Characterization of two novel heat-active α-galactosidases from thermophilic bacteria.

Two genes (agal1 and agal2) encoding α-galactosidases were identified by sequence-based screening approaches. The gene agal1 was identified from a data set of a sequenced hot spring metagenome, and the deduced amino-acid sequence exhibited 99% identity to an α-galactosidase from the thermophilic bacterium Dictyoglomus thermophilum. The gene agal2 was identified from the whole genome sequence of the thermophile Meiothermus ruber. The amino-acid sequences exhibited structural motifs typical for glycoside hydrolase (GH) family 36 members and were also differentiated into different subgroups of this family. Recombinant production of the heat-active GH36b enzyme Agal1 (87 kDa) and GH36bt enzyme Agal2 (57 kDa) was carried out in E. coli. Agal1 exhibited a specific activity of 1502.3 U/mg at 80 °C, pH 6.5, and Agal2 225.4 U/mg at 60-70 °C, pH 6.5. Half-lives of 14 h (Agal1) and 39 h (Agal2) were obtained at 50 °C, and Agal1 showed half-lives of 4 and 2 h at 70 and 80 °C, respectively. In addition to the natural substrates melibiose, raffinose, and stachyose, 4NP α-D-galactopyranoside was hydrolyzed. Galactose was also liberated from locust bean gum. Both heat-active enzymes are attractive candidates for application in food and feed industry for high-temperature processes for the degradation of raffinose family oligosaccharides.

Establishing wild-type levels of catalytic activity on natural and artificial (beta alpha)8-barrel protein scaffolds.

The generation of high levels of new catalytic activities on natural and artificial protein scaffolds is a major goal of enzyme engineering. Here, we used random mutagenesis and selection in vivo to establish a sugar isomerisation reaction on both a natural (beta alpha)(8)-barrel enzyme and a catalytically inert chimeric (beta alpha)(8)-barrel scaffold, which was generated by the recombination of 2 (beta alpha)(4)-half barrels. The best evolved variants show turnover numbers and substrate affinities that are similar to those of wild-type enzymes catalyzing the same reaction. The determination of the crystal structure of the most proficient variant allowed us to model the substrate sugar in the novel active site and to elucidate the mechanistic basis of the newly established activity. The results demonstrate that natural and inert artificial protein scaffolds can be converted into highly proficient enzymes in the laboratory, and provide insights into the mechanisms of enzyme evolution.

High-resolution crystal structure of an artificial (betaalpha)(8)-barrel protein designed from identical half-barrels.

Ample evidence suggests that the ubiquitous (betaalpha)(8)-barrel enzyme fold has evolved by the duplication and fusion of an ancestral (betaalpha)(4)-half-barrel. To reconstruct this process in the laboratory with a model protein, we earlier fused two copies of the C-terminal half-barrel HisF-C of imidazole glycerol phosphate synthase (HisF) and stepwise stabilized the resulting HisF-CC construct. We now further increased its stability and solubility by introducing two additional amino acid exchanges, which allowed us to crystallize the resulting artificial (betaalpha)(8)-barrel protein HisF-C***C. The analysis of its X-ray structure at 2.1 A resolution reveals a striking similarity to wild-type HisF, helps us to understand its improved stability, and provides further insights into the evolution of (betaalpha)(8)-barrel proteins.

Stabilisation of a (betaalpha)8-barrel protein designed from identical half barrels.

It has been suggested that the common (betaalpha)(8)-barrel enzyme fold has evolved by the duplication and fusion of identical (betaalpha)(4)-half barrels, followed by the optimisation of their interface. In our attempts to reconstruct these events in vitro we have previously linked in tandem two copies of the C-terminal half barrel HisF-C of imidazole glycerol phosphate synthase from Thermotoga maritima and subsequently reconstituted in the fusion construct HisF-CC a salt bridge cluster present in wild-type HisF. The resulting recombinant protein HisF-C*C, which was produced in an insoluble form and unfolded with low cooperativity at moderate urea concentrations has now been stabilised and solubilised by a combination of random mutagenesis and selection in vivo. For this purpose, Escherichia coli cells were transformed with a plasmid-based gene library encoding HisF-C*C variants fused to chloramphenicol acetyltransferase (CAT). Stable and soluble variants were identified by the survival of host cells on solid medium containing high concentrations of the antibiotic. The selected HisF-C*C proteins, which were characterised in vitro in the absence of CAT, contained eight different amino acid substitutions. One of the exchanges (Y143C) stabilised HisF-C*C by the formation of an intermolecular disulfide bond. Three of the substitutions (G245R, V248M, L250Q) were located in the long loop connecting the two HisF-C copies, whose subsequent truncation from 13 to 5 residues yielded the stabilised variant HisF-C*C Delta. From the remaining substitutions, Y143H and V234M were most beneficial, and molecular dynamics simulations suggest that they strengthen the interactions between the half barrels by establishing a hydrogen-bonding network and an extensive hydrophobic cluster, respectively. By combining the loop deletion of HisF-C*C Delta with the Y143H and V234M substitutions, the variant HisF-C**C was generated. Recombinant HisF-C**C is produced in soluble form, forms a pure monomer with its tryptophan residues shielded from solvent and unfolds with similar cooperativity as HisF. Our results show that, starting from two identical and fused half barrels, few amino acid exchanges are sufficient to generate a highly stable and compact (betaalpha)(8)-barrel protein with wild-type like structural properties.

Library Generation and Auxotrophic Selection Assays in Escherichia coli and Thermus thermophilus.

The selection of optimized enzymes from gene libraries is important, both for basic and applied research. Here, we first describe the generation of plasmid-borne libraries using error-prone PCR and highly competent Escherichia coli cells. We then provide protocols for the use of these libraries for auxotrophic selection assays with E. coli and the extremely thermophilic bacterium Thermus thermophilus as hosts.

Characterization of a Theme C Glycoside Hydrolase Family 9 Endo-Beta-Glucanase from a Biogas Reactor Metagenome.

From a biogas reactor metagenome an ORF (bp_cel9A) encoding a bacterial theme C glycoside hydrolase family 9 (GH9) enzyme was recombinantly produced in E. coli BL21 pQE-80L. BP_Cel9A exhibited ≤ 55% identity to annotated sequences. Subsequently, the enzyme was purified to homogeneity by affinity chromatography. The endo-beta-glucanase BP_Cel9A hydrolyzed the beta-1,3-1,4-linked barley beta-glucan with 24 U/mg at 30 °C and pH 6.0. More than 62% of activity was measured between 10 and 40 °C. Lichenan and xyloglucan were hydrolyzed with 67% and 40% of activity, respectively. The activity towards different substrates varied with different temperatures. However, the enzyme activity on CMC was extremely low (> 1%). In contrast to BP_Cel9A, most GH9 glucanases act preferably on crystalline or soluble cellulose with only side activities towards related substrates. The addition of calcium or magnesium enhanced the activity of BP_Cel9A, especially at higher temperatures. EDTA inhibited the enzyme, whereas EGTA had no effect, suggesting that Mg2+ may adopt the function of Ca2+. BP_Cel9A exhibited a unique substrate spectrum when compared to other GH9 enzymes with great potential for mixed-linked glucan or xyloglucan degrading processes at moderate temperatures.

Interconverting the catalytic activities of (betaalpha)(8)-barrel enzymes from different metabolic pathways: sequence requirements and molecular analysis.

The (betaalpha)(8)-barrel enzymes N'-[(5'-phosphoribosyl)formimino]-5-aminoimidazole-4-carboxamide ribonucleotide isomerase (tHisA) and imidazole glycerol phosphate synthase (tHisF) from Thermotoga maritima catalyze two successive reactions in the biosynthesis of histidine. In both enzymes, aspartate residues at the C-terminal end of beta-strand 1 (Asp8 in tHisA and Asp11 in tHisF) and beta-strand 5 (Asp127 in tHisA and Asp130 in tHisF) are essential for catalytic activity. It was demonstrated earlier that in tHisA the substitution of Asp127 by valine (tHisA-D127V) generates phosphoribosylanthranilate isomerase (TrpF) activity, a related (betaalpha)(8)-barrel enzyme participating in tryptophan biosynthesis. It is shown here that in tHisF the corresponding substitution of Asp130 by valine (tHisF-D130V) also generates TrpF activity. To determine the effectiveness of individual amino acid exchanges in these conversions, each of the 20 standard amino acid residues was introduced at position 127 of tHisA and 130 of tHisF by saturation random mutagenesis. The tHisA-D127X and tHisF-D130X variants with TrpF activity were identified by selection in vivo, and the proteins purified and characterized. The results obtained show that removal of the negatively charged carboxylate side-chain at the C-terminal end of beta-strand 5 is sufficient to establish TrpF activity in tHisA and tHisF, presumably because it allows the binding of the negatively charged TrpF substrate, phosphoribosylanthranilate. In contrast, the double mutants tHisA-D8N+D127V and tHisF-D11N+D130V did not show detectable activity, demonstrating that the aspartate residues at the C-terminal end of beta-strand 1 are essential for catalysis of the TrpF reaction. The ease with which TrpF activity can be established on both the tHisA and tHisF scaffolds supports the evolutionary relationship of these three enzymes and highlights the functional plasticity of the (betaalpha)(8)-barrel enzyme fold.

A sugar isomerization reaction established on various (ßα)8-barrel scaffolds is based on substrate-assisted catalysis.

In the course of tryptophan biosynthesis, the isomerization of phosphoribosylanthranilate (PRA) is catalyzed by the (ßα)8-barrel enzyme TrpF. The reaction occurs via a general acid-base mechanism with an aspartate and a cysteine residue acting as acid and base, respectively. PRA isomerase activity could be established on two (ßα)8-barrel enzymes involved in histidine biosynthesis, namely HisA and HisF, and on a HisAF chimera, by introducing two aspartate-to-valine substitutions. We have analyzed the reaction mechanism underlying this engineered activity by measuring its pH dependence, solving the crystal structure of a HisF variant with bound product analogue, and applying molecular dynamics simulations and mixed quantum and molecular mechanics calculations. The results suggest that PRA is anchored by the C-terminal phosphate-binding sites of HisA, HisF and HisAF. As a consequence, a conserved aspartate residue, which is equivalent to Cys7 from TrpF, is properly positioned to act as catalytic base. However, no obvious catalytic acid corresponding to Asp126 from TrpF could be identified in the three proteins. Instead, this role appears to be carried out by the carboxylate group of the anthranilate moiety of PRA. Thus, the engineered PRA isomerization activity is based on a reaction mechanism including substrate-assisted catalysis and thus differs substantially from the naturally evolved reaction mechanism used by TrpF.

Mimicking enzyme evolution by generating new (betaalpha)8-barrels from (betaalpha)4-half-barrels.

Gene duplication and fusion events that multiply and link functional protein domains are crucial mechanisms of enzyme evolution. The analysis of amino acid sequences and three-dimensional structures suggested that the (betaalpha)8-barrel, which is the most frequent fold among enzymes, has evolved by the duplication, fusion, and mixing of (betaalpha)4-half-barrel domains. Here, we mimicked this evolutionary strategy by generating in vitro (betaalpha)8-barrels from (betaalpha)4-half-barrels that were deduced from the enzymes imidazole glycerol phosphate synthase (HisF) and N'[(5'-phosphoribosyl)formimino]-5-aminoimidazole-4-carboxamide-ribonucleotide isomerase (HisA). To this end, the gene for the C-terminal (betaalpha)4-half-barrel (HisF-C) of HisF was duplicated and fused in tandem to yield HisF-CC, which is more stable than HisF-C. In the next step, by optimizing side-chain interactions within the center of the beta-barrel of HisF-CC, the monomeric and compact (betaalpha)8-barrel protein HisF-C*C was generated. Moreover, the genes for the N- and C-terminal (betaalpha)4-half-barrels of HisF and HisA were fused crosswise to yield the chimeric proteins HisFA and HisAF. Whereas HisFA contains native secondary structure elements but adopts ill-defined association states, the (betaalpha)8-barrel HisAF is a stable and compact monomer that reversibly unfolds with high cooperativity. The results obtained suggest a previously undescribed dimension for the diversification of enzymatic activities: new (betaalpha)8-barrels with novel functions might have evolved by the exchange of (betaalpha)4-half-barrel domains with distinct functional properties.