Animal DNA-dependent RNA polymerases. Purification and molecular structure of hen-oviduct and liver class-B RNA polymerases.

Hen ovidcut and liver class B RNA polymerases have been extensively purified and their molecular structure has been analysed. While only one enzyme B form (BIIb) was found in liver, three forms (BI, BIIa and BIIb) were resolved from oviduct. The molecular structures of the various class B RNA polymerase forms purified from hen oviduct and liver are identical to the corresponding forms previously purified from calf thymus and rat liver. At the present level of resolution the only difference lies in a slight difference in the charge of one subunit (SB2a) of enzyme form BIIa, when comparing the mammal and bird enzymes. It is unlikely that the absence of enzyme forms BI and BIIa in purified hen liver RNA polymerase B could be related to limited and specific proteolysis during the purification, since co-purification of oviduct and liver RNA polymerase B activities from a mixture of oviduct and liver nuclei does not affect the presence of either oviduct enzyme form BI or BIIa in the final purified mixture.     

Early evolution of eukaryotic DNA-dependent RNA polymerases

Eukaryotic DNA-dependent RNA polymerases (Pol I-III) share a conserved core of 12 subunits, which is closely related to archaeal RNA polymerases. Rpb8, a subunit found in Pol I, II and III, was thought to be restricted to eukaryotes. We show here that Rpb8 closely resembles an archaeal protein called G, found only in Crenarchaea, which identifies a last missing link between the core structure of archaeal and eukaryotic RNA polymerases.     

DNA-dependent RNA polymerases from normal mouse liver

Three forms of DNA-dependent RNA polymerase from adult mouse liver are separable by DEAE-Sephadex A-25 chromatography. Two of the forms (IA and IB) are insensitive to inhibition by α-amanitin, while the third form is completely inhibited by 0.3 μg/ml of α-amanitin. The three enzyme forms are compared to the enzymes found in adult rat liver, and to the enzymes found in several other mouse tissues.     

DNA-dependent RNA polymerases isolated from yeast mitochondria

Purified preparations of yeast mitochondria yield three species of DNA-dependent RNA polymerases. These enzymes have been separated and purified to homogeneity for analysis of their properties and for comparison with the properties of nuclear preparations of yeast RNA polymerases. Three enzymes have been separated by DEAE-Sephadex chromatography of each fraction. Both nuclear and mitochondrial preparations yield three components with nearly identical elution properties. The distributions of enzyme activity on DEAE-Sephadex chromatography differ with the three nuclear peaks, being found in ratios (uncorrected for the effect of increasing salt concentration) of 8:85:7 and the mitochondrial peaks in ratios of 8:32:60 at late log phase of growth under optimized conditions in which protease inhibitors and an antioxidant were included. The type of mitochondrial enzymes in 3-day-old cells differed from those grown to late logarithmic phase. It has been established that the enzymes of the mitochondrial preparation are associated with the membrane fraction. While extraction with 0.5 m KCl solubilizes considerable enzyme activity, greatly enhanced yields of enzyme MIII are obtained by addition of the antioxidant 2,6-di-t-butyl-4-hydroxymethyl phenol during enzyme extraction. Inhibition of protease activity has also been shown to have a major effect on the yield and distribution of enzymes obtained from mitochondrial preparations. The mitochondrial preparations of yeast polymerases are generally similar but not identical to corresponding nuclear polymerases in subunit molecular weights, inhibitor sensitivities, and in DNA template dependence. Comparative studies of nuclear and mitochondrial polymerases clearly establish that differences do exist among the isolated enzymes of these classes. It has not been ruled out to date that these enzymes may be derived in part or in total from the same cytoplasmic subunit pool, nor has it been established that any of these enzymes function in mitochondria in vivo.     

DNA replication during muscle cell differentiation: identification of multiple DNA-dependent DNA polymerases

DNA-dependent DNA polymerases have been studied during chick embryo muscle differentiation in vitro. The total activity, extracted at both low and high ionic strengths, does not change throughout the differentiative process, although DNA synthesis stops at the moment of fusion. Analyses by glycerol gradient centrifugation of the extracts at low and high ionic strengths show two major DNA polymerase forms, one sedimenting at 7.5 S and another at 3-4 S. Both enzymes are present in similar amounts in duplicating myoblasts and in post-mitotic myotubes. These data suggest that the arrest of DNA synthesis which accompanies myoblast differentiation is not dependent on the disappearance or decrease of the major DNA polymerase activities described.     

Synthesis of two DNA-dependent RNA polymerases in yeast

Specific activities of Saccharomyces cerevisiae RNA polymerases I and II were measured in cells growing under different nutrient conditions and throughout the mitotic cell cycle. The specific activity of RNA polymerase I (possibly the ribosomal polymerase) does not vary during the yeast cell cycle. In contrast the specific activity of RNA polymerase II (messenger polymerase) increases during the first third of the cycle and thereafter declines. The independent regulation of synthesis of these two enzymes is further emphasised by observations on the response to different nutrient conditions. Shifting cells from minimal to rich medium led to enhanced RNA polymerase I activity but very little change in activity of RNA polymerase II. Furthermore the activity of RNA polymerase I varies directly with change in growth rate whereas the activity of RNA polymerase II is approximately constant over a range of growth rates. From this data it is suggested: (i) The synthesis of these two enzymes is independently regulated; (ii) RNA polymerase I is synthesised continuously throughout the cycle whereas RNA polymerase II is synthesised periodically early in the cell cycle.     

Synthesis and properties of fluorescent nucleotide substrates for DNA-dependent RNA polymerases.

A new class of fluorescent nucleotide analogs which contain the fluorophore 1-aminonaphthalene-5-sulfonate attached via a gamma-phosphoamidate bond has been synthesized. Both the purine and pyrimidine analogs have fluorescence emission maxima at 460 nm. Cleavage of the alpha-beta-phosphoryl bond produces change in both the absorption and fluorescence emission spectra. The fluorescence of the pyrimidine analogs is quenched; cleavage of the alpha-beta-phosphoryl bond of the UTP analog produces about a 14-fold increase in fluorescence intensity at 500 nm. Under the same conditions the fluorescence of the CTP analog increases about 8-fold, whereas the fluorescence of the purine analogs shows only a slight change. These derivatives are good substrates for Escherichia coli RNA polymerase with only slightly increased Km values and with Vmax values about 50 to 70% that of the normal nucleotides. They are used less efficiently by wheat germ RNA polymerase II. The ATP analog can be used by E. coli RNA polymerase to initiate RNA chains.     

DNA-dependent RNA polymerases from Schneider 2-L cells of Drosophila. I. Preliminary characterization

The DNA-dependent RNA polymerases of Schneider 2-L cells of Drosophila melanogaster are described. These cells contain five readily detectable forms of this enzyme, polymerases I_a, I_b, III_a, II, and III_b, which elute from DEAE-Sephadex at 0.08, 0.12, 0.15, 0.20, and 0.22 m ammonium sulfate, respectively. RNA polymerases III_a and III_b, which each constitute about 5–10% of the total RNA polymerase activity in Drosophila embryos, are found to constitute 30 and 10%, respectively, of the total polymerase activity in cultured cells. The two form III polymerases are further characterized by in vitro response to divalent cations and ionic strength, template utilization, and sensitivity to -amanitin. Verification of the class III designation of these two polymerases is provided by their sensitivity to only very high levels of -amanitin (50% inhibition at approximately 800 µg/ml), their 10-fold greater activity on poly[d(A–T)], and their elution from DEAE-cellulose at lower ionic strengths than from DEAE-Sephadex.This work was supported by the Natural Sciences and Engineering Research Council.     

DNA-dependent RNA polymerases from murine testis. Properties of two activities.

Multiple forms of DNA-dependent RNA polymerase activities have been isolated from nuclei of mouse testis. Using highly purified nuclei, two activities can be solubilized and are separable by DEAE-Sephadex chromatography; peak I eluting at 0.11–0.14 M and peak II eluting at 0.24–0.27 M (NH₄)₂SO₄. A third form of RNA polymerase activity is observed eluting at 0.31–0.33 M (NH₄)₂SO₄ when an extract from a less highly purified nuclear preparation is analysed. At concentrations of 0.125 μg/ml, peak I is insensitive to the toxin α-amanitin, peak II is totally inhibited, and peak III is partially inhibited. Peak I activity is optimal at pH 8.4 in the presence of Mg²⁺ (2–6 mM) or Mn²⁺ (1 mM) and uses native and heat-denatured DNA template equally well. Peak II has optimal activity at pH 7.9 in the presence of Mn²⁺ (2 mM) and heat-denatured DNA. Mg²⁺ has little effect on the activity of peak II.     

Nuclear and mitochondrial DNA-dependent RNA polymerases in bovine spermatozoa

DNA-dependent RNA polymerases have been solubilized from separated head and tail fractions from normal bovine spermatozoa and from spermatozoa carrying the 'decapitated sperm defect'. When enzyme extracts from separated heads and tails were chromatographed on DEAE-Sephadex, the head fraction was resolved into 2 distinguishable peaks eluting at about 0.11 and 0.15 M-(NH4)2SO4 while the tail fraction yielded 4 distinct peaks eluting at about 0.11, 0.15, 0.255 and 0.35 M-(NH4)2SO4. Results indentical to those observed for sperm tails were obtained with extracts prepared from highly purified mitochondria from bovine or murine heart or liver. Optimization of reaction parameters and inhibitor studies with alpha-amanitin and rifampicin revealed strong similarities between eucaryotic nuclear RNA polymerases 1 and 2 and the 2 RNA polymerases associated with sperm heads. Similar experiments comparing the RNA polymerases from somatic mitochondria and sperm tails suggested the sperm tail enzymes were mitochondrial in origin.