REDEFINING BILIARY ATRESIA: INTEGRATIVE MODELS AND METHODOLOGIES Restricted; Files Only

Abstract

Biliary atresia (BA) is the most prevalent serious liver disease of infancy, presenting as a fibroinflammatory erasure of the extrahepatic bile duct and rapidly progressing intrahepatic cholangiopathy. Without effective non-surgical therapies, a confirmed etiology, or agreed upon preclinical models, BA is a devastating pediatric disorder with multiple unmeet needs. Addressing these concerns, and led by exome analyses of BA patients, we hypothesized that ciliary genetic perturbations in murine developing cholangiocytes could induce a spectrum of phenotypes that are observed in BA. ARC 1 of this thesis focused on characterizing the developmental, adult, and obstructive phenotypes in livers deficient in the ciliary BA candidate gene; Pkd1l1. Initiated by these findings, ARC 2 outlines the first comprehensive machine-learning platform for quantification of biliary forms, expanding the analyses of Pkd1l1-deficient livers, and several other cholangiopathy models. ARC 3 introduces several new ciliary BA candidate genes, validated through in vitro knockdown within intra- and extrahepatic cholangiocyte organoids. Illustrated in ARCs 1 & 2, the first genetic-based model of BA, the Pkd1l1 liver-restricted deletion mouse, has developmental bile duct paucity, adulthood peribiliary fibroinflammation, and significant exacerbations in the presence of obstruction. In ARC 3, divergent morphological phenotypes were observed within cholangiocyte organoids deficient in the new ciliary BA candidate genes. Selectively, each ciliary candidate gene, those from ARCs 1-3, resulted in a distinct injury to cholangiocyte cells that could initiate disease. This thesis redefines BA as a developmental cholangiopathy, induced, in part, by genetic perturbations in specific ciliary genes essential for biliary tree morphogenesis. 

Table of Contents

CHAPTER I. INTRODUCTION

1

CHAPTER II. LIVER-RESTRICTED DELETION OF THE BILIARY ATRESIA CANDIDATE GENE INDUCES BILE DUCT DYSMORPHOGENESIS AND CILIOPATHY

48

CHAPTER III. BiliQML: A supervised machine learning model to quantify biliary forms from digitized whole-slide liver histopathological images

90

CHAPTER IV. ROLES FOR Pkd1l1 IN PATHWAYS MAINTAINING BILIARY MATURATION

133

CHAPTER V. MULTIPLE GENETIC PATHWAYS LEADING TO THE BILIARY ATRESIA PHENOTYPE 

162

CHAPTER VI. DISCUSSION

184

CHAPTER VII. OTHER NOTABLE WORK

197

About this Dissertation

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School	Laney Graduate School
Department	Biological and Biomedical Sciences
Subfield / Discipline	Genetics and Molecular Biology
Degree	Ph.D.
Submission	Dissertation
Language	English
Research Field	Biology, Genetics Health Sciences, Human Development Biology, Molecular
Keyword	Machine Learning Cholangiocyte Hepatology Immunofluorescence Liver Bile duct Cilia
Committee Chair / Thesis Advisor	Saul J. Karpen, Emory University
Committee Members	Andrew S. Neish, Emory University Tamara Caspary, Emory University Adam D. Gracz, Emory University Stacey S. Huppert, Cincinnati Children's Hospital Medical Center

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