Difference between revisions of "Interaction prediction"

Revision as of 16:54, 29 January 2012

Interaction prediction

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Once an interaction has been experimentally determined in a (model) organism, under what conditions can we infer that the homologues of the interaction partners interact as well? Just as in comparative sequence analysis, we need to consider the degree of sequence similarity, but other aspects also come into play. Just as in function prediction, predictions may also be made from first principles.

Introductory reading

Zinman et al. (2011) Biological interaction networks are conserved at the module level. BMC Syst Biol 5:134. (pmid: 21861884)

[ PubMed ] [ DOI ] Abstract

Further reading and resources

Yu et al. (2004) Annotation transfer between genomes: protein-protein interologs and protein-DNA regulogs. Genome Res 14:1107-18. (pmid: 15173116)

[ PubMed ] [ DOI ] Abstract

Mika & Rost (2006) Protein-protein interactions more conserved within species than across species. PLoS Comput Biol 2:e79. (pmid: 16854211)

[ PubMed ] [ DOI ] Abstract

Experimental high-throughput studies of protein-protein interactions are beginning to provide enough data for comprehensive computational studies. Today, about ten large data sets, each with thousands of interacting pairs, coarsely sample the interactions in fly, human, worm, and yeast. Another about 55,000 pairs of interacting proteins have been identified by more careful, detailed biochemical experiments. Most interactions are experimentally observed in prokaryotes and simple eukaryotes; very few interactions are observed in higher eukaryotes such as mammals. It is commonly assumed that pathways in mammals can be inferred through homology to model organisms, e.g. the experimental observation that two yeast proteins interact is transferred to infer that the two corresponding proteins in human also interact. Two pairs for which the interaction is conserved are often described as interologs. The goal of this investigation was a large-scale comprehensive analysis of such inferences, i.e. of the evolutionary conservation of interologs. Here, we introduced a novel score for measuring the overlap between protein-protein interaction data sets. This measure appeared to reflect the overall quality of the data and was the basis for our two surprising results from our large-scale analysis. Firstly, homology-based inferences of physical protein-protein interactions appeared far less successful than expected. In fact, such inferences were accurate only for extremely high levels of sequence similarity. Secondly, and most surprisingly, the identification of interacting partners through sequence similarity was significantly more reliable for protein pairs within the same organism than for pairs between species. Our analysis underlined that the discrepancies between different datasets are large, even when using the same type of experiment on the same organism. This reality considerably constrains the power of homology-based transfer of interactions. In particular, the experimental probing of interactions in distant model organisms has to be undertaken with some caution. More comprehensive images of protein-protein networks will require the combination of many high-throughput methods, including in silico inferences and predictions. http://www.rostlab.org/results/2006/ppi_homology/

Brown & Jurisica (2007) Unequal evolutionary conservation of human protein interactions in interologous networks. Genome Biol 8:R95. (pmid: 17535438)

[ PubMed ] [ DOI ] Abstract

Saeed & Deane (2008) An assessment of the uses of homologous interactions. Bioinformatics 24:689-95. (pmid: 18042554)

[ PubMed ] [ DOI ] Abstract

MOTIVATION: Protein-protein interactions have proved to be a valuable starting point for understanding the inner workings of the cell. Computational methodologies have been built which both predict interactions and use interaction datasets in order to predict other protein features. Such methods require gold standard positive (GSP) and negative (GSN) interaction sets. Here we examine and demonstrate the usefulness of homologous interactions in predicting good quality positive and negative interaction datasets. RESULTS: We generate GSP interaction sets as subsets from experimental data using only interaction and sequence information. We can therefore produce sets for several species (many of which at present have no identified GSPs). Comprehensive error rate testing demonstrates the power of the method. We also show how the use of our datasets significantly improves the predictive power of algorithms for interaction prediction and function prediction. Furthermore, we generate GSN interaction sets for yeast and examine the use of homology along with other protein properties such as localization, expression and function. Using a novel method to assess the accuracy of a negative interaction set, we find that the best single selector for negative interactions is a lack of co-function. However, an integrated method using all the characteristics shows significant improvement over any current method for identifying GSN interactions. The nature of homologous interactions is also examined and we demonstrate that interologs are found more commonly within species than across species. CONCLUSION: GSP sets built using our homologous verification method are demonstrably better than standard sets in terms of predictive ability. We can build such GSP sets for several species. When generating GSNs we show a combination of protein features and lack of homologous interactions gives the highest quality interaction sets. AVAILABILITY: GSP and GSN datasets for all the studied species can be downloaded from http://www.stats.ox.ac.uk/~deane/HPIV.

Seidl & Schultz (2009) Evolutionary flexibility of protein complexes. BMC Evol Biol 9:155. (pmid: 19583842)

[ PubMed ] [ DOI ] Abstract

BACKGROUND: Proteins play a key role in cellular life. They do not act alone but are organised in complexes. Throughout the life of a cell, complexes are dynamic in their composition due to attachments and shared components. Experimental and computational evidence indicate that consecutive addition and secondary losses of components played a major role in the evolution of some complexes, mostly without affecting the core function. Here, we analysed in a large scale approach whether this flexibility in evolution is only limited to a distinct number of complexes or represents a more general trend. RESULTS: Focussing on human protein complexes, we based our analysis on a manually curated dataset from HPRD. In total, 1,060 complexes with 6,136 proteins from 2,187 unique genes were considered. We computed interologs in 25 different species and predicted the composition of complexes. Over the analysed species, the composition of most complexes was highly flexible and only 25% of all genes were never lost. Even if one component was lost at a particular point in time, the fraction of observed second, independent losses of additional components was high (75% of all complexes affected). Still, loss of whole complexes happened rarely. This biological signal deviated significantly from random models. We exemplified this trend on the anaphase promoting complex (APC) where a core is highly conserved throughout all metazoans, but flexibility in certain components is observable. CONCLUSION: Consecutive additions and losses of distinct units is a fundamental process in the evolution of protein complexes. These evolutionary events affecting genes coding for units in human protein complexes showed a significantly different phylogenetic pattern compared to randomly selected genes. Determination of taxon specific attachments or losses might be linked to specific cellular or morphological features. Thus, protein complexes contain not only structural and functional, but also evolutionary cores.

Poupon & Janin (2010) Analysis and prediction of protein quaternary structure. Methods Mol Biol 609:349-64. (pmid: 20221929)

[ PubMed ] [ DOI ] Abstract

Clark et al. (2011) Using coevolution to predict protein-protein interactions. Methods Mol Biol 781:237-56. (pmid: 21877284)

[ PubMed ] [ DOI ] Abstract

@@ Line 8: / Line 8: @@
-Once an interaction has been experimentally determined in a (model) organism, under what conditions can we infer that the homologues of the interaction partners interact as well? Just as in comparative sequence analysis, we need to consider the degree of sequence similarity, but other aspects come into play as well. Just as in function prediction, predictions may also be made from first principles.
+Once an interaction has been experimentally determined in a (model) organism, under what conditions can we infer that the homologues of the interaction partners interact as well? Just as in comparative sequence analysis, we need to consider the degree of sequence similarity, but other aspects also come into play. Just as in function prediction, predictions may also be made from first principles.
 __TOC__
-<!--
+&nbsp;
 ==Introductory reading==
 <section begin=reading />
+{{#pmid:21861884}}   <!-- intro. reading -->
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+&nbsp;
 ==Contents==
 The concept of ''Interologs''.
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+&nbsp;
 ==References==
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+&nbsp;
 ==Further reading and resources==
+{{#pmid:15173116}}
+{{#pmid:16854211}}
+{{#pmid:17535438}}
+{{#pmid:18042554}}
+{{#pmid:19583842}}
+{{#pmid:20221929}}
+{{#pmid:21877284}}
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 [[Category:Computational_Systems_Biology]]
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Difference between revisions of "Interaction prediction"

Revision as of 16:54, 29 January 2012

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