MYO5B Mutations Research Articles

Alterations in cellular metabolic pathway and epithelial cell maturation induced by MYO5B defects are partially reversible by LPAR5 activation.

Functional loss of the motor protein, Myosin Vb (MYO5B), induces various defects in intestinal epithelial function and causes a congenital diarrheal disorder, microvillus inclusion disease (MVID). Utilizing the MVID model mice, Vil1-CreERT2;Myo5bflox/flox (MYO5B∆IEC) and Vil1-CreERT2;Myo5bflox/G519R (MYO5B(G519R)), we previously reported that functional MYO5B loss disrupts progenitor cell differentiation and enterocyte maturation that result in villus blunting and deadly malabsorption symptoms. In this study, we determined that both absence and a point mutation of MYO5B impair lipid metabolism and alter mitochondrial structure, which may underlie the progenitor cell malfunction observed in MVID intestine. Along with a decrease in fatty acid oxidation, the lipogenesis pathway was enhanced in the MYO5B∆IEC small intestine. Consistent with these observations in vivo, RNA-sequencing of enteroids generated from the two MVID mouse strains showed similar downregulation of energy metabolic enzymes, including mitochondrial oxidative phosphorylation genes. In our previous studies, lysophosphatidic acid (LPA) signaling ameliorates epithelial cell defects in MYO5B∆IEC tissues and enteroids. The present study demonstrated that the highly soluble LPAR5-preferred agonist, Compound-1, improved sodium transporter localization and absorptive function, and tuft cell differentiation in patient-modeled MVID animals that carry independent mutations in MYO5B. Body weight loss in male MYO5B(G519R) mice was ameliorated by Compound-1. These observations suggest that Compound-1 treatment has a trophic effect on intestine with MYO5B functional loss through epithelial cell-autonomous pathways that can accelerate the differentiation of progenitor cells and the maturation of enterocytes. Targeting LPAR5 may represent an effective therapeutic approach for treatment of MVID symptoms induced by different point mutations in MYO5B.

Myosin Vb Traffics P-glycoprotein to the Apical Membrane of Intestinal Epithelial Cells

The xenobiotic efflux pump P-glycoprotein is highly expressed on the apical membrane of the gastrointestinal tract, where it regulates the levels of intracellular substrates. P-glycoprotein is altered in disease, but the mechanisms that regulate the levels of P-glycoprotein are still being explored. The molecular motor myosin Vb (Myo5b) traffics diverse cargo to the apical membrane of intestinal epithelial cells. We hypothesized that Myo5b was responsible for the delivery of P-glycoprotein to the apical membrane of enterocytes. We used multiple murine models that lack functional Myo5b or the myosin binding partner Rab11a to analyze P-glycoprotein localization. Pig and human tissue were analyzed to determine P-glycoprotein localization in the setting of MYO5B mutations. Intestinal organoids were used to examine P-glycoprotein trafficking and to assay P-glycoprotein function when MYO5 is inhibited. In mice lacking Myo5b or the binding partner Rab11a, P-glycoprotein was improperly trafficked and had decreased presence in the brush border of enterocytes. Immunostaining of a pig model lacking functional Myo5b and human biopsies from a patient with an inactivating mutation in Myo5b also showed altered localization of intestinal P-glycoprotein. Human intestinal organoids expressing the motorless MYO5B tail domain had colocalization with P-glycoprotein, confirming that P-glycoprotein was trafficked by MYO5B in human enterocytes. Inhibition of MYO5 in human intestinal cell lines and organoids resulted in decreased P-glycoprotein capacity. Additionally, inhibition of MYO5 in human colon cancer cells diminished P-glycoprotein activity and increased cell death in response to a chemotherapeutic drug. Collectively, these data demonstrate that Myo5b is necessary for the apical delivery of P-glycoprotein.

A286 MYO5B MUTATIONS AS A CAUSE OF CHOLESTASIS IN A CHILD WITHOUT MICROVILLOUS INCLUSION DISEASE

Abstract Background Biallelic Myosin Vb (MYO5B) mutations are identified in the majority of patients with microvillus inclusion disease (MVID) that requires life-long parenteral nutrition and eventually cholestatic liver disease. Biallelic MYO5B mutations have also been reported in a few children with predominant early-onset cholestatic liver disease. Aims To report on a patient with MYO5B mutations and progressive familial intrahepatic cholestasis PFIC-like phenotype and normal serum GGT without intestinal disease. Methods We describe a 2-year and 8-month-old girl, who is the first child of healthy non- consanguineous parents from the Phillipines with no family history of liver disease. She presented at the age of 10 months for evaluation of mild jaundice, which was noticed at the age of 6 months. Other symptoms included pruritus, slowly weight gain, intermittent pale stools and dark urine. Laboratory investigations revealed AST 99, ALT 87, GGT 27, conjugated bilirubin 13 and INR 0.8. Fasting abdominal ultrasound was normal apart from a possibly hypoplastic gallbladder and mild splenomegaly. Additional investigations revealed normal thyroid-stimulating hormone, cortisol, galactosemia screening and sweat chloride, but bile acids were elevated 391.6 umol/L. A liver biopsy was performed and a cholestasis genetic panel sent. The patient was started on ursodiol, hydroxyzine, rifampicin and vitamin D. Results Liver biopsy revealed moderate hepato-canalicular cholestasis, bile duct injury without prominent ductopenia, small caliber bile ducts with no features of obstructive cholangiopathy, mild periportal and pericentral fibrosis stage 1-2/ 4. Electron microscopy demonstrated cytoplasmic and canalicular bile accumulation. The bile canaliculi were variably distended by coarse granular bile. Immunohistochemical staining for BSEP and MDR3, showed canalicular staining in zones 1 and absence of staining in zones 2 and 3. Genetic analysis revealed one pathogenic variant and one variant of uncertain significance in MYO5B. No mutations in ABCB11 or ATP8B1 genes were identified. On follow-up, the jaundice improved, pruritus was managed with the medications described above. Her growth has improved and she is growing on the 25th centiles. She has not developed any gastrointestinal symptoms. Conclusions We present a patient with MYO5B mutations who presented with normal GGT cholestasis and a liver biopsy consistent with PFIC, without any evidence of intestinal disease. Because MYO5B mutations disrupt the intracellular trafficking of brush border proteins in the intestine, it has been assumed that it similarly disrupts the trafficking of the canalicular bile acid transporting and bilirubin transporting proteins in the liver. This case highlights the broad phenotype associated with MYO5B variants. Funding Agencies None

THU-336 - Odevixibat therapy in patients with MYO5B mutations: a retrospective case series

THU-336 - Odevixibat therapy in patients with MYO5B mutations: a retrospective case series

Modeling of a Novel Patient-Based MYO5B Point Mutation Reveals Insights Into MVID Pathogenesis

Modeling of a Novel Patient-Based MYO5B Point Mutation Reveals Insights Into MVID Pathogenesis

MYO5B Gene Mutations: A Not Negligible Cause of Intrahepatic Cholestasis of Infancy With Normal Gamma-Glutamyl Transferase Phenotype.

Progressive familial intrahepatic cholestasis is an expanding group of autosomal recessive intrahepatic cholestatic disorders. Recently, next-generation sequencing allowed identifying new genes responsible for new specific disorders. Two biochemical phenotypes have been identified according to gamma-glutamyltransferase (GGT) activity. Mutations of the myosin 5B gene (MYO5B) are known to cause microvillus inclusion disease. Recently, different mutations in MYO5B gene have been reported in patients with low-GGT cholestasis. A multicenter retrospective and prospective study was conducted in 32 children with cryptogenic intrahepatic cholestasis. Clinical, biochemical, histological, and treatment data were analyzed in these patients. DNA from peripheral blood was extracted, and all patients were studied by whole exome sequencing followed by Sanger sequencing. Six patients out of 32 had mutations in the MYO5B gene. Of these six patients, the median age at disease onset was 0.8 years, and the median length of follow-up was 4.2 years. The most common signs were pruritus, poor growth, hepatomegaly, jaundice, and hypocholic stools. Two patients also showed intestinal involvement. Transaminases and conjugated bilirubin were moderately increased, serum bile acids elevated, and GGT persistently normal. At anti-Myo5B immunostaining, performed in liver biopsy of two patients, coarse granules were evident within the cytoplasm of hepatocytes while bile salt export pump was normally expressed at the canalicular membrane. Six variants in homozygosity or compound heterozygosity in the MYO5B gene were identified, and three of them have never been described before. All nucleotide alterations were located on the myosin motor domain except one missense variant found in the isoleucine-glutamine calmodulin-binding motif. We identified causative mutations in MYO5B in 18.7% of a selected cohort of patients with intrahepatic cholestasis confirming a relevant role for the MYO5B gene in low-GGT cholestasis.

A Functional Relationship Between UNC45A and MYO5B Connects Two Rare Diseases With Shared Enteropathy.

Background & AimsUNC45A is a myosin (co-)chaperone, and mutations in the UNC45A gene were recently identified in osteo-oto-hepato-enteric (O2HE) syndrome patients presenting with congenital diarrhea and intrahepatic cholestasis. Congenital diarrhea and intrahepatic cholestasis are also the prime symptoms in patients with microvillus inclusion disease (MVID) and mutations in MYO5B, encoding the recycling endosome–associated myosin Vb. The aim of this study was to determine whether UNC45A and myosin Vb are functionally linked.MethodsCRISPR-Cas9 gene editing and site-directed mutagenesis were performed with intestinal epithelial and hepatocellular cell lines, followed by Western blotting, quantitative polymerase chain reaction, and scanning electron and/or confocal fluorescence microscopy to determine the relationship between (mutants of) UNC45A and myosin Vb.ResultsUNC45A depletion in intestinal and hepatic cells reduced myosin Vb protein expression, and in intestinal epithelial cells, it affected 2 myosin Vb-dependent processes that underlie MVID pathogenesis: rat sarcoma-associated binding protein (RAB)11A-positve recycling endosome positioning and microvilli development. Reintroduction of UNC45A in UNC45A-depleted cells restored myosin Vb expression, and reintroduction of UNC45A or myosin Vb, but not the O2HE patient UNC45A-c.1268T>A variant, restored recycling endosome positioning and microvilli development. The O2HE patient-associated p.V423D substitution, encoded by the UNC45A-c.1268T>A variant, impaired UNC45A protein stability but as such not the ability of UNC45A to promote myosin Vb expression and microvilli development.ConclusionsA functional relationship exists between UNC45A and myosin Vb, thereby connecting 2 rare congenital diseases with overlapping enteropathy at the molecular level. Protein instability rather than functional impairment underlies the pathogenicity of the O2HE syndrome–associated UNC45A-p.V423D mutation.

Novel MYO5B mutation in microvillous inclusion disease of Syrian ancestry.

Microvillus inclusion disease (MVID) is a rare autosomal recessive condition characterized by a lack of microvilli on the surface of enterocytes, resulting in severe, life-threatening diarrhea that could lead to mortality within the first year of life. We identify two unrelated families, each with one child presenting with severe MVID from birth. Using trio whole-exome sequencing, we observed that the two families share a novel nonsense variant (Glu1589*) in the MYO5B gene, a type Vb myosin motor protein in which rare damaging mutations were previously described to cause MVID. This founder mutation was very rare in public databases and is likely specific to patients of Syrian ancestry. We present a detailed account of both patients’ clinical histories to fully characterize the effect of this variant and expand the genotype–phenotype databases for MVID patients from the Middle East.

Genetic Disorders of Bile Acid Transport.

Genetic Disorders of Bile Acid Transport.

Advanced Microscopy for Liver and Gut Ultrastructural Pathology in Patients with MVID and PFIC Caused by MYO5B Mutations.

Mutations in the actin motor protein myosinVb (myo5b) cause aberrant apical cargo transport and the congenital enteropathy microvillus inclusion disease (MVID). Recently, missense mutations in myo5b were also associated with progressive familial intrahepatic cholestasis (MYO5B-PFIC). Here, we thoroughly characterized the ultrastructural and immuno-cytochemical phenotype of hepatocytes and duodenal enterocytes from a unique case of an adult MYO5B-PFIC patient who showed constant hepatopathy but only periodic enteric symptoms. Selected data from two other patients supported the findings. Advanced methods such as cryo-fixation, freeze-substitution, immuno-gold labeling, electron tomography and immuno-fluorescence microscopy complemented the standard procedures. Liver biopsies showed mislocalization of Rab11 and bile canalicular membrane proteins. Rab11-positive vesicles clustered around bile canaliculi and resembled subapical clusters of aberrant recycling endosomes in enterocytes from MVID patients. The adult patient studied in detail showed a severe, MVID-specific enterocyte phenotype, despite only a mild clinical intestinal presentation. This included mislocalization of numerous proteins essential for apical cargo transport and morphological alterations. We characterized the heterogeneous population of large catabolic organelles regarding their complex ultrastructure and differential distribution of autophagic and lysosomal marker proteins. Finally, we generated duodenal organoids/enteroids from biopsies that recapitulated all MVID hallmarks, demonstrating the potential of this disease model for personalized medicine.

Congenital Diarrhea and Cholestatic Liver Disease: Phenotypic Spectrum Associated with MYO5B Mutations.

Myosin Vb (MYO5B) is a motor protein that facilitates protein trafficking and recycling in polarized cells by RAB11- and RAB8-dependent mechanisms. Biallelic MYO5B mutations are identified in the majority of patients with microvillus inclusion disease (MVID). MVID is an intractable diarrhea of infantile onset with characteristic histopathologic findings that requires life-long parenteral nutrition or intestinal transplantation. A large number of such patients eventually develop cholestatic liver disease. Bi-allelic MYO5B mutations are also identified in a subset of patients with predominant early-onset cholestatic liver disease. We present here the compilation of 114 patients with disease-causing MYO5B genotypes, including 44 novel patients as well as 35 novel MYO5B mutations, and an analysis of MYO5B mutations with regard to functional consequences. Our data support the concept that (1) a complete lack of MYO5B protein or early MYO5B truncation causes predominant intestinal disease (MYO5B-MVID), (2) the expression of full-length mutant MYO5B proteins with residual function causes predominant cholestatic liver disease (MYO5B-PFIC), and (3) the expression of mutant MYO5B proteins without residual function causes both intestinal and hepatic disease (MYO5B-MIXED). Genotype-phenotype data are deposited in the existing open MYO5B database in order to improve disease diagnosis, prognosis, and genetic counseling.

Genetic Enteropathies Linked to Epithelial Structural Abnormalities and Enteroendocrine Deficiency: A Systematic Review.

Congenital diarrhea and enteropathies linked to epithelial structural abnormalities constitute 3 different rare diseases: the tufting enteropathies (TE; EPCAM and SPINT2 mutations), microvillous inclusion disease (MVID; MYO5B and STX3 mutations), and tricho-hepato-enteric syndrome (THE; TTC37 and SKIV2L mutations). Moreover, enteroendocrine deficiencies (ED; PCSK1 and NEUROG3 mutations) share common clinical characteristics with TE, THE, and MVID in that the treatment requires, in most cases, long-term parenteral nutrition. Although numerous cases have been reported in the literature, aggregated data on morbidity and mortality are missing owing to the rarity of the diseases. We performed a systematic review of all published cases and retrieved 86 articles describing 323 patients (164 boys and 135 girls). The mortality rate was 20.28%, with a median age at death of 13.5 months (range 0-228 months); the mortality risk was 30.8/1000 person-year; in half of the cases, death was caused by infections. Parenteral nutrition was required in 95.4% of patients and weaning off from parenteral nutrition was achieved in 29.35% at a median age of 23 months (range 3.3-276 months). The patients with ED linked to PCSK1 were nearly all weaned at a median age of 14 months, but most of the patients became overweight. MVID patients with MYO5B mutations were most often born preterm. ED linked to NEUROG3 mutation and THE patients usually presented with intrauterine growth retardation. This review presents data from 323 patients with congenital diarrhea linked to EPCAM TE, SPINT2 TE, TTC37 THE, SKIV2L THE, MYO5B MVID, STX3 MVID, NEUROG3 ED, and PCSK1 ED mutations.

Recruitment of Polarity Complexes and Tight Junction Proteins to the Site of Apical Bulk Endocytosis.

Background & AimsThe molecular motor, Myosin Vb (MYO5B), is well documented for its role in trafficking cargo to the apical membrane of epithelial cells. Despite its involvement in regulating apical proteins, the role of MYO5B in cell polarity is less clear. Inactivating mutations in MYO5B result in microvillus inclusion disease (MVID), a disorder characterized by loss of key apical transporters and the presence of intracellular inclusions in enterocytes. We previously identified that inclusions in Myo5b knockout (KO) mice form from invagination of the apical brush border via apical bulk endocytosis. Herein, we sought to elucidate the role of polarity complexes and tight junction proteins during the formation of inclusions.MethodsIntestinal tissue from neonatal control and Myo5b KO littermates was analyzed by immunofluorescence to determine the localization of polarity complexes and tight junction proteins.ResultsProteins that make up the apical polarity complexes—Crumbs3 and Pars complexes—were associated with inclusions in Myo5b KO mice. In addition, tight junction proteins were observed to be concentrated over inclusions that were present at the apical membrane of Myo5b-deficient enterocytes in vivo and in vitro. Our mouse findings are complemented by immunostaining in a large animal swine model of MVID genetically engineered to express a human MVID-associated mutation that shows an accumulation of Claudin-2 over forming inclusions. The findings from our swine model of MVID suggest that a similar mechanism of tight junction accumulation occurs in patients with MVID.ConclusionsThese data show that apical bulk endocytosis involves the altered localization of apical polarity proteins and tight junction proteins after loss of Myo5b.

Unequal Effects of Myosin 5B Mutations in Liver and Intestine Determine the Clinical Presentation of Low-Gamma-Glutamyltransferase Cholestasis.

Mutations in the MYO5B gene cause in some patients low gamma-glutamyltransferase (low-GGT) cholestatic liver disease (CLD) and in other patients microvillus inclusion disease (MVID, a congenital diarrheal and malabsorption disorder). Overlap of symptoms occurs but more MVID patients present cholestasis than CLD patients present diarrhea. Clinical observations indicate that MYO5B mutations can cause but also protect against CLD. This complicates family counseling and therapeutic decisions. Here we have reviewed the literature on MYO5B mutations in relation to CLD. It appears that variations in the clinical presentation of low-GGT CLD can be attributed to the coincident expression but unequal effects of MYO5B mutations in hepatocytes versus enterocytes, two cell types that jointly constitute the core of the enterohepatic circulation. Therefore, contrasting other low-GGT CLDs, those associated with MYO5B mutations should be viewed as a disease of the enterohepatic circulation rather than solely of the liver.

MYO5B mutations in pheochromocytoma/paraganglioma promote cancer progression.

Identification of additional cancer-associated genes and secondary mutations driving the metastatic progression in pheochromocytoma and paraganglioma (PPGL) is important for subtyping, and may provide optimization of therapeutic regimens. We recently reported novel recurrent nonsynonymous mutations in the MYO5B gene in metastatic PPGL. Here, we explored the functional impact of these MYO5B mutations, and analyzed MYO5B expression in primary PPGL tumor cases in relation to mutation status. Immunohistochemistry and mRNA expression analysis in 30 PPGL tumors revealed an increased MYO5B expression in metastatic compared to non-metastatic cases. In addition, subcellular localization of MYO5B protein was altered from cytoplasmic to membranous in some metastatic tumors, and the strongest and most abnormal expression pattern was observed in a paraganglioma harboring a somatic MYO5B:p.G1611S mutation. In addition to five previously discovered MYO5B mutations, the present study of 30 PPGL (8 previous and 22 new samples) also revealed two, and hence recurrent, mutations in the gene paralog MYO5A. The three MYO5B missense mutations with the highest prediction scores (p.L587P, p.G1611S and p.R1641C) were selected and functionally validated using site directed mutagenesis and stable transfection into human neuroblastoma cells (SK-N-AS) and embryonic kidney cells (HEK293). In vitro analysis showed a significant increased proliferation rate in all three MYO5B mutated clones. The two somatically derived mutations, p.L587P and p.G1611S, were also found to increase the migration rate. Expression analysis of MYO5B mutants compared to wild type clones, demonstrated a significant enrichment of genes involved in migration, proliferation, cell adhesion, glucose metabolism, and cellular homeostasis. Our study validates the functional role of novel MYO5B mutations in proliferation and migration, and suggest the MYO5-pathway to be involved in the malignant progression in some PPGL tumors.

A Molecular Mechanism Underlying Genotype-Specific Intrahepatic Cholestasis Resulting From MYO5B Mutations.

Background and AimsProgressive familial intrahepatic cholestasis (PFIC) 6 has been associated with missense but not biallelic nonsense or frameshift mutations in MYO5B, encoding the motor protein myosin Vb (myoVb). This genotype‐phenotype correlation and the mechanism through which MYO5B mutations give rise to PFIC are not understood. The aim of this study was to determine whether the loss of myoVb or expression of patient‐specific myoVb mutants can be causally related to defects in canalicular protein localization and, if so, through which mechanism.Approach and ResultsWe demonstrate that the cholestasis‐associated substitution of the proline at amino acid position 600 in the myoVb protein to a leucine (P660L) caused the intracellular accumulation of bile canalicular proteins in vesicular compartments. Remarkably, the knockout of MYO5B in vitro and in vivo produced no canalicular localization defects. In contrast, the expression of myoVb mutants consisting of only the tail domain phenocopied the effects of the Myo5b‐P660L mutation. Using additional myoVb and rab11a mutants, we demonstrate that motor domain‐deficient myoVb inhibited the formation of specialized apical recycling endosomes and that its disrupting effect on the localization of canalicular proteins was dependent on its interaction with active rab11a and occurred at the trans‐Golgi Network/recycling endosome interface.ConclusionsOur results reveal a mechanism through which MYO5B motor domain mutations can cause the mislocalization of canalicular proteins in hepatocytes which, unexpectedly, does not involve myoVb loss‐of‐function but, as we propose, a rab11a‐mediated gain‐of‐toxic function. The results explain why biallelic MYO5B mutations that affect the motor domain but not those that eliminate myoVb expression are associated with PFIC6.

Glucocorticoids and myosin5b loss of function induce heightened PKA signaling in addition to membrane traffic defects.

Loss-of-function mutations in the nonconventional myosin Vb (Myo5b) result in microvillus inclusion disease (MVID) and massive secretory diarrhea that often begins at birth. Myo5b mutations disrupt the apical recycling endosome (ARE) and membrane traffic, resulting in reduced surface expression of apical membrane proteins. ARE disruption also results in constitutive phosphoinositide-dependent kinase 1 gain of function. In MVID, decreased surface expression of apical anion channels involved in Cl− extrusion, such as cystic fibrosis transmembrane conductance regulator (CFTR), should reduce fluid secretion into the intestinal lumen. But the opposite phenotype is observed. To explain this contradiction and the onset of diarrhea, we hypothesized that signaling effects downstream from Myo5b loss of function synergize with higher levels of glucocorticoids to activate PKA and CFTR. Data from intestinal cell lines, human MVID, and Myo5b KO mouse intestine revealed changes in the subcellular redistribution of PKA activity to the apical pole, increased CFTR phosphorylation, and establishment of apical cAMP gradients in Myo5b-defective cells exposed to physiological levels of glucocorticoids. These cells also displayed net secretory fluid fluxes and transepithelial currents mainly from PKA-dependent Cl− secretion. We conclude that Myo5b defects result in PKA stimulation that activates residual channels on the surface when intestinal epithelia are exposed to glucocorticoids at birth.

P4.37: Extra-Intestinal Manifestations of Children with Genetically Confirmed Microvillus Inclusion Disease

Objectives: Microvillous inclusion disease (MVID): congenital disorder caused by MYO5B or STX3 mutations. Pathognomonic features are severe intractable diarrhoea and malabsorption due to intestinal brush border atrophy, accumulation of lysosomal granules and microvillus inclusions in the apical cytoplasm of enterocytes. All epithelial tissues express MYO5B but gut involvement is classically described. Method: Two males: A, 2-year-old Pakistani and B, 12-month-old Kuwaiti with MYO5B mutation. Results: Patient A: Neonatal secretory diarrhea with high fluid and electrolyte requirements, deteriorated on feed introduction. Duodenal histology: blunted villi, hyperplastic crypts, loss of surface epithelium, goblet cell depletion and apoptosis. Periodic acid–Schiff (PAS) and CD10 staining suggested MVID, confirmed by electron microscopy (EM). Genetics: homozygosity of MYO5B gene: c.1087C>T mutation. He was discharged on home parenteral nutrition (PN) at 10 months with ongoing high volume and sodium demands, gradually worsening diarrhea and minor transaminitis in his first year but otherwise stable liver function. Annual PN screening showed low TMP/GFR (0.89mmol/L), elevated cystatin C (1.27mg/L), biochemical evidence of renal tubular leak and radiological signs of rickets but no nephrocalcinosis. Fanconi syndrome was diagnosed. Currently on 24hr PN (250ml/kg) with large amounts of electrolytes, phosphate, acetate with over 20 watery stools/day. He was referred for small bowel (SB) transplantation. Patient B: Neonatal watery diarrhea and severe acidosis with feed introduction. He was commenced on PN, tertiary referral to London at 2months; arriving in poor nutritional status, marked conjugated hyperbilirubinemia and transaminitis. SB mucosal biopsies demonstrated total villous atrophy, focally vacuolated superficial epithelium and few intraepithelial lymphocytes. PAS and CD10 staining suggested MVID confirmed by EM. Genetics: compound heterozygosity for MYO5B gene mutations; c.1576C>T; p. and c.2111del; p. variant. Liver biopsy: lobular cholestasis, hepatocyte giant cell transformation and bridging fibrosis. He currently tolerates small amount of an amino-acid based formula and 170ml/kg/day PN with 10-hours break; with stable diarrhea (6–7/day). Due to severe liver injury and long term PN, he is being assessed for combined liver and SB transplantation. Conclusion: MVID has variable phenotypes, with other organ involvement such as liver and kidney apart from the gut.

220.5: Diagnosis and management of congenital enteropathies: analysis of a large multi-center cohort and the role of Next Generation Sequencing.

Introduction: A small percentage of children with intestinal failure suffer from congenital enteropathies responsible for chronic diarrhea associated with severe growth failure and dehydration. These disorders usually present early in infancy and result from monogenic mutations in genes affecting intestinal epithelial function. Recently, next-generation sequencing (NGS) technology has revolutionized the approach to molecular diagnosis, although there still remains little information about the associated natural history, and complete clinical phenotype. To better understand the natural history and the impact of NGS, we studied a historical cohort of children with congenital enteropathies. Methods: A retrospective analysis of children followed in the intestinal failure / congenital enteropathy programs at Necker-Enfants Malades and Boston Children’s Hospitals was done. Diagnosis was obtained either from pathology, targeted sequencing, and from 2012 (Boston)/ 2014 (Paris) by NGS (whole exome, or targeted gene panels). Genetic findings were validated clinically and/or functionally. Results: 85 patients were included (53% female, age 2 months to 25 years). Three out 85 patients died. In 82% (70/85) of cases, a diagnosis could be established. 25 (29%) patients were diagnosed with microvillus inclusion disease (MYO5B mutation), 19 (22%) patients were diagnosed with tufting enteropathy (EPCAM mutations). Other diagnoses included DGAT1 mutations (8,5%), TTC37/SKIV2L, and SLC26A3 [UMO1] mutations. Since 2012, 37 out of 46 patients (80%) obtained a molecular diagnosis, including the discovery of novel genes (DGAT1, UNC45A, WNT2B). 9 out of 42 patients at Necker-Enfants Malades underwent intestinal transplantation. In a number of patients, diagnosis facilitated by NGS led to significant changes in clinical management such as removal of high-risk immunosuppressive medications. Conclusion: We carried out an analysis of a large cohort of children with congenital enteropathy, across two major pediatric centers. Mutations in MYO5B and EPCAM were responsible for 51% of our cohort, with considerable genetic heterogeneity in the rest of the cohort. Since 2012, most patients underwent NGS, with a molecular diagnosis achieved in 80% of cases[UMO2]. NGS was critical in achieving a diagnosis particularly in atypical or hypomorphic presentations and enabled clinically significant changes in management as well as the discovery of novel disease-causing genes.

Loss of MYO5B Leads to Reductions in Na+ Absorption With Maintenance of CFTR-Dependent Cl– Secretion in Enterocytes

Inactivating mutations in MYO5B cause microvillus inclusion disease (MVID), but the physiological cause of the diarrhea associated with this disease is unclear. We investigated whether loss of MYO5B results inaberrant expression of apical enterocyte transporters. We studied alterations in apical membrane transporters in MYO5B-knockout mice, as well as mice with tamoxifen-inducible, intestine-specific disruption of Myo5b (VilCreERT2;Myo5bflox/flox mice) or those not given tamoxifen (controls). Intestinal tissues were collected from mice and analyzed by immunostaining, immunoelectron microscopy, or cultured enteroids were derived. Functions of brush border transporters in intestinal mucosa were measured in Ussing chambers. We obtained duodenal biopsy specimens from individuals with MVID and individuals without MVID (controls) and compared transporter distribution by immunocytochemistry. Compared to intestinal tissues from littermate controls, intestinal tissues from MYO5B-knockout mice had decreased apical localization of SLC9A3 (also called NHE3), SLC5A1 (also called SGLT1), aquaporin (AQP) 7, and sucrase isomaltase, and subapical localization of intestinal alkaline phosphatase and CDC42. However, CFTR was present on apical membranes ofenterocytes from MYO5B knockout and control mice. Intestinal biopsies from patients with MVID had subapical localization of NHE3, SGLT1, and AQP7, but maintained apical CFTR. After tamoxifen administration, VilCreERT2;Myo5bflox/flox mice lost apical NHE3, SGLT1, DRA, and AQP7, similar to germline MYO5B knockout mice. Intestinal tissues from VilCreERT2;Myo5bflox/flox mice had increased CFTR in crypts andCFTR localized to the apical membranes of enterocytes. Intestinal mucosa from VilCreERT2;Myo5bflox/flox mice given tamoxifen did not have an intestinal barrier defect, based on Ussing chamber analysis, but did have decreased SGLT1 activity and increased CFTR activity. Although trafficking of many apical transporters is regulated by MYO5B, trafficking of CFTR is largely independent of MYO5B. Decreased apical localization of NHE3, SGLT1, DRA, and AQP7 might be responsible for dysfunctional water absorption in enterocytes of patients with MVID. Maintenance of apical CFTR might exacerbate water loss by active secretion of chloride into the intestinal lumen.