Abstract
Proteins with great sequence similarity usually have similar structure, function and other physicochemical properties. But in many cases, one or more of the physicochemical or functional characteristics differ, sometimes very considerably, among these homologous proteins. To better understand how critical amino acids determine quantitative properties of function in proteins, the responsible residues must be located and identified. This can be difficult to achieve, particularly in cases where multiple amino acids are involved. In this work, two triosephosphate isomerases with very high similarity from two related human parasites were used to address one such problem. We demonstrate that a seventy-fold difference in the reactivity of an interface cysteine to the sulfhydryl reagent methylmethane sulfonate in these two enzymes depends on three amino acids located far away from this critical residue and which could not have been predicted using other current methods. Starting from previous observations with chimeric proteins involving these two triosephosphate isomerases, we developed a strategy involving additive mutant enzymes and selected site directed mutants to locate and identify the three amino acids. These three residues seem to induce changes in the interface cysteine in reactivity by increasing (or decreasing) its apparent pKa. Some enzymes with four to seven mutations also exhibited altered reactivity. This study completes a strategy for identifying key residues in the sequences of proteins that can have applications in future protein structure-function studies.
Highlights
Sequence similarity searching is the most common method to identify homologous sequences
We showed that the chimeric enzyme TbTIM 1, 4; TcTIM 2–3, 5–8, which has a sequence containing 92.8% of the amino acids of wild type (WT) TcTIM, has an inactivation profile that is comparable, and even slightly more resistant, than WT TbTIM when exposed to the sulfhydryl reagent methylmethane thiosulfonate (MMTS) [14]
This implies that within the 18 amino acids that are different in these two regions, either all, or a subset of them, account for the differences in the susceptibility to MMTS in TcTIM and TbTIM
Summary
Sequence similarity searching is the most common method to identify homologous sequences. It is generally assumed that proteins with similar sequences will usually be homologous (share a common ancestry) and have a similar function [1]. This is so when the sequence identity is very high [2,3,4]. One would expect two nearly identical enzyme sequences. Key amino acids in protein function fellowship from CONACyT The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript
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