EC:3.2.1.17 - FACTA Search

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)

Serologically detected antigenic determinants unique to an antibody or group of antibodies are called idiotopes. The sum of idiotopes of an antibody constitute its idiotype. Idiotypes have been intensively studied following a hypothesis for the self-regulation of the immune system through a network of idiotype-anti-idiotype interactions. Furthermore, as antigen and anti-idiotypes can competitively bind to idiotype-positive, antigen-specific antibodies, anti-idiotypes may carry an 'internal image' of the external antigen. Here we describe the structure of the complex between the monoclonal anti-lysozyme FabD1.3 and the anti-idiotopic FabE225 at 2.5 A resolution. This complex defines a private idiotope consisting of 13 amino-acid residues, mainly from the complementarity-determining regions of D1.3. Seven of these residues make contacts with the antigen, indicating a significant overlap between idiotope and antigen-combining site. Idiotopic mimicry of the external antigen is not achieved at the molecular level in this example.
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PMID:Three-dimensional structure of an idiotope-anti-idiotope complex. 170 Mar 5

Idiotopes are antigenic determinants, unique to an antibody or group of antibodies, defined by the reaction of anti-idiotopic antibodies with the antibodies bearing the idiotopes. The ensemble of idiotopes of an antibody constitutes its idiotype. Idiotypes are useful as markers to follow specific antibodies and clones of cells in immune responses and the inheritance of immunoglobulin genes. As external antigens and anti-idiotypic antibodies can competitively bind the combining site of specific antibodies, some anti-idiotypic antibodies may resemble the external antigen, thus mimicking its structure. It has been proposed that an anti-idiotypic antibody, anti-anti-X, may resemble the external antigen X and thus carry its 'internal image', but this idea is not unequivocally supported by the three-dimensional structures of anti-idiotopic antibodies, either because the structures of the external antigen or of the anti-idiotopic antibody were unknown, or because the anti-idiotopic antibodies showed no resemblance to the external antigens (reviewed in ref. 10). Functional mimicry of ligands of biological receptors by anti-idiotypic antibodies has been described in several systems (reviewed in ref. 11). But how closely can antibodies mimic antigens at the molecular level? Here we present the crystal structure of an idiotope-anti-idiotope complex between the Fv fragments of the anti-lysozyme antibody D1.3 and the anti-D1.3 antibody E5.2. D1.3 contacts the antigen, lysozyme and the anti-idiotopic E5.2 through essentially the same combining-site residues. In addition, E5.2 interacts with D1.3, making contacts similar to those between lysozyme and D1.3. Thus, the anti-idiotopic antibody E5.2 mimics lysozyme in its binding interactions with D1.3. Validating these observations, E5.2, used as an immunogen, induces an anti-lysozyme response.
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PMID:Molecular basis of antigen mimicry by an anti-idiotope. 753 3

The crystal structure of the complex between the cross-reacting antigen Guinea fowl lysozyme and the Fab from monoclonal antibody F9.13.7, raised against hen egg lysozyme, has been determined by x-ray diffraction to 3-A resolution. The antibody interacts with exposed residues of an alpha-helix and surrounding loops adjacent to the lysozyme active site cleft. The epitope of lysozyme bound by antibody F9.13.7 overlaps almost completely with that bound by antibody HyHEL10; the same 12 residues of the antigen interact with the two antibodies. The antibodies, however, have different combining sites with no sequence homology at any of their complementarity-determining regions and show a dissimilar pattern of cross-reactivity with heterologous antigens. Side chain mobility of epitope residues contributes to confer steric and electrostatic complementarity to differently shaped combining sites, allowing functional mimicry to occur. The capacity of two antibodies that have different fine specificities to bind the same area of the antigen emphasizes the operational character of the definition of an antigenic determinant. This example demonstrates that degenerate binding of the same structural motif does not require the existence of sequence homology or other chemical similarities between the different binding sites.
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PMID:Crystal structure of a cross-reaction complex between Fab F9.13.7 and guinea fowl lysozyme. 762 16

Under a variety of circumstances antibodies can be elicited against the variable region of other antibody molecules (anti-idotypic antibodies, anti-ids). Some of the antibodies are directed against the binding sites of the eliciting antibodies. Of particular interest are the antibodies that recognize epitopes of the original antibody that are in contact with antigen. Antibodies of this kind have been produced and used in a variety of situations including attempts at using them as therapeutic agents. In recent years structural data at the atomic level have emerged for anti-idiotypic antibodies from X-ray diffraction studies. These studies provided structural basis for molecular mimicry of anti-ids. For a large globular antigen (lysozyme), where epitope is noncontinuguous, molecular mimicry is not present at the atomic level. In this case, idiotopes are largely composed of CDR residues, but framework residues are also used. For an epitope that is sequence-specific (anti-FIPV system), molecular mimicry appears to be present as evidenced by the sequence homology between the CDR loops of the anti-id and the epitope of the original antigen. In the case of a small hormone antigen (angiotensin II), an internal image of the eliciting antigen appears to be represented in a single CDR loop of the antiiodiotypic antibody.
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PMID:Anti-idiotypic antibodies: biological function and structural studies. 782 58

Anti-idiotopic antibodies react with unique antigenic features, usually associated with the combining sites, of other antibodies. They may thus mimic specific antigens that react with the same antibodies. The structural basis of this mimicry is analyzed here in detail for an anti-idiotopic antibody that mimics the antigen, hen egg-white lysozyme. The crystal structure of an anti-hen-egg-white lysozyme antibody (D1.3) complexed with an anti-idiotopic antibody (E5.2) has been determined at a nominal resolution of 1.9 A. E5.2 contacts substantially the same residues of D1.3 as lysozyme, thus mimicking its binding to D1.3. The mimicry embodies conservation of hydrogen bonding: six of the 14 protein-protein hydrogen bonds bridging D1.3-E5.2 are structurally equivalent to hydrogen bonds bridging D1.3-lysozyme. The mimicry includes a similar number of van der Waals interactions. The mimicry of E5.2 for lysozyme, however, does not extend to the topology of the non-polar surfaces of E5.2 and lysozyme, which are in contact with D1.3 as revealed by a quantitative analysis of the contacting surface similarities between E5.2 and lysozyme. The structure discussed herein shows that an anti-idiotopic antibody can provide an approximate topological and binding-group mimicry of an external antigen, especially in the case of the hydrophilic surfaces, even though there is no sequence homology between the anti-idiotope and the antigen.
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PMID:Crystal structure of an Fv-Fv idiotope-anti-idiotope complex at 1.9 A resolution. 895 Feb 73

Peptides have the potential for targeting vaccines against pre-specified epitopes on folded proteins. When polyclonal antibodies against native proteins are used to screen peptide libraries, most of the peptides isolated align to linear epitopes on the proteins. The mechanism of cross-reactivity is unclear; both structural mimicry by the peptide and induced fit of the epitope may occur. The most effective peptide mimics of protein epitopes are likely to be those that best mimic both the chemistry and the structure of epitopes. Our goal in this work has been to establish a strategy for characterizing epitopes on a folded protein that are candidates for structural mimicry by peptides. We investigated the chemical and structural bases of peptide-protein cross-reactivity using phage-displayed peptide libraries in combination with computational structural analysis. Polyclonal antibodies against the well-characterized antigens, hen eggwhite lysozyme and worm myohemerythrin, were used to screen a panel of phage-displayed peptide libraries. Most of the selected peptide sequences aligned to linear epitopes on the corresponding protein; the critical binding sequence of each epitope was revealed from these alignments. The structures of the critical sequences as they occur in other non-homologous proteins were analyzed using the Sequery and Superpositional Structural Assignment computer programs. These allowed us to evaluate the extent of conformational preference inherent in each sequence independent of its protein context, and thus to predict the peptides most likely to have structural preferences that match their protein epitopes. Evidence for sequences having a clear structural bias emerged for several epitopes, and synthetic peptides representing three of these epitopes bound antibody with sub-micromolar affinities. The strong preference for a type II beta-turn predicted for one peptide was confirmed by NMR and circular dichroism analyses. Our strategy for identifying conformationally biased epitope sequences provides a new approach to the design of epitope-targeted, peptide-based vaccines.
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PMID:The role of structure in antibody cross-reactivity between peptides and folded proteins. 968 Apr 84

Whereas antibodies have demonstrated the ability to mimic various compounds, classic heavy/light-chain antibodies may be limited in their applications. First, they tend not to bind enzyme active site clefts. Second, their size and complexity present problems in identifying key elements for binding and in using these elements to produce clinically valuable compounds. We have previously shown how cAb-Lys3, a single variable domain fragment derived from a lysozyme-specific camel antibody naturally lacking light chains, overcomes the first limitation to become the first antibody structure observed penetrating an enzyme active site. We now demonstrate how cAb-Lys3 mimics the oligosaccharide substrate functionally (inhibition constant for lysozyme, 50 nM) and structurally (lysozyme buried surface areas, hydrogen bond partners, and hydrophobic contacts are similar to those seen in sugar-complexed structures). Most striking is the mimicry by the antibody complementary determining region 3 (CDR3) loop, especially Ala104, which mimics the subsite C sugar 2-acetamido group; this group has previously been identified as a key feature in binding lysozyme. Comparative simplicity, high affinity and specificity, potential to reach and interact with active sites, and ability to mimic substrate suggest that camel heavy-chain antibodies present advantages over classic antibodies in the design, production, and application of clinically valuable compounds.
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PMID:Camel single-domain antibody inhibits enzyme by mimicking carbohydrate substrate. 972 20

We created hybrid proteins to study the functions of TonB. We first fused the portion of Escherichia coli tonB that encodes the C-terminal 69 amino acids (amino acids 170 to 239) of TonB downstream from E. coli malE (MalE-TonB69C). Production of MalE-TonB69C in tonB(+) bacteria inhibited siderophore transport. After overexpression and purification of the fusion protein on an amylose column, we proteolytically released the TonB C terminus and characterized it. Fluorescence spectra positioned its sole tryptophan (W213) in a weakly polar site in the protein interior, shielded from quenchers. Affinity chromatography showed the binding of the TonB C-domain to other proteins: immobilized TonB-dependent (FepA and colicin B) and TonB-independent (FepADelta3-17, OmpA, and lysozyme) proteins adsorbed MalE-TonB69C, revealing a general affinity of the C terminus for other proteins. Additional constructions fused full-length TonB upstream or downstream of green fluorescent protein (GFP). TonB-GFP constructs had partial functionality but no fluorescence; GFP-TonB fusion proteins were functional and fluorescent. The activity of the latter constructs, which localized GFP in the cytoplasm and TonB in the cell envelope, indicate that the TonB N terminus remains in the inner membrane during its biological function. Finally, sequence analyses revealed homology in the TonB C terminus to E. coli YcfS, a proline-rich protein that contains the lysin (LysM) peptidoglycan-binding motif. LysM structural mimicry occurs in two positions of the dimeric TonB C-domain, and experiments confirmed that it physically binds to the murein sacculus. Together, these findings infer that the TonB N terminus remains associated with the inner membrane, while the downstream region bridges the cell envelope from the affinity of the C terminus for peptidoglycan. This architecture suggests a membrane surveillance model of action, in which TonB finds occupied receptor proteins by surveying the underside of peptidoglycan-associated outer membrane proteins.
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PMID:Insight from TonB hybrid proteins into the mechanism of iron transport through the outer membrane. 1839 Jun 58

Insects and fungi share a long history of association in various habitats, including the wood-decomposition niche. Fungal mimicry of termite eggs is one of the most striking evolutionary consequences of insect-fungus association. Termites of the genus Reticulitermes often harbor fungal sclerotia, called "termite balls," along with eggs in nursery chambers, whereby the fungus gains a competitor-free habitat in termite nests. Sophisticated morphological and chemical camouflage are needed for the fungus to mimic termite eggs. However, the mechanism of chemical egg mimicry by the fungus is unknown. Here, we show that the fungus mimics termite eggs chemically by producing the cellulose-digesting enzyme beta-glucosidase. We found that the termite egg-recognition pheromone consists of beta-glucosidase and lysozyme. Both enzymes are major salivary compounds in termites and are also produced in termite eggs. Termite balls were tended by termites only when the fungus produced beta-glucosidase. Our results demonstrated that the overlap of the cellulose digestion niche between termites and the fungus sharing the same chemicals provided the opportunity for the origin of termite egg mimicry by the fungus. This suggests that pheromone compounds might have originally evolved within other life history contexts, only later gaining function in chemical communication.
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PMID:Cuckoo fungus mimics termite eggs by producing the cellulose-digesting enzyme beta-glucosidase. 1911 Apr 29

This paper presents some processes of the antibacterial effect of serum, which mainly results from the activities of complement (C) and lysozyme (muramidase, LZ). The C system consists ofa group of serum proteins and tissue fluids which are activated in a particular order. Complement,operating together with lysozyme, constitutes the main protection from microorganisms entering the body. Pathogenic microorganisms are able to avoid natural protective mechanisms by, among others, molecular mimicry, binding complement control proteins, or secreting proteolytic enzymes.The effectiveness of the cytolytic action of C proteins and LZ also depends on the surface structures of the microorganisms. Imbalance between the activation and deactivation of inflammatory reactions in the presence of pathogens can lead to various pathological states, such as autoimmunological diseases.
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PMID:[The efficiency of the bactericidal action of serum raised by complement and lysozyme against bacteria which avoid the immunological response of higher organisms]. 1985 Sep 71

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