Construction and properties of a cell-free system for bacteriophage T4 late RNA synthesis

Without a license, or accidents waiting to happen

This is a memoir of circumstances that have shaped my life as a scientist, some of the questions that have excited my interest, and some of the people with whom I have shared that pursuit. I was introduced to transcription soon after the discovery of RNA polymerase and have been fascinated by questions relating to gene regulation since that time. My account touches on early experiments dealing with the ability of RNA polymerase to selectively transcribe its DNA template. Temporal programs of transcription that control the multiplication cycles of viruses (phages) and the precise mechanisms generating this regulation have been a continuing source of fascination and new challenges. A longtime interest in eukaryotic RNA polymerase III has centered on yeast and on the enumeration and properties of its transcription initiation factors, the architecture of its promoter complexes, and the mechanism of transcriptional initiation. These areas of research are widely regarded as separate, but to my thinking they have posed similar questions, and I have been unwilling or unable to abandon either one for the other. An additional interest in archaeal transcription can be seen as stemming naturally from this point of view.

Sigma competition: the contest between bacteriophage T4 middle and late transcription

In bacterial transcription, diverse sigma-family promoter recognition proteins compete for a common RNA polymerase core. Bacteriophage T4 infection ultimately reduces this competition to a duel between activated viral middle and enhanced late transcription, involving two sigma proteins, two phage-encoded activator proteins and two phage-specific co-activators. This competition has been analyzed in vitro, and the relative abundances in T4-infected Escherichia coli of the participating proteins have been measured. Activated late transcription holds an advantage over activated middle transcription, especially at higher ionic strength. This advantage is further compounded by ADP-ribosylation of the RNA polymerase alpha subunits, and by the phage-specific, RNA polymerase core-bound RpbA subunit. The largest contribution to the middle-late competition is made by gp55, the late sigma factor, but not enough of gp55 is produced during T4 infection to shut off middle transcription by direct competition with sigma(70). AsiA, the originally identified anti-sigma protein is not a major determinant of middle-late competition.

Bacteriophage T4 gol site: sequence analysis and effects of the site on plasmid transformation

The Escherichia coli lit gene product is required for the multiplication of bacteriophage T4 at temperatures below 34 degrees C. After infection of a lit mutant host, early gene product synthesis is normal, as is T4 DNA replication; however, the late gene products never appear, and early gene product synthesis eventually ceases. Consequently, at late times, there is no protein synthesis of any kind (W. Cooley, K. Sirotkin, R. Green, and L. Snyder, J. Bacteriol. 140:83-91, 1979; W. Champness and L. Snyder, J. Mol. Biol. 155:395-407, 1982), and no phage are produced. We have isolated T4 mutants which can multiply in lit mutant hosts. The responsible T4 mutations (called gol mutations) completely overcome the block to T4 gene expression (Cooley et al., J. Bacteriol. 140:83-91). We have proposed that gol mutations alter a cis-acting regulatory site on T4 DNA rather than a diffusible gene product and that the wild-type form of the gol site (gol+) somehow interferes with gene expression late in infection (Champness and Snyder, J. Mol. Biol. 155:395-409). In this communication, we report the sequence of the gol region of the T4 genome from five different gol mutants. The gol mutations are all single-base-pair transitions within 40 base pairs of DNA. Therefore, the gol site is at least 40 base pairs long. The sequence data confirm that the gol phenotype is not due to an altered protein. We also report that the gol+ site in plasmids prevents transformation of Lit- but not Lit+ E. coli. Thus, the gol site is at least partially active in the absence of the T4 genome.

In vitro transcription of phage T4 late genes on purified DNA by partially purified RNA polymerase from T4-infected Escherichia coli b cells

RNA polymerase was purified from 'late' phage T4-infected Escherichia coli B cells by DNA-cellulose affinity chromatography and high salt agarose filtration. The DNA-cellulose-purified RNA polymerase preparation contained T4-coded DNA endonuclease activity and several proteins, some with sizes comparable with the known T4 maturation factors, essential for late RNA synthesis. Some of these proteins, and the DNA endonuclease utilizing native, parental T4 DNA and supercoiled phi X 174 DNA as substrates, were partially separated from the RNA polymerase as a complex during agarose filtration. In vitro RNA was made by the DNA-cellulose-purified RNA polymerase using native, parental T4 DNA as template. About 26% of the in vitro RNA was transcribed from the DNA r-strand; 75% from the same r-strand region as in vivo late after infection. Both the abundancy and specificity of the in vitro r-strand transcription were markedly reduced after agarose filtration of the enzyme. Addition of the proteins separated from the RNA polymerase during agarose filtration caused a restoration of in vitro r-strand transcription abundance, but not its specificity. These results show that partially purified RNA polymerase from T4-infected E. coli B cells was able to transcribe late T4 genes in vitro with some abundancy and specificity on purified, parental T4 DNA, but further purification of the enzyme caused an irreversible reduction of this ability.

DNA-RNA polymerase complexes associated with the membrane from bacteriophage T2- or T4-infected Escherichia coli. I. General properties

Properties of DNA-RNA polymerase complexes, apparently bound to a fraction of the cell membrane of bacteriophage T2- or T4-infected Escherichia coli, are described. Evidence is presented to show that the complexes initiate the asymmetric synthesis of RNA, and release the finished product. The transcription capacity per unit of beta' + beta was 10 times higher at 6 min than at 30 min after infection.

DNA-RNA polymerase complexes associated with the membrane from bacteriophage T2- or T4-infected Escherichia coli. II. A comparison of in vitro RNA with the in vivo RNA products

Membrane preparations, containing DNA-RNA polymerase from bacteriophage T2- or T4-infected Escherichia coli, caused the asymmetric synthesis of RNA classes similar to those produced sequentially in vivo: 1, Pre-early RNA was formed when a membrane preparation was isolated 1 min after infection. 2, Pre-early and delayed early RNA, in roughly the same proportion as that obtained in vivo, was synthesized by a preparation obtained 6 min after infection. 3, Pre-early, delayed early and late genes were transcribed by preparations isolated from cells during the late period of infection. In late preparations, however, less late and more pre-early RNA was usually synthesized in vitro than that obtained in vivo. Late RNA was not synthesized when a phage T4 mutant defective in either gene 33 or gene 55 was used. Evidence is presented to show that late RNA synthesis cannot solely be accounted for from the completion of already initiated chains.