Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:3.2.1.17 (lysozyme)
 21,489 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The construction of an expression vector for increased expression of cytoplasmic proteins in Saccharomyces cerevisiae is described. To enhance the yield of expressed proteins, fusion of ubiquitin to an octapeptide (a FLAG tag) upstream of the respective model genes was applied. During protein maturation ubiquitin is efficiently removed by yeast autologous hydrolases, generating the FLAG octapeptide at the N-terminus. Fusion proteins were recognized by the specific monoclonal antibody M1 directed against the FLAG tag. The FLAG-tagged proteins were purified to homogeneity by immunoaffinity chromatography using an anti-FLAG M1 agarose. Different model proteins, green fluorescent protein, green fluorescent protein-human lysozyme, green fluorescent protein elongation-initiahon factor 5a, green fluorescent protein-rapamycin-selective 25-kDa immunophilin, and green fluorescent protein-heat shock protein 90 beta have been selected to demonstrate the efficiency of the new vector construct.
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PMID:Expression and purification of homogenous proteins in Saccharomyces cerevisiae based on ubiquitin-FLAG fusion. 1192 67

The combination of advanced high-resolution nuclear magnetic resonance (NMR) techniques with high-pressure capability represents a powerful experimental tool in studies of protein folding. This review is organized as follows: after a general introduction of high-pressure, high-resolution NMR spectroscopy of proteins, the experimental part deals with instrumentation. The main section of the review is devoted to NMR studies of reversible pressure unfolding of proteins with special emphasis on pressure-assisted cold denaturation and the detection of folding intermediates. Recent studies investigating local perturbations in proteins and the experiments following the effects of point mutations on pressure stability of proteins are also discussed. Ribonuclease A, lysozyme, ubiquitin, apomyoglobin, alpha-lactalbumin and troponin C were the model proteins investigated.
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PMID:High-resolution nuclear magnetic resonance studies of proteins. 1198 93

The glycine-alanine repeat (GAr) of the Epstein-Barr virus nuclear antigen-1 is a cis-acting transferable element that inhibits ubiquitin/proteasome-dependent proteolysis in vitro and in vivo. We have here examined the effect of a synthetic 20-mer GAr oligopeptide on the degradation of iodinated or biotin labeled lysozyme in a rabbit reticulocyte lysates in vitro assay. Micromolar concentrations of the GA-20 peptide inhibited the hydrolysis of lysozyme without significant effect on ubiquitination. Addition of the peptide did not inhibit the hydrolysis of fluorogenic substrate by purified proteasomes and did not affect the ubiquitination of lysozyme. An excess of the peptide failed to compete for binding of a synthetic tetra-ubiquitin complex to the S5a ubiquitin-binding subunit of the 19S regulator, confirming that the GAr does not block the access of ubiquitinated substrates to the proteasome. Our data suggest that the GAr may act by destabilizing the interaction of ubiquitinated substrates with the proteasome and promote the premature release of the substrate.
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PMID:Inhibition of ubiquitin-dependent proteolysis by a synthetic glycine-alanine repeat peptide that mimics an inhibitory viral sequence. 1209 25

Accelerated proteolytic cleavage of proteins under controlled microwave irradiation has been achieved. Selective peptide fragmentation by endoproteases trypsin or lysine C led to smaller peptides that were analyzed by matrix-assisted laser desorption ionization (MALDI) or liquid chromatography-electrospray ionization (LC-ESI) techniques. The efficacy of this technique for protein mapping was demonstrated by the mass spectral analyses of the peptide fragmentation of several biologically active proteins, including cytochrome c, ubiquitin, lysozyme, myoglobin, and interferon alpha-2b. Most important, using this novel approach digestion of proteins occurs in minutes, in contrast to the hours required by conventional methods.
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PMID:Microwave-enhanced enzyme reaction for protein mapping by mass spectrometry: a new approach to protein digestion in minutes. 1238 49

Oxidatively modified proteins that accumulate in aging and many diseases can form large aggregates because of covalent cross-linking or increased surface hydrophobicity. Unless repaired or removed from cells, these oxidized proteins are often toxic, and threaten cell viability. Most oxidatively damaged proteins appear to undergo selective proteolysis, primarily by the proteasome. Previous work from our laboratory has shown that purified 20 S proteasome degrades oxidized proteins without ATP or ubiquitin in vitro, but there have been no studies to test this mechanism in vivo. The aim of this study was to determine whether ubiquitin conjugation is necessary for the degradation of oxidized proteins in intact cells. We now show that cells with compromised ubiquitin-conjugating activity still preferentially degrade oxidized intracellular proteins, at near normal rates, and this degradation is still inhibited by proteasome inhibitors. We also show that progressive oxidation of proteins such as lysozyme and ferritin does not increase their ubiquitinylation, yet the oxidized forms of both proteins are preferentially degraded by proteasome. Furthermore, rates of oxidized protein degradation by cell lysates are not significantly altered by addition of ATP, excluding the possibility of an energy requirement for this pathway. Contrary to earlier popular belief that most proteasomal degradation is conducted by the 26 S proteasome with ubiquitinylated substrates, our work suggests that oxidized proteins are degraded without ubiquitin conjugation (or ATP hydrolysis) possibly by the 20 S proteasome, or the immunoproteasome, or both.
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PMID:Ubiquitin conjugation is not required for the degradation of oxidized proteins by proteasome. 1240 7

The progressive reduction of charge in charge states of non-denatured proteins (lysozyme, ubiquitin, and cytochrome c), observed with nanospray in the positive ion mode, when the buffer salt ammonium acetate is replaced by ethylammonium acetates (EtNH(3)Ac, Et(2)NH(2)Ac and Et(3)NHAc) is rationalized on the basis of the charge residue model (CRM). The charge states of the multiply protonated protein are shown to be controlled by the increasing gas-phase basicities, GB(B), of the bases(B) NH(3), EtNH(2), Et(2)NH and Et(3)N. Charge states derived from evaluated apparent gas-phase basicities GB(app) of the basic side-chains of the protein and the known GB(B) of the above bases are found to be in agreement with the experimentally observed charge states. This is a requirement of the CRM, because in this model the small positive ions (the buffer cations in the present case) at the surface of the electrospray droplets are the excess ions that provide the charge of the final small droplet that contains the protein molecule and on evaporation of the solvent transfer the charge to the protein. The observed charge states in the absence of buffer salts, i.e. pure water, are attributed to excess H(3)O(+) ions produced by the electrolysis process that attends electrospray. A proposed extended mechanism provides predictions of factors that determine the sensitivity for detection of the multiply protonated proteins. Consideration of restraints imposed by the CRM lead to some simple predictions for conditions that should be present to obtain accurate determinations by electrospray and nanospray of stability constants for the protein-complex equilibrium in aqueous solution.
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PMID:Effect of buffer cations and of H3O+ on the charge states of native proteins. Significance to determinations of stability constants of protein complexes. 1282 31

The ubiquitin-proteasome pathway is critically involved in the pathology of neurodegenerative diseases characterized by protein misfolding and aggregation. Data in the present study suggest that the polyglutamine neurodegenerative disease protein, ataxin-3 (AT3), functions in the ubiquitin-proteasome pathway. AT3 contains an ubiquitin interaction motif (UIM) domain that binds polyubiquitylated proteins with a strong preference for chains containing four or more ubiquitins. Mutating the conserved leucine in the first UIM (L229A) almost totally eliminates binding to polyubiquitin chains while a similar mutation in the second UIM (L249A) also inhibits binding to polyubiquitin chains but to a lesser extent. Both wild-type and pathological AT3 increase cellular levels of a short-lived GFP that is degraded by the ubiquitin-proteasome pathway. AT3 has several properties characteristic of ubiquitin proteases including decreasing polyubiquitylation of 125I-lysozyme by removing ubiquitin from polyubiquitin chains, cleaving a ubiquitin protease substrate, and binding the specific ubiquitin protease inhibitor, ubiquitin-aldehyde. Mutating the predicted catalytic cysteine in AT3 inhibits each of these ubiquitin protease activities. The ability to bind and cleave ubiquitylated proteins is consistent with AT3 playing a role in the ubiquitin-proteasome system. This raises the possibility that pathological AT3, which tends to misfold and aggregate, may be exposed to aggregate-prone misfolded/denatured proteins as part of its normal function.
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PMID:The polyglutamine neurodegenerative protein ataxin-3 binds polyubiquitylated proteins and has ubiquitin protease activity. 1455 76

Preparation of proteins in their crystalline state has been found to be important in producing stable therapeutic protein formulations, cross-linked enzyme crystals for application in industrial processes, generating novel porous media for separations, and of course in structure elucidation. Of these applications only X-ray crystallography requires large crystals, defined here as being crystals 100s of microns or greater in size. Smaller crystals have attractive attributes in many instances, and are just as useful in structure determination by solid state NMR (ssNMR) as are large crystals. In this paper we outline a simple set of procedures for preparing nanocrystalline protein samples for ssNMR or other applications and describe the characterization of their crystallinity by ssNMR and X-ray powder diffraction. The approach is demonstrated in application to five different proteins: ubiquitin, lysozyme, ribonuclease A, streptavidin, and cytochrome c. In all instances the nanocrystals produced are found to be highly crystalline as judged by natural abundance 13C ssNMR and optical and electron microscopy. We show for ubiquitin that nanocrystals prepared by rapid batch crystallization yield equivalent 13C ssNMR spectra to those of larger X-ray diffraction quality crystals. Single crystal and powder X-ray diffraction measurements are made to compare the degree of order present in polycrystalline, nanocrystalline, and lyophilized ubiquitin. Solid state 13C NMR is also used to show that ubiquitin nanocrystals are thermally robust, giving no indication of loss of local order after repeated temperature cycling between liquid nitrogen and room temperature. The methods developed are rapid and should scale well from the tenths of milligram to multi-gram scales, and as such should find wide utility in the preparation of protein nanocrystals for applications in catalysis, separations, and especially in sample preparation for structural studies using ssNMR.
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PMID:Preparation of protein nanocrystals and their characterization by solid state NMR. 1456 26

Nano-electrospray-ionization mass spectrometry (nano-ESI-MS) is employed here to describe equilibrium protein conformational transitions and to analyze the influence of instrumental settings, pH, and solvent surface tension on the charge-state distributions (CSD). A first set of experiments shows that high flow rates of N(2) as curtain gas can induce unfolding of cytochrome c (cyt c) and myoglobin (Mb), under conditions in which the stability of the native protein structure has already been reduced by acidification. However, it is possible to identify conditions under which the instrumental settings are not limiting factors for the conformational stability of the protein inside ESI droplets. Under such conditions, equilibrium unfolding transitions described by ESI-MS are comparable with those obtained by other established biophysical methods. Experiments with the very stable proteins ubiquitin (Ubq) and lysozyme (Lyz) enable testing of the influence of extreme pH changes on the ESI process, uncoupled from acid-induced unfolding. When HCl is used for acidification, Ubq and Lyz mass spectra do not change between pH~7 and pH 2.2, indicating that the CSD is highly characteristic of a given protein conformation and not directly affected by even large pH changes. Use of formic or acetic acid for acidification of Ubq solutions results in major spectral changes that can be interpreted in terms of protein unfolding as a result of the increased hydrophobicity of the solvent. On the other hand, Lyz, cyt c, and Mb enable direct comparison of protein CSD (corresponding to either the folded or the unfolded protein) in HCl or acetic acid solutions at low pH. The values of surface tension for these solutions differ significantly. Confirming indications already present in the literature, we observe very similar CSD under these solvent conditions for several proteins in either compact or disordered conformations. The same is true for comparison between water and water-acetic acid for folded cyt c and Lyz. Thus, protein CSD from water-acetic solutions do not seem to be limited by the low surface tension of acetic acid as previously suggested. This result could reflect a general lack of dependence of protein CSD on the surface tension of the solvent. However, it is also possible that the effect of acetic acid on the precursor ESI droplets is smaller than generally assumed.
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PMID:Interpreting conformational effects in protein nano-ESI-MS spectra. 1466 47

We report an automated procedure for high-throughput NMR resonance assignment for a protein of known structure, or of an homologous structure. Our algorithm performs Nuclear Vector Replacement (NVR) by Expectation/Maximization (EM) to compute assignments. NVR correlates experimentally-measured NH residual dipolar couplings (RDCs) and chemical shifts to a given a priori whole-protein 3D structural model. The algorithm requires only uniform (15)N-labelling of the protein, and processes unassigned H(N)-(15)N HSQC spectra, H(N)-(15)N RDCs, and sparse H(N)-H(N) NOE's (d(NN)s). NVR runs in minutes and efficiently assigns the (H(N),(15)N) backbone resonances as well as the sparse d(NN)s from the 3D (15)N-NOESY spectrum, in O (n(3)) time. The algorithm is demonstrated on NMR data from a 76-residue protein, human ubiquitin, matched to four structures, including one mutant (homolog), determined either by X-ray crystallography or by different NMR experiments (without RDCs). NVR achieves an average assignment accuracy of over 99%. We further demonstrate the feasibility of our algorithm for different and larger proteins, using different combinations of real and simulated NMR data for hen lysozyme (129 residues) and streptococcal protein G (56 residues), matched to a variety of 3D structural models.
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PMID:An expectation/maximization nuclear vector replacement algorithm for automated NMR resonance assignments. 1501 27


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