Localization of Escherichia coli RNA polymerase binding sites on bacteriophage S13 and 0X174 DNAs by electron microscopy.

Complexes between Escherichia coli RNA polymerase and bacteriophage S13 and phage phiX174 replicative form III DNAs have been shown to form at specific locations on the phage genomes. The major locations on S13 have been mapped at 8 to 10 and 92 to 96% of the genome length, starting from the unique Pst I cleavage site. The locations correspond to the beginnings of genes D and B, respectively. Four minor locations map at 18 to 22, 28 to 32, 50 to 56, and 70 to 74% of the genome. The 70 to 74% site corresponds to the beginning of the A gene. The major locations on phiX174 are at 8 to 10, 50 to 54, and 92 to 94% of the genome. The 50 to 54% site is at the start of the H gene and has an equivalent minor site on S13, but it is not a promoter site. Three minor sites on phiX174, at 20 to 24, 26 to 32, and 68 to 74% of the genome, correspond to sites on S13. The data confirm the locations of sites identified by restriction fragment binding experiments (E. Rassart and J. H. Spencer, J. Virol. 27:677--687, 1978) and the assignment of putative promoters at the start of genes A, B and D.     

Escherichia coli mutant which restricts T7 bacteriophage has an altered RNA polymerase.

We have previously described an Escherichia coli K-12 mutant, Y49, which restricts the growth of bacteriophage T7 and causes the accumulation of short DNA molecules and head-related particles during infection. We now show that the basis for these effects is the inability of the T7 gene 2 product to inactivate the Y49 RNA polymerase during infection, similar to what has been shown by DeWyngaert and Hinkle (J. Biol. Chem. 254:11247--11253, 1979) for the BR3 and tsnB strains of E. coli.     

ADP ribosylation of Escherichia coli RNA polymerase is nonessential for bacteriophage T4 development.

The bacteriophage T4-induced alt and mod gene products covalently add ADP-ribose to the Escherichia coli RNA polymerase alpha polypeptides; phage carrying either an alt or a mod mutation are viable. A genetic cross between T4alt and T4mod phages yielded alt mod recombinant progeny which could not ADP ribosylate RNA polymerase at all, yet grew apparently normally. Thus, ADP ribosylation of RNA polymerase appeared to be nonessential for T4 development (at least in E. coli B/r and E. coli CR63), even though the phage has evolved two distinct enzymes to catalyze this reaction.     

Kinetic measurements of Escherichia coli RNA polymerase association with bacteriophage T7 early promoters

During infection of Escherichia coli by bacteriophage T7, E. coli RNA polymerase utilizes only three promoters (A1, A2, and A3). In vitro, the A promoters predominate at very low polymerase concentration, but at higher polymerase concentration the minor B, C, D, and E promoters are used with equal efficiency. The binding constant for the initial association of polymerase with promoters and the forward rate of isomerization to an "open" complex capable of initiation have been measured for the A1, A3, C, and D promoters using the abortive initiation reaction. At 80 mM KCl, 37 degrees C, both major and minor promoters isomerize rapidly (t1/2 = 10 to 30 s). In contrast, initial binding to the minor promoters (KI = 10(7) ) is at least 10-fold weaker than binding to major promoters KI greater than or equal to 10(8) ), suggesting promoter selectivity in the T7 system occurs at the point of initial binding. Association kinetics of the A1 and C promoters on intact T7 were the same as measured on restriction fragments of length greater than or equal to 500 base pairs. All open complexes dissociated with half-lives longer than 1 h. Overall equilibrium binding constants estimated from kinetic measurements ranged from 10(10) to greater than or equal to 10(11) M-1 for minor and major promoters, respectively. Data on heparin attack and abortive initiation turnover rates indicate open complex polymerase conformation may be different at the A1 and A3 promoters.     

Rapid isolation and identification of bacteriophage T4-encoded modifications of Escherichia coli RNA polymerase: a generic method to study bacteriophage/host interactions

Bacteriophages are bacterial viruses that infect bacterial cells, and they have developed ingenious mechanisms to modify the bacterial RNA polymerase. Using a rapid, specific, single-step affinity isolation procedure to purify Escherichia coli RNA polymerase from bacteriophage T4-infected cells, we have identified bacteriophage T4-dependent modifications of the host RNA polymerase. We suggest that this methodology is broadly applicable for the identification of bacteriophage-dependent alterations of the host synthesis machinery.