Purification using polyethylenimine precipitation and low molecular weight subunit analyses of calf thymus and wheat germ DNA-dependent RNA polymerase II

Hodo, Henry G.; Blatti, S. P.

doi:10.1021/bi00630a005

Cited by 220 publications

(104 citation statements)

References 27 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Purification of RNA polymerase II from calf thymus was carried out by a modification ofthe method of Hodo and Blatti (28), except that all buffers contained 0.1% Nonidet P-40. Fractions from the phosphocellulose column containing RNAP II activity were pooled and applied to a heparin-agarose column equilibrated with buffer containing 60 mM ammonium sulfate.…”

Section: Methodsmentioning

confidence: 99%

Identification of autoantibodies to RNA polymerase II. Occurrence in systemic sclerosis and association with autoantibodies to RNA polymerases I and III.

et al. 1993

View full text Add to dashboard Cite

In this study, autoantibodies to RNA polymerase II from sera of patients with systemic sclerosis have been identified and characterized. These antibodies immunoprecipitated polypeptides of 220 kD (IIA) and 145 kD (IIC), the two largest subunits of RNA polymerase II, and bound both subunits in immunoblots. These polypeptides were immunoprecipitated by the anti-RNA polymerase II monoclonal antibody 8WG16, which recognizes the carboxyl-terminal domain of the 220-kD subunit, and their identity to the proteins bound by human sera was confirmed in immunodepletion studies. Sera with anti-RNA polymerase II antibodies also immunoprecipitated proteins that were consistent with components of RNA polymerases I and III. In vitro transcription experiments showed that the human antibodies were an effective inhibitor of RNA polymerase II activity. In indirect immunofluorescence studies, anti-RNA polymerase II autoantibodies stained the nucleoplasm, as expected from the known location of RNA polymerase II, and colocalized with the anti-RNA polymerase II monoclonal antibody. The human sera also stained the nucleolus, the location of RNA polymerase I. From a clinical perspective, these antibodies were found in 13 of 278 patients with systemic sclerosis, including 10 with diffuse and three with limited cutaneous disease, but were not detected in sera from patients with other connective tissue diseases and from normal controls. We conclude that anti-RNA polymerase II antibodies are specific to patients with systemic sclerosis, and that they are apparently associated with antibodies to RNA polymerases I and III. These autoantibodies may be useful diagnostically and as a probe for further studies ofthe biological function ofRNA polymerases. (J. Clin. Invest. 1993. 91:2665-2672

show abstract

Section: Methodsmentioning

confidence: 99%

Identification of autoantibodies to RNA polymerase II. Occurrence in systemic sclerosis and association with autoantibodies to RNA polymerases I and III.

et al. 1993

View full text Add to dashboard Cite

show abstract

“…However, analysis of specific transcription products by polyacrylamide gel electrophoresis revealed that these enzyme preparations contained a small amount of RNA polymerase III activity resistant to 2 pLg of a-amanitin per ml. (Residual RNA polymerase III has also been observed [51] in RNA polymerase II preparations purified by the method of Hodo and Blatti [27] were obtained from D. Bentley and M. Groudine. The templates used for transcription were generated by restriction digestion of the plasmid at a unique site followed by addition of single-stranded polydeoxycytidylate extensions of 30 to 100 residues by using terminal deoxynucleotidyl transferase (28).…”

Section: Methodsmentioning

confidence: 99%

Intrinsic sites of transcription termination and pausing in the c-myc gene.

Kerppola¹,

Kane²

1988

Mol. Cell. Biol.

View full text Add to dashboard Cite

We have studied transcription elongation and termination in the human c-myc gene. Transcription of c-myc gene sequences with purified mammalian RNA polymerase II revealed several sites of transcription termination and pausing in the vicinity of the exon 1-intron 1 junction. This region previously has been shown to block transcription elongation in vivo by nuclear run-on analysis (D. Bentley and M. Groudine, Nature [London] 321:702-706, 1986). These sites were recognized by purified RNA polymerase II, and we therefore designated them intrinsic sites of termination and pausing. Two of these sites cause termination of RNA polymerase Ill transcription as well. RNA polymerase II terminated transcription in a cluster of seven consecutive T residues in the nontranscribed strand and paused during transcription at three additional sites in this region. The intrinsic sites of transcription termination and pausing described here correspond closely to the 3' ends of transcripts synthesized in Xenopus oocytes injected with plasmids containing the c-myc termination region (D. Bentley and M. Groudine, Cell 53:245-256, 1988). This correspondence suggests that the intrinsic recognition of these termination and pause sites by purified RNA polymerase II may play a role in the transcription elongation block observed in vivo.

show abstract

“…While a number of groups have purified human pol II and associated proteins (26,32,36,45,51; also reviewed in references 57 and 70), it has been clear from a comparison of results that the number, molecular weight, and quantity of copurified proteins are somewhat variable between different groups and starting sources of material, and it was previously uncertain whether a human RPB4 homolog existed. The ϳ27 kDa hsRPB7 species and ϳ18-to 19-kDa native hsRPB4 species described in this work are now shown to be present in affinity-purified pol II, conclusively demonstrating their functionality in mammalian cells.…”

Section: Conservation Of Hsrpb4 Mmrpb4 and Rpb4 Subunitsmentioning

confidence: 99%

Analysis of the Interaction of the Novel RNA Polymerase II (pol II) Subunit hsRPB4 with Its Partner hsRPB7 and with pol II

Khazak

Estojak

Cho

et al. 1998

Molecular and Cellular Biology

View full text Add to dashboard Cite

Under conditions of environmental stress, prokaryotes and lower eukaryotes such as the yeast Saccharomyces cerevisiae selectively utilize particular subunits of RNA polymerase II (pol II) to alter transcription to patterns favoring survival. In S. cerevisiae, a complex of two such subunits, RPB4 and RPB7, preferentially associates with pol II during stationary phase; of these two subunits, RPB4 is specifically required for survival under nonoptimal growth conditions. Previously, we have shown that RPB7 possesses an evolutionarily conserved human homolog, hsRPB7, which was capable of partially interacting with RPB4 and the yeast transcriptional apparatus. Using this as a probe in a two-hybrid screen, we have now established that hsRPB4 is also conserved in higher eukaryotes. In contrast to hsRPB7, hsRPB4 has diverged so that it no longer interacts with yeast RPB7, although it partially complements rpb4 ؊ phenotypes in yeast. However, hsRPB4 associates strongly and specifically with hsRPB7 when expressed in yeast or in mammalian cells and copurifies with intact pol II. hsRPB4 expression in humans parallels that of hsRPB7, supporting the idea that the two proteins may possess associated functions. Structure-function studies of hsRPB4-hsRPB7 are used to establish the interaction interface between the two proteins. This identification completes the set of human homologs for RNA pol II subunits defined in yeast and should provide the basis for subsequent structural and functional characterization of the pol II holoenzyme.Selective control of mRNA transcription in response to intracellular and extracellular signals occurs at multiple levels, with targets for regulation including gene-specific transcription factors, general transcription factors, and the RNA polymerase II holoenzyme (15,18,38,55,63). This last mechanism of regulation, involving modification of core RNA polymerase II (pol II) structural composition by altering incorporation of subunits or regulated phosphorylation, has been well documented in prokaryotes and in yeast (17,31,59,62,70). In higher eukaryotes, the majority of transcriptional control studies have focused on characterizing the expression and modification of gene-specific and general transcription factors. However, a growing body of work on mammalian transcriptional control has demonstrated that mammalian pol II is also subject to modification by phosphorylation of the largest subunit, presumably as a means of regulation (10,24,41,42,49). In contrast, the issue of subunit variation has not been actively investigated.Studies of eukaryotic pol II function have depended heavily on paradigms developed through detailed characterization of the yeast Saccharomyces cerevisiae pol II (reviewed in reference 70). Yeast pol II contains 12 subunits (RPB1-12), all of which have been cloned and sequenced and many of which have been subjected to genetic and biochemical functional analysis. Five of these subunits, the common subunits (RPB5, RPB6, RPB8, RPB10, and RPB12), are also incorporated into RNA polymeras...

show abstract

Purification using polyethylenimine precipitation and low molecular weight subunit analyses of calf thymus and wheat germ DNA-dependent RNA polymerase II

Cited by 220 publications

References 27 publications

Identification of autoantibodies to RNA polymerase II. Occurrence in systemic sclerosis and association with autoantibodies to RNA polymerases I and III.

Identification of autoantibodies to RNA polymerase II. Occurrence in systemic sclerosis and association with autoantibodies to RNA polymerases I and III.

Intrinsic sites of transcription termination and pausing in the c-myc gene.

Analysis of the Interaction of the Novel RNA Polymerase II (pol II) Subunit hsRPB4 with Its Partner hsRPB7 and with pol II

Contact Info

Product

Resources

About