Gregory J. Digby scite author profile

Short-chain fatty acids, generated in colon by bacterial fermentation of dietary fiber, protect against colorectal cancer and inflammatory bowel disease. Among these bacterial metabolites, butyrate is biologically most relevant. GPR109A is a G-protein-coupled receptor for nicotinate, but recognizes butyrate with low affinity. Millimolar concentrations of butyrate are needed to activate the receptor. Although concentrations of butyrate in colonic lumen are sufficient to activate the receptor maximally, there have been no reports on the expression/function of GPR109A in this tissue. Here we show that GPR109A is expressed in the lumen-facing apical membrane of colonic and intestinal epithelial cells and that the receptor recognizes butyrate as a ligand. The expression of GPR109A is silenced in colon cancer in humans, in a mouse model of intestinal/colon cancer, and in colon cancer cell lines. The tumor-associated silencing of GPR109A involves DNA methylation directly or indirectly. Re-expression of GPR109A in colon cancer cells induces apoptosis, but only in the presence of its ligands butyrate and nicotinate. Butyrate is an inhibitor of histone deacetylases, but apoptosis induced by activation of GPR109A with its ligands in colon cancer cells does not involve inhibition of histone deacetylation. The primary changes in this apoptotic process include downregulation of Bcl-2, Bcl-xL, and cyclin D1, and upregulation of death receptor pathway. In addition, GPR109A/butyrate suppresses NF-κB activation in normal and cancer colon cell lines as well as in normal mouse colon. These studies show that GPR109A mediates the tumor-suppressive effects of the bacterial fermentation product butyrate in colon.

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G-protein-independent coupling of MC4R to Kir7.1 in hypothalamic neurons

Ghamari‐Langroudi

Digby

Sebag

et al. 2015

Nature

162

171

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The regulated release of anorexigenic α-MSH and orexigenic Agouti-related protein (AgRP) from discrete hypothalamic arcuate neurons onto common target sites in the CNS plays a fundamental role in the regulation of energy homeostasis. Both peptides bind with high affinity to the melanocortin-4 receptor (MC4R); existing data showα-MSH is an agonist that couples the receptor to the Gαs signaling pathway1, while AgRP binds competitively to block α-MSH binding2, and block the constitutive activity mediated by the ligand-mimetic amino terminal domain of the receptor3. Here, we show that regulation of firing activity of hypothalamic PVN neurons by α-MSH and AgRP can be mediated independently of Gαs signaling by ligand-induced coupling of MC4R to closure of inwardly rectifying potassium channel, Kir7.1. Further, AgRP is a biased agonist that hyperpolarizes neurons by binding to MC4R and opening Kir7.1, independently of its inhibition of α-MSH binding. Consequently, Kir7.1 signaling appears central to melanocortin-mediated regulation of energy homeostasis within the PVN. Coupling of MC4R to Kir7.1 may explain unusual aspects of the control of energy homeostasis by melanocortin signaling, including the gene dosage effect of MC4R4, and the sustained effects of AgRP on food intake5.

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The c-terminus of GRK3 indicates rapid dissociation of G protein heterotrimers

Hollins

Kuravi

Digby

et al. 2009

Cellular Signalling

143

167

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Signals mediated by heterotrimeric G proteins often develop over the course of tens of milliseconds, and could require either conformational rearrangement or complete physical dissociation of Gα βγ heterotrimers. Although it is known that some active heterotrimers are dissociated (into Gα and Gβγ) at steady-state, it is not clear that dissociation occurs quickly enough to participate in rapid signaling. Here we show that fusion proteins containing the c-terminus of GPCR kinase 3 (GRK3ct) and either the fluorescent protein cerulean or Renilla luciferase bind to venus-labeled Gβγ dimers (Gβγ-V), resulting in Förster or bioluminescence resonance energy transfer (FRET or BRET). GRK3ct fusion proteins are freely-diffusible, and do not form preassembled complexes with G proteins. GRK3ct fusion proteins bind to free Gβγ-V dimers but not to rearranged heterotrimers, and thus can report G protein dissociation with high temporal resolution. We find that heterotrimer dissociation can occur in living cells in less than 100 milliseconds. Under the conditions of these experiments diffusion and collision of masGRK3ct fusion proteins and Gβγ-V were not rate-limiting. These results indicate that G protein heterotrimers can dissociate quickly enough to participate in rapid signaling.

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Novel Allosteric Agonists of M1 Muscarinic Acetylcholine Receptors Induce Brain Region-Specific Responses That Correspond with Behavioral Effects in Animal Models

Digby

Noetzel²,

Bubser³

et al. 2012

Journal of Neuroscience

104

137

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M1 muscarinic acetylcholine receptors (mAChRs) represent a viable target for treatment of multiple disorders of the central nervous system (CNS) including Alzheimer’s disease and schizophrenia. The recent discovery of highly selective allosteric agonists of M1 receptors has provided a major breakthrough in developing a viable approach for discovery of novel therapeutic agents that target these receptors. Here, we describe the characterization of two novel M1 allosteric agonists VU0357017 and VU0364572 that display profound differences in their efficacy in activating M1 coupling to different signaling pathways including Ca++ and β-arrestin responses. Interestingly, the ability of these agents to differentially activate coupling of M1 to specific signaling pathways leads to selective actions on some but not all M1-mediated responses in brain circuits. These novel M1 allosteric agonists induced robust electrophysiological effects in rat hippocampal slices but showed lower efficacy in striatum and no measureable effects on M1-mediated responses in medial prefrontal cortical pyramidal cells in mice. Consistent with these actions, both M1 agonists enhanced acquisition of hippocampal-dependent cognitive function but did not reverse amphetamine-induced hyperlocomotion in rats. Together, these data reveal that M1 allosteric agonists can differentially regulate coupling of M1 to different signaling pathways and this can dramatically alter the actions of these compounds on specific brain circuits important for learning and memory and psychosis.

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The Melanocortin-4 Receptor Is Expressed in Enteroendocrine L Cells and Regulates the Release of Peptide YY and Glucagon-like Peptide 1 In Vivo

et al. 2014

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SUMMARY The melanocortin-4 receptor (MC4R) is expressed in the brainstem and vagal afferent nerves, and regulates a number of aspects of gastrointestinal function. Here we show that the receptor is also diffusely expressed in cells of the gastrointestinal system, from stomach to descending colon. Furthermore, MC4R is the second most highly expressed GPCR in peptide YY (PYY) and glucagon-like peptide one (GLP-1) expressing enteroendocrine L cells. When vectorial ion transport is measured across mouse or human intestinal mucosa, administration of α-MSH induces a MC4R-specific PYY-dependent anti-secretory response consistent with a role for the MC4R in paracrine inhibition of electrolyte secretion. Finally, MC4R-dependent acute PYY and GLP-1 release from L cells can be stimulated in vivo by intraperitoneal administration of melanocortin peptides to mice. This suggests physiological significance for MC4R in L cells, and indicates a previously unrecognized peripheral role for the MC4R, complementing vagal and central receptor functions.

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Gregory J. Digby

GPR109A Is a G-protein–Coupled Receptor for the Bacterial Fermentation Product Butyrate and Functions as a Tumor Suppressor in Colon

G-protein-independent coupling of MC4R to Kir7.1 in hypothalamic neurons

The c-terminus of GRK3 indicates rapid dissociation of G protein heterotrimers

Novel Allosteric Agonists of M1 Muscarinic Acetylcholine Receptors Induce Brain Region-Specific Responses That Correspond with Behavioral Effects in Animal Models

The Melanocortin-4 Receptor Is Expressed in Enteroendocrine L Cells and Regulates the Release of Peptide YY and Glucagon-like Peptide 1 In Vivo

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