Abstract
Almost all (99.9%) nucleotide bases are exactly the same in all people, however, the remaining 0.1% account for about 1.4 million locations where single-base DNA differences/polymorphisms (SNPs) occur in humans. Some of these SNPs, called non-synonymous SNPs (nsSNPs), result in a change of the amino acid sequences of the corresponding proteins affecting protein functions and interactions. This review summarizes the plausible mechanisms that nsSNPs may affect the normal cellular function. It outlines the approaches that have been developed in the past to predict the effects caused by nsSNPs with special emphasis on the methods that use structural information. The review provides systematic information on the available resources for predicting the effects of nsSNPs and includes a comprehensive list of existing SNP databases and their features. While nsSNPs resulting in amino acid substitution in the core of a protein may affect protein stability irreversibly, the effect of an nsSNP resulting to a mutation at the surface of a protein or at the interface of protein-protein complexes, could, in principle be, subject of drug therapy. The importance of understanding the effects caused by nsSNP mutations at the protein-protein and protein-DNA interfaces is outlined.
Keywords: nsSNP, residue mutation, disease-causing SNP, protein-protein interactions, protein stability
Related Books
Industrial Applications of Soil Microbes
Industrial Applications of Soil Microbes
Algal Biotechnology for Fuel Applications
Biopolymers Towards Green and Sustainable Development
Terpenoids: Recent Advances in Extraction, Biochemistry and Biotechnology
Environmental Microbiology: Advanced Research and Multidisciplinary Applications
Biomarkers in Medicine
Industrial Applications of Soil Microbes
Recent Advances in Biotechnology
Sustainable Utilization of Fungi in Agriculture and Industry
20