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1.
Nuclear Receptors as Autophagy-Based Antimicrobial Therapeutics.
Silwal, P, Paik, S, Jeon, SM, Jo, EK
Cells. 2020;(9)
Abstract
Autophagy is an intracellular process that targets intracellular pathogens for lysosomal degradation. Autophagy is tightly controlled at transcriptional and post-translational levels. Nuclear receptors (NRs) are a family of transcriptional factors that regulate the expression of gene sets involved in, for example, metabolic and immune homeostasis. Several NRs show promise as host-directed anti-infectives through the modulation of autophagy activities by their natural ligands or small molecules (agonists/antagonists). Here, we review the roles and mechanisms of NRs (vitamin D receptors, estrogen receptors, estrogen-related receptors, and peroxisome proliferator-activated receptors) in linking immunity and autophagy during infection. We also discuss the potential of emerging NRs (REV-ERBs, retinoic acid receptors, retinoic acid-related orphan receptors, liver X receptors, farnesoid X receptors, and thyroid hormone receptors) as candidate antimicrobials. The identification of novel roles and mechanisms for NRs will enable the development of autophagy-adjunctive therapeutics for emerging and re-emerging infectious diseases.
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2.
Immunoregulatory Functions of Nuclear Receptors: Mechanisms and Therapeutic Implications.
Zhao, L, Gimple, RC, Yang, Z, Wei, Y, Gustafsson, JÅ, Zhou, S
Trends in endocrinology and metabolism: TEM. 2020;(2):93-106
Abstract
Members of the nuclear receptor superfamily serve as master regulators in signaling by either positively or negatively regulating gene expression. Accumulating evidence has suggested that nuclear receptors are actively involved in immune responses, with specific roles in different immune cell compartments that contribute to both normal function and to disease development. The druggable properties of nuclear receptors have made them ideal modulatory therapeutic targets. Here, we revisit nuclear receptor biology, summarize recent advances in our understanding of the immunological functions of nuclear receptors, describe cell-type-specific roles and specific nuclear receptors in disease pathogenesis, and explore their potential as novel therapeutic targets. These nuclear receptor-dependent alterations in the immune system are amenable to pharmacological manipulation and suggest novel therapeutic strategies.
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3.
Potential of Intestine-Selective FXR Modulation for Treatment of Metabolic Disease.
van Zutphen, T, Bertolini, A, de Vries, HD, Bloks, VW, de Boer, JF, Jonker, JW, Kuipers, F
Handbook of experimental pharmacology. 2019;:207-234
Abstract
Farnesoid X receptor controls bile acid metabolism, both in the liver and intestine. This potent nuclear receptor not only maintains homeostasis of its own ligands, i.e., bile acids, but also regulates glucose and lipid metabolism as well as the immune system. These findings have led to substantial interest for FXR as a therapeutic target and to the recent approval of an FXR agonist for treating primary biliary cholangitis as well as ongoing clinical trials for other liver diseases. Given that FXR biology is complex, including moderate expression in tissues outside of the enterohepatic circulation, temporal expression of isoforms, posttranscriptional modifications, and the existence of several other bile acid-responsive receptors such as TGR5, clinical application of FXR modulators warrants thorough understanding of its actions. Recent findings have demonstrated remarkable physiological effects of targeting FXR specifically in the intestine (iFXR), thereby avoiding systemic release of modulators. These include local effects such as improvement of intestinal barrier function and intestinal cholesterol turnover, as well as systemic effects such as improvements in glucose homeostasis, insulin sensitivity, and nonalcoholic fatty liver disease (NAFLD). Intriguingly, metabolic improvements have been observed with both an iFXR agonist that leads to production of enteric Fgf15 and increased energy expenditure in adipose tissues and antagonists by reducing systemic ceramide levels and hepatic glucose production. Here we review the recent findings on the role of intestinal FXR and its targeting in metabolic disease.
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4.
Current and upcoming pharmacotherapy for non-alcoholic fatty liver disease.
Rotman, Y, Sanyal, AJ
Gut. 2017;(1):180-190
Abstract
Given the high prevalence and rising incidence of non-alcoholic fatty liver disease (NAFLD), the absence of approved therapies is striking. Although the mainstay of treatment of NAFLD is weight loss, it is hard to maintain, prompting the need for pharmacotherapy as well. A greater understanding of disease pathogenesis in recent years was followed by development of new classes of medications, as well as potential repurposing of currently available agents. NAFLD therapies target four main pathways. The dominant approach is targeting hepatic fat accumulation and the resultant metabolic stress. Medications in this group include peroxisome proliferator-activator receptor agonists (eg, pioglitazone, elafibranor, saroglitazar), medications targeting the bile acid-farnesoid X receptor axis (obeticholic acid), inhibitors of de novo lipogenesis (aramchol, NDI-010976), incretins (liraglutide) and fibroblast growth factor (FGF)-21 or FGF-19 analogues. A second approach is targeting the oxidative stress, inflammation and injury that follow the metabolic stress. Medications from this group include antioxidants (vitamin E), medications with a target in the tumour necrosis factor α pathway (emricasan, pentoxifylline) and immune modulators (amlexanox, cenicriviroc). A third group has a target in the gut, including antiobesity agents such as orlistat or gut microbiome modulators (IMM-124e, faecal microbial transplant, solithromycin). Finally, as the ongoing injury leads to fibrosis, the harbinger of liver-related morbidity and mortality, antifibrotics (simtuzumab and GR-MD-02) will be an important element of therapy. It is very likely that in the next few years several medications will be available to clinicians treating patients with NAFLD across the entire spectrum of disease.
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5.
Cell-Surface and Nuclear Receptors in the Colon as Targets for Bacterial Metabolites and Its Relevance to Colon Health.
Sivaprakasam, S, Bhutia, YD, Ramachandran, S, Ganapathy, V
Nutrients. 2017;(8)
Abstract
The symbiotic co-habitation of bacteria in the host colon is mutually beneficial to both partners. While the host provides the place and food for the bacteria to colonize and live, the bacteria in turn help the host in energy and nutritional homeostasis, development and maturation of the mucosal immune system, and protection against inflammation and carcinogenesis. In this review, we highlight the molecular mediators of the effective communication between the bacteria and the host, focusing on selective metabolites from the bacteria that serve as messengers to the host by acting through selective receptors in the host colon. These bacterial metabolites include the short-chain fatty acids acetate, propionate, and butyrate, the tryptophan degradation products indole-3-aldehyde, indole-3-acetic, acid and indole-3-propionic acid, and derivatives of endogenous bile acids. The targets for these bacterial products in the host include the cell-surface G-protein-coupled receptors GPR41, GPR43, and GPR109A and the nuclear receptors aryl hydrocarbon receptor (AhR), pregnane X receptor (PXR), and farnesoid X receptor (FXR). The chemical communication between these bacterial metabolite messengers and the host targets collectively has the ability to impact metabolism, gene expression, and epigenetics in colonic epithelial cells as well as in mucosal immune cells. The end result, for the most part, is the maintenance of optimal colonic health.
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6.
Investigating the role of nucleotide-binding oligomerization domain-like receptors in bacterial lung infection.
Leissinger, M, Kulkarni, R, Zemans, RL, Downey, GP, Jeyaseelan, S
American journal of respiratory and critical care medicine. 2014;(12):1461-8
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Abstract
Lower respiratory tract infections (LRTIs) are a persistent and pervasive public health problem worldwide. Pneumonia and other LRTIs will be among the leading causes of death in adults, and pneumonia is the single largest cause of death in children. LRTIs are also an important cause of acute lung injury and acute exacerbations of chronic obstructive pulmonary disease. Because innate immunity is the first line of defense against pathogens, understanding the role of innate immunity in the pulmonary system is of paramount importance. Pattern recognition molecules (PRMs) that recognize microbial-associated molecular patterns are an integral component of the innate immune system and are located in both cell membranes and cytosol. Toll-like receptors and nucleotide-binding oligomerization domain-like receptors (NLRs) are the major sensors at the forefront of pathogen recognition. Although Toll-like receptors have been extensively studied in host immunity, NLRs have diverse and important roles in immune and inflammatory responses, ranging from antimicrobial properties to adaptive immune responses. The lung contains NLR-expressing immune cells such as leukocytes and nonimmune cells such as epithelial cells that are in constant and close contact with invading microbes. This pulmonary perspective addresses our current understanding of the structure and function of NLR family members, highlighting advances and gaps in knowledge, with a specific focus on immune responses in the respiratory tract during bacterial infection. Further advances in exploring cellular and molecular responses to bacterial pathogens are critical to develop improved strategies to treat and prevent devastating infectious diseases of the lung.
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7.
Crosstalk and DC-SCRIPT: expanding nuclear receptor modulation.
Ansems, M, Hontelez, S, Karthaus, N, Span, PN, Adema, GJ
Biochimica et biophysica acta. 2010;(2):193-9
Abstract
Nuclear receptors (NR) are intracellular receptors that execute a transcriptional program upon binding to hormones, vitamins and metabolic products. They are key regulators of distinct physiological processes, including growth and differentiation, metabolism, and immunity. The impact of NR activation on a given cell can differ from proliferation induction to programmed cell death. NR malfunction is associated with different diseases, such as diabetes, chronic inflammatory diseases and cancer. Much progress has been made towards understanding the transcriptional regulation by individual NR at the molecular level. However, essentially every cell expresses multiple NR and will encounter complex mixtures of NR ligands during its life cycle. In this review, we will focus on novel insights in balancing NR activity via NR crosstalk and DC-SCRIPT/ZNF366, a bi-functional NR coregulator. The impact on breast cancer development and prognosis will be discussed.
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Vitamin D and the regulation of Wnt/beta-catenin signaling and innate immunity in colorectal cancer.
Byers, S, Shah, S
Nutrition reviews. 2007;(8 Pt 2):S118-20
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9.
Nuclear receptors and autoimmune disease: the potential of PPAR agonists to treat multiple sclerosis.
Racke, MK, Gocke, AR, Muir, M, Diab, A, Drew, PD, Lovett-Racke, AE
The Journal of nutrition. 2006;(3):700-3
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Abstract
Experimental autoimmune encephalomyelitis (EAE) is a T-cell-mediated, autoimmune disorder characterized by central nervous system inflammation and demyelination, features reminiscent of the human disease, multiple sclerosis (MS). Prior work in the EAE model has suggested that encephalitogenic T cells are of the T helper (Th)-1 phenotype. Our group has performed several studies in the EAE model that suggest that a strategy for treating autoimmune disorders is to convert the pathogenic cells from the Th1 to Th2 phenotype. Peroxisome proliferator-activated receptors (PPARs) are members of a nuclear hormone receptor superfamily that include receptors for steroids, retinoids, and thyroid hormone, all of which are known to affect the immune response. Recently, we examined the role of PPARgamma in EAE and observed that administration of the PPARgamma agonist 15-deoxy-Delta(12,14) prostaglandin J2 exerted a significant therapeutic effect predominantly by inhibiting the activation and expansion of encephalitogenic T cells. One potential advantage in studying PPARalpha agonists is that they have been very well tolerated when used in humans to treat conditions such as elevated triglycerides. Building on prior work in immune deviation and with PPAR agonists, we have demonstrated that PPARalpha agonists can alter the cytokine phenotype of myelin-reactive T cells, alter their encephalitogenicity, and be useful in the treatment of EAE. The fact that PPARalpha agonists have been used as therapeutic agents in humans to treat metabolic conditions for over 25 years with little toxicity makes them attractive candidates for use as adjunctive therapies in MS.
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10.
PPARgamma: observations in the hematopoietic system.
Greene, ME, Pitts, J, McCarville, MA, Wang, XS, Newport, JA, Edelstein, C, Lee, F, Ghosh, S, Chu, S
Prostaglandins & other lipid mediators. 2000;(1):45-73
Abstract
Human Peroxisome Proliferator-Activated Receptor gamma (PPARgamma) was originally cloned from a human bone marrow library. What role does this ligand activated transcription factor play in hematopoiesis and the immune system? We note that: a) PPARgamma has potential to interact/interfere or synergize with retinoid biology, b) fatty acids and a prostaglandin have been identified as ligands, and c) lymphocytes, monocytes and neutrophils use fatty acids as a major source of energy production, d) PPARgamma has been shown to oppose TNFalpha and down regulate cytokine production in monocytes. Therefore, we undertook a review of the literature and an expression survey of PPARgamma in a number of major organs and cells involved in the hematopoietic system, for the purpose of building a database towards understanding the role and function of PPARgamma gene regulation in the developing blood and immune systems. PPARgamma is expressed before mesodermal induction in tissue in and around Speymann's organizer in the xenopus blastocyst, in erythroid precursors of blood islands and in the circulation of the day 10.0 murine embryo, in human 19 week fetal liver, in some but not all murine and human bone marrow erythroid, myeloid, and monocytoid progenitors, bone marrow stromal cells and adipocytes, osteoblasts, endothelial cells, some T, and B lymphocytes, monocytes, macrophages, and other monocytic derivatives. It can be found in the cells of Peyer's patches, lymphoid follicles, spleen, and thymus. It is not clear if it is ever or transiently expressed in megakaryocytes, mast cells, or neutrophils. Based on the above data and a review of the literature, PPARgamma seems to play a role during the elicitation of immune responses. We propose PPARgamma may be involved in changes in energy states required during activation and development of many cell types involved, and has additional immunologically relevant effects in erythroid, myeloid, monocytic, T and B lymphocytic, stromal, and endothelial cell function.