Abstract
Transmembrane protein coding genes are commonly associated with human diseases. We characterized disease causing mutations and natural polymorphisms in transmembrane proteins by mapping missense genetic variations from the UniProt database on the transmembrane protein topology listed in the Human Transmembrane Proteome database. We found characteristic differences in the spectrum of amino acid changes within transmembrane regions: in the case of disease associated mutations the non-polar to non-polar and non-polar to charged amino acid changes are equally frequent. In contrast, in the case of natural polymorphisms non-polar to charged amino acid changes are rare while non-polar to non-polar changes are common. The majority of disease associated mutations result in glycine to arginine and leucine to proline substitutions. Mutations to positively charged amino acids are more common in the center of the lipid bilayer, where they cause more severe structural and functional anomalies. Our analysis contributes to the better understanding of the effect of disease associated mutations in transmembrane proteins, which can help prioritize genetic variations in personal genomic investigations.
Highlights
Completion of the Human Genome Project resulted in a significant progression in genetic research
In this study we combined information obtained from the Human Transmembrane Proteome and UniProt databases to analyze the characteristics of naturally occurring missense genetic mutations in human Transmembrane proteins (TMPs)
The amino acid residue substitution matrix of the human transmembrane proteome reveals that the glycine to arginine changes are primarily responsible for this phenomenon (Table 4)
Summary
Completion of the Human Genome Project resulted in a significant progression in genetic research. Despite the spate of data emerging from these projects, the relevance of individual variations is not fully understood [4]. The smallest alteration in the sequence of these proteins can have severe or fatal [5,6,7,8] effect. These proteins participate in the communication between the cell and the environment, they can be potential targets of drugs. Analysis of genetic variations in the context of the 3D structure of PLOS ONE | DOI:10.1371/journal.pone.0151760. Analysis of genetic variations in the context of the 3D structure of PLOS ONE | DOI:10.1371/journal.pone.0151760 March 17, 2016
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