Guinea pig skeletal muscle 5′-nucleotidase

ATP, UTP, GTP, and CTP were found to be powerful competitive inhibitors of 5′-nucleotidase partially purified from guinea pig skeletal muscle, the concentrations required for 50% inhibition being 1.25 uM, 5.5 uM, 10 uM and 27.5 uM respectively with 5′-AMP as substrate. The enzyme does not require divalent cations. Furthermore magnesium, calcium and cobalt ions added in large excess with respect to nucleoside triphosphates did not completely relieve the inhibition, indicating that the complexes nucleoside triphosphates-divalent cations are also inhibitors. Using specific optical assays to follow the dephosphorylation of AMP, GMP and IMP it was found that the hydrolysis of each 5′-mononucleotide is competitively inhibited by other 5′-mononucleotides. The regulation of skeletal muscle 5′-nucleotidase supports the hypothesis of its role in the mechanism of muscular contraction.     

Studies on ribonucleic acid and homopolyribonucleotide formation in neuronal, glial and liver nuclei

1. Various types of nuclear preparations, with different ratios of neuronal to glial nuclei, were isolated from guinea-pig cerebral grey matter and ox cerebral grey matter and white matter. Conditions appropriate for the separate assay of RNA and poly A formation were described. Comparative rates of RNA and poly A formation were studied in cerebral and liver nuclei. 2. RNA polymerase activity per nucleus is higher in neuronal nuclei than in glial nuclei. In liver nuclei, the activity is much lower than in cerebral nuclei. The physical relationship between RNA polymerase and deoxyribonucleoprotein seems to differ in neuronal, glial and liver nuclei. 3. Poly A polymerase activity in liver nuclei is selectively activated by Mn(2+) and inhibited by GTP, CTP and UTP. On a DNA basis, the activity in an aggregate enzyme is the same as in intact nuclei. Poly A polymerase activity per nucleus is much higher in liver nuclei than in neuronal nuclei. Glial nuclei show an intermediate activity. 4. It is suggested that, in neuronal nuclei, the synthesis of RNA is more prominent than that of poly A under conditions where both polymers are formed simultaneously. This contrasts with liver nuclei, where more poly A is made than RNA. 5. In neuronal nuclei, the rate of CTP incorporation is much higher than in glial and liver nuclei. This incorporation is most probably due to poly C synthesis.     

Studies on ribonucleic acid metabolism using nuclear columns. Release of rapidly labeled RNA from rat liver nuclei.

A method is described to study the effect of successively changing incubation conditions on the release of rapidly labeled RNA from isolated nuclei. Nuclear columns containing immobilized rat liver nuclei isolated after in vivo application of labeled orotic acid are perfused with different non-radioactive media. Within the course of one perfusion, the rate of RNA release can be repeatedly altered by variation of temperature, acidity and concentrations of nucleoside triphosphates, complexing agents, sodium chloride and manganese chloride. RNA release can be started and stopped, indicating that the reaction does not result from damage to nuclei. During 60 min perfusion the same product, labeled ribonucleoprotein (sigma = 1.43 g/cm3 in CsCl), is released. High release rates depend on the ratio of nucleoside triphosphate to divalent cation concentration, not on the concentration of the agents per se. Ribonucleoside and deoxyribonucleoside triphosphates exert the same effect as ATP. The SH reagents iodoacetamide and iodoacetate only slightly affect the ATP-induced reaction. In contrast, p-chloromercuribenzoate, after an initial stimulation, causes inhibition of RNA release.     

EFFECT OF GTP AND OTHER NUCLEOSIDE TRIPHOSPHATES ON GMP INCORPORATION BY ISOLATED CORTICAL NUCLEI

—The concentration of GTP was found to be critically important in determining the characteristics of incorporation of GMP by DNA-dependent RNA polymerase from rat brain nuclei. The linearity of the incorporation rate was related to the log of the GTP concentration. Three hundred μM-GTP in the presence of the other nucleoside triphosphates (1 mM) was near to the optimal conditions in terms of maximum incorporation and linearity. The concentration of ammonium sulfate was an important factor in determining the maximum GMP and UMP incorporation. The U/G incorporation ratio was less than one at low concentrations of substrate and increased with increasing substrate or ammonium sulfate concentration. α-Amanitin strongly inhibited the reaction, indicating that RNA polymerase II is the effective enzyme.     

Erratum

RNA polynucleotide kinase has been shown to transfer [γ³²P] from ATP to 5-OH termini of endogenous nuclear RNA. The products of this reaction have been isolated in RNA larger than 125 after in vitro incubation of mouse L cell nuclei. About 20%–30% of these 5′-OH kinase products are polyadenylated. A sizeable fraction of the [γ³²P] label from ATP is also found in internal phosphodiester bonds after 30-minute nuclear incubation in vitro. The possibility of substantial [³²P] recycling via the α position of nucleoside triphosphate was ruled out because: (1) 2mM nucleoside triphosphates in the incubation medium, (2) limited nearestneighbor distribution 3′ and 5′ to the phosphodiester bond compared with that from [α³²P] UTP, (3) different nearest-neighbor distribution for RNA molecules > 12S and 12-3S, (4) relative insensitivity of the [γ³²P] incorporation to α-amanitin as compared with total RNA synthesis, (5) internal [³²P] appearance in RNA > 12S in less than five minutes of incubation, and (6) < 0.03% to 0.6% of the total [³²P] in the α position of nucleoside triphosphates after 30 minutes of incubation. The [γ³²P] incorporation was dependent on high ATP concentration and was insensitive to competition by inorganic phosphate. These results are consistent with the levels of 5′ RNA polynucleotide kinase activity in L cell nuclei and suggest the presence of an RNA ligase that can utilize the termini generated by the 5′-OH RNA kinase in a ligation reaction.     

Enzymatic synthesis of cytidine diphosphate diglyceride

Evidence is presented for the enzymatic formation of cytidine diphosphate diglyceride in microsomal preparations from guinea pig liver according to the reaction: CTP + phosphatidic acid right harpoon over left harpoon CDP-diglyceride + p-O-P. Conditions have been found in which the incorporation of labeled CTP into CDP-diglyceride is almost entirely dependent upon added phosphatidic acid. The incorporation of CMP into lipid is very slight. A substantial net synthesis of CDP-diglyceride takes place under these conditions. Some properties of the enzyme system are described.     

Activation of a latent RNAase from yeast by nucleoside triphosphates

A latent RNAase activity stimulated by nucleoside triphosphates has been isolated from a yeast chromatin extract, by filtration on Sepharose 6B and hydroxyapatite chromatography. The RNAase was separated from a thermolabile proteic inhibitor on phosphocellulose. When separated from the inhibitor, the RNAase hydrolyses RNA to 5′-mononucleotides. Its activity is retained in the presence of EDTA, and 50% inhibited by 1 mM ATP or CTP. The RNAase is inhibited by the thermolabile component only in the presence of divalent cations. The activity is recovered upon addition of 0.01 mM ATP to the mixture. The K_m for ATP is 10 μM. ATP can be replaced by other ribo- or deoxyribonucleoside triphosphates with varying efficiency but not by ADP, AMP or cAMP. These results suggest multiple interactions between the RNAase, a regulatory component, divalent cations and nucleoside triphosphates.     

RNA transport from isolated nuclei of cultured Djungarian hamster cells

The in vitro system of RNA transport containing isolated nuclei of Djungarian hamster cells transformed by SV-40 virus was studied. A functional test for cytoplasmic contaminations of the nuclei was proposed. The release of the newly synthesized RNA was found to be dependent on the duration of incubation, temperature and pH of the incubation medium as well as on the presence of spermine, spermidine, dithiothreitol, Mg2+, EDTA, exogenous RNA, nucleoside triphosphates and cytosol. The results obtained indicate that RNA release is an active process with activation energy of 12 kcal/mol. ATP, GTP, CTP and UTP have equal ability to serve as energy sources for the release of RNA. The nucleoside triphosphatase activity of the nuclei was the same in the presence of these four nucleoside triphosphates.     

Inhibitory effects of nucleoside triphosphates on nucleolar RNA synthesis.

Studies on the effects of substrates on RNA polymerase I [EC 2.7.7.6] in vitro showed that nucleolar RNA synthesis was inhibited by an excess of substrate nucleoside triphosphates in the presence of Mg2+. GTP and UTP were more inhibitory than CTP and ATP. These compounds specfically inhibited nucleolar RNA synthesis and a concentration of GTP that strongly inhibited nucleolar RNA synthesis did not inhibit RNA synthesis by partially purified RNA polymerase I. The inhibition of nucleolar RNA synthesis disappeared at pH 9.0 without any change in the apparent Km for GTP or the Vmax of RNA synthesis.     

AN ENZYME SYSTEM IN RAT BRAIN NUCLEI INCORPORATING AMP INTO POLYADENYLATE

Abstract— The presence of an ATP polymerizing system has been demonstrated in rat brain nuclei. The enzymic activity was not dependent on DNA, and poly A itself primed the incorporation of AMP into polyadenylate. Poly U did not prime the incorporation of AMP. The incorporation obtained in the presence of ribosomal RNA from rat brain as primer was mainly attributable to terminal attachment of AMP. Actinomycin and inorganic ortho-phosphate had no effect on the enzymic activity, however, inorganic pyrophosphate, ammonium sulphate and nucleoside triphosphates (GTP, CTP and UTP) were inhibitory. The same nuclear extract of brain, used for the synthetic reaction producing poly A, also degraded the polynucleotide to yield adenosine mono, di and triphosphates.     

Formation of deoxycytidine diphosphate-diglyceride by nuclei isolated from HeLa cells.

Isolated nuclei from HeLa cells synthesize dCDP-diglyceride from dCTP at the rapid rate of 5–10 nmol/20 min/10⁸ nuclei. The incorporation of dCTP into this phospholipid precursor is thus 10 to 20 times faster than the incorporation of dCTP into DNA, in vitro, under the same conditions. ATP, phosphatidic acid, and MgCl₂ are required for optimal synthesis of dCDP-diglyceride. The reaction is completely inhibited by the presence of 0.04% Triton N-101. Liponucleotide formation occurs equally well with dCTP or CTP in this system and competition studies suggest that a single enzyme catalyzes the formation of dCDP- and CDP-diglyceride.     

NUCLEAR-CYTOSOL INTERACTIONS THAT FACILITATE RELEASE OF RNA FROM MOUSE BRAIN NUCLEI

Abstract— Mouse brain nuclei were incubated in vitro under conditions that primarily lead to the synthesis of radioactive polydisperse and messengerlike nuclear RNA. After incubation the effects of Mg² concentrations, nucleoside triphosphate levels and brain cytosol were examined with regard to their ability to influence the release of RNA from brain nuclei. The presence of 8 mM -MgCl₂ and a total of 0.3 mM-nuclcoside triphosphates during the labelling procedure allowed only a minimal amount of RNA to be released. However, when the MgCl₂ was decreased to 2 mM and the nucleoside triphosphates were increased to 1 mM, a stimulation of RNA release was observed. The addition of unfractionated brain cytosol under these conditions resulted in an inhibition of RNA release.
G-100 Sephadex filtration removed detectable RNase activity from the cytosol preparations and allowed the identification of fractions that were able to facilitate nuclear RNA release by 3-fold. The fractions that stimulated release did not have detectable levels of RNase, protease or DNA-dependenl RNA polymerase. Under conditions that provided maximum nuclear RNA release by both labelled mouse brain and neuroblastoma nuclei, no release of DNA could be measured. The cytosol fractions that facilitated RNA release did not have a high affinity for nuclear RNA or an ability to stimulate nuclear RNA synthesis. However, other components in the cytosol were shown to stimulate RNA metabolism in isolated mouse brain nuclei and to have a relatively high binding affinity to nuclear RNA. Further purification of the RNA release components in the brain cytosol by DEAF. Sephadex chromatography allowed an increase in specific activity of at least 40-fold. The thermal lability, effective filtration size, and solubility in phenol suggested that the cytosol factors that facilitiated nuclear RNA release were associated with cellular proteins.     

Kinetics of DNA-dependent RNA synthesis: coupled synthesis of di- and trinucleotides in the presence of a minimum complement of substrate

The qualitative and quantitative characteristics of the synthesis of the short oligonucleotides by Escherichia coli RNA polymerase on A1 promoter of the bacteriophage T7 deletion mutant delta D111 DNA in the presence of the incomplete set of nucleoside triphosphates were studied. It was shown, that in conformity with the structure of A1 promoter the oligonucleotides pppApU, pppApUpC were synthesized in the presence of ATP, UTP, CTP; the oligonucleotides pApU, pApUpC-in the presence of AMP, UTP, CTP and oligonucleotides pApU, pApUpC, pApUpCpG-in the presence of AMP, UTP, CTP, GTP. The curves of di- and trinucleotide syntheses as the functions of the substrate concentrations were obtained. The analytical formulas for the rates of the coupled synthesis were derived from these curves. A kinetic scheme that is in conformity with the experimental data was proposed. This scheme includes the stage of the reversible, random and release of di- and trinucleotides from the enzyme-template complex.     

Kinetics of DNA-dependent RNA synthesis: couple synthesis of di-, tri- and tetranucleotides in the presence of a limited set of substrates

The qualitative and quantitative characteristics of the short oligonucleotides synthesis by Escherichia coli RNA polymerase on A1 promoter of the bacteriophage T7 in the presence if incomplete set of nucleoside triphosphates were studied. The binding of the fourth substrate with enzyme-template complex was shown to occur after binding of the third substrate only. The curves of di-, tri- and tetranucleotide synthesis as the function of CTP and GTP concentration were constructed. The empiric formulas for the rates of the coupled synthesis if tri- and tetranucleotides were derived from these curves. A kinetic scheme describing the experimental data was proposed.     

Inhibition of hepatitis C virus RNA replication by 2'-modified nucleoside analogs

The RNA-dependent RNA polymerase (NS5B) of hepatitis C virus (HCV) is essential for the replication of viral RNA and thus constitutes a valid target for the chemotherapeutic intervention of HCV infection. In this report, we describe the identification of 2'-substituted nucleosides as inhibitors of HCV replication. The 5'-triphosphates of 2'-C-methyladenosine and 2'-O-methylcytidine are found to inhibit NS5B-catalyzed RNA synthesis in vitro, in a manner that is competitive with substrate nucleoside triphosphate. NS5B is able to incorporate either nucleotide analog into RNA as determined with gel-based incorporation assays but is impaired in its ability to extend the incorporated analog by addition of the next nucleotide. In a subgenomic replicon cell line, 2-C-methyladenosine and 2'-O-methylcytidine inhibit HCV RNA replication. The 5'-triphosphates of both nucleosides are detected intracellularly following addition of the nucleosides to the media. However, significantly higher concentrations of 2'-C-methyladenosine triphosphate than 2'-O-methylcytidine triphosphate are detected, consistent with the greater potency of 2'-C-methyladenosine in the replicon assay, despite similar inhibition of NS5B by the triphosphates in the in vitro enzyme assays. Thus, the 2'-modifications of natural substrate nucleosides transform these molecules into potent inhibitors of HCV replication.     

Regulation of RNA synthesis in higher plant cells by the action of a nucleoside triphosphatase

The influence of nucleoside triphosphates in relation to divalent cations on RNA synthesis of cells from a suspension culture from parsley was investigated. The data obtained from experiments with isolated nuclei and with an in vitro system with highly purified RNA polymerase I were compared with a chromatin-bound nucleoside triphosphatase activity within the nucleus. The results might suggest a regulatory role of the nucleoside triphosphatase activity in RNA synthesis.Abbreviations NTP nucleoside triphosphates - NTPase nucleoside triphosphatase     

The Escherichia coli adenylyl cyclase complex: stimulation by GTP and other nucleotides.

Escherichia coli cells permeabilized by treatment with low concentrations of toluene contain an adenylyl cyclase activity that can be stimulated 3.6-7.6-fold by GTP. The stimulatory effect of GTP is maximal at concentrations of the nucleotide in the physiological range (above 0.7 mM). Studies of the dependence of velocity on substrate (ATP) concentration indicate that the velocity vs. substrate plots are sigmoid in the absence of GTP but hyperbolic in the presence of GTP, suggesting an allosteric regulatory site that can be occupied by either ATP or GTP. Replacement of ATP by AMPPNP as substrate results in velocity vs. substrate plots that are hyperbolic in the absence or presence of GTP, although GTP increases the Vmax by a factor of 2.2; these findings indicate that AMPPNP specifically occupies the substrate site and GTP exclusively occupies the regulatory site. A test of the capacity of other guanine nucleotides to stimulate adenylyl cyclase activity showed that 2'-deoxy-GTP was almost as effective as GTP, but that GDP, GMP, ppGpp, and 3',5'-cGMP were not stimulatory effectors; GTP-gamma-S and GMPPNP stimulated adenylyl cyclase activity but to a lesser degree than did GTP. In addition to the previous indication that ATP can occupy the regulatory site on adenylyl cyclase, it was found that CTP and UTP were potent stimulators. Thus, all the naturally occurring RNA precursor nucleoside triphosphates are capable of stimulating adenylyl cyclase activity. In contrast, PPPi inhibits adenylyl cyclase activity.(ABSTRACT TRUNCATED AT 250 WORDS)     

Fractionation of nuclei from brain by zonal centrifugation and a study of the ribonucleic acid polymerase activity in the various classes of nuclei

1. The nuclei of the cells of the whole rat brain have been fractionated in a B-XIV zonal rotor with a discontinuous gradient of sucrose. Five fractions were obtained. Zone (I) contained neuronal nuclei (70%) and astrocytic nuclei (23%). Zone (II) contained astrocytic nuclei (81%) and neuronal nuclei (15%). Zone (III) contained astrocytic nuclei (84%) and oligodendrocytic nuclei (15%). Zone (IV) contained oligodendrocytic nuclei (92%) and zone (V) contained only oligodendrocytic nuclei. 2. The content of DNA, RNA and protein per nucleus was determined for each zone. Although the amount of DNA per nucleus is constant (7pg) the RNA varies from 4.5 to 2.5pg/nucleus and the protein from 38 to 17.6pg/nucleus. The neuronal nuclei have the greatest amounts of protein. The oligodendrocytic nuclei have the least content of RNA and protein. 3. The effects of pH, ionic strength, and Mg(2+) and Mn(2+) concentration on the activity of the nuclear system for synthesis in vitro of RNA have been investigated for unfractionated nuclei. From these studies a standard set of conditions for the assay of nuclear RNA polymerase has been established. 4. The activity of the RNA polymerase in each of the zonal fractions has been determined in the presence and in the absence of alpha-amanitin. Zone (II) is the most active, followed by zone (I). The nuclei of zones (IV) and (V) have comparable activity, which is 40% of that of zone (II). 5. The extent of incorporation of each of the four labelled nucleoside triphosphates by the nuclei from each zone has been measured. These values have been used to calculate the base composition of the RNA synthesized in vitro in each class of nucleus. 6. The effect of changes in the condition of assay of RNA polymerase in the different classes of nuclei has been investigated. Significant differences in the response to concentrations of metal ions and ammonium sulphate have been observed. 7. Homopolymer formation in each zone of brain nuclei has been determined. The extent of formation of the four homopolymers roughly parallels the RNA polymerase activity.