通过N端替换提高木聚糖酶的热稳定性

以来源于Thermomonospora fusca的耐高温木聚糖酶TfxA和来源于Streptomycesolivaceoviridis的高比活木聚糖酶XYNB为亲本,构建出耐热高比活融合木聚糖酶TB,将TB在大肠杆菌BL21和毕赤酵母GS115中进行表达并对表达产物的酶学性质进行分析比较。分析表明,融合蛋白TB最适pH值为6.0,最适温度为70℃,较XYNB有大幅度的提高;在热稳定性方面,TB明显优于XYNB,将两种稀释好的酶液分别在80℃和90℃下热处理3min,TB的热稳定性较XYNB提高了6倍左右;TB的pH稳定性为5～9(相对剩余活性在50%以上的pH范围),较XYNB有所下降,但两者的比活性基本不变,保持了亲本XYNB的高比活性。通过同源建模和序列比较,分析了可能影响融合蛋白TB酶学性质的因素,为进一步研究木聚糖酶的结构与功能提供了新的思路。     

Substitution of Asp189 residue alters the activity and thermostability of <Emphasis Type="Italic">Geobacillus</Emphasis> sp. NTU 03 lipase

Error-prone PCR was used to create more thermoactive and/or thermostable variants of thermoalkalophilic lipases. A variant of the α6 helix (lid domain), with an 189E to V substitution at residue 189, lost its thermostability but exhibited higher activity than that of its wild-type predecessor (r03Lip). Site-saturation mutagenesis was used to explore the sequence-function relationship. Five other mutants also lost thermostability (20–40%) but exhibited enhanced thermoactivity (6.3–79-fold). The mutant E189I showed the highest activity retaining 50% activity after maintaining it at 65°C for 24 h. In comparison to r03Lip, the mutant E189I had a higher affinity for p-nitrophenyl palmitate and p-nitrophenyl stearate (61 and 56% decreased Km) and catalytic efficiency (42-fold and 18-fold increased kcat/Km). The mutant lipase retained its tolerance to n-hexane, but had an improved transesterification activity. The results suggest that residue Glu189 plays a significant role in the thermostability and activity of this thermoalkalophilic lipase.     

Enhancing thermostability of a Rhizomucor miehei lipase by engineering a disulfide bond and displaying on the yeast cell surface

To increase the thermostability of Rhizomucor miehei lipase, the software Disulfide by Design was used to engineer a novel disulfide bond between residues 96 and 106, and the corresponding double cysteine mutants were constructed. The R. miehei lipase mutant could be expressed by Pichia pastoris in a free secreted form or could be displayed on the cell surface. The new disulfide bond spontaneously formed in the mutant R. miehei lipase. Thermostability was examined by measuring of hydrolysis activity using 4-nitrophenyl caprylate as a substrate. The engineered disulfide bond contributed to thermostability in the free form of the R. miehei lipase variant. The variant displayed on the yeast cell surface had significantly increased residual hydrolytic activity in aqueous solution after incubation at 60°C for 5 h and increased synthetic activity in organic solvent at 60°C. These results indicated that yeast surface display might improve the stability of R. miehei lipase, as well as amplifying the thermostability through the engineered disulfide bond.     

木聚糖酶XYNB分子中折叠股B1和B2间的疏水作用对酶热稳定性的影响

对来源于Streptomycesolivaceoviridis的高比活木聚糖酶XYNB进行同源建模,并结合嗜热木聚糖酶氮末端芳香族氨基酸疏水作用的结构分析,设计了XYNB的T11Y定点突变,观察XYNB分子中折叠股B1和B2的疏水作用对酶的热稳定性的影响。将突变酶XYNB′在毕赤酵母中表达,表达的XYNB′经纯化后与原酶XYNB(同样经毕赤酵母表达后纯化)进行酶学性质比较,结果表明,XYNB′的耐热性比XYNB有明显的提高,但最适温度与原酶一样为60℃。另外,XYNB′的最适pH、Km值及比活性均有一定的改变。实验证实了木聚糖酶XYNB的氮端芳香族氨基酸之间的疏水相互作用与其热稳定性相关,为进一步的结构与功能研究提供了优良的基因材料。     

In Silico Rational Design and Systems Engineering of Disulfide Bridges in the Catalytic Domain of an Alkaline α-Amylase from Alkalimonas amylolytica To Improve Thermostability

High thermostability is required for alkaline α-amylases to maintain high catalytic activity under the harsh conditions used in textile production. In this study, we attempted to improve the thermostability of an alkaline α-amylase from Alkalimonas amylolytica through in silico rational design and systems engineering of disulfide bridges in the catalytic domain. Specifically, 7 residue pairs (P35-G426, Q107-G167, G116-Q120, A147-W160, G233-V265, A332-G370, and R436-M480) were chosen as engineering targets for disulfide bridge formation, and the respective residues were replaced with cysteines. Three single disulfide bridge mutants—P35C-G426C, G116C-Q120C, and R436C-M480C—of the 7 showed significantly enhanced thermostability. Combinational mutations were subsequently assessed, and the triple mutant P35C-G426C/G116C-Q120C/R436C-M480C showed a 6-fold increase in half-life at 60°C and a 5.2°C increase in melting temperature compared with the wild-type enzyme. Interestingly, other biochemical properties of this mutant also improved: the optimum temperature increased from 50°C to 55°C, the optimum pH shifted from 9.5 to 10.0, the stable pH range extended from 7.0 to 11.0 to 6.0 to 12.0, and the catalytic efficiency (k_cat/K_m) increased from 1.8 × 10⁴ to 2.4 × 10⁴ liters/g · min. The possible mechanism responsible for these improvements was explored through comparative analysis of the model structures of wild-type and mutant enzymes. The disulfide bridge engineering strategy used in this work may be applied to improve the thermostability of other industrial enzymes.     

A <Emphasis Type="Italic">Paenibacillus</Emphasis> sp. dextranase mutant pool with improved thermostability and activity

Random mutagenesis was used to create a library of chimeric dextranase (dex1) genes. A plate-screening protocol was developed with improved thermostability as a selection criterion. The mutant library was screened for active dextranase variants by observing clearing zones on dextran-blue agar plates at 50°C after exposure to 68°C for 2 h, a temperature regime at which wild-type activity was abolished. A number of potentially improved variants were identified by this strategy, five of which were further characterised. DNA sequencing revealed ten nucleotide substitutions, ranging from one to four per variant. Thermal inactivation studies showed reduced (2.9-fold) thermostability for one variant and similar thermostability for a second variant, but confirmed improved thermostability for three mutants with 2.3- (28.9 min) to 6.9-fold (86.6 min) increases in half-lives at 62°C compared to that of the wild-type enzyme (12.6 min). Using a 10-min assay, apparent temperature optima of the variants were similar to that of the wild type (T _opt 60°C). However, one of these variants had increased enzyme activity. Therefore, the first-generation dextranase mutant pool obtained in this study has sufficient molecular diversity for further improvements in both thermostability and activity through recombination (gene shuffling).     

Increasing the thermal stability of cellulase C using rules learned from thermophilic proteins: a pilot study

Some structural features underlying the increased thermostability of enzymes from thermophilic organisms relative to their homologues from mesophiles are known from earlier studies. We used cellulase C from Clostridium thermocellum to test whether thermostability can be increased by mutations designed using rules learned from thermophilic proteins. Cellulase C has a TIM barrel fold with an additional helical subdomain. We designed and produced a number of mutants with the aim to increase its thermostability. Five mutants were designed to create new electrostatic interactions. They all retained catalytic activity but exhibited decreased thermostability relative to the wild-type enzyme. Here, the stabilizing contributions are obviously smaller than the destabilization caused by the introduction of the new side chains. In another mutant, the small helical subdomain was deleted. This mutant lost activity but its melting point was only 3 degrees C lower than that of the wild-type enzyme, which suggests that the subdomain is an independent folding unit and is important for catalytic function. A double mutant was designed to introduce a new disulfide bridge into the enzyme. This mutant is active and has an increased stability (deltaT(m)=3 degrees C, delta(deltaG(u))=1.73 kcal/mol) relative to the wild-type enzyme. Reduction of the disulfide bridge results in destabilization and an altered thermal denaturation behavior. We conclude that rules learned from thermophilic proteins cannot be used in a straightforward way to increase the thermostability of a protein. Creating a crosslink such as a disulfide bond is a relatively sure-fire method but the stabilization may be smaller than calculated due to coupled destabilizing effects.     

Site-Directed Mutagenesis and Thermostability of Xylanase XYNB from <Emphasis Type="Italic">Aspergillus niger</Emphasis> 400264

Xylanase is one of the most important hemicellulases in industry. However, its low thermostability limits its applications. In this study, one thermostable xylanase-producing strain 400264 was obtained from screening 11 Aspergillus niger strains (producing thermotolerant xylanase), and the optimum temperature of crude xylanase extracted from it was 55°C. Original activity of the crude xylanase is 64% at 60°C and 55% at 85°C with an incubation time of 30 min, respectively. After the expression of recombinant xylanase gene (xynA/xynB), the XYNB (xylanase B) showed higher thermostability than XYNA (xylanase A). Recombinant enzyme XYNB retained 94% of its activity for 10 min at 85°C, while XYNA with no activity left. Site-directed mutagenesis was performed to replace Ala33 of XYNB by Ser33 resulting 19% decrease in enzyme activity after incubating at 85°C for 30 min. It suggested that the Ala33 residue may have a certain effect on the thermophilic adaptation of xylanase.     

Engineering and introduction of <Emphasis Type="Italic">de novo</Emphasis> disulphide bridges in organophosphorus hydrolase enzyme for thermostability improvement

The organophosphorus hydrolase (OPH) has been used to degrade organophosphorus chemicals, as one of the most frequently used decontamination methods. Under chemical and thermal denaturing conditions, the enzyme has been shown to unfold. To utilize this enzyme in various applications, the thermal stability is of importance. The engineering of de novo disulphide bridges has been explored as a means to increase the thermal stability of enzymes in the rational method of protein engineering. In this study, Disulphide by Design software, homology modelling and molecular dynamics simulations were used to select appropriate amino acid pairs for the introduction of disulphide bridge to improve protein thermostability. The thermostability of the wild-type and three selected mutant enzymes were evaluated by half-life, ΔG inactivation (ΔGi) and structural studies (fluorescence and far-UV CD analysis). Data analysis showed that half-life of A204C/T234C and T128C/E153C mutants were increased up to 4 and 24 min, respectively; however, for the G74C/A78C mutant, the half-life was decreased up to 9 min. For the T128C/E124C mutant, both thermal stability and Catalytic efficiency (kcat) were also increased. The half-life and ΔGi results were correlated to the obtained information from structural studies by circular dichroism (CD) spectrometry and extrinsic fluorescence experiments; as rigidity increased in A204C/T2234C and T128C/E153C mutants, half-life and ΔGi also increased. For G74C/A78C mutant, these parameters decreased due to its higher flexibility. The results were submitted a strong evidence for the possibility to improve the thermostability of OPH enzyme by introducing a disulphide bridge after bioinformatics design, even though this design would not be always successful.     

Delicate balance of electrostatic interactions and disulfide bridges in thermostability of firefly luciferase

The wild type Photinus pyralis luciferase does not have any disulfide bridge. Disulfide bridges are determinant in inherent stability of protein at moderate temperatures. Meanwhile, arginin is responsible for thermostability at higher temperatures. In this study, by concomitant introduction of disulfide bridge and a surface arginin in a mutant (A296C-A326C/I232R), the contribution of disulfide bridge introduction and surface hydrophilic residue on activity and global stability of P. pyralis luciferase is investigated. In addition to the mentioned mutant; I232R, A296C-A326C and wild type luciferases are characterized. Though addition of Arg caused stability against proteolysis but in combination with disulfide bridge resulted in decreased thermal stability compared to A296C-A326C mutant. In spite of long distance of two different mutations (A296C-A326C and I232R) from each other in the three-dimensional structure, combination of their effects on the stability of luciferase was not cumulative.     

Engineering a Disulfide Bond in the Lid Hinge Region of Rhizopus chinensis Lipase: Increased Thermostability and Altered Acyl Chain Length Specificity

The key to enzyme function is the maintenance of an appropriate balance between molecular stability and structural flexibility. The lid domain which is very important for “interfacial activation” is the most flexible part in the lipase structure. In this work, rational design was applied to explore the relationship between lid rigidity and lipase activity by introducing a disulfide bond in the hinge region of the lid, in the hope of improving the thermostability of R. chinensis lipase through stabilization of the lid domain without interfering with its catalytic performance. A disulfide bridge between F95C and F214C was introduced into the lipase from R. chinensis in the hinge region of the lid according to the prediction of the “Disulfide by Design” algorithm. The disulfide variant showed substantially improved thermostability with an eleven-fold increase in the t _1/2 value at 60°C and a 7°C increase of T _m compared with the parent enzyme, probably contributed by the stabilization of the geometric structure of the lid region. The additional disulfide bond did not interfere with the catalytic rate (k _cat) and the catalytic efficiency towards the short-chain fatty acid substrate, however, the catalytic efficiency of the disulfide variant towards pNPP decreased by 1.5-fold probably due to the block of the hydrophobic substrate channel by the disulfide bond. Furthermore, in the synthesis of fatty acid methyl esters, the maximum conversion rate by RCLCYS reached 95% which was 9% higher than that by RCL. This is the first report on improving the thermostability of the lipase from R. chinensis by introduction of a disulfide bond in the lid hinge region without compromising the catalytic rate.     

Point mutation Arg153-His at surface of <Emphasis Type="Italic">Bacillus</Emphasis> lipase contributing towards increased thermostability and ester synthesis: insight into molecular network

In order to design proteins with improved properties i.e. thermostability, catalytic efficiency and to understand the mechanisms underlying, a thermostable variant of Bacillus lipase was generated by site-directed mutagenesis with enhanced thermal (?Tm = + 12 °C) and chemical (?Cm denaturation for Gdmcl = + 1.75 M) stability as compared to WT. Arg153-His variant showed 72-fold increase in thermostability (t ^1/2 = 6 h) at 60 °C as compared to WT (t ^1/2 = 5 min). Increase in thermostability might be contributed by the formation of additional hydrogen bonds between His153/AO-Arg106/ANH2 as well as His153-Arg106/ANE. The variant demonstrated broad substrate specificity. A maximum conversion of 59 and 62% was obtained for methyl oleate and methyl butyrate, respectively, using immobilized variant lipase, whereas immobilized WT enzyme synthesizes 35% methyl oleate. WT enzyme was unable to synthesize methyl butyrate as it showed negligible activity with pNP-butyrate.     

Stabilization of a (betaalpha)8-barrel protein by an engineered disulfide bridge.

The aim of this study was to increase the stability of the thermolabile (betaalpha)8-barrel enzyme indoleglycerol phosphate synthase from Escherichia coli by the introduction of disulfide bridges. For the design of such variants, we selected two out of 12 candidates, in which newly introduced cysteines potentially form optimal disulfide bonds. These variants avoid short-range connections, substitutions near catalytic residues, and crosslinks between the new and the three parental cysteines. The variant linking residues 3 and 189 fastens the N-terminus to the (betaalpha)8-barrel. The rate of thermal inactivation at 50 degrees C of this variant with a closed disulfide bridge is 65-fold slower than that of the reference dithiol form, but only 13-fold slower than that of the parental protein. The near-ultraviolet CD spectrum, the reactivity of parental buried cysteines with Ellman's reagent as well as the decreased turnover number indicate that the protein structure is rigidified. To confirm these data, we have solved the X-ray structure to 2.1-A resolution. The second variant was designed to crosslink the terminal modules betaalpha1 and betaalpha8. However, not even the dithiol form acquired the native fold, possibly because one of the targeted residues is solvent-inaccessible in the parental protein.     

Conversion of trypsin to a functional threonine protease

The hydroxyl group of a serine residue at position 195 acts as a nucleophile in the catalytic mechanism of the serine proteases. However, the chemically similar residue, threonine, is rarely used in similar functional context. Our structural modeling suggests that the Ser 195 --> Thr trypsin variant is inactive due to negative steric interaction between the methyl group on the beta-carbon of Thr 195 and the disulfide bridge formed by cysteines 42 and 58. By simultaneously truncating residues 42 and 58 and substituting Ser 195 with threonine, we have successfully converted the classic serine protease trypsin to a functional threonine protease. Substitution of residue 42 with alanine and residue 58 with alanine or valine in the presence of threonine 195 results in trypsin variants that are 10(2) -10(4) -fold less active than wild type in kcat/KM but >10(6)-fold more active than the Ser 195 --> Thr single variant. The substitutions do not alter the substrate specificity of the enzyme in the P1'- P4' positions. Removal of the disulfide bridge decreases the overall thermostability of the enzyme, but it is partially rescued by the presence of threonine at position 195.     

Engineered disulfide bonds improve thermostability and activity of L‐isoleucine hydroxylase for efficient 4‐HIL production in Bacillus subtilis 168

4‐Hydroxyisoleucine, a promising drug, has mainly been applied in the clinical treatment of type 2 diabetes in the pharmaceutical industry. l ‐Isoleucine hydroxylase specifically converts l‐ Ile to 4‐hydroxyisoleucine. However, due to its poor thermostability, the industrial production of 4‐hydroxyisoleucine has been largely restricted. In the present study, the disulfide bond in l ‐isoleucine hydroxylase protein was rationally designed to improve its thermostability to facilitate industrial application. The half‐life of variant T181C was 4.03 h at 50°C, 10.27‐fold the half‐life of wild type (0.39 h). The specific enzyme activity of mutant T181C was 2.42 ± 0.08 U/mg, which was 3.56‐fold the specific enzyme activity of wild type 0.68 ± 0.06 U/mg. In addition, molecular dynamics simulation was performed to determine the reason for the improvement of thermostability. Based on five repeated batches of whole‐cell biotransformation, Bacillus subtilis 168/pMA5‐ido^T181C recombinant strain produced a cumulative yield of 856.91 mM (126.11 g/L) 4‐hydroxyisoleucine, which is the highest level of productivity reported based on a microbial process. The results could facilitate industrial scale production of 4‐hydroxyisoleucine. Rational design of disulfide bond improved l ‐isoleucine hydroxylase thermostability and may be suitable for protein engineering of other hydroxylases.     

Enhancing thermostability of <Emphasis Type="Italic">Escherichia coli</Emphasis> phytase AppA2 by error-prone PCR

Phytases are used to improve phosphorus nutrition of food animals and reduce their phosphorus excretion to the environment. Due to favorable properties, Escherichia coli AppA2 phytase is of particular interest for biotechnological applications. Directed evolution was applied in the present study to improve AppA2 phytase thermostability for lowering its heat inactivation during feed pelleting (60–80°C). After a mutant library of AppA2 was generated by error-prone polymerase chain reaction, variants were expressed initially in Saccharomyces cerevisiae for screening and then in Pichia pastoris for characterizing thermostability. Compared with the wild-type enzyme, two variants (K46E and K65E/K97M/S209G) showed over 20% improvement in thermostability (80°C for 10 min), and 6–7°C increases in melting temperatures (T _m). Structural predictions suggest that substitutions of K46E and K65E might introduce additional hydrogen bonds with adjacent residues, improving the enzyme thermostability by stabilizing local interactions. Overall catalytic efficiency (k _cat / K _m) of K46E and K65E/K97M/S209G was improved by 56% and 152% than that of wild type at pH 3.5, respectively. Thus, the catalytic efficiency of these enzymes was not inversely related to their thermostability.     

Anabaena sp. DyP‐type peroxidase is a tetramer consisting of two asymmetric dimers

DyP‐type peroxidases are a newly discovered family of heme peroxidases distributed from prokaryotes to eukaryotes. Recently, using a structure‐based sequence alignment, we proposed the new classes, P, I and V, as substitutes for classes A, B, C, and D [Arch Biochem Biophys 2015;574:49–55]. Although many class V enzymes from eukaryotes have been characterized, only two from prokaryotes have been reported. Here, we show the crystal structure of one of these two enzymes, Anabaena sp. DyP‐type peroxidase (AnaPX). AnaPX is tetramer formed from Cys224‐Cys224 disulfide‐linked dimers. The tetramer of wild‐type AnaPX was stable at all salt concentrations tested. In contrast, the C224A mutant showed salt concentration‐dependent oligomeric states: in 600 mM NaCl, it maintained a tetrameric structure, whereas in the absence of salt, it dissociated into monomers, leading to a reduction in thermostability. Although the tetramer exhibits non‐crystallographic, 2‐fold symmetry in the asymmetric unit, two subunits forming the Cys224‐Cys224 disulfide‐linked dimer are related by 165° rotation. This asymmetry creates an opening to cavities facing the inside of the tetramer, providing a pathway for hydrogen peroxide access. Finally, a phylogenetic analysis using structure‐based sequence alignments showed that class V enzymes from prokaryotes, including AnaPX, are phylogenetically closely related to class V enzymes from eukaryotes. Proteins 2016; 84:31–42. © 2015 Wiley Periodicals, Inc.     

Effect of a disulfide bond on mevalonate kinase

Mevalonate kinase is one of ATP-dependent enzymes in the mevalonate pathway and catalyzes the phosphorylation of mevalonate to form mevalonate 5-phosphate. In animal cells, it plays a key role in regulating biosynthesis of cholesterol, while in microorganisms and plants, it is involved in the biosynthesis of isoprenoid derivatives that are one of the largest groups of natural products. Crystal structure and sequence alignment show that a unique disulfide bond exists in mevalonate kinase of thermostable species Methanococcus jannaschii, but not in rat mevalonate kinase. In the present study, we investigated the effect of the disulfide bond in M. jannaschii mevalonate kinase and an engineered disulfide bond in rat mevalonate kinase mutant A141C on the properties of enzymes through characterization of their wild-type and variant enzymes. Our result suggests that the Cys107-Cys281 disulfide bond is important for maintaining the conformation and the thermal activity of M. jannaschii mevalonate kinase. Other interactions could also have contributions. The thiol-titration and fluorescence experiment further indicate that rat mevalonate kinase A141C variant enzyme has a new disulfide bond, which makes the variant protein enhance its thermal activity and resist to urea denaturation.     

Molecular characterization of xynX, a gene encoding a multidomain xylanase with a thermostabilizing domain from Clostridium thermocellum

A Clostridium thermocellum gene, xynX, coding for a xylanase was cloned and the complete nucleotide sequence was determined. The xylanase gene of Clostridium thermocellum consists of an ORF of 3261 nucleotide encoding a xylanase (XynX) of 1087 amino acid residues (116 kDa). Sequence analysis of XynX showed a multidomain structure that consisted of four different domains: an N-terminal thermostabilizing domain homologous to sequences found in several thermophilic enzymes, a catalytic domain homologous to family 10 glycosyl hydrolases, a duplicated cellulose-binding domain (CBD) homologous to family IX CBDs, and a triplicated S-layer homologous domain. A deletion mutant of xynX having only the catalytic region produced a mutant enzyme XynX-C which retained catalytic activity but lost thermostability. In terms of half-life at 70 °C, the thermostability of XynX-C was about six times lower than that of the other mutant enzyme, XynX-TC, produced by a mutant containing both the thermostabilizing domain and the catalytic domain. The optimum temperature of XynX-C was about 5–10 °C lower than that of XynX-TC. Received: 12 January 2000 / Received revision: 24 April 2000 / Accepted: 1 May 2000     

Effect of disulfide-bond introduction on the activity and stability of the extended-spectrum class A beta-lactamase Toho-1

The production of class A beta-lactamases is a major cause of clinical resistance to beta-lactam antibiotics. Some of class A beta-lactamases are known to have a disulfide bridge. Both narrow spectrum and extended spectrum beta-lactamases of TEM and the SHV enzymes possess a disulfide bond between Cys77 and Cys123, and the enzymes with carbapenem-hydrolyzing activity have a well-conserved disulfide bridge between Cys69 and Cys238. We produced A77C/G123C mutant of the extended-spectrum beta-lactamase Toho-1 in order to introduce a disulfide bond between the cysteine residues at positions 77 and 123. The result of 5,5'-dithiobis-2-nitrobenzoic acid (DTNB) titrations confirmed formation of a new disulfide bridge in the mutant. The results of irreversible heat inactivation and circular dichroism (CD) melting experiments indicated that the disulfide bridge stabilized the enzyme significantly. Though kinetic analysis indicated that the catalytic properties of the mutant were quite similar to those of the wild-type enzyme, E. coli producing this mutant showed drug resistance significantly higher than E. coli producing the wild-type enzyme. We speculate that the stability of the enzymes provided by the disulfide bond may explain the wide distribution of TEM and SHV derivatives and explain how various mutations can cause broadened substrate specificity without loss of stability.