSML mice was found to drive myocardial fibrosis by engaging a Src/NFkB pathway resulting in increased activation of interleukin-6 (IL6). Increased expression of IL6 in the hearts of NSML mice was reversed in NSML/PZRY242F mice and PZRY242F mutant fibroblasts were defective for IL6 secretion and STAT3-mediated fibrogenesis. These results demonstrate that NSML-associated PTPN11 mutations that induce PZR hypertyrosyl phosphorylation trigger pathophysiological signaling that promotes HCM and cardiac fibrosis.
Jae-Sung Yi, Sravan K. Perla, Liz E. Enyenihi, Anton M. Bennett
De novo lipogenesis (DNL) plays a role in the development of hepatic steatosis. In humans with lipodystrophy, reduced adipose tissue causes lower plasma leptin, insulin resistance, dyslipidemia and ectopic triglyceride (TG) accumulation. We hypothesized that recombinant leptin (metreleptin) for 6 months in 11 patients with lipodystrophy would reduce DNL by decreasing insulin resistance and glycemia, thus reducing circulating and hepatic-TG. The percentage of TG-rich lipoprotein particle (TRLP)-TG derived from DNL (%DNL) was measured by deuterium incorporation from body water into palmitate. At baseline, DNL was elevated with levels similar to levels previously shown in obesity-associated nonalcoholic fatty liver disease (NAFLD). After metreleptin, DNL decreased into the normal range. Similarly, absolute DNL (TRLP-TG x % DNL) decreased by 88% to near-normal levels. Metreleptin improved peripheral insulin sensitivity (hyperinsulinemic-euglycemic clamp) and lowered HbA1c and hepatic-TG. Both before and after metreleptin, DNL positively correlated with insulin resistance, insulin doses, and hepatic-TG, supporting the hypothesis that hyperinsulinemia stimulates DNL and that elevated DNL is integral to the pathogenesis of lipodystrophy-associated NAFLD.These data suggest that leptin-mediated improvement in insulin sensitivity increases clearance of blood glucose by peripheral tissues, reduces hepatic carbohydrate flux, and lowers insulinemia, resulting in DNL reductions, and improvements in hepatic steatosis and dyslipidemia.
Annah P. Baykal, Elizabeth J. Parks, Robert Shamburek, Majid M. Syed-Abdul, Shaji K. Chacko, Elaine Cochran, Megan Startzell, Ahmed M. Gharib, Ronald Ouwerkerk, Khaled Z. Abd-Elmoniem, Peter J. Walter, Mary Walter, Ranganath Muniyappa, Stephanie T. Chung, Rebecca J. Brown
Cigarette smoking (CS) and genetic susceptibility determine the risk for development, progression, and severity of chronic obstructive pulmonary diseases (COPD). We posited that an incidental balanced reciprocal chromosomal translocation was linked to a patient’s risk of severe COPD. We determined 46,XX,t(1;4)(p13.1;q34.3) caused a breakpoint in IGSF3 (immunoglobulin superfamily, member 3) gene, with markedly decreased expression. Examination of COPDGene cohort identified 14 IGSF3 SNPs of which, rs1414272 and rs12066192 were directly- and rs6703791 inversely associated with COPD severity, including COPD exacerbations. We confirmed that IGSF3 is a tetraspanin-interacting protein that colocalized with CD9 and integrin B1 in tetraspanin enriched domains. IGSF3-deficient patient-derived lymphoblastoids exhibited multiple alterations in gene expression, especially in the unfolded protein response and ceramide pathways. IGSF3-deficient lymphoblastoids had high ceramide- and sphingosine-1 phosphate-, but low glycosphingolipids- and gangliosides levels; were less apoptotic and more adherent; with marked changes in multiple TNFRSF molecules. Similarly, IGSF3 knockdown increased ceramide in lung structural cells, rendering them more adherent, with impaired wound repair and a weakened barrier function. These findings suggest that, by maintaining sphingolipid and membrane receptor homeostasis, IGSF3 is required for cell mobility-mediated lung injury repair. IGSF3 deficiency may increase susceptibility to CS-induced lung injury in COPD.
Kelly S. Schweitzer, Natini Jinawath, Raluca Yonescu, Kevin Ni, Natalia Rush, Varodom Charoensawan, Irina Bronova, Evgeny Berdyshev, Sonia M. Leach, Lucas A. Gillenwater, Russell P. Bowler, David B. Pearse, Constance A. Griffin, Irina Petrache
Group 2 innate lymphoid cells (ILC2s) in mouse lungs are activated by the epithelium-derived alarmin IL-33. Activated ILC2s proliferate and produce IL-5 and IL-13 that drive allergic responses. In neonatal lungs, IL-33 is spontaneously released resulting in activation of lung ILC2s. Here we report that neonatal lung ILC2 activation by endogenous IL-33 has significant effects on ILC2 functions in adulthood. Most neonatal lung ILC2s incorporated 5-bromo-2’-deoxyuridine (BrdU) and persisted into adulthood. BrdU+ ILC2s in adult lungs responded more intensely to IL-33 treatment than BrdU- ILC2s. In IL-33 deficient (KO) mice, lung ILC2s develop normally but they are not activated in the neonatal period. Lung ILC2s in KO mice responded less intensely to IL-33 in adulthood compared to wild type (WT) ILC2s. While there was no difference in the number of lung ILC2s, there were fewer IL-13+ ILC2s in KO than WT mice. The impaired responsiveness of ILC2s in KO mice was reversed by intranasal administrations of IL-33 in the neonatal period. These results suggest that activation of lung ILC2s by endogenous IL-33 in the neonatal period may “train” ILC2s seeding the lung after birth to become long-lasting resident cells that respond more efficiently to challenges later in life.
Catherine A. Steer, Laura Mathä, Hanjoo Shim, Fumio Takei
It has been proposed that unmethylated insulin promoter fragments in plasma derive exclusively from β-cells, reflect their recent demise and can be used to assess β-cell damage in type 1 diabetes. Herein we describe an ultrasensitive assay for detection of a β-cell-specific DNA methylation signature, by simultaneous assessment of six DNA methylation markers, that identifies β-cell DNA in mixtures containing as little as 0.03% β-cell DNA (less than one β-cell genome equivalent). With this assay, plasma from non-diabetic individuals (N=218, aged 4-78 years) contained on average only one β-cell genome equivalent/ml. As expected, β-cell cfDNA was significantly elevated in islet transplant recipients shortly after transplantation. We also detected β-cell cfDNA in a patient with KATP congenital hyperinsulinism where substantial β-cell turnover is thought to occur. Strikingly, in contrast to previous reports, we observed no elevation of β-cell-derived cfDNA in autoantibody positive subjects at-risk for type 1 diabetes (N=32), individuals with recent-onset type 1 diabetes (<4 months, N=92), or those with a long-standing disease (>4 months, N=38). We discuss the utility of sensitive beta-cell cfDNA analysis and potential explanations for the lack of a β-cell cfDNA signal in T1D.
Daniel Neiman, David Gillis, Sheina Piyanzin, Daniel Cohen, Ori Fridlich, Joshua Moss, Aviad Zick, Tal Oron, Frida Sundberg, Gun Forsander, Oskar Skog, Olle Korsgren, Floris Levy-Khademi, Dan Arbell, Saar Hashavya, A.M. James Shapiro, Cate Speake, Carla Greenbaum, Jennifer Hosford, Amanda Posgai, Mark A. Atkinson, Benjamin Glaser, Desmond Schatz, Ruth Shemer, Yuval Dor
Rituximab, a B cell-depleting therapy, is indicated for treating a growing number of autoantibody-mediated autoimmune disorders. However, relapses can occur after treatment and autoantibody-producing B cell subsets may be found during relapses. It is not understood if these autoantibody-producing B cell subsets emerge from the failed depletion of pre-existing B cells or are generated de novo. To further define the mechanisms that cause post-rituximab relapse, we studied patients with autoantibody-mediated muscle-specific kinase (MuSK) myasthenia gravis (MG) who relapsed after treatment. We carried out single-cell transcriptional and B cell receptor (BCR) profiling on longitudinal B cell samples. We identified clones present prior to therapy that continued to persist during relapse. Persistent B cell clones included both antibody-secreting cells and memory B cells characterized by gene expression signatures associated with B cell survival. A subset of persistent antibody-secreting cells and memory B cells were specific for the MuSK autoantigen. These results demonstrate that rituximab is not fully effective at eliminating autoantibody-producing B cells and provide a mechanistic understanding of post-rituximab relapse in MuSK MG.
Ruoyi Jiang, Miriam L. Fichtner, Kenneth B. Hoehn, Minh C. Pham, Panos Stathopoulos, Richard J. Nowak, Steven H. Kleinstein, Kevin C. O'Connor
Pancreatic ductal adenocarcinoma (PDA) is a lethal malignancy that has no effective treatment. The tumor microenvironment (TME) of PDA employs a multitude of immune derangement strategies to protect PDA from immune elimination. Tumor associated macrophages (TAMs) have been implicated in pathogenesis of immune suppression of PDA-TME, however, its underlying mechanisms remained largely unknown. Using primary patient samples, our studies showed that in comparison with macrophages isolated from normal pancreatic tissues, the phagocytosis activity of PDA-TAM is significantly reduced. We found that the expression of homeobox protein VentX, a master regulator of macrophage plasticity, is significantly decreased in the PDA-TAMs. We demonstrated that VentX is required for phagocytosis and that restoration of VentX expression in PDA-TAMs promotes phagocytosis through regulating the signaling cascades involved in the process. Using an ex-vivo culture model of primary human PDA, we showed that VentX-modulated-TAMs transformed PDA-TME from a pro-tumor milieu to an anti-tumor microenvironment by rectifying differentiation, proliferation and activation of PDA-infiltrating immune cells. Using NSG-PDX models of primary human PDAs, we showed that VentX-modulated-TAMs exert strong inhibition on PDA tumorigenesis in vivo. Taken together, our data revealed a central mechanism underlying immune evasion of PDA and a potential novel venue to improve PDA prognosis.
Yi Le, Hong Gao, William G. Richards, Lei Zhao, Ronald Bleday, Thomas Clancy, Zhenglun Zhu
No posts were found with this tag.