Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: 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)

Exons of eukaryotic genes that encode proteins frequently appear to encode structural and/or functional protein units [Gilbert, W. (1978) Nature (London) 271, 501; Blake, C.C.F. (1979) Nature (London) 277, 598]. alpha-Lactalbumin and c-type lysozyme are functionally quite different but structurally highly homologous proteins. Their gene organizations have been shown to be virtually the same and their exon structures are identical. The exon 2 region of hen lysozyme contains most of the amino acid residues that make up its catalytic cleft. In this study, we engineered a hybrid protein in which the exon 2 region of goat alpha-lactalbumin was replaced with that of hen lysozyme. This conferred catalytic activity on the alpha-lactalbumin, which is a nonenzymatic protein in its native structural form.
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PMID:Functional conversion of the homologous proteins alpha-lactalbumin and lysozyme by exon exchange. 163 Oct 69

The method of in vivo footprinting uses partial methylation of the DNA in living cells with dimethyl sulfate (DMS), cleavage of the DNA chains at modified guanosines with piperidine, and mapping of the site of cleavage by the genomic sequencing technique of Church and Gilbert. Here we report on a spontaneous breakage reaction of DMS-methylated DNA at guanosines as well as adenosines, which is highly non-random with respect to the DNA sequence. In our in vivo genomic footprinting studies at the chicken lysozyme promoter this reaction gave rise to additional adenosine-derived bands in the guanosine sequence ladder.
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PMID:Non-random spontaneous chain breakages occur in DNA methylated with dimethyl sulfate. 279 88

The complexity of protein folding is often aggravated by the low solubility of the denatured state. The inefficiency of the oxidative refolding of reduced, denatured lysozyme results from a kinetic partitioning of the unfolded protein between pathways leading to aggregation and pathways leading to the native structure. Protein disulfide isomerase (PDI), a resident foldase of the endoplasmic reticulum, catalyzes the in vitro oxidative refolding of reduced, disulfide-containing proteins, including denatured lysozyme. Depending on the concentrations of foldase and denatured substrate and the order in which they are added to initiate folding, PDI can exhibit either a chaperone activity or an anti-chaperone activity (Puig, A., and Gilbert, H. F. (1994) J. Biol. Chem 269, 7764-7771). PDI's chaperone activity leads to quantitative recovery of native lysozyme. Its anti-chaperone activity diverts substrate away from productive folding and facilitates disulfide cross-linking of lysozyme into large, inactive aggregates that specifically incorporate PDI. A mutant PDI (NmCm-PDI), in which both the N- and C-terminal active site cysteines have been changed to serines, loses all chaperone activity and behaves as an anti-chaperone at all substrate and PDI concentrations tested. The dithiol/disulfide sites of PDI are essential for the chaperone activity observed at high PDI concentrations, but they are not required for the anti-chaperone activity found at low PDI concentrations. Inactivation of PDI's peptide/protein binding site by a specific photoaffinity label (Noiva, R., Freedman, R. B., and Lennarz, W. J. (1993) J. Biol. Chem. 268, 19210-19217) inhibits the disulfide isomerase and chaperone activity, but the protein still retains its anti-chaperone activity. In a glutathione redox buffer, lysozyme-PDI aggregates are disulfide cross-linked; however, disulfide cross-linking is not required for aggregate formation or for the incorporation of PDI into the aggregates. Although both the peptide binding site and the catalytic active sites of PDI are required for chaperone and disulfide isomerase activity, neither of these sites are involved in PDI's anti-chaperone activity. PDI's anti-chaperone activity could serve as a quality control device by providing an efficient mechanism to retain misfolded proteins in the endoplasmic reticulum (Marquardt, T., and Helenius, A. (1992) J. Cell. Biol. 117, 505-513).
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PMID:The role of the thiol/disulfide centers and peptide binding site in the chaperone and anti-chaperone activities of protein disulfide isomerase. 791 69

Folding catalysts of the endoplasmic reticulum (ER), such as protein disulfide isomerase (PDI), accelerate the slow chemical steps, such as disulfide bond formation, that accompany protein folding. Molecular chaperones of the ER, notably the heavy chain-binding protein, BiP (grp78), bind and release unfolded proteins in an ATP-dependent fashion. In vitro, the fate of reduced, denatured lysozyme is dependent on whether the substrate interacts first with BiP or PDI. Depending on the ratio of PDI to substrate and order in which the components of the reaction are mixed, PDI can exhibit a foldase/chaperone activity, which increases the rate and extent of lysozyme refolding, or it can function as an anti-chaperone that promotes the formation of inactive, disulfide-linked lysozyme aggregates (Puig, A., and Gilbert, H.F. (1994) J. Biol. Chem. 269, 7764-7771). Reduced, denatured lysozyme, but not the native protein, interacts with BiP and efficiently stimulates its peptide-dependent ATPase activity. When present at substoichiometric amounts, BiP, like PDI, facilitates the formation of large, inactive lysozyme aggregates that are non-covalently associated with BiP. BiP and PDI compete for a limited number of sites in these insoluble aggregates. If BiP is present at a high molar excess, the chaperone binds unfolded lysozyme and inhibits its aggregation by maintaining it in a soluble, yet inactive, conformation, both in the presence or absence of ATP. Increasing concentrations of BiP decrease the extent, but not the initial rate, of refolding, suggesting that BiP and PDI compete for unfolded lysozyme and that the BiP-lysozyme complex is not a very good substrate for PDI either in the presence or absence of ATP. Depending on the BiP and PDI concentrations, unfolded lysozyme may either be efficiently refolded into the native conformation in a PDI-catalyzed reaction, or it may form both soluble and insoluble BiP-lysozyme complexes. In vitro, PDI- and BiP-facilitated aggregation, as well as the competition of the two proteins for substrate, reproduces many of the features of the quality control system of the ER.
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PMID:Anti-chaperone behavior of BiP during the protein disulfide isomerase-catalyzed refolding of reduced denatured lysozyme. 792 93

Coexpression of the enzyme, protein disulfide isomerase (PDI), has been shown to increase soluble and secreted IgG levels from baculovirus-infected insect cells (Hsu, T.-A., Watson, S., Eiden, J. J., and Betenbaugh, M. J. (1996) Protein Expression Purif. 7, 281-288). PDI is known to include catalytic active sites in two separate thioredoxin-like domains, one near the amino terminus and another near the carboxyl terminus. To examine the role of these catalytic active sites in enhancing immunoglobulin solubility, baculovirus constructs were utilized with cysteine to serine mutations at the first cysteine of one or both of the CGHC active site sequences. Trichoplusia ni insect cells were coinfected with a baculovirus vector coding for IgG in concert with either the wild-type human PDI virus, amino-terminal mutant (PDI-N), carboxyl-terminal mutant (PDI-C), or mutant with both active sites altered (PDI-NC). Western blot analysis revealed that both immunoglobulins and PDI protein were expressed in the coinfected cells. To evaluate the effect of the PDI variants on immunoglobulin solubility and secretion, the infected cells were labeled with 35S-amino-acids for different periods, and the soluble immunoglobulins were immunoprecipitated from clarified cell lysates and culture medium using anti-IgG antibodies. Only coinfections with the wild-type PDI and PDI-N mutant led to increased immunoglobulin solubility and higher IgG secretion. In contrast, infection with the PDI-C and PDI-NC variants actually lowered immunoglobulin solubility levels below those achieved with a negative control virus. Immunoprecipitation with anti-PDI antibody revealed that heterologous PDI-C and PDI-NC were insoluble, even though PDI-N and wild-type PDI protein were detected in soluble form. The capacity for PDI-N to increase immunoglobulin solubility whereas the PDI-C mutant lowered solubility indicates that the amino- and carboxyl-terminal thioredoxin domains of PDI are functionally distinct in vivo following mutations to the active site. Furthermore, mutations at the active site of the carboxyl-terminal thioredoxin domain result in PDI variants that can act as anti-chaperones of immunoglobulin solubility in vivo as has been observed in vitro for lysozyme aggregation by wild-type PDI and PDI mutants (Puig, A., and Gilbert, H. F. (1994) J. Biol. Chem. 269, 7764-7771).
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PMID:Thioredoxin domain non-equivalence and anti-chaperone activity of protein disulfide isomerase mutants in vivo. 927 9

Protein disulfide isomerase (PDI), a folding catalyst and chaperone can, under certain conditions, facilitate the misfolding and aggregation of its substrates. This behavior, termed antichaperone activity [Puig, A., and Gilbert, H. F., (1994) J. Biol. Chem. 269, 25889] may provide a common mechanism for aggregate formation in the cell, both as a normal consequence of cell function or as a consequence of disease. When diluted from the denaturant, reduced, denatured lysozyme (10-50 microM) remains soluble, although it does aggregate to form an ensemble of species with an average sedimentation coefficient of 23 +/- 5 S (approximately 600 +/- 100 kDa). When low concentrations of PDI (1-5 microM) are present, the majority (80 +/- 8%) of lysozyme molecules precipitate in large, insoluble aggregates, together with 87 +/- 12% of the PDI. PDI-facilitated aggregation occurs even when disulfide formation is precluded by the presence of dithiothreitol (10 mM). Maximal lysozyme-PDI precipitation occurs at a constant lysozyme/PDI ratio of 10:1 over a range of lysozyme concentrations (10-50 microM). Concomitant resolubilization of PDI and lysozyme from these aggregates by increasing concentrations of urea suggests that PDI is an integral component of the mixed aggregate. PDI induces lysozyme aggregation by noncovalently cross-linking 23 S lysozyme species to form aggregates that become so large (approximately 38,000 S) that they are cleared from the analytical ultracentrifuge even at low speed (1500 rpm). The rate of insoluble aggregate formation increases with increasing PDI concentration (although a threshold PDI concentration is observed). However, increasing lysozyme concentration slows the rate of aggregation, presumably by depleting PDI from solution. A simple mechanism is proposed that accounts for these unusual aggregation kinetics as well as the switch between antichaperone and chaperone behavior observed at higher concentrations of PDI.
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PMID:Mechanism of the antichaperone activity of protein disulfide isomerase: facilitated assembly of large, insoluble aggregates of denatured lysozyme and PDI. 1065 66

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