Presentation is loading. Please wait.

Presentation is loading. Please wait.

BIOINFORMATICS ON NETWORKS Nick Sahinidis University of Illinois at Urbana-Champaign Chemical and Biomolecular Engineering.

Published byHilary McCormick Modified over 8 years ago

Similar presentations

Presentation on theme: "BIOINFORMATICS ON NETWORKS Nick Sahinidis University of Illinois at Urbana-Champaign Chemical and Biomolecular Engineering."— Presentation transcript:

1 BIOINFORMATICS ON NETWORKS Nick Sahinidis University of Illinois at Urbana-Champaign Chemical and Biomolecular Engineering

2 MOTIVATION Genomics and proteomics help us understand the structure, properties, and function of single genes and proteins Genes and proteins function in complex networks Bioinformatics on biochemical networks aims to understand and rationally manipulate networks of genes and proteins These networks are very complex –http://www.expasy.org/cgi-bin/show_thumbnails.plhttp://www.expasy.org/cgi-bin/show_thumbnails.pl –http://www.expasy.org/cgi-bin/show_thumbnails.pl?2http://www.expasy.org/cgi-bin/show_thumbnails.pl?2 –http://www.genome.ad.jp/kegg/pathway.htmlhttp://www.genome.ad.jp/kegg/pathway.html

3 LEARNING OBJECTIVES (two lectures) Introduction to: –Metabolic networks –Flux balance analysis –S-systems theory –Gene additions and deletions –Pathway reconstruction from data

4 METABOLIC NETWORKS Definitions –Metabolic network: a system of interacting proteins and small molecules converting raw materials to energy and other useful substances in a living organism –Metabolites: materials consumed or produced in a metabolic network –Enzymes: proteins that catalyze reactions –The sets of metabolites and enzymes of a network are not necessarily disjoint Key observation –A large proportion of the chemical processes that underlie life are shared across a very wide range of organisms

5 GRAPHICAL REPRESENTATION Nodes represent metabolites and enzymes Arcs correspond to reactions and modulation Dotted or colored lines often reserved to denote modulation A negative sign associated with an arc is used to denote inhibition

6 METABOLIC NETWORK EXAMPLE ABCE D Five metabolites (A, B, C, D, E) Six reactions (one reversible and five irreversible) Network interacts with environment through: –Consumption of A –Secretion of E –Consumption or secretion of C and D

7 FLUX BALANCE ANALYSIS Pseudo steady-state hypothesis: metabolic dynamics are much faster compared to those of the environment Model network through steady-state mass balances for metabolites For each metabolite, its rate of consumption must equal its rate of production

8 FBA EXAMPLE ABCE D v1v1 v7v7 v6v6 v4v4 v3v3 v5v5 v2v2 Network Boundary v 3 : B D v 2 : B C v 4 : D B v 1 : A B v 5 : C D v 6 : C E v 7 : 2D E Internal Fluxes b 4 : E b 3 : D b 1 : A b 2 : C Exchange Fluxes b1b1 b2b2 b4b4 b3b3 Exchange fluxes may be positive (system output) or Negative (input to metabolic network)

9 FBA EQUATIONS ABCE D v1v1 v7v7 v6v6 v4v4 v3v3 v5v5 v2v2 Network Boundary b1b1 b2b2 b4b4 b3b3 Sign restrictions 0  v 1,…,v 7 b 1  0 -   b 2  +  -   b 3  +  b 4  0 Steady state mass balances A: - v 1 - b 1 = 0 B: v 1 + v 4 – v 2 – v 3 = 0 C: v 2 - v 5 - v 6 - b 2 = 0 D: v 3 + v 5 - v 4 - 2v 7 - b 3 = 0 E: v 6 + v 7 - b 4 = 0

10 MODELING WITH FBA Problem #1: Interpret metabolic network behavior –Hypothesis: Network is an optimizer –Likely objectives: »Maximize growth »Minimize energy consumption –Leads to a linear program Problem #2: Manipulate a metabolic network to produce certain desired products through –Control of external fluxes –Structural manipulations in the network

11 GENE ADDITIONS AND DELETIONS Two-level problem –Upper level: maximize a bioengineering objective through gene knockouts –Lower level: cell is still an optimizer that seeks to optimize its own objective through adjusting internal fluxes Use binary variable for each gene to decide whether to knock it out or not (or whether to over-express) Inner linear program can be converted to a set of linear equalities and inequalities via duality theory giving rise to a mixed-integer linear program for the overall problem

12 REFERENCES AND FURTHER READING B. Palsson, 2000 Hougen Lectures –http://gcrg.ucsd.edu/presentations/hougen/hougen.htm E. Voit, Computational Analysis of Biochemical Systems, Cambridge University Press, 2000. N. Friedman, Inferring cellular networks using probabilistic graphical models, Science, 303, 799-805, 2004. Metabolic Systems Engineering course: –http://archimedes.scs.uiuc.edu/courses/meteng.htmlhttp://archimedes.scs.uiuc.edu/courses/meteng.html

Download ppt "BIOINFORMATICS ON NETWORKS Nick Sahinidis University of Illinois at Urbana-Champaign Chemical and Biomolecular Engineering."

Similar presentations

Metabolic Modeling - Why? Models - why? Building models of a system helps us improve our understanding. It is also a way of checking our understanding,

Metabolic Modeling - Why? Models - why? Building models of a system helps us improve our understanding. It is also a way of checking our understanding,
Lecture #9 Regulation.

Lecture #9 Regulation.
Lecture #8 Stoichiometric Structure. Outline Cofactors and carriers Bi-linear nature of reactions Pathways versus cofactors Basics of high energy bond.

Lecture #8 Stoichiometric Structure. Outline Cofactors and carriers Bi-linear nature of reactions Pathways versus cofactors Basics of high energy bond.
Lets begin constructing the model… Step (I) - Definitions We begin with a very simple imaginary metabolic network represented as a directed graph: Vertex.

Lets begin constructing the model… Step (I) - Definitions We begin with a very simple imaginary metabolic network represented as a directed graph: Vertex.
Linear Programming. Introduction: Linear Programming deals with the optimization (max. or min.) of a function of variables, known as ‘objective function’,

Linear Programming. Introduction: Linear Programming deals with the optimization (max. or min.) of a function of variables, known as ‘objective function’,
Modelling and Identification of dynamical gene interactions Ronald Westra, Ralf Peeters Systems Theory Group Department of Mathematics Maastricht University.

Modelling and Identification of dynamical gene interactions Ronald Westra, Ralf Peeters Systems Theory Group Department of Mathematics Maastricht University.
Modelling Cell Signalling Pathways in PEPA

Modelling Cell Signalling Pathways in PEPA
Regulation of Gene Expression in Flux Balance Models of Metabolism.

Regulation of Gene Expression in Flux Balance Models of Metabolism.
Lecture #10 Metabolic Pathways. Outline Glycolysis; a central metabolic pathway Fundamental structure (m x n = 20 x 21) Co-factor coupling (NAD, ATP,

Lecture #10 Metabolic Pathways. Outline Glycolysis; a central metabolic pathway Fundamental structure (m x n = 20 x 21) Co-factor coupling (NAD, ATP,
Biological pathway and systems analysis An introduction.

Biological pathway and systems analysis An introduction.
Darwinian Genomics Csaba Pal Biological Research Center Szeged, Hungary.

Darwinian Genomics Csaba Pal Biological Research Center Szeged, Hungary.
Chapter 10 Introduction to Metabolism. Metabolism The sum of the chemical changes that convert nutrients into energy and the chemically complex products.

Chapter 10 Introduction to Metabolism. Metabolism The sum of the chemical changes that convert nutrients into energy and the chemically complex products.
The (Right) Null Space of S Systems Biology by Bernhard O. Polson Chapter9 Deborah Sills Walker Lab Group meeting April 12, 2007.

The (Right) Null Space of S Systems Biology by Bernhard O. Polson Chapter9 Deborah Sills Walker Lab Group meeting April 12, 2007.
EE462 MLCV Lecture 11-12 Introduction of Graphical Models Markov Random Fields Segmentation Tae-Kyun Kim 1.

EE462 MLCV Lecture Introduction of Graphical Models Markov Random Fields Segmentation Tae-Kyun Kim 1.
E.coli aerobic/anaerobic switch study Chao Wang, Mar 1 2006.

E.coli aerobic/anaerobic switch study Chao Wang, Mar
Flux Balance Analysis. FBA articles Advances in flux balance analysis. K. Kauffman, P. Prakash, and J. Edwards. Current Opinion in Biotechnology 2003,

Flux Balance Analysis. FBA articles Advances in flux balance analysis. K. Kauffman, P. Prakash, and J. Edwards. Current Opinion in Biotechnology 2003,
System Biology Study Group Walker Research Group Spring 2007.

System Biology Study Group Walker Research Group Spring 2007.
Energy Balance Analysis Reference Paper: Beard et al. Energy Balance for Analysis of Complex Metabolic Networks. Biophysical Journal 83, 79-86 (2002) Presented.

Energy Balance Analysis Reference Paper: Beard et al. Energy Balance for Analysis of Complex Metabolic Networks. Biophysical Journal 83, (2002) Presented.
Petri net modeling of biological networks Claudine Chaouiya.

Petri net modeling of biological networks Claudine Chaouiya.
Mathematical Representation of Reconstructed Networks The Left Null space The Row and column spaces of S.

Mathematical Representation of Reconstructed Networks The Left Null space The Row and column spaces of S.

Similar presentations

Ads by Google