Systems model of the ATP-generating metabolic network in Drosophila flight muscle Jacob Feala, Laurence Coquin, Andrew McCulloch, Giovanni Paternostro,

Slides:



Advertisements
Similar presentations
How Cells Harvest Energy Chapter 7. 2 Respiration Organisms can be classified based on how they obtain energy: autotrophs: are able to produce their own.
Advertisements

Chapter 8: How Cells Release Stored Energy. Overview of Carbohydrate Metabolism Glucose + 6 O 2  6 CO H 2 O The overall reaction is exergonic.
Effect of oxygen on the Escherichia coli ArcA and FNR regulation systems and metabolic responses Chao Wang Jan 23, 2006.
KREBS CYCLE. Introduction Let us review fates of Pyruvate Depending on the oxidation state of the cell: Aerobic – converted to acetyl-CoA via TCA cycle.
Regulated Flux-Balance Analysis (rFBA) Speack: Zhu YANG
Gene expression analysis summary Where are we now?
Metabolic/Subsystem Reconstruction And Modeling. Given a “complete” set of genes… Assemble a “complete” picture of the biology of an organism? Gene products.
Cellular Respiration Chapter 9.
Lesson 7: Harvesting of Energy “Cellular Respiration”
Cell Respiration Chapter 5. Cellular Respiration Release of energy in biomolecules (food) and use of that energy to generate ATP ENERGY (food) + ADP +
Cellular Respiration.
Cellular Respiration 7.3 Aerobic Respiration.
CELLULAR RESPIRATION BIOLOGY IB/ SL Option C.3.
Lecture #23 Varying Parameters. Outline Varying a single parameter – Robustness analysis – Old core E. coli model – New core E. coli model – Literature.
Key Area 1: Cellular respiration Glycolysis, Citric Acid Cycle, Electron Transport Chain Unit 2: Metabolism and Survival.
~~ ~~ Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display GLUCOSE Pentose phosphate pathway Starts.
Transcriptional Regulation in Constraints-based metabolic Models of E. coli Published by Markus Covert and Bernhard Palsson, 2002.
1 Respiration Cellular respiration is a series of reactions that: -are oxidations – loss of electrons -are also dehydrogenations – lost electrons are accompanied.
Cellular Respiration Pages: 98 to 103 and 357 to 368.
Cell Respiration Chapter 9. Slide 2 of 33 Why Respire?  Living cells require energy transfusions to perform most of their tasks  From external sources.
Breathing (Pulmonary Respiration) versus Cellular Respiration
Redox buffering, respiration, and fermentation
Energy Harvesting Pathways Glycolysis & Cellular Respiration.
Intro to Cellular Respiration, Glycolysis & Krebs Cycle
Chapter 4 Cells and Energy Cellular Respiration. Cellular respiration  Process by which food molecules are broken down to release energy  Glucose and.
How Cells Harvest Energy Chapter 6
© 2012 Pearson Education, Inc. Lecture by Edward J. Zalisko PowerPoint Lectures for Campbell Biology: Concepts & Connections, Seventh Edition Reece, Taylor,
After Digestion And Absorption
How Cells Harvest Energy
Cellular Respiration.
Chapter 9~ Cellular Respiration: Harvesting Chemical Energy
1 Departament of Bioengineering, University of California 2 Harvard Medical School Department of Genetics Metabolic Flux Balance Analysis and the in Silico.
Chapter 7: Cellular Pathways That Harvest Chemical Energy CHAPTER 7 Cellular Pathways That Harvest Chemical Energy.
Chapter 7: Cellular Pathways That Harvest Chemical Energy Cellular Pathways That Harvest Chemical Energy Obtaining Energy and Electrons from GlucoseObtaining.
Oxidative Decarboxylation of Pyruvate
Cellular Respiration: Harvesting Chemical Energy
Chapter 6 Acquiring Energy.
Glycolysis Glucose → pyruvate (+ ATP, NADH) Preparatory phase + Payoff phase Enzymes –Highly regulated (eg. PFK-1 inhibited by ATP) –Form multi-enzyme.
Lecture #4Date _________ Chapter 9~ Cellular Respiration: Harvesting Chemical Energy.
CELLULAR RESPIRATION and FERMENTATION. Energy Harvest Fermentation – partial breakdown w/o oxygen Cellular Respiration – most efficient, oxygen consumed,
Introduction: Acknowledgments Thanks to Department of Biotechnology (DBT), the Indo-US Science and Technology Forum (IUSSTF), University of Wisconsin-Madison.
Cell Respiration Chapter 9. Slide 2 of 40 Cellular Respiration.
Coordination of Intermediary Metabolism. ATP Homeostasis Energy Consumption (adult woman/day) – kJ (>200 mol ATP) –Vigorous exercise: 100x rate.
Metabolic pathway alteration, regulation and control (3) Xi Wang 01/29/2013 Spring 2013 BsysE 595 Biosystems Engineering for Fuels and Chemicals.
Flexibility in energy metabolism supports hypoxia tolerance in Drosophila flight muscle: metabolomic and computational systems analysis Jacob Feala 1,2.
Cell Metabolism and Product Formation. Metabolic pathways catabolismanabolism proteins, carbohydrates lipids, nucleic acids glucose CO 2, H 2 O, energy.
Intro to Cellular Respiration, Glycolysis & Krebs Cycle
Cellular Respiration AP Biology. The Equation C 6 H 12 O 6 + 6O 2  6CO 2 + 6H ATP C 6 H 12 O 6 = glucose 6O 2 = oxygen gas 6CO 2 = carbon dioxide.
Harvesting energy Genes and Development Biology 122.
Chapter 6 Cellular Respiration. Outline Day 1 –Energy Flow and Carbon Cycling –Overview of Energy Metabolism –Redox Reactions –Electrons and Role of Oxygen.
Chapter 9 Cellular Respiration: Harvesting Chemical Energy.
Cellular Respiration An Overview. Principles of Energy Harvest Catabolic pathway √ Fermentation √Cellular Respiration C 6 H 12 O 6 + 6O2 ---> 6CO 2 +
Cellular Respiration Making ATP. Cellular Respiration Cell respiration is the controlled release of energy from organic compounds in cells to form ATP.
Project 2 Flux Balance Analysis of Mitochondria Energy Metabolism Suresh Gudimetla Salil Pathare.
Lecture #4Date _________ Chapter 9~ A Musical Journey Through Cellular Respiration Objective: How do organisms produce energy for themselves to do work?
An Overview of Cellular Respiration
Flexibility in energy metabolism supports hypoxia tolerance in Drosophila flight muscle: metabolomic and computational systems analysis Jacob Feala Laurence.
NS 315 Unit 4: Carbohydrate Metabolism
How Cells Release Chemical Energy Chapter 7. p.106a Overall Concept of Cellular Respiration.
How Cells Release Chemical Energy
Cellular Respiration.
Packet #13 Short Edition Chapter #9
Jacob Feala1,2 Laurence Coquin, PhD2 Andrew McCulloch, PhD1
Cellular Respiration Harvesting Chemical Energy
Figure 1 Immune cell metabolism during homeostasis
Chapter 9: Cellular Respiration: Harvesting Chemical Energy.
Cellular Respiration.
Pyruvate Dehydrogenase
Schematic of the integration and results of the alveolar macrophage (iAB‐AMØ‐1410) and Mycobacterium tuberculosis (iNJ661) reconstructions. Schematic of.
Presentation transcript:

Systems model of the ATP-generating metabolic network in Drosophila flight muscle Jacob Feala, Laurence Coquin, Andrew McCulloch, Giovanni Paternostro, Presenting work from the labs of: Giovanni Paternostro, MD, PhD Burnham Institute for Medical Research Andrew McCulloch, PhD Cardiac Mechanics Research Group University of California, San Diego

Systems Biology Choose well known model organism with sequenced genome and genetic tools Use high-throughput technologies to acquire genome-scale data on biological components under the context of interest Reconstruct interaction networks from the annotated genome and high-throughput data Develop predictive, quantitative models of systems properties and integrative functions Systematically perturb components, in-silico and experimentally. Compare simulation with experiment to refine model and generate new experimentally testable hypotheses

Model context: hypoxic metabolism Global regulation of metabolism during hypoxia To survive, must balance: – ATP supply/demand – Acid production – Redox state – Metabolic intermediates Use a genome-scale model to keep track of it all – how do flies maintain homeostasis? Hochachka, 1996

Reconstruction Overview Gene-protein-reaction associations Literature and Databases Annotated Genome Stoichiometric matrix Metabolic network reconstruction NMR metabolomics Thorax microarray

Reconstruction steps Database integration –KEGG: metabolic genes, enzymes, reactions, EC numbers, pathways –Flybase: complete genome, proteins, function, compartment, mutant stocks, references Filtered gene index Pathways109 EC numbers437 Genes1322 Genes (mitochondrial)125 Genes (stocks available)507

Reconstruction steps

NMR Metabolomics 1 H NMR spectroscopy of flight muscle at t=0,1,10,60,240 minutes Reconstruction steps

Phase 0Phase 1 Reconstruction steps Network model of central metabolism –211 genes, 196 reactions (74 associated with genes), 6 pathways –Glycolysis, TCA cycle, oxidative phosphorylation, β –oxidation, amino acid degradation, glutathione redox cycle, superoxide production and scavenging –Elementally- and charge- balanced

Constraint-based modeling Steady state assumption: dx/dt = Sv = 0 Flux constraints: v i = (C i t2 – C i t1 )/∆t Optimize for objective function: Z = cv Mass and charge balance inherent Particular solution (optimal) Null Space of S Solution space Metabolic network reconstruction S matrix

Price, et. al. (2004) Nat Rev Microbiol 2,

Hypoxia simulation: 3 pyruvate pathways vs 1 Abbreviations: atp: ATP production co2: CO2 production glc: glucose uptake h: proton production ac: acetate accumulation lac: lactate accumulation ala: alanine accumulation Drosophila (Pseudo-) Mammalian Reduced glucose uptake Stable pH Equivalent ATP Using pathways that generate alanine and acetate increases ATP/H + and ATP/glucose ratios

Aging and hypoxia tolerance Data-driven FBA of young and old flies after 4 hours hypoxia and 5 minutes recovery  Map of flux ratios on recovery (green:red = young:old) Young flies recover mitochondrial respiration pathways better, old flies rely on anaerobic acetate production Poster 854B, Laurence Coquin

Resources and applications Resources for the community –Drosophila model files in SBML Feala et. al., 2007, Mol Sys Biol (Supplementary Material) –Updated model (in submission) me for advanced copy: –COBRA Toolbox for Matlab Future directions –Different tissues –Applications Mechanistic understanding Multiple interventions

Acknowledgements Matt Owen UCSD Undergrads –Francis Le –Polly Huang –Khoi Pham Palsson Lab –Bernhard Palsson –Adam Feist –Thuy Vo

1 H NMR spectroscopy of hypoxic fly muscle 0.5% O minutes NMR specialist: Laurence Coquin MAMMALIAN TISSUE: Troy H et. al. Metabolomics 2005; 1: High-throughput technologies

Alanine Acetyl-CoA α-OxoglutarateGlutamate Cytosol Mitochondria Acetate Acyl-carnitine shuttle Glucose PyruvateLactate Main Energetic Pathways in Model ATP Oxaloacetate NADH Acetyl-CoA Citrate ATP Pyruvate ATP NADH NADH/FADH 2 NADH NADH/FADH 2 O2O2 H2OH2O TCA cycle Oxidative phosphorylation Glycolysis NADH FADH α-GPDH shuttle Products seen in NMR Hypothesized pathways Known Drosophila pathways ATP CO 2 NH 4

Simulation conditions - Glucose (and equivalents) only carbon substrate - Lactate, alanine, acetate constrained to NMR fluxes - Varied O2 uptake constraint - Objective: maximize ATP production Flux-balance analysis of hypoxia lac ala ac glc

GenomeNetworksModulesFunctional Models BioinformaticsSystems Biology Multiscale Modeling cell tissue organ Experiment

Feedback: Privacy Policy Feedback
Do Not Sell My Personal Information
About project: SlidePlayer Terms of Service

© 2025 SlidePlayer.com. Inc. All rights reserved.