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2. The epithelial-specific ER stress sensor IRE1β enables host-microbiota crosstalk to affect colon goblet cell development

Author

Jay R. Thiagarajah, Jerrold R. Turner, Michael J. Grey, Irini A. M. Kreulen, Doyle V. Ward, Heidi De Luca, Wayne I. Lencer, Sage E. Foley, and Beth A. McCormick

Subjects
Goblet cell, XBP1, biology, Chemistry, Endoplasmic reticulum, Context (language use), Gut flora, biology.organism_classification, Mucus, Cell biology, medicine.anatomical_structure, Unfolded protein response, medicine, Respiratory system
Abstract

Epithelial cells lining mucosal surfaces of the gastrointestinal and respiratory tracts uniquely express IRE1β (Ern2), a paralogue of the most evolutionarily conserved endoplasmic reticulum stress sensor IRE1α. How IRE1β functions at the host-environment interface and why a second IRE1 paralogue evolved remain incompletely understood. Using conventionally raised and germ-freeErn2-/-mice, we found that IRE1β was required for microbiota-induced goblet cell maturation and mucus barrier assembly in the colon. This occurred only after colonization of the alimentary tract with normal gut microflora, which induced IRE1β expression. IRE1β acted by splicingXbp1mRNA to expand ER function and prevent ER stress in goblet cells. Although IRE1α can also spliceXbp1mRNA, it did not act redundantly to IRE1β in this context. By regulating assembly of the colon mucus layer, IRE1β further shaped the composition of the gut microbiota. Mice lacking IRE1β had a dysbiotic microbial community that failed to induce goblet cell development when transferred into germ-free wild type mice. These results show that IRE1β evolved at mucosal surfaces to mediate crosstalk between gut microbes and the colonic epithelium required for normal homeostasis and host defense.

Published
2021
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3. The epithelial-specific ER stress sensor ERN2/IRE1β enables host-microbiota crosstalk to affect colon goblet cell development

Author

Michael J. Grey, Heidi De Luca, Doyle V. Ward, Irini A.M. Kreulen, Katlynn Bugda Gwilt, Sage E. Foley, Jay R. Thiagarajah, Beth A. McCormick, Jerrold R. Turner, and Wayne I. Lencer

Subjects
Mice, Colon, Microbiota, Endoribonucleases, Animals, Membrane Proteins, General Medicine, Goblet Cells, RNA, Messenger, Intestinal Mucosa, Protein Serine-Threonine Kinases
Abstract

Epithelial cells lining mucosal surfaces of the gastrointestinal and respiratory tracts uniquely express ERN2/IRE1β, a paralogue of the most evolutionarily conserved endoplasmic reticulum stress sensor, ERN1/IRE1α. How ERN2 functions at the host-environment interface and why a second paralogue evolved remain incompletely understood. Using conventionally raised and germ-free Ern2-/- mice, we found that ERN2 was required for microbiota-induced goblet cell maturation and mucus barrier assembly in the colon. This occurred only after colonization of the alimentary tract with normal gut microflora, which induced Ern2 expression. ERN2 acted by splicing Xbp1 mRNA to expand ER function and prevent ER stress in goblet cells. Although ERN1 can also splice Xbp1 mRNA, it did not act redundantly to ERN2 in this context. By regulating assembly of the colon mucus layer, ERN2 further shaped the composition of the gut microbiota. Mice lacking Ern2 had a dysbiotic microbial community that failed to induce goblet cell development and increased susceptibility to colitis when transferred into germ-free WT mice. These results show that ERN2 evolved at mucosal surfaces to mediate crosstalk between gut microbes and the colonic epithelium required for normal homeostasis and host defense.

Published
2021

4. Gut microbiota regulation of P-glycoprotein in the intestinal epithelium in maintenance of homeostasis

Author

Ana Maldonado-Contreras, Beth A. McCormick, Rose L. Szabady, Doyle V. Ward, Sage E. Foley, Randall J. Mrsny, Heidi De Luca, JeanMarie Houghton, Michael J. Grey, Merran Dunford, Christine Tuohy, and Caitlin Cawley

Subjects
Microbiology (medical), ATP Binding Cassette Transporter, Subfamily B, Inflammation, Gut flora, P-glycoprotein, Inflammatory bowel diseases, Microbiology, Microbial ecology, Mice, Short-chain fatty acids, Multi-drug resistance transporter, Intestinal mucosa, medicine, Animals, Homeostasis, Humans, Microbiome, ATP Binding Cassette Transporter, Subfamily B, Member 1, Intestinal epithelium, Intestinal Mucosa, Secondary bile acids, Endocannabinoid, Innate immune system, biology, Research, QR100-130, biology.organism_classification, Cell biology, Gastrointestinal Microbiome, Ulcerative colitis, biology.protein, medicine.symptom
Abstract

BackgroundP-glycoprotein (P-gp) plays a critical role in protection of the intestinal epithelia by mediating efflux of drugs/xenobiotics from the intestinal mucosa into the gut lumen. Recent studies bring to light that P-gp also confers a critical link in communication between intestinal mucosal barrier function and the innate immune system. Yet, despite knowledge for over 10 years that P-gp plays a central role in gastrointestinal homeostasis, the precise molecular mechanism that controls its functional expression and regulation remains unclear. Here, we assessed how the intestinal microbiome drives P-gp expression and function.ResultsWe have identified a “functional core” microbiome of the intestinal gut community, specifically genera within theClostridiaandBacilliclasses, that is necessary and sufficient for P-gp induction in the intestinal epithelium in mouse models. Metagenomic analysis of this core microbial community revealed that short-chain fatty acid and secondary bile acid production positively associate with P-gp expression. We have further shown these two classes of microbiota-derived metabolites synergistically upregulate P-gp expression and function in vitro and in vivo. Moreover, in patients suffering from ulcerative colitis (UC), we find diminished P-gp expression coupled to the reduction of epithelial-derived anti-inflammatory endocannabinoids and luminal content (e.g., microbes or their metabolites) with a reduced capability to induce P-gp expression.ConclusionOverall, by means of both in vitro and in vivo studies as well as human subject sample analysis, we identify a mechanistic link between cooperative functional outputs of the complex microbial community and modulation of P-gp, an epithelial component, that functions to suppress overactive inflammation to maintain intestinal homeostasis. Hence, our data support a new cross-talk paradigm in microbiome regulation of mucosal inflammation.

Published
2021

6. IRE1β negatively regulates IRE1α signaling in response to endoplasmic reticulum stress

Author

Adrienne W. Paton, Yevgeniy V. Serebrenik, Mariska S. Simpson, Eva Cloots, Michael J. Grey, Nicole LeDuc, Sophie Janssens, Wayne I. Lencer, Phi Luong, Sven Eyckerman, James C. Paton, Jay R. Thiagarajah, Delphine De Sutter, Markus A. Seeliger, and Heidi De Luca

Subjects
Models, Molecular, MECHANISM, DOMAINS, XBP1, Protein Homeostasis, IRE1, Protein Serine-Threonine Kinases, Biology, Endoplasmic Reticulum, Biochemistry, Article, ACTIVATION, 03 medical and health sciences, Mediator, 0302 clinical medicine, Cell Signaling, Sequence Analysis, Protein, Stress, Physiological, Endoribonucleases, Medicine and Health Sciences, Humans, Chronic stress, ATF6, 030304 developmental biology, 0303 health sciences, Chemistry, UNFOLDED-PROTEIN-RESPONSE, Endoplasmic reticulum, HEK 293 cells, Membrane Proteins, Cell Biology, ER STRESS, Cell biology, HEK293 Cells, Protein kinase domain, RNA splicing, Proteostasis, Unfolded Protein Response, Unfolded protein response, Phosphorylation, BINDING SITE, Caco-2 Cells, Signal transduction, MESSENGER-RNA, 030217 neurology & neurosurgery, Signal Transduction
Abstract

Grey et al. discover a mechanism by which the epithelial-specific ER stress sensor IRE1β acts as a negative regulator of IRE1α. IRE1β interacts directly with IRE1α to suppress XBP-1 splicing and modify the unfolded protein response to endoplasmic reticulum stress in intestinal epithelial cells., IRE1β is an ER stress sensor uniquely expressed in epithelial cells lining mucosal surfaces. Here, we show that intestinal epithelial cells expressing IRE1β have an attenuated unfolded protein response to ER stress. When modeled in HEK293 cells and with purified protein, IRE1β diminishes expression and inhibits signaling by the closely related stress sensor IRE1α. IRE1β can assemble with and inhibit IRE1α to suppress stress-induced XBP1 splicing, a key mediator of the unfolded protein response. In comparison to IRE1α, IRE1β has relatively weak XBP1 splicing activity, largely explained by a nonconserved amino acid in the kinase domain active site that impairs its phosphorylation and restricts oligomerization. This enables IRE1β to act as a dominant-negative suppressor of IRE1α and affect how barrier epithelial cells manage the response to stress at the host–environment interface.

Published
2020
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8. Intoxication of zebrafish and mammalian cells by cholera toxin depends on the flotillin/reggie proteins but not Derlin-1 or -2

Author

Barry H. Paw, Daniel J.-F. Chinnapen, Jessica Wagner, Himani Chinnapen, David E. Saslowsky, Wayne I. Lencer, Heidi De Luca, Wendy R. Kam, Ramiro Massol, and Jin Ah Cho

Subjects
Cholera Toxin, Endosome, Biological Transport, Active, Endosomes, G(M1) Ganglioside, Biology, medicine.disease_cause, Cell Line, Membrane Microdomains, Chlorocebus aethiops, Genetic model, medicine, Animals, Humans, RNA, Small Interfering, Lipid raft, Zebrafish, Base Sequence, Endoplasmic reticulum, Cholera toxin, Membrane Proteins, General Medicine, Zebrafish Proteins, biology.organism_classification, Molecular biology, Cell biology, Cytosol, Membrane protein, COS Cells, lipids (amino acids, peptides, and proteins), Research Article
Abstract

Cholera toxin (CT) causes the massive secretory diarrhea associated with epidemic cholera. To induce disease, CT enters the cytosol of host cells by co-opting a lipid-based sorting pathway from the plasma membrane, through the trans-Golgi network (TGN), and into the endoplasmic reticulum (ER). In the ER, a portion of the toxin is unfolded and retro- translocated to the cytosol. Here, we established zebrafish as a genetic model of intoxication and examined the Derlin and flotillin proteins, which are thought to be usurped by CT for retro-translocation and lipid sorting, respectively. Using antisense morpholino oligomers and siRNA, we found that depletion of Derlin-1, a component of the Hrd-1 retro-translocation complex, was dispensable for CT-induced toxicity. In contrast, the lipid raft-associated proteins flotillin-1 and -2 were required. We found that in mammalian cells, CT intoxication was dependent on the flotillins for trafficking between plasma membrane/endosomes and two pathways into the ER, only one of which appears to intersect the TGN. These results revise current models for CT intoxication and implicate protein scaffolding of lipid rafts in the endo-somal sorting of the toxin-GM1 complex.

Published
2010
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9. Microtubule motors power plasma membrane tubulation in clathrin-independent endocytosis

Author

Michael W. Davidson, Bing Han, Daniel J.-F. Chinnapen, Nicholas W. Baetz, Anne K. Kenworthy, Charles A. Day, Courtney A. Copeland, Randall K. Holmes, Kimberly R. Drake, Trina A. Schroer, Heidi De Luca, Lewis J. Kraft, Michael G. Jobling, Ajit Tiwari, and Wayne I. Lencer

Subjects
Cholera Toxin, Biology, Endocytosis, medicine.disease_cause, Biochemistry, Microtubules, Exocytosis, Cell membrane, Plasma membrane tubulation, 03 medical and health sciences, 0302 clinical medicine, Structural Biology, dynactin, Chlorocebus aethiops, Receptors, Transferrin, Genetics, medicine, Animals, Humans, Molecular Biology, 030304 developmental biology, 0303 health sciences, dynein, Cholera toxin, Cell Membrane, Dyneins, Cell Biology, Receptor-mediated endocytosis, Original Articles, clathrin-independent endocytosis, Clathrin, Cell biology, medicine.anatomical_structure, Membrane curvature, COS Cells, membrane curvature, Dynactin, 030217 neurology & neurosurgery, HeLa Cells, Protein Binding
Abstract

How the plasma membrane is bent to accommodate clathrin-independent endocytosis remains uncertain. Recent studies suggest Shiga and cholera toxin induce membrane curvature required for their uptake into clathrin-independent carriers by binding and cross-linking multiple copies of their glycosphingolipid receptors on the plasma membrane. But it remains unclear if toxin-induced sphingolipid crosslinking provides sufficient mechanical force for deforming the plasma membrane, or if host cell factors also contribute to this process. To test this, we imaged the uptake of cholera toxin B-subunit into surface-derived tubular invaginations. We found that cholera toxin mutants that bind to only one glycosphingolipid receptor accumulated in tubules, and that toxin binding was entirely dispensable for membrane tubulations to form. Unexpectedly, the driving force for tubule extension was supplied by the combination of microtubules, dynein and dynactin, thus defining a novel mechanism for generating membrane curvature during clathrin-independent endocytosis.

Published
2015

11. A Biochemical Method for Tracking Cholera Toxin Transport From Plasma Membrane to Golgi and Endoplasmic Reticulum

Author

Heidi De Luca and Wayne I. Lencer

Subjects
Toxin, Endoplasmic reticulum, Cholera toxin, Golgi apparatus, Asiatic cholera, medicine.disease_cause, Cell biology, Adenylyl cyclase, symbols.namesake, chemistry.chemical_compound, Cytosol, chemistry, event.disaster, symbols, medicine, event, Secretory pathway
Abstract

Asiatic cholera is a rapidly progressing disease resulting in extreme diarrhea and even death. The causative agent, cholera toxin, is an AB5-subunit enterotoxin produced by the bacterium Vibrio cholera. The toxin must enter the intestinal cell to cause disease. Entry is achieved by the B-subunit binding to a membrane lipid that carries the toxin all the way from the plasma membrane through the trans-Golgi to the endoplasmic reticulum (ER). Once in the ER, a portion of the A-subunit, the A1 chain, unfolds and separates from the B-subunit to retro-translocate to the cytosol. The A1 chain then activates adenylyl cyclase to cause disease. To study this pathway in intact cells, we used a mutant toxin with C-terminal extension of the B-subunit that contains N-glycosylation and tyrosine-sulfation motifs (CT-GS). This provides a biochemical readout for toxin entry into the trans Golgi (by 35S-sulfation) and ER (by N-glycosylation). In this chapter, we describe the methods we developed to study this trafficking pathway.

Published
2006
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12. Role of p97 AAA-ATPase in the retrotranslocation of the cholera toxin A1 chain, a non-ubiquitinated substrate

Author

Jessica Wagner, Michael Kothe, Heidi De Luca, Wayne I. Lencer, Eli Kern, Tom A. Rapoport, and Yihong Ye

Subjects
Cholera Toxin, Protein Folding, Time Factors, Mutant, Genes, MHC Class I, Astrocytoma, medicine.disease_cause, Endoplasmic Reticulum, Biochemistry, Adenoviridae, Cytosol, Ubiquitin, Cell Line, Tumor, medicine, Cyclic AMP, Animals, Humans, Immunoprecipitation, Molecular Biology, Genes, Dominant, Adenosine Triphosphatases, biology, Dose-Response Relationship, Drug, Toxin, Endoplasmic reticulum, Cholera toxin, Nuclear Proteins, Cell Biology, AAA proteins, Electrophysiology, Protein Transport, ADP-ribosylation, COS Cells, Mutation, biology.protein, Protein Binding
Abstract

The enzymatic A1 chain of cholera toxin retrotranslocates across the endoplasmic reticulum membrane into the cytosol, where it induces toxicity. Almost all other retrotranslocation substrates are modified by the attachment of polyubiquitin chains and moved into the cytosol by the ubiquitin-interacting p97 ATPase complex. The cholera toxin A1 chain, however, can induce toxicity in the absence of ubiquitination, and the motive force that drives retrotranslocation is not known. Here, we use adenovirus expressing dominant-negative mutants of p97 to test whether p97 is required for toxin action. We find that cholera toxin still functions with only a small decrease in potency in cells that cannot retrotranslocate other substrates at all. These results suggest that p97 does not provide the primary driving force for extracting the A1 chain from the endoplasmic reticulum, a finding that is consistent with a requirement for polyubiquitination in p97 function.

Published
2005

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