噬菌体治疗细菌性感染及其限制因素

近年来,细菌耐药性已成为抗感染领域面临的严峻问题,临床对一些细菌性感染疾病束手无策。噬菌体疗法是一种通过噬菌体裂解细菌来治疗病原菌感染的治疗手段。噬菌体在抗菌领域表现出显著的优越性,成为目前治疗细菌性感染的研究热点。本文对近年来噬菌体治疗动物和人类病原菌感染、限制其临床应用的因素及解决措施进行综述。     

噬菌体在防控鱼类细菌性病害中的作用机制及其应用

鱼类细菌性病害对发展鱼类养殖业构成了严重的威胁,而抗生素的滥用和病原菌耐药性的出现对鱼类养殖产量、水产品质量和养殖环境造成了严重的影响。为了推动鱼类健康养殖产业的发展,亟待创新研究鱼类病害的绿色防控技术。噬菌体作为一种天然、无残留的细菌杀手,具有特异性强、裂解效率高等特点,利用噬菌体治疗鱼类细菌性病害将是一种重要的技术途径。本文综述了噬菌体的重要资源挖掘、鱼类细菌性病害防控中的作用机制及其应用前景,并提出了在鱼类健康养殖领域加快研究噬菌体治疗技术的措施,对鱼类的健康养殖具有重要意义。     

噬菌体对黏质沙雷菌感染 BA LB／c小鼠的保护作用

本文旨在观察噬菌体对黏质沙雷菌感染小鼠的治疗作用,为噬菌体疗法应用于细菌性感染提供依据。以黏质沙雷菌为宿主菌,采用双层琼脂噬斑法从污水中分离和纯化裂解性噬菌体。将最小致死量的黏质沙雷菌经腹腔感染BALB／c小鼠后,立即腹腔注射不同剂量的噬菌体,观察动物的生存率并确定噬菌体的保护剂量。在动物感染后的不同时间（0、20、40、60和180 min ）观察噬菌体疗法对动物存活率的影响。将噬菌体和细菌同时或分别注射动物后,分析噬菌体在动物体内的药代动力学。结果显示,经噬斑法从污水中分离出1株裂解性噬菌体（命名为φSM9‐3Y ）,电镜观察发现该噬菌体属有尾噬菌体目肌尾噬菌体科。动物腹腔感染黏质沙雷菌并立即给予噬菌体后发现,当噬菌体的保护剂量为108 PFU／ml时,动物的存活率为100％。动物感染后40和60 min给予噬菌体（1010 PFU／ml）治疗,动物的存活率为60％。药代动力学表明,将噬菌体和细菌同时注入动物体内,在6 h内噬菌体的滴度维持在1010 PFU／ml。结果提示,噬菌体对黏质沙雷菌所致动物腹腔内感染的治疗是有效的,提示针对细菌性感染的噬菌体疗法具有潜在的应用价值。     

青枯菌特异性噬菌体的研究进展与应用

烟草等茄科植物青枯病的防治是一个世界性难题,传统的化学防治、合理轮作、抗病品种等措施无法有效控制该病的发生。噬菌体用于细菌性病害的防治已有很长历史,近年来利用噬菌体防治青枯菌引发的青枯病方面的研究越来越受重视。我们简要综述了青枯菌噬菌体的研究进展,并对青枯菌噬菌体生物防治的应用前景进行了展望。     

噬菌体治疗肺炎克雷伯菌感染的研究进展

肺炎克雷伯菌是肠杆菌科家族中的一员,在各种环境中广泛存在,可导致诸如奶牛乳房炎在内的多种动物疫病,引起人类的肺炎、尿路感染、菌血症、伤口性感染和化脓性脓肿在内的多种临床感染。该菌对抗生素的耐受日趋严重,而且高毒力菌株不断出现,给该菌的防控带来了巨大挑战。噬菌体是一种裂解细菌的病毒,因其具有治疗耐药细菌感染的潜力而备受关注,世界各地均有使用噬菌体成功治疗耐药细菌感染的案例。本文基于国内外对肺炎克雷伯菌及其噬菌体的研究数据,综述了肺炎克雷伯菌的流行病学调查情况和噬菌体在治疗肺炎克雷伯菌感染方面的应用,以期为基于肺炎克雷伯菌噬菌体的抗菌研究和临床应用提供参考。     

噬菌体展示技术在疫苗研究中的应用进展

噬菌体是一种以细菌为宿主的具有严格宿主特异性的病毒,近年来由于分子生物学和基因重组技术的长足发展,藉助噬菌体的基本特性创立和发展了噬菌体展示技术,此项技术将外源肽或蛋白与特定噬菌体衣壳蛋白融合并展示于噬菌体表面。利用这项技术制作的疫苗具有安全可靠、稳定性高、免疫效果好等优点,因此,在新型疫苗的研制上具有很大的应用价值。就噬菌体展示技术及其在疫苗研究中的优势、预防性疫苗与治疗性疫苗的研究进展予以综述。     

T7家族噬菌体感染宿主菌的起始——吸附和穿入

噬菌体和细菌互相作用的研究,是分子生物学的重要内容,在细菌感染性疾病的治疗等方面有重要的应用价值。噬菌体的感染从噬菌体吸附于宿主菌表面并将核酸注入开始。介绍了T7家族代表株T7噬菌体在吸附和穿入阶段需要的结构和具体过程,并简要综述了T7家族3个亚群的特征。     

噬菌体治疗中细菌对噬菌体的抗性

抗生素治疗尽管有几十年有效治疗的历史,但随着越来越多耐/抗药性细菌的出现,细菌对抗生素的抗药性已成为一个大问题。噬菌体治疗是使用噬菌体作为抗菌剂来感染细菌株系,它一直是人们倡导的一个很有前途的常规抗生素治疗的替代方案。然而,由于细菌与噬菌体的协同进化中,细菌可以通过多种机制获得对噬菌体的抗性。因此,人们对噬菌体治疗抱有期望的同时,也关注噬菌体治疗长时间的使用之后,是否会与抗生素使用之后结果相类似,导致抗性细菌病原菌感染的治疗困难。综述了细菌-噬菌体协同进化中细菌病原菌对有感染能力的噬菌体是否会产生抗性,及其在噬菌体治疗中影响的争论,并展望了噬菌体治疗的潜在前景。     

细菌耐受噬菌体感染的分子机制研究进展

噬菌体是能感染细菌的病毒。为了抵抗噬菌体的感染,细菌进化出多种抵抗噬菌体感染的机制,这些机制的阐析极大地促进了基因编辑领域的发展,同时也为噬菌体治疗的开展奠定了基础。本文就细菌针对噬菌体感染的各个环节所进行的抵抗及其分子机制进行了简要综述,同时讨论了这些防御系统的存在对细菌自身的影响,分析了当前细菌耐受噬菌体机制研究存在的局限性,并对未来研究进行了展望。     

合成噬菌体的贡献与风险

噬菌体（bacteriophage,phage）是感染细菌、真菌、放线菌或螺旋体等微生物的细菌病毒的总称。噬菌体在生态、微生物进化、细菌性疾病预防和治疗、细菌鉴定与疾病诊断等方面扮演重要角色。基因组测序技术和高效合成平台促进了合成基因组学的发展。利用合成基因组学技术,对噬菌体基因组进行设计或者合成出新的噬菌体来服务人类在不久的未来可能成为现实。但与此同时,合成噬菌体带来的风险也必须认真考虑。     

Use of phages to control Campylobacter spp.

The use of phages to control pathogenic bacteria has been investigated since they were first discovered in the beginning of the 1900s. Over the last century we have slowly gained an in-depth understanding of phage biology including which phage properties are desirable when considering phage as biocontrol agents and which phage characteristics to potentially avoid. Campylobacter infections are amongst the most frequently encountered foodborne bacterial infections around the world. Handling and consumption of raw or undercooked poultry products have been determined to be the main route of transmission. The ability to use phages to target these bacteria has been studied for more than a decade and although we have made progress towards deciphering how best to use phages to control Campylobacter associated with poultry production, there is still much work to be done. This review outlines methods to improve the isolation of these elusive phages, as well as methods to identify desirable characteristics needed for a successful outcome. It also highlights the body of research undertaken so far and what criteria to consider when doing in-vivo studies, especially because some in-vitro studies have not been found to translate into to phage efficacy in-vivo.     

Optimal bacteriophage mutation rates for phage therapy

The mutability of bacteriophages offers a particular advantage in the treatment of bacterial infections not afforded by other antimicrobial therapies. When phage-resistant bacteria emerge, mutation may generate phage capable of exploiting and thus limiting population expansion among these emergent types. However, while mutation potentially generates beneficial variants, it also contributes to a genetic load of deleterious mutations. Here, we model the influence of varying phage mutation rate on the efficacy of phage therapy. All else being equal, phage types with historical mutation rates of approximately 0.1 deleterious mutations per genome per generation offer a reasonable balance between beneficial mutational diversity and deleterious mutational load. We determine that increasing phage inoculum density can undesirably increase the peak density of a mutant bacterial class by limiting the in situ production of mutant phage variants. For phage populations with minimal genetic load, engineering mutation rate increases beyond the mutation-selection balance optimum may provide even greater protection against emergent bacterial types, but only with very weak selective coefficients for de novo deleterious mutations (below approximately 0.01). Increases to the mutation rate beyond the optimal value at mutation-selection balance may therefore prove generally undesirable.     

Structure and assembly of filamentous bacteriophages

Filamentous bacteriophages are interesting paradigms in structural molecular biology, in part because of the unusual mechanism of filamentous phage assembly. During assembly, several thousand copies of an intracellular DNA-binding protein bind to each copy of the replicating phage DNA, and are then displaced by membrane-spanning phage coat proteins as the nascent phage is extruded through the bacterial plasma membrane. This complicated process takes place without killing the host bacterium.     

The isolation and characterization of two Stenotrophomonas maltophilia bacteriophages capable of cross-taxonomic order infectivity

Background

A rapid worldwide increase in the number of human infections caused by the extremely antibiotic resistant bacterium Stenotrophomonas maltophilia is prompting alarm. One potential treatment solution to the current antibiotic resistance dilemma is “phage therapy”, the clinical application of bacteriophages to selectively kill bacteria.

Results

Towards that end, phages DLP1 and DLP2 (vB_SmaS-DLP_1 and vB_SmaS-DLP_2, respectively) were isolated against S. maltophilia strain D1585. Host range analysis for each phage was conducted using 27 clinical S. maltophilia isolates and 11 Pseudomonas aeruginosa strains. Both phages exhibit unusually broad host ranges capable of infecting bacteria across taxonomic orders. Transmission electron microscopy of the phage DLP1 and DLP2 morphology reveals that they belong to the Siphoviridae family of bacteriophages. Restriction fragment length polymorphism analysis and complete genome sequencing and analysis indicates that phages DLP1 and DLP2 are closely related but different phages, sharing 96.7 % identity over 97.2 % of their genomes. These two phages are also related to P. aeruginosa phages vB_Pae-Kakheti_25 (PA25), PA73, and vB_PaeS_SCH_Ab26 (Ab26) and more distantly related to Burkholderia cepacia complex phage KL1, which together make up a taxonomic sub-family. Phages DLP1 and DLP2 exhibited significant differences in host ranges and growth kinetics.

Conclusions

The isolation and characterization of phages able to infect two completely different species of bacteria is an exciting discovery, as phages typically can only infect related bacterial species, and rarely infect bacteria across taxonomic families, let alone across taxonomic orders.

Electronic supplementary material

The online version of this article (doi:10.1186/s12864-015-1848-y) contains supplementary material, which is available to authorized users.     

噬菌体疗法及其在美洲幼虫腐臭病中的研究进展

美洲幼虫腐臭病是西方蜜蜂中最严重的细菌病之一,给养蜂业带来了严重的损失。幼虫芽胞杆菌是幼蜂感染美洲幼虫腐臭病的病原菌。由于抗生素产生的耐药性越来越严重,并且抗生素的使用会破坏宿主肠道菌群,使蜂群处于高危的环境中,因此迫切需要抗生素治疗的替代技术,而噬菌体在预防和控制细菌耐药性方面已显示出显著的优势。主要综述了噬菌体疗法、安全性及其在蜜蜂美洲幼虫腐臭病中的研究现状,介绍了噬菌体疗法在各类细菌病中的研究与应用,对今后噬菌体治疗蜜蜂细菌病研究方向进行了展望。     

一株肺炎克雷伯菌噬菌体的生物学特性及全基因组分析

【背景】随着抗生素的广泛使用甚至滥用,细菌耐药性问题日益显著,利用噬菌体治疗耐药致病菌的方法重新开始被人们关注。【目的】对一株烈性肺炎克雷伯菌噬菌体vB_KpnP_IME279进行生物学特性研究及生物信息学分析。【方法】以一株多重耐药的肺炎克雷伯菌为宿主菌,从医院污水中分离噬菌体,应用双层平板法检测噬菌体效价、最佳感染复数(Optimal MOI)、一步生长曲线以及裂解谱,纯化后通过透射电镜观察噬菌体形态;应用蛋白酶K/SDS法提取噬菌体全基因组,使用Illumina MiSeq测序平台进行噬菌体全基因组测序,测序后对噬菌体全基因组序列进行组装、注释、进化和比较基因组学分析。【结果】分离到一株新的肺炎克雷伯菌噬菌体,命名为vB_KpnP_IME279;其最佳感染复数为0.1,一步生长曲线显示潜伏期为20 min,平均裂解量140 PFU/cell,电镜观察显示该噬菌体属于短尾噬菌体科(Podoviridae)。基因组测序表明,噬菌体基因组全长为42 518 bp,(G+C)mol%含量为59.3%。BLASTn比对结果表明,该噬菌体与目前已知噬菌体的相似性较低,基因组仅70%区域与已知噬菌体有同源性。构建噬菌体主要衣壳蛋白的基因进化树,分析了噬菌体IME279与其他短尾科噬菌体的进化关系,结果表明该噬菌体是短尾科噬菌体的一名新成员。【结论】分离鉴定了一株新的肺炎克雷伯菌噬菌体,进行了生物学特性、全基因组测序和生物信息学分析,为研究肺炎克雷伯菌噬菌体与宿主之间的相互作用关系以及治疗多重耐药细菌感染奠定了基础。     

The host range of the male-killing symbiont Arsenophonus nasoniae in filth fly parasitioids

The Son-killer bacterium, Arsenophonus nasoniae, infects Nasonia vitripennis (Hymenoptera: Pteromalidae), a parasitic wasp that attacks filth flies. This gammaproteobacterium kills a substantial amount of male embryos produced by an infected female. Aside from male death, the bacterium does not measurably affect the host, and how it is maintained in the host population is unknown. Interestingly, this bacterial symbiont can be transmitted both vertically (from mother to offspring) and horizontally (to unrelated Nasonia wasps developing in the same fly host). This latter mode may allow the bacterium to spread throughout the ecological community of filth flies and their parasitoids, and to colonize novel species, as well as permit its long-term persistence.We tested 11 species of filth flies and 25 species of their associated parasitoids (representing 28 populations from 16 countries) using diagnostic PCR to assess the bacterium’s actual host range. In addition to 16S rRNA, two loci were targeted: the housekeeping gene infB, and a sequence with high homology to a DNA polymerase gene from a lysogenic phage previously identified from other insect symbionts. We identified infections of A. nasoniae in four species of parasitoids, representing three taxonomic families. Highly similar phage sequences were also identified in three of the four species. These results identify the symbiont as a generalist, rather than a specialist restricted solely to species of Nasonia, and also that horizontal transmission may play an important role in its maintenance.     

A Novel Vibriophage vB＿VcaS＿HC Containing Lysogeny-Related Gene Has Strong Lytic Ability against Pathogenic Bacteria

To avoid the negative effects of antibiotics, using phage to prevent animal disease becomes a promising method in aquaculture. Here, a lytic phage provisionally named v B＿VcaS＿HC that can infect the pathogen(i.e., Vibrio campbellii 18)of prawn was isolated. The phage has an isometric head and a non-contractile tail. During phage infection, the induced host mortality in 5.5 h reached ca. 96%, with a latent period of 1.5 h and a burst size of 172 PFU/cell. It has an 81,566 bp circular dsDNA genome containing 121 open reading frames(ORFs), and ca. 71% of the ORFs are functionally unknown.Comparative genomic and phylogenetic analysis revealed that it is a novel phage belonging to Delepquintavirus,Siphoviridae, Caudovirales. In the phage genome, besides the ordinary genes related to structure assembly and DNA metabolism, there are 10 auxiliary metabolic genes. For the first time, the pyruvate phosphate dikinase(PPDK) gene was found in phages whose product is a key rate-limiting enzyme involving Embden-Meyerhof-Parnas(EMP) reaction.Interestingly, although the phage has a strong bactericidal activity and contains a potential lysogeny related gene, i.e., the recombinase(RecA) gene, we did not find the phage turned into a lysogenic state. Meanwhile, the phage genome does not contain any bacterial virulence gene or antimicrobial resistance gene. This study represents the first comprehensive characterization of a lytic V. campbellii phage and indicates that it is a promising candidate for the treatment of V.campbellii infections.     

Electrooptical analysis of the Escherichia coli-phage interaction

This article describes electrooptical (EO) characterization of biospecific binding between the bacterium Escherichia coli XL-1 and the phage M13K07. The electrooptical analyzer (ELUS EO), which has been developed at the State Research Center for Applied Microbiology, Obolensk, Russia, was used as the basic instrument for EO measurements. The operating principle of the analyzer is based on the polarizability of microorganisms, which depends strongly on their composition, morphology, and phenotype. The principle of analysis of the interaction of E. coli with the phage M13K07 is based on registration of changes of optical parameters of bacterial suspensions. The phage-cell interaction includes the following stages: phage adsorption on the cell surface, entry of viral DNA into the bacterial cell, amplification of phage within infected host, and phage ejection from the cell. In this work, we used M13K07, a filamentous phage of the family Inoviridae. Preliminary study had shown that combination of the EO approach with a phage as a recognition element has an excellent potential for mediator-less detection of phage-bacteria complex formation. The interaction of E. coli with phage M13K07 induces a strong and specific EO signal as a result of substantial changes of the EO properties of the E. coli XL-1 suspension infected by the phage M13K07. The signal was specific in the presence of foreign microflora (E. coli K-12 and Azospirillum brasilense Sp7). Integration of the EO approach with a phage has the following advantages: (1) bacteria from biological samples need not be purified, (2) the infection of phage to bacteria is specific, (3) exogenous substrates and mediators are not required for detection, and (4) it is suitable for any phage-bacterium system when bacteria-specific phages are available.     

细菌毒素-抗毒素系统在噬菌体流产感染中的作用北大核心CSCD

细菌常受到数量众多的噬菌体感染,宿主细菌在和噬菌体竞赛中进化出多样化的分子策略,流产感染(abortive infection,Abi)是其中之一。毒素-抗毒素系统(toxin-antitoxin system,TA)会在细菌受到压力胁迫时表达并介导细菌的低代谢甚至休眠,还能直接减少子代噬菌体形成。此外,部分毒素序列和结构与Cas蛋白高度同源,噬菌体甚至会编码抗毒素类似物来阻遏对应毒素的活性。这表明流产感染中细菌死亡过程导致的噬菌体感染失败与TA功能高度重合,TA可能是噬菌体侵染宿主的主要阻力和防御力量之一。文中基于TA系统的分类和功能,对参与噬菌体流产感染的TA系统进行了综述,并预测具有流产功能的TA系统和其在抗生素开发和疾病治疗中的应用前景。这有助于认识细菌-噬菌体相互作用,并指导噬菌体治疗和合成生物学。