Selective repression of RNA polymerase II by microinjected phosvitin

Phosphorylation dependence of the initiation of productive transcription of Balbiani ring 2 genes in living cells

Using polytene chromosomes of salivary gland cells of Chironomus tentans, phosphorylation state-sensitive antibodies and the transcription and protein kinase inhibitor 5,6-dichloro-1-beta-D-ribofuranosylbenzimidazole (DRB), we have visualized the chromosomal distribution of RNA polymerase II (pol II) with hypophosphorylated (pol IIA) and hyperphosphorylated (pol II0) carboxyl-terminal repeat domain (CTD). DRB blocks labeling of the CTD with 32Pi within minutes of its addition, and nuclear pol II0 is gradually converted to IIA; this conversion parallels the reduction in transcription of protein-coding genes. DRB also alters the chromosomal distribution of II0: there is a time-dependent clearance from chromosomes of phosphoCTD (PCTD) after addition of DRB, which coincides in time with the completion and release of preinitiated transcripts. Furthermore, the staining of smaller transcription units is abolished before that of larger ones. The staining pattern of chromosomes with anti-CTD antibodies is not detectably influenced by the DRB treatment, indicating that hypophosphorylated pol IIA is unaffected by the transcription inhibitor. Microinjection of synthetic heptapeptide repeats, anti-CTD and anti-PCTD antibodies into salivary gland nuclei hampered the transcription of BR2 genes, indicating the requirement for CTD and PCTD in transcription in living cells. The results demonstrate that in vivo the protein kinase effector DRB shows parallel effects on an early step in gene transcription and the process of pol II hyperphosphorylation. Our observations are consistent with the proposal that the initiation of productive RNA synthesis is CTD-phosphorylation dependent and also with the idea that the gradual dephosphorylation of transcribing pol II0 is coupled to the completion of nascent pol II gene transcripts.

The salivary gland 42-kDa phosphoprotein is a single-stranded DNA-binding protein with characteristics of the epithelial casein kinase N42 in Chironomus tentans

The DNA-binding and phosphorylation properties of a rapidly phosphorylated nuclear 42-kDa phosphoprotein and of its two structurally related proteins, pp43 and pp44 in Chironomus tentans salivary glands were investigated. pp42, pp43 and pp44 bind promoter probes of the ecdysterone controlled I-18C gene and of the joint histone H2A/H2B genes in a sequence-selective and single-stranded DNA (ssDNA) specific manner. Rapid phosphorylation appears to give pp42 and pp43 uniquely hydrophilic characters making them soluble in the aqueous phase during phenol treatment. Dephosphorylation of the nuclear proteins markedly stimulates the ssDNA-binding activity of pp42 but not of pp43 and pp44. All three phosphoproteins are sensitive to heparin and the transcription inhibitor 5,6-dichloro-1-beta-D-ribofuranosylbenzimidazole (DRB) in vitro, but their sensitivity to heparin is more than one order of magnitude lower than that of casein kinase II. The heparin sensitivity of pp42 and pp43 is, however, similar to that described for a previously identified nuclear 42-kDa phosphoprotein in a Chironomus tentans epithelial cell line, casein kinase N42 (CKN42). pp42 and pp43 bind with high affinity to a Phosvitin-Sepharose matrix, like casein kinase I, II and N42, and can be eluted with high salt buffers from the affinity column. In intact salivary gland cells, microinjected (gamma-32P)GTP labels pp42 in a heparin sensitive manner, and this GTP-phosphorylation of pp42 could be competed out by a large excess of phosvitin. (gamma-32P)ATP-based phosphorylation of pp42 was uninfluenced by phosvitin in intact cells. The experimental data suggest that the salivary gland 42-kDa phosphoprotein, pp42, is a ssDNA-binding protein with characteristics of the epithelial CKN42.

A novel nuclear 42-kDa casein kinase identified in Chironomus tentans

We have purified and characterised an apparently novel nuclear 42-kDa casein kinase from epithelial cells of Chironomus tentans which comigrates with a phosphoprotein associated with transcriptionally active salivary gland genes. The protein kinase promotes phosphorylation of casein and phosvitin, using either ATP or GTP as phosphate donors, and undergoes autophosphorylation. The casein kinase activity of the 42-kDa protein is sensitive to heparin, 5,6-dichloro-1-beta-D-ribofuranosylbezimidazole (DRB), spermine and spermidine indicating that it is a novel enzyme with similar but not identical properties to casein kinase II or nuclear protein kinase NII.

The nuclear 42-kDa phosphoprotein preferentially binds promoter-containing single-stranded DNA

The DNA-binding activity of a 42-kDa phosphoprotein from salivary gland cells and cultured epithelial cells of Chironomus tentans have been analyzed by the Southwestern technique. Both the salivary gland and the epithelial cell 42-kDa polypeptides were found to be single-stranded DNA-binding proteins. They bind to single-stranded promoter-containing restriction fragments including sequences from -204 to +74 from the ecdysterone controlled I-18C gene as well as sequences including the joint histone H2A/H2B promoters in a sequence selective manner. By contrast, the 42-kDa polypeptides show no significant binding to intragenic restriction fragments from +71 to +351 from the I-18C gene. Previous and present data taken together suggest that the 42-kDa protein has a general role in the regulation of protein coding genes.

Analysis of the structural relationships between the DNA-binding phosphoproteins pp42, pp43 and pp44 by in situ peptide mapping

A structural homology is established between three DNA-binding phosphoproteins located in the 42 to 44 kDa range, referred to as pp42, pp43 and pp44, from Chironomus tentans salivary gland cells by in situ peptide mapping. The staining patterns of pp42, pp43 and pp44 which resulted from digestion with Staphylococcus aureus V8, trypsin or papain proteases show the presence of 8 to 15 spots majority of which have identical mobility. In the patterns of the digests generated by treatments with trypsin about 10 spots appear in common between any pair of the protein substrates. In addition, each pattern includes two to three peptides of mobility not present in the other. Thus the peptide mapping of pp42, pp43 and pp44 based on the staining patterns of proteolytic digests suggest the existence of structural homology between the three unlabelled substrates. The proteolytic peptides carrying the rapidly turning over phosphate groups form markedly different electrophoretic patterns than the unlabelled peptides visualized by staining. Treatment of 32P-labelled pp42, pp43 and pp44 with V8 generates only one labelled fragment in the 30 kD range. The cleavage patterns of pp44 produced by chymotrypsin or papain contain seven to ten labelled fragments while those of pp42 and pp43 contain only two. The 32P-labelled tryptic peptides of pp42, pp43 and pp44 exhibit a ladder pattern for each substrate which probably arise by a consecutive removal of 25 to 35 amino acid residues from the primary digestion products pp29, pp29.5 and pp30 by cleavage of four to five putative interdomain regions. The possibility that these three structurally related phosphoproteins belong to the category of transcription factors is discussed.

The rapidly phosphorylated chromosomal 42-kDa protein is a subunit of larger protein complexes

We have isolated, purified and characterized a 42-kDa phosphoprotein which has been found to be preferentially associated with active gene loci of salivary gland cells of Chironomus tentans. The rapidly phosphorylated form of this protein could be extracted with 0.2 M NaCl. Chromatographic analysis by gel filtration revealed that a significant fraction of labelled 42-kDa polypeptide elutes with an apparent molecular mass of 150 to 200 kDa. The result suggests that a portion of the phosphorylated 42-kDa polypeptide in native state forms a multisubunit protein complex consisting of rapidly phosphorylated 42-kDa polypeptide chains alone.

Kinetics of inhibition by 5,6-dichloro-1-beta-D-ribofuranosylbenzimidazole on calf thymus casein kinase II

The adenosine analogue 5,6-dichloro-1-beta-D-ribofuranosylbenzimidazole (DRB) is a specific inhibitor for RNA polymerase II transcription in vivo and in vitro [Tamm + Sehgal (1978) Adv. Virus Res. 22, 187-258; Zandomeni & Weinmann (1984) J. Biol. Chem. 259, 14804-14811]. The effect on RNA polymerase II-specific transcription seems to be mediated by its inhibition of nuclear casein kinase II [Zandomeni, Carrera-Zandomeni, Shugar & Weinmann (1986) J. Biol. Chem. 261, 3414-3419]. Inhibition studies indicated that DRB acted as a mixed-type inhibitor with respect to casein and as a competitive inhibitor with respect to the nucleotide phosphate donor substrates. The DRB inhibition constant is 7 microM for the calf thymus casein kinase II, with regard to both ATP and GTP.

Effects of anti-C23 (nucleolin) antibody on transcription of ribosomal DNA in Chironomus salivary gland cells

Protein C23 (also called nucleolin or 100-kDa nucleolar protein) is a major nucleolar phosphoprotein involved in ribosome biogenesis. To determine the effects of protein C23 on preribosomal RNA (pre-rRNA) synthesis anti-C23 antiserum was microinjected into nuclei of Chironomus tentans salivary glands. Transcription was measured by incubation of the glands with 32P-labeled RNA precorsors followed by microdissection of nucleoli, RNA extraction, and electrophoretic analyses. Injection of the anti-C23 antibody caused a 2- to 3.5-fold stimulation of 32P incorporation into 38S pre-rRNA. No stimulation was observed in salivary glands injected with preimmune serum or antiserum preabsorbed with protein C23. The stimulatory effect was selective for pre-rRNA as indicated by the lack of stimulation of 32P incorporation into extranucleolar RNA. Injection of the antiserum produced little or no effect on pre-RNA processing as measured by the relative amounts of 32P-labeled intermediate cleavage products of pre-rRNA in stimulated versus control glands. When protein extracts of Chironomus tentans salivary gland nuclei were probed on Western blots with anti-C23 antibody the predominant cross-reacting species was a 110-kDa polypeptide which had an electrophoretic mobility similar to that of protein C23. These results suggest that protein C23 not only is involved in ribosome assembly but also plays a role in regulating the transcription of the preribosomal RNA.

Microinjection of anti-topoisomerase I immunoglobulin G into nuclei of Chironomus tentans salivary gland cells leads to blockage of transcription elongation

Purified anti-topoisomerase I immunoglobulin G (IgG) was microinjected into nuclei of Chironomus tentans salivary gland cells, and the effect on DNA transcription was investigated. Synthesis of nucleolar preribosomal 38S RNA by RNA polymerase I and of chromosomal Balbiani ring RNA by RNA polymerase II was inhibited by about 80%. The inhibitory action of anti-topoisomerase I IgG could be reversed by the addition of exogenous topoisomerase I. Anti-topoisomerase I IgG had less effect on RNA polymerase II-promoted activity of other less efficiently transcribing heterogeneous nuclear RNA genes. The pattern of inhibition of growing nascent Balbiani ring chains indicated that the transcriptional process was interrupted at the level of chain elongation. The highly decondensed state of active Balbiani ring chromatin, however, remained unaffected after injection of topoisomerase I antibodies. These data are consistent with the interpretation that topoisomerase I is an essential component in the transcriptional process but not in the maintenance of the decondensed state of active chromatin.

Microinjection of anti-topoisomerase I immunoglobulin G into nuclei of Chironomus tentans salivary gland cells leads to blockage of transcription elongation

Purified anti-topoisomerase I immunoglobulin G (IgG) was microinjected into nuclei of Chironomus tentans salivary gland cells, and the effect on DNA transcription was investigated. Synthesis of nucleolar preribosomal 38S RNA by RNA polymerase I and of chromosomal Balbiani ring RNA by RNA polymerase II was inhibited by about 80%. The inhibitory action of anti-topoisomerase I IgG could be reversed by the addition of exogenous topoisomerase I. Anti-topoisomerase I IgG had less effect on RNA polymerase II-promoted activity of other less efficiently transcribing heterogeneous nuclear RNA genes. The pattern of inhibition of growing nascent Balbiani ring chains indicated that the transcriptional process was interrupted at the level of chain elongation. The highly decondensed state of active Balbiani ring chromatin, however, remained unaffected after injection of topoisomerase I antibodies. These data are consistent with the interpretation that topoisomerase I is an essential component in the transcriptional process but not in the maintenance of the decondensed state of active chromatin.

Differential kinase systems are involved in the rapidly turning over phosphorylation of prominent nuclear proteins

The activity of endogenous nuclear protein kinases has been probed in an vitro assay system of isolated nuclei from Chironomus salivary gland cells. The phosphorylation of a set of seven prominent rapidly phosphorylated non-histone proteins and of histones H3, H2A and H4 was analyzed using ATP or GTP as phosphoryl donor and heparin as protein kinase effector. The core histones H2A and H3 both incorporate 32P from [gamma-32P]ATP as well as from [gamma-32P]GTP but their phosphorylation is differentially affected by heparin. The phosphorylation of H2A is blocked by heparin while that of H3 is even stimulated in the presence of heparin when ATP is used as phosphate donor. H4 is unable to incorporate phosphate groups from GTP but its ATP-based phosphorylation is heparin sensitive. Of the non-histone protein kinase substrates, we could only detect two, the 44-kDa and 115-kDa proteins, which are heparin sensitive with either ATP or GTP and, thus, strictly meet the criteria for casein kinase type II-specific phosphorylation. The investigated histones and non-histone proteins can be grouped into three broad categories on the basis of their phosphorylation properties. (A) Proteins very likely affected by casein kinase NII. (B) Proteins phosphorylated by strictly ATP-specific protein kinases. (C) Proteins phosphorylated by ATP as well as GTP utilizing protein kinase(s) other than casein NII. Category B proteins can be subdivided into proteins phosphorylated in a heparin-resistant (B1) and heparin-sensitive (B2) manner. The phosphorylation of category C proteins may be heparin sensitive with ATP only (C1), heparin sensitive with GTP only (C2), heparin insensitive with both ATP and GTP (C3) or stimulated by heparin (C4).