BIN-PPI-Databases

Protein-Protein Interaction Databases

Keywords: IntAct, iRef,

Abstract

Exploring IntAct and BioGRID PPI databases.

This unit ...

Prerequisites

You need the following preparation before beginning this unit. If you are not familiar with this material from courses you took previously, you need to prepare yourself from other information sources:

Biomolecules: The molecules of life; nucleic acids and amino acids; the genetic code; protein folding; post-translational modifications and protein biochemistry; membrane proteins; biological function.

You need to complete the following units before beginning this one:

BIN-PPI-Concepts (Protein-Protein Interaction (PPI) Concepts)

Objectives

This unit will ...

... introduce issues surrounding the collection and curation of protein-protein interactions in databases;
... explore the Web interfaces to IntAct and BioGRID;
... discuss the limitations of interaction predictions based on homology ;

Outcomes

After working through this unit you ...

... can access IntAct and BioGRID and discover interactions with a protein of interest.

Deliverables

Time management: Before you begin, estimate how long it will take you to complete this unit. Then, record in your course journal: the number of hours you estimated, the number of hours you worked on the unit, and the amount of time that passed between start and completion of this unit.
Journal: Document your progress in your Course Journal. Some tasks may ask you to include specific items in your journal. Don't overlook these.
Insights: If you find something particularly noteworthy about this unit, make a note in your insights! page.

Evaluation

Evaluation: NA

This unit is not evaluated for course marks.

In high-throughput biology, the genome was the beginning. As Sydney Brenner has phrased it: we have now written the "white-pages" of the cell, fulfilling the "CAP-criterion" (Comprehensive, Accurate and Permanent). The next level is figuring out the way the parts work - if you will, the "Yellow Pages" - and many of us expect that substantial progress can be made by mapping their interactions. After all, physiological function can be described to a large part as the result of physical interaction.

Please note that there are different types of physical interactions. We most often think of complexes, either stable or transient homo- or heterooligomers when we speak of physical interactions. But there are also interactions between substrates and products and not all of them correspond to classical enzymatic pathways. Phosphorylation and dephosphorylation are processes of key importance in signal transduction and acetylation/deacetylation plays a critical role in regulatory pathways. Here, the substrates are proteins and the interaction with the modifying enzyme is of course a physical interaction.

Genetic interactions on the other hand are another story. Here the word interaction is used in an entirely different sense: it is not synonymous with contact it is synonymous with influence. In fact, most proteins that display genetic interactions would not be expected to interact physically as well. See the FND-PPI-Physical_vs_genetic unit for details.

Task:

Read the introductory notes on protein-protein interaction databases.

Read

Licata & Orchard (2016) The MIntAct Project and Molecular Interaction Databases. Methods Mol Biol 1415:55-69. (pmid: 27115627)

[ PubMed ] [ DOI ] Abstract

Chatr-Aryamontri et al. (2017) The BioGRID interaction database: 2017 update. Nucleic Acids Res 45:D369-D379. (pmid: 27980099)

[ PubMed ] [ DOI ] Abstract

Data Sources

Interaction databases have similar problems as sequence databases: the need for standards for abstracting biological concepts into computable objects, data integrity, search and retrieval, and the metrics of comparison. There is however an added complication: interactions are rarely all-or-none, and the high-throughput experimental methods have large false-positive and false-negative rates. This makes it necessary to define confidence scores for interactions. On top of experimental methods, there are also a variety of methods for computational interaction prediction. However, even though the "gold standard" are careful, small-scale laboratory experiments, different curated efforts on the same experimental publication usually lead to different results - with as little as 42% overlap between databases being reported.

Currently, likely the best integrated protein-protein interaction database is IntAct, at the EBI, which besides curating interactions from the literature hosts interactions from the IMEx consortium, an extensive data-sharing agreement between a number of general and specialized source databases.

Task:

Access IntAct and enter the UniProt ID for yeast Mbp1 P39678.
The EBI search directly returns a table of pairwise interactions; both partners are listed as a pair and, in each pair one of the partners should be YDL056W (the systematic name of yeast Mbp1).
How many different physical interaction detection methods do the IntAct records list? Follow the links and read their definitions. (Bravo to the IntAct developers, for defining their terms. In a better world, all the semantics of our databases should be similarly defined to be meaningful.)
Click on the "Graph" tab to load a network graph.
Switch "Merge edges" off to show the reported edges for this interaction individually. Which protein pair has the most interactions? Does this make sense?

But then what?

If you are like me, you would now like to be able to link expression profiles, information about known complexes, GO annotations, knock-out phenotypes etc. etc. Too bad.

Next, we explore the BioGRID interaction database. BioGrid stores physical and genetic interactions.

Task:

Access the the BioGRID database at the Samuel-Lunenfeld Research Institute, Mount Sinai Hospital, Toronto. Search for interactions of the Mbp1 gene by entering the gene name into the form field.
Follow the correct link in BioGrid for saccharomyces cerevisiae Mbp1 (YDL056W). All genes listed in that table have demonstrated interactions with Mbp1.
List what general experimental type(s) the BioGrid interactors come from. (In particular note the difference between yellow and green boxes).

You will note that some, but not all physical interactions listed by BioGRID and IntAct are the same according to a restrictive interpretation: same organism, same proteins, same experiment, same publication.

Which of the IntAct Mbp1 interactions are the same in BioGrid?
Check whether all of the interactions between the regulators of the G₁/S phase as per the digram in the "Systems Concepts" PDF are present in BioGRID interactions.

Now, what about MYSPE? Could you infer interactions between proteins whose orthologs interact in another species? Such predictions are called interologs (interacting homologs). Unfortunately, that does not appear to be the case. Confident prediction of interologs can only be achieved in cases of >80% joint sequence identity of both pairs^[1], a level of similarity that (I believe) none of our Mbp1 proteins achieves. Does this mean the pathways and interactions are not conserved? Certainly not. We expect a very high degree of conservation of the system's function, but we can't say for sure whether any two specific proteins interact in a different species the same way they interact in yeast. All we can do is to use annotation transfer for hypothesis generation. But that is a useful starting point.

Notes

↑

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/

Self-evaluation

If in doubt, ask! If anything about this learning unit is not clear to you, do not proceed blindly but ask for clarification. Post your question on the course mailing list: others are likely to have similar problems. Or send an email to your instructor.

About ...

Author:

Boris Steipe <boris.steipe@utoronto.ca>

Created:

2017-08-05

Modified:

2017-09-11

Version:

1.0

Version history:

1.0 First live
0.1 First stub

This copyrighted material is licensed under a Creative Commons Attribution 4.0 International License. Follow the link to learn more.

[1] 
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/

[1]

BIN-PPI-Databases

Contents

Abstract

This unit ...

Prerequisites

Objectives

Outcomes

Deliverables

Evaluation

Contents

Data Sources

Further reading, links and resources

Notes

Self-evaluation

Navigation menu

Personal tools

Namespaces

Variants

Views

More

Search

Sections

Tools