Abstract
Knowledge of protein–DNA binding specificity has important implications in understanding DNA metabolism, transcriptional regulation and developing therapeutic drugs. Previous studies demonstrated hydrogen bonds between amino acid side chains and DNA bases play major roles in specific protein–DNA interactions. In this paper, we investigated the roles of individual DNA strands and protein secondary structure types in specific protein–DNA recognition based on side chain-base hydrogen bonds. By comparing the contribution of each DNA strand to the overall binding specificity between DNA-binding proteins with different degrees of binding specificity, we found that highly specific DNA-binding proteins show balanced hydrogen bonding with each of the two DNA strands while multi-specific DNA binding proteins are generally biased towards one strand. Protein-base pair hydrogen bonds, in which both bases of a base pair are involved in forming hydrogen bonds with amino acid side chains, are more prevalent in the highly specific protein–DNA complexes than those in the multi-specific group. Amino acids involved in side chain-base hydrogen bonds favor strand and coil secondary structure types in highly specific DNA-binding proteins while multi-specific DNA-binding proteins prefer helices.
Highlights
Protein-DNA interactions play crucial roles in many cellular processes, such as transcription, DNA replication, DNA packaging and repair [1]
It has been demonstrated that hydrogen bonds between amino acid side chains and DNA bases play major roles in specific protein–DNA interactions [10,12,14,18]
It has been demonstrated that hydrogen bonds between amino acid side chains and DNA bases play major roles in specific protein–DNA recognition [10,12,14,18]
Summary
Protein-DNA interactions play crucial roles in many cellular processes, such as transcription, DNA replication, DNA packaging and repair [1]. Some DNA binding proteins are very specific, which include most type II restriction endonucleases, an important component of the restriction-modification (RM) systems in bacteria. These enzymes recognize and cleave foreign DNA at very specific target sequences while the target sites of the host. It has been demonstrated that aberrant mutations or genetic variations can alter the binding specificity and affect the gene expression, leading to various types of diseases [4,5]. Deciphering the protein–DNA recognition codes can help us better understand the mechanisms of these specific binding events, and help explain diseases caused by mutations that affect protein–DNA binding specificity and design therapeutic drugs
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