Abstract
There is growing concern about the emergence of bacterial strains showing resistance to all classes of antibiotics commonly used in human medicine. Despite the broad range of available antibiotics, bacterial resistance has been identified for every antimicrobial drug developed to date. Alarmingly, there is also an increasing prevalence of multidrug-resistant bacterial strains, rendering some patients effectively untreatable. Therefore, there is an urgent need to develop alternatives to conventional antibiotics for use in the treatment of both humans and food-producing animals. Bacteriophage-encoded lytic enzymes (endolysins), which degrade the cell wall of the bacterial host to release progeny virions, are potential alternatives to antibiotics. Preliminary studies show that endolysins can disrupt the cell wall when applied exogenously, though this has so far proven more effective in Gram-positive bacteria compared with Gram-negative bacteria. Their potential for development is furthered by the prospect of bioengineering, and aided by the modular domain structure of many endolysins, which separates the binding and catalytic activities into distinct subunits. These subunits can be rearranged to create novel, chimeric enzymes with optimized functionality. Furthermore, there is evidence that the development of resistance to these enzymes may be more difficult compared with conventional antibiotics due to their targeting of highly conserved bonds.
Highlights
In 2014, the World Health Organization (WHO) calculated the global prevalence of seven antibiotic-resistant bacteria of international concern, and noted very high rates of resistance in all WHO regions [1]
We discuss the potential of cell wall lysis proteins derived from bacteriophages for use as a new class of antimicrobial agents, and evaluate whether they could replace, or supplement, Antibiotics 2018, 7, 17; doi:10.3390/antibiotics7010017
The skin lesions were treated with a hydrogel containing a chimeric endolysin composed of the cell wall-targeting domain (SH3b) of lysostaphin and the phage K ORF56 muralytic domain [104]
Summary
In 2014, the World Health Organization (WHO) calculated the global prevalence of seven antibiotic-resistant bacteria of international concern, and noted very high rates of resistance The outer membrane of Gram-negative bacteria presents a physical a physical protective barrier against the activity of endolysins [6]. Gram-negative bacteria contain an outer membrane (OM) structure not present in Gram-positive. The C-terminal cell wall-binding domain is often lytic activity [11,12,13]. C-terminal cell wall-binding domain required to maintain full lytic activity [11,12,13].or. Globular endolysins only contain cell wall-binding domain can result in equal or increased lytic activity [14,15,16]. EAD: enzymatically-active domain; CBD: cell wall-binding domain; OMP: outer-membrane permeabilizer; AMP: antimicrobial peptide. Both bioengineered and phage-isolated endolysins are promising alternatives to antibiotics. We provide an overview of native and chimeric endolysins with potential therapeutic applications
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