Louise Glover

Crosstalk between Microbiota-Derived Short-Chain Fatty Acids and Intestinal Epithelial HIF Augments Tissue Barrier Function

Interactions between the microbiota and distal gut are fundamental determinants of human health. Such interactions are concentrated at the colonic mucosa and provide energy for the host epithelium through the production of the short-chain fatty acid butyrate. We sought to determine the role of epithelial butyrate metabolism in establishing the austere oxygenation profile of the distal gut. Bacteria-derived butyrate affects epithelial O2 consumption and results in stabilization of hypoxia-inducible factor (HIF), a transcription factor coordinating barrier protection. Antibiotic-mediated depletion of the microbiota reduces colonic butyrate and HIF expression, both of which are restored by butyrate supplementation. Additionally, germ-free mice exhibit diminished retention of O2-sensitive dyes and decreased stabilized HIF. Furthermore, the influences of butyrate are lost in cells lacking HIF, thus linking butyrate metabolism to stabilized HIF and barrier function. This work highlights a mechanism where host-microbe interactions augment barrier function in the distal gut.

Hypoxia-inducible factor-1 alpha–dependent induction of FoxP3 drives regulatory T-cell abundance and function during inflammatory hypoxia of the mucosa

Recent studies have demonstrated dramatic shifts in metabolic supply-and-demand ratios during inflammation, a process resulting in localized tissue hypoxia within inflammatory lesions (“inflammatory hypoxia”). As part of the adaptive immune response, T cells are recruited to sites of inflammatory hypoxia. Given the profound effects of hypoxia on gene regulation, we hypothesized that T-cell differentiation is controlled by hypoxia. To pursue this hypothesis, we analyzed the transcriptional consequences of ambient hypoxia (1% oxygen) on a broad panel of T-cell differentiation factors. Surprisingly, these studies revealed selective, robust induction of FoxP3, a key transcriptional regulator for regulatory T cells (Tregs). Studies of promoter binding or loss- and gain-of-function implicated hypoxia-inducible factor (HIF)-1α in inducing FoxP3. Similarly, hypoxia enhanced Treg abundance in vitro and in vivo. Finally, Treg-intrinsic HIF-1α was required for optimal Treg function and Hif1a–deficient Tregs failed to control T-cell–mediated colitis. These studies demonstrate that hypoxia is an intrinsic molecular cue that promotes FoxP3 expression, in turn eliciting potent anti-inflammatory mechanisms to limit tissue damage in conditions of reduced oxygen availability.

Contribution of Adenosine A2B Receptors to Inflammatory Parameters of Experimental Colitis

Inflammatory diseases influence tissue metabolism, significantly altering the profile of extracellular adenine nucleotides. A number of studies have suggested that adenosine (Ado) may function as an endogenously generated anti-inflammatory molecule. Given the central role of intestinal epithelial cells to the development of colitis, we hypothesized that specific Ado receptors would contribute to disease resolution in mucosal inflammation as modeled by dextran sodium sulfate (DSS) colitis. Initial profiling studies revealed that murine intestinal epithelial cells express predominantly the Ado A2B receptor (AA2BR) and to a lesser extent AA2AR. Guided by these results, we examined the contribution of AA2BR to colitis. Initial studies indicated that the severity of colitis was increased in Aa2br−/− mice relative to Aa2br+/+ controls, as reflected by increased weight loss, colonic shortening, and disease activity indices. Likewise, enteral administration of the selective AA2BR inhibitor PSB1115 to Aa2br+/+ mice resulted in a similar increase in severity of DSS colitis. Cytokine profiling of colonic tissue revealed specific deficiencies in IL-10 in Aa2br−/− mice relative to controls. Extensions of these findings in cultured human intestinal epithelial cells revealed that stable Ado analogs induce IL-10 mRNA and protein and that such increases can be blocked with PSB1115. Taken together, these studies indicate a central regulatory role for AA2BR-modulated IL-10 in the acute inflammatory phase of DSS colitis, thereby implicating AA2BR as an endogenously protective molecule expressed on intestinal epithelial cells.

Dysferlin in Membrane Trafficking and Patch Repair

The muscular dystrophies are a heterogeneous group of inherited disorders, defined by progressive muscle weakness and atrophy. Following the discovery of dystrophin, remarkable progress has been made in defining the molecular properties of proteins involved in the various dystrophies. This has underlined the importance of the dystrophin‐associated protein complex as a cell membrane scaffold, providing structural stability to muscle cells (McNeil PL, Khakee R. Disruptions of muscle fiber plasma membranes. Role in exercise‐induced damage. Am J Pathol 1992;140:1097–1109). While the dystrophies linked to loss of function of dystrophin and its associated proteins are caused by diminished membrane integrity, it is now believed that a new class of dystrophies arises because of a diminished capacity for rapid muscle membrane repair after injury. Dysferlin is the first identified member of a putative muscle‐specific repair complex that permits rapid resealing of membranes disrupted by mechanical stress. Membrane resealing is a function conserved by most cells and is mediated by a mechanism closely resembling regulated, Ca2+‐dependent exocytosis. A primary role for dysferlin in this pathway, as a Ca2+‐regulated fusogen, has been suggested, and a number of candidate partner proteins have been identified. This review outlines the current understanding of the role of dysferlin in membrane repair and the evolving picture of dysferlin‐related signaling pathways in muscle cell physiology and pathology.

Resolvin E1-induced intestinal alkaline phosphatase promotes resolution of inflammation through LPS detoxification

Resolvin-E1 (RvE1) has been demonstrated to promote inflammatory resolution in numerous disease models. Given the importance of epithelial cells to coordination of mucosal inflammation, we hypothesized that RvE1 elicits an epithelial resolution signature. Initial studies revealed that the RvE1-receptor (ChemR23) is expressed on intestinal epithelial cells (IECs) and that microarray profiling of cells exposed to RvE1 revealed regulation of inflammatory response gene expression. Notably, RvE1 induced intestinal alkaline phosphatase (ALPI) expression and significantly enhanced epithelial ALPI enzyme activity. One role recently attributed to ALPI is the detoxification of bacterial LPS. In our studies, RvE1-exposed epithelia detoxified LPS (assessed by attenuation of NF-κB signaling). Furthermore, in epithelial-bacterial interaction assays, we determined that ALPI retarded the growth of Escherichia coli. To define these features in vivo, we used a murine dextran sulfate sodium (DSS) model of colitis. Compared with vehicle controls, administration of RvE1 resulted in significant improvement of disease activity indices (e.g., body weight, colon length) concomitant with increased ALPI expression in the intestinal epithelium. Moreover, inhibition of ALPI activity resulted in increased severity of colitis in DSS-treated animals and partially abrogated the protective influence of RvE1. Together, these data implicate a previously unappreciated role for ALPI in RvE1-mediated inflammatory resolution.

Adenosine A2A receptor is a unique angiogenic target of HIF-2α in pulmonary endothelial cells

Hypoxia, through the hypoxia-inducible transcription factors HIF-1α and HIF-2α (HIFs), induces angiogenesis by up-regulating a common set of angiogenic cytokines. Unlike HIF-1α, which regulates a unique set of genes, most genes regulated by HIF-2α overlap with those induced by HIF-1α. Thus, the unique contribution of HIF-2α remains largely obscure. By using adenoviral mutant HIF-1α and adenoviral mutant HIF-2α constructs, where the HIFs are transcriptionally active under normoxic conditions, we show that HIF-2α but not HIF-1α regulates adenosine A2A receptor in primary cultures of human lung endothelial cells. Further, siRNA knockdown of HIF-2α completely inhibits hypoxic induction of A2A receptor. Promoter studies show a 2.5-fold induction of luciferase activity with HIF-2α cotransfection. Analysis of the A2A receptor gene promoter revealed a hypoxia-responsive element in the region between −704 and −595 upstream of the transcription start site. By using a ChIP assay, we demonstrate that HIF-2α binding to this region is specific. In addition, we demonstrate that A2A receptor has angiogenic potential, as assessed by increases in cell proliferation, cell migration, and tube formation. Additional data show increased expression of A2A receptor in human lung tumor cancer samples relative to adjacent normal lung tissue. These data also demonstrate that A2A receptor is regulated by hypoxia and HIF-2α in human lung endothelial cells but not in mouse-derived endothelial cells.

Hypoxia and Metabolic Factors That Influence Inflammatory Bowel Disease Pathogenesis

The gastrointestinal epithelium is anatomically positioned to provide a selective barrier between the anaerobic lumen and lamina propria, which has a high rate of metabolism. Supported by a complex vasculature, this important barrier is affected by reduced blood flow and resultant tissue hypoxia, particularly during the severe metabolic shifts associated with active inflammation in individuals with inflammatory bowel disease. Activation of hypoxia-inducible factor (HIF) under these conditions promotes resolution of inflammation in mouse models of disease. Protective influences of HIF are attributed, in part, to the complex regulation of barrier protection with the intestinal mucosa. Reagents that activate HIF, via inhibition of the prolyl hydroxylase enzymes, might be developed to induce hypoxia-mediated resolution in patients with intestinal mucosal inflammatory disease.

Selective induction of integrin β1 by hypoxia-inducible factor: implications for wound healing

Because of localized vascular damage and increased tissue oxygen demand, wound healing occurs in a relatively hypoxic microenvironment. These features are particularly relevant to wound healing and fibrosis in chronic inflammatory conditions, such as Crohns disease and ulcerative colitis. In these studies, we sought to identify the contribution of hypoxia to mechanisms of wound repair in a model of the intestinal submucosa. Initial studies revealed that hypoxia promotes wound healing, as modeled by an increase in intestinal fibroblastmediated collagen gel contraction. Guided by results from transcriptional profiling, we identified the selective induction of fibroblast integrin β1 (ITGB1) by hypoxia. Further analysis revealed that hypoxia, as well as pharmacological activators of hypoxia‐inducible factor (HIF), induce fibroblast pi integrin mRNA, protein, and function by as much as 4‐fold. Cloning and analysis of the βi integrin gene promoter revealed a 10 ± 0.8‐fold increase in promoter activity in response to hypoxia, and subsequent studies identified a functional DNA binding region for HIF in the ITGB1 gene promoter. Mutational analysis of the HIF binding site within the ITGB1 promoter resulted in a significant loss of ITGB1 hypoxia‐inducibility. As proof of principle, studies in a murine model of colitis revealed a correlation between colitic disease severity and tissue ITGB1 expression (R2=0.80). Taken together, these results demonstrate that hypoxia induces fibroblast ITGB1 expression and function by transcriptional mechanisms dependent on HIF.— Keely, S., Glover, L. E., MacManus, C. F., Campbell, E. L., Scully, M. M., Furuta, G. T., Colgan, S. P. Selective induction of integrin β1 by hypoxia‐inducible factor: implications for wound healing. FASEBJ. 23, 1338–1346 (2009)

Fundamental role for HIF-1α in constitutive expression of human β defensin-1

Antimicrobial peptides are secreted by the intestinal epithelium to defend from microbial threats. The role of human β defensin-1 (hBD-1) is notable because its gene (beta-defensin 1 (DEFB1)) is constitutively expressed and its antimicrobial activity is potentiated in the low-oxygen environment that characterizes the intestinal mucosa. Hypoxia-inducible factor (HIF) is stabilized even in healthy intestinal mucosa, and we identified that epithelial HIF-1α maintains expression of murine defensins. Extension to a human model revealed that basal HIF-1α is critical for the constitutive expression of hBD-1. Chromatin immunoprecipitation identified HIF-1α binding to a hypoxia response element in the DEFB1 promoter whose importance was confirmed by site-directed mutagenesis. We used 94 human intestinal samples to identify a strong expression correlation between DEFB1 and the canonical HIF-1α target GLUT1. These findings indicate that basal HIF-1α is critical for constitutive expression of enteric DEFB1 and support targeting epithelial HIF for restoration and maintenance of intestinal integrity.

Control of creatine metabolism by HIF is an endogenous mechanism of barrier regulation in colitis

Significance Intestinal epithelial barrier dysregulation is a hallmark of inflammatory bowel diseases (IBDs). A central role for hypoxic signaling has been defined in barrier modulation during inflammation. We demonstrate that genes involved in creatine metabolism, the creatine kinases (CKs), are coordinately regulated by hypoxia-inducible transcription factors (HIFs) and that such regulation is critical to barrier function. Inhibition of the CK pathway abrogates apical junction assembly and barrier integrity. Dietary creatine supplementation profoundly attenuates the pathogenic course of mucosal inflammation in mouse colitis models. Moreover, we demonstrate altered expression of mitochondrial and cytosolic CK enzymes in IBD patient tissue. These findings highlight the fundamental contribution of creatine metabolism to intestinal mucosal function, homeostasis, and disease resolution. Mucosal surfaces of the lower gastrointestinal tract are subject to frequent, pronounced fluctuations in oxygen tension, particularly during inflammation. Adaptive responses to hypoxia are orchestrated largely by the hypoxia-inducible transcription factors (HIFs). As HIF-1α and HIF-2α are coexpressed in mucosal epithelia that constitute the barrier between the lumen and the underlying immune milieu, we sought to define the discrete contribution of HIF-1 and HIF-2 transactivation pathways to intestinal epithelial cell homeostasis. The present study identifies creatine kinases (CKs), key metabolic enzymes for rapid ATP generation via the phosphocreatine–creatine kinase (PCr/CK) system, as a unique gene family that is coordinately regulated by HIF. Cytosolic CKs are expressed in a HIF-2–dependent manner in vitro and localize to apical intestinal epithelial cell adherens junctions, where they are critical for junction assembly and epithelial integrity. Supplementation with dietary creatine markedly ameliorated both disease severity and inflammatory responses in colitis models. Further, enzymes of the PCr/CK metabolic shuttle demonstrate dysregulated mucosal expression in a subset of ulcerative colitis and Crohn disease patients. These findings establish a role for HIF-regulated CK in epithelial homeostasis and reveal a fundamental link between cellular bioenergetics and mucosal barrier.