Abstract
It is still largely unknown how mutations in different genes cause similar diseases – a condition known as locus heterogeneity. A likely explanation is that the different proteins encoded by the locus heterogeneity genes participate in the same biological function and, specifically, that they belong to the same protein complex. Here we report that, in up to 30% of the instances of locus heterogeneity, the disease-causing proteins are indeed members of the same protein complex. Moreover, we observed that, in many instances, the diseases and protein complexes only partially intersect. Among the possible explanations, we surmised that some genes that encode proteins in the complex have not yet been reported as causing disease and are therefore candidate disease genes. Mutations of known human disease genes and murine orthologs of candidate disease genes that encode proteins in the same protein complex do in fact often cause similar phenotypes in humans and mice. Furthermore, we found that the disease-complex intersection is not only incomplete but also non-univocal, with many examples of one disease intersecting more than one protein complex or one protein complex intersecting more than one disease. These limits notwithstanding, this study shows that action on proteins in the same complex is a widespread pathogenic mechanism underlying numerous instances of locus heterogeneity.
Highlights
It is still largely unknown how mutations in different genes cause similar diseases – a condition known as locus heterogeneity
We counted the intersections between this set of locus heterogeneity (LH)-diseases and the protein complexes (PC)
We found that 21.8% of the LH-diseases (36 out of 165) share www.nature.com/scientificreports at least two proteins with at least one PC
Summary
It is still largely unknown how mutations in different genes cause similar diseases – a condition known as locus heterogeneity. These limits notwithstanding, this study shows that action on proteins in the same complex is a widespread pathogenic mechanism underlying numerous instances of locus heterogeneity Gene mutations exert their primary and direct effects at the molecular level, by affecting the structure and function of the gene products that the genes encode. A mutation in a given disease-causing gene is likely to affect – even disrupt – the overall structure and function of the PC containing the protein encoded by the mutated gene[3] This hypothesis is borne out by studies of protein-protein interactions, showing that physical interactions are frequent among proteins responsible for similar phenotypes[4,5,6,7,8]. The mutations of different genes that result in the same disease (i.e. in LH) could be explained mechanistically as alternative ways of affecting the same cellular machinery (the PC)
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