Fractionation of RNA polymerase subspecies from soybean hypocotyls by isoelectric focusing in Sephadex

RNA polymerase enzymes isolated from chromatin of 6-day-old soybean hypocotyls are resolved into two major and one minor species of activity by DEAE-Sephadex chromatography. A soluble form of the enzyme, isolated from the postchromatin supernatant fraction, shows a broad peak of activity when fractionated by this method. The elution characteristics and α-amanitin sensitivity data indicate the two major chromatin-bound activities to be Class I and III enzymes, while the minor chromatin-bound activity and the soluble enzyme are representative of the Class II enzymes. In contrast to these profiles, fractionation of these enzyme preparations by the new method of isoelectric focusing in Sephadex G-15 yields five distinct chromatin-bound and four soluble subspecies. The relationships of these observed activities to their parent DEAE classes are investigated, showing two subspecies within the Class I and III RNA polymerase enzymes, respectively, and four subspecies within the Class II enzymes.     

Increased mitochondrial DNA and RNA polymerase activity in ethylene-treated potato tubers

A purified mitochondrial fraction was isolated from potato (Solanum tuberosum L.) tubers respiring normally at 23°C or at an accelerated rate in response to treatment with ethylene (10 microliters per liter).

A pronounced increase in various mitochondrial enzymic activities was observed in response to exposure of the whole tubers to ethylene. Cytochrome c oxidase activity increased more than 50%, DNA polymerase activity increased about 2-fold, and RNA polymerase activity increased 2.5-fold. Moreover, DNA or RNA polymerase activities of mitochondria isolated from tubers not treated with ethylene were not affected by ethylene treatment in vitro. Respiratory control ratios decreased from 2.84 to 1.50 with increasing periods of ethylene treatment from 0 to 15 hours. None of these changes were observed in untreated tubers. It is concluded that the stimulation of respiration by ethylene in potato tubers is accompanied in vivo by an enhancement of mitochondrial enzymic activity of both membrane-associated enzymes which participate in the mitochondrial oxidative electron transport as well as soluble enzymes which are not directly involved in respiration.

     

Isolation and characterization of DNA-dependent RNA polymerase A, B and C from rat brain nuclei

Abstract— DNA-dependent RNA polymerase activities were solubilized from the brain nuclei of young rats. Six forms of RNA polymerases were distinguished on DEAE-Sephadex A-25 chromatography and designated A, BI, BII, CI, CII, and Oil by their sensitivities to α-amanitin. CII enzyme was shown to derive from CIII enzyme by serine-protease digestion. CI enzyme was also suggested to be a product of a proteolytic process. Using a DNA template, enzyme A was completely resistant to α-amanitin; BI and BII enzymes were equally sensitive to this toxin (50% inhibition at 0.006 μg/ml); while C enzymes showed intermediate sensitivity (50% inhibition at 30 μg/ml). When poly[d(A-T)] was used as a template, α-amanitin sensitivities were altered in A, CI, CII, and CIII enzymes without any change in the BII enzyme. CI, CII and CIII enzymes were greatly stimulated by poly[d(A-T)], whereas A and BII enzymes were only slightly stimulated. All six forms of RNA polymerases were extensively characterized with respect to their ammonium sulphate optima, effects of divalent metal ions, template requirements and pH optima, using DNA and poly[d(A-T)] as templates. The results show new findings in several properties and supply basic data for discussion and future studies on RNA metabolism of the brain.     

Norovirus proteinase-polymerase and polymerase are both active forms of RNA-dependent RNA polymerase

In vitro mapping studies of the MD145 norovirus (Caliciviridae) ORF1 polyprotein identified two stable cleavage products containing the viral RNA-dependent RNA polymerase (RdRp) domains: ProPol (a precursor comprised of both the proteinase and polymerase) and Pol (the mature polymerase). The goal of this study was to identify the active form (or forms) of the norovirus polymerase. The recombinant ProPol (expressed as Pro(-)Pol with an inactivated proteinase domain to prevent autocleavage) and recombinant Pol were purified after synthesis in bacteria and shown to be active RdRp enzymes. In addition, the mutant His-E1189A-ProPol protein (with active proteinase but with the natural ProPol cleavage site blocked) was active as an RdRp, confirming that the norovirus ProPol precursor could possess two enzymatic activities simultaneously. The effects of several UTP analogs on the RdRp activity of the norovirus and feline calicivirus Pro(-)Pol enzymes were compared and found to be similar. Our data suggest that the norovirus ProPol is a bifunctional enzyme during virus replication. The availability of this recombinant ProPol enzyme might prove useful in the development of antiviral drugs for control of the noroviruses associated with acute gastroenteritis.     

Dissection of two hallmarks of the open promoter complex by mutation in an RNA polymerase core subunit

Deletion of 10 evolutionarily conserved amino acids from the beta subunit of Escherichia coli RNA polymerase leads to a mutant enzyme that is unable to efficiently hold onto DNA. Open promoter complexes formed by the mutant enzyme are in rapid equilibrium with closed complexes and, unlike the wild-type complexes, are highly sensitive to the DNA competitor heparin (Martin, E., Sagitov, V., Burova, E., Nikiforov, V., and Goldfarb, A. (1992) J. Biol. Chem. 267, 20175-20180). Here we show that despite this instability, the mutant enzyme forms partially open complexes at temperatures as low as 0 degrees C when the wild-type complex is fully closed. Thus, the two hallmarks of the open promoter complex, the stability toward a challenge with DNA competitors and the sensitivity toward low temperature, can be uncoupled by mutation and may be independent in the wild-type complex. We use the high resolution structure of Thermus aquaticus RNA polymerase core to build a functional model of promoter complex formation that accounts for the observed defects of the E. coli RNA polymerase mutants.     

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.     

Two active forms of RD-114 virus DNA polymerase in infected cells.

Two forms of DNA polymerase are present in RD-114-infected human, dog, and mink cells, but are not detectable in uninfected cells. The two enzymes are indistinguishable catalytically and immunologically, but differ with respect to molecular weight and elution position from (dT)12-18-cellulose and phosphocellulose. The large enzyme (equivalent 95,000 daltons) is found in the infected cells, but not the virions produced by these cells. The virions contain only the smaller enzyme (equivalent 70,000 daltons). The larger form may represent a mammalian viral equivalent to the beta subunit of avian RNA tumor virus DNA polymerase.     

Escherichia coli RNA polymerase core and holoenzyme structures

Multisubunit RNA polymerase is an essential enzyme for regulated gene expression. Here we report two Escherichia coli RNA polymerase structures: an 11.0 A structure of the core RNA polymerase and a 9.5 A structure of the sigma(70) holoenzyme. Both structures were obtained by cryo-electron microscopy and angular reconstitution. Core RNA polymerase exists in an open conformation. Extensive conformational changes occur between the core and the holoenzyme forms of the RNA polymerase, which are largely associated with movements in ss'. All common RNA polymerase subunits (alpha(2), ss, ss') could be localized in both structures, thus suggesting the position of sigma(70) in the holoenzyme.     

Isolation and characterization of DNA-dependent RNA polymerase I of Tetrahymena pyriformis

A procedure for the separation and purification of DNA-dependent RNA polymerases [EC 2.7.7.6] from macronuclei of Tetrahymena pyriformis is described. We have used it to isolate and characterize the class I enzyme. RNA polymerase I was identified by its resistance against alpha-amanitin and its location in nucleoli. The purified enzyme consists of at least 12 major subunits with approximate molecular weights of 180,000, 118,000, 37,500, 36,000, 29,000, 27,500, 20,000, 18,500, 15,600, 14,500, 13,500, and 12,600. Chromatography on DEAE-Sephadex separated two forms of RNA polymerase I which differed in the presence of an additional polypeptide of 25 kDa. Independently of this polypeptide, the enzyme was found to segregate on DNA cellulose into a binding and a non-binding fraction. This type of heterogeneity was found to be unrelated to differences in molar ratios or molecular weights of the enzyme subunits. The catalytic properties of all enzyme subfractions were very similar and complied with the general characteristics of RNA polymerase I [cf. Roeder, R.G. (1976) in RNA Polymerase (Losick, R. & Chamberlin, M., eds.) pp. 285-329, Cold Spring Harbor Publ. Co., New York].     

The inhibition of mitochondrial DNA polymerase gamma from animal cells by intercalating drugs.

DNA polymerase gamma from purified nuclei of EMT-6 cells (mice) seems to be identical to the mitochondrial DNA polymerase from the same source following several criteria. These two enzyme activities are strongly inhibited by ethidium bromide and acriflavin, while proflavin, acridine orange, daunomycin and chloroquine inhibition is less pronounced. In the case of DNA polymerases alpha and beta very little inhibition by ethidium bromide was observed. Intercalation of this dye in a poly dA-dT 12-18 template-primer was studied spectrophotometrically under conditions similar to those in the in vitro DNA polymerase assay. The polymerase assay. The inhibition by this drug of the mitochondrial DNA polymerase gamma activity was shown to be competitive at varying concentrations of TTP while the inhibition was of the non-competitive type at different concentrations of poly dA-dT 12-18. We conclude that the drug, most probably in the intercalated form, is able to interact with the active site (s) of mitochondrial DNA polymerase.