In Escherichia coli, the first enzyme in the methionine biosynthesis pathway, homoserine o-succinyltransferase (MetA) [1, 3–5], is extremely sensitive to many stress conditions (e.g., thermal, oxidative or acidic stress) [6–8]. At temperatures higher than 25°C, MetA activity is reduced, and the Protein Tyrosine Kinase inhibitor protein tends to unfold, resulting in a methionine limitation in E. coli growth [9]. MetA reversibly unfolds at temperatures approaching
42°C and is a substrate for the ATP-dependent proteases Lon, ClpP/X and HslVU [6]. At temperatures of 44°C and higher, MetA completely aggregates and is no longer found in the soluble protein fraction, thus limiting growth [9]. The chemical chaperone trimethylamine oxide reduces insoluble MetA accumulation and improves E. coli growth at elevated temperatures [9]. It has been suggested that MetA could be classified as a Class III substrate for chaperones because this molecule is extremely prone to aggregation [10]. Despite the importance of MetA in E. coli growth, little information
exists on the amino acid residues involved in the inherent instability of MetA. The sensitivity of MetA to multiple stress conditions suggests that this enzyme might be a type of ‘metabolic fuse’ for the detection of unfavorable growth conditions [7]. Previously, we used random mutagenesis of metA to improve E. coli growth at elevated temperatures [11]. Mutations that resulted in the amino acid substitutions I229T and N267D enabled the E. coli strain WE to grow at higher temperatures and increased the ability of Luminespib datasheet the strain to tolerate acidic conditions. In
this study, we extended our stabilization DOCK10 studies using a computer-based design and consensus approach [12] to identify additional mutations that might stabilize the inherently unstable MetA enzyme. To achieve pronounced thermal stabilization, we combined several single substitutions in a multiple mutant, as the thermo-stabilization effects of individual mutations in many cases were independent and nearly additive [12]. Here, we describe the successful application of the consensus concept approach and the I-mutant2.0 modeling tool [13] to design stabilized MetA mutants. The consensus concept approach for engineering thermally stable proteins is based on an idea that by multiple sequence alignment of the homologous counterparts from mesophiles and thermophiles, the nonconsensus amino acid might be determined and substituted with the respective consensus amino acid, contributing to the protein stability [12]. I-Mutant2.0 is a support vector machine-based web server for the automatic prediction of protein stability changes with single-site mutations (http://gpcr.biocomp.unibo.it/~emidio/I-Mutant2.0/I-Mutant2.0_Details.html). Four substitutions, Q96K, I124L, I229Y and F247Y, improved the growth of the E. coli WE strain at elevated temperatures.