Authors: Ibrahim, H.R.; Aoki, T.; Pellegrini, A.

Source: Current Pharmaceutical Design, Volume 8, Number 9, 1 April 2002 , pp. 671-693(23)

Publisher: Bentham Science Publishers

Abstract:

The increasing development of bacterial resistance to traditional antibiotics has reached alarming levels, thus necessitating the strong need to develop new antimicrobial agents. These new antimicrobials should possess both novel modes of action as well as different cellular targets compared with the existing antibiotics. Lysozyme, muramidase, and aprotinin, a protease inhibitor, both exhibit antimicrobial activities against different microorganisms, were chosen as model proteins to develop more potent bactericidal agents with broader antimicrobial specificity. The antibacterial specificity of lysozyme is basically directed against certain Gram-positive bacteria and to a lesser extent against Gram-negative ones, thus its potential use as antimicrobial agent in food and drug systems is hampered. Several strategies were attempted to convert lysozyme to be active in killing Gram-negative bacteria which would be an important contribution for modern biotechnology and medicine. Three strategies were adopted in which membrane-binding hydrophobic domains were introduced to the catalytic function of lysozyme, to enable it to damage the bacterial membrane functions. These successful strategies were based on either equipping the enzyme with a hydrophobic carrier to enable it to penetrate and disrupt the bacterial membrane, or coupling lysozyme with a safe phenolic aldehyde having lethal activity toward bacterial membrane. In a different approach, proteolytically tailored lysozyme and aprotinin have been designed on the basis of modifying the derived peptides to confer the most favorable bactericidal potency and cellular specificity. The results obtained from these strategies show that proteins can be tailored and modelled to achieve particular functions. These approaches introduced, for the first time, a new conceptual utilization of lysozyme and aprotinin, and thus heralded a great opportunity for potential use in drug systems as new antimicrobial agent.

Keywords: Antimicrobial Proteins; Peptides; Lysozyme; Aprotinin; muramidase; gram-positive; gram-negative; gram-negative-bacteria; lysozme; anti gram-negative lysozyme/kwd>; fatty-acylation

Document Type: Review article

DOI: http://dx.doi.org/10.2174/1381612023395349

Publication date: 2002-04-01

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• Current Pharmaceutical Design publishes timely in-depth reviews covering all aspects of current research in rational drug design. Each issue is devoted to a single major therapeutic area. A Guest Editor who is an acknowledged authority in a therapeutic field has solicits for each issue comprehensive and timely reviews from leading researchers in the pharmaceutical industry and academia.
  
  Each thematic issue of Current Pharmaceutical Design covers all subject areas of major importance to modern drug design, including: medicinal chemistry, pharmacology, drug targets and disease mechanism.

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