Membrane protein biosynthesis in bacteriophage BF23-infected Escherichia coli.

When Escherichia coli is infected with bacteriophage BF23, two new proteins with molecular weights greater than 10,000, as indicated by polyacrylamide gel electrophoresis, are found associated with the cells' membranes. One of these, found associated with both the inner and outer membrane, has a molecular weight of about 55,000 and is regulated by the A1 gene of this phage, a gene found on the spontaneously injected 8% piece of BF23 DNA, DNA that codes for the synthesis of proteins necessary for the injection of the whole phage genome. The other protein, often undetected in whole membrane preparations, is found exclusively associated with the inner membrane. Evidence indicates that this protein is also regulated by the initially injected 8% piece of the DNA.     

Terminally redundant deletion mutants of bacteriophage BF23.

Deletion mutants of bacteriophage BF23 were isolated and the positions of the deletions were determined. Two different deletable regions were detected: one in the same region as previously reported for bacteriophage T5, which is closely related to BF23; and the other within both terminal repetitions. The former deletable region lay between positions 0.31 and 0.36, which represented the fractional lengths of the BF23 ( + ) DNA as measured from its left end. The latter deletion was evenly divided between the two terminal repetitions. The deletion in the left terminal repetition lay between positions 0.044 and 0.078 and was repeated in the corresponding region of the right terminal repetition between positions 0.966 and 1.0. The size of the DNA transferred to host cells during the first step of DNA transfer by BF23 carrying deletions in the terminal repetitions of its DNA was less than the size of DNA transferred during the first step by wild-type BF23 by an amount equal to the size of the deletion in each terminal repetition. This finding suggests the existence of a specific mechanism for delineating the position at which the first step of DNA transfer is stopped.     

Abortive infection by bacteriophage BF23 due to the colicin Ib factor. II. Involvement of pre-early proteins

The mechanism by which the growth of phage BF23 is arrested in cells carrying colicinogenic factor Ib involves certain phage-specific pre-early proteins. BF23 induces the extensive formation of proteins lc and ld, but very little formation of protein le, whereas BF23h^? (a mutant that is not arrested in cells carrying colicinogenic factor Ib) induces very small amounts of proteins lc and ld, but extensive amounts of protein le. Proteins lc and ld may be oligomers of protein le, and it is the presence of these putative oligomers that is necessary for the arrest of phage growth.     

Arrangement of the single-stranded fragments in E. coli bacteriophage BF23 DNA

Bacteriophage BF23st(0) DNA was denatured with alkali and fractionated by agarose gel electrophoresis. Seven single-stranded fragments (designated Fragments I--VII) were identified as the major constituents of the phage DNA. The presence of several minor fragments which represent minor populations of the phage genome was also observed. The largest fragment (Fragment I) represents the intact strand of phage DNA, whereas the other fragments form the complementary strand. Thus, BF23st(0) DNA carries single-strand interruptions in only one strand. The arrangement of the major fragments in the nicked strand was determined by use of gamma-exonuclease and agarose gel electrophoresis. From the mode of action of this nuclease, and from the kinetics of release or disappearance of the fragments, the polarity of the fragments in BF23st(0) DNA was specified. In addition, the presence of two types of major phage populations differing in their composition of the fragments was demonstrated. One type has an additional nick (yielding Fragment IV and Fragment V) in a specific fragment (Fragment II) of other type.     

Physical map of bacteriophage BF23 DNA: restriction enzyme analysis.

Cleavage maps of bacteriophage BF23 DNA have been constructed for the restriction endonucleases SalI (3 fragments), BamHI (5 fragments), EcoRI, (8 fragments), BalI (13 fragments), and HpaI (49 fragments, 32 of which have been ordered). The maps were determined by (i) analysis of deletion mutants, (ii) digestion with two endonucleases, (iii) digestion of isolated fragments with a second enzyme, (iv) analysis of partial digests, and (v) digestion after treatment with lambda exonuclease.     

Lysis of lysis-inhibited bacteriophage T4-infected cells.

T4 bacteriophage (phage)-infected cells show a marked increase in latent-period length, called lysis inhibition, upon adsorption of additional T4 phages (secondary adsorption). Lysis inhibition is a complex phenotype requiring the activity of at least six T4 genes. Two basic mysteries surround our understanding of the expression of lysis inhibition: (i) the mechanism of initiation (i.e., how secondary adsorption leads to the expression of lysis inhibition) and (ii) the mechanism of lysis (i.e., how this signal not to lyse is reversed). This study first covers the basic biology of the expression of lysis inhibition and lysis of T4-infected cells at high culture densities. Then evidence is presented which implies that, as with the initiation of lysis inhibition, sudden, lysis-associated clearing of these cultures is likely caused by T4 secondary adsorption. For example, such clearing is often observed for lysis-inhibited T4-infected cells grown in batch culture during T4 stock preparation. The significance of this secondary adsorption-induced lysis to wild T4 populations is discussed. The study concludes with a logical argument suggesting that the lytic nature of the T4 phage particle evolved as a novel mechanism of phage-induced lysis.     

Stability of the carrier state in bacteriophage M13-infected cells.

Bacteriophage M13-infected carrier cells were shown to be unstable to prolonged growth under all conditions. Carrier Hfr cells were transferred in dilute culture (10(3) to 10(4)/ml), where reinfection was impossible and the physiology of the cell was minimally altered. After an initial period of about 10 generations, during which all cells in the culture remained infected, there was exponential decay in the proportion of infected cells in the culture. Uninfected cells that appeared were M13 sensitive. Hfr and F' males were also transferred serially at high cell densities (10(7) to 10(9)/ml), where high levels of phage should permit reinfection. The proportion of phage-producing cells in the cultures remained constant for 7 to 15 generations and then dropped exponentially on further growth. Non-phage-producing cells appearing in the culture were refractory to infection by M13; in some cases cells scored as non-phage producers for 20 generations were observed to produce phage on further growth in liquid culture. F'trp+ males infected with M13 lost trp+ function almost immediately; this was not regained in these experiments. Infected cells grown in dilute culture or on plates remained infected longer, produced more PFU per cell for a longer period, and retained trp+ function in F'trp+ males for over 90 generations. Non-phage-producing cells that appeared were sometimes phage resistant, sometimes phage sensitive. The existence of a phage-related material accumulating at high cell densities and affecting expression of free episomes, episomal expression in Hfr males, and phage synthesis itself is suggested.     

Cloning, sequencing, and expression of bacteriophage BF23 late genes 24 and 25 encoding tail proteins.

Two bacteriophage BF23 late genes, genes 24 and 25, were isolated on a 7.4-kb PstI fragment from the phage DNA, and their nucleotide sequences were determined. Gene 24 encodes a minor tail protein with the expected M(r) of 34,309, and gene 25 located 4 bp upstream of gene 24 encodes a major tail protein with the expected M(r) of 50,329. When total cellular RNA isolated from either phage-infected cells or cells bearing the cloned genes was analyzed by the primer extension method using the primers specific to either gene 25 or gene 24, we identified a possible late gene promoter, designated P25, in the 5'-flanking region of gene 25. This promoter was similar in structure to Escherichia coli promoters for sigma 70. Studies of the translational gene 25- and gene 24-lacZ fusions in the cloned gene system revealed that the promoter P25 was responsible for the expression of both genes 25 and 24 even in the absence of the regulatory genes which were absolutely required for late gene expression in the normal phage-infected cells. These results indicate that the two genes constitute an operon under the control of P25 and that the regulatory gene products of BF23 do not participate directly in specifying the late gene promoter.     

Relationships among genes and gene products of bacteriophage BF23

Twenty-five gene products of bacteriophage BF23 were identified by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, and their functions were studied in relation to type I and II genes classified by means of genetic complementation tests. All the type I mutants were defective in the synthesis of a tail protein, L3. In addition, 4 type I gene products, L5 (gp21), L7 (gp20), L8 (gp29), and L9 (gp25), were identified as constituents of tails (gp21 denotes that a protein is a product of gene 21). Three type IIb mutants in genes 10, 14, and 19 diminished substantially the production of late proteins, including tail and head proteins, and the two other type IIb mutants in genes 1 and 2 were defective in the synthesis of both early and late proteins. Of 14 type IIa mutants, at least 6 were defective in phage DNA synthesis and 2 were defective in the synthesis of head proteins. The defect in the head donor activities of type IIa mutants in extract complementation tests was due to the failure of the formation of mature heads containing DNA. The above results support directly the results of the genetic characterization of BF23 genes.     

Physical map of the dispensable region of the genome of E. coli bacteriophage BF23

Using 13 deletion mutants of bacteriophage BF23, physical as well as genetic structures of that portion of the genome which is dispensable for phage growth were investigated. The dispensable region covers at least 15% of the genome of wild type BF23, extending from about 0.2 to 0.35 map unit. Restriction endonuclease (EcoRI and HindIII) cleavage sites and the sites of single-strand interruptions in this dispensable region were localized. It was found that the dispensable region contains an interruption site, which is missing in the mutant BF23st(0) used by Okada and Shimura (1980). Wild-type phage DNA is heterogeneous in the presence or absence of specific single-strand interruptions in this or in a neighboring region of the genome.     

Protein synthesis in bacteriophage ghost-infected cells.

Escherichia coli B infected with T4 phage ghosts at 10 mM Mg2+ regains its protein synthesizing activity upon addition of ATP, GTP, and their generator to approximately 2% of the intact exponentially growing cells. In contrast to amino acid incorporation by intact cells, this system is sensitive to EDTA or low Mg2+. On the other hand, this system, differing from the regular cell-free system, does not respond to addition of soluble protein and ribonuclease. The ghost-infected cells were able to synthesize beta-galactosidase upon addition of the inducer isopropyl thiogalactoside. The initial rate of the induction was 2.6% of intact cells. For this induction, the addition of cyclic AMP, amino acids, ATP, GTP, UTP, CTP, and their generator was necessary. The induction of beta-galactosidase in these ghost-infected cells was very sensitive to the addition of EDTA, CaCl2, sulfhydryl blocking reagent, rifampin and chloramphenicol but insensitive to DNA synthesis inhibitors such as nalidixic acid and DNase.     

Replicative bacteriophage DNA synthesis in plasmolyzed T4-infected cells: evidence for two independent pathways to DNA.

Bacteriophage T4-infected Escherichia coli rendered permeable to nucleotides by sucrose plasmolysis exhibited two apparently separate pathways or channels to T4 DNA with respect to the utilization of exogenously supplied substrates. By one pathway, individual labeled ribonucleotides, thymidine (tdR), and 5-hydroxymethyl-dCMP could be incorporated into phage DNA. Incorporation of each of these labeled compounds was not dependent upon the addition of the other deoxyribonucleotide precursors, suggesting that a functioning de novo pathway to deoxyribonucleotides was being monitored. The second pathway or reaction required all four deoxyribonucleoside triphosphates or the deoxyribonucleoside monophosphates together with ATP. However, in this reaction, dTTP was not replaced by TdR. The two pathways were also distinguished on the basis of their apparent Mg2+ requirements and responses to N-ethylmaleimide, micrococcal nuclease, and to hydroxyurea, which is a specific inhibitor of ribonucleoside diphosphate reductase. Separate products were synthesized by the two channels, as shown by density-gradient experiments and velocity sedimentation analysis. Each of the pathways required the products of the T4 DNA synthesis genes. Furthermore, DNA synthesis by each pathway appeared to be coupled to the functioning of several of the phage-induced enzymes involved in deoxyribonucleotide biosynthesis. Both systems represent replicative phage DNA synthesis as determined by CsCl density-gradient analysis. Autoradiographic and other studies provided evidence that both pathways occur in the same cell. Further studies were carried out on the direct role of dCMP hydroxymethylase in T4 DNA replication. Temperature-shift experiments in plasmolyzed cells using a temperature-sensitive mutant furnished strong evidence that this gene product is necessary in DNA replication and is not functioning by allowing preinitiation of DNA before plasmolysis.     

Cloning, sequencing, and recombinational analysis with bacteriophage BF23 of the bacteriophage T5 oad gene encoding the receptor-binding protein.

Binding of bacteriophage T5 to its receptor, the Escherichia coli FhuA protein, is mediated by tail protein pb5. In this article we confirm that pb5 is encoded by the T5 oad gene and describe the isolation, expression, and sequencing of this gene. In order to locate oad precisely, we analyzed recombinants between BF23, a T5-related phage with a different host range, and plasmid clones containing segments of the T5 chromosome. This analysis also showed that oad has little or no homology with hrs, the analogous BF23 gene. We were able to overproduce a protein that comigrates with pb5 after fusing a 2-kb segment containing oad to a phage T7 promoter. This segment contains an open reading frame that can encode a protein of the appropriate size. Its deduced amino acid sequence does not closely resemble that of any other protein in the database. The sequence upstream of the open reading frame shows typical characteristics of a promoter region with two overlapping, divergently orientated promoters.     

Physical map of bacteriophage BF23 DNA: terminal redundancy and localization of single-chain interruptions.

The DNA of bacteriophage BF23 possesses two structural features, localized single-chain interruptions and a large terminal repetition, previously described for T5, a closely related virus. As is the case for T5, single-chain interruptions occur with variable frequencies at a small number of fixed sites within one strand of the double-stranded BF23 genome. The sites where interruptions occur with the highest frequencies were napped by an electrophoretic analysis of the single-stranded fragments produced by denaturation of BF23 DNA. The positions of these fragments were determined by degrading BF23 DNA to various extents with lambda exonuclease and observing the relative order with which they were (i) degraded or (ii) released intact from the undenatured duplex. The exact locations of the interruptions were determined from analysis of analogous duplex fragments produced by degrading exonuclease III-treated BF23 DNA with a single-strand-specific endonuclease. BF23 has five principal sites (located at 7.9, 18.7, 32.4, 65.8, and 99.6% from the left end of the DNA) where interruptions occur in most molecules. The principal interruptions in T5 DNA occur at similar positions. The locations of eight secondary interruptions in BF23 DNA were also determined. In general, BF23 DNA has fewer secondary interruptions than t5 dna, although there is at least one location where an interruption occurs with a greater frequency in BF23. The presence of a terminal repetition in BF23 DNA was demonstrated by annealing ligase-repaired molecules that had been partially digested with lambda exonuclease. If the complementary sequences at both ends of the DNA were exposed by exonuclease treatment, the duplex segment that resulted from annealing could be released by digestion with a single-strand-specific endonuclease. This segment was analyzed by agarose gel electrophoresis and found to represent 8.4% of BF23 DNA.     

Transport in bacteriophage P22-infected Salmonella typhimurium.

There was rapid efflux of L-leucine, L-phenylalanine, and alpha-methyl-D-glucoside after infection of Salmonella typhimurium with the clear plaque mutant C1 of phage P22. The efflux was similar to that observed with cyanide or arsenate treatment except that there was partial recovery in the case of phage infection and almost complete recovery under the condition of lysogeny. There was no efflux after infection with the temperature-sensitive mutant ts16C1 at nonpermissive temperature. Superinfection of superinfection exclusion negative lysogen (sie A minus sie B minus) with C1 led to efflux, whereas the efflux was much less on superinfection of sie A+ Sie B+ lysogen. These results indicate that an effective injection process is enough to cause depression in the cellular transport processes.