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Biological networks: Types and origin

Biological networks: Types and origin. Protein-protein interactions, complexes, and network properties. Thomas Skøt Jensen Center for Biological Sequence Analysis The Technical University of Denmark. Networks in electronics. Radio kindly provided by Lazebnik, Cancer Cell, 2002. Model

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Biological networks: Types and origin

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  1. Biological networks:Types and origin Protein-protein interactions, complexes, and network properties Thomas Skøt Jensen Center for Biological Sequence Analysis The Technical University of Denmark

  2. Networks in electronics Radio kindly provided by Lazebnik, Cancer Cell, 2002

  3. Model Generation Interactions • Sequencing • Gene knock-out • Microarrays • etc. YER001W YBR088C YOL007C YPL127C YNR009W YDR224C YDL003W YBL003C … YDR097C YBR089W YBR054W YMR215W YBR071W YBL002W YNL283C YGR152C … Parts List • Genetic interactions • Protein-Protein interactions • Protein-DNA interactions • Subcellular Localization Interactions • Microarrays • Proteomics • Metabolomics Dynamics Radio kindly provided by Lazebnik, Cancer Cell, 2002

  4. Types of networks

  5. Interaction networks in molecular biology • Protein-protein interactions • Protein-DNA interactions • Genetic interactions • Metabolic reactions • Co-expression interactions • Text mining interactions • Association networks

  6. Interaction networks in molecular biology • Protein-protein interactions • Protein-DNA interactions • Genetic interactions • Metabolic reactions • Co-expression interactions • Text mining interactions • Association networks

  7. Characterization of physical interactions • Obligation • obligate (protomers only found/function together) • non-obligate (protomers can exist/function alone) • Time of interaction • permanent (complexes, often obligate) • strong transient (require trigger, e.g. G proteins) • weak transient (dynamic equilibrium)

  8. Examples: GPCR ol obligate, permanent non-obligate, strong transient

  9. Approaches by interaction type • Physical Interactions • Yeast two hybrid screens • Affinity purification (mass spec) • Protein-DNA by chIP-chip • Other measures of ‘association’ • Genetic interactions (double deletion mutants) • Functional associations (STRING) • Co-expression

  10. Yeast two-hybrid method Y2H assays interactions in vivo. Uses property that transcription factors generally have separable transcriptional activation (AD) and DNA binding (DBD) domains. A functional transcription factor can be created if a separately expressed AD can be made to interact with a DBD. A protein ‘bait’ B is fused to a DBD and screened against a library of protein “preys”, each fused to a AD.

  11. Yeast two-hybrid method Fields and Song

  12. Issues with Y2H • Strengths • High sensitivity (transient & permanent PPIs) • Takes place in vivo • Independent of endogenous expression • Weaknesses: False positive interactions • Auto-activation • ‘sticky’ prey • Detects “possible interactions” that may not take place under real physiological conditions • May identify indirect interactions (A-C-B) • Weaknesses: False negatives interactions • Similar studies often reveal very different sets of interacting proteins (i.e. False negatives) • May miss PPIs that require other factors to be present (e.g. ligands, proteins, PTMs)

  13. Protein interactions by immuno-precipitation followed by mass spectrometry • Start with affinity purification of a single epitope-tagged protein • This enriched sample typically has a low enough complexity to be fractionated on a standard polyacrylamide gel • Individual bands can be excised from the gel and identified with mass spectrometry.

  14. Affinity Purification

  15. Affinity Purification • Strengths • High specificity • Well suited for detecting permanent or strong transient interactions (complexes) • Detects real, physiologically relevant PPIs • Weaknesses • Less suited for detecting weaker transient interactions (low sensitivity) • May miss complexes not present under the given experimental conditions (low sensitivity) • May identify indirect interactions (A-C-B)

  16. Error rate may be as high as 30-50 % Protein-protein interaction data growth

  17. Complex pull-downs Low confidence (rarely purified together) High confidence (often purified together) Topology based scoring of interactions D Yeast two-hybrid A B C High confidence (1 unshared interaction partners) Low confidence (4 unshared interaction partners) de Lichtenberg et al., Science, 2005

  18. Filtering by subcellular localization de Lichtenberg et al., Science, 2005

  19. Filtering reduces coverage and increases specificity

  20. Network Properties Graphs, paths, topology

  21. Graphs • Graph G=(V,E) is a set of vertices V and edges E • A subgraph G’ of G is induced by some V’V and E’ E • Graph properties: • Connectivity (node degree, paths) • Cyclic vs. acyclic • Directed vs. undirected

  22. Sparse vs Dense • G(V, E) where |V|=n, |E|=m the number of vertices and edges • Graph is sparse if m~n • Graph is dense if m~n2 • Complete graph when m=n2

  23. Connected Components • G(V,E) • |V| = 69 • |E| = 71

  24. Connected Components • G(V,E) • |V| = 69 • |E| = 71 • 6 connected components

  25. Paths A path is a sequence {x1, x2,…, xn} such that (x1,x2), (x2,x3), …, (xn-1,xn) are edges of the graph. A closed path xn=x1 on a graph is called a graph cycle or circuit.

  26. Shortest-Path between nodes

  27. Shortest-Path between nodes

  28. Longest Shortest-Path

  29. Degree or connectivity

  30. Random vs scale-free networks P(k) is probability of each degree k, i.e fraction of nodes having that degree. For random networks, P(k) is normally distributed. For real networks the distribution is often a power-law: P(k) ~ k-g Such networks are said to be scale-free

  31. Target the ‘hubs’ to have an efficient safe sex education campaign “The Swedish sex web” Lewin Bo, et al., Sex i Sverige; Om sexuallivet i Sverige 1996, Folkhälsoinstitutet, 1998

  32. Knock-out lethality and connectivity

  33. Clustering coefficient The density of the network surrounding node I, characterized as the number of triangles through I. Related to network modularity k: neighbors of I nI: edges between node I’s neighbors The center node has 8 (grey) neighbors There are 4 edges between the neighbors C = 2*4 /(8*(8-1)) = 8/56 = 1/7

  34. Proteins subunits are highly interconnected and thus have a high clustering coefficient There exists algorithms, such as MCODE, for identifying subnetworks (complexes) in large protein-protein interaction networks Protein complexes have a high clustering coefficient

  35. Hierarchical Networks

  36. Detecting hierarchical organization

  37. Scale-free networks are robust • Complex systems (cell, internet, social networks), are resilient to component failure • Network topology plays an important role in this robustness • Even if ~80% of nodes fail, the remaining ~20% still maintain network connectivity • Attack vulnerability if hubs are selectively targeted • In yeast, only ~20% of proteins are lethal when deleted, and are 5 times more likely to have degree k>15 than k<5.

  38. Other interesting features • Cellular networks are assortative, hubs tend not to interact directly with other hubs. • Hubs tend to be “older” proteins (so far claimed for protein-protein interaction networks only) • Hubs also seem to have more evolutionary pressure—their protein sequences are more conserved than average between species (shown in yeast vs. worm)

  39. Sub-cellular localization coverage

  40. Co-localization of interacting proteins

  41. Tendency to interact with your cousin

  42. Over-representation of highly abundant proteins

  43. say a lot, of which most is wrong say a lot, of which most is right say little, of which most is wrong say little, of which most is right Coverage versus Accuracy Sensitivity Specificity

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