Darwinian Genomics Csaba Pal Biological Research Center Szeged, Hungary
Genomics: Major revolution in the past 10 – 15 years with the rise of high-throughput molecular technologies: New methods for rapid and relatively cheap measurements of biological molecules on a global scale
Systematic mapping components, interactions and functional states of the cell Genomics: genome sequencing and annotation Transcriptomics: mRNA levels, mRNA half-lives Proteomics: protein levels, protein – protein interactions, protein modifications Metabolomics: metabolite concentrations Phenomics: creating collections of mutant strains and measuring phenotypes (e.g. cell growth) under various conditions
Darwinian genomics: Testing key issues in evolutionary biology Examples: 1)Role of chance and necessity 2)Gradual changes or jumps 3)Extent and evolution of robustness against mutations
Darwinian genomics: Testing key issues in evolutionary biology Examples: 1)Role of chance and necessity 2)Gradual changes or jumps 3)Extent and evolution of robustness against mutations
Yeast (S. cerevisiae) is an ideal model organism 1)Complete genome sequence/detailed biochemical studies -> network reconstruction 2) Genome-scale computational models -> systems level properties of cellular networks 3) Large-scale mutant libraries -> test predictions of the models 4) Complete genome sequences for ~30 closely related species -> study evolution across species
The knock-out paradox High-throughput single gene knock-out studies: no phenotype for most genes in the lab
Why keep them during evolution? 1)Keep optimal cellular performance in face of harmful mutations and non-heritable errors 2)Allow cellular growth under wide range of external conditions
compensated by a gene duplicate (genetic redundancy) compensated by alternative genetic pathways (distributed robustness) have important functions only under specific environmental conditions (Seemingly) dispensable genes.... Gene A Gene B Gene A
Redundancy is only apparent, most genes should have important contribution to survival under special environmental conditions
Hillenmeyer et al. Science 2008
Compared growth rates of ~ 5000 single gene knock-out strains under >1000 environments 97% of the mutants show slow growth under at least one condition
compensated by a gene duplicate (genetic redundancy) compensated by alternative genetic pathways (distributed robustness) have important functions only under specific environmental conditions Are these explanations mutually exclusive? Gene A Gene B Gene A
Does the capacity to compensate the impact of gene deletions depend on the environment?
A B A B A B A B Environment I. a B A b a b A B a B A b a b A B a B A b a b Environment II.Environment III. Observed gene deletion phenotypes ( viable, lethal): synthetic lethalityno interaction The extent of compensation may depend on nutrient availability
Computational tool: Flux Balance Analysis (FBA) 1)Network reconstruction In S. cerevisiae ~1400 biochemical reactions, including transport processes. 2)Application of constraints Specify the nutrients available in the environment (B,E), the key metabolites or biomass constituents (X, Y, Z) essential for survival, presence/absence of genes 3)Find a particular enzymatic flux distribution -> rate of biomass production (fitness) Amino acids Carbohydrates Ribonucleotides Deoxyribonucleotides Lipids Phospholipids Steroles Fatty acids fitness
What are the advantages of flux balance analysis? 1)Study large number of genes and environments simultaneously 2)Predictions: a) Changes in enzyme activity as a response to nutrient conditions and genetic deletions b) Impact of gene deletions and gene addition on growth rates 3) Good agreement between experimental studies and model predictions (~90%) Forster et al OMICS, Papp et al. Nature 2004
Interactions between mutations in metabolic networks A special case: Synthetic lethal genetic interactions A B normal growth lethal (or sick) a – B A b – a – b – Redundant gene duplicates Gene A Gene B Gene A Alternative cellular pathways
Model predictions and verification of genetic interactions Using Flux Balance analysis, we simulated all possible single and double gene deletions (~ ) in the metabolic network under 53 different nutrient conditions 98 gene pairs are synthetic lethal under at least one condition We performed lab experiments to validate them: ΔABΔAB n AΔBAΔB n A/ΔA B/ΔB 2n sporulation
Results: 1) 50% of the predictions were correct (only ~ 0.6% expected by chance!) 2) 85% of the interacting gene pairs show condition-dependent synthetic lethality unconditional synthetic lethality
Harrison et al. (2007) PNAS 104: An example:
Harrison et al. (2007) PNAS 104: An example:
Conclusions The metabolic network model can reliably predict (synthetic lethal) genetic interactions. The presence of genetic interactions (and hence the extent of compensation) vary extensively across nutrient conditions.
Speculations and potential implications: Experimental design. Different environments should be screened to identify the majority of genetic interactions Functional genomics. Redundancy is more apparent than real. Many seemingly dispensable genes have important physiological role under specific conditions Evolution. Robustness against mutations may not be a directly selected trait, but rather a by-product of evolution of novel metabolic pathways towards new environmental conditions
Shortcomings: The computational model is far from perfect, and ignores many biological details Only specific genetic interactions have been studied No systematic experimental screen Harrison et al. (2007) PNAS 104:
Collaboration with Charles Boone lab 1)Using robotic protocols, they map genetic interactions across the whole yeast genome (~10 7 combinations ) 2)They developed high-throughput protocols to measure fitness at high precision
Why study evolution?
Evolution of antibiotics resistance: 33 Billion $ annual costs in US
Ignoring evolution has serious health consequences
Evolutionary Systems Biology Group Projects: Analyses of genetic interactions Evolution of antibiotics resistance
Interactions between genes are masked by distant gene duplicates Confirmed by creating corresponding triple knock-outs: Overlapping enzymatic activities between duplicates conserved across more than 100 million years of evolution