Comparative genomics of the T4-Like Escherichia coli phage JS98: implications for the evolution of T4 phages

About 130 kb of sequence information was obtained from the coliphage JS98 isolated from the stool of a pediatric diarrhea patient in Bangladesh. The DNA shared up to 81% base pair identity with phage T4. The most conserved regions between JS98 and T4 were the structural genes, but their degree of conservation was not uniform. The head genes showed the highest sequence conservation, followed by the tail, baseplate, and tail fiber genes. Many tail fiber genes shared only protein sequence identity. Except for the insertion of endonuclease genes in T4 and gene 24 duplication in JS98, the structural gene maps of the two phages were colinear. The receptor-recognizing tail fiber proteins gp37 and gp38 were only distantly related to T4, but shared up to 83% amino acid identity to other T6-like phages, suggesting lateral gene transfer. A greater degree of variability was seen between JS98 and T4 over DNA replication and DNA transaction genes. While most of these genes came in the same order and shared up to 76% protein sequence identity, a few rearrangements, insertions, and replacements of genes were observed. Many putative gene insertions in the DNA replication module of T4 were flanked by intron-related endonuclease genes, suggesting mobile DNA elements. A hotspot of genome diversification was located downstream of the DNA polymerase gene 43 and the DNA binding gene 32. Comparative genomics of 100-kb genome sequence revealed that T4-like phages diversify more by the accumulation of point mutations and occasional gene duplication events than by modular exchanges.     

Functional interactions of the genomes of Shigella sonnei phages and Escherichia coli phage T4 in mixed infection]

A comparative study of Shigella sonnei phages U and G and Escherichia coli phage T4 has shown that enzymes coded for by the Sh. sonnei phages can functionally substitute for some T4-coded products. This finding in indicative of an evolutionary relationship between T-even phages and disenteric phages U and G. The U phage is uncapable to compensate amber mutants for the genes that control the conversion of cytosine into 5-hydroxymethyl cytosine (5-HMC) and the glucosylation of the latter, which agrees with our earlier finding that the U phage DNA contains no 5-HMC. U and G phages are also found to exclude the T4 phage in the course of mixed infection.     

Role of superinfecting phage in lysis inhibition with phage T4 in Escherichia coli

Rutberg, Blanka (Karolinska Institutet, Stockholm, Sweden), and Lars Rutberg. Role of superinfecting phage in lysis inhibition with phage T4 in Escherichia coli. J. Bacteriol. 90:891-894. 1965.-The ability of bacteriophage T4 to induce lysis inhibition upon superinfection was investigated after various treatments of the phage. This ability was found not to be a property of the external protein part of the phage, nor was it dependent on the functional and possibly structural integrity of the phage genetic material.     

一株强裂解性大肠杆菌T1样噬菌体新成员的分离与鉴定

【目的】自然界中噬菌体种类繁多,其裂菌功能在针对细菌耐药方面具有潜在应用价值。不同噬菌体也呈现出显著的基因多样性及宿主特异性。从上海某猪场仔猪肠内容物样品中分离、纯化大肠杆菌的裂解性噬菌体,分析其生物学特性和病毒学特征,为探索应用噬菌体治疗细菌性感染提供研究材料。【方法】采用双层琼脂平板法分离、纯化噬菌体,观察噬菌斑特征,通过电镜观察噬菌体形态特征,测定其裂菌谱、最佳感染复数、一步生长曲线和生物学特性,进行噬菌体全基因组测序和遗传进化分析。【结果】分离、纯化获得一株能高效裂解大肠杆菌K-12菌株的噬菌体,命名为v B_Eco S_SH2(SH2),噬菌斑呈圆形、大而透明、边缘整齐。电镜观察SH2的头部呈二十面体立体对称,尾部较长。噬菌体的潜伏期为10 min,暴发期为60 min,裂解量高达121 PFU/感染细胞,其最佳感染复数为0.1。基因组测序和比对结果表明,SH2的核酸类型为ds DNA,基因组全长为49 088 bp,G+C%含量为45%,Gen Bank登录号为KY985004,结合电镜观察及BLASTp分析,确定其属于有尾噬菌体目长尾噬菌体科成员。同源性及进化分析表明,该噬菌体为大肠杆菌T1样噬菌体的新成员。【结论】分离鉴定了一株裂解效率极高的大肠杆菌T1样噬菌体,并确认其为T1样噬菌体新成员,为研究大肠杆菌噬菌体及其抗菌应用提供了新的实验材料。     

Rifampicin resistant DNA synthesis in phage T4 infected Escherichia coli

We have found that net DNA synthesis in T4 infected cells is rifampicin resistant. This finding implies that both the initiation of each T4 genome and its elongation are rifampicin resistant processes.     

Non-toxic expression in Escherichia coli of a plasmid-encoded gene for phage T4 lysozyme

The phage T4 gene coding for lysozyme has been cloned into a plasmid under control of the (trp/lac) hybrid tac promoter and expressed in Escherichia coli with no significant toxic effect to actively growing cells. E. coli D1210 (lacIq) transformed with this plasmid produced active T4 lysozyme at levels up to 2% of the cellular protein after induction with isopropyl-beta-D-thiogalactoside. A strain producing active lysozyme was shown to be under a selective disadvantage when co-cultured with a similar strain producing inactive lysozyme. Purified strains, however, are reasonably stable in culture and under normal storage conditions.     

Campylobacter jejuni group III phage CP81 contains many T4-like genes without belonging to the T4-type phage group: implications for the evolution of T4 phages

CP81 is a virulent Campylobacter group III phage whose linear genome comprises 132,454 bp. At the nucleotide level, CP81 differs from other phages. However, a number of its structural and replication/recombination proteins revealed a relationship to the group II Campylobacter phages CP220/CPt10 and to T4-type phages. Unlike the T4-related phages, the CP81 genome does not contain conserved replication and virion modules. Instead, the respective genes are scattered throughout the phage genome. Moreover, most genes for metabolic enzymes of CP220/CPt10 are lacking in CP81. On the other hand, the CP81 genome contains nine similar genes for homing endonucleases which may be involved in the attrition of the conserved gene order for the virion core genes of T4-type phages. The phage apparently possesses an unusual modification of C or G bases. Efficient cleavage of its DNA was only achieved with restriction enzymes recognizing pure A/T sites. Uncommonly, phenol extraction leads to a significant loss of CP81 DNA from the aqueous layer, a property not yet described for other phages belonging to the T4 superfamily.     

A morphologic study of filamentous phage infection of Escherichia coli using biotinylated phages

Using biotinylated phage (BIO-phages), we observed the infection of filamentous phages into Escherichia coli JM109 morphologically. BIO-phages and BIO-phage-derived proteins, mainly pVIII, were detected in E. coli by using the avidin-biotin-peroxidase complex method with electron microscopy. Infected cells revealed positive staining on the outer and inner membranes and in the periplasmic space. Some cells showed specific or predominant staining of the outer membrane, whereas others showed predominant staining of the inner membrane or equivalent staining of the outer and inner membranes. The periplasmic spaces in some infected cells were expanded and filled with reaction products. Some cells showed wavy lines of positive staining in the periplasmic space. BIO-phages were detected as thick filaments or clusters covered with reaction products. The ends of the infecting phages were located on the surface of cells, in the periplasmic space, or on the inner membrane. These findings suggest that phage major coat proteins are integrated into the outer membrane and that phages cause periplasmic expansion during infection.     

Complete Genome Sequence of T4-Like Escherichia coli Bacteriophage HX01

Phage T4 is among the best-characterized biological systems (S. Kanamaru and F. Arisaka, Seikagaku 74:131-135, 2002; E. S. Miller et al., Microbiol. Mol. Biol. Rev. 67:86-156, 2003; W. B. Wood and H. R. Revel, Bacteriol. Rev. 40:847-868, 1976). To date, several genomes of T4-like bacteriophages are available in public databases but without any APEC bacteriophages (H. Jiang et al., Arch. Virol. 156:1489-1492, 2011; L. Kaliniene, V. Klausa, A. Zajanckauskaite, R. Nivinskas, and L. Truncaite, Arch. Virol. 156:1913-1916, 2011; J. H. Kim et al., Vet. Microbiol. 157:164-171, 2012; W. C. Liao et al., J. Virol. 85:6567-6578, 2011). We isolated a bacteriophage from a duck factory, named HX01, that infects avian pathogenic Escherichia coli (APEC). Sequence and morphological analyses revealed that phage HX01 is a T4-like bacteriophage and belongs to the family Myoviridae. Here, we announce the complete genome sequence of phage HX01 and report the results of our analysis.     

Adenylate kinase of Escherichia coli, a component of the phage T4 dNTP synthetase complex

Adenylate kinase, which catalyzes the reversible ATP-dependent phosphorylation of AMP to ADP and dAMP to dADP, can also catalyze the conversion of nucleoside diphosphates to the corresponding triphosphates. Lu and Inouye (Lu, Q., and Inouye, M. (1996) Proc. Natl. Acad. Sci. U. S. A. 93, 5720-5725) showed that an Escherichia coli ndk mutant, lacking nucleoside diphosphate kinase, can use adenylate kinase as an alternative source of nucleoside triphosphates. Bacteriophage T4 can reproduce in an Escherichia coli ndk mutant, implying that adenylate kinase can meet a demand for deoxyribonucleoside triphosphates that increases by up to 10-fold as a result of T4 infection. In terms of kinetic linkage and specific protein-protein associations, NDP kinase is an integral component of T4 dNTP synthetase, a multienzyme complex containing phage-coded enzymes, which facilitates the synthesis of dNTPs and their flow into DNA. Here we asked whether, by similar criteria, adenylate kinase of the host cell is also a specific component of the complex. Experiments involving protein affinity chromatography, immunoprecipitation, optical biosensor measurements, and glutathione S-transferase pulldowns demonstrated direct interactions between adenylate kinase and several phage-coded enzymes, as well as E. coli nucleoside diphosphate kinase. These results identify adenylate kinase as a specific component of the complex. The rate of DNA synthesis after infection of an ndk mutant was found to be about 40% of the rate seen in wild-type infection, implying that complementation of the missing NDP kinase function by adenylate kinase is fairly efficient, but that adenylate kinase becomes rate-limiting for DNA synthesis when it is the sole source of dNTPs.