Characterization of Chimeric Isocitrate Dehydrogenases of a Mesophilic Nitrogen-Fixing Bacterium, <Emphasis Type="Italic">Azotobacter vinelandii,</Emphasis> and a Psychrophilic Bacterium, <Emphasis Type="Italic">Colwellia maris</Emphasis>

Several properties of chimeric enzymes between a mesophilic isocitrate dehydrogenase (IDH) from a nitrogen-fixing bacterium, Azotobacter vinelandii, and a cold-adapted IDH isozyme (IDH-II) from a psychrophilic bacterium, Colwellia maris, were examined. Each of the genes encoding the IDHs was divided into four regions of almost equal lengths, and each region was ligated with different combinations to construct various chimeric genes. The resultant wild-type and chimeric genes were overexpressed in Escherichia coli. The wild-type and chimeric IDHs were classified into three groups based on optimum temperatures for activity of 20°, 30°, and 40°C. The IDHs with a lower optimum temperature were more thermolabile. The optimum temperature and thermostability of the chimeric enzymes decreased on increasing the proportion derived from the cold-adapted IDH-II of C. maris. Furthermore, the C-terminal region of the C. maris IDH-II was suggested to be responsible for its psychrophilic characteristics.     

Interchange of functional domains switches enzyme specificity: construction of a chimeric pneumococcal-clostridial cell wall lytic enzyme

Bacterial autolysins are endogenous enzymes that specifically cleave covalent bonds in the cell wall. These enzymes show both substrate and bond specificities. The former is related to their interaction with the insoluble substrate whereas the latter determine their site of action. The bond specificity allows their classification as muramidases (lysozymes), glucosaminldases, amidases, and endopeptidases. To demonstrate that the autolysin (LYC muramidase) of Clostridium acetobutylicum ATCC824 presents a domainal organization, a chimeric gene (clc) containing the regions coding for the catalytic domain of the LYC muramidase and the choline-binding domain of the pneumococcal phage CPL1 muramidase has been constructed by in vitro recombination of the corresponding gene fragments. This chimeric construction codes for a choline-binding protein (CLC) that has been purified using affinity chromatography on DEAE-cellulose. Several biochemical tests demonstrate that this rearrangement of domains has generated an enzyme with a choline-dependent muramidase activity on pneumococcal cell walls. Since the parental LYC muramidase was cholineindependent and unable to degrade pneumococcal cell walls, the formation of this active chimeric enzyme by exchanging protein domains between two enzymes that specifically hydrolyse cell walls of bacteria belonging to different genera shows that a switch on substrate specificity has been achieved. The chimeric CLC muramidase behaved as an autolytic enzyme when it was adsorbed onto a live autolysin-defective mutant of Streptococcus pneumoniae. The construction described here provides experimental support for the theory of modular evolution which assumes that novel proteins have evolved by the assembly of preexisting polypeptide units.     

Construction and characterization of novel chimeric β-glucosidases with Cellvibrio gilvus (CG) and Thermotoga maritima (TM) by overlapping PCR

In order to create novel β-glucosidase constructs, 8 kinds of chimeric β-glucosidases were constructed using overlapping polymerase chain reaction (PCR) based on Cellvibrio gilvus (CG) and Thermotoga maritima (TM) genes. Two kinds of novel chimeric β-glucosidases (No. 6 and No. 8 type) were selected and their properties characterized. SDS-PAGE analysis showed that both constructs had a molecular mass of 80 kDa. The optimum pH of No. 6 chimeric β-glucosidase was found to be 3.0 and 5.0, showing varying maximum activity according to the buffer used. No. 8 chimeric enzyme was found to be optimally active at a pH of 4.5 and the optimum temperature of No.6 and No.8 chimeric β-glucosidases was reported to be 60°C, respectively. The Km values of both novel chimeric enzymes were calculated to be 0.012 mM and 0.0082 mM, respectively and the characteristics of the novel chimeric enzymes were to lie between those of the parental enzymes.     

Isolation of Chanoclavine-(I) and Two New Interconvertible Alkaloids,Rugulovasine A and B,from the Cultures of Penicillium concavo-rugulosum

The chimeric 3-isopropylmalate dehydrogenase enzymes were constructed from the deep-sea piezophilic Shewanella benthica and the shallow water Shewanella oneidensis genes. The properties of the enzymatic activities under pressure conditions indicated that the central region, which contained the active center and the dimer forming domains, was shown to be the most important region for pressure tolerance in the deep-sea enzyme.     

Probing Structural Elements of Thermal Stability in Bacterial Oligomeric Alcohol Dehydrogenases. I. Construction and Characterization of Chimeras Consisting of Secondary ADHs from Thermoanaerobacter brockii and Clostridium beijerinckii

Summary Two tetrameric secondary alcohol dehydrogenases (ADHs), one from the mesophileClostridium beijerinckii (CBADH) and the other from the extreme thermophileThermoanaerobacter brockii (TBADH), share 75% sequence identity but differ by 26°C in thermal stability. To explore the role of linear segments of these similar enzymes in maintaining the thermal stability of the thermostable TBADH, a series of 12 CBadh and TBadh chimeric genes and the two parental wild-type genes were expressed inEscherichia coli, and the enzymes were isolated, purified and characterized. The thermal stability of each chimeric enzyme was approximately exponentially proportional to the content of the amino acid sequence of the thermophilic enzyme, indicating that the amino acid residues contributing to the thermal stability of TBADH are distributed along the whole protein molecule. It is suggested that major structural elements of thermal stability may reside among the nine discrepant amino acid residues between the N-terminal 50-amino acid residues of TBADH and CBADH.     

Metabolic engineering of a complex biochemical pathway: The lysine and threonine biosynthesis as an example

The nutritional quality of crop plants is determined by their content in essential amino acids provided in food for humans or in feed for monogastric animals. Amino acid composition of crop–based diets can be improved via manipulation of the properties of key enzymes of amino acid biosynthetic pathways by mutation and transformation. We focused on the aspartate-derived amino acid pathway producing four essential amino acids: lysine, threonine, isoleucine and methionine. Genes encoding aspartate kinase (AK) and dihydrodipicolinate synthase (DHDPS) that operate as key genes of the aspartate pathway have been cloned from Arabidopsis. Genetic and molecular studies revealed that at least five different ak genes are represented. Some of them were characterized in terms of gene and promoter structure, developmental expression and regulatory properties. In the case of dhdps, two quite identical genes have been identified and characterized at expression level. Mutated genes encoding a fully feedback-insensitive form of the DHDPS enzyme were obtained from Nicotiana sylvestris and Arabidopsis. Several chimeric constructs harbouring this mutated allele under the control of constitutive or seed-specific promoters were transferred via Agrobacterium or biolistics in various plant species. In all cases, lines with significant increase of free lysine content were obtained in vegetative organs, but the impact of the transgene in seeds is limited due to the presence of an active catabolic enzyme, lysine ketoreductase. These results show that, although dealing with a complex, highly regulated pathway, the overexpression of a single gene encoding a feedback-insensitive form of the key enzyme DHDPS exerts a significant effect on the carbon flux through the aspartate pathway towards lysine production.     

Characterization of a chimeric enzyme comprising feruloyl esterase and family 42 carbohydrate-binding module

We engineered a chimeric enzyme (AwFaeA-CBM42) comprising of type-A feruloyl esterase from Aspergillus awamori (AwFaeA) and family 42 carbohydrate-binding module (AkCBM42) from glycoside hydrolase family 54 α-l-arabinofuranosidase of Aspergillus kawachii. The chimeric enzyme was successfully produced in Pichia pastoris and accumulated in the culture broth. The purified chimeric enzyme had an apparent relative molecular mass (M _r) of 53,000. The chimeric enzyme binds to arabinoxylan; this indicates that the AkCBM42 in AwFaeA-CBM42 binds to arabinofuranose side chain moiety of arabinoxylan. The thermostability of the chimeric enzyme was greater than that of AwFaeA. No significant difference of the specific activity toward methyl ferulate was observed between the AwFaeA and chimeric enzyme, but the release of ferulic acid from insoluble arabinoxylan by the chimeric enzyme was approximately 4-fold higher than that achieved by AwFaeA alone. In addition, the chimeric enzyme and xylanase acted synergistically for the degradation of arabinoxylan. In conclusion, the findings of our study demonstrated that the components of the AwFaeA-CBM42 chimeric enzyme act synergistically to bring about the degradation of complex substrates and that the family 42 carbohydrate-binding module has potential for application in the degradation of polysaccharides.     

Construction of Chimeric Glucansucrases for Analyzing Substrate-binding Regions That Affect the Structure of Glucan Products

A gene that encodes dextransucrase S (dsrS) from Leuconostoc mesenteroides NRRL B-512F encodes a glucansucrase dextransucrase S (DSRS) which mainly produces water-soluble glucan (dextran), while the dsrT5 gene derived from dsrT of the B-512F strain encodes an enzyme dextransucrase T5 (DSRT5), which mainly produces water-insoluble glucan. Tyr340-Asn510 of DSRS and Tyr307-Asn477 of DSRT5 (Site 1), Lys696-Gly768 of DSRS and Lys668-Gly740 of DSRT5 (Site 2), and Asn917-Lys1131 of DSRS and Asn904-Lys1118 of DSRT5 (Site 3) were exchanged and six different chimeric enzymes were constructed. Water-soluble glucan produced by recombinant DSRS was composed of 64% 6-linked glucopyranoside (Glcp), 9% 3,6-linked Glcp, and 13% 4-linked Glcp. Water-insoluble glucan produced by recombinant DSRT5 was composed of 47% 6-linked Glcp and 43% 3-linked Glcp. All of the chimeric enzymes produced glucans different from the ones produced by their parental enzymes. Some of the glucans produced by chimeric enzymes were extremely changed. The Site 1 chimeric enzyme of DSRS (STS1) produced water-soluble glucan composed mostly of 6-linked Glcp. That of DSRT5 (TST1) produced water-insoluble glucan composed mostly of 4-linked Glcp. The Site 3 chimeric enzyme of DSRS (STS3) produced mainly water-insoluble glucan, DSRT5 (TST3) produced mainly water-soluble glucans, and all of the glucan fractions consisted of 3-Glcp, 4-Glcp, and 6-Glcp. The amounts of the three linkages in the water-soluble glucan produced by TST3 were about 1:1:1. Site 1 was assumed to be important for making or avoiding making α-1,4 linkages, while Site 3 was assumed to be important for determining the kinds of glucosyl linkages made.     

Assembling a xylanase–lichenase chimera through all-atom molecular dynamics simulations

Multifunctional enzyme engineering can improve enzyme cocktails for emerging biofuel technology. Molecular dynamics through structure-based models (SB) is an effective tool for assessing the tridimensional arrangement of chimeric enzymes as well as for inferring the functional practicability before experimental validation. This study describes the computational design of a bifunctional xylanase–lichenase chimera (XylLich) using the xynA and bglS genes from Bacillus subtilis. In silico analysis of the average solvent accessible surface area (SAS) and the root mean square fluctuation (RMSF) predicted a fully functional chimera, with minor fluctuations and variations along the polypeptide chains. Afterwards, the chimeric enzyme was built by fusing the xynA and bglS genes. XylLich was evaluated through small-angle X-ray scattering (SAXS) experiments, resulting in scattering curves with a very accurate fit to the theoretical protein model. The chimera preserved the biochemical characteristics of the parental enzymes, with the exception of a slight variation in the temperature of operation and the catalytic efficiency (k_cat/K_m). The absence of substantial shifts in the catalytic mode of operation was also verified. Furthermore, the production of chimeric enzymes could be more profitable than producing a single enzyme separately, based on comparing the recombinant protein production yield and the hydrolytic activity achieved for XylLich with that of the parental enzymes.     

Screening of stable proteins in an extreme thermophile, Thermus thermophilus

The leuB gene codes for 3-isopropylmalate dehydrogenase of the leucine biosynthetic pathway in an extreme thermophile, Thermus thermophilus. The leuB gene of the thermophile was replaced with a temperature-sensitive chimeric leuB gene. The resultant transformant was adapted to high temperature, a thermostable mutant strain being obtained. A single base substitution that replaces isoleucine at 93 with leucine was found in the chimeric leuB gene of the thermostable mutant. The resultant amino acid residue coincided with the corresponding residue of the T. thermophilus enzyme. It was confirmed that the mutant enzyme is more stable than the original chimeric enzyme. This system can be used to produce stabilized mutants of other enzymes without structural knowledge of them.     

Construction and expression of a hybrid plasmid containing the Escherichia coli thrA and thrB genes.

Summary In vitro recombination techniques were used to clone the Escherichia coli thrA and thrB structural genes in the plasmid vector pBR322. The chimeric plasmid was analyzed and characterized genetically, by restriction mapping and DNA sequencing. The limited expression of the threonine biosynthetic enzymes in the strain carrying the recombinant plasmid is discussed.     

Construction of Intra-Domain Chimeras of Aminoacyl-tRNA Synthetases

Abstract

To explore new approaches to enzyme engineering, intra-domain chimeras of two aminoacyltRNA synthetases were constructed. Connections were made within the nucleotide folds of these enzymes at sites earlier shown either to be dispensable for activity or able to accomodate oligopeptide insertions. (R.M. Starzyk, T.A. Webster and P. Schimmel, Science 237, 1614 (1987); R.M. Starzyk, J.J. Burbaum and P. Schimmel, Biochemistry, in press). Based on the known structure of one synthetase and structural modeling of the other, the locations of the connection sites allow the possibility of functional “compound” ATP and tRNA binding sites. Of five chimeric genes which were constructed, three direct synthesis of polypeptides that accumulate in vivo. These stable hybrids provide prototypes to which mutagenesis procedures may be applied to produce enzymatically active chimeric synthetases.     

Anticodon-binding domain swapping in a nondiscriminating aspartyl-tRNA synthetase reveals contributions to tRNA specificity and catalytic activity

The nondiscriminating aspartyl-tRNA synthetase (ND-AspRS), found in many archaea and bacteria, covalently attaches aspartic acid to tRNA^Asp and tRNA^Asn generating a correctly charged Asp-tRNA^Asp and an erroneous Asp-tRNA^Asn. This relaxed tRNA specificity is governed by interactions between the tRNA and the enzyme. In an effort to assess the contributions of the anticodon-binding domain to tRNA specificity, we constructed two chimeric enzymes, Chimera-D and Chimera-N, by replacing the native anticodon-binding domain in the Helicobacter pylori ND-AspRS with that of a discriminating AspRS (Chimera-D) and an asparaginyl-tRNA synthetase (AsnRS, Chimera-N), both from Escherichia coli. Both chimeric enzymes showed similar secondary structure compared to wild-type (WT) ND-AspRS and maintained the ability to form dimeric complexes in solution. Although less catalytically active than WT, Chimera-D was more discriminating as it aspartylated tRNA^Asp over tRNA^Asn with a specificity ratio of 7.0 compared to 2.9 for the WT enzyme. In contrast, Chimera-N exhibited low catalytic activity toward tRNA^Asp and was unable to aspartylate tRNA^Asn. The observed catalytic activities for the two chimeras correlate with their heterologous toxicity when expressed in E. coli. Molecular dynamics simulations show a reduced hydrogen bond network at the interface between the anticodon-binding domain and the catalytic domain in Chimera-N compared to Chimera-D or WT, explaining its lower stability and catalytic activity.     

Expression of a reporter gene is reduced by a ribozyme in transgenic plants

A chimeric gene encoding a ribozyme under the control of the cauliflower mosaic virus (CaMV) 35S promoter was introduced into transgenic tobacco plants. In vivo activity of this ribozyme, which was designed to cleave npt mRNA, was previously demonstrated by transient expression assays in plant protoplasts. The ribozyme gene was transferred into transgenic tobacco plants expressing an rbcS-npt chimeric gene as an indicator. Five double transformants out of sixteen exhibited a reduction in the amount of active NPT enzyme. To measure the amount of ribozyme produced, in the absence of its target, the ribozyme and target genes were separated by genetic segregation. The steady-state concentrations of ribozyme and target RNA were shown to be similar in the resulting single transformants. Direct evidence for a correlation between reduced npt gene expression and ribozyme expression was provided by crossing a plant containing only the ribozyme gene with a transgenic plant expressing the npt gene under control of the 35S promoter, i.e. the same promoter used to direct ribozyme expression. The expression of npt was reduced in all progeny containing both transgenes. Both steady-state levels of npt mRNA and amounts of active NPT enzyme are decreased. In addition, our data indicate that, at least in stable transformants, a large excess of ribozyme over target is not a prerequisite for achieving a significant reduction in target gene expression.     

Enhancement of transglycosylation activity by construction of chimeras between mesophilic and thermophilic beta-glucosidase

The family 3 beta-glucosidase from Thermotoga maritima is a highly thermostable enzyme (85 degrees C) that displays transglycosylation activity. In contrast, the beta-glucosidase from Cellvibrio gilvus is mesophilic (35 degrees C) and displays no such transglycosylation activity. Both enzymes consist of two domains, an N-terminal and a C-terminal domain, and the amino acid identities between the two enzymes in these domains are 32.4 and 36.4%, respectively. In an attempt to identify the molecular basis underpinning the display of transglycosylation activity and the requirements for thermal stability, eight chimeric genes were constructed by shuffling the two parental beta-glucosidase genes at four selected borders, two in the N-terminal domain and two in the C-terminal domain. Of the eight chimeric genes constructed, only two chimeric enzymes (Tm578/606Cg and Tm638/666Cg) gave catalytically active forms and these were the ones shuffled in the C-terminal domain. For these active chimeric enzymes, 80% (Tm578/606Cg) and 88% (Tm638/666Cg) of their amino acid sequences originated from T. maritima. With regard to their thermal profiles, the two active chimeric enzymes, Tm578/606Cg and Tm638/666Cg, displayed profiles intermediate to those of the two parental enzymes as they were optimally active at 65 and 70 degrees C, respectively. These two chimeric enzymes were optimally active at pH 4.1 and 3.9, which is closer to that observed for the T. maritima enzyme (pH 3.2-3.5) than that for the C. gilvus enzyme (pH 6.2-6.5). Kinetic parameters for the chimeric enzymes were investigated with five different substrates including pNP-beta-D-glucopyranoside. The kinetic parameters obtained for the chimeric enzymes were closer to those of the T. maritima enzyme than to those of the C. gilvus enzyme. Transglycosylation activity was observed for both chimeric enzymes and the activity of the Tm578/606Cg chimera was at a level twice that observed with the T. maritima enzyme. This study is an effective demonstration of the usefulness of chimeric enzymes in altering the characteristics of an enzyme.     

Change in maltose- and soluble starch-hydrolyzing activities of chimeric α-glucosidases of Mucor javanicus and Aspergillus oryzae

The chimeric α-glucosidases of Mucor javanicus and Aspergillus oryzae, which has high activity toward not only maltooligosaccharides but also soluble starch and has high activity toward maltooligosaccharides but faint activity toward soluble starch, respectively, were constructed by shuffling the C-terminal regions where low homology is observed between the two enzymes. The chimera genes were expressed in Pichia pastoris to produce and secrete the enzymes that have predicted molecular masses in the culture medium. The two chimeric M. javanicus α-glucosidases, of which the N- and C-terminal regions are substituted for those of A. oryzae, respectively, decreased in soluble starch-hydrolyzing activity, however, increased in maltose-hydrolyzing activity by 2.1 and 4.9 times higher than that of the native form of M. javanicus α-glucosidase, respectively. The chimeric enzymes changed on the V_max values for maltose significantly, whereas the K_m values were similar to that of the native enzyme.     

In-fusion expression and characterization of <Emphasis Type="Italic">β</Emphasis>-xylanase and <Emphasis Type="Italic">β</Emphasis>-1,3-1,4-glucanase in <Emphasis Type="Italic">Pichia pastoris</Emphasis>

Two chimeric genes, XynA-Bs-Glu-1 and XynA-Bs-Glu-2, encoding Aspergillus sulphureus β-xylanase (XynA, 26 kDa) and Bacillus subtilis β-1,3-1,4-glucanase (Bs-Glu, 30 kDa), were constructed via in-fusion by different linkers and expressed successfully in Pichia pastoris. The fusion protein (50 kDa) exhibited both β-xylanase and β-1,3-1,4-glucanase activities. Compared with parental enzymes, the moiety activities were decreased in fermentation supernatants. Parental XynA and Bs-Glu were superior to corresponding moieties in each fusion enzymes because of lower K_n higher k_cat. Despite some variations, common optima were generally 50°C and pH 3.4 for the XynA moiety and parent, and 40°C and pH 6.4 for the Bs-Glu counterparts. Thus, the fusion enzyme XynA-Bs-Glu-1 and XynA-Bs-Glu-2 were bifunctional.     

Structural and functional analysis of SleL,a peptidoglycan lysin involved in germination of Bacillus spores

A major event in the germination of Bacillus spores concerns hydrolysis of the cortical peptidoglycan that surrounds the spore protoplast, the integrity of which is essential for maintenance of dormancy. Cortex degradation is initiated in all species of Bacillus spores by the combined activity of two semi‐redundant cortex‐lytic enzymes, SleB and CwlJ. A third enzyme, SleL, which has N‐acetylglucosaminidase activity, cleaves peptidoglycan fragments generated by SleB and CwlJ. Here we present crystal structures of B. cereus and B. megaterium SleL at 1.6 angstroms and 1.7 angstroms, respectively. The structures were determined with a view to identifying the structural basis of differences in catalytic efficiency between the respective enzymes. The catalytic (α/β)₈‐barrel cores of both enzymes are highly conserved from a structural perspective, including the spatial distribution of the catalytic residues. Both enzymes are equipped with two N‐terminal peptidoglycan‐binding LysM domains, which are also structurally highly conserved. However, the topological arrangement of the respective enzymes second LysM domain is markedly different, and this may account for differences in catalytic rates by impacting upon the position of the active sites with respect to their substrates. A chimeric enzyme comprising the B. megaterium SleL catalytic domain plus B. cereus SleL LysM domains displayed enzymatic activity comparable to the native B. cereus protein, exemplifying the importance of the LysM domains to SleL function. Similarly, the reciprocal construct, comprising the B. cereus SleL catalytic domain with B. megaterium SleL LysM domains, showed reduced activity compared with native B. cereus SleL. Proteins 2015; 83:1787–1799. © 2015 Wiley Periodicals, Inc.