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.     

The separation of RNA polymerases I and II achieved by fractionation of plant chromatin

Chromatin-bound RNA polymerase I and II from soybean hypocotyl can be separated by differential centrifugation. While all detectable RNA polymerase I is pelleted in association with chromatin, nearly all of the RNA polymerase II activity is not pelleted even at high speeds. Substitution of pH 6 for pH 8 isolation medium results in several-fold greater recovery of chromatin-bound RNA polymerase II.     

A simple solubilization method for loosely and tightly chromatin-bound RNA polymerase II from rat liver nuclei

Rat liver chromatin-bound RNA polymerase II could be differentially solubilized into two distinct populations, loosely and tightly bound enzymes, by a simple method. By this method the recovery of the solubilized enzyme from the chromatin fraction could be increased considerably as compared with the procedure of Yu (1). The two chromatin-bound enzymes had different properties:

1. Loosely bound enzyme was easily extractable from chromatin with relatively mild ionic condition (0.5 M NaCl); the tightly bound enzyme had to be solubilized by more drastic conditions such as sonication or nuclease treatment.
2. Loosely bound enzyme could not efficiently transcribe the chromatin template, but the tightly bound enzyme was active toward the same template. The latter enzyme is involved in the tight complex with the RNA synthesis activating factors.
3. Cycloheximide treatment in vivo suggests that the two enzymes have different turn-over rates.

Therefore, with this simple solubilization method the functionally different two chromatin-bound RNA polymerase II activities can be estimated.     

Developmental Changes in Multiple Forms of Deoxyribonucleic Acid-dependent Ribonucleic Acid Polymerase in Soybean Hypocotyl

The relative levels of multiple RNA polymerases were determined in soybean (Glycine max L. var. Wayne) hypocotyl during various stages of development. The meristematic region of the hypocotyl contains more total polymerase activity per gram fresh weight and a greater proportion of polymerase I relative to II than the differentiated regions. The fully elongated tissue comprising the lower half of the hypocotyl contains mainly RNA polymerase II. The hook region contains a polymerase activity peak which is completely sensitive to alpha-amanitin and partially sensitive to rifamycin SV. This peak is not detectable in other regions of the hypocotyl. Polymerase I is reproducibly separated into a major and a minor component, both being resistant to alpha-amanitin. The two components elute at salt concentrations of 0.2 m and 0.23 m KCl, respectively, while the alpha-amanitin-sensitive polymerase (II) elutes at 0.3 m KCl. The polymerase activity peak which is detectable only in the hook region elutes at approximately 0.5 m KCl. Polymerase levels were also determined in water-stressed tissue and in tissue which was harvested after three days of growth instead of the usual four days.     

Alpha-Amanitin resistance of RNA polymerase II in mutant Chinese hamster ovary cell lines.

A number of mutant Chinese hamster ovary (CHO) cell lines resistant to the cytotoxic action of alpha-amanitin have been isolated. The alpha-amanitin sensitivity of the different mutant cell lines varied widely, but correlated well with the alpha-amanitin sensitivity of the RNA polymerase II activity in each of these mutant cell lines. In comparison with the RNA polymerase II of wild-type cells, three mutants, Ama39, Ama6, and Amal, required respectively 2- to 3-fold, 8- to 10-fold, and about 800-fold higher concentrations of alpha-amanitin for inhibition of their polymerase II activity. Determination of the equilibrium dissociation constants (KD) for complexes between 0-[3H]methyl-demethyl-gamma-amanitin and RNA polymearse II indicated that differences in alpha-amanitin sensitivity were reflected in differences in the ability of the enzymes to bind amanitin. Hybrids formed by fusion of mutants with cells of wild-type sensitivity contained both mutant and wild-type polymerase II activities. Thus, each of the different alpha-amanitin resistance mutations was expressed co-dominantly. A test for complementation between two of these mutations by measurement of both the alpha-amanitin sensitivity and the [3H]amanitin binding by RNA polymerase II in Ama6 X Amal hybrid cells did not reveal any wild-type RNA polymerase II activity. These data provide evidence that the mutation to alpha-amanitin resistance involves structural changes in the gene coding for the alpha-amanitin binding subunit of RNA polymerase II. These changes appear to account for the alpha-amanitin-resistant phenotypes of these mutant cells.     

Growth hormone and drug metabolism. Acute effects on nuclear ribonucleic acid polymerase activity and chromatin.

Adult male rats, subjected either to sham operation or to hypophysectomy and adrenalectomy were maintained for 10 days before treatment with growth hormone. Results of the acute effects of growth hormone on the rat liver nuclear RNA polymerase I (nucleolar) and II (nucleoplasmic) activities as well as the chromatin template capacity were then studied and compared with the growth-hormone effects on the drug metabolism described in the preceding paper (Wilson & Spelsberg, 1976). 2. Conditions for isolation and storage of nuclei for maintenance of optimal polymerase activities are described. It is verified that the assays for polymerase activities require a DNA template, all four nucleoside triphosphates, and a bivalent cation, and that the acid-insoluble radioactive product represents RNA. Proof is presented that under high-salt conditions DNA-like RNA (polymerase II) is synthesized, and that under low-salt conditions in the presence of alpha-amanitin, rRNA (polymerase I) is synthesized. 3. In the livers of hypophysectomized/adrenalectomized rats, growth hormone increases the activity of both RNA polymerase enzymes and the chromatin template capacity within 1h after treatment. The effects last for 12h in the case of polymerase II but for only 6h in the case of polymerase I. Sham-operated rats respond to growth hormone in a manner somewhat similar to that shown by hypophysectomized/adrenalectomized rats. These results, which demonstrate an enhancement of RNA polymerase I activity in response to growth hormone, support those from other laboratories. 4. Growth-hormone enhancement of the chromatin template capacity in the liver of hypophysectomized/adrenalectomized rats contrasts with previous reports. The growth-hormone-induced de-repression of the chromatin DNA could represent the basis of the growth-hormone-induced enhancement of RNA polymerase II activity in the hypophysectomized/adrenalectomized rats, although some effect of growth-hormone on the polymerase enzymes is still suggested.     

Effects of partial hepatectomy on RNA polymerase activities in mouse liver

Chromatin-bound and poly[d(A-T)]dependent RNA polymerase I plus III and II activities of mouse liver were analysed 24 and 48 hr after partial hepatectomy. Chromatin-bound RNA polymerase I plus III activity showed an increase of 57% at 24 hr and 51% at 48 hr after partial hepatectomy. There was a decrease in chromatin-bound RNA polymerase II activity of 15% at 24 hr and 34% at 48 hr after partial hepatectomy. There was no significant changes in poly[d(A-T)]dependent RNA polymerase activities. Heparin caused an approximately 10-fold increase in chromatin-bound RNA polymerase II activity. The stimulation by heparin was significantly increased 48 h after partial hepatectomy. Anaesthesia and/or surgery had great influence on RNA polymerase activities. At 24 hr after operation, chromatin-bound RNA polymerase I plus III and II activities were depressed, and the liver cell chromatin was more susceptible to stimulation by heparin.     

Auxin-induced enhancement of RNA polymerase activity in soybean as a function of development

Studies on chromatin and solubilized RNA polymerase from control and 2,4-D treated whole hypocotyls indicate that the activity of RNA polymerase I is enhanced by the auxin treatment while the activity of polymerase II is essentially the same in control and treated tissue. However, different portions of the hypcotyl respond differently to the auxin treatment. The enhancement of solubilized polymerase I activity is greater in the lower half of the hypocotyl than it is in the upper half. In the hook region an inhibition of RNA solubilized polymerase activity is observed. Similarly, 2,4-D treatment results in an inhibition of chromatin bound RNA polymerase activity in nuclei isolated from first leaves. Chromatography on DEAE-Sephadex also reveals a selective enhancement of polymerase I in the upper and lower halves of the hypocotyl.     

Quantitative conservation of chromatin-bound RNA polymerases I and II in mitosis. Implications for chromosome structure

RNA synthesis almost ceases in mitosis. It is ambiguous whether this temporal, negative control of RNA synthesis is solely because of the nature of chromosomes per se, (i.e., their condensed state), or to a physical loss of RNA polymerases along with other nuclear proteins which have been shown to pass into the cytoplasm in mitosis, or to their combined feature. Aside from such regulatory considerations, a question has also been raised as to whether RNA polymerases are constituents of metaphase chromosomes. To clarify these aspects of RNA polymerase-chromatin interaction in mitosis, the enzymes in chromosomes were quantitated and their levels compared to those in interphase nuclei and cells at various phases of the cell cycle. The results show that the amounts of form I, form II, and probably form III enzymes bound to a genome-equivalent of chromatin stay constant during the cell cycle. Thus, the mechanism for the negative control of RNA synthesis in mitosis appears to exist in the chromosomes per se, but not to be directly related to the RNA polymerase levels. This quantitative conservation of chromatin-bound RNA polymerases implies that they may persist as structural components of the chromosomes in mitosis.     

RNA polymerase activities and chromatin protein composition of rat liver during methionine deprivation and refeeding

The reversible effect of dietary methionine deficiency was studied in young adult rats. The sensitivity of nuclear chromatin to micrococcal nuclease (EC3.1.4.7) digestion and the composition of the chromatin proteins were unaffected by the dietary regimens. The specific chromatin-bound RNA polymerase II activity decreased during methionine deficiency. Refeeding of methionine for 2 days restored the activity in the nuclease-released chromatin. RNA polymerase I plus III activity remained unchanged. Total RNA polymerase activity changed with the liver wet weight which was reduced during methionine deficiency and was not restored to control level after 2 days of methionine refeeding. RNA polymerase activity was altered by methionine deficiency. The recovery was independent of major modifications of the chromatin structure and protein composition.     

Isolation and characterization of an alpha-amanitin-resistant rat myoblast mutant cell line possessing alpha-amanitin-resistant RNA polymerase II.

Cultures of the rat skeletal muscle myoblast cell line, L6, were treated with the mutagen ethylmethanesulfonate and grown in the presence of alpha-amanitin, an inhibitor of RNA polymerase II in vitro. One clonal cell line, Ama102, resistant tc the cytotoxic action of 2 mu-g/ml of alpha-amanitin was isolated and extensively characterized. Ama102 cells were about 30-fold more resistant to alpha-amanitin than their Ama+ parent cells based on a comparison of the concentration of alpha-amanitin required to reduce their plating efficiencies to similar extents. The RNA polymerase activities from Ama+ and Ama102 cells were solubilized and separated by DEAE-Sephadex chromatography. Whereas all of the Ama+ RNA polymerase II activity was inhibited by 0.1 mu-g/ml of alpha-amanitin, about 30% of the activity in the Ama102 RNA polymerase II peak was resistant to this concentration of alpha-amanitin and was inhibited only by much higher concentrations (25 mu-g/ml) of alpha-amanitin. This alpha-amanitin-resistant activity in Ama102 cells was identified as a bona fide RNA polymerase II by its chromatographic behavior on DEAE-Sephadex, salt optimum, preference for denatured DNA as template, insensitivity to inhibition by potassium phosphate, thermal inactivation kinetics, and inactivation by anti-RNA polymerase II antiserum. Both RNA polymerase IIa and IIb from Ama102 cells exhibited the partial alpha-amanitin resistance, as did this activity when purified further on phosphocellusose. Unlike the parental Ama+ cells, Ama102 cells neither fused at confluence nor showed an increase in the specific activity of creatine kinase. The altered sensitivity of the Ama102 RNA polymerase II to alpha-amanitin appears to account for the drug-resistant phenotype of these cells.     

Lutropin stimulation of RNA synthesis in corpus luteum chromatin.

Lutropin and human choriogonadotropin stimulated the endogenous chromatin-associated polymerase activity in purified chromatin prepared from nuclei of bovine corpus luteum. Chromatin was incubated in two different buffer systems: one that mainly supports the activity of polymerase I, another that supports the activity of polymerase II and is largely alpha-amanitin sensitive. The hormones lutropin and chorigonadotropin stimulated an increase in the rate of incorporation of [14C]ATP or [14C]UTP into RNA in both buffer systems. Follitropin, prolactin and beta-corticotropin had no stimulatory effect. Neither the alpha nor beta subunit of lutropin stimulated RNA synthesis. When premixed, the subunits rapidly formed the active molecule. A maximum response to RNA synthesis was achieved by a 10(-9) M concentration of human choriogonadotropin. Considerable activity was obtained at 10(-11) M human choriogonadotropin. There was no lutropin stimulation to RNA synthesis using calf thymus DNA and Escherichia coli RNA polymerase.     

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.