线粒体DNA聚合酶的起源与演化

随着新的DNA聚合酶A家族成员的加入,家族内部的系统发育关系需要重新检查,来自大肠杆菌DNA聚合酶I(DNA Pol I)和它的细菌、噬菌体和真核细胞同源物被用来重建这个家族的系统发育史.分析显示:在真核生物演化的不同阶段,线粒体DNA聚合酶基因可能通过水平基因转移方式起源于不同类群的生物.原始真核生物线粒体DNA聚合酶基因可能来源于细菌,植物线粒体DNA聚合酶基因可能从质粒获得,而真菌和动物线粒体DNA聚合酶基因可能起源于T3/T7相关噬菌体.     

噬菌体吸附及受体结合蛋白(RBP)的研究进展与应用

噬菌体通过受体结合蛋白(Receptor binding protein,RBP)结合到细菌表面,其过程需要复杂的原子结构的参与和构象改变。针对噬菌体侵染,细菌发展了多种抗性机制,同时,噬菌体也进化出多种逃逸宿主抗性的机制。对噬菌体与细菌间"吸附-抗吸附-逃逸过程"的探索有助于我们理解噬菌体与细菌共进化的过程,对科学发展噬菌体治疗技术以及噬菌体的生物应用技术具有重要意义。本文概述了噬菌体吸附相关蛋白及吸附发生过程、基于RBP改变的噬菌体逃逸机制和RBP相关的生物技术研究进展。     

线粒体DNA聚合酶的起源研究

随着新的DNA聚合酶A家族成员的加入,家族内部的系统发育关系需要重新检查。分析显示：在真核生物演化的不同阶段,线粒体DNA聚合酶基因可能通过水平基因转移方式起源于不同类群的生物。原始真核生物线粒体DNA聚合酶基因可能来源于细菌,植物线粒体DNA聚合酶基因可能从质粒获得,而真菌和动物线粒体DNA聚合酶基因可能起源于T3/T7相关噬菌体。     

鼠疫菌噬菌体效价噬菌斑测定法的建立

目的建立鼠疫菌噬菌体噬菌斑效价测定方法。方法通过分析细菌接种浓度、孵育吸附时间及培养温度等参数,建立鼠疫菌噬菌体效价测定方法,并分析其精密性;建立鼠疫活疫苗鉴别及纯菌检查用噬菌体效价质量标准。结果经优化后确定细菌接种浓度为7×108/mL,不需孵育吸附,培养温度为29℃,所建立的检测方法精密性较好,用于鼠疫活疫苗鉴别及纯菌检查用噬菌体效价质量标准应不低于1×106PFU/mL。结论建立了鼠疫菌噬菌体噬菌斑效价测定方法,为鼠疫菌噬菌体及疫苗质量控制奠定了基础。     

细菌与噬菌体相互抵抗机制研究进展

噬菌体作为一种侵染细菌的病毒,能够特异性识别宿主细菌。近年来,抗生素的过度使用导致耐药细菌的出现,噬菌体有望成为对抗耐药细菌的新武器。在细菌与噬菌体长期共进化过程中,二者都演化出一系列抵御策略。本文从抑制噬菌体吸附、阻止噬菌体DNA进入、切割噬菌体基因组、流产感染以及群体感应对噬菌体的调控等方面,对细菌抵抗噬菌体的机制以及噬菌体应对细菌的策略进行了综述,同时还列举了细菌和噬菌体相互抵抗机制的检测方法,以期为噬菌体在细菌控制中的应用以及探究细菌抵抗噬菌体的机制提供理论依据。     

利用重组噬菌体诱导表达的大肠杆菌表达系统

将编码噬菌体T7RNA聚合酶的基因克隆至噬菌体M13mpl8RFDNA中,置于lac启动子的控制之下,得到了可表达T7 RNA聚合酶的重组噬菌体M13HEP。利用该噬菌体感染含T7启动子表达质粒的宿主菌以提供T7RNA聚合酶,可以诱导T7启动子控制下的外源基因的表达。该噬茵体诱导表达系统已成功地表达了多种外源基因,特别是一些表达产物对宿主菌有毒性的基因。同时,通过细菌接合将F',因子从大脑杆菌XL1-blue转至大肠杆菌HMS174,构建了新的大脑杆菌菌株HMSl74F,,使得T7表达质粒构建、表达及单链制备可以在同一菌株中完成,得到了一个完整的T7表达系统。     

细菌-噬菌体对抗性共进化研究进展 *

共进化现象在自然界中普遍存在。细菌和细菌的天敌噬菌体之间的对抗是一场持久战,细菌-噬菌体系统是研究共进化的模式材料。目前关于细菌-噬菌体对抗性共进化的机制有两种公认的模型,即GFG模型和MA模型,对应于两种模式,即ARD模式和FSD模式;主要采用Time-Shift Assays方法测定细菌-噬菌体的对抗性共进化动力学模式。长尾噬菌体是有尾噬菌体中最大的家族。目前关于细菌-噬菌体系统共进化的研究主要集中在短尾和肌尾噬菌体与其宿主之间,而细菌-长尾噬菌体共进化的研究报道较少。     

细菌-噬菌体对抗性共进化研究进展

共进化现象在自然界中普遍存在。细菌和细菌的天敌噬菌体之间的对抗是一场持久战,细菌-噬菌体系统是研究共进化的模式材料。目前关于细菌-噬菌体对抗性共进化的机制有两种公认的模型,即GFG模型和MA模型,对应于两种模式,即ARD模式和FSD模式;主要采用TimeShift Assays方法测定细菌-噬菌体的对抗性共进化动力学模式。长尾噬菌体是有尾噬菌体中最大的家族。目前关于细菌-噬菌体系统共进化的研究主要集中在短尾和肌尾噬菌体与其宿主之间,而细菌-长尾噬菌体共进化的研究报道较少。     

细菌与噬菌体的相互抵抗作用机制

噬菌体是地球生物圈里数量最多、存在最久的个体之一,也是应对抗生素耐药细菌感染的极具特点的候选制剂之一。本文分别以细菌和噬菌体的视角,从阻止噬菌体吸附、超感染排除、限制修饰系统、CRISPR­Cas、流产感染等方面综述了细菌抗噬菌体的机制以及噬菌体针对细菌抗性机制的应变。     

溶原性

大多数噬菌体是烈性的(如T4、T7、φ×174等),即它们在生长循环结束时杀死细胞。不过有许多噬菌体,能以另一种方式和寄主相互作用:噬菌体和寄主一起增殖,这样的关系就叫做溶原性。在溶原性细胞中的噬菌体叫做前噬菌体。一、溶原性菌株的性质温和噬菌体感染一个敏感细菌菌株时,可根据各     

The role of ATP and membrane potential in the penetration of phage T17 DNA into the cell during infection

The role of ATP and membrane potential in phage T7 DNA injection into E. coli during infection has been studied. Entrance of phage T7 genes of class II and III was shown to be prevented by arsenate, indicating the requirement for phosphorylated macroergs in the phage DNA injection. The injection process was also inhibited by exposition of the cells to the uncoupler of oxidative phosphorylation. Dependence of the injection efficiency on the membrane-potential value has been shown to be sigmoidal, which suggests a regulatory role of the membrane potential in phage T7 DNA injection from the virion into the host cell.     

Physiological and Genetic Aspects of Abortive Infection of a Shigella sonnei Strain by Coliphage T7

Phage T7 adsorbed to and lysed cells of Shigella sonnei D(2) 371-48, although the average burst size was only 0.1 phage per cell (abortive infection). No mechanism of host-controlled modification was involved. Upon infection, T7 rapidly degraded host deoxyribonucleic acid (DNA) to acid-soluble material. Phage-directed DNA synthesis was initiated normally, but after a few minutes the pool of phage DNA, including the parental DNA, was degraded. Addition of chloramphenicol, at the time of phage infection, prevented both the initiation of phage-directed DNA synthesis and the degradation of parental phage DNA. Addition of chloramphenicol 4.5 min after phage was added permitted the onset of phage-directed DNA synthesis but prevented breakdown of phage DNA. Mutants of T7 (ss(-) mutants) have been isolated which show normal growth in strain D(2) 371-48. Upon mixed infection of this strain with T7 wild type and an ss(-) mutant, infection was abortive; no complementation occurred. The DNA of the ss(-) mutants was degraded in mixed infection like that of the wild type. Revertant mutants which have lost their ability to grow on D(2) 371-48 were isolated from ss(-) mutants; they are, in essence, phenotypically like T7 wild type. Independently isolated revertants of ss(-) mutants did not produce ss(-) recombinants when they were crossed among themselves. When independently isolated ss(-) mutants were crossed with each other, wild-type recombinants were found; ss(-) mutants could then be mapped in a cluster compatible with the length of one cistron. We concluded that T7 codes for an active, chloramphenicol-sensitive function [ss(+) function (for suicide in Shigella)] which leads to the breakdown of phage DNA in the Shigella host.     

Alteration of tail fiber protein gp38 enables T2 phage to infect Escherichia coli O157:H7

Artificial control of phage specificity may contribute to practical applications, such as the therapeutic use of phages and the detection of bacteria by their specific phages. To change the specificity of phage infection, gene products (gp) 37 and 38, expressed at the tip of the long tail fiber of T2 phage, were exchanged with those of PP01 phage, an Escherichia coli O157:H7 specific phage. Homologous recombination between the T2 phage genome and a plasmid encoding the region around genes 37-38 of PP01 occurred in transformant E. coli K12 cells. The recombinant T2 phage, named T2ppD1, carried PP01 gp37 and 38 and infected the heterogeneous host cell E. coli O157:H7 and related species. On the other hand, T2ppD1 could not infect E. coli K12, the original host of T2, or its derivatives. The host range of T2ppD1 was the same as that of PP01. Infection of T2ppD1 produced turbid plaques on a lawn of E. coli O157:H7 cells. The binding affinity of T2ppD1 to E. coli O157:H7 was weaker than that of PP01. The adsorption rate constant (ka) of T2ppD1 (0.17 x 10(-9)(ml CFU(-1) min(-1)) was almost 1/6 that of PP01 (1.10 x 10(-9)(ml CFU(-1) min(-1))). In addition to the tip of the long tail fiber, exchange of gene products expressed in the short tail fiber may be necessary for tight binding of recombinant phage.     

Effects of Escherichia coli physiology on growth of phage T7 in vivo and in silico

Phage development depends not only upon phage functions but also on the physiological state of the host, characterized by levels and activities of host cellular functions. We established Escherichia coli at different physiological states by continuous culture under different dilution rates and then measured its production of phage T7 during a single cycle of infection. We found that the intracellular eclipse time decreased and the rise rate increased as the growth rate of the host increased. To develop mechanistic insight, we extended a computer simulation for the growth of phage T7 to account for the physiology of its host. Literature data were used to establish mathematical correlations between host resources and the host growth rate; host resources included the amount of genomic DNA, pool sizes and elongation rates of RNA polymerases and ribosomes, pool sizes of amino acids and nucleoside triphosphates, and the cell volume. The in silico (simulated) dependence of the phage intracellular rise rate on the host growth rate gave quantitatively good agreement with our in vivo results, increasing fivefold for a 2.4-fold increase in host doublings per hour, and the simulated dependence of eclipse time on growth rate agreed qualitatively, deviating by a fixed delay. When the simulation was used to numerically uncouple host resources from the host growth rate, phage growth was found to be most sensitive to the host translation machinery, specifically, the level and elongation rate of the ribosomes. Finally, the simulation was used to follow how bottlenecks to phage growth shift in response to variations in host or phage functions.     

DNA injection during bacteriophage T4 infection of Escherichia coli.

The process of phage T4 DNA injection into the host cell was studied under a fluorescent microscope, using 4',6-diamidino-2-phenylindole as a DNA-specific fluorochrome. The phage DNA injection was observed when spheroplasts were infected with the artificially contracted phage particles having a protruding core. The DNA injection was mediated by the interaction of the core tip with the cytoplasmic membrane of the spheroplast. A membrane potential was not required for the process of DNA injection. On the other hand, DNA injection upon infection by intact noncontracted phage of the intact host cell was inhibited by an energy poison. Based on these observations, together with results from previous work, a model for the T4 infection process is presented, and the role of the membrane potential in the infection process is discussed.     

Biological consequences of infection of Escherichia coli B by alkylated T7 bacteriophage.

Alkylation of T7 bacteriophage considerably delayed phage development and reduced the phage's killing action on host cells. Only a small fraction of infected cells produced phage. For these phages, the latent period was markedly prolonged but the burst was equivalent to or only slightly lower than that of untreated phage. In the progeny of alkylated phage, there was an increase in the fraction of defective particles as well as a change in their morphology. These data show that infection with alkylated T7 bacteriophage is to a large degree abortive; hence, biological consequences of this infection are very different from those characteristic of a normal virus infection.     

Rescue of abortive T7 gene 2 mutant phage infection by rifampin.

Infection of Escherichia coli with T7 gene 2 mutant phage was abortive; concatemeric phage DNA was synthesized but was not packaged into the phage head, resulting in an accumulation of DNA species shorter in size than the phage genome, concomitant with an accumulation of phage head-related structures. Appearance of concatemeric T7 DNA in gene 2 mutant phage infection during onset of T7 DNA replication indicates that the product of gene 2 was required for proper processing or packaging of concatemer DNA rather than for the synthesis of T7 progeny DNA or concatemer formation. This abortive infection by gene 2 mutant phage could be rescued by rifampin. If rifampin was added at the onset of T7 DNA replication, concatemeric DNA molecules were properly packaged into phage heads, as evidenced by the production of infectious progeny phage. Since the gene 2 product acts as a specific inhibitor of E. coli RNA polymerase by preventing the enzyme from binding T7 DNA, uninhibited E. coli RNA polymerase in gene 2 mutant phage-infected cells interacts with concatemeric T7 DNA and perturbs proper DNA processing unless another inhibitor of the enzyme (rifampin) was added. Therefore, the involvement of gene 2 protein in T7 DNA processing may be due to its single function as the specific inhibitor of the host E. coli RNA polymerase.     

Bacteriophage T4D receptors and the Escherichia coli cell wall structure: role of spherical particles and protein b of the cell wall in bacteriophage infection.

The nature of the interaction of bacteriophage T4D and the outer cell wall of its host, Escherichia coli B, has been investigated. Bacteria with altered or modified cell walls have been obtained by two different growth procedures: (i) growth in high osmolarity medium or (ii) growth in broth in the presence of divalent heavy metal ions. When these altered host cells were washed and subsequently added to regular growth medium, they interacted with added phage particles, but successful infection did not occur. Most of the phage particles released from these treated cells were observed to have full heads and an altered tail structure. The altered phage tails had contracted sheaths and unusual pieces of the bacterial cell wall attached to the distal portion of the exposed phage tail tube. Phage released from bacteria grown in the high osmolarity medium had attached cell wall pieces of two major types, these pieces being either 40 or 21 nm in diameter. The smaller-type cell wall pieces (21 nm) were formed by three spheres each measuring 7 nm in diameter. Phage particles released from cells previously exposed to the divalent metal ions had only one 7-nm cell wall sphere attached to the distal end of the tail tube. It was found that these 7-nm spheres (i) are normal components of the cell wall and are morphologically similar to endotoxin, (ii) are held in place on the cell wall by a component of the cell wall called protein b, and (iii) are most likely the site of penetration of the phage tail tube through which the phage DNA enters the host cell.