Difference between revisions of "MARINa"
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===Table Viewer=== | ===Table Viewer=== |
Revision as of 16:26, 18 April 2014
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Contents
Overview
This chapter details the MARINa (MAster Regulator INference algorithm) method of Master Regulator Analysis. Please see the Master Regulator Analysis chapter for a higher-level introduction.
MARINa uses gene set enrichment analysis (GSEA) to calculate if the regulon of a TF is enriched for genes that are differentially expressed among 2 classes of microarrays. Please note that this does not involve any of the special gene lists available for use with the GSEA algorithm, such as MSigDB. Following the GSEA runs, MARINa performs an additional "shadow" analyses. The "Synergy" analysis option is not currently supported.
The MARINa algorithm runs on a computational cluster at Columbia and access is restricted. It is run from geWorkbench using a grid service, selected using the "Services" tab.
The MARINa algorithm differs substantially from the "FET" method described in the MRA-FET chapter.
- The list of signature markers is determined using a t-test directly in the MARINa algorithm, rather than being loaded separately as for the FET method.
- The list of candidate Master Regulators is taken from the hub markers in the network, rather than using a separate list as in the "FET" method.
- MARINa uses "case" and "control" designations of arrays in the Arrays component if provided. However, unlike the FET method, it will also run if only "case" arrays are designated. This should be used only where the loaded expression dataset has been pre-processed to represent fold-change values. geWorkbench itself cannot produce such a dataset.
A special 2-tailed version of GSEA is used, as described in Lim WK, Lyashenko E, Califano A (2009).
Inputs
Main Tab
These inputs and the GUI are described in detail in the chapter Master Regulator Analysis.
- Network - the network (e.g. from ARACNe) upon which MARINa will operate.
- If the network is loaded into MARINa as gene symbols or Entrez IDs, it will be transformed (expanded) to include all probesets annotated to each such gene if an annotation file has been loaded for the expression dataset.
- GSEA P-Value: The enrichment score p-value below which a regulon is considered enriched in differentially expressed genes.
MARINa Tab
- GSEA and shadow/synergy analysis run parameters:
- Minimum Number of Targets: minimum number of genes in a regulon for a GSEA run (a positive integer).
- Minimum Number of Samples: minimum number of arrays PER CLASS (e.g. case or control) in the input microarray set in order to run sample-based permutations in GSEA (a positive integer). If sample-based permutations cannot be used, then probe shuffling will be used instead. The default is set to 6, but having a least 7 is better and 8 per class will give much better significance.
- Number of GSEA permuations: number of GSEA permutations to compute enrichment score distribution (a positive integer).
- GSEA Tail: whether 1-tailed (1) or 2-tailed GSEA (2) is to be performed. If all correlations in the network file are greater than zero, then one-tail GSEA will be performed regardless of the value the user assigns to "tail".
- Shadow P-value: significance threshold for shadow analysis.
- SynergyP-value: significance threshold for synergy analysis.
- Retrieve prior result with ID (checkbox) - if checked, all parameter fields are disabled and the prior ID field is enabled. The user can retrieve the results of a previous run. In this case, the "case" and "control" array sets do not need to be activated - they are retrieved from the MARINa run directory on the server.
GSEA Tail
If a two-tailed GSEA run is requested, the MARINa algorithm will divide a TF's regulon genes into positive and negative correlation groups, based on the Spearman's correlation between the expression of the TF and each gene in its regulon. However, if all correlations are found to be positive, only a single GSEA run will be performed. The correlation values are calculated by geWorkbench, or can also be provided directly if the "5-column network file" is used.
Sample Shuffling
Sample shuffling is done with random draws. If the number of samples per class is too low, the number of unique draws may be much lower than the number of permutations and lead to a false calculation of power.
The number of possible permutations is given by N!/2*{(N/2)!(N/2)!], where N is the total number of samples in the two classes together. The two in the divisor is because each draw of case and control arrays can occur in either order with identical result. That is, the two outcomes are not distinguishable in the calculation.
Note also that because random draws are performed, the number of unique draws will be less than the number of draws. If the number of samples per class is low, then many repeats of the same draw will be encountered.
For N=14 (that is, 7 per class), the number of unique results is 1716. For N=16 (8 per class), there are 6435 unique draws.
In addition, it is better if the number of samples per class is balanced, rather than say 6 in one class and 60 in the other class.
Finally, it is recommended to treat the calculated p-values with scepticism. One common correction is to multiply calculated p-values by a factor of 10, so a calculated p-value of 0.001 is treated instead as 0.01. This correction is not included in geWorkbench, but can be set by the user if so desired. That is, if you want a p-value of 0.01, instead set a p-value of 0.001.
Unpaired/Paired Runs
Normally, the user will specify two classes of arrays, e.g. "case" and "control". Under these conditions, an unpaired calculation is performed. However, if the user only includes one class of array (control), then "paired" analysis is performed. The assumption here is that the values are not direct expression values but are fold-change values for paired samples from patients. Such a pre-analyzed dataset would need to be loaded into geWorkbench, as there is no built-in method to performed such a paired analysis.
Network alternative 5-column file format
MARINa in geWorkbench will normally be set up to work with a network that is either already in the Workspace, or that is loaded from disk in a standard format, e.g. an ARACNe-style adjacency matrix or SIF file. geWorkbench will generate a file in the following 5-column format which is then sent to the remote MARINa service. However, a file in this format can also be directly loaded into the MARINa component. In this case, the values contained in the file are used directly, and are not replaced by values calculated by geWorkbench.
Each line represents a network edge and comprises five tab-delimited columns:
- Transcription factor id: A string that provides the transcription factor end of the edge. This is usually a probeset id or a gene symbol.
- Target id: A string that provides the target end of the edge. This is usually a probeset id or a gene symbol
- Mutual information: The mutual information (MI) of the edge (a real number). If the edge MI is not known/available, the value 1 can be entered here.
- Spearman's correlation: The Spearman's correlation for the edge, computed on the original microarray set that gave rise to the ARACNe network (a real number). If not known/available, the value 1 can be entered here.
- P-value for Spearman's correlation. The p-value associated with Spearman's correlation found in the previous column (a real number between 0 and 1). It this p-value is not known/available, a value of 0 can be entered here.
Example data files for running MARINa
MARINa runs, even on a large computational cluster, can be very time-consuming. We include here a small test dataset with which to demonstrate running MARINa.
Example data files (.zip). Includes expression file, network file (5-column format) and files defining two microarray classes. The individual files are:
- mra_grid_data.exp - Affymetrix File Matrix format expression file.
- mra_grid_5colnetwork.txt - A network file matching the expression data. This file is in the "5-column" format and can only be loaded directly into the MRA component. Network files in the adjacency matrix and SIF formats should normally be used, this file is for demonstration only.
- mra_grid_ixclass1.csv - array set definition file, for loading into the Arrays component to define phenotype class 1 (Case).
- mra_grid_ixclass2.csv - array set definition file, for loading into the Arrays component to define phenotype class 2 (Control).
Note - This is a much smaller dataset than the one used to generate results shown further below.
Running MARINa
Prerequisites
- Expression Data
- An expression data set must be loaded in geWorkbench.
- The expression data should be log transformed for best results with the t-test.
- Phenotypic classes - specified in the Arrays component in the currently active list view.
- Two classes - Normally, "case" (reported as class1) and "control" (reported as class2) array sets should be defined and activated in the Arrays component. There can be no arrays that belong to both classes. If there are, a warning will be displayed and the analysis will not be launched. With two specified classes, the calculation will be run in "unpaired" mode.
- Single class - However, if only one class is present (e.g. if no arrays are marked "case" or activated, then only a single class will be used. In this case, the calculation is run in "paired" mode. This mode assumes that the expression data already represents fold-change results, a type of data manipulation that is not directly supported in geWorkbench. This data should be either e.g. log2(case/control) or log2(case) - log2(control).
- Network file - a network that is already present in the Workspace as a child of the expression dataset can be used, or a network can be loaded directly into the MRA component via its Main tab.
Example of activating "case" and "control" array sets in the Arrays component.
Setting the MARINa Parameters
Please note that MARINa analysis can only be selected in the Services tab as a grid service. Just opening the MARINa parameters tab does not select the MARINa service.
Main Tab
- In the Main tab of the MRA component, select or load a network.
- Set the desired GSEA p-value.
Please see the description of this tab in the Master Regulator Analysis chapter.
Selecting the MARINa grid service
- You must search for and activate the MARINa grid service in the MRA services tab. If the local service is selected it will run the FET method.
The figure below shows the Services tab after the MARINa grid service has been retrieved and selected.
MARINa Parameters
- Inspect and if desired change the parameters. See the section on "Inputs" above.
MARINa Parameters - Retrieve prior result
- If the "Retrieve prior results" box is checked, all other parameter fields will be disabled and disregarded.
- In this case, it is not necessary to activate "case" and "control" sets. They will be retrieved from the server for use in generating the "bar-code" display.
- Enter the MARINa runID from a previous run of MARINa (this runID is found in the name of the MARINa result node in the Workspace, e.g. "mra30980", see an example in the Results section below).
Analyze
Push the Analyze button to launch the analysis on the grid service. You will be prompted to enter a grid username and password.
Results
The MARINa calculation result is placed in the Workspace as a new data node. The name of the node takes the form "MARINa Result: mranum, where num is a job id assigned on the server.
Results Viewer
Note - if no significant MRs are found, an empty result node is returned to the Workspace. The MRA viewer will appear but be empty.
First Row of Controls
- Symbol - display the markers using their gene symbol (if available)
- Probeset - display markers using their marker (probeset) name.
- Graphs for top ... - Restrict the "bar-code graph" to at most the specified number of entries.
- Bar height ... - set the height of the vertical lines in the bar graph in pixels.
- Bars for
- Regulon - draw bars for each marker in the hub marker's regulon
- GSEA Leading Edge - draw bars for only those markers in the GSEA leading edge set.
Second Row of Controls
Export Table
This command will export the entire master regulator results table to a file. It exports the same information shown on screen, sorted in the same way if the table has been sorted on one of the columns. The user can choose to export the table in CSV (.csv) or tab-delimited text format (.txt).
Export all targets
This command writes a file to disk containing each MR in the table, along with each MR's GSEA leading-edge targets and a differential expression value for each target (-log10(P-value)*sign(t-value)).
Each master regulator is listed on a line, followed by its targets with their transformed t-test values. Each MR is separated by a blank line from the preceding section. The order in the file is not changed by sorting the results table prior to export.
Export File format:
marker, gene name, -log10(P-value)*sign(t-value)
Example:
220462_at, CSRNP3 200660_at, S100A11, 12.541623 201474_s_at, ITGA3, 7.4126143 202910_s_at, CD97, 10.785 ....
202614_at, SLC30A9 160020_at, MMP14, 4.415267 200808_s_at, ZYX, 9.006654 200859_x_at, FLNA, 8.309419 ....
Exported files automatically receive a ".csv" file name extension.
Add Targets to Set
Create a new marker set in the Markers component containing the GSEA leading-edge targets for the selected master regulator. The set is named after the master regulator.
MARINa Viewer Table Columns
- Master Regulator: transcription factor gene name or probeset id.
- GSEA P-value: p-value of the GSEA result.
- Markers in regulon:
- NumLedge: sum of NumLedgePos and NumLedgeNeg from the Table Viewer. The number of genes in the combined GSEA leading edge.
- OddRatio: odds of a regulon gene being in the GSEA leading edge set / odds of a regulon gene being in the GSEA trailing edge set.
- NES: GSEA normalized enrichment score for the regulon of the TF.
- absNES: absolute value of NES
- Mode: taken from the sign of the NES. Indicates whether the activity of the TF is positive or repressed in the "case" vs "control" samples.
Bar Graph View
Description
The bar-code graph is created based on ranked differential expression results for all markers in the dataset. However, only markers in the TF's regulon or GSEA-leading edge set (depending on the setting chosen) are drawn as vertical bars, allowing their positions in the entire set of markers to be visualized.
The value used to calculate the differential expression display is -log10(p-value) * sign (t-value), as in the detailed table display described above.
- Vertical bars - The vertical bars correspond to ranked positions of the markers belonging to each TF's regulon or intersection set (depending on the setting chosen).
- Bar position on horizontal axis - bars for displayed markers are positioned using their rank in a list of all markers ordered by (-log10(p-value) * sign (t-value)), calculated using a t-test for differential expression.
- Bar Color - The color of each bar indicates the sign of the Spearman's Correlation between the expression profile of the TF and its targets (calculated using data from all microarrays in the experiment, not just those in the case and control sets):
- Red means that the two markers are positively correlated (r >= 0) while
- Blue means that correlation is negative (r < 0).
- The color intensity of each bar is scaled to represent the number of overlapping bars at any given point in the graph.
- Gradient - The red-blue gradient at the bottom of the graph qualitatively represents the ranking between the lowest (blue) and the highest (red) test statistic. The white area in the middle represents the middle of the ranking (not necessarily zero differential expression). This gradient does not represent the colors used for the bars themselves, only the relative position in the ranked differential expression results.
Detailed Examples
Detail for CEBPD:
The bar graph shown above, for CEBPD, indicates that the expression profile of CEBPDis positively correlated with its regulon targets having positive differential expression in the "case", mesenchymal phenotype. FOSL2 is more active in the mesenchymal than in the proneural phenotype.
Detail for ZNF248:
The bar graph shown above, for ZNF238, indicates that expression profile of ZNF248 is positively correlated with its regulon targets having positive differential expression in the control, proneural phenotype. ZNF248 is less active in the mesenchymal phenotype and more active in the proneural phenotype.
Save Image
Via a right-click menu on the bar graph, the user can save an image of the displayed bar graph to
- the Workspace as an image snapshot, or
- directly to a file on disk. Available formats are PNG, JPEG, TIF and BMP.
Table Viewer
Result Columns
This example was run with sample shuffling. When probe shuffling is used, the MeanClass1 and MeanClass2 columns are not shown.
The MARINa results file contains one line for each TF whose GSEA enrichment score renders it significant above the user-specified p-value threshold (pvalue_gsea), as long as such TF is not "shadowed" by other significant TFs.
NOTE: synergy analysis is not performed in this version of MARINa.
The columns represented in the results are as follows:
- TFsym: transcription factor id (usually this is the probeset id).
- GeneName: transcription factor gene name.
- NumPosGSet: number of genes (among those in the regulon of the transcription factor) which are positively regulated by the TF. Only genes represented in the microarray set are counted.
- NumNegGSet: number of genes (among those in the regulon of the transcription factor) which are negatively regulated by the TF. Only genes represented in the microarray set are counted.
- NumLedgePos: number of genes (among those counted under the NumPosGSet column) which are in the GSEA leading edge.
- NumLedgeNeg: number of genes (among those counted under the NumNegGSet column) which are in the GSEA leading edge.
- NumLedge: sum of NumLedgePos and NumLedgeNeg.
- ES: GSEA enrichment score for the regulon of the TF.
- NES: GSEA normalized enrichment score for the regulon of the TF.
- absNES: absolute value of NES
- PV: p-value of normalized enrichment score (NES).
- OddRatio: odds of a regulon gene being in the GSEA leading edge set / odds of a regulon gene being in the GSEA trailing edge set.
- TScore - t-test t-statistic.
- MeanClass1: mean expression value of TF among all "Class 1" arrays.
- MeanClass2: mean expression value of TF among all "Class 2" arrays.
- Note - there are no columns for MeanClass1 and MeanClass2 when probe shuffling is performed.
- Original MRA/Recovered_MRA: a value of 1 in this column means that the TF was found to be enriched by GSEA (above the significance level pvalue_gsea) and that it was not shadowed by any other TF. A value of 0 means that the TF was found to be enriched by GSEA and that it was shadowed by another TF and that it remained enriched even after the common targets with the other TF were removed from its regulon. For details on Shadow analysis please see pg. 17 of the Supplemental text to Lefebvre et al. 2010..
Controls
- Sorting - The table can be sorted on the value of any column by clicking on the column header.
- Export Table button - Export the table to a CSV format file. The table contents are exported in the same order shown on screen, preserving sorting on any column values.
References
- Basso K, Margolin AA, Stolovitzky G, Klein U, Dalla-Favera R, Califano A (2005). Reverse engineering of regulatory networks in human B cells. Nat Genet 37(4):382-390 (link to paper).
- Carro MS, Lim WK, Alvarez MJ, Bollo RJ, Zhao X, Snyder EY, Sulman EP, Anne SL, Doetsch F, Colman H, Lasorella A, Aldape K, Califano A, Iavarone A (2010) The transcriptional network for mesenchymal transformation of brain tumors. Nature 463(7279):318-25.
- Lefebvre C, Rajbhandari P, Alvarez MJ, Bandaru P, Lim WK, Sato M, Wang K, Sumazin P, Kustagi M, Bisikirska BC, Basso K, Beltrao P, Krogan N, Gautier J, Dalla-Favera R, Califano A (2010) A human B-cell interactome identifies MYB and FOXM1 as master regulators of proliferation in germinal centers. Mol Syst Biol. 6:377. PMID: 20531406 (link to paper).
- Lim WK, Lyashenko E, Califano A (2009) Master regulators used as breast cancer metastasis classifier. Pac Symp Biocomput. 2009:504-15. PMID 19209726, (link to paper).