Protein engineering最新文献

Topsalign is a method that will structurally align diverse protein structures, for example, structural alignment of protein superfolds. All proteins within a superfold share the same fold but often have very low sequence identity and different biological and biochemical functions. There is often significant structural diversity around the common scaffold of secondary structure elements of the fold. Topsalign uses topological descriptions of proteins. A pattern discovery algorithm identifies equivalent secondary structure elements between a set of proteins and these are used to produce an initial multiple structure alignment. Simulated annealing is used to optimize the alignment. The output of Topsalign is a multiple structure-based sequence alignment and a 3D superposition of the structures. This method has been tested on three superfolds: the beta jelly roll, TIM (alpha/beta) barrel and the OB fold. Topsalign outperforms established methods on very diverse structures. Despite the pattern discovery working only on beta strand secondary structure elements, Topsalign is shown to align TIM (alpha/beta) barrel superfamilies, which contain both alpha helices and beta strands.

The ribosome display system is a very effective and powerful tool for in vitro screening of transcribed mRNAs that encode proteins (or peptides) with specific (known or unknown) functions. The system depends on the stability of ribosome-mRNA complexes that have been formed as a result of the removal of a stop codon. To assess the general applicability of the system, we examined the stability of ribosome-mRNA complexes in the presence and absence of a stop codon, as well as in the presence and the absence of an additional interaction between the translated peptide and its mRNA within the ribosome-mRNA complex. The additional interaction that we exploited was the interaction between a tandemly fused MS2 coat-protein (MSp) dimer and the RNA sequence of the corresponding specific binding motif, C-variant (Cv). The MSp dimer and Cv were placed, respectively, at the N-terminal end of a nascent protein, translated in vitro, and at the 5' end of the protein's mRNA, and consequently further stabilize the ribosome-mRNA complex. To our surprise, we were able to select proteins even in the presence of a stop codon. Moreover, as we had anticipated, the interaction between the MSp dimer and Cv enhanced the stability of the ribosome-mRNA complex, suggesting that this kind of interaction might be useful in the design of an efficient ribosome display selection strategy. Indeed, the yield of the mRNAs of interest after selection was increased upon the introduction of the interaction between the MSp dimer and Cv.

Probabilistic methods have been developed that estimate the site-specific probabilities of the amino acids in sequences likely to fold to a particular target structure, and such information can be used to guide the de novo design of proteins and to probe sequence variability. An extension of these methods for the design of symmetric homo-oligomeric quaternary structures is presented. The theory is in excellent agreement with the results of studies on exactly solvable lattice models. Application to an atomically detailed representation of proteins verifies the utility of a symmetry assumption, which greatly simplifies and accelerates the calculations. The method may be applied to a wide variety of symmetric and periodic protein structures.

A series of molecular mechanics calculations were used to analyze the energetics for moving a single polysaccharide chain from the surface of microcrystalline cellulose into the binding cleft of the Cel5A cellulase from Acidothermus cellulolyticus. A build-up procedure was used to model the placement of a 12-residue oligosaccharide chain along the surface of the enzyme, using as a guide the four residues of the tetrasaccharide substrate co-crystallized with the protein in the crystallographic structure determination. The position of this 12-residue oligosaccharide was used to orient the enzyme properly above two different surfaces of cellulose 1beta, the (1,0,0) and the (1,1,0) faces of the crystal. Constrained molecular dynamics simulations were then used to pull a target chain directly below the enzyme up out of the crystal surface and into the binding groove. The energetics for this process were favorable for both faces, with the step face being more favorable than the planar face, implying that this surface could be hydrolyzed more readily.

MT3 shows apparently different properties and function from MT1 even though they have 70% sequence homology. Possibly the two inserts, Thr5 and a negatively charged hexapeptide at position-55 in MT3, play important roles. A series of MT3 variants around the EAAEAE hexapeptide have been prepared by site-directed mutagenesis and their properties and reactivity towards pH, EDTA and DTNB have been studied. Our detailed studies revealed that the EAAEAE insert is essential to the property of MT3. It is the hexapeptide insert, to some extent, making the MT3 alpha-domain looser and lower stability of the metal-thiolate cluster, which could be accessed more easily.

Tyrosine phosphatases play an important role in cellular signalling and networking that is antagonistic to the kinases. Near completion of the human genome- sequencing project permits us to review the distribution of this family and study its involvement in different pathways. Ninety-six homologues of the classical and dual- specific tyrosine phosphatases (DuSPs) were identified in the human genome using sensitive sequence search techniques. Uncommon domain architectures were encountered, including an example where a kinase and a phosphatase domain are found to co-exist in a single polypeptide. The evolutionary rate is higher for the DuSP compared with the classical tyrosine phosphatases. Orthologues of the 96 putative human tyrosine phosphatases were identified in four model organisms to study the conservation of the family members. Three nuclear localized tyrosine phosphatases retain an orthologous relationship with all model systems considered but still differ in their domain architectures. The diversity in the multi-domain members of the superfamily occurs mainly through domain recruitment, especially in receptor tyrosine phosphatases. The curation of human tyrosine phosphatases provides a convenient framework for characterizing and analysing the functional and structural properties of this diverse family of proteins.

Alkaline conditions are generally preferred for sanitization of chromatography media by cleaning-in-place (CIP) protocols in industrial biopharmaceutical processes. The use of such rigorous conditions places stringent demands on the stability of ligands intended for use in affinity chromatography. Here, we describe efforts to meet these requirements for a divalent proteinaceous human serum albumin (HSA) binding ligand, denoted ABD*dimer. The ABD*dimer ligand was constructed by genetic head-to-tail linkage of two copies of the ABD* moiety, which is a monovalent and alkali-stabilized variant of one of the serum albumin-binding motifs of streptococcal protein G. Dimerization was performed to investigate whether a higher HSA-binding capacity could be obtained by ligand multimerization. We also investigated the influence on alkaline stability and HSA-binding capacity of three variants (VDANS, VDADS and GGGSG) of the inter-domain linker. Biosensor binding studies showed that divalent ligands coupled using non-directed chemistry demonstrate an increased molar HSA-binding capacity compared with monovalent ligands. In contrast, equal molar binding capacities were observed for both types of ligands when using directed ligand coupling chemistry involving the introduction and recruitment of a unique C-terminal cysteine residue. Significantly higher molar binding capacities were also detected when using the directed coupling chemistry. These results were confirmed in affinity chromatography binding capacity experiments, using resins containing thiol-coupled ligands. Interestingly, column sanitization studies involving exposure to 0.1 M NaOH solution (pH 13) showed that of all the tested constructs, including the monovalent ligand, the divalent ligand construct containing the VDADS linker sequence was the most stable, retaining 95% of its binding capacity after 7 h of alkaline treatment.

A pH-responsive polymer Eudragit S-100 has been found to assist in correct folding of alpha-chymotrypsin denatured with 8 M urea and 100 mM dithiothreitol at pH 8.2. The complete activity could be regained within 10 min during refolding. Both native and refolded enzymes showed emission of intrinsic fluorescence with lambda(max) of 342 nm. Gel electrophoresis showed that the presence of Eudragit S-100 led to dissociation of multimers followed by the appearance of a band at the monomer position. The unfolding (by 8 M urea) and folding (assisted by the polymer) also led to complete renaturation of alpha-chymotrypsin initially denatured by 90% dioxane. The implications of the data in recovery of enzyme activity from inclusion bodies and the interesting possibility in the in vivo context of reversing protein aggregation in amyloid-based diseases have been discussed.

Prion diseases are a group of fatal neurodegenerative disorders associated with structural conversion of a normal, mostly alpha-helical cellular prion protein, PrP(C), into a pathogenic beta-sheet-rich conformation, PrP(Sc). The structure of PrP(C) is well studied, whereas the insolubility of PrP(Sc) makes the characterization of its structure problematic. No proteins similar to PrP, except for its paralog with the same fold, PrP-Doppel, are known. However, PrP-Doppel does not undergo a structural transition into a beta-sheet-rich conformation. Structural information from proteins that share a weak but significant sequence similarity with PrP may be used to gain additional insights into the conformation of PrP(Sc). We construct a sequence profile corresponding to the structured domain of PrP and use this profile to search the SWISS-PROT and TrEMBL databases. We identify a significant sequence similarity between PrP and chimpanzee cytomegalovirus glycoprotein UL9. This glycoprotein scores higher than all PrP-Doppel sequences. Fold recognition methods assign a mainly-beta fold to UL9. Owing to the observed sequence similarity with PrP and a putative mainly-beta fold, the UL9 glycoprotein may represent a potential target for experimental structure determination aimed at obtaining a structural template for PrP(Sc) modeling.

The aim of this work was to study the effect of the formation of more heat-stable conformers of chicken egg ovalbumin during incubation at basic pH (9.9) and elevated temperature (55 degrees C) on the protein aggregation properties at neutral pH. Native ovalbumin (N-OVA) is converted on the hours time-scale into more heat-stable forms denoted I- (intermediate) and S-OVA, that have denaturation temperatures 4.8 and 8.4 degrees C, respectively, higher than that of N-OVA. The conversions most likely proceed via I-OVA, but direct conversion of N-OVA into S-OVA with slower kinetics can not be excluded. It is demonstrated that both I- and S-OVA have similar denaturation characteristics to N-OVA, except that higher temperatures are required for denaturation. The presence of even small contributions of I-OVA does, however, reduce the Stokes radius of the aggregates formed upon heat treatment of the material at 90 degrees C about 2-fold. This affects the gel network formation considerably. Since many (commercial) preparations of ovalbumin contain varying contributions of the more heat-stable forms mentioned, proper characterization or standardization of the isolation procedure of the material is essential to control or predict the industrial application of this protein.