A comparative study of mouse liver and mouse blastocyst DNA-dependent RNA polymerases.

DNA-dependent RNA polymerase has been studied in adult mouse liver and mouse blastocysts. The enzyme from mouse liver was resolved into three enzyme forms by DEAE-Sephadex chromatography. Two of the forms, IA and IB, are insensitive to α-amanitin, have low $\text{Mn}{}^{\mathrm{2+}}\text{Mg}{}^{\mathrm{2+}}$ activity ratios, and are optimally active at low ionic strength. Form II is inhibited by α-amanitin, has a higher $\text{Mn}{}^{\mathrm{2+}}\text{Mg}{}^{\mathrm{2+}}$ activity ratio, and is most active at high ionic strength. An optimal reaction temperature of 37 ° C was found for all enzyme forms. All of the isolated enzyme forms are inhibited by the exotoxin from Bacillus thuringiensis and the inhibition can be partially reversed by increased ATP levels. Forms IA and IB are most active with native template while form II prefers denatured DNA.The blastocyst RNA polymerase activity exhibits similar requirements for divalent metal ions and ionic strength to the purified liver enzymes. The maximum inhibition of blastocyst RNA polymerase obtained with α-amanitin and exotoxin differs from that observed for purified liver enzymes but is similar to the inhibition of liver homogenate. However, the concentrations of inhibitor required for maximum inhibition by α-amanitin and exotoxin is different for the blastocyst and liver homogenate enzymes.     

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.     

Variations in the amounts of RNA polymerase forms I, II and III during preimplantation development in the mouse.

DNA-dependent RNA polymerase has been measured at various stages of preimplantation development in mouse embryos. The total RNA polymerase activity per embryo increases rapidly from the 8-cell stage to the blastocyst stage. Studies with low α-amanitin concentrations, which inhibit form II RNA polymerase, and high α-amanitin concentrations, which inhibit both form II and III RNA polymerases indicate that the relative proportions of the three forms change significantly during preimplantation development. The changes which occur in the types and levels of RNA polymerase appear to parallel corresponding changes in the synthesis of the major classes of RNA.     

The effects of aphidicolin and α-amanitin on DNA synthesis in preimplantation mouse embryos

The effects of aphidicolin and α-amanitin on DNA synthesis by preimplantation mouse embryos were studied. It was found that both blastocyst and 8-cell embryos showed marked inhibition of ³H-thymidine incorporation into DNA by aphidicolin at concentrations of 20–50 μg/ml. However, aphidicolin did not inhibit the conversion of morula embryos to blastocyst embryos, although aphidicolin-treated blastocysts lost their blastocoel and collapsed into a compact form after prolonged exposure to the drug. Both 8-cell and blastocyst embryos were found to be susceptible to inhibition of DNA synthesis by α-amanitin.     

Synthesis of alpha-fetoprotein and albumin by fetal mouse liver cultured in chemically defined medium

Fetal mouse liver synthesizes two major secretory proteins: α-fetoprotein and albumin. The relative proportions of these proteins change during development. Fetal mouse liver secretes predominantly α-fetoprotein, and the neonatal mouse liver secretes predominantly albumin. α-Fetoprotein and albumin synthesis were studied in vitro using an organ culture system and a chemically defined medium (BGJ_b). This medium does not support hepatocellular replication but maintains protein synthesis at high levels for prolonged periods of culture. Patterns of protein synthesis were analyzed as functions of gestational age and time in culture. The ratio of α-fetoprotein/albumin decreases from 1.4 on gestational Day 14 to 0.4 on gestational Day 18. However, when liver cultures were begun on any given gestational day, the ratio of α-fetoprotein/albumin remains constant for as long as 8 days in culture. Thus, developmental changes in α-fetoprotein and albumin synthesis are arrested under the conditions of this culture system. Fetal mouse liver secretes two electrophoretically distinguishable forms of albumin. One form is similar in mobility to albumin from adult mouse serum; the other more electropositive species is similar in mobility to proalbumin isolated from adult mouse liver microsomes and can be converted to albumin by mild trypsin treatment.     

Evidence for variation in the number of functional gene copies at the AmaR locus in chinese hamster cell lines

The hypothesis of functional hemizygosity has been examined for the α-amanitin resistant (Ama^R, a codominant marker) locus in a series of Chinese hamster cell lines. Ama^R mutants were obtained from different cell lines, e.g., CHO, CHW, M3-1 and CHO-Kl, at similar frequencies. After fractionation of different RNA polymerase activities in the extracts by chromatographic procedures, the sensitivity of the mutant RNA polymerase II towards α-amanitin was determined. While all of the RNA polymerase II activity in mutant CHO and CHO-Kl lines became resistant to α-amanitin inhibition, only about 50% of the activity is highly resistant in Ama^R mutants of CHW and M3-1 cell lines. The remaining activity in the latter cell lines shows α-amanitin sensitivity similar to that seen with the wild-type enzyme. This behaviour is similar to that observed with a 1:1 mixture of resistant and sensitive enzymes from CHO cells. These results, therefore, strongly indicate that while only one functional copy of the gene affected by α-amanitin is present in CHO and CHO-Kl cells, two copies of this gene are functional in the CHW and M3-1 cell lines.     

Distribution and mechanism of α-amanitin tolerance in mycophagous Drosophila (Diptera: Drosophilidae)

Many mycophagous species of Drosophila can tolerate the mushroom poison α-amanitin in wild mushrooms and in artificial diet. We conducted feeding assays with sixteen Drosophila species and α-amanitin in artificial diet to better determine the phylogenetic distribution of this tolerance. For eight tolerant and one related susceptible species, we sequenced the gene encoding the large subunit of RNA Polymerase II, which is the target site of α-amanitin. We found no differences in the gene that could account for differences in susceptibility to the toxin. We also conducted feeding assays in which α-amanitin was combined with chemical inhibitors of cytochrome P450s or glutathione S-transferases (GSTs) in artificial diet to determine if either of these enzyme families is involved in tolerance to α-amanitin. We found that an inhibitor of GSTs did not reduce tolerance to α-amanitin, but that an inhibitor of cytochrome P450s reduced tolerance in several species. It is possible that the same cytochrome P450 activity that produces tolerance of α-amanitin might produce tolerance of other mushroom toxins as well. If so, a general detoxification mechanism based on cytochrome P450s might answer the question of how tolerance to α-amanitin arose in mycophagous Drosophila when this toxin is found in relatively few mushrooms.     

Characterization of mouse liver alpha-L-fucosidase. Demonstration of unusual basic isoelectric forms of the enzyme that appear to be developmentally regulated.

Mouse tissues contain unusual basic isoelectric forms of alpha-L-fucosidase (with approximate isoelectric points of 8.3 and 9.0) in addition to the usual acidic and neutral forms previously described in tissues of other species. These unusual forms are very prominent in placenta and foetal tissues and comprise approx, 50-80% of total activity up to 11 days of postnatal development. By 15 days of postnatal development, the basic forms are diminished in amount and comprise not more than 25% of total activity. Neuraminidase treatment of adult mouse liver alpha-L-fucosidase led to significantly decreased amounts of acidic forms and increased amounts of the basic forms, suggesting that these forms are chemically related at least in part by sialic acid residues. Comparative kinetic studies on mouse liver, human liver and mouse placental alpha-L-fucosidases indicated that they have the same Km (0.05-0.06 mM) for 4-methylumbelliferyl alpha-L-fucopyranoside but different pH optima and thermostability properties. Mouse liver alpha-L-fucosidase has one pH optimum (5.5) and an acidic shoulder (centred around pH 4.0) compared with two distinct optima (4.3 and 6.8) for the human liver enzyme. Mouse placental alpha-L-fucosidase has a pH-activity curve comparable with that of the mouse liver enzyme except that the acidic shoulder is absent. Mouse liver alpha-L-fucosidase is considerably more thermolabile after preincubation at 50 degrees C than are the human liver and mouse placental enzymes, which gave similar thermodenaturation curves. Immunochemical studies indicated that mouse and human alpha-L-fucosidases are dissimilar antigenically but exhibit some cross-reactivity. The IgG fraction of antibody prepared in goat against human liver alpha-L-fucosidase was ineffective by itself in immunoprecipitating mouse liver alpha-L-fucosidase, but 63% and 72% of the mouse liver and placental enzymes respectively could be immunoprecipitated in the double-antibody experiments under conditions that immunoprecipitated 92% of the human liver enzyme.     

Regulation of RNA polymerase II activity in α-amanitin-resistant CHO hybrid cells

CHO hybrid cell lines obtained by fusing cells of wild-type sensitivity to α-amanitin with mutant cells containing RNA polymerase II activity resistant to α-amanitin have both sensitive (wild-type) and resistant forms of RNA polymerase II. When these hybrids were grown in medium containing α-amanitin, the sensitive form of polymerase II was inactivated, and the activity resistant to α-amanitin increased proportionally. The total polymerase II activity level therefore remained constant. This regulation of RNA polymerase II activity occurred independently of that of RNA polymerase I and was similar to that observed previously in the α-amanitin-resistant rat myoblast mutant clone Ama102 (Somers, Pearson, and Ingles, 1975).A sensitive radioimmunoassay was developed to quantitate the total mass of RNA polymerase II enzyme. Under conditions of regulation of the enzymatic activity when hybrids grown in α-amanitin exhibited a 2–3 fold increase in the activity of the α-amanitin-resistant enzyme, no major change in the enzyme mass was detected immunologically. However, quantitation of the α-amanitin-inactivated polymerase II of wild-type sensitivity by ³H-amanitin binding indicated that the loss of its enzymic activity was accompanied by a loss of ³H-amanitin binding capacity in the cell lysates. All these results taken together indicate that a mechanism for regulating the intracellular level of RNA polymerase II exists and that it involves changes in the concentration of enzyme.     

Control of protein synthesis during blastocyst formation in the mouse.

In order to evaluate the dependence of the embryo on new mRNA synthesis during the period leading to blastulation, quantitative and qualitative aspects of protein synthesis in developing mouse morulae were investigated using α-amanitin, an inhibitor of RNA polymerase II. Only 1 of 423 early morulae cultured for 27 hr in the presence of 11 μg/ml α-amanitin cavitated, although most progressed as far as fully compacted morulae. About two-thirds of the untreated embryos cavitated during the same period. Incorporation of [³⁵S]methionine into protein was measured at 3- or 4-hr intervals over a 24-hr period and showed a two- to fivefold increase in control embryos. This increase was blocked in the α-amanitin-treated group although initial levels of incorporation were maintained. Total uptake of the amino acid appeared to be unaffected by the inhibitor. RNA synthesis, as measured by [³H]uridine incorporation over the same period, was reduced by between 5 and 52%, and the preblastulation surge in RNA synthesis was also blocked by α-amanitin. Two-dimensional polyacrylamide gel electrophoresis of labeled polypeptides synthesized by the embryos after 24-hr incubation in the presence or absence of the inhibitor revealed three distinct classes of polypeptide. The majority of polypeptides continued to be synthesized in the presence of α-amanitin whereas a small number of polypeptides, the synthesis of which would normally have increased during the development of the morula to the blastocyst, were prevented from doing so. A few polypeptides which normally cease to be synthesized over this period continued to be synthesized in the presence of α-amanitin. It is concluded that, while most of the proteins detectable at the morula stage are synthesized on mRNA templates of relatively long translational life, the general surge in protein synthesis, including the increased synthesis of a few species of polypeptide, are dependent on continuous translational activity.     

α-Amanitin-sensitive DNA-dependent RNA polymerase I from cherry salmon (Oncorhynchus masou) liver nuclei

DNA-dependent RNA polymerases I and II were purified approximately 3900- and 13300 fold, respectively, from a sonicated nuclear extract of the cherry salmon liver by column chromatographies on DEAE-Sephadex, heparin-Sepharose and DNA-cellulose. The RNA polymerases were examined with respect to template-specificity, the effects of Mn²⁺, Mg²⁺ and ammonium sulfate, α-amanitin sensitivity. Results showed that the RNA polymerase I differed from other eukaryotic RNA polymerase I in α-amanitin sensitivity.     

THE ACTION OF α-AMANITIN ON RNA SYNTHESIS IN CHINESE HAMSTER OVARY CELLS : Ultrastructural and Biochemical Studies

α-Amanitin acts in vitro as a selective inhibitor of the nucleoplasmic form B RNA polymerases. Treatment of Chinese hamster ovary (CHO) cells with this drug leads principally to a severe fragmentation of the nucleoli. While the ultrastructural lesions induced by α-amanitin in CHO cells and in rat or mouse liver are quite similar, the results diverge concerning the effect on RNA synthesis. It has been shown that in rat or mouse liver α-amanitin blocks both extranucleolar and nucleolar RNA synthesis. Our autoradiographic and biochemical evidence indicates that in CHO cells high molecular weight extranucleolar RNA synthesis (HnRNA) is blocked by the α-amanitin treatment, whereas nucleolar RNA (preribosomal RNA) synthesis remains unaffected even several hours after the inhibition of extranucleolar RNA synthesis. Furthermore, the processing of this RNA as well as its transport to the cytoplasm seem only slightly affected by the treatment. Finally, under these conditions, the synthesis of the low molecular RNA species (4–5S) still occurs, though less actively. The results are interpreted as evidence for a selective impairment of HnRNA synthesis by α-amanitin in CHO cells.     

Concentration of particular high molecular mass phosphoproteins in rat liver nuclei and nuclear matrix decreases following inhibition of RNA synthesis by α-amanitin

Purified liver nuclei were isolated from rats treated with non-lethal doses of α-amanitin, actinomycin D, galactosamine or cycloheximide. The nuclei were incubated in the presence of adenosine 5′-[γ-³²P]triphosphate, and digested with DNAase or DNAase plus high salt concentrations to prepare nuclear residual structures. Using SDS-polyacrylamide gel electrophoresis followed by autoradiography, samples from untreated rats were shown to contain major phosphoproteins in the range 76–260 kDa, with a prominent triplet of bands with 110, 117 and 128 kDa. Treatment of animals with α-amanitin or high doses of actinomycin D and galactosamine caused a significant decrease in the concentration of a few phosphorylated species, including the 110 kDa protein in whole nuclei, and their disappearance from the nuclear matrix or residual ribonucleoprotein structures after 1–3 h. The changes were reversible, complete recovery being observed after 5 h in the case of α-amanitin. No similar results were obtained with nuclei from rats treated with the translation inhibitor cycloheximide. The data are discussed in view of a possible effect of certain high molecular mass phosphoproteins on reactions of the heterogeneous nuclear RNA/mRNA pathway in the cell.     

The Effect of α-Amanitin on Nucleic Acid Synthesis in Preimplantation Mouse Embryos

It has been hypothesized that multiple forms of RNA polymerase may play a role in the control of development and differentiation in eukaryotic organisms. For this to be true, three criteria must be met. First, multiple forms of RNA polymerase must be demonstrated. Second, the relative proportion of the enzyme forms must be shown to change with development or differentiation. And third, the types of RNA synthesized must correlate with the types of RNA polymerase present at each developmental stage. We have previously reported data satisfying the first two criteria for preimplantation mouse embryos. The present paper probes the third criterion in this differentiating system.
It was found that although the proportion of the RNA polymerase enzyme forms changes from the 8-cell to the blastocyst stage of development, the types of newly synthesized nucleic acids at each of these stages were similar. Furthermore, inhibition of rRNA, mRNA, and tRNA, by α-amanitin, was identical for 8-cell and blastocyst embryos. The only difference between these two stages was that DNA synthesis in blastocysts was more sensitive to inhibition by α-amanitin than DNA synthesis in 8-cell embryos. We conclude that the synthesis of different classes of RNA by preimplantation mouse embryos is not simply controlled by changes in the levels of the multiple forms of RNA polymerase.     

The participation of the embryonic genome during early cleavage in the rabbit

Actinomycin D and the mushroom toxin α-amanitin similarly inhibit ribonucleic acid synthesis in the rabbit zygote. Actinomycin D also causes an immediate arrest of cleavage, whereas α-amanitin allows limited further development. The decreasing rate of amino acid incorporation caused by continuous exposure of cleaving rabbit embryos to α-amanitin suggests that a relatively homogeneous embryonic RNA is involved in the support of early protein synthesis and is turning over with a half-life of approximately 24 hr, or three cell generation times.     

7种鹅膏菌属真菌肽类毒素的HPLC分析

利用HPLC法对长白山地区分布的7种鹅膏属真菌成熟子实体中的α鹅膏毒肽(αamanitin)、β鹅膏毒肽(βamanitin)和鬼笔毒肽(phalloidin)的含量进行了测定。结果表明:芥橙黄鹅膏(Amanitasubjunquillea)和橙黄鹅膏(Amanitaaff.citrina)中均含有3种毒素,其中芥橙黄鹅膏的α鹅膏毒肽含量为2395.91μg/g、β鹅膏毒肽含量为1653.75μg/g和鬼笔毒肽含量为405.26μg/g;橙黄鹅膏的分别为1121μg/g、4244μg/g和9442μg/g。芥橙黄鹅膏白色变种(Amanitasubjunquilleavar.abla)中含有β鹅膏毒肽,其含量为614.00μg/g。其他5种鹅膏中均未检测到上述3种毒素。