Transcript Dol1 Dol3
Network Analysis of Glycerol Kinase Deficient Mice Predicts Genes Essential for Survival: A Systems Biology Approach NK MacLennan, J Dong, S Horvath, L Ornelas, L Rahib, K Dipple and ERB McCabe. UCLA, Los Angeles, CA, United States. Glycerol Kinase • Catalyzes the reaction Glycerol glycerol 3-phosphate, a substrate for gluconeogenesis and lipid metabolism Human Glycerol Kinase Deficiency (hGKD) • hGKD is an X-linked inborn error of metabolism. • Symptoms include metabolic and central nervous system deterioration. • Treatment: low-fat diet. • There is no satisfactory correlation between GKD genotype and phenotype. Mouse Model of GKD • GK knockout (KO) mice model the human GKD phenotype. Huq et al., Hum Mol Genet. 1997; Kuwada et al., Biochem Biophys Res Commun. 2005 • Unlike humans, mice die at 3-4 days of life (Dol). Objective • Identify genes associated with survival of WT mice using network analysis that relates a measure of differential expression to connectivity. • Highly connected highly differentially expressed genes have been found to be predictors of survival. Methods • Microarray analysis on liver mRNA WT KO WT C • Expression data was filtered for the top 10% most varying probe sets for Weighted Gene Co-Expression Network Analysis (WGCNA). Weighted Gene Co-Expression Network Analysis (WGCNA) Overview http://www.genetics.ucla.edu/labs/horvath/CoexpressionNetwork/ Construct a network Rationale: make use of interaction patterns between genes Identify modules Rationale: module (pathway) based analysis Relate modules to external information Array Information: Sample data Gene Information: EASE Rationale: find biologically interesting modules Study Module Preservation across different data Rationale: • Same data: to check robustness of module definition • Different data: to find interesting modules Find the key drivers in interesting modules Tools: Module connectivity, causality testing Rationale: experimental validation, therapeutics, biomarkers Construct a network Rationale: make use of interaction patterns between genes Identify modules Rationale: module (pathway) based analysis Relate modules to external information Array Information: Sample data Gene Information: EASE Rationale: find biologically interesting modules Study Module Preservation across different data Rationale: • Same data: to check robustness of module definition • Different data: to find interesting modules Find the key drivers in interesting modules Tools: Module connectivity, causality testing Rationale: experimental validation, therapeutics, biomarkers Construct a Network Microarray gene expression data Gene expression correlation Correlation Matrix Power adjacency function generates a weighted network aij | cor ( xi , x j ) | Construct a network Rationale: make use of interaction patterns between genes Identify modules Rationale: module (pathway) based analysis Relate modules to external information Array Information: Sample data Gene Information: EASE Rationale: find biologically interesting modules Study Module Preservation across different data Rationale: • Same data: to check robustness of module definition • Different data: to find interesting modules Find the key drivers in interesting modules Tools: Module connectivity, causality testing Rationale: experimental validation, therapeutics, biomarkers Module Identification • WGCNA aim: Detect modules. • Modules are groups of highly correlated, highly connected genes. • Defined with the standard distance measure: 1correlation. Construct a network Rationale: make use of interaction patterns between genes Identify modules Rationale: module (pathway) based analysis Relate modules to external information Array Information: Sample data Gene Information: EASE Rationale: find biologically interesting modules Study Module Preservation across different data Rationale: • Same data: to check robustness of module definition • Different data: to find interesting modules Find the key drivers in interesting modules Tools: Module connectivity, causality testing Rationale: experimental validation, therapeutics, biomarkers • A measure of a gene’s connection strength to other genes in the whole network. • Use both k and GS Gene Significance (GS) Connectivity (k) and Gene Significance (GS) Module Connectivity Construct a network Rationale: make use of interaction patterns between genes Identify modules Rationale: module (pathway) based analysis Relate modules to external information Array Information: Sample data Gene Information: EASE Rationale: find biologically interesting modules Study Module Preservation across different data Rationale: • Same data: to check robustness of module definition • Different data: to find interesting modules Find the key drivers in interesting modules Tools: Module connectivity, causality testing Rationale: experimental validation, therapeutics, biomarkers Construct a network Rationale: make use of interaction patterns between genes Identify modules Rationale: module (pathway) based analysis Relate modules to external information Array Information: Sample data Gene Information: EASE Rationale: find biologically interesting modules Study Module Preservation across different data Rationale: • Same data: to check robustness of module definition • Different data: to find interesting modules Find the key drivers in interesting modules Tools: Module connectivity, causality testing Rationale: experimental validation, therapeutics, biomarkers Results • Unsupervised hierarchical clustering analysis revealed that overall gene expression profiles of the dol 1 and 3 KO mice differed from WT. Dol 1 Dol3 Identify Modules and Study Module Preservation Dol 1 Dol 3 Dol 3 colors Dol 1 colors Relate Modules to Gene Significance Glycerol Kinase Knockout Status DOL 1 KO • Blue: Underexpressed • Turquoise: Overexpressed DOL 3 KO • Blue: Underexpressed • Brown: No relationship • Turquoise: Overexpressed Relate Modules to External Information Functional Group Enrichment Dol1 Mitotic cell cycle, transcription factor binding, response to DNA damage stimulus, protein metabolism, apoptosis, cell death. Organic acid/carboxylic acid, lipid, amino acid, steroid and carbohydrate metabolism. Dol3 Mitotic cell cycle, protein metabolism, epigenetic regulation of gene expression. Carboxylic acid/organic acid, fatty acid, amino acid and glucose metabolism. Find the Key Drivers in Interesting Modules Dol3 Gene Significance GK TAT HNF4a BCL2 BID GADD45 TRP53inp1 Module Connectivity Gene Significance GPD VDAC ACOT PSAT TAT HNF4a Gene Significance Module Connectivity Module Connectivity GK GPD VDAC Gene Significance Dol1 ACOT PSAT PLK3 Module Connectivity Validation Studies • Cell Culture – ACOT – PSAT – PLK3 • KO Mice – ACOT Summary • Dol 1 Blue module: – Genes underexpressed in KO – GK gene module membership – Enriched with Apoptosis/ cell death genes Summary • Dol 3 blue module: – Genes Underexpressed in KO – Loss of Apoptosis/ cell death gene enrichment Summary • Dol 1 and 3 Turquoise module: – Genes overexpressed in KO – ACOT, PSAT, PLK3 connected Summary • Gene validation studies supported the WGCNA. – ACOT – PSAT – PLK3 Conclusion • WGCNA permits the reduction of high dimensionality data to low dimensionality output that is more easily understood – Revealed novel target genes possibly essential for survival of WT – Provided evidence of an apoptotic role for GK that is lost in GKD Acknowledgements • McCabe Lab • Dipple Lab Cell Culture Validation 350 *** % of Control 300 ** 250 *** 200 150 100 *** *** 50 0 GK Acot Gyk Clofibrate GK Plk3 GK Psat Gyk Gyk Naltrexone Paclitaxel Choice of Power, β