Difference between revisions of "AmiGO Manual: Term Enrichment"
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The AmiGO interface gives the user the ability to change the ''maximum p-value'' and the ''minimum number of gene products'' that are used when running the algorithm. Please see the [http://www.ncbi.nlm.nih.gov/pubmed/15297299 published material] for a more detailed discussion of what these values mean and how to use them meaningfully. To determine whether any GO terms annotate a specified list of genes at a frequency greater than that would be expected by chance, GO::TermFinder calculates a P-value using the hypergeometric distribution, (
The AmiGO interface gives the user the ability to change the ''maximum p-value'' and the ''minimum number of gene products'' that are used when running the algorithm. Please see the [http://www.ncbi.nlm.nih.gov/pubmed/15297299 published material] for a more detailed discussion of what these values mean and how to use them meaningfully. To determine whether any GO terms annotate a specified list of genes at a frequency greater than that would be expected by chance, GO::TermFinder calculates a P-value using the hypergeometric distribution, ([http://www.ncbi.nlm.nih.gov/pubmed/15297299 ]).
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Latest revision as of 15:43, 28 October 2013
The Term Enrichment tool can be used to discover what a set of genes may have in common by examining annotations and finding significant shared GO terms. The algorithm employed by the tool attempts to determine whether an observed level of annotation for a group of genes is significant within the context of annotation for all genes within the genome; examples of studies that have used this algorithm are PMID:15492223 and PMID:14561723. AmiGO's Term Enrichment tool, which is based on the GO-TermFinder perl module by Gavin Sherlock and Shuai Weng at Stanford University, allows users to specify a list of genes, define a background set against which the significance will be calculated and set the p-value (significance indicator) cut-off.
Term enrichment is a very useful method for analyzing data from large scale experiments, such as gene clusters from microarray expression data. For a more detailed discussion of the algorithm, please see the published material on GO::TermFinder. The p-values returned by this software undergo Bonferroni correction.
Caution: Please note that by default, this tool uses annotation datasets that include electronically inferred (IEA) data. The results for organisms where a proportion of the annotation coverage is IEA-based will not match/correspond only to the annotations made by curators. For more information about what data AmiGO uses, please see the overview page.
Gene Product List
The user may upload a plain text file with a whitespace separated list of gene product identifiers. These may be a mix of gene product symbols, synonyms or accessions. If the list is too large for manual input, the user may instead upload a either a file containing identifiers (as listed above) or a gene association file. Also, if AmiGO finds any gene product identifiers that are ambiguous or not found, the user will be informed before the end of the process.
Where possible, we recommend users should supply their own background set.
Your background set should be your whole gene/gene product set from the experiment being analyzed i.e. the list from which your gene/gene product list of interest has been derived. This might be all genes on your microarray, for example, or possibly all genes in the genome of your organism. If you do not provide a background set, the database filter selected will be used as the background set, that is, all genes for that database that have GO annotation.
The background set may be input in a very similar way to the gene product list above. The only difference is the addition of an optional database filter--the user must either enter/upload a background set, select a database filter, or do both.
If the user enters a background set and selects a database, the inputted background set will be filtered so that only gene products that are found in that database will be used in the calculations. This can help to remove a lot of possible ambiguity in the inputted set. The abbreviations used in the filter are as follows:
|AspDB||Aspergillus Genome Database||Aspergillus nidulans|
|CGD||Candida Genome Database||Candida albicans|
|EcoCyc||EcoCyc and EcoliWiki||Escherichia coli K-12|
|Ensembl||Ensembl project Genome Databases||Multi-species|
|GeneDB_Lmajor||Sanger GeneDB||Leishmania major|
|GeneDB_Pfalciparum||Sanger GeneDB||Plasmodium falciparum|
|GeneDB_Spombe||Sanger GeneDB||Schizosaccharomyces pombe|
|GeneDB_Tbrucei||Sanger GeneDB||Trypanosoma brucei|
|JCVI_CMR||The J. Craig Venter Institute||Multi-species, bacterial|
|MGI||Mouse Genome Initiative||Mus musculus|
|NCBI||National Center for Biotechnology Information||Multi-species|
|NCBI_GP||NCBI GenPept, proteins||Multi-species|
|NCBI_NP||NCBI RefSeq, proteins||Multi-species|
|PAMGO_VMD||Plant-Associated Microbe Gene Ontology (PAMGO) consortium||Multi-species, plant-associated microbes|
|PDB||Protein Data Bank||Multi-species|
|PseudoCAP||Pseudomonas aeruginosa Community Annotation Project||Pseudomonas aeruginosa|
|RGD||Rat Genome Database||Rattus norvegicus|
|RefSeq||NCBI Reference Sequence||Multi-species|
|SGD||Saccharomyces cerevisiae Genome Database||Saccharomyces cerevisiae|
|SGN||SOL Genomics Network||Multispecies, plant|
|TAIR||The Arabidopsis Information Resource||Arabidopsis thaliana|
|TIGR_CMR||The Institute for Genomic Research||Multi-species, bacterial|
|UniProtKB||UniProt Protein Knowledge Base||Multispecies|
|UniProtKB/Swiss-Prot||UniProt reviewed, manually annotated||Multispecies|
|UniProtKB/TrEMBL||UniProt unreviewed, automatically annotated||Multispecies|
|ZFIN||Zebrafish Information Network||Danio rerio|
- (For more detail see the GO xref page)
Otherwise, if the user did not enter a background set, the selected database will be used as the background set. If you do not supply a background set, we recommend you do not use a multi-species database as a filter as this will lead to all genes from all species being used as your background set which may give unreliable results. We currently do not have a filter directly corresponding to the human genome/proteome, so we recommend for human gene lists you always supply your own background set.
By default, this tool uses annotation datasets that do not include IEA (electronically inferred) data. The results for organisms where a proportion of the annotation coverage is IEA-based will match/correspond only to the annotations made by curators. If you wish to include IEA data, please check the "use IEAs" box on the form.
The AmiGO interface gives the user the ability to change the maximum p-value and the minimum number of gene products that are used when running the algorithm. Please see the published material for a more detailed discussion of what these values mean and how to use them meaningfully. To determine whether any GO terms annotate a specified list of genes at a frequency greater than that would be expected by chance, GO::TermFinder calculates a P-value using the hypergeometric distribution, (PMID:15297299).
Clicking on Display advanced result options gives advanced users access to additional settings.
In addition to the standard results that are returned from this page, the user may also select all results, which will return all results without any kind of threshold filtering (and ignoring any threshold inputs specified above).
In addition to the standard html page results, the user may instead select a tab-delimited file or an xml file. Please be warned that the XML file is in an unstable internal format and should only really be used by people prefer parsing XML over other types.
The columns of the tab-delimited format are as follows:
- acc of the GO term
- aspect of the GO
- GO term name
- p-value (see thresholds above)
- number of gene products in the sample set that are annotated
- number of gene products in the sample set
- number of gene products in the background set that are annotated
- number of gene products in the background set
- list of gene products in the sample set annotated to the GO term
When you have received results from the Term Enrichment tool, you will be given the option to visualize your results within the top results section block. Since the visualization is produced by the AmiGO_Manual:_Visualize component, relation coloring conventions can be found there. For the node coloration, the following slide down table currently applies:
Unfortunately, at this time, the term enrichment tool and slimmer both suffer from timeout and load issues on their They are limited in the amount of work that they can accomplish before a timeout event occurs either on the client or server. Due to these limitations, the current tool is not really designed to work on sets beyond a certain size. Unfortunately, this size is hard to pinpoint: depending on input type, size, and database warmup, the results available may be very different. If you get a timeout error, or see a phrase like "Query execution was interrupted", you have probably reached the time resource limit.
In the fairly near future we'll be moving to a Galaxy based workflow system that will not have these same limitations in size and time. Until then, you may wish to take a look at other available third-party tools:
Or look at a tool like Ontologizer: