TOWARDS BIOMARKER DISCOVERY IN CONGENITAL URINARY TRACT OBSTRUCTION

Abstract

Proteome analysis techonologies are commonly employed for discovery-based biomarker identification studies. This thesis aims to help bridge the gap between analytical technology development and clinical application by improving and appling a proteomics workflow for biomarker discovery in congenital urinary tract obstruction (UTO). By accentuating the importance of experimental design, and evaluating the biological relevance of quantitative proteome analyses, the results of this research provide confidence in a number of identified candidate biomarkers of UTO. A sensitive method for quantification of proteome samples was developed using temperature controlled reversed-phase liquid chromatography (TPLC). The TPLC system provides high recovery (> 90 %), as well as high accuracy and precision in estimating the concentration across a number of protein sample types (CV < 10 %). The need for extensive fractionation strategies coupled with LC-MS analysis challenges the throughput of the overall experiment. Development of a dual column LC-MS interface reduced the total analysis time by a factor of 2 over conventional single column LC-MS systems. The system was applied to a quantitative proteome analysis of proximal tubule cells exposed to mechanical stretch, mimicking the conditions they experience during UTO and a urinary exosomal proteome analysis for candidate biomarker identification of this disease. A total of 1636 proteins were identified in the whole cell proteome analysis, of which 317 were found to be significantly altered in abundance. Analysis of the urinary exosomal proteome yielded 318 proteins, of which 189 were found to be altered in abundance due to obstruction. Western blot confirmation of a few select proteins provided backing to the quantitative proteome analysis, while gene ontology and KEGG pathway analysis yielded functional information. The results from the quantitative analyses of the urinary exosomes and proximal tubule cells identified candidates for both diagnosis and prognosis of UTO. In addition, activation of a novel pathway was identified, presenting a potential drug target which could be exploited to improve recovery of children following relief of UTO. This thesis therefore contributes useful technological and methodological advancements towards routine proteome analysis, as well as providing candidate biomarker identification for the leading cause of renal functional loss in children.