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Canadian Bioinformatics Workshops www.bioinformatics.ca.

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1 Canadian Bioinformatics Workshops www.bioinformatics.ca

2 2Module #: Title of Module

3 Module 4 Network Visualization and Analysis http://baderlab.org

4 Module 4: Network Visualization and Analysis bioinformatics.ca Network Analysis Workflow Load Networks e.g. PPI data – Import network data into Cytoscape Load Attributes e.g. gene expression data – Get data about networks into Cytoscape Analyze and Visualize Networks Prepare for Publication A specific example of this workflow: Cline, et al. “Integration of biological networks and gene expression data using Cytoscape”, Nature Protocols, 2, 2366-2382 (2007).

5 Module 4: Network Visualization and Analysis bioinformatics.ca Network Visualization and Analysis Outline Network introduction Network visualization Cytoscape software tool for network visualization and analysis Network analysis

6 Module 4: Network Visualization and Analysis bioinformatics.ca Networks Represent relationships – Physical, regulatory, genetic, functional interactions Useful for discovering relationships in large data sets – Better than tables in Excel Visualize multiple data types together – See interesting patterns

7 Module 4: Network Visualization and Analysis bioinformatics.ca Network Representations

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9 Biological Pathways/Networks?

10 Module 4: Network Visualization and Analysis bioinformatics.ca Mapping Biology to a Network A simple mapping – one compound/node, one interaction/edge A more realistic mapping – Cell localization, cell cycle, cell type, taxonomy – Only represent physiologically relevant interaction networks Edges can represent other relationships Critical: understand what nodes and edges mean

11 Module 4: Network Visualization and Analysis bioinformatics.ca Protein Sequence Similarity Network http://apropos.icmb.utexas.edu/lgl/

12 Module 4: Network Visualization and Analysis bioinformatics.ca Six Degrees of Separation Everyone in the world is connected by at most six links Which path should we take? Shortest path by breadth first search – If two nodes are connected, will find the shortest path between them Are two proteins connected? If so, how? Biologically relevant? http://www.time.com/time/techtime/200406/community.html

13 humangenetics-amc.nl Gene Function Prediction – shows connections to sets of genes/proteins involved in same biological process Detection of protein complexes/other modular structures – discover modularity & higher order organization (motifs, feedback loops) Network evolution – biological process(es) conservation across species Prediction of new interactions and functional associations – Statistically significant domain- domain correlations in protein interaction network to predict protein-protein or genetic interaction jActiveModules, UCSD PathBlast, UCSD MCODE, University of Toronto DomainGraph, Max Planck Institute Applications of Network Biology

14 humangenetics-amc.nl Identification of disease subnetworks – identification of disease network subnetworks that are transcriptionally active in disease. Subnetwork-based diagnosis – source of biomarkers for disease classification, identify interconnected genes whose aggregate expression levels are predictive of disease state Subnetwork-based gene association – map common pathway mechanisms affected by collection of genotypes June 2009 Agilent Literature Search Mondrian, MSKCC PinnacleZ, UCSD Applications of Network Informatics in Disease

15 Module 4: Network Visualization and Analysis bioinformatics.ca What’s Missing? Dynamics –Pathways/networks represented as static processes Difficult to represent a calcium wave or a feedback loop –More detailed mathematical representations exist that handle these e.g. Stoichiometric modeling, Kinetic modeling (VirtualCell, E-cell, …) Need to accumulate or estimate comprehensive kinetic information Detail – atomic structures Context – cell type, developmental stage

16 Module 4: Network Visualization and Analysis bioinformatics.ca What Have We Learned? Networks are useful for seeing relationships in large data sets Important to understand what the nodes and edges mean Important to define the biological question - know what you want to do with your gene list or network Many methods available for gene list and network analysis – Good to determine your question and search for a solution – Or get to know many methods and see how they can be applied to your data

17 Module 4: Network Visualization and Analysis bioinformatics.ca Network Visualization Outline Automatic network layout Visual features Visually interpreting a network

18 Module 4: Network Visualization and Analysis bioinformatics.ca Automatic network layout

19 Module 4: Network Visualization and Analysis bioinformatics.ca Automatic network layout Force-directed: nodes repel and edges pull Good for up to 500 nodes – Bigger networks give hairballs - Reduce number of edges Advice: try force directed first, or hierarchical for tree-like networks Tips for better looking networks – Manually adjust layout – Load network into a drawing program (e.g. Illustrator) and adjust labels

20 Focus Overview Zoom PKC Cell Wall Integrity

21 Module 4: Network Visualization and Analysis bioinformatics.ca Visual Features Node and edge attributes – String, integer, float, Boolean, list – E.g. represent gene, interaction attributes Visual attributes – Node, edge visual properties – Colour, shape, size, borders, opacity...

22 Module 4: Network Visualization and Analysis bioinformatics.ca Visually Interpreting a Network Guilt-by-association Dense clusters Global relationships

23 Module 4: Network Visualization and Analysis bioinformatics.ca What Have We Learned? Automatic layout is required to visualize networks Networks help you visualize interesting relationships in your data Avoid hairballs by focusing analysis Visual attributes enable multiple types of data to be shown at once – useful to see their relationships

24 Module 4: Network Visualization and Analysis bioinformatics.ca Network Visualization and Analysis using Cytoscape Network visualization and analysis using Cytoscape software Cytoscape basics Cytoscape network analysis examples

25 Network visualization and analysis UCSD, ISB, Agilent, MSKCC, Pasteur, UCSF, Unilever, UToronto, U Texas http://cytoscape.org Pathway comparison Literature mining Gene Ontology analysis Active modules Complex detection Network motif search

26 Network Analysis using Cytoscape Databases Literature Expert knowledge Experimental Data Find biological processes underlying a phenotype Network Information Network Analysis

27 Manipulate NetworksFilter/Query Automatic Layout Interaction Database Search

28 Module 4: Network Visualization and Analysis bioinformatics.ca Active Community Help – Tutorials, case studies – Mailing lists for discussion – Documentation, data sets Annual Conference: San Diego, May 18-21, 2011 10,000s users, 2500 downloads/month >100 Plugins Extend Functionality – Build your own, requires programming http://www.cytoscape.org Cline MS et al. Integration of biological networks and gene expression data using Cytoscape Nat Protoc. 2007;2(10):2366-82

29

30 Module 4: Network Visualization and Analysis bioinformatics.ca What Have We Learned? Cytoscape is a useful, free software tool for network visualization and analysis Provides basic network manipulation features Plugins are available to extend the functionality

31 Cytoscape Demo Version 2.8.0 www.cytoscape.org

32 Desktop Canvas Network overview Network manager Attribute browser CytoPanels FYI

33 yFiles Organic FYI

34 yFiles Circular FYI

35 Module 4: Network Visualization and Analysis bioinformatics.ca Network Layout 15 algorithms available through plugins Demo: Move, zoom/pan, rotate, scale, align FYI

36 Create Subnetwork FYI

37 Create Subnetwork FYI

38 Module 4: Network Visualization and Analysis bioinformatics.ca Visual Style Customized views of experimental data in a network context Network has node and edge attributes E.g. expression data, GO function, interaction type Mapped to visual attributes E.g. node/edge size, shape, colour… E.g. Visualize gene expression data as node colour gradient on the network FYI

39 Visual Style Load “Your Favorite Network” FYI

40 Visual Style Load “Your Favorite Expression” Dataset FYI

41 Visual Style Map expression values to node colours using a continuous mapper FYI

42 Visual Style Expression data mapped to node colours FYI

43 Module 4: Network Visualization and Analysis bioinformatics.ca Network Filtering FYI

44 Interaction Database Search FYI

45 Module 4: Network Visualization and Analysis bioinformatics.ca FYI

46 Module 4: Network Visualization and Analysis bioinformatics.ca FYI

47

48 Module 4: Network Visualization and Analysis bioinformatics.ca We are on a Coffee Break & Networking Session

49

50 Module 4: Network Visualization and Analysis bioinformatics.ca VistaClara Visualization for gene expression data Heat maps, sorting, animation

51 Module 4: Network Visualization and Analysis bioinformatics.ca Cytoscape Lab Cytoscape – expression data visualization – Load the sample network file: galFiltered.sif – Lay it out – try different layouts – Load expression data - galExpData.pvals Use File->Import->Attribute from Table – Examine node attributes – Visualize gene expression data using the Visual Mapper – Install the VistaClara plugin from the plugin manager – Play the expression data as a movie

52 Module 4: Network Visualization and Analysis bioinformatics.ca BiNGO plugin Calculates over-representation of a subset of genes with respect to a background set in a specific GO category Input: subnetwork, or list – Background set by user Output: tree with nodes color reflecting overrepresentation; also as lists Caveats: Gene identifiers must match; low GO term coverage, GO bias, Background determining

53 Module 4: Network Visualization and Analysis bioinformatics.ca BiNGO Maere, S., Heymans, K. and Kuiper, M Bioinformatics 21, 3448-3449, 2005 Hypergeometric p-value Multiple testing correction (Benjamini-Hochberg FDR)

54 Module 4: Network Visualization and Analysis bioinformatics.ca Cerebral http://www.pathogenomics.ca/cerebral /

55 Module 4: Network Visualization and Analysis bioinformatics.ca Find Active Subnetworks Active modules –Input: network + p-values for gene expression values e.g. from GCRMA –Output: significantly differentially expressed subgraphs Method –Calculate z-score/node, Z A score/subgraph, correct vs. random expression data sampling –Score over multiple experimental conditions –Simulated annealing used to find high scoring networks Ideker T, Ozier O, Schwikowski B, Siegel AF Bioinformatics. 2002;18 Suppl 1:S233-40

56 Module 4: Network Visualization and Analysis bioinformatics.ca Active Module Results Network: yeast protein-protein and protein-DNA network Expression data: 3 gene knock out conditions (enzyme, TF activator, TF repressor) Note: non-deterministic, multiple runs required for confidence of result robustness Ideker T et al. Science. 2001 May 4;292(5518):929-34.

57 Module 4: Network Visualization and Analysis bioinformatics.ca Network Clustering Clusters in a protein-protein interaction network have been shown to represent protein complexes and parts of pathways Clusters in a protein similarity network represent protein families Network clustering is available through the ClusterMaker Cytoscape plugin Bader & Hogue, BMC Bioinformatics 2003 4(1):2

58 Proteasome 26S Proteasome 20S Ribosome RNA Pol core RNA Splicing

59 Module 4: Network Visualization and Analysis bioinformatics.ca Text Mining Computationally extract gene relationships from text, usually PubMed abstracts Useful if network is not in a database –Literature search tool BUT not perfect –Problems recognizing gene names –Natural language processing is difficult Agilent Literature Search Cytoscape plugin iHOP (www.ihop-net.org/UniPub/iHOP/)

60 Agilent Literature Search

61 Cytoscape Network produced by Literature Search. Abstract from the scientific literature Sentences for an edge

62 Module 4: Network Visualization and Analysis bioinformatics.ca Analysis Lab Find Network Motifs - Netmatch plugin Network motif is a sub-network that occurs significantly more often than by chance alone Input: query and target networks, optional node/edge labels Output: topological query matches as subgraphs of target network Supports: subgraph matching, node/edge labels, label wildcards, approximate paths http://alpha.dmi.unict.it/~ctnyu/netmatch.html

63 Finding specific biological relevant TF-PPI sub-networks QueryResults Ferro et al. Bioinformatics 2007

64 Find Signaling Pathways Potential signaling pathways from plasma membrane to nucleus via cytoplasm Raf-1 Mek MAPK TFs Nucleus - Growth Control Mitogenesis MAP Kinase Cascade Ras NetMatch query Shortest path between subgraph matches Signaling pathway example NetMatch Results

65 Find Expressed Motifs ProteinDifferential Expression Significance YLR075W1.7255E-4 YGR085C2.639E-4 YPR102C3.7183E-4 NetMatch query NetMatch Results Find specific subgraphs where certain nodes are significantly differentially expressed

66 Module 4: Network Visualization and Analysis bioinformatics.ca Cytoscape Tips & Tricks “Root graph” – “There is one graph to rule them all….” – The networks in Cytoscape are all “views” on a single graph. – Changing the attribute for a node in one network will also change that attribute for a node with the same ID in all other loaded networks – There is no way to “copy” a node and keep the same ID – Make a copy of the session

67 Module 4: Network Visualization and Analysis bioinformatics.ca Cytoscape Tips & Tricks Network views – When you open a large network, you will not get a view by default – To improve interactive performance, Cytoscape has the concept of “Levels of Detail” Some visual attributes will only be apparent when you zoom in The level of detail for various attributes can be changed in the preferences To see what things will look like at full detail: – View  Show Graphics Details

68 Module 4: Network Visualization and Analysis bioinformatics.ca Cytoscape Tips & Tricks Sessions – Sessions save pretty much everything: Networks Properties Visual styles Screen sizes – Saving a session on a large screen may require some resizing when opened on your laptop

69 Module 4: Network Visualization and Analysis bioinformatics.ca Cytoscape Tips & Tricks Logging – By default, Cytoscape writes it’s logs to the Error Dialog: Help  Error Dialog – Can change a preference to write it to the console Edit  Preferences  Properties… Set logger.console to true Don’t forget to save your preferences Restart Cytoscape – (can also turn on debugging: cytoscape.debug, but I don’t recommend it)

70 Module 4: Network Visualization and Analysis bioinformatics.ca Cytoscape Tips & Tricks Memory – Cytoscape uses lots of it – Doesn’t like to let go of it – An occasional restart when working with large networks is a good thing – Destroy views when you don’t need them – Java doesn’t give us a good way to get the memory right at start time Since version 2.7, Cytoscape does a much better job at “guessing” good default memory sizes than previous versions

71 Module 4: Network Visualization and Analysis bioinformatics.ca Cytoscape Tips & Tricks.cytoscape directory – Your defaults and any plugins downloaded from the plugin manager will go here – Sometimes, if things get really messed up, deleting (or renaming) this directory can give you a “clean slate” Plugin manager – “Outdated” doesn’t necessarily mean “won’t work” – Plugin authors don’t always update their plugins immediately after new releases

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