Purification and properties of a bacteriophage T5-modified form of Escherichia coli RNA polymerase

Novel Escherichia coli RNA Polymerase Binding Protein Encoded by Bacteriophage T5

The Escherichia coli bacteriophage T5 has three temporal classes of genes (pre-early, early, and late). All three classes are transcribed by host RNA polymerase (RNAP) containing the σ⁷⁰ promoter specificity subunit. Molecular mechanisms responsible for the switching of viral transcription from one class to another remain unknown. Here, we find the product of T5 gene 026 (gpT5.026) in RNAP preparations purified from T5-infected cells and demonstrate in vitro its tight binding to E. coli RNAP. While proteins homologous to gpT5.026 are encoded by all T5-related phages, no similarities to proteins with known functions can be detected. GpT5.026 binds to two regions of the RNAP β subunit and moderately inhibits RNAP interaction with the discriminator region of σ⁷⁰-dependent promoters. A T5 mutant with disrupted gene 026 is viable, but the host cell lysis phase is prolongated and fewer virus particles are produced. During the mutant phage infection, the number of early transcripts increases, whereas the number of late transcripts decreases. We propose that gpT5.026 is part of the regulatory cascade that orchestrates a switch from early to late bacteriophage T5 transcription.

Pre-early functions of bacteriophage T5 and its relatives

Coliphage T5 injects its DNA in 2 steps: the first step transfer (FST) region 7.9% is injected and its genes are expressed and only then does the remainder (second step transfer, SST) of its DNA enter the cell. In the FST region, only 2 essential genes (A1 and A2) have been identified and a third (dmp) non-essential gene codes for a deoxyribonucleotide 5' monophosphatase. Thirteen additional putative ORFs are present in the FST region. Numerous properties have been attributed to FST region, including SST, host DNA degradation, inhibition of host RNA and protein synthesis, restriction insensitivity and protection of T5 DNA. These effects do not occur following infection with an A1 mutant. The A2 gene seems only to be involved in SST transfer. This is puzzling since there are more seemingly unrelated effects than there are essential genes to accomplish them and it is possible that some important genes were not identified. This review attempts to analyze these problems that were first identified in the 1970-80 s. In particular, an attempt is made to determine which potential ORFs are conserved in evolution (and thus likely to be important); by comparing T5 to 10 newly isolated and completely sequenced T5-like phages. A similar approach is used to identify conserved repeats, inverted repeats and palindromes that occur in all T5-like phages in the region containing the injection stop signal (iss) and the terminase substrate. Finally, an attempt is made to re-analyze the mechanism whereby T5 protects itself from the enzymes that degrade host DNA, from the RecBCD nuclease and from restriction enzymes. For all of these FST effects new hypotheses and possible new genetic and biochemical approaches are envisaged.

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.

Regulation of the temporal synthesis of proteins in bacteriophage BF23-infected cells

Regulation of temporal synthesis of pre-early, early, and late proteins in bacteriophage BF23-infected cells has been studied by using five amber mutants defective in genes 1, 2, 10, 14, and 19. The synthesis of pre-early proteins is negatively regulated by the actions of gene 1, a pre-early gene. The switch from pre-early to early protein synthesis is mainly regulated by the second-step DNA transfer reaction, which is controlled by at least genes 1 and 2. Early proteins can be kinetically and genetically divided into two regulatory classes, designated Ea and Eb. The shutoff of Eb-early protein synthesis is associated with the turn-on of late protein synthesis. This step is controlled by genes 10, 14, and 19. Gene 10 also regulates negatively the synthesis of Ea-early proteins, indicating that this gene has a dual function in the regulation of early protein synthesis. The temporal synthesis of phage-encoded proteins is regulated mainly at the transcriptional level. Evidence is presented indicating that the host RNA polymerase is modified by the interaction with the gene products of genes 2, 10, and 14 (gp2, gp10, and gp14, respectively). gp2 interacts with the enzyme in the earlier stage of infection but is replaced by gp10 in the later stage. This exchange reaction depends on the presence of gp14 and gp19 and is related to the switch from Eb to late protein synthesis. Thus, the regulation of BF23 gene expression occurs in a coordinated manner throughout the development of this phage.

Transcription regulatory elements in the late region of bacteriophage T5 DNA

Transcription promoters and terminators have been cloned from the late region of bacteriophage T5 DNA and their strengths determined in vivo in plasmid derivatives. DNA sequence analysis shows these transcription signals to be remarkable in that, in all four cases studied in detail, the promoters and terminators overlapped or were very close together.

Modification of RNA polymerase from Escherichia coli by pre-early gene products of bacteriophage T5

RNA polymerase from cells of Escherichia coli infected with T5 were recovered as a complex with two pre-early phage-coded polypeptides, the 60,000-dalton product of gene A1 and a previously reported 11,000-dalton polypeptide. This RNA polymerase complex had altered transcriptional specificity, in that it transcribed pre-early genes less efficiently than it did early genes.

Amino acid and sugar transport in Escherichia coli (ColIb) during abortive infection by bacteriophage T5

T5 bacteriophage cannot replicate in Escherichia coli containing the colicinogenic factor ColIb. We show that active transport of proline and glutamine begins to decline at about 10 min after infection, the same time at which macromolecular synthesis stops during abortive infection. Uptake of alpha-methylglucoside is stimulated, however, and this change is evident even by 5 min after infection. These changes in membrane function do not occur during infections that are productive because of mutations on the plasmid or phage. The results suggest that the abortive infection is caused by membrane depolarization.

Membrane damage in abortive infections of colicin Ib-containing Escherichia coli by bacteriophage T5

Strains of Escherichia coli K-12 containing the colicin Ib (Col Ib) factor did not produce progeny phage when infected by T5 bacteriophage. The cells were killed but did not lyse. If sodium dodecyl sulfate (SDS) was added to T5-infected E. coli (Col Ib), lysis occurred prematurely, but no phage were produced. SDS had no effect on infected cells that did not contain the Col Ib factor or on uninfected cells with or without the Col Ib factor. Cells that contained a mutant Col Ib factor that allowed phage production were not prematurely lysed after infection in the presence of SDS. When the Col Ib-containing cells were infected, protein and RNA synthesis stopped at about 10 min postinfection, and the cells released abnormal amounts of 32P-containing material, ATP, and beta-galactosidase into the medium. They also became inhibited in their ability to accumulate thiomethyl-beta-D-galactopyranoside and to utilize glycerol. Two alternative hypotheses are presented to explain these results.