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Correct Folding (correct + folding)
Selected AbstractsCharacterization of the glutamyl endopeptidase from Staphylococcus aureus expressed in Escherichia coliFEBS JOURNAL, Issue 3 2008Takayuki K. Nemoto V8 protease, a member of the glutamyl endopeptidase I family, of Staphylococcus aureus V8 strain (GluV8) is widely used for proteome analysis because of its unique substrate specificity and resistance to detergents. In this study, an Escherichia coli expression system for GluV8, as well as its homologue from Staphylococcus epidermidis (GluSE), was developed, and the roles of the prosegments and two specific amino acid residues, Val69 and Ser237, were investigated. C-terminal His6 -tagged proGluSE was successfully expressed from the full-length sequence as a soluble form. By contrast, GluV8 was poorly expressed by the system as a result of autodegradation; however, it was efficiently obtained by swapping its preprosegment with that of GluSE, or by the substitution of four residues in the GluV8 prosequence with those of GluSE. The purified proGluV8 was converted to the mature form in vitro by thermolysin treatment. The prosegment was essential for the suppression of proteolytic activity, as well as for the correct folding of GluV8, indicating its role as an intramolecular chaperone. Furthermore, the four amino acid residues at the C-terminus of the prosegment were sufficient for both of these roles. In vitro mutagenesis revealed that Ser237 was essential for proteolytic activity, and that Val69 was indispensable for the precise cleavage by thermolysin and was involved in the proteolytic reaction itself. This is the first study to express quantitatively GluV8 in E. coli, and to demonstrate explicitly the intramolecular chaperone activity of the prosegment of glutamyl endopeptidase I. [source] Folding of epidermal growth factor-like repeats from human tenascin studied through a sequence frame-shift approachFEBS JOURNAL, Issue 21 2004Francesco Zanuttin In order to investigate the factors that determine the correct folding of epidermal growth factor-like (EGF) repeats within a multidomain protein, we prepared a series of six peptides that, taken together, span the sequence of two EGF repeats of human tenascin, a large protein from the extracellular matrix. The peptides were selected by sliding a window of the average length of tenascin EGF repeats over the sequence of EGF repeats 13 and 14. We thus obtained six peptides, EGF-f1 to EGF-f6, that are 33 residues long, contain six cysteines each, and bear a partial overlap in the sequence. While EGF-f1 corresponds to the native EGF-14 repeat, the others are frame-shifted EGF repeats. We carried out the oxidative folding of these peptides in vitro, analyzed the reaction mixtures by acid trapping followed by LC-MS, and isolated some of the resulting products. The oxidative folding of the native EGF-14 peptide is fast, produces a single three-disulfide species with an EGF-like disulfide topology and a marked difference in the RP-HPLC retention time compared with the starting product. On the contrary, frame-shifted peptides fold more slowly and give mixtures of three-disulfide species displaying RP-HPLC retention times that are closer to those of the reduced peptides. In contrast to the native EGF-14, the three-disulfide products that could be isolated are mainly unstructured, as determined by CD and NMR spectroscopy. We conclude that both kinetics and thermodynamics drive the correct pairing of cysteines, and speculate about how cysteine mispairing could trigger disulfide reshuffling in vivo. [source] ALys amyloidosis caused by compound heterozygosity in Exon 2 (Thr70Asn) and Exon 4 (Trp112Arg) of the lysozyme gene,,HUMAN MUTATION, Issue 1 2006Christoph Röcken Abstract Hereditary amyloidoses are caused by germline mutations, which increase the propensity of a protein to form cross-, aggregates and deposit as amyloid. Hereditary amyloidoses are particularly interesting as they help to understand how changes in the primary structure of an otherwise non-amyloidogenic protein contribute to amyloidogenesis. Here we report on a novel form of systemic ALys amyloidosis, caused by compound heterozygosity in exon 2 (p.T70N) and exon 4 (p.W112R) of the lysozyme gene (LYZ), with both mutations being present on the same allele. This type of hereditary ALys amyloidosis is characterized by extended amyloid deposits in the upper gastrointestinal tract, entire colon, and kidney, leading to gastrointestinal bleeding. Both mutations are probably effective in disease manifestation. The novel mutation at position 112 in the mature protein is located within the ,-helical domain of the protein and therefore outside the cluster of residues that has so far been implicated in ALys amyloidosis. Taken together with the p.T70N mutation, this results in a lysozyme species where the correct folding of various protein domains is probably impaired and increases the propensity of amyloid fibril formation. Interestingly, this form of ALys amyloidosis is also characterized by the occurrence of proteolytic fragments of lysozyme in the amyloid deposits. © 2005 Wiley-Liss, Inc. [source] Folding in solution of the C-catalytic protein fragment of angiotensin-converting enzymeJOURNAL OF PEPTIDE SCIENCE, Issue 8 2009Sotirios-Spyridon M. Vamvakas Abstract Angiotensin-converting enzyme (ACE) is a key molecule of the renin,angiotensin,aldosterone system which is responsible for the control of blood pressure. For over 30 years it has become the target for fighting off hypertension. Many inhibitors of the enzyme have been synthesized and used widely in medicine despite the lack of ACE structure. The last 5 years the crystal structure of ACE separate domains has been revealed, but in order to understand how the enzyme works it is necessary to study its structure in solution. We present here the cloning, overexpression in Escherichia coli, purification and structural study of the Ala959 to Ser1066 region (ACE_C) that corresponds to the C-catalytic domain of human somatic angiotensin-I-converting enzyme. ACE_C was purified under denatured conditions and the yield was 6 mg/l of culture. Circular dichroism (CD) spectroscopy indicated that 1,1,1-trifluoroethanol (TFE) is necessary for the correct folding of the protein fragment. The described procedure can be used for the production of an isotopically labelled ACE959,1066 protein fragment in order to study its structure in solution by NMR spectroscopy. Copyright © 2009 European Peptide Society and John Wiley & Sons, Ltd. [source] Synthesis of the C -terminal domain of the tissue inhibitor of metalloproteinases-1(TIMP-1)JOURNAL OF PEPTIDE SCIENCE, Issue 7 2003József Bódi Abstract According to recent investigations, the C -terminal domain of the tissue inhibitor of matrix metalloproteinases-1 (TIMP-1) is responsible for some biological effects that are independent of the enzyme-inhibiting effect of the N -terminal domain of the molecule. The C -terminal domain has been prepared for structure,biological activity investigations. After the chemical synthesis and the folding of the linear peptide, LC-MS and MALDI-MS analysis revealed that two isomers with different disulphide bond arrangements were formed. Since more than 30 folding experiments resulted in products with a very similar HPLC-profile, it was concluded that in the absence of the TIMP-1 N -terminal domain no entirely correct folding of the C -terminal domain occurred. Furthermore, it was observed that, in spite of several purification steps, mercury(II) ions were bound to the 6SH-linear peptide; it was demonstrated,using disulphide bonded TIMP-1(Cys145 -Cys166) as a model,that mercury(II) ions can cause peptide degradation at pH 7.8 as well as in 0.1% trifluoroacetic acid. Copyright © 2003 European Peptide Society and John Wiley & Sons, Ltd. [source] Identification of the membrane penetrating domain of Vibrio cholerae cytolysin as a ,-barrel structureMOLECULAR MICROBIOLOGY, Issue 1 2005Angela Valeva Summary Vibrio cholerae cytolysin (VCC) is an oligomerizing pore-forming toxin that is related to cytolysins of many other Gram-negative organisms. VCC contains six cysteine residues, of which two were found to be present in free sulphydryl form. The positions of two intramolecular disulphide bonds were mapped, and one was shown to be essential for correct folding of protoxin. Mutations were created in which the two free cysteines were deleted, so that single cysteine substitution mutants could be generated for site-specific labelling. Employment of polarity-sensitive fluorophores identified amino acid side-chains that formed part of the pore-forming domain of VCC. The sequence commenced at residue 311, and was deduced to form a ,-barrel in the assembled oligomer with the subsequent odd-numbered residues facing the lipid bilayer and even-numbered residues facing the lumen. Pro328/Lys329 were tentatively identified as the position at which the sequence turns back into the membrane and where the antiparallel ,-strand commences. This was deduced from fluorimetric analyses combined with experiments in which the pore was reversibly occluded by derivatization of sulphydryl groups with a bulky moiety. Our data support computer-based predictions that the membrane-permeabilizing amino acid sequence of VCC is homologous to the ,-barrel-forming sequence of staphylococcal cytolysins and identify the ,-barrel as a membrane-perforating structure that is highly conserved in evolution. [source] Secretion of proteins with dimerization capacity by the haemolysin type I transport system of Escherichia coliMOLECULAR MICROBIOLOGY, Issue 4 2004Sofía Fraile Summary The tolerance of the haemolysin transport system (Hly) for exporting dimeric protein substrates to the supernatants of Escherichia coli cultures was examined. A strong dimerization domain (i.e. an amphipathic ,-helix capable of forming a leucine zipper in the yeast transcription factor GCN4) was inserted into an epitope-tagged version of the 23 kDa C-terminal secretion signal of haemolysin (EHlyA). The zipper-containing polypeptide (ZEHlyA) was effectively secreted by E. coli cells carrying the HlyBD transporter and accumulated in the culture media as a stable dimer as determined by gel filtration chromatography. In vivo protein cross-linking experiments and coexpression with a secretion-deficient derivative of ZEHlyA indicated that leucine zipper-dependent dimerization occurs following secretion. To test whether dimerization allows the correct folding of the secreted polypeptide, immunoglobulin VHH -domains obtained from camel antibodies were fused to EHlyA and ZEHlyA. Functional dimerization of the ZEHlyA hybrid was anticipated to increase the apparent binding affinity (i.e. avidity) of the VHH moiety, thus becoming an excellent reporter of correct protein folding and dimerization. Both VHH -EHlyA and VHH -ZEHlyA hybrids were quantitatively secreted and found in the extracellular medium as active monomers and dimers respectively. When compared with their monomeric counterparts, the dimeric VHH -ZEHlyA molecules showed superior binding properties to their cognate antigen, with a 10-fold increase in their avidity. These data reveal a non-anticipated permissiveness of the Hly type I transport machinery for the secretion of substrates with dimerization capacity. [source] Not all J domains are created equal: Implications for the specificity of Hsp40,Hsp70 interactionsPROTEIN SCIENCE, Issue 7 2005Fritha Hennessy Abstract Heat shock protein 40s (Hsp40s) and heat shock protein 70s (Hsp70s) form chaperone partnerships that are key components of cellular chaperone networks involved in facilitating the correct folding of a broad range of client proteins. While the Hsp40 family of proteins is highly diverse with multiple forms occurring in any particular cell or compartment, all its members are characterized by a J domain that directs their interaction with a partner Hsp70. Specific Hsp40,Hsp70 chaperone partnerships have been identified that are dedicated to the correct folding of distinct subsets of client proteins. The elucidation of the mechanism by which these specific Hsp40,Hsp70 partnerships are formed will greatly enhance our understanding of the way in which chaperone pathways are integrated into finely regulated protein folding networks. From in silico analyses, domain swapping and rational protein engineering experiments, evidence has accumulated that indicates that J domains contain key specificity determinants. This review will critically discuss the current understanding of the structural features of J domains that determine the specificity of interaction between Hsp40 proteins and their partner Hsp70s. We also propose a model in which the J domain is able to integrate specificity and chaperone activity. [source] Biologically Important Reactions Catalyzed by RNA MoleculesTHE CHEMICAL RECORD, Issue 5 2002Yutaka Ikeda Abstract The last few years have seen a considerable increase in our understanding of catalysis by naturally occurring RNA molecules called ribozymes. The biological functions of RNA molecules depend upon their adoption of appropriate three-dimensional structures. The structure of RNA has a very important electrostatic component, which results from the presence of charged phosphodiester bonds. Metal ions are usually required to stabilize the folded structures and/or catalysis. Some ribozymes utilize metal ions as catalysts, whereas others use the ions to maintain appropriate three-dimensional structures. In the latter case, the correct folding of the RNA structures can perturb the pKa values of the nucleotide(s) within a catalytic pocket such that they act as general acid/bases catalysts. © 2002 The Japan Chemical Journal Forum and Wiley Periodicals, Inc. Chem Rec 2: 307,318, 2002: Published online in Wiley InterScience (www.interscience.wiley.com) DOI 10.1002/tcr.10031 [source] Production of biopharmaceuticals and vaccines in plants via the chloroplast genomeBIOTECHNOLOGY JOURNAL, Issue 10 2006Henry Daniell Dr.Article first published online: 27 SEP 200 Abstract Transgenic plants offer many advantages, including low cost of production (by elimination of fermenters), storage and transportation; heat stability; and absence of human pathogens. When therapeutic proteins are orally delivered, plant cells protect antigens in the stomach through bioencapsulation and eliminate the need for expensive purification and sterile injections, in addition to development of both systemic and mucosal immunity. Chloroplast genetic engineering offers several advantages, including high levels of transgene expression, transgene containment via maternal inheritance and multi-gene expression in a single transformation event. Hyper-expression of vaccine antigens against cholera, tetanus, anthrax, plague or canine parvovirus (4,31% of total soluble protein, tsp) in transgenic chloroplasts (leaves) or non-green plastids (carrots, tomato), as well as the availability of antibiotic-free selectable markers or the ability to excise selectable marker genes, facilitate oral delivery. Hyper-expression of several therapeutic proteins, including human serum albumin (11.1% tsp), somatotropin (7% tsp), interferon-gamma (6% tsp), anti-microbial peptide (21.5% tsp), facilitates efficient and economic purification. Also, the presence of chaperones and enzymes in chloroplasts facilitate assembly of complex multi-subunit proteins and correct folding of human blood proteins with proper disulfide bonds. Functionality of chloroplast-derived vaccine antigens and therapeutic proteins has been demonstrated by several assays, including the macrophage lysis assay, GM1-ganglioside binding assay, protection of HeLa cells or human lung carcinoma cells against encephalomyocarditis virus, systemic immune response, protection against pathogen challenge, and growth or inhibition of cell cultures. Thus, transgenic chloroplasts are ideal bioreactors for production of functional human and animal therapeutic proteins in an environmentally friendly manner. [source] From pro defensins to defensins: synthesis and characterization of human neutrophil pro ,-defensin-1 and its mature domainCHEMICAL BIOLOGY & DRUG DESIGN, Issue 2 2003Z. Wu Abstract: Human neutrophil ,-defensins (HNPs) are small, cationic, Cys-rich antimicrobial proteins that play important roles in innate immunity against infectious microbes such as bacteria, fungi and enveloped viruses. Synthesized as inactive precursors in vivo (pre-proHNPs), HNPs are activated through proteolytic removal of the inhibitory pro-peptide required for subcellular sorting and correct folding. We seek to understand the molecular basis for the recognition between the 45-residue pro-peptide and the C-terminal functional domain. Here we described, total chemical synthesis of the 75-residue human neutrophil pro ,-defensin-1 (proHNP1) via native chemical ligation. After oxidative folding, proHNP1 is cleaved by cyanogen bromide at the Met45,Ala46 peptide bond to release the mature form. The native disulfide connectivity in HNP1, i.e. Cys1,Cys6, Cys2,Cys4 and Cys3,Cys5, is verified by mass mapping of peptide fragments generated by proteolytic digestion and Edman degradation. Fluorescence spectroscopy studies and antimicrobial activity assays further support that synthetic proHNP1 and HNP1 are correctly folded. While largely unstructured in aqueous solution, the pro-peptide binds to HNP1 intermolecularly with an apparent Kd value of 6.2 ,m at pH 7.4, confirming the mode of intramolecular inactivation of human ,-defensin precursors. [source] | |||||||||||||