Characterization of two poly(A) polymerases from cultured hamster fibroblasts.

The enzymatic and physiochemical properties of poly(A) polymerases IIA and IIB from cultured hamster fibroblasts were investigated. The enzymes show an absolute requirement for Mn2+ as the divalent ion. Although Mg2+ alone is inactive, maximum activity is observed in the presence of both Mn2+ and Mg2+. An optimal pH of approx. 8 is found for polymerases IIA and IIB. The enzymes, however, differ somewhat in the pH curves as well as in the Mn2+ and Mg2+ concentration curves. Poly(A) polymerases IIA and IIB have an isoelectric point of about 6 and a sedimentation coefficient of 3.5--4 S. The molecular weights, obtained by gel filtration chromatography, are 145 000 and 155 000 for enzymes IIA and IIB, respectively. Poly(A) polymerases IIA and IIB can utilize a variety of natural and synthetic RNAs as well as DNA as primers. Poly(A) polymerase IIA is saturated at much lower concentrations of primer than enzyme IIB. On the other hand, the chain length of the product synthesized by polymerase IIA is independent of the primer concentration, whereas, with polymerase IIB, the length of the product decreases when the concentration of RNA is increased.     

DNA-dependent RNA polymerases from Drosophila melanogaster adults: Isolation and partial characterization

In preparation for the isolation and biochemical characterization of putative RNA polymerase mutants, DNA-dependent RNA polymerases of Drosophila melanogaster adults were isolated and partially characterized. Approximately 70% of the female adult RNA polymerase is located in ovaries. Multiple forms of ovarian RNA polymerases I and II are separable by DEAE-Sephadex chromatography. The two forms of RNA polymerase II differ in ammonium sulfate optima. RNA polymerase IIA is more active with double-stranded DNA as template, whereas RNA polymerase IIB transcribes single-stranded DNA most efficiently. Rechromatography of RNA polymerase IIA on DEAE-Sephadex results in the loss of ability of this form to transcribed double-stranded DNA most efficiently. Ovariectomized carcasses have two forms of RNA polymerase I and one form of RNA polymerase II and each transcribes single-stranded DNA most efficiently. As judged by gel filtration chromatography, female adult extracts have forms of RNA polymerase II that differ in molecular weight and template preference.Supported by Grants GM23456 from the NIH and 11259 from the City University Research Foundation.     

Plant DNA-dependent RNA polymerases: subunit structures and enzymatic properties of the class II enzymes from quiescent and proliferating tissues

Class II DNA-dependent RNA polymerases were purified from soybean tissues of different physiological states: (1) from seed embryo tissue, representative of a quiescent, low metabolic state and (2) from auxin-treated hypocotyl tissue, representative of a highly proliferative and metabolically active state. Dodecyl sulfate, polyacrylamide gel electrophoresis indicates that RNA polymerase II from embryonic tissue consists largely (90-95%) of the form IIA enzyme, the largest subunit having a molecular weight of 215 000. RNA polymerase II from hypocotyl tissue is exclusively a form IIB enzyme, the largest subunit having a molecular weight of 180 000. Polypeptides common to RNA polymerases IIA and IIB have the following molecular weights: 138 000; 42 000; 27 000; 22 000; 19 000; 17 600; 17 000; 16 200; 16 100; and 14 000. Peptide mapping in the presence of dodecyl sulfate suggests that the 215 000 and 180 000 subunits possess similar peptide fragments. Plant embryo tissues do not contain protease activity capable of cleaving the 215 000 subunit to the 180 000 subunit, but proliferating plant tissues do contain such an activity. Mixing experiments indicate that appreciable amounts of RNA polymerase IIB are not being artifactually produced during protein purification.     

Deoxyribinucleic acid-binding proteins in virus-transformed cell lines.

The synthesis of proteins with affinity for DNA has been studied in clones of a Syrian hamster cell line (NIL) and subclones of this line transformed by polyoma virus (NIL-Py) or hamster sarcoma virus (NIL-HSV). The results show that the synthesis of DNA-binding proteins in NIL and in its virus-transformed derivatives NIL-Py and NIL-HSV is very similar in exponentially growing cells, but in dense culture there is a very significant difference in the level of a protein (P8), which is much higher in the transformed lines than in untransformed NIL. The high levels of P8 in dense transformed cells have been observed in all the clones of transformed cells examined, indicating that this behavior of P8 is related to transformation and not simply due to a fortuitous clonal selection from the NIL. Experiments with synchronized cells indicate that the time of maximal P8 synthesis relative to cellular DNA synthesis in NIL-HSV precedes that observed in NIL cells. P8 has a molecular weight of 30,000 as determined by polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate and is present in large amounts in the transformed cells in dense culture, where it makes up 0.5 to 1% of the total soluble protein.     

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.     

Vesicular stomatitis virus infection reduces the number of active DNA-dependent RNA polymerases in myeloma cells.

Infection of mouse myeloma (MPC-11) cells with vesicular stomatitis virus resulted in rapid loss in activity of cellular RNA polymerases associated with nuclear chromatin. No RNA polymerase inhibitor could be detected in extracts of infected cell nuclei. Reconstitution experiments with solubilized RNA polymerases dissociated from chromatin of infected and uninfected cells demonstrated that vesicular stomatitis viral infection did not affect the ability of the polymerases to function on endogenous or exogenous templates; nor did infection alter the template capability of the chromatin. Measurement of the number of actively growing RNA chains revealed that infected cell nuclei contained fewer active polymerase units; however, the rates of RNA chain elongation were the same in nuclei from infected and uninfected cells. Quantitation of the number of polymerase units active in nuclear chromatin revealed that the alpha-amantin-sensitive polymerase II was more severely reduced by viral infection than were polymerases I and III.     

Poly(A) synthesis by RNA polymerase II from rat liver

Multiple forms of DNA-dependent RNA polymerase were resolved by DEAE-Sephadex chromatography. In addition to RNA polymerases, an active poly(A) polymerase was also fractionated. RNA polymerases were examined for their capacity to synthesize poly(A). None of the freshly prepared enzymes could efficiently make poly(A) in presence or absence of exogenous primers. However, “aging” of polymerase II by simple incubation at 37°C resulted in the loss of RNA polymerizing activity with a corresponding increase in poly(A) synthesizing activity. Transformation of RNA polymerase to poly(A) polymerase resulted in reduced capacity to transcribe native DNA and altered chromatographic behavior. The results suggest that subunits of polymerase II obligatory to DNA-dependent RNA synthesis were degraded by “aging” and that a stable subunit of the RNA polymerase could preferentially make poly(A).     

Fiber composition and oxidative capacity of hamster skeletal muscle.

The hamster is a valuable biological model for physiological investigation. Despite the obvious importance of the integration of cardiorespiratory and muscular system function, little information is available regarding hamster muscle fiber type and oxidative capacity, both of which are key determinants of muscle function. The purpose of this investigation was to measure immunohistochemically the relative composition and size of muscle fibers composed of types I, IIA, IIX, and IIB fibers in hamster skeletal muscle. The oxidative capacity of each muscle was also assessed by measuring citrate synthase activity. Twenty-eight hindlimb, respiratory, and facial muscles or muscle parts from adult (144-147 g bw) male Syrian golden hamsters (n=3) were dissected bilaterally, weighed, and frozen for immunohistochemical and biochemical analysis. Combining data from all 28 muscles analyzed, type I fibers made up 5% of the muscle mass, type IIA fibers 16%, type IIX fibers 39%, and type IIB fibers 40%. Mean fiber cross-sectional area across muscles was 1665 +/- 328 microm(2) for type I fibers, 1900 +/- 417 microm(2) for type IIA fibers, 3230 +/- 784 microm(2) for type IIX fibers, and 4171 +/- 864 microm(2) for type IIB fibers. Citrate synthase activity was most closely related to the population of type IIA fibers (r=0.68, p<0.0001) and was in the rank order of type IIA > I > IIX > IIB. These data demonstrate that hamster skeletal muscle is predominantly composed of type IIB and IIX fibers.     

RNA-specific ribonucleotidyl transferases

RNA-specific nucleotidyl transferases (rNTrs) are a diverse family of template-independent polymerases that add ribonucleotides to the 3'-ends of RNA molecules. All rNTrs share a related active-site architecture first described for DNA polymerase beta and a catalytic mechanism conserved among DNA and RNA polymerases. The best known examples are the nuclear poly(A) polymerases involved in the 3'-end processing of eukaryotic messenger RNA precursors and the ubiquitous CCA-adding enzymes that complete the 3'-ends of tRNA molecules. In recent years, a growing number of new enzymes have been added to the list that now includes the "noncanonical" poly(A) polymerases involved in RNA quality control or in the readenylation of dormant messenger RNAs in the cytoplasm. Other members of the group are terminal uridylyl transferases adding single or multiple UMP residues in RNA-editing reactions or upon the maturation of small RNAs and poly(U) polymerases, the substrates of which are still not known. 2'-5'Oligo(A) synthetases differ from the other rNTrs by synthesizing oligonucleotides with 2'-5'-phosphodiester bonds de novo.     

Binding properties of avian myeloblastosis virus DNA polymerases to nucleic acid affinity columns.

A new method for the analysis and purification of the RNA-directed DNA polymerase of RNA tumor viruses has been developed. This nucleic acid affinity chromatography system utilizes an immobilized oligo (dT) moiety annealed with poly (A). The alpha and alphabeta DNA polymerases of avain myeloblastosis virus bound effectively to poly (A) oligo (dT)-cellulose. Alpha DNA polymerase did not bind effectively to poly (A) oligo (dT)-cellulose, poly (A)-cellulose, or to cellulose. Alphabeta bound to oligo (dT)-cellulose and cellulose at the same extent (approximately 30%), indicating that this enzyme did not bind specifically to the oligo (DT) moiety only. However, alphabeta bound to poly (A)-cellulose two to three times better than to cellulose itself, showing that alphabeta could bind to poly (A) without a primer. Alphabeta DNA polymerase also bound to poly (C)-cellulose, whereas alpha did not. These data show that the alpha DNA polymerase is defective in binding to nucleic acids if the beta subunit is not present. Data is presented which demonstrates that the alphabeta DNA polymerase bound tighter to poly (A). oligo (DT)-cellulose and to calf thymus DNA-cellulose than the alpha DNA polymerase, suggesting that the beta subunit or, at least part of it is responsible for this tighter binding. In addition, alphabeta DNA polymerase is able to reversibly transcribe avian myeloblastosis virus 70S RNA approximately fivefold faster than alpha DNA polymerase in the presence of Mg2+ and equally efficient in the presence of Mn2+. alpha DNA polymerase transcribed 9S globin m RNA slightly better than alphabeta with either metal ion.