Laboratory evolution of laccase for substrate specificity

A laccase, CotA, from Bacillus subtilis was engineered using a combination of rational and directed evolution approaches. CotA is a generalist, an enzyme with broad specificity, and it was optimized to be a specialist, an enzyme with narrowed specificity. Wild-type CotA oxidizes ABTS (ABTS = diammonium 2,2′-azino-bis(3-ethylbenzothiazoline-6-sulfonate) and SGZ (SGZ = 4-hydroxy-3,5-dimethoxy-benzaldehyde azine), and it was engineered for increased specificity for ABTS. Based on the ABTS-bound crystal structure of CotA, 19 amino acids are within 6 Å of ABTS, and they were simultaneously randomized. A mutant was identified that was 132 times more specific for ABTS. Unexpectedly, the variant was found to acquire enhanced thermal stability. The half-life for the heat inactivation (t_1/2) at 80 °C was increased by 62 min for the mutant. Laccases have several applications in biotechnology, which include pulp bleaching, biosensors, bioremediation, and biofuel cells. The substrate specificity of CotA is moldable and the enzyme can be tailored to oxidize a variety of target molecules for specific purposes.     

Polar residues in the protein core of Escherichia coli thioredoxin are important for fold specificity

Most globular proteins contain a core of hydrophobic residues that are inaccessible to solvent in the folded state. In general, polar residues in the core are thermodynamically unfavorable except when they are able to form intramolecular hydrogen bonds. Compared to hydrophobic interactions, polar interactions are more directional in character and may aid in fold specificity. In a survey of 263 globular protein structures, we found a strong positive correlation between the number of polar residues at core positions and protein size. To probe the importance of buried polar residues, we experimentally tested the effects of hydrophobic mutations at the five polar core residues in Escherichia coli thioredoxin. Proteins with single hydrophobic mutations (D26I, C32A, C35A, T66L, and T77V) all have cooperative unfolding transitions like the wild type (wt), as determined by chemical denaturation. Relative to wt, D26I is more stable while the other point mutants are less stable. The combined 5-fold mutant protein (IAALV) is less stable than wt and has an unfolding transition that is substantially less cooperative than that of wt. NMR spectra as well as amide deuterium exchange indicate that IAALV is likely sampling a number of low-energy structures in the folded state, suggesting that polar residues in the core are important for specifying a well-folded native structure.     

Biochemical characterization of the thioredoxin domain of Escherichia coli DsbE protein reveals a weak reductant

Thioredoxin (Trx) domain is a typical fold functioning in thiol/disulfide exchange. DsbE protein is one of the Trx-domain containing proteins involved in electron transfer for cytochrome c maturation in the periplasm of Escherichia coli. The soluble C-terminal Trx domain of DsbE protein was overexpressed and purified to homogeneity. We herein report biochemical characterization of the structural and redox properties of this domain. During redox reaction, the domain undergoes a structural transformation resulting in a more stable reduced form with a free energy difference (DeltaDeltaG(Redox)) of ca. 5 kcal/mol, but the thiol/disulfide exchange exhibits very low reactivity. The standard redox potential (E0') for the active thiol/disulfide is -0.175 V and the pK(a) value of the active cysteine is around 6.8, indicating that the domain acts as a weak reductant. This implies that the membrane-anchored DsbE protein may provide driven reducing power for the redox reaction in the thiol/disulfide exchange pathway.     

Structure of Escherichia coli tetrahydrodipicolinate N-succinyltransferase reveals the role of a conserved C-terminal helix in cooperative substrate binding

Tetrahydrodipicolinate N-succinyltransferase is an enzyme present in many bacteria that catalyzes the first step of the succinylase pathway for the synthesis of meso-diaminopimelate and the amino acid L-lysine. Inhibition of the synthesis of meso-diaminopimelate, a component of peptidoglycan present in the cell wall of bacteria, is a potential route for the development of novel anti-bacterial agents. Here, we report the crystal structure of the DapD tetrahydrodipicolinate N-succinyltransferase from Escherichia coli at 2.0 A resolution. Comparison of the structure with the homologous enzyme from Mycobacterium bovis reveals the C-terminal helix undergoes a large rearrangement upon substrate binding, which contributes to cooperativity in substrate binding.     

Examination of polypeptide substrate specificity for Escherichia coli ClpB

Escherichia coli ClpB is a molecular chaperone that belongs to the Clp/Hsp100 family of AAA+ proteins. ClpB is able to form a hexameric ring structure to catalyze protein disaggregation with the assistance of the DnaK chaperone system. Our knowledge of the mechanism of how ClpB recognizes its substrates is still limited. In this study, we have quantitatively investigated ClpB binding to a number of unstructured polypeptides using steady‐state anisotropy titrations. To precisely determine the binding affinity for the interaction between ClpB hexamers and polypeptide substrates the titration data were subjected to global non‐linear least squares analysis incorporating the dynamic equilibrium of ClpB assembly. Our results show that ClpB hexamers bind tightly to unstructured polypeptides with binding affinities in the range of ～3–16 nM. ClpB exhibits a modest preference of binding to Peptide B1 with a binding affinity of (1.7 ± 0.2) nM. Interestingly, we found that ClpB binds to an unstructured polypeptide substrate of 40 and 50 amino acids containing the SsrA sequence at the C‐terminus with an affinity of (12 ± 3) nM and (4 ± 2) nM, respectively. Whereas, ClpB binds the 11‐amino acid SsrA sequence with an affinity of (140 ± 20) nM, which is significantly weaker than other polypeptide substrates that we tested here. We hypothesize that ClpB, like ClpA, requires substrates with a minimum length for optimal binding. Finally, we present evidence showing that multiple ClpB hexamers are involved in binding to polypeptides ≥152 amino acids. Proteins 2015; 83:117–134. © 2014 Wiley Periodicals, Inc.     

Identification of an antigenic determinant within the phylogenetically conserved triprolyl region of myelin basic protein

Synthetic peptide SP6 (RTPPPSG), comprising amino acid residues 98-103-Gly of myelin basic protein (MBP), and a series of peptide analogs were used to probe the structural requirements for antigenicity of a highly conserved region of a self protein. By means of a liquid-phase radioimmunoassay, antibody responses directed toward this determinant in both multi-specific anti-MBP and monospecific anti-peptide antisera were measured. The specificities of the antibodies present in the anti-MBP and anti-peptide antisera were examined by an equilibrium competitive inhibition radioimmunoassay by using the set of related peptides, as well as intact MBP from different species. Although the fine specificities of the reagent antisera differed, competitive inhibition analyses with intact MBP revealed a cross-reactive determinant involving residues 99-100 (Thr-Pro). This suggests that the neighborhood of the triprolyl region of MBP, despite its strong phylogenetic conservation, serves as an immunogen for humoral responses whether presented as a hapten-carrier conjugate or in the context of intact MBP. The latter supports the contention that the general antigenicity of a protein need not require sequence differences between the immunizing protein and its counterpart in the host.     

Protein folding in the periplasm of Escherichia coli

With the discovery of molecular chaperones and the development of heterologous gene expression techniques, protein folding in bacteria has come into focus as a potentially limiting factor in expression and as a topic of interest in its own right. Many proteins of importance in biotechnology contain disulphide bonds, which form in the Escherichia coli periplasm, but most work on protein folding in the periplasm of E. coli is very recent and is often speculative. This MicroReview gives a short overview of the possible fates of a periplasmic protein from the moment it is translocated, as well as of the E. coli proteins involved in this process. After an introduction to the specific physiological situation in the periplasm of E. coli, we discuss the proteins that might help other proteins to obtain their correctly folded conformation — disulphide isomerase, rotamase, parts of the translocation apparatus and putative periplasmic chaperones — and briefly cover the guided assembly of multi-subunit structures. Finally, our MicroReview turns to the fate of misfolded proteins: degradation by periplasmic proteases and aggregation phenomena.     

Glycosyl transferase activity of the Escherichia coli penicillin-binding protein 1b: specificity profile for the substrate

The glycosyl transferase of the Escherichia coli bifunctional penicillin-binding protein (PBP) 1b catalyzes the assembly of lipid-transported N-acetylglucosaminyl-beta-1,4-N-acetylmuramoyl-L-Ala-gamma-D-Glu-meso-A2pm-D-Ala-D-Ala units (lipid II) into linear peptidoglycan chains. These units are linked, at C1 of N-acetylmuramic acid (MurNAc), to a C55 undecaprenyl pyrophosphate. In an in vitro assay, lipid II functions both as a glycosyl donor and as a glycosyl acceptor substrate. Using substrate analogues, it is suggested that the specificity of the enzyme for the glycosyl donor substrate differs from that for the acceptor. The donor substrate requires the presence of both N-acetylglucosamine (GlcNAc) and MurNAc and a reactive group on C1 of the MurNAc and does not absolutely require the lipid chain which can be replaced by uridine. The enzyme appears to prefer an acceptor substrate containing a polyprenyl pyrophosphate on C1 of the MurNAc sugar. The problem of glycan chain elongation that presumably proceeds by the repetitive addition of disaccharide peptide units at their reducing end is discussed.     

Recovery of a foreign protein from the periplasm of Escherichia coli by chemical permeabilization.

We have applied the technique of protein release by chemical permeabilization to recover a foreign protein in active form from the periplasm of a recombinant strain of Escherichia coli. The two agents used in our chemical permeabilization scheme, guanidine hydrochloride and Triton X-100, have different modes of action, allowing selectivity in protein release based on intracellular location under different treatment conditions. Specifically, treatment of E. coli C600-1 cells by guanidine alone resulted in 40-fold purification of recombinant beta-lactamase, which is periplasmically expressed in this host. Achieving such high purification in the cell disruption stage could alleviate some of the problems associated with recovery of intracellular products, such as low expression or the need to solubilize cytoplasmic inclusion bodies. Recovery of periplasmic proteins by chemical permeabilization is simpler than by osmotic shock and is less expensive than using enzymatic digestion.     

Structural basis for substrate specificity of Escherichia coli purine nucleoside phosphorylase

Purine nucleoside phosphorylase catalyzes reversible phosphorolysis of purine nucleosides and 2'-deoxypurine nucleosides to the free base and ribose (or 2'-deoxyribose) 1-phosphate. Whereas the human enzyme is specific for 6-oxopurine ribonucleosides, the Escherichia coli enzyme accepts additional substrates including 6-oxopurine ribonucleosides, 6-aminopurine ribonucleosides, and to a lesser extent purine arabinosides. These differences have been exploited in a potential suicide gene therapy treatment for solid tumors. In an effort to optimize this suicide gene therapy approach, we have determined the three-dimensional structure of the E. coli enzyme in complex with 10 nucleoside analogs and correlated the structures with kinetic measurements and computer modeling. These studies explain the preference of the enzyme for ribose sugars, show increased flexibility for active site residues Asp204 and Arg24, and suggest that interactions involving the 1- and 6-positions of the purine and the 4'- and 5'-positions of the ribose provide the best opportunities to increase prodrug specificity and enzyme efficiency.     

Crystal structure of a conserved hypothetical protein from Escherichia coli

The crystal structure of a conserved hypothetical protein from Escherichia coli has been determined using X-ray crystallography. The protein belongs to the Cluster of Orthologous Group COG1553 (National Center for Biotechnology Information database, NLM, NIH), for which there was no structural information available until now. Structural homology search with DALI algorism indicated that this protein has a new fold with no obvious similarity to those of other proteins with known three-dimensional structures. The protein quaternary structure consists of a dimer of trimers, which makes a characteristic cylinder shape. There is a large closed cavity with approximate dimensions of 16 Å × 16 Å × 20 Å in the center of the hexameric structure. Six putative active sites are positioned along the equatorial surface of the hexamer. There are several highly conserved residues including two possible functional cysteines in the putative active site. The possible molecular function of the protein is discussed.     

Six conserved cysteines of the membrane protein DsbD are required for the transfer of electrons from the cytoplasm to the periplasm of Escherichia coli.

The active-site cysteines of the Escherichia coli periplasmic protein disulfide bond isomerase (DsbC) are kept reduced by the cytoplasmic membrane protein, DsbD. DsbD, in turn, is reduced by cytoplasmic thioredoxin, indicating that DsbD transfers disulfidereducing potential from the cytoplasm to the periplasm. To understand the mechanism of this unusual mode of electron transfer, we have undertaken a genetic analysis of DsbD. In the process, we discovered that the previously suggested start site for the DsbD protein is incorrect. Our results permit the formulation of a model of DsbD membrane topology. Also, we show that six cysteines of DsbD conserved among DsbD homologs are essential for the reduction of DsbC, DsbG and for a reductive pathway leading to c-type cytochrome assembly in the periplasm. Our findings suggest a testable model for the DsbD-dependent transfer of electrons across the membrane, involving a cascade of disulfide bond reduction steps.     

Substitution of the conserved tryptophan 31 in Escherichia coli thioredoxin by site-directed mutagenesis and structure-function analysis

All prokaryotic and eukaryotic thioredoxins contain a conserved tryptophan residue, exposed at the active site disulfide/dithiol. The role of this W31 in Escherichia coli thioredoxin (Trx) was studied by site-directed mutagenesis. Four mutant Trx with W31Y, W31F, W31H, and W31A replacements were characterized. Very low tryptophan fluorescence emission from the remaining W28 was observed in all mutant Trx; reduction resulted in large, but variable increases (up to 11-fold) of fluorescence, to levels higher than in native or denatured wild-type Trx, demonstrating a previously postulated change involving W28. All W31 mutant Trx were good substrates for E. coli thioredoxin reductase. Compared with wild type, the apparent Km values were increased less than 2-fold for the W31A, W31H, and W31F Trx and the W31Y Trx showed even slightly higher catalytic efficiency (kcat/Km value). Functions of reduced Trx with ribonucleotide reductase and in reduction of insulin disulfides were more strongly influenced by the W31 replacements, in particular at low pH for A and H residues. T7 DNA polymerase activity generated by T7 gene 5 protein and reduced Trx was lowered by large factors for W31Y, W31A, or W31H compared with W31F or the wild-type protein. The in vivo function of Trx was studied by using pUC118-trxA expression in an E. coli trxA- background. The trxA genes with W31Y and W31F substitutions restored, fully and partly, the methionine sulfoxide utilization of a trxA- metE- test strain; W31A and W31H mutations resulted in no growth. Propagation of M13 was moderately impeded by W31Y and W31F or severely by W31A and W31H replacements. Growth of a phage T3/7 hybrid was possible only with the W31Y and W31F substitutions reflecting the in vitro results for T7 DNA polymerase.     

Export of unprocessed precursor maltose-binding protein to the periplasm of Escherichia coli cells.

The Escherichia coli maltose-binding protein (MBP) R2 signal peptide is a truncated version of the wild-type structure that still facilitates very efficient export of MBP to the periplasm. Among single amino acid substitutions in the R2 signal peptide resulting in an export-defective precursor MBP (pMBP) were two that replaced residues in the consensus Ala-X-Ala sequence (residues -3 to -1) that immediately precedes the cleavage site. It was suggested that the functional hydrophobic core and signal peptidase recognition sequence of this signal peptide substantially overlap and that these two alterations affect both pMBP translocation and processing. In this study, the export of pMBP by the mutants, designated CC15 and CC17, with these two alterations was investigated further. The pMBP of mutant CC17 has an Arg substituted for Leu at the -2 position. It was found that CC17 cells exported only a very small amount of MBP, but that which was exported appeared to be correctly processed. This result was consistent with other studies that have concluded that virtually any amino acid can occupy the -2 position. For mutant CC15, which exhibits a fully Mal+ phenotype, an Asp is substituted for the Ala at the -3 position. CC15 cells were found to export large quantities of unprocessed, soluble pMBP to the periplasm, although such export was achieved in a relatively slow, posttranslational manner. This result was also consistent with other studies that suggested that charged residues are normally excluded from the -3 position of the cleavage site. Using in vitro oligonucleotide-directed mutagenesis, we constructed a new signal sequence mutant in which Asp was substituted for Arg at the -3 position of an otherwise wild-type MBP signal peptide. This alteration had no apparent effect on pMBP translocation across the cytoplasmic membrane, but processing by signal peptidase was inhibited. This pMBP species with its full-length hydrophobic core remained anchored to the membrane, where it could still participate in maltose uptake. The implications of these results for models of protein export are discussed.     

Characterization of the Moraxella catarrhalis opa-like protein, OlpA, reveals a phylogenetically conserved family of outer membrane proteins

Moraxella catarrhalis is a human-restricted pathogen that can cause respiratory tract infections. In this study, we identified a previously uncharacterized 24-kDa outer membrane protein with a high degree of similarity to Neisseria Opa protein adhesins, with a predicted beta-barrel structure consisting of eight antiparallel beta-sheets with four surface-exposed loops. In striking contrast to the antigenically variable Opa proteins, the M. catarrhalis Opa-like protein (OlpA) is highly conserved and constitutively expressed, with 25 of 27 strains corresponding to a single variant. Protease treatment of intact bacteria and isolation of outer membrane vesicles confirm that the protein is surface exposed yet does not bind host cellular receptors recognized by neisserial Opa proteins. Genome-based analyses indicate that OlpA and Opa derive from a conserved family of proteins shared by a broad array of gram-negative bacteria.     

Phenotypic characterization of a conserved inner membrane protein YhcB in Escherichia coli

Although bacteria have diverse membrane proteins, the function of many of them remains unknown or uncertain even in Escherichia coli. In this study, to investigate the function of hypothetical membrane proteins, genome-wide analysis of phenotypes of hypothetical membrane proteins was performed under various envelope stresses. Several genes responsible for adaptation to envelope stresses were identified. Among them, deletion of YhcB, a conserved inner membrane protein of unknown function, caused high sensitivities to various envelope stresses and increased membrane permeability, and caused growth defect under normal growth conditions. Furthermore, yhcB deletion resulted in morphological aberration, such as branched shape, and cell division defects, such as filamentous growth and the generation of chromosome-less cells. The analysis of antibiotic susceptibility showed that the yhcB mutant was highly susceptible to various anti-folate antibiotics. Notably, all phenotypes of the yhcB mutant were completely or significantly restored by YhcB without the transmembrane domain, indicating that the localization of YhcB on the inner membrane is dispensable for its function. Taken together, our results demonstrate that YhcB is involved in cell morphology and cell division in a membrane localization-independent manner.     

High-yield export of a native heterologous protein to the periplasm by the tat translocation pathway in Escherichia coli

Numerous high‐value recombinant proteins that are produced in bacteria are exported to the periplasm as this approach offers relatively easy downstream processing and purification. Most recombinant proteins are exported by the Sec pathway, which transports them across the plasma membrane in an unfolded state. The twin‐arginine translocation (Tat) system operates in parallel with the Sec pathway but transports substrate proteins in a folded state; it therefore has potential to export proteins that are difficult to produce using the Sec pathway. In this study, we have produced a heterologous protein (green fluorescent protein; GFP) in Escherichia coli and have used batch and fed‐batch fermentation systems to test the ability of the newly engineered Tat system to export this protein into the periplasm under industrial‐type production conditions. GFP cannot be exported by the Sec pathway in an active form. We first tested the ability of five different Tat signal peptides to export GFP, and showed that the TorA signal peptide directed most efficient export. Under batch fermentation conditions, it was found that TorA‐GFP was exported efficiently in wild type cells, but a twofold increase in periplasmic GFP was obtained when the TatABC components were co‐expressed. In both cases, periplasmic GFP peaked at about the 12 h point during fermentation but decreased thereafter, suggesting that proteolysis was occurring. Typical yields were 60 mg periplasmic GFP per liter culture. The cells over‐expressed the tat operon throughout the fermentation process and the Tat system was shown to be highly active over a 48 h induction period. Fed‐batch fermentation generated much greater yields: using glycerol feed rates of 0.4, 0.8, and 1.2 mL h^?1, the cultures reached OD₆₀₀ values of 180 and periplasmic GFP levels of 0.4, 0.85, and 1.1 g L^?1 culture, respectively. Most or all of the periplasmic GFP was shown to be active. These export values are in line with those obtained in industrial production processes using Sec‐dependent export approaches. Biotechnol. Bioeng. 2012; 109: 2533–2542. © 2012 Wiley Periodicals, Inc.     

Mutation of conserved residues in Escherichia coli thioredoxin: effects on stability and function.

Mutations were made in three highly conserved residues in Escherichia coli thioredoxin. An internal charged residue, Asp-26, was changed to an alanine. The mutant protein was more stable than the wild type. It can function as a substrate for thioredoxin reductase with a 10-fold increase in the Km over the wild type. Although the redox potential was not substantially changed from that of the wild type, thioredoxin D26A was a poor reducing agent for ribonucleotide reductase. Asp-26 apparently serves to maintain an optimal charge distribution in the active site region for interaction with other proteins. Mutation of a surface Pro-34 in the active site disulfide ring to a serine had little effect on protein stability. A slight decrease in the redox potential (9 mV) made thioredoxin P34S a better reducing agent for ribonucleotide reductase. In contrast, mutation of the internal cis Pro-76 to an alanine destabilized the protein. The data indicate a change had also occurred in the charge distribution in the active site region. Thioredoxin P76A had a higher redox potential than the wild type protein and was not an effective reducing agent for ribonucleotide reductase. It was concluded that this residue is essential for maintaining the conformation of the active site and the redox potential of thioredoxin.     

Probing the substrate specificity of Escherichia coli RNase E using a novel oligonucleotide-based assay

Endoribonuclease RNase E has a central role in both processing and decay of RNA in Escherichia coli, and apparently in many other organisms, where RNase E homologs were identified or their existence has been predicted from genomic data. Although the biochemical properties of this enzyme have been already studied for many years, the substrate specificity of RNase E is still poorly characterized. Here, I have described a novel oligonucleotide-based assay to identify specific sequence determinants that either facilitate or impede the recognition and cleavage of RNA by the catalytic domain of the enzyme. The knowledge of these determinants is crucial for understanding the nature of RNA–protein interactions that control the specificity and efficiency of RNase E cleavage and opens new perspectives for further studies of this multi-domain protein. Moreover, the simplicity and efficiency of the proposed assay suggest that it can be a valuable tool not only for the characterization of RNase E homologs but also for the analysis of other site-specific nucleases.