Protein engineering to change thermal stability for food enzymes.

In this review we have briefly indicated how the present state of knowledge allows proteins to be mutated to increase or decrease stability. We have discussed experiments on both model proteins and those of relevance to the food industry, and show how hydrophobic forces are a major driving force for folding as well as having a major role in thermostability. We have also indicated the large contribution that hydrogen bonding, electrostatic interactions and, in a less well predicted way, disulphide bridges make to thermostability.     

How oligomerization contributes to the thermostability of an archaeon protein. Protein L-isoaspartyl-O-methyltransferase from Sulfolobus tokodaii

To study how oligomerization may contribute to the thermostability of archaeon proteins, we focused on a hexameric protein, protein L-isoaspartyl-O-methyltransferase from Sulfolobus tokodaii (StoPIMT). The crystal structure shows that StoPIMT has a distinctive hexameric structure composed of monomers consisting of two domains: an S-adenosylmethionine-dependent methyltransferase fold domain and a C-terminal alpha-helical domain. The hexameric structure includes three interfacial contact regions: major, minor, and coiled-coil. Several C-terminal deletion mutants were constructed and characterized. The hexameric structure and thermostability were retained when the C-terminal alpha-helical domain (Tyr(206)-Thr(231)) was deleted, suggesting that oligomerization via coiled-coil association using the C-terminal alpha-helical domains did not contribute critically to hexamerization or to the increased thermostability of the protein. Deletion of three additional residues located in the major contact region, Tyr(203)-Asp(204)-Asp(205), led to a significant decrease in hexamer stability and chemico/thermostability. Although replacement of Thr(146) and Asp(204), which form two hydrogen bonds in the interface in the major contact region, with Ala did not affect hexamer formation, these mutations led to a significant decrease in thermostability, suggesting that two residues in the major contact region make significant contributions to the increase in stability of the protein via hexamerization. These results suggest that cooperative hexamerization occurs via interactions of "hot spot" residues and that a couple of interfacial hot spot residues are responsible for enhancing thermostability via oligomerization.     

A probabilistic method to correlate ion pairs with protein thermostability

Recent developments in research on the stability of proteins - specifically, comparisons of the ion pairs of homologous structures - show that ion pairs potentially contribute to the thermostability of proteins. This study proposes a probabilistic Bayesian statistical method to efficiently predict the thermostability of proteins based on the properties of ion pairs. The experimental results suggest that the numbers, types and bond lengths of ion pairs can be used to predict with high accuracy (up to 80%) the thermostability of functionally similar proteins. The predictions have high precision (99%), especially for hyperthermophilic proteins. Results for proteins with differing functions also indicate that the number of ion pairs is related to the thermostability of proteins, and that predictions of thermostability can also be made for proteins with different functions.     

Using a strategy based on the concept of convergent evolution to identify residue substitutions responsible for thermal adaptation

Factors that are related to thermostability of proteins have been extensively studied in recent years, especially by comparing thermophiles and mesophiles. However, most of them are global characters. It is still not clear how to identify specific residues or fragments which may be more relevant to protein thermostability. Moreover, some of the differences among the thermophiles and mesophiles may be due to phylogenetic differences instead of thermal adaptation. To resolve these problems, I adopted a strategy to identify residue substitutions evolved convergently in thermophiles or mesophiles. These residues may therefore be responsible for thermal adaptation. Four classes of genomes were utilized in this study, including thermophilic archaea, mesophilic archaea, thermophilic bacteria, and mesophilic bacteria. For most clusters of orthologous groups (COGs) with sequences from all of these four classes of genomes, I can identify specific residues or fragments that may potentially be responsible for thermal adaptation. Functional or structural constraints (represented as sequence conservation) were suggested to have higher impact on thermal adaptation than secondary structure or solvent accessibility does. I further compared thermophilic archaea and mesophilic bacteria, and found that the most diverged fragments may not necessarily correspond to the thermostability-determining ones. The usual approach to compare thermophiles and mesophiles without considering phylogenetic relationships may roughly identify sequence features contributing to thermostability; however, to specifically identify residue substitutions responsible for thermal adaptation, one should take sequence evolution into consideration.     

蛋白质空间结构属性与全基因组微生物耐热性的关系

 溶剂接触表面积、空腔个数和体积、紧密度、疏水性以及温度因子是影响蛋白质耐热的主要三维结构参数.挑选NCBI COG数据库中具有全基因组的单细胞微生物,选择其中三维结构已知的蛋白质作为研究对象,分析这些因素对细菌类和古细菌类微生物耐热性的影响.结果表明：（1）古细菌类蛋白质的空腔个数和体积与耐热性无关,极性面积和表面残基个数随耐热性增加而降低;（2）超高温细菌类蛋白质的分子量比较小,空腔个数和体积都小于常温蛋白质,而且空腔个数对稳定性的贡献大于空腔体积;（3）无论是古细菌还是细菌类蛋白质,疏水性和紧密度都不随耐热性变化,但暴露残基个数越多,蛋白质的耐热性越差;（4）两类蛋白质侧链的温度因子都高于主链,这与侧链的运动性（柔性）一般比主链高的实验结果一致;另外,超高温细菌类蛋白质的温度因子明显高于常温蛋白质.     

Transproteomic evidence of a loop-deletion mechanism for enhancing protein thermostability.

Understanding the molecular determinants of protein thermostability is of theoretical and practical importance. While numerous determinants have been suggested, no molecular feature has been judged of paramount importance, with the possible exception of ion-pair networks. The difficulty in identifying the main determinants may have been the limited structural information available on the thermostable proteins. Recently the complete genomes for mesophilic, thermophilic and hyperthermophilic organisms have been sequenced, vastly improving the potential for uncovering general trends in sequence and structure evolution related to thermostability and, thus, for isolating the more important determinants. From a comparative analysis of 20 complete genomes, we find a trend towards shortened thermophilic proteins relative to their mesophilic homologs. Moreover, sequence alignments to proteins of known structure indicate that thermophilic sequences are more likely than their mesophilic homologs to have deletions in exposed loop regions. The new genomes offer enough comparable sequences to compute meaningful statistics that point to loop deletion as a general evolutionary strategy for increasing thermostability.     

Development of an Escherichia coli expression system and thermostability screening assay for libraries of mutant xylanase

A thermostability screening assay was developed using an Escherichia coli expression system to express Streptomyces lividans xylanase A (XlnA). The screening system was tested using mutants randomized at position 49 of the S. lividans XlnA gene, a position previously shown to confer thermostability with a I49P point mutation. The library was cloned into an E. coli expression vector and transformed into XL1-blue bacteria. The resulting clones were screened for increased thermostability with respect to wild-type XlnA. Using this assay, we isolated the I49P mutant previously shown to be thermostable, as well as novel I49A and I49C mutants. The I49A and I49C mutants were shown to have 2.8- to 8-fold increase in thermostability over that of wild-type XlnA. The results show that the screening assay can selectively enrich for clones with increased thermostability and is suitable for screening small- to medium-sized libraries of 5000–20,000 clones. Journal of Industrial Microbiology & Biotechnology (2000) 25, 310–314. Received 18 May 2000/ Accepted in revised form 19 September 2000     

Comparison of crystal structure interactions and thermodynamics for stabilizing mutations in the Tetrahymena ribozyme

Although general mechanisms of RNA folding and catalysis have been elucidated, little is known about how ribozymes achieve structural stability at high temperature. A previous in vitro evolution experiment identified a small number of mutations that significantly increase the thermostability of the tertiary structure of the Tetrahymena ribozyme. Because we also determined the crystal structure of this thermostable ribozyme, we have for the first time the opportunity to compare the structural interactions and thermodynamic contributions of individual nucleotides in a ribozyme. We investigated the contribution of five mutations to thermostability by using temperature gradient gel electrophoresis. Unlike the case with several well-studied proteins, the effects of individual mutations on thermostability of this RNA were highly context dependent. The three most important mutations for thermostability were actually destabilizing in the wild-type background. A269G and A304G contributed to stability only when present as a pair, consistent with their proximity in the ribozyme structure. In an evolutionary context, this work supports and extends the idea that one advantage of protein enzyme systems over an RNA world is the ability of proteins to accumulate stabilizing single-site mutations, whereas RNA may often require much rarer double mutations to improve the stability of both its tertiary and secondary structures.     

枯草杆菌蛋白酶嗜热性改造单突变效果评判方法研究

对蛋白质进行嗜热性改造是蛋白质工程的主要问题之一,残基突变方法被广泛运用于其中。本文以枯草杆菌蛋白酶（SUBTILISIN BPN＇）为研究对象,旨在建立评判嗜热性改造效果的方法,选取了有可靠实验资料的9个突变点,运用分子动力学模拟方法,在四种不同模拟条件下,对其中的6个突变体和1个野生型蛋白进行了多种参量的对比分析,提取4个特征有效参量,建立了蛋白酶嗜热性改造单突变效果评判方法;利用该方法对其它3个突变效果进行评判,评判结果与实验资料完全吻合,证明该方法可用于枯草杆菌蛋白酶嗜热性改造单突变效果的评判。     

Amino acid residues stabilizing a Bacillus alpha-amylase against irreversible thermoinactivation

The alpha-amylase of Bacillus licheniformis (BLA) is stable and active at high temperature. More than 80% of its activity is retained after heat treatment at 90 degrees C for 30 min, and the optimum temperature for its activity is 80-85 degrees C. In contrast, the alpha-amylase of Bacillus amyloliquefaciens (BAA), the amino acid sequence of which shows 80% homology with that of BLA, is rapidly inactivated at 90 degrees C. Various chimeric genes were constructed from the structural genes for the two enzymes, and their products were analyzed for stability as to irreversible thermoinactivation. Two regions in the amino acid sequence of BLA comprising Gln178 (region I) and the 255th-270th residues (region II), respectively, were shown to determine the thermostability of BLA. Region I plays a major role in determining the thermostability. By means of site-directed mutagenesis of the BAA gene, deletion of Arg176 and Gly177 in region I and substitutions of alanine for Lys269 and aspartic acid for Asn266 in region II were shown to be responsible for the enhancement of the thermostability. Mutant BAAs containing the above deletion and substitutions showed almost the same thermostability as BLA as to irreversible thermoinactivation. Nevertheless, the mutant BAAs showed a temperature optimum as low as that of BAA (65 degrees C), indicating that they are still susceptible to reversible inactivation at temperatures higher than 65 degrees C.     

Purification and properties of two membrane alkaline phosphatases from Bacillus subtilis 168.

Two alkaline phosphatases were extracted from the membranes of Bacillus subtilis 168 stationary-phase cells and purified as homogeneous proteins by hydroxyapatite column chromatography. Alkaline phosphatases I and II differed in several properties such as subunit molecular weight, substrate specificity, thermostability, Km, pH stability, and peptide maps.     

Engineering proteins for thermostability through rigidifying flexible sites

Engineering proteins for thermostability is an exciting and challenging field since it is critical for broadening the industrial use of recombinant proteins. Thermostability of proteins arises from the simultaneous effect of several forces such as hydrophobic interactions, disulfide bonds, salt bridges and hydrogen bonds. All of these interactions lead to decreased flexibility of polypeptide chain. Structural studies of mesophilic and thermophilic proteins showed that the latter need more rigid structures to compensate for increased thermal fluctuations. Hence flexibility can be an indicator to pinpoint weak spots for enhancing thermostability of enzymes. A strategy has been proven effective in enhancing proteins' thermostability with two steps: predict flexible sites of proteins firstly and then rigidify these sites. We refer to this approach as rigidify flexible sites (RFS) and give an overview of such a method through summarizing the methods to predict flexibility of a protein, the methods to rigidify residues with high flexibility and successful cases regarding enhancing thermostability of proteins using RFS.     

In vitro evolutionary thermostabilization of congerin II: a limited reproduction of natural protein evolution by artificial selection pressure

The thermostability of the conger eel galectin, congerin II, was improved by in vitro evolutionary protein engineering. Two rounds of random PCR mutagenesis and selection experiments increased the congerin II thermostability to a level comparative to its naturally thermostable isoform, congerin I. The crystal structures of the most thermostable double mutant, Y16S/T88I, and the related single mutants, Y16S and T88I, were determined at 2.0 angstroms, 1.8 angstroms, and 1.6 angstroms resolution, respectively. The exclusion of two interior water molecules by the Thr88Ile mutation, and the relief of adjacent conformational stress by the Tyr16Ser mutation were the major contributions to the thermostability. These features in the congerin II mutants are similar to those observed in congerin I. The natural evolution of congerin genes, with the K(A)/K(S) ratio of 2.6, was accelerated under natural selection pressures. The thermostabilizing selection pressure artificially applied to congerin II mimicked the implied natural pressure on congerin I. The results showed that the artificial pressure made congerin II partially reproduce the natural evolution of congerin I.     

Protein Thermostability: Mechanism and Control Through Protein Engineering

Chemical modification and protein engineering especially are now the useful tools for thermo-stabilizing proteins, and also for elucidating the mechanism of protein stability. The information on the mechanism so far accumulated indicate that a single or few amino acid replacement(s) in a protein is/are sufficient to enhance protein thermostability. Salt bridges inside protein molecule or decrease of internal or external hydrophobicity, respectively, may contribute to increased thermostability. However, generalized molecular reasons for protein thermostability and generalized methods for protein stabilization have not yet been proposed. Some of typical examples of the application of protein engineering to stabilize proteins are presented. They are based on information concerning the tertiary structure of the proteins or their related proteins. Even if such structural information is unavailable, one can replace amino acid(s) in a protein by mutagenesis of the gene coding for the protein via the application of chemicals to the gene (or the plasmid harbouring the gene) or organism. A promising strategy involving transfer of the identified gene into a thermophile and subsequent growth at higher temperatures (thermal adaptation) is described.     

A comparative study of the thermal stability of plastocyanin, cytochrome c6 and Photosystem I in thermophilic and mesophilic cyanobacteria

Cytochrome c₆ (Cyt) from the thermophilic cyanobacterium Phormidium laminosum has been purified and characterized. It is a mildly acidic protein, with physicochemical properties very similar to those of plastocyanin (Pc). This is in agreement with the functional interchangeability of the two metalloproteins as electron donors to Photosystem I (PS I). The kinetic analyses of the interaction of Pc and Cyt with Photosystem I show that both metalloproteins reduce PS I with similar efficiencies, according to an oriented collisional kinetic model involving repulsive electrostatic interactions. The thermostability study of the Phormidium Pc/PS I system compared with those from mesophilic cyanobacteria (Synechocystis, Anabaena and Pseudanabaena) reveals that Pc is the partner limiting the thermostability of the Phormidium couple. The cross-reactions between Pc and PS I from different organisms demonstrate not only that Phormidium Pc enhances the stability of the Pc/PS I system using PS I from mesophilic cyanobacteria, but also that Phormidium PS I possesses a higher thermostability than the other photosystems. This revised version was published online in June 2006 with corrections to the Cover Date.     

Preparation and Properties of Clostridium thermocellum Lichenase Deletion Variants and Their Use for Construction of Bifunctional Hybrid Proteins

Major properties (pH and temperature optimum, stability) of lichenase (b-1,3-1,4-glucanase) deletion variants from Clostridium thermocellum were comparatively studied. The deletion variant LicBM2 was used to create hybrid bifunctional proteins by fusion with sequences of the green fluorescent protein (GFP) from Aequorea victoria. The data show that in hybrid proteins both GFP and lichenase retain their major properties, namely, GFP remains a fluorescent protein and the lichenase retains activity and high thermostability. Based on the results of this investigation and results that have been obtained earlier, the use of the deletion variants of lichenase and the bifunctional hybrid proteins as reporter proteins is suggested.     

High resolution structure and sequence of T. aurantiacus xylanase I: implications for the evolution of thermostability in family 10 xylanases and enzymes with (beta)alpha-barrel architecture.

Xylanase I is a thermostable xylanase from the fungus Thermoascus aurantiacus, which belongs to family 10 in the current classification of glycosyl hydrolases. We have determined the three-dimensional X-ray structure of this enzyme to near atomic resolution (1.14 A) by molecular replacement, and thereby corrected the chemically determined sequence previously published. Among the five members of family 10 enzymes for which the structure has been determined, Xylanase I from T. aurantiacus and Xylanase Z from C. thermocellum are from thermophilic organisms. A comparison with the three other available structures of the family 10 xylanases from mesophilic organisms suggests that thermostability is effected mainly by improvement of the hydrophobic packing, favorable interactions of charged side chains with the helix dipoles and introduction of prolines at the N-terminus of helices. In contrast to other classes of proteins, there is very little evidence for a contribution of salt bridges to thermostability in the family 10 xylanases from thermophiles. Further analysis of the structures of other proteins from thermophiles with eight-fold (beta)alpha-barrel architecture suggests that favorable interactions of charged side chains with the helix dipoles may be a common way in which thermophilic proteins with this fold are stabilized. As this is the most common type of protein architecture, this finding may provide a useful guide for site-directed mutagenesis aimed to improve the thermostability of (beta)alpha-barrel proteins. Proteins 1999;36:295-306.     

Structure and function of focal adhesions

Integrin-dependent cell adhesions come in different shapes and serve in different cell types for tasks ranging from cell-adhesion, migration, and the remodeling of the extracellular matrix to the formation and stabilization of immunological and chemical synapses. A major challenge consists in the identification of adhesion-specific as well as common regulatory mechanisms, motivating the need for a deeper analysis of protein-protein interactions in the context of intact focal adhesions. Specifically, it is critical to understand how small differences in binding of integrins to extracellular ligands and/or cytoplasmic adapter proteins affect the assembly and function of an entire focal adhesion. By using the talin-integrin pair as a starting point, I would like to discuss how specific protein-protein and protein-lipid interactions can control the behavior and function of focal adhesions. By responding to chemical and mechanical cues several allosterically regulated proteins create a dynamic multifunctional protein network that provides both adhesion to the extracellular matrix as well as intracellular signaling in response to mechanical changes in the cellular environment.     

Fluorinated chloramphenicol acetyltransferase thermostability and activity profile: improved thermostability by a single-isoleucine mutant

A lysate-based thermostability and activity profile is described for chloramphenicol acetyltransferase (CAT) expressed in trifluoroleucine, T (CAT T). CAT and 13 single-isoleucine CAT mutants were expressed in medium supplemented with T and assayed for thermostability on cell lysates. Although fluorinated mutants, L82I T and L208I T, showed losses in thermostability, the L158I T fluorinated mutant demonstrated an enhanced thermostability relative to CAT T. Further characterization of L158I T suggested that T at position 158 contributed to a portion of the observed loss in thermostability upon global fluorination.     

Gln277 and Phe554 residues are involved in thermal inactivation of protective antigen of Bacillus anthracis

Protective antigen (PA) is the main component of all the vaccines against anthrax. The currently available vaccines have traces of other proteins that contribute to its reactogenicity. Thus, purified PA is recommended for human vaccination. PA loses its biological activity within 48h at 37 degrees C and its thermolability has been a cause of concern as accidental exposure to higher temperatures during transportation or storage could decrease its efficacy. In the present study, we have used protein engineering approach to increase the thermostability of PA by mutating amino acid residues on the surface as well as the interior of the protein. After screening several mutants, the mutants Gln277Ala and Phe554Ala have been found to be more thermostable than the wild-type PA. Gln277Ala retains approximately 45% and Phe554Ala retains approximately 90% activity, even after incubation at 37 degrees C for 48h while in the same period wild-type PA loses its biological activity completely. It is the first report of increasing thermostability of PA using site-directed mutagenesis. Generation of such mutants could pave the way for better anthrax vaccines with longer shelf life.