Mode of Host Cell Penetration by Bacteriophage φX174

Bacteriophage phiX174 is an icosahedral phage which attaches to host cells without the aid of a complex tail assembly. When phiX174 was mixed with cell walls isolated from the bacterial host, the virions attached to the wall fragments and the phage deoxyribonucleic acid (DNA) was released. Attachment was prevented if the cell walls were treated with chloroform. Release of phage DNA, but not viral attachment, was prevented if the cell walls were incubated with lysozyme or if the virions were inactivated with formaldehyde. Treatment of the cell walls with lysozyme released structures which were of uniform size (6.5 by 25 nm). These structures attached phiX174 at the tip of one of its 12 vertices, but the viral DNA was not released. The virions attached to these structures were oriented with their fivefold axis of symmetry normal to the long axis of the structure. No virions were attached to these structures by more than one vertex. Freeze-etch preparations of phiX174 adsorbed to intact bacteria showed that the virions were submerged to one half their diameter into the host cell wall, and the fivefold axis of symmetry was normal to the cell surface. A second cell could not be attached to the outwardly facing vertex of the adsorbed phage and thus the phage could not cross-link two cells. When the virions were labeled with (3)H-leucine, purified, and adsorbed to Escherichia coli cells, about 15% of the radioactivity was recovered as low-molecular-weight material from spheroplasts formed by lysozyme-ethylenediaminetetraacetic acid. Other experiments revealed that about 7% of the total parental virus protein label could be recovered in newly formed progeny virus.     

Bacteriophages of Clostridium saccharoperbutylacetonicum

The fine structure of phage HM 2 (group I) active on Clostridium saccharoperbutylacetonicum was studied by an electron microscopy with a negative-staining technique, and compared with those of more conventional types, phages HM 3 (group II) and HM 7 (group III), whose tails were clearly observed by a shadow-casting technique. This study revealed that phage HM 2 had an intricate tail which was not observed by a shadow-casting technique.

Phage HM 2 has an icosahedral head about 450 Å in diameter and a non-contractile tail about 300 Å long. The distal 130 Å of the tail axis has a width of 80 Å which is wider than the upper portion of the tail (50 to 60 Å). The distal enlargement is not seen in the hollow tail. Twelve fibrous-shaped appendages are attached symmetrically at the upper portion of tail axis and extend toward the distal base of the tail. Their length is a little shorter than 300 Å. They combine with divalent cations in the phage dilution medium, and also adsorb the host cell debris.

Phage HM 3 has an icosahedral head about 770 Å in diameter and a tail about 1000 Å long and 150 Å wide with contractile sheath. Phage HM 7 has an icosahedral head about 750 Å in diameter and a long non-contractile tail about 2000 Å long and about 120 Å wide with forked tip.

The structure of the tail of phage HM 2 is quite different from those of phages HM 3 and HM 7 hitherto described and those of the various phages of other bacteria.     

Evidence for a net-like organization of lipopolysaccharide particles in the Escherichia coli outer membrane

Cell wall LPS of Escherichia coli are organized as particles which are visible in the electron microscope, after treatment of the wall with alkali. We now describe alkali treated walls of three E. coli strains with differences in susceptibility to the T4 phage infection. Strain CR63, a usual host for the T4 phage, shows the LPS particles on the murein layer. These particles are absent in alkali treated cell walls of the strain W. Walls of this strain are broken during T4 infection and phages can be seen bearing pieces of membrane attached to their long as well as their short tail fibers. Strain AS19 which is hypersensitive to the lysis from without caused by T4 shows murein layers with no LPS particles on their surface, and networks of LPS particles with bacterial shape. This suggested that LPS are organized in a network of particles which may serve as the skeleton of the cell wall.     

Reversible bacteriophage resistance by shedding the bacterial cell wall

Phages are highly abundant in the environment and pose a major threat for bacteria. Therefore, bacteria have evolved sophisticated defence systems to withstand phage attacks. Here, we describe a previously unknown mechanism by which mono- and diderm bacteria survive infection with diverse lytic phages. Phage exposure leads to a rapid and near-complete conversion of walled cells to a cell-wall-deficient state, which remains viable in osmoprotective conditions and can revert to the walled state. While shedding the cell wall dramatically reduces the number of progeny phages produced by the host, it does not always preclude phage infection. Altogether, these results show that the formation of cell-wall-deficient cells prevents complete eradication of the bacterial population and suggest that cell wall deficiency may potentially limit the efficacy of phage therapy, especially in highly osmotic environments or when used together with antibiotics that target the cell wall.     

Physiological, morphological, and physicochemical characterization of a novel Escherichia coli bacteriophage, phage MM

A double-stranded DNA containing, T even-like, Escherichia coli bacteriophage, called MM, has been isolated from the local sewage and purified by polyethylene glycol precipitation followed by banding on a cesium chloride three-step gradient. It yields a burst size of 75 particles per infected cell, and has an adsorption coefficient of 3.3 x 10(-10) cm3/min and a latent period of 45 min. Electron microscopy of phage MM reveals an isometric icosahedral head, 92 nm long and 81 nm wide, and a 112-nm-long contractile tail with six pairs of 40-nm-long fibers attached to its baseplate. Phage MM appears similar to E. coli phage T4 or Salmonella phage O1. The density of phage MM in cesium chloride is 1.515 g/ml, and its total mass is 144 MDa. Gel electrophoresis of purified MM capsids displays two major capsid proteins in approximately equimolar amounts and with apparent molecular masses of 38 and 15 kDa. Similarly, purified MM tails yield two major polypeptides with apparent molecular masses of 55 and 16 kDa, most likely representing the major tail sheath and tail tube polypeptides. Its double-stranded DNA has a G-C content of 50%, a length of 131 kilobases (kb), and a mass of 89 MDa.     

Isolation and Characterization of a Bacteriophage for Vibrio fetus

Bacteriophages were isolated from 22 of 38 strains of Vibrio fetus by an enrichment process, utilizing the donor and host strains growing together in fluid thioglycollate medium. One phage, V-45, isolated by the conventional lawn-spot method, was characterized by stability in broth, growth kinetics, and morphology. It was sensitive to rapid thermal inactivation, chloroform, and pH values above 6.5. Calcium was required for phage replication and stability in broth. Magnesium provided the best protection against thermal inactivation at 50 C in the pH range of 6.5 to 7.5. The minimum latent period was 135 min, rise time was 75 min, and average burst size was 35 plaque-forming units per infected cell. Phage V-45 resembled Bradley's morphological group B, having a long tail without contractile sheath. Dimensions were: head, about 50 nm; tail, about 7 by 240 nm; and tail lumen, 2 to 3 nm.     

Characteristics of φT, the Temperate Bacteriophage Carried by Bacillus megaterium 899a

Phage T was the only phage observed in lysates of Bacillus megaterium 899a induced with mitomycin C, 0.35 mug/ml. The phage adsorbed slowly to its host in nutrient agar, giving rise to plaques of varying sizes and turbidity. Only clear plaques were observed when the phage and host cells were preincubated in an adsorption buffer and plated under optimum conditions. Plaque turbidity was caused by either the addition of 0.5 x 10(-2) to 1.0 x 10(-2) M CaCl(2) to the phage assay medium, or by raising the incubation temperature to 34 C. Phage T purified on a CsCl gradient had a density of 1.48 g/ml in CsCl and the extracted phage DNA had a buoyant density in CsCl of 1.6975 g/ml, equivalent to 38.2% guanine plus cytosine. The phage was rapidly inactivated at 75 C and was unstable in the presence of chloroform at 4 C, but it was stable in buffer stored in ice. When stage I sporulating cells were induced with mitomycin C, phage were carried into spores which when germinated lyse with the release of phi T. The burst size on induction of early-log vegetative cells was 52, whereas the burst size of induced T(0) sporulating cells, diluted in fresh medium, was 47 for a sporulating strain and 140 for an asporogenous mutant. A typical phage T had a long, noncontracting tail 240 nm long, 9 to 11 nm wide, with a repeating disk unit along the tail, 4 nm in size center to center. The tail ended in a small disk (15 nm wide) which is presumably for attachment to the host. The hexagonal head measures 68 by 57 nm and is composed of donut-shaped units 9 nm in diameter.     

Isolation and characteristics of the bacteriophage from the vaccine strain Tohama phase I

Some properties of bacteriophage phi T isolated from the vaccine strain Bordetella pertussis Tohama phase I and propagated in Bordetella parapertussis 504 cells are presented. Phage phi T belongs to the IV group in accordance with Tikhonenko classification. The diameter of head and length of noncontractile tail sheath are 49.5 +/- 0.5 and 145 +/- 7 nm, respectively. Diameter of the tail sheath is 3.2 +/- 0.6 nm. Molecular mass of the phage DNA is 37 +/- 3 kb. Population of phi T phage is polymorphous and consists of particles the genomes or which vary from each other by the "insert" located 6.8 +/- 0.6 kb from the end of molecule. The blot hybridization has demonstrated that the bacteriophage genome is not inserted into the chromosome of the lysogenic strain. Autonomous location of the phage genome in the host cell is suggested. The temperature and hydrogen ions concentration effects on bacteriophage phi T stability were studied. The conditions for phage suspension storage are described.     

Biophysical characterization of Vitrio El Tor typing phage e5

Abstract Vibrio cholerae typing phage e5, which can lyse only the El Tor strains of V. cholerae , was characterized. The phage had a polyhedral head 51 nm in diameter and a short tail 13 nm in length. It contained 13 structural polypeptides, with the molecular mass of the major component being 50 kDa. Phage chromosome comprised a 38.5-kb linear double-stranded DNA molecule with unique termini, as determined by restriction fragment analysis and electron microscopy, and had a G+C content of 35.5%. A physical map was constructed with the restriction endonucleases Hae II and Hpa II. Adsorption of the phage to its host followed a biphasic kinetics and its intracellular growth was characterized by a latent period of 15 min and a burst size of 100 particles per infected cell. The phage was found to be moderately thermotolerant.     

Population dynamics ofAzospirillum brasilense and its bacteriophage in soil

Summary This study examined the ecology and interaction ofAzospirillum brasilense and its bacteriophage in soil. Four Chernozemic soils from Canada, a Latosol and three Podzolic soils from Brazil were assayed for phage. Only the Latosol containedA. brasilense phage. None of the soils contained phage for otherA. brasilense orA. lipoferum strains tested. Recovery of phage from soil depended on the growth of indigenous or added host cells. A phage isolated from the Latosol had a hexagonal head of 100 nm and a tail of 200 nm. This phage was morphologically distinct from previously described Azospirillum phage and its host range was limited toA. brasilense strains 29145 and 29711.Survival and recovery of phage added to phage-free soil was dependent on the phage, the initial phage population, the presence of host cells and nutrients, and the soil. Phage persisted in soils at undetectable levels for at least seven weeks, but were still able to interact with multiplying host cells and exhibit a 1000-fold increase in number. Phage required a host cell population of at least 100–1000 per g of soil in order to multiply. The phage burst detected under these conditions increased as the cell to phage ratio increased. Long term incubation studies showed that the activity of phage in soil closely followed the activity of host cells and thus both were manipulated by appropriate amendments to soil.     

Participation of the host protein(s) in the morphogenesis of bacteriophage P22

Summary Spontaneous mutants of S. typhimurium resistant to thiolutin are conditionally non-permissive for phage P22 development (Joshi and Chakravorty 1979). At 40° C non-infective phage particles are produced. Phage development in two nonpermissive hosts (18/MC4 and 153/MC4) has been studied in detail. The steps at which the phage morphogenesis is interfered with differ in the two mutants. The electron micrograph of the particles produced in the mutant 18/MC4 reveals the presence of normal-looking particles; these particles contain phage DNA, adsorb to the permissive host but fail to inject their DNA. The particles produced in the mutant 153/MC4 which fail to adsorb to the host are found to be tail fibre-less. These observations indicate the involvement of host protein(s) in phage P22 morphogenesis.     

Temperate bacteriophage ZF40 of Erwinia carotovora: phage particle structure and DNA restriction analysis

Structural organization of the temperate bacteriophage ZF40 of Erwinia carotovora was studied. Phage ZF40 proved to be a typical member of the Myoviridae family (morphotype A1). Phage particles consist of an isometric head 58.3 nm in diameter and a contractile 86.3-nm-long tail with a complex basal plate and short tail fibers (31.5 nm). Phage tail sheath, a truncated cone in shape, is characterized by specific packaging of structural subunits. The ZF40 phage genome is 45.8 kb in size, as determined by restriction analysis, and contains DNA cohesive ends. The ZF40 phage of Erwinia carotovora is assumed to be a new species of bacteriophages specific for enterobacteria.     

一株粘质沙雷氏菌烈性噬菌体污水分离及特性

[目的]以粘质沙雷氏菌(8039)为宿主菌从医院污水中分离噬菌体并对其基本生物学特点进行研究.[方法]四步法污水分离噬菌体;单、双层平板噬菌斑实验筛选烈性噬菌体并观察噬菌斑形态;纯化后2%磷钨酸染色电镜观察;手工法提取噬菌体核酸酶切后琼脂糖凝胶电泳分析;利用双层平板噬菌斑实验测定最佳感染复数和完成一步生长实验.[结果]从医院污水中成功分离出粘质沙雷氏菌烈性噬菌体一株(SM701),该噬菌体有一个正多面体立体对称的头部,头径约64nm,无囊膜,有一长尾,无收缩尾鞘,尾长约143nm;基因组核酸能被双链DNA内切酶BamH Ⅰ及Hind Ⅲ切开,大小约57kb;噬菌斑圆形透明,直径1mm左右(培养12h,),边界清楚;当感染复数(multiplicity of infection,MOI)为10时,子代噬菌体滴度较高;按照一步生长实验结果绘制出一步生长曲线,可知感染宿主菌的潜伏期是约为30min,爆发期约100min,平均爆发量约为630[结论]按照国际病毒分类委员会分类标准,该噬菌体属于长尾噬菌体科(siphoviridae)烈性噬菌体,按照Bradley和Ackermann形态分类法属于B1亚群;噬菌斑与周围红色细菌生长区,颜色差异明显,非常便于观察和计数;噬菌体头部大小和形态与呼吸道病毒中的呼肠病毒和腺病毒最为接近;国内尚未见粘质沙雷氏菌噬菌体相关报道.     

Synthesis and secretion of hepatitis B middle surface antigen by the methylotrophic yeast Hansenula polymorpha

The methylotrophic yeast, Hansenula polymorpha, has been developed as a host system for the synthesis of heterologous proteins. The middle surface antigen of hepatitis B virus (preS2-HBsAg) has been synthesized under the control of a methanol-regulated promoter derived from the methanol oxidase-encoding gene. The synthesized preS2-HBsAg protein was found to be secreted outside the cell membrane into the periplasm and further excreted into the culture medium following permeabilization of the cell wall with beta-1,3-glucanase (beta Glu). Cell cultures treated with beta Glu were able to continuously synthesize and secrete 22-nm particles of preS2-HBsAg into the medium for several days. The overall yield of antigen from treated cultures was found to be over threefold greater than that of untreated controls. The observation that complex supramolecular structures, such as the 22-nm particles of preS2-HBsAg, can be secreted by H. polymorpha and released into the medium, suggests the potential for these yeasts to be an alternative secretory host.     

Sucrose concentration in the growth medium affects the cell wall composition of tobacco pollen tubes

The cell wall of pollen tubes is organized in both spatial and temporal order to allow the pollen tube to grow according to external conditions. The deposition of methyl-esterified and acid pectins in addition to callose/cellulose occurs according to a series of temporally succeeding events. In this work, we attempted to determine how the composition of the external growth medium (in terms of osmolarity) could affect the deposition of cell wall components. Pollen tubes of tobacco were grown in a hypotonic medium and then analyzed for the distribution of pectins and callose/cellulose [as well as for the distribution of the enzyme callose synthase (CALS)]. The data indicate that pollen tubes grown in a hypotonic medium show changes of the initial growth rate followed by modification of the deposition of acid pectins and, to a lesser extent, of CALS. These observations indicate that, under the osmolarity determined by the growth medium, pollen tubes adapt their cell wall to the changing conditions of growth.     

OCCURRENCE OF A TEMPERATE CYANOPHAGE LYSOGENIZING THE MARINE CYANOPHYTE PHORMIDIUM PERSICINUM1

A temperate cyanophage was found to lysogenize the marine cyanophyte Phormidium persicinum (Reinke) Com. (Provasoli strain). The lytic cycle was induced by the addition of mitomycin C or by brief illumination with ultraviolet light. The lytic process observed under the electron microscope showed that phage particles appeared in a nucleoplasm region 15 to 24 h after the addition of mitomycin C. The induction of the lytic process occurred simultaneously in almost all cells of every trichome. Matured phage particles were released to the medium 30 to 50 h after the addition of mitomycin C. Phage particles isolated from algal lysates had a polyhedral head (about 40 nm in diameter) with a long (about 300 nm) and noncontractile tail. The most abundant protein, presumably a structural protein, had an apparent molecular mass of about 38 kDa. The genome size estimated from restriction analysis was about 50 kbp. Phage DNA was digested with several restriction endonucleases including Sau3AI and DpnI. However, MboI failed to digest the phage DNA, suggesting that the phage DNA is highly methylated. Southern blot analysis suggested that some part of the phage was in the lytic cycle in algal cells growing under normal conditions. A possible role of temperate cyanophages in the regulation of cyanophyte populations in the marine environment is discussed.     

Temperate Bacteriophage ZF40 of Erwinia carotovora: Phage Particle Structure and DNA Restriction Analysis

Structural organization of the temperate bacteriophage ZF40 of Erwinia carotovora was studied. Phage ZF40 proved to be a typical member of the Myoviridae family (morphotype A1). Phage particles consist of an isometric head 58.3 nm in diameter and a contractile 86.3-nm-long tail with a complex basal plate and short tail fibers (31.5 nm). Phage tail sheath, a truncated cone in shape, is characterized by specific packaging of structural subunits. The ZF40 phage genome is 45.8 kb in size, as determined by restriction analysis, and contains DNA cohesive ends. The ZF40 phage ofErwinia carotovora is assumed to be a new species of bacteriophages specific for enterobacteria.     

Phage formation in Staphylococcus muscae cultures. X. The relationship between virus synthesis,the release of bacterial ribonucleic acid,virus liberation,and cellular lysis

1. Under a variety of conditions in which cells are infected with one or a few virus particles and the host cells are killed, but no infective particles or virus material is formed as indicated by plaque count, one-step growth curve, or protein or desoxyribonucleic determinations, the cells neither lyse nor release ribonucleic acid into the medium. 2. The "killing" effect of S. muscae phage is separate from its lytic property. 3. The release of ribonucleic acid into the medium is not simply due to the killing of the cell by the virus, and ribonucleic acid is never found in the medium unless virus material is synthesized. 4. Infected cells of S. muscae synthesizing virus release ribonucleic acid into the medium before cellular lysis begins and before any virus is liberated. 5. The higher the phage yield the more ribonucleic acid is released into the medium before any virus is released. 6. Phage may be released from one strain of Staphylococcus muscae without cellular lysis, although bacterial lysis begins shortly after the virus is released. In another strain, infected under similar conditions, virus liberation occurs simultaneously with cellular lysis. 7. The viruses liberated from both bacterial strains appear to be the same in so far as they cannot be distinguished by serological tests, have the same plaque type and plaque size, and need the same amino acids added to the medium in order to grow. Furthermore, the virus liberated from one strain can infect and multiply in the other strain and vice versa. 8. It is suggested that virus synthesis, in S. muscae cells infected with one or a few phage particles, leads to a disturbance of the normal cellular metabolism, resulting in lysis of the host cell.     

一株产L-天冬氨酸酶大肠埃希氏菌的噬菌体分离和生物学特性

【目的】从大肠埃希氏菌CICC 11021S发酵液中分离一株噬菌体,对其生物学特性进行研究。【方法】采用双层平板法分离噬菌体CICC 80003;利用透射电镜观察噬菌体形态;提取噬菌体基因组,核酸内切酶处理并进行凝胶电泳;分析噬菌体最佳感染复数、一步生长曲线、p H和温度稳定性、宿主谱。考察CICC 80003对CICC 11021S生长和L-天冬氨酸酶活力的影响。【结果】CICC 80003噬菌斑圆形透明,有明显晕环;头部规则,直径约50-60 nm,尾部长约120-130 nm;基因组能被核酸内切酶Bam H I和Mlu I切开;最佳感染复数0.1,潜伏期5 min,裂解期25 min,平均裂解量约86个;最适p H值8.0;90°C温育15 min,噬菌体全部失活;能裂解大肠埃希氏菌和沙门氏菌的部分菌株。发生噬菌体污染时,CICC 11021S无法正常生长,基本检测不到L-天冬氨酸酶活力。【结论】CICC 80003属于长尾噬菌体科ds DNA噬菌体,液体环境中能够彻底裂解大肠埃希氏菌CICC 11021S。     

Localization and functional role of the pseudomonas bacteriophage 2 depolymerase.

The adsorption apparatus of phage 2 consits of a symmetrical base plate of snowflake appearance, composed of six droplike spikes 7.0 to 7.5 nm in length with a maximum diameter of 4.5 to 5.0 nm. The spikes are attached by their narrow ends to a central ring 7.0 to 7.5 nm in diameter. Phage 2 deopolymerase, a phage 2-induced hydrolytic enzyme, was found to be a structural protein of phage 2 or in close association with the base plate. Pdp1, a phage 2 mutant, possesses a polypeptide that is antigenically similar to the depolymerase, but devoid of hydrolytic activity. This polypeptide was found to be located in the region of the base plate of pdp1. Treatment of intact cells of strain BI with purified phage 2 depolymerase inhibited the adsorption of phage 2. When phage receptor-containing fractions of slime glycolipoprotein and lipopolysaccharide were hydrolyzed by the depolymerase, amino sugars were released, and the phage-inactivating activities of these fractions were lost. The depolymerase was also observed to induce the lysis of strain BI cells in hypotenic medium. The phage 2 depolymerase appears to play a role in adsorption and release of phage.