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.     

Bacteriophages of Clostridium saccharoperbutylacetonicum

Antiphage sera were produced in rabbits against the HM-phages of Clostridium saccharoperbutylacetonicum; on the basis of cross-neutralization experiments with homologous and heterologous antisera, the twelve HM-phages were classified into three serological groups, termed I, II and III. Group I contained seven phages, i.e., HM 1, HM 2, HM 8, HM 9, HM 10, HM 11 and HM 12. Group II contained four phages, i.e., HM 3, HM 4, HM 5 and HM 6, and group III one phage, i.e., HM 7. This classification was in accord with morphological one that was reported in the preceding paper. By using the K value of antisera, the degree of serological relatedness among the phages within groups I and II was demonstrated. On the bases of serological similarities and of dissimilarities in host-rang specificity, the phages of groups I and II are considered as host range mutants derived from an identical ancestor, HM 1 and HM 3, respectively.     

Bacteriophages of Clostridium saccharoperbutylacetonicum

The three representative HM-phages (HM 2, HM 3 and HM 7) of Clostridium saccharoperbutylacetonicum were used.

The adsorption rate of the phages HM 2 and HM 7 on the host bacteria was high, whereas that of the phage HM 3 was lower. The adsorption rates of the phages were maximum at pH 5.9~6.6, 30°C.

One-step growth experiment was successfully adapted to the phage-host systems of anaerobic bacteria by bubbling pure nitrogen gas into the medium in the growth tube. The growth characteristics of the HM-phages were investigated by using this technique. The minimal latent periods for phages HM 2, HM 3 and HM 7 were about 45, 90 and 120 minutes, respectively. The corresponding average burst sizes were approximately 500, 100 and 20, respectively. The growth of the phages was optimal at pH 6.2, 30~33°C. The phages failed to grow at 37°C, although the host bacteria multiplied at that temperature. By using a defined medium, it was found that calcium ion was not essential for the growth of the HM-phages.     

Studies on Fungal Tannase

The possibility that selective inhibition of phage by antibiotic may be achieved by using bacterial mutant resistant to the antibiotic was investigated in the system of HM-phages of Clostridium saccharoperbutylacetonicum, a butanol-producing bacterium.

Consequently, it was found that Oxytetracycline, using the antibiotic-resistant mutant as host, inhibited selectively the growth of HM-phages. The bacterial mutant termed type A (one-step mutant resistant to 30 μg/ml of Oxytetracycline) did not permit the growth of HM-phages (HM 2 and HM 3) in the presence of the antibiotic (ca. 10 μg/ml), though it permitted the growth of the phages in the absence of the antibiotic.

An analysis of the mode of action of Oxytetracycline in HM 2-phage system revealed the following, (i) The antibiotic had a slight phagicidal action, (ii) It did not prevent the phage adsorption, (iii) It inhibited the protein synthesis in phage-infected cells, (iv) It inhibited the lysis of infected cells. Active phages were, however, not detected when the lysis-inhibited cells were artificially lysed.

Another type of bacterial mutant was also encountered. In this mutant termed type B the development of resistance to Oxytetracycline (30 μg/ml) was associated with a simultaneous loss of sensitivity to particular phages (HM 2 group).     

Some Properties of Five New Salmonella Bacteriophages

Five bacteriophages were isolated from lysogenic strains of Salmonella potdam. On the basis of plaque morphology, thermostability, serology, host range, one-step growth parameters, and phage morphology, they were divided into three groups: group A, phages P4 and P9c; group B, phages P3 and P9a; and group C, phage P10. Group A phages had a hexagonal head 55 nm in diameter with a short tail 15 nm long. These phages were particularly characterized by high thermostability, lack of serological relationship with any of the other phages, and restriction of lysis to other Salmonella strains of Kauffmann-White group C(1). Group B phages had a head identical in size and shape to that of the A phages, but they possessed a tail 118 nm long with a contractile sheath. A unique feature was the occurrence of tail fibers at the end of the core rather than at the base of the sheath. These phages were considerably less thermostable, had extended host ranges, and were serologically distinct from each other but unrelated to the A phages. The group C phage, P10, had a head identical to that of the A and B phages. It had a tail 95 nm in length, with tail fibers attached to a base plate at the end of a contractile sheath. P10 was highly sensitive to heat, lysed only smooth strains of Salmonella, and showed a degree of serological relationship to both B phages. The relationship of these phage groups to previous Salmonella phage grouping schemes is discussed.     

Characterization of a Temperate Phage and Four Bacteriocins Produced by Nonpathogenic Clostridium Species

We previously reported the isolation of a temperate phage (named KT) and several bacteriocins (named clostocins) from strains of nonpathogenic Clostridium species. Later, the induction and some properties of the phage and four clostocins (A, B, C and D) were examined.

The phage was induced by UV light and mitomycin C. The phage had a polygonal head (about 85mμ in diameter) and a tail with contractile sheath (about 100mμ in length). Some other properties of the phage were also studied; plaque morphology, stability in salt solution, inactivation by UV light, pH stability, thermal inactivation, host-range and lysis of infected culture.

Clostocins A and D were partially induced by UV light and mitomycin C, whereas that of B and C were not. All clostocins failed to pass through a dialysis membrane, and were insensitive to UV light and to ribo- and deoxyribonuclease. They were destroyed by some proteolytic enzymes, but differences in degree of their susceptibility were observed among them. Clostocins A and D were very thermo-stable, whereas B and C were relatively thermo-labile. Clostocins A and D acted on some strains in the genus Clostridium, whereas B and C did on many strains in the family Bacillaceae.

There was no demonstrable serological relationship between phage KT and clostocin A, although they seemed to adsorb on the same bacterial receptor.     

Morphological, Host Range, and Genetic Characterization of Two Coliphages

Two coliphages, AR1 and LG1, were characterized based on their morphological, host range, and genetic properties. Transmission electron microscopy showed that both phages belonged to the Myoviridae; phage particles of LG1 were smaller than those of AR1 and had an isometric head 68 nm in diameter and a complex contractile tail 111 nm in length. Transmission electron micrographs of AR1 showed phage particles consisting of an elongated isometric head of 103 by 74 nm and a complex contractile tail 116 nm in length. Both phages were extensively tested on many strains of Escherichia coli and other enterobacteria. The results showed that both phages could infect many serotypes of E. coli. Among the enterobacteria, Proteus mirabilis, Shigella dysenteriae, and two Salmonella strains were lysed by the phages. The genetic material of AR1 and LG1 was characterized. Phage LG1 had a genome size of 49.5 kb compared to 150 kb for AR1. Restriction endonuclease analysis showed that several restriction enzymes could degrade DNA from both phages. The morphological, genome size, and restriction endonuclease similarities between AR1 and phage T4 were striking. Southern hybridizations showed that AR1 and T4 are genetically related. The wide host ranges of phages AR1 and LG1 suggest that they may be useful as biocontrol, therapeutic, or diagnostic agents to control and detect the prevalence of E. coli in animals and food.     

Bacteriophages of Clostridium saccharoperbutylacetonicun

Some characteristics of the twelve phages were given. Phages were obtained from the twelve abnormal broths in the industrial production of acetone and butanol by use of Cl. saccharoperbutylacetonicum, producing a high proportion of butanol. These new phages were designated as HM and numbered consecutively in the order of appearance. The HM-phages were highly specific for the strains of this bacterium. Each phage could be distinguished from the others by its differential host specificity against various phage-resistant mutants of this bacterium. The HM-phages were not temperate ones under our experimental conditions. They were divided into two groups on the basis of their stability in the salts solution. While one group was slightly less stable in 0.85 percent saline or 0.067 m phosphate buffer, the other was strikingly unstable. The addition of magnesium ion was effective for increase in stability of both groups.

The double-layer method similar to that described by Adams, with modifications to incubate the plates anaerobically, was applied to assay the phages of butanol-producing bacteria, Cl. saccharoperbutylacetonicum, after the studies on some factors influencing the plaque formation. Factors influencing the number and size of plaque were as follows; agar concentration and amount of overlayer medium, pH of media, age and number of host cells, temperature and period of incubation, and so on. Plaques formed by this method were medial size and easily counted. Assay of viable cells of this anaerobic bacterium was also possible by this method with slight modifications.     

Lysogeny among mycobacteria

Our investigations to detect naturally lysogenic strains of mycobacteria were limited to 1 strain ofMycobacterium smegmatis, 4 strains ofMycobacterium borstelense var.niacinogenes, and to 5 strains ofMycobacterium marinum (Syn:Mycobacterium balnei), all together 10 strains. They were chosen because as a sign of lysis they secrete a large quantity of cytoplasmatic components (nucleic acids proteins, amino acids etc.) into the fluid medium (for instance phosphate buffer), in which they are suspended. In a first series of experiments culture filtrates were tested on 84 strains of slowly and rapidly growingMycobacterium species as indicator strains. Using this method free phage particles were only found in the culture filtrate of 1 strain,Mycobacterium smegmatis SN 46, isolated from a patient with achalasia. Phage particles could not be found in the filtrates of the other 9 probably lysogenic strains. In a second series of experiments more closely related indicator strains were used. The 10 probably lysogenic strains were cultured in bovine serum or antiphage-antiserum containing medium and single selected colony cultures a small part of which showed sensitivity to the filtrates. The released and adapted phages, designated as B₂₄, B₃₀, B₃₂, B₃₃, B₃₄ and B₃₅ have a very narrow host range. The plaques are very small and turbid. On electron micrographs the temperate phages B₂₄, B₃₀ and B₃₅ exhibit the typical head-tail morphology. The head of the temperateborstelense var.niacinogenes phage B₃₀ is 45 nm in diameter, the tength of tail is about, 120nm. The average dimensions of the long head ofsmegmatis phage B₂₄ are 40 × 80 nm, the tail is about 160 nm long. The balnei phage B₃₅ is very similar morphologically to phage B₃₀. The head is about 50 nm in diameter, the length of tail about 160 nm. The phage sensitive variants are not “carrier” strains. Their phage sensitivity is not a stable property. After several culture passages in serum-free medium the variants regain their phage immunity completely and release phages like the lysogenic parent strains. The sensitive variants must therefore be considered to be also lysogenic. TheMycobacterium borstelense var.niacinogenes phages are serologically very related. Dedicated to Academician Ivan Málek on the occasion of his 60th birthday     

Bacteriophages of Clostridium saccharoperbutylacetonicum

The HM-phages contained only deoxyribonucleic acid (DNA) as the nucleic acid moiety. The DNA was extracted from the phages by the phenol method. The content of guanine plus cytosine (%G + C) in the DNA was determined by paper chromatography and by thermal denaturation method. The values of HM 2 (group I), HM 3 (group II) and HM 7 (group III) were 35, 30 and 29, respectively.

The DNA was also isolated from the two host strains of Clostridium saccharoperbutylacetonicum by the method of Marmur and by Saito and Miura’s phenol extraction method. The %G + C of the DNA was 31. No unusual bases were detected in either the bacterial or phage DNA.     

Bacteriophages of l-Glutamic Acid-Producing Bacteria

Deoxyribonucleic acids were isolated from Brevibacterium lacto fermentum No. 2256 and its four representative phages belonging to different serological groups, i.e., P465 (group I), P 468 II (group II), Ap 85 III (group III) and P4 (group IV), by phenol extraction.

DNA’s isolated from the four phages contained only usual four bases, i.e., guanine, adenine, cytosine and thymine. The G-C content of the phage DNA was determined by thermal denaturation method (T_m); the values of P465, P 468 II, Ap 85 III and P4 were 54.0, 54.6, 56.6 and 55.3%, respectively. Sedimentation coefficient was measured by ultracentrifugal analysis using ultraviolet optics; s_20,w of the phage DNA’s were 15.5 to 31.8 s.

Unusual bases were not detected also in the host bacterial DNA. The G-C content of the bacterial DNA determined by paperchromatography was 55.1% which came very close to the G-C content derived from the T_m.

Morphological properties of the P- and Ap-series phages described in previous papers were examined by means of electron microscopy, analytical centrifugation, CsCl density-gradient centrifugation and ultrafiltration.

In view of the buoyant density of phage particles, fourteen Brevibacterium phages were classified into four groups, i.e., the phages under group I had buoyant density of 1.511 to 1.514g cm^?3, and those under groups II, III and IV, densities of 1.482, 1.492 and 1.508 g cm^?3, respectively; and above grouping corresponded to that by the serological chracteristics of the phages.

Electron microscopic observation by means of shadow-casting or negative staining recognized all the phages as tadpole-shaped; their particles having polyhedral head (40 ~ 70 mμ in diameter) and long tail (80 ~ 275 mμ in length).

In relation to particle sizes of the phages as estimated by all of above-mentioned methods, no significant differences were observed between the sizes calculated from ultrafiltration and those obtained directly from electron micrographs by negative staining.     

Electron microscopy of virulent phages for Streptococcus lactis.

Electron microscopic studies were made on eight virulent Streptococcus lactis bacteriophages. These phages were taken as representative of eight host range groups established in a study of 75 phage isolates and 253 hosts (213 S. lactis, 22 S. cremoris, 18 S. diacetilactis). The phages studied were shown to have an isometric hexagonal head and noncontractile tails, usually several times longer than the head diameter. The virus heads were octahedral. The phages investigated represented three morphological types on the basis of head diameter , tail thickness, and tail length. These dimensions were approximately: for type I phages, 63, 172, and 11 nm, respectively; type II, 73, 200, and 20 nm, respectively; and type III, represented here by a single phage, 98, 551, and 12 nm, respectively. The tail surface revealed a different arrangment of the structural subunits which lent a helical appearance to the tails of type I and II phages and a guaffered tube appearance to the tail of type III phage. The number of turns along the tail axis, turn length, axial pitch, and helix angle were: type I, 32, 12 to 13 nm, 7.14 nm, and 11 degrees 43', respectively; type II, 24, 24, to 28 nm, 40.00 nm, and 32 degrees 30', respectively; and type III, 120, 12 nm, and no visible slope towards the axis. The morphology types showed complete correlation with serological groups, but not with groups based on host range pattern.     

Ultrastructure of Listeria monocytogenes bacteriophages]

No morphological differences were found among the 10 Listeria phages suspensions examined. The polyhedric head appears to be about 62-66 nm in diameter, the tail devoided of contractile sheath measures 260-280 X 10 nm. The phage adsorption is observed on the cell-wall of Listeria.     

Two Novel Bacteriophages of Thermophilic Bacteria Isolated from Deep-Sea Hydrothermal Fields

Bacteriophages of thermophiles are of great interest due to their important roles in many biogeochemical and ecological processes. However, no virion has been isolated from deep-sea thermophilic bacteria to date. In this investigation, two lytic bacteriophages (termed Bacillus virus W1 and Geobacillus virus E1) of thermophilic bacteria were purified from deep-sea hydrothermal fields in the Pacific for the first time. Bacillus virus W1 (BVW1) obtained from Bacillus sp. w13, had a long tail (300nm in length and 15 nm in width) and a hexagonal head (70 nm in diameter). Another virus, Geobacillus virus E1 (GVE1) from Geobacillus sp. E26323, was a typical Siphoviridae phage with a hexagonal head (130 nm in diameter) and a tail (180 nm in length and 30 nm in width). The two phages contained double-stranded genomic DNAs. The genomic DNA sizes of BVW1 and GVE1 were estimated to be about 18 and 41 kb, respectively. Based on SDS-PAGE of purified virions, six major proteins were revealed for each of the two phages. The findings in our study will be very helpful to realize the effect of virus on thermophiles as well as the communities in deep-sea hydrothermal fields.     

一株嗜麦芽窄食单胞菌裂解性噬菌体的分离及生物学特性

【背景】嗜麦芽窄食单胞菌是一种广泛存在于医院和自然环境中的条件致病菌,其分离率与耐药率逐年增加。噬菌体是一类能特异性感染并杀灭细菌的病毒。【目的】分离一株新型嗜麦芽窄食单胞菌噬菌体,为临床嗜麦芽窄食单胞菌感染及防控提供补充手段。【方法】以临床分离的嗜麦芽窄食单胞菌为宿主菌,用点板法从医院污水中分离鉴定噬菌体;用双层平板法测定噬菌体效价及一步生长曲线等生物学特性;用透射电镜观察噬菌体形态;提取噬菌体基因组DNA进行全基因组测序,拼接噬菌体基因组并进行注释。【结果】分离到一株嗜麦芽窄食单胞菌裂解性噬菌体,命名为v B＿Sma S＿P11。该噬菌体感染宿主菌的潜伏期小于5 min,快速增殖60 min后达到平稳期,暴发量为100 PFU/cell。透射电镜观察该噬菌体为长尾噬菌体,具有典型的二十面体头和不可收缩的尾部。基因组测序结果表明,该噬菌体基因组全长44 600 bp,GC含量为63.7%,无抗生素耐受基因、毒力基因和t RNA,与NCBI数据库中所有已知嗜麦芽窄食单胞菌噬菌体相比同源性很低。基因组注释显示该噬菌体含有66个开放阅读框(open reading frame,ORF),其...     

Morphological,host range,and genetic characterization of two coliphages

Two coliphages, AR1 and LG1, were characterized based on their morphological, host range, and genetic properties. Transmission electron microscopy showed that both phages belonged to the Myoviridae; phage particles of LG1 were smaller than those of AR1 and had an isometric head 68 nm in diameter and a complex contractile tail 111 nm in length. Transmission electron micrographs of AR1 showed phage particles consisting of an elongated isometric head of 103 by 74 nm and a complex contractile tail 116 nm in length. Both phages were extensively tested on many strains of Escherichia coli and other enterobacteria. The results showed that both phages could infect many serotypes of E. coli. Among the enterobacteria, Proteus mirabilis, Shigella dysenteriae, and two Salmonella strains were lysed by the phages. The genetic material of AR1 and LG1 was characterized. Phage LG1 had a genome size of 49.5 kb compared to 150 kb for AR1. Restriction endonuclease analysis showed that several restriction enzymes could degrade DNA from both phages. The morphological, genome size, and restriction endonuclease similarities between AR1 and phage T4 were striking. Southern hybridizations showed that AR1 and T4 are genetically related. The wide host ranges of phages AR1 and LG1 suggest that they may be useful as biocontrol, therapeutic, or diagnostic agents to control and detect the prevalence of E. coli in animals and food.     

Clostridium sordellii bacteriophage active on Clostridium difficile

Among five strains of Clostridium difficile and 39 strains of Cl. sordellii tested, one Cl. difficile phage and four Cl. sordellii phages were found to be lytic for Cl. difficille strain 2. The five phages were similar in morphology, showing a polyhedral head of 60 nm in diameter, a tail of 105–120 nm, a contractile tail sheath and a base plate. They were sensitive to heat (60°C/10 min) and stable at 4°C for at least 6 months. As the phage donor strains and the indicator strain were not cytotoxigenic, no phage-infected culture of Cl. difficile 2 was able to produce cytotoxin.     

Studies on Temperate Phages of Lactobacillus salivarius

Twenty-three temperate phages of Lactobacillus salivarius isolated from human feces were studied as to their morphological, biological, and serological properties. (1) Among 30 strains of L. salivarius tested, 23 strains were lysed by induction with mitomycin C (MC). In all these lysates, phage particles were detected by electron microscopic examination. (2) These phages were morphologically divided into three groups: particles with a regular hexagonal head and a long flexible tail; particles having a regular hexagonal head with or without a short tail-like structure; particles with an elongated head and a long noncontractile tail. (3) Only two, phage 223 having an elongated head and phage 227 with a regular hexagonal head and a long noncontractile tail, produced tiny and very turbid plaques on several host bacteria. Six phages could produce only inhibition zones, ranging from complete inhibition through partial inhibition to normal growth by a serial dilution spot test. (4) All these killer particles could also inhibit the growth of their producer cells. (5) A serological relationship was observed between temperate phages and killer particles, and this was somewhat consistent with the morphological groupings.     

DNA relatedness among bacteriophages of the morphological group C3

Six bacteriophages with an elongated head and a short, noncontractile tail were compared by DNA-DNA hybridization, seroneutralization kinetics, mol% G+C and molecular weight of DNA, and host range. Three phage species could be identified. Phage species 1 containedEnterobacter sakazakii phage C2,Erwinia herbicola phages E3 and E16P, andSalmonella newport phage 7–11. These phages had a rather wide host range (4 to 13 bacterial species). DNA relatedness among species 1 phages was above 75% relative binding ratio (S1 nuclease method, 60°C) when labeled DNA from phage C2 was used, and above 41% when labeled DNA from phage E3 was used. Molecular weight of DNA was about 58×10⁶ (C2) to 67 ×10⁶ (E3). The mol% G+C of DNA was 43–45. Anti-C2 serum that neutralizes all phages of species 1 does not neutralize phages of the other two species. Species 2 contains only coliphage Esc-7-11, whose host range was only oneEscherichia coli strain out of 188 strains of Enterobacteriaceae studied; it was unrelated to the other two species by seroneutralization and DNA hybridization. DNA from phage Esc-7-11 had a base composition of 43 mol% G+C and a molecular weight of about 45×10⁶. Species 3 contains onlyProteus mirabilis phage 13/3a. Its host range was limited to swarmingProteus species. Species 3 was unrelated to the other two species by seroneutralization and DNA hybridization. DNA from phage 13/3a had a base composition of 35 mol% G+C and molecular weight of about 53×10⁶. It is proposed that phage species be defined as phage nucleic acid hybridization groups.     

一株铅黄肠球菌噬菌体的生物学特性和全基因组分析

【目的】铅黄肠球菌是医源感染的机会致病菌,可引起危及生命的败血症、脑膜炎等,但针对其噬菌体的研究尚属空白。噬菌体作为细菌病毒,具有宿主特异性。本研究首次分离到可培养的铅黄肠球菌烈性噬菌体,对其基因组序列的分析和其他特征研究为进一步探讨噬菌体与宿主的作用机制及治疗应用提供参考。【方法】噬菌体Ecf_virus_SZ01以健康人粪便中分离的铅黄肠球菌(DO55)作为宿主菌,分离自深圳市南山区未经处理的生活污水样本,利用透射电镜观察噬菌体形态并对其生物学特征和基因组特点进行研究。【结果】透射电镜显示,噬菌体Ecf_virus_SZ01头部直径约为106 nm,尾部直径约为150 nm,尾长且无伸缩性尾鞘,属长尾噬菌体科;该噬菌体的最佳感染复数为0.01;一步生长曲线显示,潜伏期约为30 min,每个受感染细胞产生子代的平均数量为50 PFU/cell;抑菌曲线显示MOI=0.01时对宿主菌具有很好的抑制效果;宿主特异性强,不能实现跨属侵染;测序结果显示其基因组为dsDNA,长度为59 409 bp,GC含量为43.2%;该噬菌体共有102个开放阅读框,BLASTn比对显示该噬菌体与NCBI数据库中其他噬菌体相似性极低。【结论】首次分离到宿主为铅黄肠球菌的噬菌体,具有潜伏期短、裂解能力强、宿主专一的特征,基因组与数据库中现有噬菌体相比十分新颖,并对其生物学特性和基因组进行了分析。