Albert, Réka - Departments of Biology & Physics, Pennsylvania State University

• TOR Signaling Pathway for Nutrient-Regulated
• A Novel Method for Signal Transduction Network Inference from Indirect Experimental Evidence
• Search in complex networks Hari Prasad ThadakamallaHari Prasad Thadakamalla
• Graph Processing Istvn Albert
• Network inference from dynamic (state) information
• Properties of real networks: degree distribution
• CMPSC 497E: Graphs and networks in systems biology Homework assignment 2, due Thursday Sept. 10
• Phys 597A: Graphs and Networks in Systems Biology
• Properties common to many large-scale networks, independently of their origin and function
• The two faces of network dynamics Evolving network models describe the dynamics/assembly/evolutionEvolving network models describe the dynamics/assembly/evolution
• Properties common to many large-scale networks, independently of their origin and function
• The structure of cellular networksThe structure of cellular networks To be able to construct and analyze a cellular network, we need
• N E W S A N D V I E W S 286 VOLUME 39 | NUMBER 3 | MARCH 2007 | NATURE GENETICS
• Topological perturbation of complex networksnetworks
• A network model for plantpollinator community assembly
• Network model of survival signaling in large granular lymphocyte leukemia
• Heterotrimeric G-proteins, composed of , and subunits, participate in a wide range of signaling pathways in eukaryotes (Morris and Malbon, 1999). According to the typical, mammalian paradigm, in its
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• CURRENT PERSPECTIVE ESSAY SPECIAL SERIES ON LARGE-SCALE BIOLOGY
• VARIATION IN HOST SUSCEPTIBILITY AND INFECTIOUSNESS GENERATED BY CO-INFECTION: THE MYXOMA-TRICHOSTRONGYLUS
• Supplementary Information Elucidation of Directionality for Co-Expressed Genes
• General network theory rka albert
• Phys 597A CMPS 497EPhys 597A, CMPS 497E Graphs and Networks in Systems Biology
• Properties of real networks: degree di t ib tidistribution
• Community structure in networks Many real-world networks, especially social ones,
• Graph representationsp p V number of vertices (nodes), E number of edges
• Modeling signal transduction networks by continuous and deterministic modelsy
• Spreading Processes Modeling Infectious Disease Dynamics with Networks
• Discrete dynamic modeling of biological The functional form of regulatory relationships and kinetic parameters
• CMPSC 497E: Graphs and networks in systems biology Homework assignment 1, due Thursday Sept. 3
• PHYS 597A: Graphs and networks in systems biology Homework assignment 1, due Thursday Sept. 3
• PHYS 597A: Graphs and networks in systems biology Homework assignment 2, due Thursday Sept. 10
• PHYS 597A, CMPSC 497E, Graphs and Networks in Systems Biology
• Graph concepts Graphs are made up by vertices (nodes) and edges (links).
• Many real-world networks, especially social ones, exhibit community structure.
• ISTVN ALBERT BIOINFORMATICS CENTER
• The structure of molecular & cellularThe structure of molecular & cellular networksnetworks
• Properties common to many large-scale networks, independently of their origin and function
• Biological network models Approaches used to understand the mechanisms behind the
• Topological perturbation of complex Effects on the global topology
• Spreading processes on networks In some cases is not enough to specify the nodes (components)
• Understanding the dynamics and function of cellular networks
• Discrete dynamic modeling of biological The functional form of regulatory relationships and kinetic parameters
• Modeling the segment polarity gene network First: System is biologically defined; known expression patterns
• PHYS 597A: Graphs and networks in systems biology Homework assignment 1, due Tuesday Jan. 20
• PHYS 597A, CMPS 497E: Graphs and networks in sys-tems biology
• PHYS 597A, CMPS497E: Graphs and networks in sys-tems biology
• PHYS 597A, CMPS 497E, Graphs and Networks in Systems Homework 9, due Tuesday March 31
• PHYS 597A, CMPSC 497E: Graphs and networks in sys-tems biology
• CMPS 497E: Graphs and networks in systems biology Project assignment 1, due Tuesday March 16
• PHYS 597A: Graphs and networks in systems biology Project assignment 1, due Tuesday March 16
• PHYS 597A, CMPSC 497E: Graphs and networks in systems biology Spring 2009
• PHYS 597A: Graphs and networks in systems biology Spring 2008
• Properties of real networks: degree distribution
• Quick review The question of how scale-free topologies arise can be
• Topological perturbation of complex Effects on the global topology
• Understanding the dynamics and function of cellular networks
• Basics of Chemical Kinetics -1 Rate of reaction = rate of disappearance of A =
• Modeling signal transduction Receptor -ligand binding -assumed to be elementary reaction
• Discrete dynamic modeling of biological The functional form of regulatory relationships and kinetic parameters
• Inference methods Probabilistic methods
• PHYS 597A: Graphs and networks in systems biology Project assignment 1, due Tuesday March 18
• PHYS 597A: Graphs and networks in systems biology Spring 2007
• Phys 597A: Graphs and Networks in Systems Biology
• Graph concepts Graphs are made up by vertices (nodes) and edges (links).
• Scientific Programming for Systems Biologists
• Inference methods Probabilistic methods
• Qualitative modeling of biological systems The functional form of regulatory relationships and kinetic parameters
• Alireza ZomorrodiAlireza Zomorrodi An Optimization-Based
• Introduction Model Fitting
• Boolean Modeling of Serotonin mediated Ca2+ Signaling pathway
• Investigating Statistical MechanicsInvestigating Statistical Mechanics of Complex Supply Chainof Complex Supply Chain
• Since Most of the presentation I would have explained the slides as they were shown, it may not be clear just by looking
• A Study on Netflix Movie-User Introduction
• Graphs and Networks in Systems Biology
• Graph concepts Graphs are made up by vertices (nodes) and edges (links).
• The structure of cellular networksThe structure of cellular networks To be able to construct and analyze a cellular network, we need
• Spreading processes on networks In some cases is not enough to specify the nodes (components)
• Stochasticity in Gene John Fricks
• Qualitative modeling of biological systems The functional form of regulatory relationships and kinetic parameters
• As we find out more about gene regulatory networks, it is not necessary to assume random topologies and regulatory functions
• Properties common to many large-scale networks, independently of their origin and function
• Cool Applications of Network Theory to Molecular Evolution
• PHYS 597A, CMPS 497E: Graphs and networks in sys-tems biology
• PHYS 597A, CMPSC 497E: Graphs and networks in sys-tems biology
• ARTICLE IN PRESS Physica A ( )
• Spreading processes on networks In some cases is not enough to specify the nodes (components)
• CMPSC 497E: Graphs and networks in systems biology Project assignment 1, due Tuesday Oct. 20
• The structure of molecular & cellularThe structure of molecular & cellular networksnetworksnetworksnetworks
• PHYS 597A: Graphs and networks in systems biology Homework assignment 2, due Tuesday Jan. 27
• PHYS 597A, CMPSC 497E: Graphs and networks in sys-tems biology
• Graph concepts Graphs are made up by vertices (nodes) and edges (links).
• PHYS 597A, CMPSC 497E: Graphs and networks in sys-tems biology
• OPERATIONS RESEARCH AND MANAGEMENT SCIENCE HANDBOOK
• Ecological NetworksEcological Networks 15 September 2009
• CMPS 497E: Graphs and networks in systems biology Homework assignment 2, due Tuesday Jan. 27
• Inferring (Biological) Signal Transduction Networks via Transitive Reductions of Directed Graphs
• Understanding the dynamics and function of cellular networks
• Graph concepts G h d b ti ( d ) d d (li k )Graphs are made up by vertices (nodes) and edges (links).
• Cis-Regulatory module network Swathi Ashok Kumar
• PHYS 597A, CMPSC 497E: Graphs and networks in systems biology T Th 9:45 -11:00 am
• Community structures in complex networks
• The topology and evolution of a network model for genome evolution
• Network models random graphs Properties common to many large-scale networks, independently of
• NET-SYNTHESIS: A software for synthesis, inference and simplification of signal transduction networks
• Properties common to many large-scale networks, independently of their origin and function
• PHYS 597A: Graphs and networks in systems biology Project assignment 1, due Tuesday Oct. 20
• CMPS 497E: Graphs and networks in systems biology Homework assignment 1, due Tuesday Jan. 20
• Phys 597A, CMPS 497E Graphs and Networks in Systems Biology
• Systems-level insights into cellular regulation: inferring, analysing, and modelling intracellular
• Topological perturbation of complex Effects on the global topology
• PHYS 597A, CMPS 497E: Graphs and networks in sys-tems biology
• The structure of cellular networksThe structure of cellular networks To be able to construct and analyze a cellular network, we need
• PHYS 597A, CMPSC 497E: Graphs and networks in sys-tems biology
• An Overview of Systems Biology Rka Albert1,2
• Constraint-based network model of pathogenimmune system interactions
• Wikipedia as Semantic Network What does Knowledge look like?
• PHYS 597A, CMPSC 497E: Graphs and networks in sys-tems biology
• Studying the effect of cell division on expression patterns of the segment polarity genes
• Properties common to many large-scale networks, independently of their origin and function
• Network models Properties common to many large-scale networks, independently of
• Understanding the dynamics and function of cellular networks
• Networks Perspective Duplication And Divergence
• Topological perturbation of complex Effects on the global topology
• Properties common to many large-scale networks, independently of their origin and function
• Properties common to many large-scale networks, independently of their origin and function
• Graph Processing Istvn Albert
• Light Induced Guard Cell Sunando Roy
• Phys 597A: Graphs and Networks in Systems Biology
• 597A-Complex Networks in Biological A Context Based growth and
• PHYSICAL REVIEW E 84, 036117 (2011) Computationally efficient measure of topological redundancy
• PHYSICAL REVIEW E 84, 031929 (2011) Network analysis reveals cross-links of the immune pathways activated by bacteria and allergen