Project description:NHLBI GO-ESP: Family Studies (Atypical Cystic Fibrosis)

Project description:NHLBI GO-ESP: Lung Cohorts Exome Sequencing Project (Cystic Fibrosis)

Project description:Cystic fibrosis (CF) is one of the commonest lethal genetic diseases in which the role of microRNAs (miRNAs) has yet to be explored. We hypothesized that unique miRNA expression profiles exist in CF versus non-CF bronchial epithelial cells so the our aim was to investigate whether unique miRNA expression profiles exist in CF, particularly in CF bronchial epithelial cells and explore their effects on influencing signaling pathways. The expression of 667 miRNAs were measured in bronchial brushings from individuals with and without cystic fibrosis (CFn=5, non-CF n=5). The 5 CF patient samples have been normalised to the controls so we get a final normalised value for 5 samples only. There are 2 raw data files for samples and controls as there are two cards A and B ran for each sample, for a total of 4 raw data files available on the Series record.

Project description:This multi-center study will compare multi-target DNA and quantitative FIT stool-based testing to colonoscopy in individuals with Cystic Fibrosis (CF) undergoing colon cancer screening with colonoscopy. The primary endpoint is detection of any adenomas, including advanced adenomas and colorectal cancer (CRC).

Project description:<p>The major goal of this project is to apply second generation resequencing technology to identify disease causing variants influencing pediatric and adult lung diseases in a collection of two longitudinal population cohorts of cystic fibrosis patients that have been well characterized for a comprehensive set of clinical traits. In Phase I, exome sequencing was performed on 43 cystic fibrosis patients with early <i>Pa</i> infection and 48 cystic fibrosis patients with late <i>Pa</i> infection to identify variants influencing the time to onset of <i>Pa</i> infection. In Phase II, additional exomes were added to the study, to reach a total of 91 individuals with early <i>Pa</i> infection and 96 with late <i>Pa</i> infection. The majority of the 340 subjects of Phase II do not have a <i>Pa</i> infection phenotype, but instead have a pulmonary function phenotype (121 severe vs. 124 mild impairment) as determined by the survival corrected Kulich FEV percentile of Corey et al. A small minority have intermediate phenotypes and/or show severe decline in lung function during childhood.</p>

Project description:Cystic fibrosis (CF) is one of the commonest lethal genetic diseases in which the role of microRNAs (miRNAs) has yet to be explored. We hypothesized that unique miRNA expression profiles exist in CF versus non-CF bronchial epithelial cells so the our aim was to investigate whether unique miRNA expression profiles exist in CF, particularly in CF bronchial epithelial cells and explore their effects on influencing signaling pathways.

Project description:To provide a more detailed survey of adaptive changes in the physiology of P. aeruginosa (PA) during long-term infection of the cystic fibrosis (CF) lung, we performed a comparative proteome and transcriptome analysis of a set of isogenic sequential non-mutator and mutator isolates from three selected CF patients. Recently, we showed that during CF lung persistence PA mutators converge to a virulence-attenuated phenotype. In this study, we demonstrate that besides virulence-associated traits (VATs) the adaptation process of PA predominantly comprises metabolic pathways. In end-stage mutator strains, transcripts of genes encoding VATs, chemotaxis, degradation of aromatic compounds and several two-component regulatory systems were decreased. In contrast, several transcripts of genes or proteins involved in metabolism of fatty acids, nucleotides, amino acids and the generation of energy were increased. Of particular interest is the increased expression level of genes involved in (i) the anaerobic arginine-deiminase pathway, (ii) the anaerobic respiration such as nitrate-uptake protein OprF, redox-active azurin and cytchrome c551 peroxidase, (iii) the micro-aerobic respiration such as high oxygen-affinity cytochrome oxidase cbb3 (iv) the tricarboxylic acid cycle (TCA), glyoxylate shunt and anaplerotic carboxylation reactions to oxaloacetate. Strikingly, an increased transcription of the anaerobic regulator gene anr correlates with the up-regulation of ANR-dependent genes. In conclusion, these changes in transcriptome and proteome indicate an adaptive shift towards constitutive expression of genes of metabolic pathways obviously required for growth under micro-aerobic and nutritional conditions of suppurative CF lung tissue. Finally, these results provide us with new targets for antimicrobial agents and biomarkers reflecting adaptation of PA towards progressive CF lung disease. Experiment Overall Design: P. aeruginosa isolates recovered from different time points of chronic cystic fibrosis lung disease were cultered in vitro, harvested for RNA extraction and hybridization on Affymetrix microarrays. We compared the transcriptome (triplicate microarrays) of early non-mutator P. aeruginosa isolates with late mutator isolates with high mutation frequency probably the driving force of an efficient adaptation to changing environements to conclude from differences in gene expression to the requirements of CF lung environment. Experiment Overall Design: Second publication of array data to be added later

Project description:Chronic airway infection with P. aeruginosa (PA) is a hallmark of cystic fibrosis (CF) disease. The mechanisms producing PA persistence in CF therapies remain poorly understood. To gain insight on PA physiology in patient airways and better understand how in vivo bacterial functioning differs from in vitro conditions, we investigated the in vivo proteomes of PA in 35 sputum samples from 11 CF patients. We developed a novel bacterial-enrichment method enabling improved identification of PA proteome with CF sputum samples. The in vivo PA proteomes were compared with the proteomes of ex vivo-grown PA populations from the same patient sample. We detected 1528 PA proteins (encoded by 1458 core genes and 70 accessory genes) that were expressed in CF airways, of which 1178 proteins were commonly identified with the ex vivo-grown PA populations. Label-free quantitation and proteome comparison revealed the in vivo up-regulation of siderophore TonB-dependent receptors, remodeling in central carbon metabolism including glyoxylate cycle and lactate utilization, and alginate overproduction. Knowledge of these in vivo proteome differences or others derived using the presented methodology could lead to future treatment strategies aimed at altering PA physiology in vivo to compromise infectivity or improve antibiotic efficacy.

Project description:<p>The NHLBI "Grand Opportunity" Exome Sequencing Project (GO-ESP), a signature project of the NHLBI Recovery Act investment, was designed to identify genetic variants in coding regions (exons) of the human genome (the "exome") that are associated with heart, lung and blood diseases. These and related diseases that are of high impact to public health and individuals from diverse racial and ethnic groups will be studied. These data may help researchers understand the causes of disease, contributing to better ways to prevent, diagnose, and treat diseases, as well as determine whether to tailor prevention and treatments to specific populations. This could lead to more effective treatments and reduce the likelihood of side effects. GO-ESP is comprised of five collaborative components: 3 cohort consortia - HeartGO, LungGO, and WHISP - and 2 sequencing centers - BroadGO and SeattleGO.</p> <p>Cystic fibrosis (CF) patients without detectable disease-causing mutations in CFTR present a clinical phenotype very similar to, but possibly discrete from, classic CF. We hypothesize that the phenotype of these atypical CF patients is not due only to mutations in the carbonic anhydrase gene CA12 or in the genes encoding the epithelium sodium ion channel ENaC, but is due to mutations in novel genes that have yet to be associated with CF. The goal of this study is to determine the molecular etiology of this atypical CF.</p>

Project description:Cystic Fibrosis Keystone Species