Nuclear phosphoprotein kinases and the regulation of gene transcription

Mechanisms of cAMP-mediated gene induction: examination of renal epithelial cell mutants affected in the catalytic subunit of the cAMP-dependent protein kinase

The precise mechanistic role of the cAMP-dependent protein kinase (cAMP-PK) in cAMP-mediated gene induction remains unclear. Renal epithelial cell mutants were compared to the LLC-PK1 parental cell line for induction of the cAMP-responsive urokinase-type plasminogen activator (uPA) gene, as quantitated by the technique of mRNA solution hybridization. The FIB4 and FIB6 mutants, which possess less than 10% parental cAMP-PK catalytic (C) subunit activity, showed markedly diminished uPA mRNA induction in response to agents elevating intracellular cAMP such as the cAMP analogue 8-bromo-cAMP and the adenylate cyclase-stimulating hormones vasopressin and calcitonin. In contrast, the mutant cells responded to a similar or greater extent than the parental cells in terms of uPA mRNA induction following treatment with the Ca2+/phospholipid-dependent protein kinase activator phorbol 12-myristate 13-acetate (PMA). Elevation of intracellular cAMP was found to induce a translocation of the cAMP-PK C subunit from the perinuclear Golgi region to the nucleus in both parental and mutant cell lines, as shown by immunocytochemical techniques. Results argue for the role of the cAMP-PK C subunit activity and possibly nuclear translocation of the C subunit in cAMP-mediated uPA induction, which is mechanistically distinct from the PMA-stimulated response.

Role of site-selective cAMP analogs in the control and reversal of malignancy

Two isoforms of cAMP receptor protein, RI and RII, the regulatory subunits of cAMP-dependent protein kinase, transduce opposite signals, the RI being stimulatory and the RII being inhibitory of cell proliferation. In normal cells RI and RII exist at a specific physiological ratio whereas in cancer cells such physiological balance of these receptor proteins is disrupted. Reversal and suppression of malignancy can be achieved when the physiologic ratio of these intracellular signal transducers of cAMP is restored as shown by the use of site-selective cAMP analogs, antisense oligodeoxynucleotides or gene transfer, suggesting new approaches to cancer control.

Chronic antidepressant administration alters the subcellular distribution of cyclic AMP-dependent protein kinase in rat frontal cortex

The influence of chronic administration of antidepressants on cyclic AMP-dependent protein kinase activity was examined in rat frontal cortex. Chronic administration of imipramine, tranylcypromine, or electroconvulsive seizures decreased cyclic AMP-dependent protein kinase activity in soluble fractions by approximately 25%, whereas enzyme activity was increased in the particulate fractions by approximately 20%. In contrast, enzyme activity in crude homogenates was not altered. This effect appears to be specific to antidepressant drugs, because representatives of several other classes of psychotropic drugs-namely, haloperidol, morphine, and diazepam--failed to alter either soluble or particulate levels of cyclic AMP-dependent protein kinase activity in this brain region following chronic administration. When the total particulate fraction was subfractionated, it was found that chronic imipramine treatment significantly increased the activity of cyclic AMP-dependent protein kinase in crude nuclear fractions but not in crude synaptosomal or microsomal fractions. Taken together, the data raise the possibility that chronic antidepressant treatments may stimulate the translocation of cyclic AMP-dependent protein kinase from the cytosol to the nucleus. This effect would represent a novel action of antidepressants that could contribute to the long-term adaptive changes in brain thought to be essential for the clinical actions of these treatments.

Cyclic AMP has the ability to influence multiple events during B cell stimulation

Negative regulators of cellular proliferation are important in maintaining a balanced growth control. In this study we have examined the effects of the diterpene forskolin on various parameters of B cell activation. Forskolin is known to elevate intracellular adenosine 3',5'-cyclic monophosphate (cAMP) levels and thereby to influence B cell stimulation. We found that forskolin exerted an inhibitory effect on early as well as late events during stimulation of resting normal human B cells. Cells were activated either by antibodies to surface immunoglobulins (anti-mu), by the monoclonal antibody 1F5 reactive with the CD20 antigen or by 12-O-tetradecanoylphorbol 13-acetate. While anti-mu stimulation induces increased phosphatidylinositol (PI) turnover and [Ca2+]i fluxes, the latter two reagents confer an activation of B cells independent of the PI/Ca2+ pathway. We found a clear inhibitory effect of forskolin on the anti-mu-induced PI turnover and [Ca2+]i fluxes as well as on later parameters of cell activation. There was also a clear inhibition of G1 entry and DNA synthesis when PI/Ca2+-independent activation was employed, indicating that cAMP interferes with B lymphocyte stimulation in several ways. Importantly, forskolin maintained its inhibitory effect when added late after anti-mu stimulation, implying an effect also at multiple stages of activation. When examining the inhibitory effect of forskolin on neoplastic B cells, we found essentially no differences from the responses in normal cells.

Soluble cAMP-independent protein kinase from human spleen

A protein kinase (EC 2.7.1.37) was purified 2000-fold, from the soluble protein fraction of human spleen cells, using ion-exchange chromatography, ammonium sulfate fractionation, and gel filtration. This rapid procedure yielded 30% of the initial activity and an enzyme preparation with specific activity of 62 nmol min-1 mg-1 of protein. On the basis of disc gel electrophoresis in sodium dodecyl sulfate acrylamide gels and isoelectric focusing the enzyme preparation appears homogeneous and to consist of one polypeptide with a molecular weight of 43,000 and having a pI of 7.1. The purified enzyme activity is cyclic AMP and cGMP independent phosphorylates both alpha-casein and phosvitin, and uses Mg2+ ATP and Mg2+ GTP as phosphate donors, exhibiting an apparent Km of 2.0 and 6.6 X 10(-5)m, respectively. Furthermore, the enzyme activity is strongly inhibited by heparin (K50 = 0.1 micrograms/ml). These catalytic properties are characteristic of the enzyme casein kinase II, as described in several eukaryotic cells.

Site-selective cAMP analogs induce nuclear translocation of the RII cAMP receptor protein in Ha-MuSV-transformed NIH/3T3 cells

Site-selective cAMP analogs, depending on the position of their substituents on the adenine ring, selectively bind to either site 1 or site 2 of the known cAMP binding sites of protein kinase. Treatment of Harvey murine sarcoma virus-transformed NIH/3T3 cells with such site-selective analogs results in growth inhibition and phenotypic reversion, and the combination of a C-8 thio or halogen analog (site 1 selective) with an N6 analog (site 2 selective) produces a synergistic effect. We report here that the growth inhibitory effect of the analogs correlates with the nuclear translocation of the RII cAMP receptor protein, the regulatory subunit of protein kinase type II. The transformed NIH/3T3 cells contained no detectable level of RII in the nucleus, whereas nontransformed NIH/3T3 cells exhibited a high level of nuclear RII. Within 30 min after treatment of the transformed cells with the site-selective analogs, immunofluorescence against the RII protein markedly increased in the cell nucleus. The nuclear translocation of the RII cAMP receptor protein is an early event in the reverse transformation of the fibroblasts treated with site-selective cAMP analogs.

Identification of nuclear substrates of the cyclic AMP-dependent protein kinase in Dictyostelium discoideum

A search for nuclear substrates of the cAMP-dependent protein kinase (cAMP-d PK) of Dictyostelium discoideum led to the identification of several such proteins. Identification was based initially on increased phosphorylation of the proteins in nuclear extracts catalyzed by added cAMP-d PK. One protein of Mr 38,000 was phosphorylated also in intact nuclei and in vivo; the amount of phosphoprotein or the level of phosphorylation increased during development. Both the Mr 38,000 protein and another substrate of Mr 195,000 were found in the nuclei of prespore and prestalk cells. Phosphorylation of other potential substrates of the cAMP-d PK was either prespore or prestalk cell-specific.

Activity of DNA and RNA polymerases in resurfacing rabbit corneal epithelium

Activity of RNA polymerases I, II and III (distinguished using alpha-amanitin) and activity of DNA polymerases alpha and beta (distinguished using N-ethylmaleimide) were assayed for varying intervals and at varying substrate (UTP or dTTP) concentrations in the purified nuclear fraction from corneal epithelium of carbamylcholine-treated and control eyes of rabbits with resurfacing acid burn defects. Incorporation was linear with time for all enzymes up to 30 min. In 10 min assays at varying substrate concentrations, all polymerases from carbamylcholine-treated eyes had significantly elevated Vmax compared to corresponding control enzymes. The drug also increased apparent affinity of RNA polymerase II for UTP and apparent affinity of DNA polymerases alpha and beta for dTTP. Results are discussed in relation to potential mechanisms by which effects of carbamylcholine on polymerase activity may be mediated.

Regulation of lactate dehydrogenase gene expression by cAMP-dependent protein kinase subunits

The studies described in this report suggest a rather complex, albeit incomplete, sequence of molecular events that we believe form part of the cascade of reactions through which a series of hormones, via cAMP, regulates the expression of specific gene products. The majority of our own studies relate to cAMP-mediated induction of LDH. Some, if not all, of the molecular steps discussed in this paper may ultimately be recognized as part of a universal mechanism by which cAMP controls gene expression in higher eukaryotes. The idea of a functional role for cAMP-dependent protein kinase subunits in cAMP-mediated gene control has already had experimental support, but our identification of the regulatory subunit RII as a topoisomerase now more firmly points to a complex function for the kinase in regulating gene function at the DNA level. We look forward to the elucidation of the function of those nuclear proteins that serve as substrate for the catalytic subunit of cAMP-dependent protein kinase. Further studies related to the molecular interaction of RII with chromosomal DNA should be a fruitful area for future research.

Exocytosis in rat parotid acini after in vitro treatment with forskolin is accompanied by cellular redistribution of regulatory subunits of cyclic AMP-dependent protein kinase

Incubation of rat parotid acinar tissue with 1 mumol/L forskolin resulted in progressive exocytosis which was virtually complete after a 30-minute incubation period. Cyclic AMP binding to protein kinase (cA-PK) regulatory (R) subunits, determined by photo-affinity labeling with [32P]-8-azido cyclic AMP, was found to increase in a time-dependent manner in the 10,000-g supernatant fraction of a broken cell preparation. An apparent redistribution of protein kinase R subunits took place in the 600-g supernatant after in vitro treatment of cells with forskolin. In control cells, RI and RII subunits and a 35-to-40-kdal fragment were present in approximately equal amounts throughout the incubation. Azido labeling of RII appeared either to increase or to remain unchanged, while that of RI decreased in the 600-g pellet. Only type I isozyme R subunits were found in the 600-g pellet in either the absence or presence of forskolin. These finding indicate that a temporal relationship exists between stimulated protein exocytosis and cyclic AMP-dependent protein kinase activation. Forskolin stimulation of adenylate cyclase in salivary gland cells therefore provides a defined system for the study of cyclic AMP-mediated protein secretion.

The nuclear matrix is the site of glucocorticoid receptor complex action in the nucleus

Binding of highly purified glucocorticoid receptor complexes to nuclear matrix was evaluated. Extraction of purified nuclei with 2M potassium chloride and brief deoxyribonuclease digestion leaves a matrix structure containing 1% of nuclear DNA and 6-12% of nuclear proteins. The nuclear matrix retained two binding sites for receptor complexes, a high affinity, low capacity site and a low affinity, high capacity site. These sites have affinities and capacities consistent with those reported for binding of these complexes to intact nuclei. More extensive deoxyribonuclease treatment of the matrix resulted in a marked reduction of high affinity complex binding. Furthermore, the DNA binding form of the receptor complex but not the unactivated receptor complex bound to DNA fibers anchored to nuclear matrix as visualized by 18 nm gold particle receptor complexes. The data suggest that the nuclear matrix is the major site for coordinating glucocorticoid hormone action in the nucleus.

Quantitative changes in the catalytic and regulatory subunits of nuclear cAMP-dependent protein kinases type I and type II during isoproterenol-induced growth of the rat parotid gland

To quantify the cAMP-dependent protein kinases I and II in parotid gland nuclei independent of the enzyme activity, monospecific antisera against their subunits were applied in a sensitive enzyme immunoassay. About 3% of total catalytic subunit in the homogenate was found in the isolated nuclei. During beta-agonist-induced proliferation of the parotid gland the nuclear concentration of catalytic and regulatory subunits changed. Related to the number of nuclei, the catalytic subunit and the regulatory subunit RI increased about 3-fold whereas the regulatory subunit RII remained unchanged.

Cyclic nucleotides in muscarinic regulation of DNA and RNA polymerase activity in cultured corneal epithelial cells of the rabbit

DNA and RNA polymerase activities in the purified nuclear fraction from cultured rabbit corneal epithelial cells were assayed over a range of substrate (labeled dTTP or UTP) concentrations using calf thymus DNA as template. Effects of carbamylcholine on polymerase activities were evaluated over a range of drug concentrations including those saturating muscarinic receptors. Carbamylcholine significantly (p less than 0.001) enhanced activity of both polymerases, both in nuclei incubated with the drug during assay and in nuclei from carbamylcholine-treated cells. Drug effects were blocked by atropine. Regression analysis of Hill plots for variation of polymerase activity with carbamylcholine concentration indicated half-maximal activity of both polymerases at approximately 1 microM carbamylcholine. Mechanisms by which carbamylcholine may alter polymerase activities are discussed in relation to effects of the drug on nuclear enzymes of cyclic nucleotide metabolism and on cyclic nucleotide-dependent protein phosphorylation.

The phosphoform of the regulatory subunit RII of cyclic AMP-dependent protein kinase possesses intrinsic topoisomerase activity

The phosphoform of the type II regulatory subunit (phospho-RII-cAMP) of cAMP-dependent protein kinase from rat liver was found to possess intrinsic topoisomerase activity towards several DNA substrates such as phi X174, pBR322, SV40, and M13. Like the type I topoisomerases from several eukaryotic cells, phospho-RII X cAMP can relax both positive and negative superhelical turns of phi X174 DNA. Topological isomers with a decreasing number of superhelical turns can be identified as transient products. Conditions under which phospho-RII X cAMP relaxes superhelical phi X174 DNA lead to transient formation of a DNA-phospho-RII X cAMP complex via DNA strand breakage and covalent attachment of the DNA to a tyrosine residue of phospho-RII X cAMP via a phospho-RII X cAMP depends on the presence of cAMP and is altered by changes in the degree of phosphorylation of RII. Both dephosphorylation and removal of cAMP from phospho-RII X cAMP abolish its topoisomerase activity.

Two classes of cAMP analogs synergistically inhibit p21 ras protein synthesis and phenotypic transformation of NIH/3T3 cells transfected with Ha-MuSV DNA

Factors that control cellular proliferation might do so by regulating quantitative expression of viral or cellular oncogenes. Since the growth regulatory effect of cAMP is well-known, the effect of cAMP on ras gene expression was examined on Ha-MuSV-transformed 13-3B-4 cells (NIH-3T3) grown in chemically defined serum-free medium. Treatment of cells with two classes of cAMP analogs which are selective for the two different cAMP-binding sites of type II protein kinase, in combination, synergistically inhibited both p21 ras protein synthesis and phenotypic transformation. The inhibition was also demonstrated with these analogs singly but at higher concentrations. The decrease in p21 synthesis was inversely correlated with an increase in the RII cAMP receptor protein, the regulatory subunit of type II protein kinase. These results suggest a role for cAMP and its receptor protein in the regulation of v-rasH oncogene expression.

Cyclic AMP regulation of eukaryotic gene transcription by two discrete molecular mechanisms

In experiments designed to study the mechanism by which peptide hormones binding to their plasma membrane receptors stimulate the expression of specific genes, the transcription of two neuroendocrine genes, prolactin and growth hormone, was analyzed in a rat pituitary cell line. The results showed that cyclic adenosine monophosphate (cyclic AMP) stimulates the transcription of discrete subsets of eukaryotic genes by at least two independent molecular mechanisms. Cyclic AMP stimulated growth hormone gene transcription and phosphorylation of a 19,000-dalton nuclear protein; this appears to reflect direct nuclear actions of the cyclic AMP-dependent protein kinase. In contrast, the stimulation by cyclic AMP of prolactin gene transcription appears to reflect activation of a discrete calcium-dependent event.

Induction of a substrate for casein kinase II during lymphocyte mitogenesis

Particulate fractions prepared from concanavalin A-activated murine T lymphocytes contain an endogenous protein kinase that phosphorylates an endogenous protein substrate of Mr 112 000. The phosphorylation of 112 kDa protein is greatly reduced or absent in unstimulated T cells. Phosphoamino acid analysis indicates that 112 kDa protein is labeled on a serine. Add-back experiments using purified protein kinases indicate that 112 kDa protein serves as a substrate for casein kinase II. Phosphorylation of 112 kDa protein by the endogenous kinase is inhibited by heparin, a known casein kinase II inhibitor. The site or sites modified by the endogenous kinase and exogenous casein kinase II appear identical by peptide-mapping experiments. A time-course of the appearance of phosphorylated 112 kDa protein following stimulation with concanavalin A, measured in the presence or absence of added casein kinase II, suggests that 112 kDa protein is induced in activated T cells. Subcellular localization studies suggest that 112 kDa protein is a nuclear protein. Silver-binding and purification studies suggest that 112 kDa protein is of the nucleolar organizing region.

Effects of FSH on acidic nuclear protein synthesis in cultured pig Sertoli cells

We studied the effect of FHS on nuclear protein synthesis by a primary culture of immature porcine Sertoli cells. The cells were cultured in a chemically defined medium and treated with FSH (50 ng/ml) for various periods (4, 8, 25 and 64 h). About 65 spots (pHi less than 8) were identified by two-dimensional polyacrylamide gel electrophoresis of the radiolabelled nuclear proteins. After 25 h of FSH treatment, we observed an increase of 5 proteins, a slight decrease of two and a disappearance of one. For the short periods of FSH treatment (4 and 8 h), no effect of FHS on nuclear protein synthesis was observed. After 64 h of FSH treatment (4 and 8 h), no effect of FHS on nuclear protein synthesis was observed. After 64 h of FSH treatment, the synthesis of all nuclear proteins appears to be decreased.

Nuclear cAMP-dependent protein kinase in rat parotid acinar cells

Receptor interactions of parotid acinar cells with beta-agonists are mediated by cyclic 3',5'-monophosphate (cAMP) and expressed as cAMP-dependent protein kinase (cAPK) activation. In addition to its location in the cytoplasm, we have shown that cAPK is associated with the nuclear non-histone protein (NHP) fraction (0.35 M NaCl extract) of rat parotid acinar cells. Nuclei were prepared from isolated parotid acini with minimal contamination from other cell types or cytoplasmic components. The nuclear cAPK activity was inhibited by the thermostable inhibitor and was stimulated by the addition of exogenous cAMP to the assay, indicating that the enzyme is present in the holoenzyme form. Enzyme activity was not increased in the presence of detergent, suggesting that cAPK is not bound to the nuclear membrane. Photoaffinity-labeling studies with an 8-azido analog of cAMP showed that regulatory subunits of both type I and type II cAPK isozymes are present in parotid cell nuclei. Short-term in vitro stimulation of the acini with 10(-6) M isoproterenol did not alter cAPK activity in the nuclear fraction. These findings indicate that compartmentation of cAPK into nuclear and extranuclear locations in rat parotid acinar cells is similar to that of several other cell types which are responsive to hormonal stimulation.

Polyamine-mediated protein phosphorylations: a possible target for intracellular polyamine action

Polyamines are well-known ubiquitous components of living cells. Although these polycations have been implicated in the regulation of major cellular functions such as DNA, RNA and protein synthesis occurring during cellular proliferation and/or differentiation processes, their mechanism of action at the molecular level has remained obscure. On the other hand, protein phosphorylation has emerged as a regulatory process of prime importance in cellular regulation. Data have recently been presented suggesting that polyamines may express at least part of their biological action through an effect upon selective protein phosphorylation systems. Two types of polyamine-sensitive protein kinases have been characterized in the last few years. The best known in molecular terms is the widespread casein kinase G (also termed casein kinase II), which represents a multifunctional protein kinase, at present classified as a messenger-independent activity. The other is a polyamine-dependent nuclear ornithine decarboxylase kinase characterized in Physarum polycephalum and several mammalian tissues. Both protein kinases are activated by polyamines in vitro at concentrations compatible with a physiological role, by a mechanism which most likely also involves an effect through the protein substrate conformation. Preliminary evidence suggests that both kinases may be implicated in the regulation of DNA-dependent RNA polymerase activities, although several other potential substrates have been suggested for casein kinase G. Another suggestion is that these kinases may also participate in the post-translational regulation of ornithine decarboxylase, the rate-limiting step in the polyamine biosynthetic pathway. A novel class of protein kinase activities may thus be defined as polyamine-mediated phosphorylation systems for which polyamines may function as intracellular messenger. Although their biological significance remains to be fully established, especially with regard to the definition of their specific intracellular target(s) and subsequent biological functions, these systems will be interesting to consider in future studies aimed at understanding the role of polyamines in cell regulation.

A variant tandemly repeated nucleotide sequence in Balbiani ring 2 of Chironomus tentans

pCtBR2-2 is a genomic clone from Chironomus tentans that hybridized in situ to Balbiani ring 2 (BR2) on salivary gland polytene chromosome IV. DNA sequencing indicated that the insert contained nearly four copies of a 180 bp tandemly repeated nucleotide sequence that was distinctly different from a previously reported BR2 repeat. Sequence titration experiments detected about 70 copies of the 180 bp repeat per haploid genome, which would correspond to approximately 34% of a 37 kb BR2 gene. Each 180 bp repeat included a conserved 90 bp segment whose sequence was internally nonrepeating (INR), and a variable 90 bp repeated (R) segment comprised of three 30 bp repeats that may have evolved from a 9 bp consensus sequence. Results presented here raise the distinct possibility that other BR genes may contain significantly different repeated sequences that have not been identified.

Fractionation and partial purification of rat liver nuclear protein kinases

We have fractional and partially purified several rat liver nuclear protein kinases by utilizing endogenous (nonhistone proteins) and exogenous acidic (dephosphophosvitin) and basic (lysine-rich histone) protein substrates. Three enzymes were active towards endogenous substrates, two towards dephosphophosvitin and two towards lysine-rich histone. Of the latter only one was cAMP-dependent, however, only minimal cAMP binding activity was detected. Several features of these enzyme reactions are described revealing distinct differences in the characteristics of each of these enzymes.

Increased phosphorylation of nuclear protein in myonuclei isolated from denervated skeletal muscle

The slow-twitch soleus muscle of the rat hindlimb was denervated by cutting the sciatic nerve in the midthigh on one side. A sham operation was performed on the contralateral side to provide a control soleus muscle. At 24, 48, 72, and 120 hours after these surgical procedures, the animals were sacrificed and the nuclei which were isolated from these muscles incubated in a phosphorylating medium containing [gamma-32P]ATP. At the 48 hour denervation period only, the in vitro phosphorylation of TCA-precipitable nuclear proteins was significantly increased compared to control values. Resolution of the SDS-solubilized nuclear proteins by polyacrylamide gel electrophoresis revealed that the increased phosphorylation was more marked in some phosphoproteins than others. The significance of these early denervation changes are discussed with respect to increases in the activities of the nuclear RNA polymerases and changes in the phosphorylation of cytosolic protein.

Polyamines modulate phosphorylation and acetylation of non-histone chromosomal proteins of the cerebral cortex of rats of various ages

In vitro phosphorylation and acetylation of NHC (non-histone chromosomal) proteins and their modulation by spermine and spermidine were studied using slices of cerebral cortex of female albino rats of various ages. The total DNA, histone and NHC proteins do not change significantly with age. Phosphorylation and acetylation of total and individual NHC proteins decreases with increasing age of the rat. Spermine and spermidine stimulate phosphorylation and acetylation of specific NHC proteins in immature rats. This effect decreases with increasing age. It is suggested that such modulatory effects of polyamines may cause alterations in the expression of specific genes during aging.

Biochemical characterization of a specific phosphate acceptor of nuclear cyclic AMP-independent protein kinase

The regulatory mechanism of transcription involved in the phosphorylation of a 13 kDa non-histone chromatin protein from calf thymus, which is the most effective phosphate acceptor for cyclic AMP-independent protein kinase purified from the nuclei of mouse spleen cells, by the kinase has been studied in vitro. An analytical study of the circular dichroism (CD) spectra of the 13 kDa protein under different conditions showed that it underwent a major conformational change when incubated with DNA. The presented data suggest that the DNA-induced conformational change may result in a great increase of the 13 kDa protein phosphorylation by the kinase in vitro. Mg2+ (8-10 mM) enhanced the binding of the protein to DNA. Furthermore, the phosphorylated 13 kDa protein stimulated elongation of RNA synthesis by RNA polymerase II from calf thymus. However, neither the 13 kDa protein nor the phosphorylated 13 kDa protein had any affect on DNA synthesis. The available evidence suggests that the 13 kDa protein may play a role in the regulation of transcription through its phosphorylation by the kinase in vitro.

Influence of 3-methylcholanthrene on liver nucleolar and nucleoplasmic activities of protein kinases and RNA polymerases

The experiments were designed to investigate some details of the action of 3-methylcholanthrene (3-MC) on the regulation of transcription. After a single intraperitoneal dose of 3-MC a significant increase in the activities of both nucleolar and nucleoplasmic protein kinases in hepatic cells of young rats was found. The maximal stimulation took place 24 hr after the administration of 3-MC and the extent of activation was much greater in the nucleolar fraction. There is a significant elevation of the activities of both functional forms, free and template-engaged, of RNA polymerase A 24 hr after a single injection of 3-MC. Free and engaged forms of extranucleolar RNA polymerase B show a different behaviour: after 24 hr of 3-MC administration the engaged form is markedly enhanced while the activity of the free enzyme shows a significant decrease. The more moderate increase in total RNA polymerase B activity is obviously preceded by a transfer of the enzyme from 'free' to 'engaged' form. Since the enhancement of protein kinase activities was accompanied by the stimulation of nuclear RNA polymerases we suggest that both kinds of enzymes are involved in an epigenetic mechanism of the inducing action of 3-MC on cytochrome P1-450.

DNA-dependent RNA polymerases from bovine thyroid: catalytic properties and template specificities

1. DNA-dependent RNA polymerases I and II have been purified starting from bovine thyroid nuclei yielding a purification factor of 230 for the RNA polymerase I and a purification factor 3212 for RNA polymerase II. RNA polymerase II was further characterized by gel electrophoresis and amino-acid analysis. 2. Kinetics and optimal assay conditions for both RNA polymerases were studied. 3. The template efficiency of a number of DNA preparations was investigated. 4. Rifamycin AF 013 and heparin act as initiation inhibitors. 5. Polyamines were shown to enhance the rate of chain elongation.