Histone formation, gene expression, and zinc deficiency in Euglena gracilis

Histones, and other basic proteins, have been isolated from zinc-sufficient (+Zn) Euglena gracilis by standard chromatographic methods. These cells contain 2.46 micrograms of histones and 1.96 micrograms of DNA per 10(6) organisms. Each of the histones, H1, H3, H2A, H2B, and H4, is present in both log- and stationary-phase +Zn cells and has been characterized according to its electrophoretic mobility and molecular weight. H1 has been further identified on the basis of its amino acid composition and its cross-reactivity with calf thymus histone H1 antibodies. Similarly, H3 has been recognized as well by its specific reaction with an H3 antibody. In contrast, log-phase zinc-deficient (-Zn) cells contain H1 and H3 while H2A, H2B, and H4 are absent. All of the histones vanish in stationary-phase-Zn organisms. The DNA content increases as the -Zn cells progress from log to stationary phase, reaching a value of 4.40 micrograms/10(6) cells, double that of comparable stationary-phase +Zn organisms. A 2000-3000-dalton polypeptide whose electrophoretic behavior differs from that of the known histones constitutes over 90% of the total basic proteins of -Zn cells. On addition of zinc to stationary -Zn cells, cell division resumes, and all the histones and other basic proteins reappear. Together with previous results, the data demonstrate that zinc significantly affects the metabolism of all major chromatin components, i.e., the RNA polymerases, DNA, and histones of E. gracilis [Vallee, B.L., & Falchuk, K.H. (1981) Philos. Trans. R. Soc. London, Ser. B 294, 185-197]. The implications of these effects of zinc on chromatin structure and function are discussed.     

Comparison of the effects of polyamines on the activities of RNA polymerases from murine normal tissues and transplantable tumors

Nuclear DNA-dependent RNA polymerases I, II and III were purified from kidney, liver and spleen from Swiss mice (Mus musculis) and from seven transplantable murine tumors. In the presence of the optimal concentration of (NH4)2SO4 for each polymerase, 1-8 mM spermidine or spermine stimulated most polymerases several fold, and generally, enzyme I was stimulated more than either enzyme II or III. Spermine was more efficacious than spermidine as a stimulant of polymerase activity except for polymerase III from three tumors. Tumor polymerases I (or II) and the corresponding normal tissue enzymes responded similarly to the polyamines. Stimulation of a RNA polymerase by a polyamine could not be correlated with the growth rate of the tissues of polymerase origin or with the tissue's RNA polymerase or RNA synthetic activities.     

Purification and Subunit Structure of DNA-dependent RNA Polymerase III from Wheat Germ

A rapid and simple, large-scale method for the purification of DNA-dependent RNA polymerase III (EC 2.7.7.6) from wheat germ is presented. The method involves enzyme extraction at low ionic strength, polyethyleneimine fractionation, (NH₄)₂SO₄ precipitation, and chromatography on DEAE-Sepharose CL-6B, DEAE-cellulose, and heparin agarose. Milligram quantities of highly purified enzyme can be obtained from kilogram quantities of starting material in 2 to 3 days. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis indicates that RNA polymerase III contains 14 subunits with molecular weights of: 150,000; 130,000; 94,000; 55,000; 38,000; 30,000; 28,000; 25,000; 24,500; 20,500; 20,000; 19,500; 17,800; and 17,000. Subunit structure comparison of wheat germ RNA polymerases I, II, and III indicates that all three enzymes may contain common subunits with molecular weights 20,000, 17,800, and 17,000. In addition, RNA polymerases II and III may contain a common subunit with a molecular weight of 25,000, and RNA polymerases I and III may contain a common subunit with a molecular weight of 38,000.     

Immunological relationships between Artemia RNA polymerases and between RNA polymerases II from different eukaryotic organisms

Summary Rabbit antibodies against Artemia RNA polymerase II have been raised and utilized to study the immunological relationships between the subunits from RNA polymerases I, II and III from this organism and RNA polymerase II from other eukaryotes. We describe here for the first time the subunit structure of Artemia RNA polymerases I and III. These enzymes have 9 and 13 subunits respectively. The anti-RNA polymerase II antibodies recognize two subunits of 19.4 and 18 kDa common to the three enzymes, and another subunit of 25.6 kDa common to RNA polymerases II and III. The antibodies against Artemia RNA polymerase II also react with the subunits of high molecular weight and with subunits of around 25 and 33 kDa of RNA polymerase II from other eukaryotes (Drosophila melanogaster, Chironomus thummi, triticum (wheat) and Rattus (rat)). This interspecies relatedness is a common feature of eukaryotic RNA polymerases.Abbreviations RNAp RNA polymerase - DPT diazophenylthioether - SDS sodium dodecylsulfate     

DNA polymerase III from Saccharomyces cerevisiae. II. Inhibitor studies and comparison with DNA polymerases I and II

The newly identified yeast DNA polymerase III was compared to DNA polymerases I and II and the mitochondrial DNA polymerase. Inhibition by aphidicolin (I50) of DNA polymerases I, II, and III was 4, 6, and 0.6 micrograms/ml, respectively. The mitochondrial enzyme was insensitive to the drug. N2-(p-n-butylphenyl)-2'-deoxyguanosine 5'-triphosphate strongly inhibited DNA polymerase I (I50 = 0.3 microM), whereas DNA polymerase III was less sensitive (I50 = 80 microM). Conditions that allowed proteolysis to proceed during the preparation of extracts converted DNA polymerase II from a sensitive form (I50 = 2.4 microM) to a resistant form (I50 = 2 mM). The mitochondrial DNA polymerase is insensitive (I50 greater than 5 mM). With most other inhibitors tested (N-ethylmaleimide, heparin, salt) only small differences were observed between the three nuclear DNA polymerases. Polyclonal antibodies to DNA polymerase III did not inhibit DNA polymerases I and II, nor were those polymerases recognized by Western blotting. Monoclonal antibodies to DNA polymerase I did not crossreact with DNA polymerases II and III. The results show that DNA polymerase III is distinct from DNA polymerase I and II.     

Three distinct forms of DNA-dependent RNA polymerase III from kidney

DNA-dependent RNA polymerases were extracted from nuclei isolated from 1 kg of pig kidney and subjected to DEAE-Sephadex chromatography using a step-wise salt gradient. Fractions corresponding to RNA polymerase III were pooled and rechromatographed on a second DEAE-Sephadex column using a linear salt gradient. At least three distinct peaks, designated as IIIA, IIIB, and IIIC were resolved. These peaks exhibited α-amanitin dose response curves characteristic of RNA polymerase III. Detection of the enzyme was facilitated by assaying with either highly polymerized calf thymus DNA and spermine or with poly [d(A-T)]. The heterogeneity of this enzyme became even more pronounced after further purification. Under the same conditions, both RNA polymerases I and II were resolved at most to two subspecies. The highly heterogeneous nature of RNA polymerase III is consistent with the large number of RNA species believed to be synthesized by this enzyme class.     

Effect of 3-methylcholanthrene administration on hepatic ribonucleic acid polymerase activities

The effect of the in vivo administration of 3-methylcholanthrene upon rat hepatic RNA polymerase activities was investigated. Aggregrate RNA polymerase activity assayed in liver nuclei was stimulated by 33% over control. Characterization of the individual RNA polymerase activities by virtue of their differential sensitivity to α-amanitin revealed that RNA polymerase I activity was maximally increased by 70% at approx. 16 h post-administration of the polycyclic hydrocarbon; RNA polymerase II activity was stimulated by 33%. The kinetics of RNA polymerases I and II stimulation differed in that the nucleolar enzyme's activity increased earlier and peaked later. RNA polymerase III activity was not significantly different from control. Phenobarbital, another inducer of the mixed function oxidases, had essentially no effect on the activity of hepatic RNA polymerases. Solubilization of the RNA polymerases followed by separation on diethylaminoethyl (DEAE)-Sephadex allowed for a comparison of the treated and control enzymatic activities using a common exogenous template. While no qualitative difference was evident, RNA polymerases I and II isolated from 3-methylcholanthrene-treated rats again were more active than control, indicating an effect of the polycyclic hydrocarbon at the level of the enzyme.     

Modification of human DNA-dependent RNA polymerase activity by cyclic GMP.

The effect of low concentrations of cyclic GMP (guanosine 3':5'-cyclic monophosphate) on the in vitro enzymatic activities of DNA-dependent RNA polymerases isolated from human peripheral blood lymphocytes has been investigated. In agreement with earlier studies which employed isolated nuclei as the enzyme source, an increase in the activity of partially purified RNA polymerase I is observed in the presence of cyclic GMP (10(-8) to 10(-10)M). RNA polymerase II activity is inhibited by the presence of cyclic GMP at concentrations between 10(-4) and 10(-10)M. RNA polymerase III activity is stimulated in a bimodal fashion by the presence of cyclic GMP with maximal activity noted at 10(-8) to 10(-10) M and 10(-5)M. In addition, [3H]cyclic GMP binds specifically to chromatographic fractions which are known to contain RNA polymerases I, II and III. This binding to RNA polymerases II and III is apprarently less tenacious as demonstrated by dissociation studies. The observations provide additional evidence for a role for cyclic GMP in the regulation of RNA synthesis.     

Mouse Brain DNA-Dependent RNA Polymerases After Chronic Morphine Treatment

Abstract: Chronic morphine pellet implantation was found to decrease the specific activity of two forms of mouse brain RNA polymerase I and to alter the requirements of Mg²⁺ and Mn²⁺ for the activities of RNA polymerases II and III. DNA-dependent RNA polymerases were partially purified from small dense nuclei isolated from brains of naive and morphine tolerant-dependent mice, and three RNA polymerases were separated on a DEAE-Sephadex A-25 column. The three fractions, referred to as peak I, peak II, and peak III, were studied, characterized, and identified as being RNA polymerases I, II, and III, respectively. Chronic-morphine pellet implantation resulted in a lower specific activity of RNA polymerase I, but the specific activities of RNA polymerases II and III were not affected. This effect was prevented by preimplantation of a naloxone pellet and thus was narcotic-specific. Chronic morphine treatment lowered the concentration of Mg²⁺ required for optimal activity of RNA polymerase II and elevated the Mn²⁺-Mg²⁺ activity ratios of RNA polymerases II and III. A second DEAE-Sephadex A-25 column chromatography of the peak I RNA polymerase was carried out, revealing five component activity peaks. Two of these contained lower specific activities as a result of chronic morphine pelletimplantation. These specific changes in RNA polymerase function in morphine tolerance-dependence may be associated with the elevated chromatin template activities, altered chromatin phosphorylation, and elevated rates of cell-free translation that have been reported by others.     

Role of prostaglandins in aldosterone production by the human adrenal.

The subunits of purified yeast RNA polymerases I, II and III have been analyzed by two-dimensional polyacrylamide gel electrophoretic subunit mapping techniques. The results suggest that polymerases I and III have two subunits in common, the 41,000 and 20,000 dalton peptides, which are not present in polymerase III. The 14,500 dalton peptide by all criteria is identical in polymerases I, II and III. The 28,000 and 24,000 subunits appear identical in polymerases I and II but have different charge properties in polymerase III.     

Viral RNA synthesis and levels of DNA-dependent RNA polymerases during replication of adenovirus 2.

The rates of RNA synthesis in cultured human KB cells infected by adenovirus 2 were estimated by measuring the endogenous RNA polymerase activities in isolated nuclei. The fungal toxin alpha-amanitin was used to determine the relative and absolute levels of RNA polymerases I, II, and III in nuclei isolated during the course of infection. Whereas the level of endogenous RNA polymerase I activity in nuclei from infected cells remained constant relative to the level in nuclei from mock-infected cells, the endogenous RNA polymerase II and III activities each increased about 10-fold. These increases in endogenous RNA polymerase activities were accompanied by concomitant increases in the rates of synthesis in isolated nuclei of viral mRNA precursor, which was quantitated by electrophoretic analysis on polyacrylamide gels. The cellular RNA polymerase levels were measured with exogenous templates after solubilization and chromatographic resolution of the enzymes on DEAE-Sephadex, using procedures in which no losses of activity were apparent. In contrast to the endogenous RNA polymerase activities in isolated nuclei, the cellular levels of the solubilized class I, II, and III RNA polymerases remained constant throughout the course of the infection. Furthermore, no differences were detected in the chromatographic properties of the RNA polymerases obtained from infected or control mock-infected cells. These observations suggest that the increases in endogenous RNA polymerase activities in isolated nuclei are not due to variations in the cellular concentrations of the enzymes. Instead, it is likely that the increased endogenous enzyme activities result from either the large amounts of viral DNA template available as a consequence of viral replication of from replication or from functional modifications of the RNA polymerases or from a combination of these effects.     

Purification and Characterization of DNA-dependent RNA Polymerases from Cauliflower Nuclei

DNA-dependent RNA polymerases were solubilized from nuclei of cauliflower inflorescences and purified by agarose A-1.5m, DEAE-cellulose, DEAE-Sephadex, and phosphocellulose chromatography and sucrose density gradient centrifugation. RNA polymerases I + III were separated from II by DEAE-cellulose chromatography. Subsequent chromatography on DEAE-Sephadex resolved RNA polymerase I from III. RNA polymerases I and II were further purified to high specific activity by phosphocellulose chromatography and sucrose density gradient centrifugation. RNA polymerase I was refractory to α-amanitin at 2 mg/ml. RNA polymerase II was 50% inhibited at 0.05 μg/ml, and RNA polymerase III was 50% inhibited at 1 to 2 mg/ml of α-amanitin. The enzymes were characterized with respect to divalent cation optima, ionic strength optima, and abilities to transcribe cauliflower, synthetic, and cauliflower mosaic virus DNA templates.     

Multiple forms of DNA-dependent RNA polymerases in Xenopus laevis. Rapid purification and structural and immunological properties

DNA-dependent RNA polymerases I, II, and III (EC 2.7.7.6) were isolated from Xenopus laevis ovaries. The soluble enzymes were precipitated with polyethyleneimine and subjected to chromatography on heparin-Sepharose, DEAE-Sephadex, and phosphocellulose. RNA polymerase I was subjected to an additional chromatographic step on CM-Sephadex. The procedure required 40 h and produced purified RNA polymerase forms IA, IIA, and III in yields of 5 to 40%. The specific activities of RNA polymerases IIA and III (on native DNA) were comparable to those reported from other eukaryotic sources, whereas that of form IA was severalfold greater than the specific activities reported for other purified class I RNA polymerases. The complex subunit compositions of chromatographically purified RNA polymerases IA, IIA, and III were distinct when analyzed by polyacrylamide gradient gel electrophoresis under denaturing conditions, although all three classes contained polypeptides with Mr = 29,000, 23,000, and 19,000. Antibodies prepared against RNA polymerase III showed common antigenic determinants within the class I, II, and III enzymes. The sites responsible for the cross-reaction are located, at least in part, on the common 29,000-dalton polypeptide.