Common evolutionary origin of the phage T4 dam and host Escherichia coli dam DNA-adenine methyltransferase genes.

We compared the known DNA nucleotide and encoded amino acid sequences of the Escherichia coli and bacteriophage T4 dam (DNA-adenine methyltransferase) genes. Despite the absence of any DNA sequence homology, there were four regions (11 to 33 residues long) of amino acid sequence homology containing 45 to 64% identity. These results suggest that the genes for these two enzymes have a common evolutionary origin.     

Sigma factors from E. coli, B. subtilis, phage SP01, and phage T4 are homologous proteins.

We show, using dot matrix comparisons and statistical analysis of sequence alignments, that seven sequenced sigma factors, E. coli sigma-70 and sigma-32, B. subtilis sigma-43 and sigma-29, phage SP01 gene products 28 and 34, and phage T4 gene product 55, comprise a homologous family of proteins. Sigma-70, sigma-32, and sigma-43 each have two copies of a sequence similar to the helix-turn-helix DNA binding motif seen in CRP, and lambda repressor and cro proteins. B. subtilis sigma-29, SP01 gp28, and SP01 gp34 have at least one copy similar to this sequence. We propose that a second sequence, conserved in all seven proteins is the core RNA polymerase binding site. A third region, present only in sigma-70 and sigma-43, may also be involved in interaction with core. Available mutational evidence supports our model for sigma factor structure.     

The optional E. coli prr locus encodes a latent form of phage T4-induced anticodon nuclease.

The optional Escherichia coli prr locus restricts phage T4 mutants lacking polynucleotide kinase or RNA ligase. Underlying this restriction is the specific manifestation of the T4-induced anticodon nuclease, an enzyme which triggers the cleavage-ligation of the host tRNALys. We report here the molecular cloning, nucleotide sequence and mutational analysis of prr-associated DNA. The results indicate that prr encodes a latent form of anticodon nuclease consisting of a core enzyme and cognate masking agents. They suggest that the T4-encoded factors of anticodon nuclease counteract the prr-encoded masking agents, thus activating the latent enzyme. The encoding of a tRNA cleavage-ligation pathway by two separate genetic systems which cohabitate E. coli may provide a clue to the evolution of RNA splicing mechanisms mediated by proteins.     

Single-strand binding proteins from phage T4 and E. coli form higher order structures with poly(dT)

Complexes of poly(dT) with gene 32 protein from phage T4 or E. coli single-strand binding protein were digested by nuclease P1 from Penicillum citrinum. Protected fragments were analyzed by gel electrophoresis. In both cases, a series of bands was obtained corresponding to multiples of a repeat unit whose size was about 80 nucleotides. Such protected fragments could not be detected under the same experimental conditions when poly(dA) was used instead of poly(dT). The formation of nucleosome-like structures is discussed in relation to the higher affinity exhibited by single-strand binding proteins towards poly(dT).     

An inhibitor of host sigma-stimulated core enzyme activity that purifies with DNA-dependent RNA polymerase of E. coli following T4 phage infection

The content of the sigma subunit (as detected by gel electrophoresis) and activity with T4 DNA were examined with RNA polymerase fractions from both normal and T4 phage-infected $\text{E. coli}$. Sigma-containing fractions and core enzymes were obtained by phosphocellulose column chromatography. The sigma-containing fraction of the enzyme from infected cells, although somewhat stimulatory to both core enzymes alone, inhibits the normal sigma-stimulated activity of the core enzyme from infected cells at both low and high KCl concentration. Normal core enzyme activity is inhibited only at high KCl concentration.     

Functional interactions between phage T4 and E. coli DNA-binding proteins during the presynapsis phase of homologous recombination

The "protein machine" for phage T4 homologous recombination has begun to be assembled in vitro. A particularly heavily studied reaction has been the uvsX protein (a RecA-like strand transferase)-mediated homologous pairing reaction between single and double-stranded DNAs, a key step in the recombination cycle in vivo. A necessary prerequisite for uvsX protein-mediated pairing is the polymerization of this factor along the invading single strand, a process known as presynapsis. Recent work has indicated that at least two other T4 recombination factors are involved in this process as well, the uvsY and gene 32 products. These proteins are also ssDNA-binding factors and exhibit an affinity for UvsX and each other. In order to begin to sort out the potential functional roles played by these protein-protein interactions in presynapsis, I have examined the ability of the uvsX protein to form stable filaments along ssDNA in the presence of these proteins. It is shown that the uvsY protein relieves the inhibition to filament formation due to the presence of the gene 32 protein, but experiments with the E. coli SSB protein (the bacterial analogue of gp32) suggest that this effect does not involve a direct interaction between UvsY and gp32.     

Purification of histidine-tagged T4 RNA ligase from E. coli

Here we report the construction of a histidine-tagged T4 RNA ligase expression plasmid (pRHT4). The construct, when overexpressed in BL21 (DE3) cells, allows the preparation of large quantities of T4 RNA ligase in high purity using only a single purification column. The histidine affinity tag does not inhibit enzyme function, and we were able to purify 1-3 mg pure protein/g cell pellet. A simple purification procedure ensures that the enzyme is de-adenylated to levels comparable to those found for many commercial preparations. The purified protein has very low levels of RNase contamination and functioned normally in a variety of activity assays.