Abstract
Next-generation sequencing (NGS) technologies are providing genomic information for an increasing number of healthy individuals and patient populations. In the context of the large amount of generated genomic data that is being generated, understanding the effect of disease-related mutations at molecular level can contribute to close the gap between genotype and phenotype and thus improve prevention, diagnosis or treatment of a pathological condition. In order to fully characterize the effect of a pathological mutation and have useful information for prediction purposes, it is important first to identify whether the mutation is located at a protein-binding interface, and second to understand the effect on the binding affinity of the affected interaction/s. Computational methods, such as protein docking are currently used to complement experimental efforts and could help to build the human structural interactome. Here we have extended the original pyDockNIP method to predict the location of disease-associated nsSNPs at protein-protein interfaces, when there is no available structure for the protein-protein complex. We have applied this approach to the pathological interaction networks of six diseases with low structural data on PPIs. This approach can almost double the number of nsSNPs that can be characterized and identify edgetic effects in many nsSNPs that were previously unknown. This can help to annotate and interpret genomic data from large-scale population studies, and to achieve a better understanding of disease at molecular level.
Highlights
Next-generation sequencing (NGS) technologies have dramatically lowered gene sequencing costs, and are providing genomic information for an increasing number of healthy individuals and patient populations
We focused our analysis on the protein-protein interaction networks of six disease phenotypes for which there was detailed structural information for most of the individual proteins within the network, but low structural coverage of the protein-protein interfaces
An example of this was the phenotype myocardial infarction (MCI) [MIM: 608446]. This phenotype is not considered in databases like dSySmap, because all coding protein genes that have been reportedly associated to the disease harbor mutations for other diseases, and no non-synonymous single nucleotide polymorphisms (nsSNPs) can be found associated with this MIM code in humsavar (Table 1)
Summary
Structural analysis of pathological mutations on protein interaction networks The general aim of this work is to show how docking-based computational approaches can help characterizing disease-related mutations in PPIs at interactomic scale, where the majority of protein-protein interfaces have no structural data. The main goal of this work is to explore computational ways of characterizing pathological mutations possibly involved in protein-protein interactions for which there is no available structural data. We aimed to complete the interface structural and energetics data of this protein interaction network with our computational approach, to explore whether this can help characterizing some of these "unexplained" mutations
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