Novel alternatives to antibiotics: bacteriophages, bacterial cell wall hydrolases, and antimicrobial peptides

Extensive research has been conducted on the development of three groups of naturally occurring antimicrobials as novel alternatives to antibiotics: bacteriophages (phages), bacterial cell wall hydrolases (BCWH), and antimicrobial peptides (AMP). Phage therapies are highly efficient, highly specific, and relatively cost-effective. However, precautions have to be taken in the selection of phage candidates for therapeutic applications as some phages may encode toxins and others may, when integrated into host bacterial genome and converted to prophages in a lysogenic cycle, lead to bacterial immunity and altered virulence. BCWH are divided into three groups: lysozymes, autolysins, and virolysins. Among them, virolysins are the most promising candidates as they are highly specific and have the capability to rapidly lyse antibiotic-resistant bacteria on a generally species-specific basis. Finally, AMP are a family of natural proteins produced by eukaryotic and prokaryotic organisms or encoded by phages. AMP are of vast diversity in term of size, structure, mode of action, and specificity and have a high potential for clinical therapeutic applications.     

Quantifying enzymatic lysis: estimating the combined effects of chemistry, physiology and physics

The number of microbial pathogens resistant to antibiotics continues to increase even as the rate of discovery and approval of new antibiotic therapeutics steadily decreases. Many researchers have begun to investigate the therapeutic potential of naturally occurring lytic enzymes as an alternative to traditional antibiotics. However, direct characterization of lytic enzymes using techniques based on synthetic substrates is often difficult because lytic enzymes bind to the complex superstructure of intact cell walls. Here we present a new standard for the analysis of lytic enzymes based on turbidity assays which allow us to probe the dynamics of lysis without preparing a synthetic substrate. The challenge in the analysis of these assays is to infer the microscopic details of lysis from macroscopic turbidity data. We propose a model of enzymatic lysis that integrates the chemistry responsible for bond cleavage with the physical mechanisms leading to cell wall failure. We then present a solution to an inverse problem in which we estimate reaction rate constants and the heterogeneous susceptibility to lysis among target cells. We validate our model given simulated and experimental turbidity assays. The ability to estimate reaction rate constants for lytic enzymes will facilitate their biochemical characterization and development as antimicrobial therapeutics.     

Enzymatic lysis of microbial cells

Cell wall lytic enzymes are valuable tools for the biotechnologist, with many applications in medicine, the food industry, and agriculture, and for recovering of intracellular products from yeast or bacteria. The diversity of potential applications has conducted to the development of lytic enzyme systems with specific characteristics, suitable for satisfying the requirements of each particular application. Since the first time the lytic enzyme of excellence, lysozyme, was discovered, many investigations have contributed to the understanding of the action mechanisms and other basic aspects of these interesting enzymes. Today, recombinant production and protein engineering have improved and expanded the area of potential applications. In this review, some of the recent advances in specific enzyme systems for bacteria and yeast cells rupture and other applications are examined. Emphasis is focused in biotechnological aspects of these enzymes.     

Biotechnological potential of pectinolytic complexes of fungi

Plant cell wall-degrading enzymes, such as cellulases, hemicellulases and pectinases, have been extensively studied because of their well documented biotechnological potential, mainly in the food industry. In particular, lytic enzymes from filamentous fungi have been the subject of a vast number of studies due both to their advantages as models for enzyme production and their characteristics. The demand for such enzymes is rapidly increasing, as are the efforts to improve their production and to implement their use in several industrial processes, with the goal of making them more efficient and environment-friendly. The present review focuses mainly on pectinolytic enzymes of filamentous fungi, which are responsible for degradation of pectin, one of the major components of the plant cell wall. Also discussed are the past and current strategies for the production of cell wall-degrading enzymes and their present applications in a number of biotechnological areas.     

Lysostaphin: an antistaphylococcal agent

Lysostaphin is a zinc metalloenzyme which has a specific lytic action against Staphylococcus aureus. Lysostaphin has activities of three enzymes namely, glycylglycine endopeptidase, endo-beta-N-acetyl glucosamidase and N-acteyl muramyl-L: -alanine amidase. Glycylglycine endopeptidase specifically cleaves the glycine-glycine bonds, unique to the interpeptide cross-bridge of the S. aureus cell wall. Due to its unique specificity, lysostaphin could have high potential in the treatment of antibiotic-resistant staphylococcal infections. This review article presents a current understanding of the lysostaphin and its applications in therapeutic agent as a treatment against antibiotic-resistant S. aureus and methicillin-resistant S. aureus (MRSA) infections, either alone or in combination with other antibiotics.     

On the catalytic mechanism of bacteriophage endolysins: Opportunities for engineering

Bacteriophage endolysins have the potential to be a long-term antibacterial replacement for antibiotics. The exogenous application of endolysins on some bacteria results in rapid cell lysis. The prospects for endolysins are furthered by the ability to engineer them; novel endolysins can be developed with optimised stability, specificity, and lytic function. But the success of endolysin engineering and application requires a comprehensive understanding of the relationship between the enzymes biochemical, biophysical and bacteriolytic properties. Here, we examine their catalytic mechanisms, opportunities for developing novel endolysins, and highlight areas where a better understanding would support their long-term success as antibacterial agents.     

肝素酶研究进展

微生物肝素酶是一类作用于肝素和类肝素的多糖裂解酶,在低分子肝素的制备以及肝素类分子的结构解析等领域具有十分重要的应用前景。本文将结合微生物基因组测序的最新进展,综述微生物肝素酶的来源,并对肝素酶的作用机理加以讨论;结合本实验室研究对肝素酶的重组表达及其在低分子肝素生产的应用最新进展作以综述,并对肝素酶其它潜在的应用作以讨论。     

Bacteriocin nanoconjugates: boon to medical and food industry

Resistance to antibiotics is an ongoing problem in the biomedical industry. Developing active, alternative drug therapies would reduce our reliance on antibiotics that induce resistance in micro-organisms. To date, bacteriocins and antimicrobial peptides have shown a positive outcome as antibiotic substitutes and synergists apart from phage therapy, antibodies and probiotics. Bacteriocins are proteinaceous antimicrobial peptides synthesized by lactic acid bacteria extensively used as bio-preservatives and alternative to traditional antibiotics to overcome the problem of drug-resistant pathogens. Nonetheless, the use of bacteriocins has several limitations such as limited antimicrobial spectrum, requiring high dose, sensitivity to proteolytic enzymes, etc. Nanoparticles are one of the promising area of research explored to improve antimicrobial spectrum of bacteriocins. This review therefore highlights the recent developments and research pertaining to use of nanoparticles and bacteriocin conjugates to tackle the resistance crisis as well as its applications in food industry.     

Lytic transglycosylases: concinnity in concision of the bacterial cell wall

The lytic transglycosylases (LTs) are bacterial enzymes that catalyze the non-hydrolytic cleavage of the peptidoglycan structures of the bacterial cell wall. They are not catalysts of glycan synthesis as might be surmised from their name. Notwithstanding the seemingly mundane reaction catalyzed by the LTs, their lytic reactions serve bacteria for a series of astonishingly diverse purposes. These purposes include cell-wall synthesis, remodeling, and degradation; for the detection of cell-wall-acting antibiotics; for the expression of the mechanism of cell-wall-acting antibiotics; for the insertion of secretion systems and flagellar assemblies into the cell wall; as a virulence mechanism during infection by certain Gram-negative bacteria; and in the sporulation and germination of Gram-positive spores. Significant advances in the mechanistic understanding of each of these processes have coincided with the successive discovery of new LTs structures. In this review, we provide a systematic perspective on what is known on the structure–function correlations for the LTs, while simultaneously identifying numerous opportunities for the future study of these enigmatic enzymes.     

Peptide antibiotic production through immobilized biocatalyst technology

The use of immobilized biocatalysts for producing known or new antibiotics is presented. An evaluation of the applicability of this concept in the fascinating field of peptide antibiotic bioconversions and fermentations is also given.The use of immobilized enzymes, organelles and cells to synthesize antibiotics as an alternative method to conventional fermentation is discussed. In vitro total enzymatic antibiotic synthesis is illustrated with the ‘multienzyme thiotemplate mechanism’ of Bacillus brevis, the producer of gramicidin S. Total synthesis of peptide antibiotics, based on immobilized living cells, has recently been demonstrated with penicillin, bacitracin, nisin and a few other antibiotics.As an industrial example of the use of enzymes or cells to convert peptide antibiotics into therapeutically useful derivatives, free and immobilized penicillin acylases, producing the penicillin nucleus 6-aminopenicillanic acid (6-APA), are reviewed as well as their potential to synthesize semisynthetic β-lactams (penicillins, cephalosporins).Acylases, acetylesterases and α-amino acid ester hydrolases acting on cephalosporin-compounds and yielding valuable intermediary or end products have also gained wide interest. Stereospecific enzymic side-chain preparations for semisynthetic penicillin and cephalosporin production have recently reached the industrial stage. Bioconversion possibilities with the novel β-lactam compounds are suggested.These examples of simple single-step, as well as complex multi-step, enzyme reactions point to the vast potential of immobilized biocatalyst technology in fermentation science, in organic synthesis and in biotechnological processes in general.     

Potentialization of antibiotics by lytic enzymes]

Few lytic enzymes, specially papaine and lysozyme, acting on the membrane and cell wall structures facilitate effects of bacitracine, streptomycine and other antibiotics. Streptomycino resistant strains became sensibles to this antibiotic after contact with papaine and lysozyme. The results of tests in physiological suspensions concern only the lytic activity of enzymes. The results on nutrient medium concern together lytic, and antibiotic activities.     

Bacterial proteinases as targets for the development of second-generation antibiotics

The emergence of bacterial pathogen resistance to common antibiotics strongly supports the necessity to develop alternative mechanisms for combating drug-resistant forms of these infective organisms. Currently, few pharmaceutical companies have attempted to investigate the possibility of interrupting metabolic pathways other than those that are known to be involved in cell wall biosynthesis. In this review, we describe multiple, novel roles for bacterial proteinases during infection using, as a specific example, the enzymes from the organism Porphyromonas gingivalis, a periodontopathogen, which is known to be involved in the development and progression of periodontal disease. In this manner, we are able to justify the concept of developing synthetic inhibitors against members of this class of enzymes as potential second-generation antibiotics. Such compounds could not only prove valuable in retarding the growth and proliferation of bacterial pathogens but also lead to the use of this class of inhibitors against invasion by other infective organisms.     

Lytic transglycosylases: bacterial space-making autolysins

Lytic transglycosylases are an important class of bacterial enzymes that act on peptidoglycan with the same substrate specificity as lysozyme. Unlike the latter enzymes, however, the lytic transglycosylases are not hydrolases but instead cleave the glycosidic linkage between N-actetylmuramoyl and N-acetylglucosaminyl residues with the concomitant formation of a 1,6-anydromuramoyl product. They are ubiquitous in bacteria which produce a compliment of different forms that are responsible for creating space within the peptidoglycan sacculus for its biosynthesis and recycling, cell division, and the insertion of cell-envelope spanning structures, such as flagella and secretion systems. As well, the lytic transglyosylases may have a role in pathogenesis of some bacterial species. Given their important role in bacterial cell wall metabolism, the lytic transglycosylases may present an attractive new target for the development of broad-spectrum antibiotics.     

Purification and properties of bacteriolytic enzymes from Bacillus licheniformis YS-1005 against Streptococcus mutans

To find a novel lytic enzyme against cariogenic Streptococci, strains showing strong lytic activity have been screened from soil using Streptococcus mutans. A strain identified as Bacillus licheniformis secreted two kinds of lytic enzymes, which were purified by methanol precipitation, CM-cellulose chromatography, gel filtration, and hydroxyapatite chromatography. The molecular weights of these two enzymes, L27 and L45, were 27,000 and 45,000, respectively. Optimum pH and temperature of both enzymes for lytic activity were pH 8 and 37 degrees C. L27 and L45 digest the peptide linkage between L-Ala and D-Glu in peptidoglycan of Streptococcus mutans. The lytic activity was highly specific for Streptococcus mutans, suggesting their potential use as a dental care product.     

Efficacy of a Broad Host Range Lytic Bacteriophage Against <Emphasis Type="Italic">E. coli</Emphasis> Adhered to Urothelium

Persistent urinary tract infections (UTI) are often caused by E. coli adhered to urothelium. This type of cells is generally recognized as very tolerant to antibiotics which renders difficult the treatment of chronic UTI. This study investigates the use of lytic bacteriophages as alternative antimicrobial agents, particularly the interaction of phages with E. coli adhered to urothelium and specifically determines their efficiency against this type of cells. The bacterial adhesion to urothelium was performed varying the bacterial cell concentrations and the period and conditions (static, shaken) of adhesion. Three collection bacteriophages (T1, T4, and phiX174 like phages) were tested against clinical E. coli isolates and only one was selected for further infection experiments. Based on the lytic spectrum against clinical isolates and its ability to infect the highest number of antibiotic resistant strains, the T1-like bacteriophage was selected. This bacteriophage caused nearly a 45% reduction of the bacterial population after 2 h of treatment. This study provides evidence that bacteriophages are effective in controlling suspended and adhered cells and therefore can be a viable alternative to antibiotics to control urothelium- adhered bacteria.     

Interactions between bacterial membranes and peptidolipids: lysis of micrococcus luteus protoplasts by derivatives of peptidolipidic antibiotics from bacillus subtilis.

The lysis of protoplasts of Micrococcus luteus has been tested with various derivatives of three peptidolipidic antibiotics: iturin A, mycosubtilin and bacillomycin L. The lytic activity is dependent to the nature of the substituting group and to the position of the substituted aminoacid residue. The acetylation of OH groups leads to a decrease of the lytic activity of the natural antibiotics. The methylation of aspartyl residues of bacillomycin L gives a strong lytic activity while natural bacillomycin L has no lytic activity. The methylation of the tyrosyl residue enhances the lytic activities of iturin A and of bacillomycin L-dimethyl ester and reduces that of mycosubtilin. Correlations between the structures of derivatives and their lytic action on M. luteus protoplasts are discussed.     

Laccase immobilization and insolubilization: from fundamentals to applications for the elimination of emerging contaminants in wastewater treatment

Over the last few decades many attempts have been made to use biocatalysts for the biotransformation of emerging contaminants in environmental matrices. Laccase, a multicopper oxidoreductase enzyme, has shown great potential in oxidizing a large number of phenolic and non-phenolic emerging contaminants. However, laccases and more broadly enzymes in their free form are biocatalysts whose applications in solution have many drawbacks rendering them currently unsuitable for large scale use. To circumvent these limitations, the enzyme can be immobilized onto carriers or entrapped within capsules; these two immobilization techniques have the disadvantage of generating a large mass of non-catalytic product. Insolubilization of the free enzymes as cross-linked enzymes (CLEAs) is found to yield a greater volume ratio of biocatalyst while improving the characteristics of the biocatalyst. Ultimately, novel techniques of enzymes insolubilization and stabilization are feasible with the combination of cross-linked enzyme aggregates (combi-CLEAs) and enzyme polymer engineered structures (EPESs) for the elimination of emerging micropollutants in wastewater. In this review, fundamental features of laccases are provided in order to elucidate their catalytic mechanism, followed by different chemical aspects of the immobilization and insolubilization techniques applicable to laccases. Finally, kinetic and reactor design effects for enzymes in relation with the potential applications of laccases as combi-CLEAs and EPESs for the biotransformation of micropollutants in wastewater treatment are discussed.     

Development of a novel method of lytic phage delivery by use of a bacteriophage P22 site-specific recombination system

Bacteriophage therapy represents a potential alternative to the use of antibiotics to control proliferation of pathogenic bacteria. As an alternative to the strategy where a limited number of doses of large numbers of lytic bacteriophages are administered, a novel method delivery system was developed so that phages are continually released into the culture. Specifically, a non-pathogenic Escherichia coli strain was constructed that was lysogenic for a lytic mutant of bacteriophage lambda. This lysogen was shown to be effective at decreasing the number of lambda-sensitive E. coli in vitro. Construction of this E. coli strain was accomplished by development of a plasmid-based system utilizing the site-specific recombination machinery of bacteriophage P22 to integrate DNA constructs into the host chromosome. This recombination system is useful for strain construction and other genetic manipulations in both E. coli and Salmonella enterica serovars.     

噬菌体裂解酶——现状与未来

噬菌体裂解酶是一种由DNA噬菌体基因编码的高特异性酶, 可高效消化细菌细胞壁。革兰氏阳性菌噬菌体裂解酶的结构域相似, 裂解效率高, 与抗生素具协同抗菌作用, 且不易产生耐受性菌株, 抗体等体液因子对裂解酶的裂解活性影响小, 裂解酶作为一种潜在抗感染药物具有重要的研究价值。目前已建立了多种病原菌裂解酶应用的动物模型, 在防控耐药性病原菌感染上取得重要进展。本文就噬菌体裂解酶的抗菌作用进行综述。