The Preparation and Properties of Ribonucleic Acid Polymerase from Azotobacter vinelandii

Purification and characterization of the DNA-dependent RNA polymerase and its subunit sigma from Micrococcus luteus

DNA-dependent RNA polymerase from Micrococcus luteus can be isolated from cell extracts after removal of an excess of nucleic acids by fractionation with ammonium sulfate, followed by two consecutive gel filtrations through agarose and chromatography on cellulose phospate. Either homogeneous holoenzyme or a mixture of core and holoenzyme is obtained in this way, as is indicated by electrophoresis in polyacrylamide gels in the absence of detergent, where core enzyme migrates ahead of holoenzyme. Homogeneous core enzyme can be isolated from holoenzyme by chromatography on DEAE-cellulose. Core enzyme contains the subunits alpha, beta and beta' previously described [U.I. Lill et al., (1975) Eur. J. Biochem. 52, 411-420] in a molar ratio of 2:1:1. Holoenzyme contains an additional subunit sigma of 80 000 molecular weight (molar subunit composition alpha2 betabeta' sigma) and two relatively small polypeptides (molecular weight 14 000 and 25 000, respectively). Subunit sigma may be isolated from holoenzyme by chromatography on DEAE-cellulose at pH 6.9 in the presence of low concentrations of glycerol. The behaviour of holoenzyme during sedimentation in a glycerol gradient at low ionic strength indicates its occurrence as a dimer of the alpha2betabeta'sigma-protomer, whereas the monomeric form is preferred by core enzyme. Holoenzyme is much more active than core enzyme in RNA synthesis on bacteriophage T4DNA as template. The activity of the latter is stimulated by isolated sigma. M. luteus sigma as well as holoenzyme enhances also the activity of core enzyme fro- Escherichia coli. The formation of a hybrid between micrococcal sigma and E. coli core polymerase is also suggested by the influence of sigma on the oligomerisation of the enzyme from E. coli.

DNA-dependent RNA polymerase from Pseudomonas BAL-31. I. Purification and properties of the enzyme

The DNA-dependent RNA polymerase from Pseudomonas BAL-31, the host for bacteriophage PM2, has been purified 154-fold using differential centrifugation, chromatography on DEAE-cellulose, ammonium sulfate precipitation, and sucrose gradient centrifugations at low and high ionic strength. The resulting enzyme is free of enzyme activities which could interfere with transcription studies and is greater than 85% pure as judged by polyacrylamide gel electrophoresis. Like other bacterial RNA polymerases, its subunit structure is beta'beta sigma alpha2. From gel electrophoresis the beta', beta, and alpha subunits have approximately the same molecular weights as those from Escherichia coli, whereas the sigma subunit is 5% larger (89,000 vs. 85,000). A summation of the subunits yields a molecular weight of 485,000 for the holoenzyme. Like other bacterial RNA polymerases, it sediments as a monomer (15 S) at low ionic strength (0.065) and as a dimer (22 S) at high ionic strength (0.75). Its activity is stimulated three-fold by monovalent cations (K+,NH4+, NA+) with additional stimulation provided by divalent cations (Mg2plus, Mn2plus). The transcription of phage PM2 form I (supercoiled) DNA has an ionic strength optimum of 0.26 for continuous long-term synthesis, and over an ionic strength range of 0.09-0.46 "plateau-type" kinetics are not observed. The sigma subunit is required for optimal PM2 transcription. The enzyme is sensitive to the same inhibitors of transcription as the RNA polymerase from E. coli, it has a temperature optimum of 28 degrees, and it is 50% inactivated by heating 10 min at 41 degrees. It has template preference similar to E. coli polymerase and shows little preference for homologous templates. With various DNAs the order of template activities is T7 greater than PM2 I congruent to T4 greater than PM2 II (relaxed circular form) greater than lambda-c greater than calf thymus greater than BAL-31 DNA. Phage PM2 form I DNA is transcribed at a twofold greater rate than PM2 form II DNA by this enzyme.

Influence of polyamine limitation on the chain growth rates of beta-galactosidase and of its messenger ribonucleic acid

The rates of elongation of beta-galactosidase and its messenger ribonucleic acid (RNA) were estimated in a polyamine-deficient mutant of Escherichia coli through an analysis of the kinetics of enzyme induction. The chain growth of beta-galactosidase was calculated from the time required after the appearance of an amino terminal fragment of 60 amino acids (auto-alpha) until completed enzyme began to accumulate. The elongation rate of beta-galactosidase messenger RNA was estimated from the time after induction at which streptolydigen-resistant, enzyme-forming capacity first appeared. Upon polyamine starvation, the rate of polypeptide elongation slowed from 17 to 10 amino acids per s and the messenger RNA elongation rate decreased from 47 to 30 nucleotides per s. These reductions in polymerization rates were proportional to the decrease in cellular growth rate produced by polyamine starvation. It was concluded that, although it is quite unlikely that polyamine levels are involved in regulation of cell growth, they may be acting as cofactors in the synthesis of RNA or protein, or both.