Bacteriophage lytic enzymes: novel anti-infectives

Bacteriophage lytic enzymes, or lysins, are highly evolved molecules produced by bacterial viruses (bacteriophage) to digest the bacterial cell wall for bacteriophage progeny release. Small quantities of purified recombinant lysin added to gram-positive bacteria causes immediate lysis resulting in log-fold death of the target bacterium. Lysins have now been used successfully in animal models to control pathogenic antibiotic resistant bacteria found on mucosal surfaces and in blood. The advantages over antibiotics are their specificity for the pathogen without disturbing the normal flora, the low chance of bacterial resistance to lysins and their ability to kill colonizing pathogens on mucosal surfaces, capabilities that were previously unavailable. Thus, lysins could be an effective anti-infective in an age of mounting antibiotic resistance.     

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。     

Recombinant bacteriophage lysins as antibacterials

With the increasing worldwide prevalence of antibiotic resistant bacteria, bacteriophage endolysins (lysins) represent a very promising novel alternative class of antibacterial in the fight against infectious disease. Lysins are phage-encoded peptidoglycan hydrolases which, when applied exogenously (as purified recombinant proteins) to Gram-positive bacteria, bring about rapid lysis and death of the bacterial cell. A number of studies have recently demonstrated the strong potential of these enzymes in human and veterinary medicine to control and treat pathogens on mucosal surfaces and in systemic infections. They also have potential in diagnostics and detection, bio-defence, elimination of food pathogens and control of phytopathogens. This review discusses the extensive research on recombinant bacteriophage lysins in the context of antibacterials, and looks forward to future development and potential.     

裂解酶治疗的研究进展与应用前景

多耐药病原细菌的不断出现和传播给公共医疗造成了严峻的威胁和挑战,开发新的抗菌分子迫在眉睫。噬菌体裂解酶来源于噬菌体,具有独特的进化和选择优势,不仅能高效快速的杀灭多耐药细菌,而且不易诱导细菌产生新的耐药性。本文对噬菌体裂解酶的结构和功能进行了简要的介绍,重点综述了裂解酶在抗细菌感染中近年的研究进展和应用前景。     

噬菌体溶壁酶研究进展

溶壁酶是噬菌体在感染末期表达的蛋白质,可水解细菌的细胞壁,使子代噬菌体释放出来。研究表明,溶壁酶在体外能高效地杀死细菌,同样对感染细菌的模型动物有很好的治疗作用。因此,溶壁酶是一种新型的抗菌物质,具有广阔的应用前景。溶壁酶通过水解细菌细胞壁肽聚糖上糖与肽间的酰胺键或肽内氨基酸残基间的连键,从而使细菌裂解。溶壁酶分子由结合功能域和催化功能域两部分组成,其晶体结构使之具有对细胞壁肽聚糖水解的高效性和特异性。对噬菌体溶壁酶的体内外抗菌作用、抗菌机理、晶体结构等最新研究成果及其应用前景进行了综述。     

Bacteriophage and their lysins for elimination of infectious bacteria

When phages were originally identified, the possibility of using them as antibacterial agents against pathogens was immediately recognized and put into practise based on the knowledge available at the time. However, with the advent of antibiotics a decline in the use of phage as therapeutics followed. Phages did, however, become more useful in the study of fundamental aspects of molecular biology and in the diagnostic laboratory for the identification of pathogenic bacteria. More recently, the original application of phage as therapeutics to treat human and animal infections has been rekindled, particularly in an era where antibiotic resistance has become so problematic/commonplace. Phage lysins have also been studied and utilized in their own right as potential therapeutics for the treatment of bacterial infections. Indeed the past decade has seen a considerable amount of research worldwide focused on the engineering of phages as antibacterial agents in a wide range of applications. Furthermore, the US Food and Drug Administration and/or the US Department of Agriculture have recently approved commercial phage preparations to prevent bacterial contamination of livestock, food crops, meat and other foods. Such developments have prompted this review into the status of phage research as it pertains to the control of infectious bacteria.     

Bacteriophage selection against a plasmid-encoded sex apparatus leads to the loss of antibiotic-resistance plasmids

Antibiotic-resistance genes are often carried by conjugative plasmids, which spread within and between bacterial species. It has long been recognized that some viruses of bacteria (bacteriophage; phage) have evolved to infect and kill plasmid-harbouring cells. This raises a question: can phages cause the loss of plasmid-associated antibiotic resistance by selecting for plasmid-free bacteria, or can bacteria or plasmids evolve resistance to phages in other ways? Here, we show that multiple antibiotic-resistance genes containing plasmids are stably maintained in both Escherichia coli and Salmonella enterica in the absence of phages, while plasmid-dependent phage PRD1 causes a dramatic reduction in the frequency of antibiotic-resistant bacteria. The loss of antibiotic resistance in cells initially harbouring RP4 plasmid was shown to result from evolution of phage resistance where bacterial cells expelled their plasmid (and hence the suitable receptor for phages). Phages also selected for a low frequency of plasmid-containing, phage-resistant bacteria, presumably as a result of modification of the plasmid-encoded receptor. However, these double-resistant mutants had a growth cost compared with phage-resistant but antibiotic-susceptible mutants and were unable to conjugate. These results suggest that bacteriophages could play a significant role in restricting the spread of plasmid-encoded antibiotic resistance.     

Bacteriophage endolysins as a novel class of antibacterial agents

Endolysins are double-stranded DNA bacteriophage-encoded peptidoglycan hydrolases produced in phage-infected bacterial cells toward the end of the lytic cycle. They reach the peptidoglycan through membrane lesions formed by holins and cleave it, thus, inducing lysis of the bacterial cell and enabling progeny virions to be released. Endolysins are also capable of degrading peptidoglycan when applied externally (as purified recombinant proteins) to the bacterial cell wall, which also results in a rapid lysis of the bacterial cell. The unique ability of endolysins to rapidly cleave peptidoglycan in a generally species-specific manner renders them promising potential antibacterial agents. Originally developed with a view to killing bacteria colonizing mucous membranes (with the first report published in 2001), endolysins also hold promise for the treatment of systemic infections. As potential antibacterials, endolysins possess several important features, for instance, a novel mode of action, a narrow antibacterial spectrum, activity against bacteria regardless of their antibiotic sensitivity, and a low probability of developing resistance. However, there is only one report directly comparing the activity of an endolysin with that of an antibiotic, and no general conclusions can be drawn regarding whether lysins are more effective than traditional antibiotics. The results of the first preclinical studies indicate that the most apparent potential problems associated with endolysin therapy (e.g., their immunogenicity, the release of proinflammatory components during bacteriolysis, or the development of resistance), in fact, may not seriously hinder their use. However, all data regarding the safety and therapeutic effectiveness of endolysins obtained from preclinical studies must be ultimately verified by clinical trials. This review discusses the prophylactic and therapeutic applications of endolysins, especially with respect to their potential use in human medicine. Additionally, we outline current knowledge regarding the structure and natural function of the enzymes in phage biology, including the most recent findings.     

细菌生物膜与耐药性相关性研究进展

细菌生物膜是一种包裹于细胞外多聚物基质中不可逆的黏附于非生物或生物表面的微生物细胞菌落.生物膜状态下的细菌相对其浮游状态具有显著增强的耐药性,对人及动物细菌性感染具有重要研究价值.然而尽管动物细菌耐药性被广泛报道,却很少涉及细菌生物膜与其之间的相关性,本文综述了细菌生物膜的耐药机制并探讨了细菌生物膜与动物源性细菌耐药性的关系,可作为研究细菌耐药性及控制动物产品安全的参考.     

The return of the phage

Phages have been used to treat infectious diseases since their discovery nearly a century ago. Modern sequencing and genetic engineering technologies now enable researchers to vastly expand the use of phages as general drug delivery vehicles....it is only in the past five years that the regulatory guidelines for the approval of phage products—both in therapy and food safety—have been createdOver the past decade, bacteriophages have occasionally stirred public and media interest because of their potential as biological weapons against bacterial infections. Such reports have tended to come from Russian or Georgian laboratories, whereas Western research institutes and companies have usually found that phages do not live up to their promise. More than a decade later, however, the view of bacteriophages is set to change. Spurred on by advances in sequencing and other molecular techniques, research into phages has yielded its first applications. Not only are phages proving effective as therapeutic agents, but they are also playing a role in food safety and as delivery vehicles for drugs against a wide range of diseases.Interest in phages as therapeutic agents emerged almost immediately after their discovery nearly a century ago (Twort, 1915; d''Hérelle, 1917). This interest evaporated quickly in the West after the discovery of penicillin, but phage research was kept alive in the old Soviet Union and continued after its collapse in the 1990s. Ongoing studies there, although not always conforming to the most rigorous standards, provided the only evidence of the therapeutic potential of phages.Eventually, especially in the light of the increasing threat from drug-resistant bacteria, Western researchers turned to exploring phages again. However, it is only in the past five years that the regulatory guidelines for the approval of phage products—in both therapy and food safety—have been created. Previously, the US Food and Drug Administration (FDA) had lacked the appropriate regulatory measures; it took them four years to approve the first phage product for use in food safety in 2006. ListShield^TM is a cocktail of several phages that target Listeria monocytogenes, contaminants in meat and poultry products. Approvals for other food safety products have followed with greater speed (Sulakvelidze, 2011). Moreover, in 2008, the FDA approved the first phase 1 clinical trial of phages. This again involved a cocktail of eight phages to target various bacteria including Staphylococcus aureus, Pseudomonas aeruginosa and Escherichia coli, in venous leg ulcers. This trial eventually established the safety of the phage preparation and cleared the way for more phage therapy trials (www.clinicaltrials.gov).The recent acceptance in the West of phages as anti-pathogenic agents was preceded by their use for diagnostic purposes to identify bacteria...The recent acceptance in the West of phages as anti-pathogenic agents was preceded by their use for diagnostic purposes to identify bacteria, according to Martin Loessner from the Institute of Food, Nutrition and Health in Zürich, Switzerland. “It then became possible to [...] harness the specificity of phage for applications such as recognition of the host cell, and also for reporter phage, which is a genetically modified phage with a gene so [you] can easily see the phage''s impact on the target cell,” he explained. “Later on we figured why not go and revisit the idea of using phages against pathogens.”This approach turned out to be highly successful against key food pathogens, Loessner said, because of the way phages work: “[T]he phage has been very finely tuned through zillions of generations in the evolutionary arms race, and is highly specific.” This specificity is important for targeting the few bacteria that cause food poisoning while sparing the bacteria in fermented food—such as soft cheeses—that are harmless and contribute flavour. “The phage is also immune to development of resistance by the host bacteria, because if not it would have become extinct a long time ago,” Loessner said.It is bacterial toxins that cause food poisoning rather than bacteria themselves, so phages are used as a preventive measure to stop the growth of bacteria such as Listeria in the first place. As such, it is important to bombard food products with a large number of phages to ensure that virtually all target bacteria are eradicated. “I always have this magic number of 10⁸, or 100 million per gram of food,” Loessner said. “In 1 g of food there are often only 500 target bacteria, so there is not enough to amplify the phage and you need really high numbers to kill the bacteria in one round of infection.” He added that, in his view, phages would soon become the main treatment for preventing bacterial contamination. “Phage in the near future will be the number one [treatment against] Listeria and Salmonella. It''s becoming number one already, especially in the US.”In Europe, the use of phages in food safety therapy is being held back by the requirement that foods treated with them are labelled as containing viruses, which means they are likely to meet consumer resistance, as happened with foods containing or made from genetically modified organisms. Loessner commented that education is required to raise awareness that the properly controlled use of phages involves minimal risk and could greatly enhance food safety. However, he also emphasized that the use of phages should represent an extra level of protection, not replace existing quality control measures....because phage lysins are often specific to a single bacterial genus, they would allow the specific targeting of pathogenic bacteriaThe ability of phages to target specific bacteria while leaving others alone also has great potential for treating bacterial infections, particularly in the light of increasing antibiotic resistance. Such treatments would not necessarily involve the phage themselves, but rather the use of their lysins—the enzymes that weaken the bacterial cell wall to allow newly formed viruses to exit the host cell. Lysins can be administered as antibiotics, at least for gram-positive bacteria that lack a separate outer membrane around the cell wall. Moreover, because phage lysins are often specific to a single bacterial genus, they would allow the specific targeting of pathogenic bacteria. “The fact that phage lysins leave the commensal microflora undisturbed is particularly significant,” commented Olivia McAuliffe, Senior Research Officer at the Teagasc Food Research Centre in Cork, Ireland. “Most of the antibiotics used clinically have broad-activity spectra and treatment with these antibiotics can have devastating effects on the normal flora, in particular for those taking long-term antibiotic courses.”Phages also have another great advantage over most conventional antibiotics in being potent against both dividing and non-dividing cells. “Because most antibiotics target pathways such as protein synthesis, DNA replication, and cell wall biosynthesis, they can only act when the cells are actively growing,” McAuliffe added. “Because lysins are enzymes, they will chew away the peptidoglycan in both viable and non-viable cells, dividing and non-dividing cells. This would be particularly important in the case of slow-growing organisms that cause infection, an example being Mycobacterium species.”This specificity of phages and their lysins is particularly important for treating chronic conditions resulting from persistent bacterial infection, particularly in the respiratory system or digestive tract. Broad-spectrum antibiotics also attack harmless and beneficial commensal bacteria, and can even worsen the condition by encouraging the growth of resistant bacteria. This is the case with Clostridium difficile, a cause of secondary infections and a major nosocomial (hospital-acquired) antibiotic-resistant pathogen, according to McAuliffe. It is a Gram-positive, rod-shaped, spore-forming bacterium that is the most serious and common cause of diarrhoea and other intestinal disease when competing bacteria in the gut flora have been wiped out by antibiotics. The bacterium and its spores, which form in aerobic conditions outside the body, are widespread in the environment and are present in the guts of 3% of healthy individuals and 66% of infants, according to the UK''s Health Protection Agency. Clostridium spreads readily on the hands of healthcare staff and visitors in hospitals. The ability of the bacteria to form spores resistant to heat, drying and disinfectants, which then adhere to surfaces, enables them to persist in the hospital environment.Because Clostridium is resistant to most conventional antibiotics, it has for some years usually been treated with metronidazole, which exploits the fact that Clostridium is anaerobic during infection. Metronidazole has proven particularly appealing as it has relatively little impact on human cells or commensal aerobic bacteria in the gut as it does not work in the presence of oxygen. But metronidazole does not always work, and physicians have therefore been using vancomycin, a stronger but more toxic antibiotic, as a last resort. Moreover, even in cases where antibiotics seem to eliminate Clostridium and cure the associated diarrhoea, infection recurs in as many as 20% of hospital patients (Kelly & LaMont, 2008). About one-fifth of these 20%, or 4% of the total number of patients succumbing to Clostridium, end up with a long-term infection that at present is difficult to eradicate.This is where phages step in, because they are well tolerated by patients and their specificity means that they will not target other gut bacteria. Clostridium phages have already been demonstrated to work selectively and there is the possibility of extracting lysins against Clostridium from the phage itself; an avenue being pursued by Aidan Coffey''s group at the Department of Biological Sciences at the Cork Institute of Technology in Bishoptown, Ireland.There is also growing interest in using phages to tackle various other infections that are resistant to existing drugs—for example, in wounds that fail to heal, which are a major risk for diabetics. The application of phages in such cases is not new—before penicillin it was often the only option—but the difference now is that modern molecular techniques for isolating bacterial strains from biopsies and matching them to phages greatly increases efficiency. One clinical trial, organized by the Institute of Immunology and Experimental Therapy of the Polish Academy of Sciences, is currently recruiting patients to evaluate the use of phage preparations against a range of drug-resistant bacteria, including MRSA (methicillin-resistant Staphylococcus aureus), Enterococcus, Escherichia, Citrobacter, Enterobacter, Klebsiella, Shigella and Salmonella. The intention is to isolate bacterial strains from each patient and to identify matching phages from the Institute''s bacteriophage collection in Wrocław.Although the potential of phages or their lysins to combat bacterial pathogens, whether in food or those causing infectious diseases, has long been recognized, more recent work has identified new applications as delivery vehicles for vaccines or cytotoxic drugs to treat cancer. These applications do not exploit the phage''s natural targeting of bacteria, but make use of their ability to carry surface ligands that attract them to specific host cells.Even though phages do not attack human cells, they elicit an immune response and can be used as vectors to carry an engineered antigen on their surface to vaccinate against viral or bacterial disease. This approach has been tested in rabbits with a DNA vaccine against hepatitis B (Clark et al, 2011). The study compared the phage DNA vaccine with Engerix B—a commercially available vaccine based on a homologous recombinant protein—and found that the phage vaccine produced a significantly higher antibody response more quickly, as well as being potentially cheaper to produce and stable at a wider range of temperatures. This hepatitis B vaccine is now being developed by the UK biotech firm BigDNA in Edinburgh, Scotland, which has been granted a European patent, pending future clinical trials in humans.Modified phages could also serve as nanoparticles to deliver cytotoxic drugs straight to tumour cells, bypassing healthy cellsModified phages could also serve as nanoparticles to deliver cytotoxic drugs straight to tumour cells, bypassing healthy cells. Phages are a promising candidate vehicle because they can be readily engineered both to display appropriate ligands for targeting tumour cells specifically, and to carry a cytotoxic payload that is only released inside the target. One Israeli group has developed a technology for manufacturing phage nanoparticles that in principle can be used to target drugs to either tumour cells or pathogens (Bar et al, 2008). The group chose one particular phage family, known as filamentous phages, because of their small size and the relative ease of engineering them. Filamentous phages comprise just 10 genes with a sheath of several thousand identical α-helical coat proteins in a helical array assembled around a single-stranded circular DNA molecule. The Israeli scientists combine genetic modification and chemical engineering to create a phage that is able to attach to its target cell and release cytotoxic molecules. “Genetic engineering makes it possible to convert the phage to a targeted particle by displaying a target-specifying molecule on the phage coat,” explained Itai Benhar from Tel-Aviv University, the lead author of the paper. “Genetic engineering also makes it possible to design a drug-release mechanism. Finally chemical engineering makes it possible to load the particle with a large payload of cargo.”The group has used the same approach to target two bacteria species, Staphylococcus aureus and Escherichia coli, with the antibiotic chloramphenicol, which was first developed in 1949 but has raised concerns over its toxicity. According to the Israeli group, the phage nanoparticle loaded with the drug was 20,000 times more potent against both bacteria than the drug administered on its own. Just as importantly, the phage particles do not affect other cells. The overall advantage of the phage-based delivery approach is that it can deliver highly effective and toxic drugs in a safe way. The other point is that this and other methods in which phages are engineered to reach specific targets have nothing directly to do with the natural ability of phage viruses to attack bacteria. “The phage''s natural ability to infect bacteria is totally irrelevant to their application for targeting non-bacterial cells,” said Benhar. “In fact, they are not relevant for targeting bacteria either in this case, since the chemical modification we subject the phages to renders them non-infective.”However, the phage nanoparticles retain their immunogenic effect, which is a problem if the objective is merely to deliver a drug to the target while minimizing all other impacts. “Phages are immunogenic, and although we found a way to reduce their immunogenicity we did not totally eliminate it,” Benhar said. The other challenge is that, as the particles carry the payload drug on their surface, the physical and chemical properties change every time a new drug is loaded. Although the payload itself is inert until it reaches the target, the varying characteristics could alter the host response and therefore affect regulatory approval for each new phage construct, as safety would have to be demonstarted in each case.The use of phages is no longer confined to directly attacking infectious bacteria, but has vastly expanded in terms of methods, applications and the diseases that can be tackledNevertheless, this approach holds great promise as a novel way of delivering not just new drugs but also existing ones that are effective but too toxic for healthy cells. This is exactly the most exciting aspect of recent therapeutic phage research. The use of phages is no longer confined to directly attacking infectious bacteria, but has vastly expanded in terms of methods, applications and the diseases that can be tackled.     

Biofilm control with natural and genetically-modified phages

Bacteriophages, as the most dominant and diverse entities in the universe, have the potential to be one of the most promising therapeutic agents. The emergence of multidrug-resistant bacteria and the antibiotic crisis in the last few decades have resulted in a renewed interest in phage therapy. Furthermore, bacteriophages, with the capacity to rapidly infect and overcome bacterial resistance, have demonstrated a sustainable approach against bacterial pathogens-particularly in biofilm. Biofilm, as complex microbial communities located at interphases embedded in a matrix of bacterial extracellular polysaccharide substances (EPS), is involved in health issues such as infections associated with the use of biomaterials and chronic infections by multidrug resistant bacteria, as well as industrial issues such as biofilm formation on stainless steel surfaces in food industry and membrane biofouling in water and wastewater treatment processes. In this paper, the most recent studies on the potential of phage therapy using natural and genetically-modified lytic phages and their associated enzymes in fighting biofilm development in various fields including engineering, industry, and medical applications are reviewed. Phage-mediated prevention approaches as an indirect phage therapy strategy are also explored in this review. In addition, the limitations of these approaches and suggestions to overcome these constraints are discussed to enhance the efficiency of phage therapy process. Finally, future perspectives and directions for further research towards a better understanding of phage therapy to control biofilm are recommended.     

A Window of Opportunity to Control the Bacterial Pathogen Pseudomonas aeruginosa Combining Antibiotics and Phages

The evolution of antibiotic resistance in bacteria is a global concern and the use of bacteriophages alone or in combined therapies is attracting increasing attention as an alternative. Evolutionary theory predicts that the probability of bacterial resistance to both phages and antibiotics will be lower than to either separately, due for example to fitness costs or to trade-offs between phage resistance mechanisms and bacterial growth. In this study, we assess the population impacts of either individual or combined treatments of a bacteriophage and streptomycin on the nosocomial pathogen Pseudomonas aeruginosa. We show that combining phage and antibiotics substantially increases bacterial control compared to either separately, and that there is a specific time delay in antibiotic introduction independent of antibiotic dose, that minimizes both bacterial density and resistance to either antibiotics or phage. These results have implications for optimal combined therapeutic approaches.     

Wastewater as a fertility source for novel bacteriophages against multi-drug resistant bacteria

Antibiotic resistance is a common and serious public health worldwide. As an alternative to antibiotics, bacteriophage (phage) therapy offers one of the best solutions to antibiotic resistance. Bacteriophages survive where their bacterial hosts are found; thus, they exist in almost all environments and their applications are quite varied in the medical, environmental, and industrial fields. Moreover, a single phage or a mixture of phages can be used in phage therapy; mixed phages tend to be more effective in reducing the number and/or activity of pathogenic bacteria than that of a single phage.     

Identification of antimicrobial peptide regions derived from genomic sequences of phage lysins

This study was designed to test the possibility that antimicrobial peptides could be derived from the genomic sequences of phage lysins. Using two lysins (D3 and PhiKZ) we selected and produced two putative peptides (X and Z, respectively) believed to possess antimicrobial properties based on their physicochemical characteristics. The data presented support this hypothesis in that the peptides and various analogs displayed antibacterial activity, bacteriostatic or bactericidal, either individually or upon combination. These putative peptides are believed to act by a mechanism of action resembling that of conventional antimicrobial peptides when judged by both structural and functional criteria. Thus, the peptides are shown to have the ability to form a helical structure, to bind to model bacterial membranes and permeabilize model liposomes. They also display rapid bactericidal kinetics and their antibacterial potency is increased upon amidation. The possible relevance of these results in contributing to potency of phage lysins is discussed. Such peptides may be used to design new potent antimicrobial compounds much needed in face of the ever threatening drug resistance problems.     

链球菌噬菌体裂解酶在大肠杆菌中的表达、纯化及活性检测

噬菌体裂解酶是噬菌体产生的细胞壁水解酶,通过水解宿主菌细胞壁使子代噬菌体释放,在体外能高效且特异性地杀死细菌。本研究旨在克隆和表达链球菌噬菌体裂解酶PlyC,并测定其生物学活性。利用PCR方法扩增PlyC的2条肽链PlyCA和PlyCB,构建表达载体pET-32a(+)-PlyCA和pET-32a(+)-PlyCB,分别转化至大肠杆菌BL21(DE3)中,以0.7 mmol/L IPTG在30 oC诱导7 h实现了高效表达,SDS-PAGE分析表明PlyCA和PlyCB表达量均可达菌体总蛋白的30%以上。采用Ni2+-NTA亲和层析法纯化目的蛋白,其纯度大于95%。用透析复性方法得到目的产物重组链球菌噬菌体裂解酶PlyC,以浊度法和平板计数法检测其体外抗菌效果,扫描电子显微镜观察裂解酶作用前后细菌细胞形态变化。结果表明重组PlyC能特异性裂解化脓性链球菌(A组β-溶血性链球菌),以4μg/mL浓度作用于OD600为0.56的菌液60 min后杀菌率达99.6%,扫描电镜观察结果显示该酶作用于菌体后,链球菌细胞裂解,呈碎片状态。本研究为开发一种新型、高效的链球菌感染疾病治疗药物打下了基础。     

Bacteriophages and Lysins in Biofilm Control

To formulate the optimal strategy of combatting bacterial biofilms, in this review we update current knowledge on the growing problem of biofilm formation and its resistance to antibiotics which has spurred the search for new strategies to deal with this complication. Based on recent findings, the role of bacteriophages in the prevention and elimination of biofilm-related infections has been emphasized. In vitro, ex vivo and in vivo biofilm treatment models with single bacteriophages or phage cocktails have been compared. A combined use of bacteriophages with antibiotics in vitro or in vivo confirms earlier reports of the synergistic effect of these agents in improving biofilm removal. Furthermore, studies on the application of phage-derived lysins in vitro, ex vivo or in vivo against biofilm-related infections are encouraging. The strategy of combined use of phage and antibiotics seems to be different from using lysins and antibiotics. These findings suggest that phages and lysins alone or in combination with antibiotics may be an efficient weapon against biofilm formation in vivo and ex vivo, which could be useful in formulating novel strategies to combat bacterial infections. Those findings proved to be relevant in the prevention and destruction of biofilms occurring during urinary tract infections,orthopedic implant-related infections, periodontal and peri-implant infections. In conclusion, it appears that most efficient strategy of eliminating biofilms involves phages or lysins in combination with antibiotics, but the optimal scheme of their administration requires further studies.     

Effects of prior exposure to antibiotics on bacterial adaptation to phages

Understanding adaptation to complex environments requires information about how exposure to one selection pressure affects adaptation to others. For bacteria, antibiotics and viral parasites (phages) are two of the most common selection pressures and are both relevant for treatment of bacterial infections: increasing antibiotic resistance is generating significant interest in using phages in addition or as an alternative to antibiotics. However, we lack knowledge of how exposure to antibiotics affects bacterial responses to phages. Specifically, it is unclear how the negative effects of antibiotics on bacterial population growth combine with any possible mutagenic effects or physiological responses to influence adaptation to other stressors such as phages, and how this net effect varies with antibiotic concentration. Here, we experimentally addressed the effect of pre‐exposure to a wide range of antibiotic concentrations on bacterial responses to phages. Across 10 antibiotics, we found a strong association between their effects on bacterial population size and subsequent population growth in the presence of phages (which in these conditions indicates phage‐resistance evolution). We detected some evidence of mutagenesis among populations treated with fluoroquinolones and β‐lactams at sublethal doses, but these effects were small and not consistent across phage treatments. These results show that, although stressors such as antibiotics can boost adaptation to other stressors at low concentrations, these effects are weak compared to the effect of reduced population growth at inhibitory concentrations, which in our experiments strongly reduced the likelihood of subsequent phage‐resistance evolution.     

Individual bacteria in structured environments rely on phenotypic resistance to phage

Bacteriophages represent an avenue to overcome the current antibiotic resistance crisis, but evolution of genetic resistance to phages remains a concern. In vitro, bacteria evolve genetic resistance, preventing phage adsorption or degrading phage DNA. In natural environments, evolved resistance is lower possibly because the spatial heterogeneity within biofilms, microcolonies, or wall populations favours phenotypic survival to lytic phages. However, it is also possible that the persistence of genetically sensitive bacteria is due to less efficient phage amplification in natural environments, the existence of refuges where bacteria can hide, and a reduced spread of resistant genotypes. Here, we monitor the interactions between individual planktonic bacteria in isolation in ephemeral refuges and bacteriophage by tracking the survival of individual cells. We find that in these transient spatial refuges, phenotypic resistance due to reduced expression of the phage receptor is a key determinant of bacterial survival. This survival strategy is in contrast with the emergence of genetic resistance in the absence of ephemeral refuges in well-mixed environments. Predictions generated via a mathematical modelling framework to track bacterial response to phages reveal that the presence of spatial refuges leads to fundamentally different population dynamics that should be considered in order to predict and manipulate the evolutionary and ecological dynamics of bacteria–phage interactions in naturally structured environments.

Bacteriophages represent a promising avenue to overcome the current antibiotic resistance crisis, but evolution of phage resistance remains a concern. This study shows that in the presence of spatial refuges, genetic resistance to phage is less of a problem than commonly assumed, but the persistence of genetically susceptible bacteria suggests that eradicating bacterial pathogens from structured environments may require combined phage-antibiotic therapies.     

Lytic enzyme discovery through multigenomic sequence analysis in <Emphasis Type="Italic">Clostridium perfringens</Emphasis>

With their ability to lyse Gram-positive bacteria, phage lytic enzymes (or lysins) have received a great deal of attention as novel anti-infective agents. The number of known genes encoding these peptidoglycan hydrolases has increased markedly in recent years, due in large part to advances in DNA sequencing technology. As the genomes of more and more bacterial species/strains are sequenced, lysin-encoding open reading frames (ORFs) can be readily identified in lysogenized prophage regions. In the current study, we sought to assess lysin diversity for the medically relevant pathogen Clostridium perfringens. The sequenced genomes of nine C. perfringens strains were computationally mined for prophage lysins and lysin-like ORFs, revealing several dozen proteins of various enzymatic classes. Of these lysins, a muramidase from strain ATCC 13124 (termed PlyCM) was chosen for recombinant analysis based on its dissimilarity to previously characterized C. perfringens lysins. Following expression and purification, various biochemical properties of PlyCM were determined in vitro, including pH/salt-dependence and temperature stability. The enzyme exhibited activity at low μg/ml concentrations, a typical value for phage lysins. It was active against 23 of 24 strains of C. perfringens tested, with virtually no activity against other clostridial or non-clostridial species. Overall, PlyCM shows potential for development as an enzybiotic agent, demonstrating how expanding genomic databases can serve as rich pools for biotechnologically relevant proteins.     

Dynamic Motion and Communication in the Streptococcal C1 Phage Lysin,PlyC

The growing problem of antibiotic resistance underlies the critical need to develop new treatments to prevent and control resistant bacterial infection. Exogenous application of bacteriophage lysins results in rapid and specific destruction of Gram-positive bacteria and therefore lysins represent novel antibacterial agents. The PlyC phage lysin is the most potent lysin characterized to date and can rapidly lyse Group A, C and E streptococci. Previously, we have determined the X-ray crystal structure of PlyC, revealing a complicated and unique arrangement of nine proteins. The scaffold features a multimeric cell-wall docking assembly bound to two catalytic domains that communicate and work synergistically. However, the crystal structure appeared to be auto-inhibited and raised important questions as to the mechanism underlying its extreme potency. Here we use small angle X-ray scattering (SAXS) and reveal that the conformational ensemble of PlyC in solution is different to that in the crystal structure. We also investigated the flexibility of the enzyme using both normal mode (NM) analysis and molecular dynamics (MD) simulations. Consistent with our SAXS data, MD simulations show rotational dynamics of both catalytic domains, and implicate inter-domain communication in achieving a substrate-ready conformation required for enzyme function. Our studies therefore provide insights into how the domains in the PlyC holoenzyme may act together to achieve its extraordinary potency.