Lysophosphatidic Acid Increases Maturation of Brush Borders and SGLT1 activity in MYO5B-deficient Mice, a Model of Microvillus Inclusion Disease.

BACKGROUND & AIM Myosin VB (MYO5B) is an essential trafficking protein for membrane recycling in gastrointestinal epithelial cells. The inactivating mutations of MYO5B cause the congenital diarrheal disease, microvillus inclusion disease (MVID). MYO5B deficiency in mice causes mislocalization of SGLT1 and NHE3, but retained apical function of CFTR, resulting in malabsorption and secretory diarrhea. Activation of lysophosphatidic acid (LPA) receptors can improve diarrhea, but the effect of LPA on MVID symptoms is unclear. We investigated whether LPA administration can reduce the epithelial deficits in MYO5B-knockout mice. METHODS Studies were conducted with tamoxifen-induced, intestine-specific knockout of MYO5B (VilCreERT2;Myo5bflox/flox) and littermate controls. Mice were given LPA, an LPAR2 agonist (GRI977143), or vehicle for 4 days after a single injection of tamoxifen. Apical SGLT1 and CFTR activities were measured in Üssing chambers. Intestinal tissues were collected, and localization of membrane transporters was evaluated by immunofluorescence analysis in tissue sections and enteroids. RNA sequencing and enrichment analysis were performed with isolated jejunal epithelial cells. RESULTS Daily administration of LPA reduced villus blunting, frequency of multivesicular bodies and levels of cathepsins in intestinal tissues of MYO5B-knockout mice compared to vehicle administration. LPA partially restored the brush border height and the localization of SGLT1 and NHE3 in small intestine of MYO5B-knockout mice and enteroids. The SGLT1-dependent short-circuit current was increased and abnormal CFTR activities were decreased in jejunum from MYO5B-knockout mice given LPA compared with vehicle. CONCLUSIONS LPA may regulate a MYO5B-independent trafficking mechanism and brush border maturation, and therefore be developed for treatment of MVID.

[1]  Hyun-Cheol Lee,et al.  Intracellular sensing of viral genomes and viral evasion , 2019, Experimental & Molecular Medicine.

[2]  M. Maurice,et al.  Wnt Signaling in 3D: Recent Advances in the Applications of Intestinal Organoids. , 2019, Trends in cell biology.

[3]  Fred A. Hamprecht,et al.  ilastik: interactive machine learning for (bio)image analysis , 2019, Nature Methods.

[4]  Adam L. Haber,et al.  Ketone Body Signaling Mediates Intestinal Stem Cell Homeostasis and Adaptation to Diet , 2019, Cell.

[5]  Min Goo Lee,et al.  Anoctamin 1/TMEM16A controls intestinal Cl− secretion induced by carbachol and cholera toxin , 2019, Experimental & Molecular Medicine.

[6]  T. Matozaki,et al.  Role of lysophosphatidic acid in proliferation and differentiation of intestinal epithelial cells , 2019, PloS one.

[7]  L. Johnson,et al.  Lysophosphatidic acid type 2 receptor agonists in targeted drug development offer broad therapeutic potential , 2019, Journal of Lipid Research.

[8]  H. Koepsell,et al.  Loss of MYO5B Leads to Reductions in Na+ Absorption With Maintenance of CFTR-Dependent Cl- Secretion in Enterocytes. , 2018, Gastroenterology.

[9]  Anushya Muruganujan,et al.  PANTHER version 14: more genomes, a new PANTHER GO-slim and improvements in enrichment analysis tools , 2018, Nucleic Acids Res..

[10]  C. Yun,et al.  Expression of lysophosphatidic acid receptor 5 is necessary for the regulation of intestinal Na+/H+ exchanger 3 by lysophosphatidic acid in vivo. , 2018, American journal of physiology. Gastrointestinal and liver physiology.

[11]  Mark A. Miller,et al.  Prevention and treatment of secretory diarrhea by the lysophosphatidic acid analog Rx100 , 2018, Experimental biology and medicine.

[12]  M. Drumm,et al.  A G542X cystic fibrosis mouse model for examining nonsense mutation directed therapies , 2018, PloS one.

[13]  Joseph T. Roland,et al.  Advances in Evaluation of Chronic Diarrhea in Infants. , 2018, Gastroenterology.

[14]  Yarden Katz,et al.  A single-cell survey of the small intestinal epithelium , 2017, Nature.

[15]  Joseph T. Roland,et al.  Abnormal Rab11‐Rab8‐vesicles cluster in enterocytes of patients with microvillus inclusion disease , 2017, Traffic.

[16]  A. Verkman,et al.  Benzopyrimido‐pyrrolo‐oxazine‐dione CFTR inhibitor (R)‐BPO‐27 for antisecretory therapy of diarrheas caused by bacterial enterotoxins , 2017, FASEB journal : official publication of the Federation of American Societies for Experimental Biology.

[17]  Masahiko Watanabe,et al.  Neural FFA3 activation inversely regulates anion secretion evoked by nicotinic ACh receptor activation in rat proximal colon , 2016, The Journal of physiology.

[18]  David S. Wishart,et al.  Heatmapper: web-enabled heat mapping for all , 2016, Nucleic Acids Res..

[19]  Byung-Hwan Lee,et al.  Plant Lysophosphatidic Acids: A Rich Source for Bioactive Lysophosphatidic Acids and Their Pharmacological Applications. , 2016, Biological & pharmaceutical bulletin.

[20]  Joseph T. Roland,et al.  Loss of MYO5B in Mice Recapitulates Microvillus Inclusion Disease and Reveals an Apical Trafficking Pathway Distinct to Neonatal Duodenum , 2015, Cellular and molecular gastroenterology and hepatology.

[21]  Min Goo Lee,et al.  Benzopyrimido-pyrrolo-oxazine-dione (R)-BPO-27 Inhibits CFTR Chloride Channel Gating by Competition with ATP , 2015, Molecular Pharmacology.

[22]  H. Clevers,et al.  An inducible mouse model for microvillus inclusion disease reveals a role for myosin Vb in apical and basolateral trafficking , 2015, Proceedings of the National Academy of Sciences.

[23]  J. Aoki,et al.  Lysophosphatidic acid as a lipid mediator with multiple biological actions. , 2015, Journal of biochemistry.

[24]  Toshiro Sato,et al.  Establishment of Gastrointestinal Epithelial Organoids , 2013, Current protocols in mouse biology.

[25]  A. Tokumura,et al.  Orally Administered Phosphatidic Acids and Lysophosphatidic Acids Ameliorate Aspirin-Induced Stomach Mucosal Injury in Mice , 2013, Digestive Diseases and Sciences.

[26]  S. Tsukita,et al.  Loss of claudins 2 and 15 from mice causes defects in paracellular Na+ flow and nutrient transport in gut and leads to death from malnutrition. , 2013, Gastroenterology.

[27]  H. Parker,et al.  Na+-d-glucose Cotransporter SGLT1 is Pivotal for Intestinal Glucose Absorption and Glucose-Dependent Incretin Secretion , 2011, Diabetes.

[28]  I. Kaji,et al.  Effects of luminal thymol on epithelial transport in human and rat colon. , 2011, American journal of physiology. Gastrointestinal and liver physiology.

[29]  T. Noda,et al.  Loss of claudin-15, but not claudin-2, causes Na+ deficiency and glucose malabsorption in mouse small intestine. , 2011, Gastroenterology.

[30]  H. Daniel,et al.  Gene ablation for PEPT1 in mice abolishes the effects of dipeptides on small intestinal fluid absorption, short-circuit current, and intracellular pH. , 2010, American journal of physiology. Gastrointestinal and liver physiology.

[31]  J. Chun,et al.  Lysophosphatidic acid stimulates the intestinal brush border Na(+)/H(+) exchanger 3 and fluid absorption via LPA(5) and NHERF2. , 2010, Gastroenterology.

[32]  W. Alrefai,et al.  Mechanisms of lysophosphatidic acid (LPA) mediated stimulation of intestinal apical Cl-/OH- exchange. , 2010, American journal of physiology. Gastrointestinal and liver physiology.

[33]  Kyoko Noguchi,et al.  LPA receptors: subtypes and biological actions. , 2010, Annual review of pharmacology and toxicology.

[34]  Brian P Ceresa,et al.  Rab7 Regulates Late Endocytic Trafficking Downstream of Multivesicular Body Biogenesis and Cargo Sequestration* , 2009, Journal of Biological Chemistry.

[35]  M. Donowitz,et al.  Differential roles of NHERF1, NHERF2, and PDZK1 in regulating CFTR-mediated intestinal anion secretion in mice. , 2009, The Journal of clinical investigation.

[36]  J. R. Bronk,et al.  An energy supply network of nutrient absorption coordinated by calcium and T1R taste receptors in rat small intestine , 2009, The Journal of physiology.

[37]  R. Erickson,et al.  Navajo microvillous inclusion disease is due to a mutation in MYO5B , 2008, American journal of medical genetics. Part A.

[38]  Anne E Carpenter,et al.  CellProfiler Analyst: data exploration and analysis software for complex image-based screens , 2008, BMC Bioinformatics.

[39]  L. Huber,et al.  MYO5B mutations cause microvillus inclusion disease and disrupt epithelial cell polarity , 2008, Nature Genetics.

[40]  B. Williams,et al.  Mapping and quantifying mammalian transcriptomes by RNA-Seq , 2008, Nature Methods.

[41]  Scott D Emr,et al.  The ESCRT complexes: structure and mechanism of a membrane-trafficking network. , 2006, Annual review of biophysics and biomolecular structure.

[42]  Masahiko Watanabe,et al.  Cellular distribution of glutamate transporters in the gastrointestinal tract of mice: an immunohistochemical and in situ hybridization approach. , 2005, Biomedical research.

[43]  Y. Fujiwara,et al.  Lysophosphatidic acid inhibits cholera toxin-induced secretory diarrhea through CFTR-dependent protein interactions , 2005, The Journal of experimental medicine.

[44]  J. Aoki Mechanisms of lysophosphatidic acid production. , 2004, Seminars in cell & developmental biology.

[45]  P. Saftig,et al.  Role for Rab7 in maturation of late autophagic vacuoles , 2004, Journal of Cell Science.

[46]  Thomas Zeuthen,et al.  Water pumps , 2002, The Journal of physiology.

[47]  Duane D. Miller,et al.  Direct quantitative analysis of lysophosphatidic acid molecular species by stable isotope dilution electrospray ionization liquid chromatography-mass spectrometry. , 2001, Analytical biochemistry.

[48]  D. Alpers Is glutamine a unique fuel for small intestinal cells? , 2000, Current opinion in gastroenterology.

[49]  H. Rossmann,et al.  A functional CFTR protein is required for mouse intestinal cAMP‐, cGMP‐ and Ca2+‐dependent HCO3− secretion , 1997, The Journal of physiology.

[50]  E. Wright,et al.  Defects in Na+/glucose cotransporter (SGLT1) trafficking and function cause glucose-galactose malabsorption , 1996, Nature Genetics.

[51]  A. Verkman,et al.  Translating molecular physiology of intestinal transport into pharmacologic treatment of diarrhea: stimulation of Na+ absorption. , 2014, Clinical gastroenterology and hepatology : the official clinical practice journal of the American Gastroenterological Association.

[52]  R. Jakab,et al.  Physiological relevance of cell-specific distribution patterns of CFTR, NKCC1, NBCe1, and NHE3 along the crypt-villus axis in the intestine. , 2011, American journal of physiology. Gastrointestinal and liver physiology.