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)

Streptococcal inhibitor of complement (SIC) is a 31 kDa extracellular protein produced by a few highly virulent strains of Streptococcus pyogenes (in particular the M1 strain). It has been shown additionally to inhibit four further components of the mucosal innate response-lysozyme, secretory leucocyte proteinase inhibitor, human alpha-defensin 1 and the cathelicidin LL-37 which are all bactericidal against Group A Streptococci (GAS). We now show that SIC also inhibits variably the antibacterial action of hBD-1, -2 and -3. By enzyme-linked immunosorbent assay (ELISA), SIC binds strongly to hBD-2 and hBD-3, but not at all to hBD-1. Investigation of the antimicrobial action of beta-defensins hBD-1, -2 and -3 against GAS in two different buffer systems shows that both the killing efficiencies of all three defensins, and the binding of SIC to them, occurs more efficiently in 10 mm Tris buffer than in 10 mm phosphate. The lower ionic strength of the Tris buffer may underlie this effect. hBD-1 kills the M1 strain of GAS only in 10 mm Tris, but is able to kill an M6 (SIC negative) strain in 10 mm phosphate. The inhibition of hBD-3 by SIC is clearly of physiological relevance, that of hBD-2 is likely to be so, but the inhibition of hBD-1 occurs only at lower ionic strength than is likely to be encountered in vivo. Elastase digestion of SIC yields three major fragments of MW 3.843 kDa comprising residues 1-33 (fragment A); 10.369 kDa comprising residues 34-126 (fragment B); and MW 16.487 kDa, comprising residues 127-273 (fragment C). By ELISA, only fragment B binds to hBD-2 and hBD-3 and this may indicate the inhibitory portion of the SIC molecule.
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PMID:The interaction of streptococcal inhibitor of complement (SIC) and its proteolytic fragments with the human beta defensins. 1505 82

The antimicrobial activity of the collective molecules comprising human milk reflects an evolutionarily successful paradigm for preventing and limiting microbial infection. Understanding the molecules that participate in this process and how they work can yield insight into potentially new antimicrobial therapies. Upon proteolytic processing, antimicrobial peptides can be derived from milk proteins, such as lactoferrin, casein, and lysozyme. Similarly, using the HIV-1 gp41 protein template, we have demonstrated that the 28-residue C-terminus, when produced as an independent peptide, exhibits selective toxicity for bacteria over eukaryotic cells. Upon optimizing this sequence for cationic charge and hydrophobic character presented as a alpha-helical structure, we show improved capability of the parent LLP1 sequence to selectively kill bacteria in the host environment and that this activity is increased by the inclusion of Trp residues on the hydrophobic face. We report that it is possible to (i) design de novo antimicrobial peptides that demonstrate optimal antimicrobial activity with minimal inflammatory activity and (ii) design antimicrobial peptides to function in a defined environment. In the end, we describe a de novo designed antimicrobial peptide, WLBU2, which is selectively toxic to microbial pathogens in complex environments and does not stimulate a significant immunomodulatory response. In spite of these properties, WLBU2 activity against Pseudomonas aeruginosa in human milk is inferior to the host peptide LL37 with regard to antimicrobial potency. These studies demonstrate that antimicrobial peptides can be engineered for greater potency in one medium but may not be optimal for working in a different medium such as human milk.
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PMID:Antimicrobial peptides in mucosal secretions: the importance of local secretions in mitigating infection. 1586 26

Beside its physical barrier against invading microorganisms, the skin has the ability to produce a number of antimicrobial peptides and proteins, including human beta-defensins, cathelicidin LL-37 and lysozyme that participate in the innate host defense. These antimicrobial agents are strongly active against a wide spectrum of various pathogens such as bacteria, viruses and fungi. Thus, antimicrobial agents are proposed to be promising candidates for innovative anti-infective drugs, and some antimicrobial peptides are currently used in clinical trials for treatment of various skin infections. In addition to their direct antimicrobial functions against invading pathogenic microorganisms, antimicrobial agents have also multiple roles as mediators of inflammation with the effects on epithelial and inflammatory cells, influencing cell proliferation, wound healing, cytokine/chemokine production and chemotaxis. This review describes the biology of these antimicrobial molecules and discusses their structure, expression and functions. Understanding the actions of antimicrobial agents in skin will provide further insight into the mechanism of innate cutaneous disease control, and yield novel therapeutic approaches to the treatment of skin disorders.
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PMID:Protective roles of the skin against infection: implication of naturally occurring human antimicrobial agents beta-defensins, cathelicidin LL-37 and lysozyme. 1615 May 77

Phenylketonuria (PKU) is an autosomal recessive metabolic disorder caused by phenylalanine hydroxylase (PAH) deficiency. Accumulation of phenylalanine leads to severe mental and psychomotor retardation, and hypopigmentation of skin and hair. We have demonstrated the cognitive outcome of biochemical and phenotypic reversal by the adeno-associated virus vector-mediated gene delivery of a human PAH transgene. In this study, we identified the expression of genes related to pathologic abnormalities of the PKU-affected brain, in which the symptoms of PKU are mainly manifest, and transcriptional changes in effective gene therapy treatment using oligonucleotide array. Therapeutic effectiveness was verified by change in enzyme activity (15+/-5.84%), phenylalanine plasma level (261+/-108 microM), and coat color. Our data indicated that 12 genes were significantly up-regulated in PKU. Four are involved in defense and inflammatory responses of neutrophils (NE, MPO, NGP, and CRAMP), three other overexpressed genes are related to extracellular matrix organization and degradation (COL1A1, COL1A2, and MMP13); the remainder were a nociceptor in sensory neurons (MrgA1), a structural gene of P lysozyme (Lzp-s), an immunoglobulin alpha heavy chain constant region gene (Igh-2), an osteocalcin-related protein precursor (Bglap-rs1), and a membrane-spanning 4 domain, subfamily A, member 3 (Ms4a3). Data demonstrated that elevated genes in the PKU-affected brain could be normalized by human PAH gene delivery. Although we could not precisely link transcript level changes and neurologic pathogenesis, this study provides a more comprehensive understanding of the PKU-affected brain at the molecular level, possibly resulting in better therapeutic approaches.
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PMID:Reversal of gene expression profile in the phenylketonuria mouse model after adeno-associated virus vector-mediated gene therapy. 1615 Jun 27

Articular joint infection is a surprisingly rare event considering the frequency of joint arthrocentesis and other invasive procedures applied to limb joints. This observation led us to the hypothesis that a local "chemical shield" in the form of antimicrobial proteins provides synovial membrane and articular cartilage with resistance to infection. We subsequently began a systematic analysis of in vitro and in vivo antimicrobially active proteins in healthy articular joints and in disease states such as pyogenic arthritis, rheumatoid arthritis, and osteoarthritis. An anatomical approach with systematic characterization combined with antimicrobial testing revealed expression and production of human antibiotic peptides and proteins. In this review, we focus on the most prominent antimicrobial proteins in articular joints, which we have identified as lysozyme, lactoferrin, secretory phospholipase A2, RNase 7, CAP37, the cathelicidin LL37, and especially the human beta-defensin-2 and -3 (HBD-2/-3). Activation pathways and possible antimicrobial functions are discussed and the involvement in non-antimicrobial processes such as tissue remodelling is also considered.
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PMID:Expression and regulation of antimicrobial peptides in articular joints. 1632 Aug 29

SIC (streptococcal inhibitor of complement) is a 31 kDa protein secreted by a few highly virulent strains of GAS (group A streptococci), predominantly by the M1 strain. Initially described as an inhibitor of the membrane attack complex of complement, it has turned out to be a polyfunctional inhibitor of the innate mucosal immune response. The SIC protein sequence contains three domains: an N-terminal SRR (short repeat region), followed by three longer tandem repeats [LRR (long repeat region)] and a C-terminal PRR (proline-rich region). SIC inhibits the antibacterial activity of a wide range of antimicrobial peptides and proteins: i.e. lysozyme, SLPI (secretory leucocyte proteinase inhibitor), LL-37, hNP-1 (human neutrophil peptide-1) and the human beta-defensins 1, 2 and 3. Analysis of the functional properties of recombinant domains of SIC shows that binding and inhibition of lysozyme and human beta-defensin-3 require the SRR+LRR, as does binding to SLPI. Complement inhibition is confined to the SRR. M12 GAS secrete a protein 'distantly related to SIC' (DRS). DRS contains a C-terminal PRR which is significantly similar to that of SIC, but it has no central LRR and the N-terminal SRR is very different. DRS inhibits human beta-defensin-3, but has no effect on lysozyme, SLPI or complement.
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PMID:Inhibition of antimicrobial peptides by group A streptococci: SIC and DRS. 1654 92

Extensive copy number polymorphism was recently reported for innate immunity-related alpha-defensin genes DEFA1 and DEFA3 and beta-defensin genes DEFB4, DEFB103, and DEFB104. To establish whether such polymorphisms are a common feature of innate immune genes we used quantitative real-time PCR to determine the copy numbers of seven genes whose products have important innate immune functions. The genes encoding lysozyme, lactoferrin, cathelicidin antimicrobial peptide (hCAP18/LL-37), cathepsin G, bactericidal/permeability-increasing protein, azurocidin (CAP37/heparin-binding protein), and neutrophil elastase were each found to be single copy per haploid genome. These findings, along with the recent observation that defensin genes DEFA4, DEFA5, DEFA6, and DEFB1 are single copy, suggest that copy number polymorphisms are not a common feature of the innate immune genome but are restricted to a small subset of innate immunity-related genes.
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PMID:Copy number polymorphisms are not a common feature of innate immune genes. 1661 5

Lysozyme is an abundant, cationic antimicrobial protein that plays an important role in pulmonary host defense. Increased concentration of lysozyme in the airspaces of transgenic mice enhanced bacterial killing whereas lysozyme deficiency resulted in increased bacterial burden and morbidity. Lysozyme degrades peptidoglycan in the bacterial cell wall leading to rapid killing of Gram-positive organisms; however, this mechanism cannot account for the protective effect of lysozyme against Gram-negative bacteria. The current study was therefore designed to test the hypothesis that the catalytic activity (muramidase activity) of lysozyme is not required for bacterial killing in vivo. Substitution of serine for aspartic acid at position 53 (D53S) in mouse lysozyme M completely ablated muramidase activity. Muramidase-deficient recombinant lysozyme (LysM(D53S)) killed both Gram-positive and Gram-negative bacteria in vitro. Targeted expression of LysM(D53S) in the respiratory epithelium of wild-type (LysM(+/+)/LysM(D53S)) or lysozyme M(null) mice (LysM(-/-)/LysM(D53S)) resulted in significantly elevated lysozyme protein in the airspaces without any increase in muramidase activity. Intratracheal challenge of transgenic mice with Gram-positive or Gram-negative bacteria resulted in a significant increase in bacterial burden in LysM(-/-) mice that was completely reversed by targeted expression of LysM(D53S). These results indicate that the muramidase activity of lysozyme is not required for bacterial killing in vitro or in vivo.
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PMID:The peptidoglycan-degrading property of lysozyme is not required for bactericidal activity in vivo. 1678 49

Antimicrobial peptides (AMP) produced throughout our body are important effectors in the defense barrier of innate immunity. Here, we have analyzed antimicrobial activity and polypeptide composition of meconium versus neonatal feces to address the development of antimicrobial defense of the neonatal gut. Extracts of meconium exhibited antimicrobial activity against Bacillus megaterium, Escherichia coli, and group B streptococci (GBS) but not against the yeast Candida albicans. Extracts of neonatal feces were found to possess low activity against E. coli, GBS, and C. albicans. However, the anti-B. megaterium activity was higher in the fecal extracts than in meconium. All activities were reduced or abolished when salt was added to the antimicrobial assay. The AMP cathelicidin LL-37, alpha-defensin HNP-1-2, alpha-defensin HD 5, and lysozyme were identified in both meconium and fecal extracts. In addition, HNP-3 and a fragment of azurocidin were found in meconium, whereas the holoprotein azurocidin was detected in feces. In meconium, histones H2A and H4 were isolated and identified by their antimicrobial activity. Notably, LL-37 and lysozyme were found at significantly higher levels in feces than in meconium. Our findings reveal that meconium and feces contain AMP, acting in the defense of the neonatal gut, and may be implicated in the control of the initial colonization.
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PMID:Antimicrobial components of the neonatal gut affected upon colonization. 1741 58

Bacterial pathogens colonize human body surfaces soon after birth. In order to survive the constant threat of invasion and infection, the human innate immune system has evolved several efficient mechanisms to prevent harmful microorganisms from traversing epithelial barriers. These include cationic antimicrobial peptides (CAMPs) such as defensins and the cathelicidin LL-37, bacteriolytic enzymes such as lysozyme, antimicrobial fatty acids, toxic oxygen- or nitrogen-containing molecules, the bacteriolytic complement components and further mechanisms with indirect impacts on bacterial multiplication. Staphylococcus aureus is an important human commensal and pathogen. In order to successfully establish an infection, S. aureus has evolved several mechanisms to resist the innate immune system. In this review, we focus on the mechanisms employed by S. aureus to achieve protection against antimicrobial host defense molecules with special emphasis on CAMPs. Lessons from recent studies on antimicrobial host defense molecules and cognate bacterial resistance adaptation should help in the development of more sustainable anti-infective compounds.
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PMID:Staphylococcus aureus evasion of innate antimicrobial defense. 1865 15

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