Host-Bacteriophage Interaction in Agrobacterium tumefaciens I. Characterization of Bacteriophage R4 and Physiological Changes in the Infected Host Cell

Infection of Agrobacterium tumefaciens B6, a tumor-producing plant pathogen, by bacteriophage R4, does not immediately shut off host deoxyribonucleic acid (DNA), ribonucleic acid (RNA), and protein synthesis. Viral DNA synthesis begins soon after infection, but the host DNA is not shut off until after 35 min; net RNA and protein synthesis are not inhibited until 30 min after infection. The pattern of synthesis of phage particles was confirmed by electron microscopy of thin sections during the infection cycle. The phage particle consists of a polyhedral head, 65 nm in diameter, and a long flexible tail 210 nm long and 10 nm wide with helically arranged subunits. By gel electrophoresis, four major protein components with the following molecular weights were found in the capsid: 72,000, 45,000, 28,000, and 14,500. The phage DNA has a molecular weight of 30 million and a guanine-cytosine content of 59%.     

Effect of Rifampicin and Chloramphenicol on Progeny Single-stranded DNA Synthesis of Bacteriophage ϕX174

Neither bacteriophage ?X174 single-stranded DNA synthesis nor phage growth was affected by rifampicin (200 μg/ml) once it started, whereas a low concentration of chloramphenicol (30 μg/ml) inhibited the phage growth when added in a late phase of infection. When rifampicin was added at a stage where double-stranded duplex (RF) DNA replication proceeded preferentially in the presence of chloramphenicol, or even after chloramphenicol was removed before the addition of rifampicin, both single-stranded DNA synthesis and phage growth were inhibited. These results suggest that RNA synthesis sensitive to rifampicin was necessary to initiate single-stranded DNA synthesis, but no longer needed once ?X174 DNA synthesis started.     

蛋白质起始的DNA病毒复制机制

DNA聚合酶在DNA合成过程中需要的引物包括RNA引物、DNA自我引物和蛋白质引物3种类型。新DNA链(如冈崎片段)的复制多是在DNA模板上合成一段RNA引物,细小病毒利用其基因组末端的反向末端重复序列(ITRs)自我折叠成DNA引物,而一些DNA、RNA病毒及真菌质粒起始复制反应的引物则是蛋白质。以感染原核生物的噬菌体Phi29和真核DNA病毒腺病毒为例,从复制过程所涉及的蛋白质、对复制原点的识别、复制起始反应、新链的延伸、复制终止过程等方面详细阐述DNA病毒由蛋白质引发的复制机制,并对已商品化的Phi29 DNA聚合酶产品多重置换扩增及单细胞测序等的应用以及基于噬菌体Phi29蛋白质起始的最小复制系统体外扩增异源DNA等最新的应用研究作相关总结介绍。     

Inhibitory action of erythromycin on bacteriophage SPO1 multiplication in sporulating cells of Bacillus subtilis 168

Summary Erythromycin (2–4 g/ml) was found to inhibit specifically multiplication of SPO1 in sporulating cells of an erythromycin-resistant, conditional asporogenous mutant of Bacillus subtilis 168 thy ^- trp ^-, Ery1040. In contrast, streptomycin (150–200 g/ml) which inhibits protein synthesis to a similar extent as erythromycin did not inhibit SPO1 multiplication severely, suggesting that the inhibition of SPO1 multiplication by erythromycin is not caused by an overall inhibition of protein synthesis. Neither phage DNA synthesis nor phage messenger RNA synthesis was affected appreciably under these conditions. However, the synthesis of three phage proteins that are synthesized 15 min after infection was preferentially inhibited by erythromycin. In addition, the inhibition of SPO1 multiplication has been correlated with the stimulation of host stable RNA synthesis exhibited by erythromycin. Possible mechanisms for the inhibition of SPO1 multiplication in Ery1040 cells are discussed.     

DNA,RNA and protein synthesis in ØLL55-infected Lactobacillus lactis

Lactobacillus lactis cells were infected with the bacteriophage ØLL55. The changes in DNA, RNA and protein synthesis were studied by following a long-term (over 3 h) incorporation of radioactive precursors into acid-insoluble material. Stimulation of DNA synthesis caused by phage occurred 30–35 min after infection and thymidine incorporation continued for about 70 min ceasing 10–20 min before the cells started to lyse. Cumulative (¹⁴C)-uracil incorporation into RNA continued at the level of uninfected cells for 30–40 min before starting to slow up. Protein synthesis in the infected cells followed that of a control culture for 40–50 min before the further incorporation of (¹⁴C)-leucine began to decrease.The additions of antibiotic inhibitors of RNA and protein synthesis (rifampicin and chloramphenicol, respectively) at various times before or during the prereplicative period showed that rifampicin, added up to 15 min after infection and chloramphenicol, added as late as 20–25 min after infection completely prevented the initiation of phage-genome replication. The later addition of these drugs did not prevent the out-burst of thymidine up-take, but promoted, however, a deduction in the initiations of new replication cycles. The results indicate that certain genes of ØLL55 genome must be expressed at the early stages of infection to confirm a proper onset and continuation of phage DNA replication.Abbreviations Rif rifampicin - CAL chloramphenicol - TCA trichloroacetic acid - cpm counts per minute     

Phage P22 helps phage MB78 to overcome blockage of DNA maturation in rifampicin-resistant host

Bacteriophage MB78, a virulent phage ofSalmonella typhimurium cannot grow in rifampicin-resistant mutant (rif-39) of the host having altered RNA polymerase. The temperate phage P22 which cannot multiply in presence of the virulent phage MB78 can, however, help MB78 to overcome replication inhibition in rif-39. The processing of concatemeric phage DNA to monomer is blocked in this nonpermissive host. Superinfection with P22 induces synthesis of at least five P22 specific polypeptides which help phage MB78 in the processing of the concatemeric DNA and maturation of phage particles.     

The replication of bacteriophage f1: Gene V protein regulates the synthesis of gene II protein

Two filamentous phage gene products are required for the replication of phage DNA. One of these, the gene II protein, is a site-specific endonuclease required for all phage-specific DNA synthesis. The other, the gene V protein, is a single-stranded DNA-binding protein required only for single-strand synthesis. Purified gene V protein, when added to an in vitro protein synthesizing system programmed by f1 DNA, specifically inhibits the synthesis of gene II protein. Inhibition seems to be translational, since synthesis of gene II protein from an RNA template is also inhibited by gene V protein. Gene V protein control of gene II expression can account for the regulation of the level of expression of the filamentous phage genome.     

Nucleic Acid Synthesis in Bacteriophage SPO2c1-Infected Bacillus subtilis

The synthesis of host macromolecules was shut off very slowly and incompletely by bacteriophage SPO2c(1). No change in the rate of incorporation of radioactive precursors into protein and ribonucleic acid (RNA) could be detected after infection, and the rate of incorporation of thymidine was increased only slightly. The relative proportions of phage and host species of nucleic acids at various intervals in the latent period were determined by means of nucleic acid hybridization. Phage-specific RNA populations synthesized early were different from those synthesized late in the latent period. Host deoxyribonucleic acid (DNA) replication continued until 8 to 10 min after SPO2c(1) infection and then decreased markedly as phage-specific DNA synthesis was initiated. Host DNA was not degraded to trichloroacetic acid-soluble fragments, and its nucleotides were not found in either newly synthesized intracellular phage DNA or in progeny phage particles. The average burst size of SPO2c(1) was approximately 200 plaque-forming units per cell.     

Inhibition of Bacteriophage ϕX174 Replicaiive-form DNA Replication by Rifampicin

?X174 DNA synthesis as well as phage production was inhibited by rifampicin when added in early phase of infection. Rifampicin did not inhibit the formation of parental duplex replicative-form, RF, and it inhibited the synthesis of progeny RF under conditions where protein synthesis was not necessary to be synthesized continuously. In addition, replication of parental RF into progeny RF was inhibited by rifampicin under conditions where a high concentration of chloramphenicol did not affect the replication. Consequently, it could be concluded that RNA synthesis other than that required for protein synthesis was necessary for both the initiation and continuation of RF replication.     

Repression of lipopolysaccharide biosynthesis in Escherichia coli by an antisense RNA of Acetobacter methanolicus phage Acm1

Lysogenic Acetobacter methanolicus strains carrying the prophage Acm1 were found to be unable to synthesize both the capsutar polysaccharide (CPS) and the O-specific side-chain of lipopolysaccharide (LPS) and to represent rough variants of the host bacterium. A 262 bp DNA fragment of phage Acm1, obviously required for interference with LPS biosynthesis, was cloned and expressed in Escherichia coli Independently of the O-type, transformation of various E. coli strains with the recombinant DNA resulted in a suppression of biosynthesis of the O-specific chains. The DNA fragment of phage Acm1 contained three very short open reading frames of 21, 24, and 36 bp. However, attempts to express phage-encoded peptides were not successful. Instead, the Acm1-derived DNA fragment was shown to code for the synthesis of a trans-acting RNA molecule of 97 nucleotides, designated lbi (L PS b iosynthesis-i nterfering) RNA. This RNA contains sequence complementarity to E. coli target RNA sequences and appears to have the ability to form intracellularly RNA hybrid duplexes with mRNA. The data presented in this study support the hypothesis that the phenotypic effect of conversion to rough-type LPS is accompanied by the expression of an antisense RNA of phage Acm1.