Your search keyword '"Greenleaf AL"' showing total 70 results

1. RNA polymerase from sporulating Bacillus subtilis. Purification and properties of a modified form of the enzyme containing two sporulation polypeptides.

Author

Linn, T, primary, Greenleaf, AL, additional, and Losick, R, additional

Published

1975

2. CDK12 Activity-Dependent Phosphorylation Events in Human Cells.

Author

Bartkowiak B, Yan CM, Soderblom EJ, and Greenleaf AL

Subjects

Cyclin-Dependent Kinases antagonists & inhibitors, HeLa Cells, Humans, Peptides pharmacology, Phosphorylation drug effects, Protein Kinase Inhibitors pharmacology, Cyclin-Dependent Kinases metabolism

Abstract

We asked whether the C-terminal repeat domain (CTD) kinase, CDK12/CyclinK, phosphorylates substrates in addition to the CTD of RPB1, using our CDK12 analog-sensitive HeLa cell line to investigate CDK12 activity-dependent phosphorylation events in human cells. Characterizing the phospho-proteome before and after selective inhibition of CDK12 activity by the analog 1-NM-PP1, we identified 5,644 distinct phospho-peptides, among which were 50 whose average relative amount decreased more than 2-fold after 30 min of inhibition (none of these derived from RPB1). Half of the phospho-peptides actually showed >3-fold decreases, and a dozen showed decreases of 5-fold or more. As might be expected, the 40 proteins that gave rise to the 50 affected phospho-peptides mostly function in processes that have been linked to CDK12, such as transcription and RNA processing. However, the results also suggest roles for CDK12 in other events, notably mRNA nuclear export, cell differentiation and mitosis. While a number of the more-affected sites resemble the CTD in amino acid sequence and are likely direct CDK12 substrates, other highly-affected sites are not CTD-like, and their decreased phosphorylation may be a secondary (downstream) effect of CDK12 inhibition.

Published

2019

3. CDK12 loss in cancer cells affects DNA damage response genes through premature cleavage and polyadenylation.

Author

Krajewska M, Dries R, Grassetti AV, Dust S, Gao Y, Huang H, Sharma B, Day DS, Kwiatkowski N, Pomaville M, Dodd O, Chipumuro E, Zhang T, Greenleaf AL, Yuan GC, Gray NS, Young RA, Geyer M, Gerber SA, and George RE

Subjects

Cell Line, Tumor, Chromatography, High Pressure Liquid, Chromatography, Liquid, Humans, Models, Molecular, Phosphorylation, Polyadenylation, RNA Processing, Post-Transcriptional, Tandem Mass Spectrometry, Cyclin-Dependent Kinases genetics, DNA Damage, DNA Repair genetics

Abstract

Cyclin-dependent kinase 12 (CDK12) modulates transcription elongation by phosphorylating the carboxy-terminal domain of RNA polymerase II and selectively affects the expression of genes involved in the DNA damage response (DDR) and mRNA processing. Yet, the mechanisms underlying such selectivity remain unclear. Here we show that CDK12 inhibition in cancer cells lacking CDK12 mutations results in gene length-dependent elongation defects, inducing premature cleavage and polyadenylation (PCPA) and loss of expression of long (>45 kb) genes, a substantial proportion of which participate in the DDR. This early termination phenotype correlates with an increased number of intronic polyadenylation sites, a feature especially prominent among DDR genes. Phosphoproteomic analysis indicated that CDK12 directly phosphorylates pre-mRNA processing factors, including those regulating PCPA. These results support a model in which DDR genes are uniquely susceptible to CDK12 inhibition primarily due to their relatively longer lengths and lower ratios of U1 snRNP binding to intronic polyadenylation sites.

Published

2019

4. Human CDK12 and CDK13, multi-tasking CTD kinases for the new millenium.

Author

Greenleaf AL

Subjects

CDC2 Protein Kinase genetics, Cyclin-Dependent Kinases genetics, Female, Humans, Male, Ovarian Neoplasms genetics, Prostatic Neoplasms genetics, Protein Kinases genetics, CDC2 Protein Kinase metabolism, Cyclin-Dependent Kinases metabolism, Ovarian Neoplasms metabolism, Prostatic Neoplasms metabolism, Protein Kinases metabolism

Abstract

As the new millennium began, CDK12 and CDK13 were discovered as nucleotide sequences that encode protein kinases related to cell cycle CDKs. By the end of the first decade both proteins had been qualified as CTD kinases, and it was emerging that both are heterodimers containing a Cyclin K subunit. Since then, many studies on CDK12 have shown that, through phosphorylating the CTD of transcribing RNAPII, it plays critical roles in several stages of gene expression, notably RNA processing; it is also crucial for maintaining genome stability. Fewer studies on CKD13 have clearly shown that it is functionally distinct from CDK12. CDK13 is important for proper expression of a number of genes, but it also probably plays yet-to-be-discovered roles in other processes. This review summarizes much of the work on CDK12 and CDK13 and attempts to evaluate the results and place them in context. Our understanding of these two enzymes has begun to mature, but we still have much to learn about both. An indicator of one major area of medically-relevant future research comes from the discovery that CDK12 is a tumor suppressor, notably for certain ovarian and prostate cancers. A challenge for the future is to understand CDK12 and CDK13 well enough to explain how their loss promotes cancer development and how we can intercede to prevent or treat those cancers. Abbreviations: CDK: cyclin-dependent kinase; CTD: C-terminal repeat domain of POLR2A; CTDK-I: CTD kinase I (yeast); Ctk1: catalytic subunit of CTDK-I; Ctk2: cyclin-like subunit of CTDK-I; PCAP: phosphoCTD-associating protein; POLR2A: largest subunit of RNAPII; SRI domain: Set2-RNAPII Interacting domain.

Published

2019

5. Expression, purification, and identification of associated proteins of the full-length hCDK12/CyclinK complex.

Author

Bartkowiak B and Greenleaf AL

Subjects

Amino Acid Sequence, Baculoviridae metabolism, Cyclin-Dependent Kinase 2 metabolism, Cyclin-Dependent Kinase 9 metabolism, Drug Discovery, Glutathione Transferase metabolism, HeLa Cells, Humans, Mass Spectrometry, Molecular Sequence Data, Mutation, Phosphorylation, Protein Binding, Protein Structure, Tertiary, RNA metabolism, Sequence Homology, Amino Acid, Substrate Specificity, Cyclin-Dependent Kinases metabolism, Cyclins metabolism

Abstract

The coupling of transcription and associated processes has been shown to be dependent on the RNA polymerase II (RNAPII) C-terminal repeat domain (CTD) and the phosphorylation of the heptad repeats of which it is composed (consensus sequence Y1S2P3T4S5P6S7). Two primary S2 position CTD kinases have been identified in higher eukaryotes: P-TEFb and CDK12/CyclinK. The more recently discovered CDK12 appears to act at the 3'-end of the transcription unit and has been identified as a tumor suppressor for ovarian cancer; however much is still unknown about the in vivo roles of CDK12/CyclinK. In an effort to further characterize these roles we have purified to near homogeneity and characterized, full-length, active, human CDK12/CyclinK, and identified hCDK12-associated proteins via mass spectrometry. We find that employing a "2A" peptide-linked multicistronic construct containing CDK12 and CyclinK results in the efficient production of active, recombinant enzyme in the baculovirus/Sf9 expression system. Using GST-CTD fusion protein substrates we find that CDK12/CyclinK prefers a substrate with unmodified repeats or one that mimics prephosphorylation at the S7 position of the CTD; also the enzyme is sensitive to the inhibitor flavopiridol at higher concentrations. Identification of CDK12-associating proteins reveals a strong enrichment for RNA-processing factors suggesting that CDK12 affects RNA processing events in two distinct ways: Indirectly through generating factor-binding phospho-epitopes on the CTD of elongating RNAPII and directly through binding to specific factors., (© 2015 by The American Society for Biochemistry and Molecular Biology, Inc.)

Published

2015

6. A DNA damage response system associated with the phosphoCTD of elongating RNA polymerase II.

Author

Winsor TS, Bartkowiak B, Bennett CB, and Greenleaf AL

Subjects

DNA Damage genetics, Mitosis genetics, Mitosis physiology, Phosphorylation, RNA Polymerase II metabolism

Abstract

RNA polymerase II translocates across much of the genome and since it can be blocked by many kinds of DNA lesions, detects DNA damage proficiently; it thereby contributes to DNA repair and to normal levels of DNA damage resistance. However, the components and mechanisms that respond to polymerase blockage are largely unknown, except in the case of UV-induced damage that is corrected by nucleotide excision repair. Because elongating RNAPII carries with it numerous proteins that bind to its hyperphosphorylated CTD, we tested for effects of interfering with this binding. We find that expressing a decoy CTD-carrying protein in the nucleus, but not in the cytoplasm, leads to reduced DNA damage resistance. Likewise, inducing aberrant phosphorylation of the CTD, by deleting CTK1, reduces damage resistance and also alters rates of homologous recombination-mediated repair. In line with these results, extant data sets reveal a remarkable, highly significant overlap between phosphoCTD-associating protein genes and DNA damage-resistance genes. For one well-known phosphoCTD-associating protein, the histone methyltransferase Set2, we demonstrate a role in DNA damage resistance, and we show that this role requires the phosphoCTD binding ability of Set2; surprisingly, Set2's role in damage resistance does not depend on its catalytic activity. To explain all of these observations, we posit the existence of a CTD-Associated DNA damage Response (CAR) system, organized around the phosphoCTD of elongating RNAPII and comprising a subset of phosphoCTD-associating proteins.

Published

2013

7. Specific interaction of the transcription elongation regulator TCERG1 with RNA polymerase II requires simultaneous phosphorylation at Ser2, Ser5, and Ser7 within the carboxyl-terminal domain repeat.

Author

Liu J, Fan S, Lee CJ, Greenleaf AL, and Zhou P

Subjects

Humans, Nuclear Magnetic Resonance, Biomolecular, Phosphorylation physiology, Protein Binding physiology, Protein Structure, Secondary, Protein Structure, Tertiary, RNA Polymerase II genetics, RNA Polymerase II metabolism, Repetitive Sequences, Amino Acid, Serine genetics, Serine metabolism, Transcriptional Elongation Factors genetics, Transcriptional Elongation Factors metabolism, RNA Polymerase II chemistry, Serine chemistry, Transcriptional Elongation Factors chemistry

Abstract

The human transcription elongation regulator TCERG1 physically couples transcription elongation and splicing events by interacting with splicing factors through its N-terminal WW domains and the hyperphosphorylated C-terminal domain (CTD) of RNA polymerase II through its C-terminal FF domains. Here, we report biochemical and structural characterization of the C-terminal three FF domains (FF4-6) of TCERG1, revealing a rigid integral domain structure of the tandem FF repeat that interacts with the hyperphosphorylated CTD (PCTD). Although FF4 and FF5 adopt a classical FF domain fold containing three orthogonally packed α helices and a 310 helix, FF6 contains an additional insertion helix between α1 and α2. The formation of the integral tandem FF4-6 repeat is achieved by merging the last helix of the preceding FF domain and the first helix of the following FF domain and by direct interactions between neighboring FF domains. Using peptide column binding assays and NMR titrations, we show that binding of the FF4-6 tandem repeat to the PCTD requires simultaneous phosphorylation at Ser(2), Ser(5), and Ser(7) positions within two consecutive Y(1)S(2)P(3)T(4)S(5)P(6)S(7) heptad repeats. Such a sequence-specific PCTD recognition is achieved through CTD-docking sites on FF4 and FF5 of TCERG1 but not FF6. Our study presents the first example of a nuclear factor requiring all three phospho-Ser marks within the heptad repeat of the CTD for high affinity binding and provides a molecular interpretation for the biochemical connection between the Ser(7) phosphorylation enrichment in the CTD of the transcribing RNA polymerase II over introns and co-transcriptional splicing events.

Published

2013

8. Proteomic analysis of mitotic RNA polymerase II reveals novel interactors and association with proteins dysfunctional in disease.

Author

Möller A, Xie SQ, Hosp F, Lang B, Phatnani HP, James S, Ramirez F, Collin GB, Naggert JK, Babu MM, Greenleaf AL, Selbach M, and Pombo A

Subjects

Chromatography, Gel, Disease, Gene Knockdown Techniques, HeLa Cells, Humans, Immunoprecipitation, Interphase, Nuclear Proteins genetics, Nuclear Proteins isolation & purification, Nuclear Proteins metabolism, Protein Interaction Mapping, Protein Subunits genetics, Protein Subunits isolation & purification, Protein Subunits metabolism, Proteome genetics, Proteome isolation & purification, Proteome metabolism, Proteomics, RNA Interference, RNA Polymerase II isolation & purification, Ribonucleoproteins genetics, Ribonucleoproteins isolation & purification, Ribonucleoproteins metabolism, Ribosomal Proteins genetics, Ribosomal Proteins isolation & purification, Ribosomal Proteins metabolism, Transcription, Genetic, Mitosis, RNA Polymerase II metabolism

Abstract

RNA polymerase II (RNAPII) transcribes protein-coding genes in eukaryotes and interacts with factors involved in chromatin remodeling, transcriptional activation, elongation, and RNA processing. Here, we present the isolation of native RNAPII complexes using mild extraction conditions and immunoaffinity purification. RNAPII complexes were extracted from mitotic cells, where they exist dissociated from chromatin. The proteomic content of native complexes in total and size-fractionated extracts was determined using highly sensitive LC-MS/MS. Protein associations with RNAPII were validated by high-resolution immunolocalization experiments in both mitotic cells and in interphase nuclei. Functional assays of transcriptional activity were performed after siRNA-mediated knockdown. We identify >400 RNAPII associated proteins in mitosis, among these previously uncharacterized proteins for which we show roles in transcriptional elongation. We also identify, as novel functional RNAPII interactors, two proteins involved in human disease, ALMS1 and TFG, emphasizing the importance of gene regulation for normal development and physiology.

Published

2012

9. Cotranscriptional association of mRNA export factor Yra1 with C-terminal domain of RNA polymerase II.

Author

MacKellar AL and Greenleaf AL

Subjects

Amino Acid Motifs, Nuclear Proteins genetics, Phosphorylation physiology, Protein Binding, Protein Structure, Tertiary, RNA Polymerase II genetics, RNA, Fungal genetics, RNA, Messenger genetics, RNA-Binding Proteins genetics, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae Proteins genetics, Nuclear Proteins metabolism, RNA Polymerase II metabolism, RNA, Fungal biosynthesis, RNA, Messenger biosynthesis, RNA-Binding Proteins metabolism, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins metabolism, Transcription, Genetic physiology

Abstract

The unique C-terminal domain (CTD) of RNA polymerase II, composed of tandem heptad repeats of the consensus sequence YSPTSPS, is subject to differential phosphorylation throughout the transcription cycle. Several RNA processing factors have been shown to bind the phosphorylated CTD and use it to localize to nascent pre-mRNA during transcription. In Saccharomyces cerevisiae, the mRNA export protein Yra1 (ALY/RNA export factor in metazoa) cotranscriptionally associates with mRNA and delivers it to the nuclear pore complex for export to the cytoplasm. Here we report that Yra1 directly binds in vitro the hyperphosphorylated form of the CTD characteristic of elongating RNA polymerase II and contains a phospho-CTD-interacting domain within amino acids 18-184, which also include an "RNA recognition motif" (RRM) (residues 77-184). Using UV cross-linking, we showed that the RRM alone binds RNA, although a larger segment extending to the C terminus (amino acids 77-226) displayed stronger RNA binding activity. Although the RRM is implicated in both RNA and CTD binding, RRM point mutations separated these two functions. Both functions are important in vivo as RNA binding-defective or CTD binding-defective versions of Yra1 engendered growth and mRNA export defects. We also report the construction and characterization of a useful new temperature-sensitive YRA1 allele (R107A/F126A). Using ChIP, we demonstrated that removing the N-terminal 76 amino acids of Yra1 (all of the phospho-CTD-interacting domain up to the RRM) results in a 10-fold decrease in Yra1 recruitment to genes during elongation. These results indicate that the phospho-CTD is likely involved directly in the cotranscriptional recruitment of Yra1.

Published

2011

10. Phosphorylation of RNAPII: To P-TEFb or not to P-TEFb?

Author

Bartkowiak B and Greenleaf AL

Abstract

The C-terminal domain of RNA polymerase II undergoes a cycle of phosphorylation which allows it to temporally couple transcription with transcription-associated processes. The characterization of hitherto unrecognized metazoan elongation phase CTD kinase activities expands our understanding of this coupling. We discuss the circumstances that delayed the recognition of these kinase activities.

Published

2011

11. cis-Proline-mediated Ser(P)5 dephosphorylation by the RNA polymerase II C-terminal domain phosphatase Ssu72.

Author

Werner-Allen JW, Lee CJ, Liu P, Nicely NI, Wang S, Greenleaf AL, and Zhou P

Subjects

Animals, Crystallography, X-Ray, Drosophila Proteins genetics, Drosophila Proteins metabolism, Drosophila melanogaster, Phosphoprotein Phosphatases genetics, Phosphoprotein Phosphatases metabolism, Proline, Protein Structure, Tertiary, RNA Polymerase II genetics, RNA Polymerase II metabolism, Structure-Activity Relationship, Drosophila Proteins chemistry, Phosphoprotein Phosphatases chemistry, RNA Polymerase II chemistry

Abstract

RNA polymerase II coordinates co-transcriptional events by recruiting distinct sets of nuclear factors to specific stages of transcription via changes of phosphorylation patterns along its C-terminal domain (CTD). Although it has become increasingly clear that proline isomerization also helps regulate CTD-associated processes, the molecular basis of its role is unknown. Here, we report the structure of the Ser(P)(5) CTD phosphatase Ssu72 in complex with substrate, revealing a remarkable CTD conformation with the Ser(P)(5)-Pro(6) motif in the cis configuration. We show that the cis-Ser(P)(5)-Pro(6) isomer is the minor population in solution and that Ess1-catalyzed cis-trans-proline isomerization facilitates rapid dephosphorylation by Ssu72, providing an explanation for recently discovered in vivo connections between these enzymes and a revised model for CTD-mediated small nuclear RNA termination. This work presents the first structural evidence of a cis-proline-specific enzyme and an unexpected mechanism of isomer-based regulation of phosphorylation, with broad implications for CTD biology.

Published

2011

12. Updating the CTD Story: From Tail to Epic.

Author

Bartkowiak B, Mackellar AL, and Greenleaf AL

Abstract

Eukaryotic RNA polymerase II (RNAPII) not only synthesizes mRNA but also coordinates transcription-related processes via its unique C-terminal repeat domain (CTD). The CTD is an RNAPII-specific protein segment consisting of repeating heptads with the consensus sequence Y(1)S(2)P(3)T(4)S(5)P(6)S(7) that has been shown to be extensively post-transcriptionally modified in a coordinated, but complicated, manner. Recent discoveries of new modifications, kinases, and binding proteins have challenged previously established paradigms. In this paper, we examine results and implications of recent studies related to modifications of the CTD and the respective enzymes; we also survey characterizations of new CTD-binding proteins and their associated processes and new information regarding known CTD-binding proteins. Finally, we bring into focus new results that identify two additional CTD-associated processes: nucleocytoplasmic transport of mRNA and DNA damage and repair.

Published

2011

13. RECQ5 helicase associates with the C-terminal repeat domain of RNA polymerase II during productive elongation phase of transcription.

Author

Kanagaraj R, Huehn D, MacKellar A, Menigatti M, Zheng L, Urban V, Shevelev I, Greenleaf AL, and Janscak P

Subjects

Amino Acid Motifs, Amino Acid Sequence, Binding Sites, Cell Line, Cell Survival, Conserved Sequence, Humans, Molecular Sequence Data, Phosphorylation, Protein Interaction Domains and Motifs, Protein Structure, Tertiary, RNA Polymerase II chemistry, RecQ Helicases chemistry, Repetitive Sequences, Amino Acid, Spliceosomes metabolism, RNA Polymerase II metabolism, RecQ Helicases metabolism, Transcription, Genetic

Abstract

It is known that transcription can induce DNA recombination, thus compromising genomic stability. RECQ5 DNA helicase promotes genomic stability by regulating homologous recombination. Recent studies have shown that RECQ5 forms a stable complex with RNA polymerase II (RNAPII) in human cells, but the cellular role of this association is not understood. Here, we provide evidence that RECQ5 specifically binds to the Ser2,5-phosphorylated C-terminal repeat domain (CTD) of the largest subunit of RNAPII, RPB1, by means of a Set2-Rpb1-interacting (SRI) motif located at the C-terminus of RECQ5. We also show that RECQ5 associates with RNAPII-transcribed genes in a manner dependent on the SRI motif. Notably, RECQ5 density on transcribed genes correlates with the density of Ser2-CTD phosphorylation, which is associated with the productive elongation phase of transcription. Furthermore, we show that RECQ5 negatively affects cell viability upon inhibition of spliceosome assembly, which can lead to the formation of mutagenic R-loop structures. These data indicate that RECQ5 binds to the elongating RNAPII complex and support the idea that RECQ5 plays a role in the maintenance of genomic stability during transcription.

Published

2010

14. Genetic organization, length conservation, and evolution of RNA polymerase II carboxyl-terminal domain.

Author

Liu P, Kenney JM, Stiller JW, and Greenleaf AL

Subjects

Amino Acid Sequence, Circular Dichroism, Genetic Variation, Models, Genetic, Molecular Sequence Data, Mutagenesis, Insertional, Mutant Proteins chemistry, Mutant Proteins metabolism, Peptides chemistry, Peptides genetics, Peptides metabolism, Phenotype, Phosphorylation, Pliability, Protein Structure, Tertiary, Saccharomyces cerevisiae enzymology, Saccharomyces cerevisiae genetics, Structure-Activity Relationship, Conserved Sequence genetics, Evolution, Molecular, RNA Polymerase II chemistry, RNA Polymerase II genetics

Abstract

With a simple tandem iterated sequence, the carboxyl terminal domain (CTD) of eukaryotic RNA polymerase II (RNAP II) serves as the central coordinator of mRNA synthesis by harmonizing a diversity of sequential interactions with transcription and processing factors. Despite intense research interest, many key questions regarding functional and evolutionary constraints on the CTD remain unanswered; for example, what selects for the canonical heptad sequence, its tandem array across organismal diversity, and constant CTD length within given species and finally and how a sequence-identical, repetitive structure can orchestrate a diversity of simultaneous and sequential, stage-dependent interactions with both modifying enzymes and binding partners? Here we examine comparative sequence evolution of 58 RNAP II CTDs from diverse taxa representing all six major eukaryotic supergroups and employ integrated evolutionary genetic, biochemical, and biophysical analyses of the yeast CTD to further clarify how this repetitive sequence must be organized for optimal RNAP II function. We find that the CTD is composed of indivisible and independent functional units that span diheptapeptides and not only a flexible conformation around each unit but also an elastic overall structure is required. More remarkably, optimal CTD function always is achieved at approximately wild-type CTD length rather than number of functional units, regardless of the characteristics of the sequence present. Our combined observations lead us to advance an updated CTD working model, in which functional, and therefore, evolutionary constraints require a flexible CTD conformation determined by the CTD sequence and tandem register to accommodate the diversity of CTD-protein interactions and a specific CTD length rather than number of functional units to correctly order and organize global CTD-protein interactions. Patterns of conservation of these features across evolutionary diversity have important implications for comparative RNAP II function in eukaryotes and can more clearly direct specific research on CTD function in currently understudied organisms.

Published

2010

15. CDK12 is a transcription elongation-associated CTD kinase, the metazoan ortholog of yeast Ctk1.

Author

Bartkowiak B, Liu P, Phatnani HP, Fuda NJ, Cooper JJ, Price DH, Adelman K, Lis JT, and Greenleaf AL

Subjects

Animals, Blotting, Western, CDC2 Protein Kinase genetics, CDC2 Protein Kinase metabolism, Cell Line, Chromosome Mapping, Cyclin T genetics, Cyclin T metabolism, Cyclin-Dependent Kinase 9 genetics, Cyclin-Dependent Kinase 9 metabolism, Cyclin-Dependent Kinases genetics, Drosophila Proteins genetics, Drosophila melanogaster cytology, Drosophila melanogaster genetics, Drosophila melanogaster metabolism, Genetic Complementation Test, HeLa Cells, Humans, Microscopy, Fluorescence, Mutation, Phosphorylation, Protein Kinases genetics, RNA Interference, RNA Polymerase II genetics, RNA Polymerase II metabolism, Recombinant Fusion Proteins genetics, Recombinant Fusion Proteins metabolism, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae growth & development, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins genetics, Cyclin-Dependent Kinases metabolism, Drosophila Proteins metabolism, Protein Kinases metabolism, Saccharomyces cerevisiae Proteins metabolism

Abstract

Drosophila contains one (dCDK12) and humans contain two (hCDK12 and hCDK13) proteins that are the closest evolutionary relatives of yeast Ctk1, the catalytic subunit of the major elongation-phase C-terminal repeat domain (CTD) kinase in Saccharomyces cerevisiae, CTDK-I. However, until now, neither CDK12 nor CDK13 has been demonstrated to be a bona fide CTD kinase. Using Drosophila, we demonstrate that dCDK12 (CG7597) is a transcription-associated CTD kinase, the ortholog of yCtk1. Fluorescence microscopy reveals that the distribution of dCDK12 on formaldehyde-fixed polytene chromosomes is virtually identical to that of hyperphosphorylated RNA polymerase II (RNAPII), but is distinct from that of P-TEFb (dCDK9 + dCyclin T). Chromatin immunoprecipitation (ChIP) experiments confirm that dCDK12 is present on the transcribed regions of active Drosophila genes. Compared with P-TEFb, dCDK12 amounts are lower at the 5' end and higher in the middle and at the 3' end of genes (both normalized to RNAPII). Appropriately, Drosophila dCDK12 purified from nuclear extracts manifests CTD kinase activity in vitro. Intriguingly, we find that cyclin K is associated with purified dCDK12, implicating it as the cyclin subunit of this CTD kinase. Most importantly, we demonstrate that RNAi knockdown of dCDK12 in S2 cells alters the phosphorylation state of the CTD, reducing its Ser2 phosphorylation levels. Similarly, in human HeLa cells, we show that hCDK13 purified from nuclear extracts displays CTD kinase activity in vitro, as anticipated. Also, we find that chimeric (yeast/human) versions of Ctk1 containing the kinase homology domains of hCDK12/13 (or hCDK9) are functional in yeast cells (and also in vitro); using this system, we show that a bur1(ts) mutant is rescued more efficiently by a hCDK9 chimera than by a hCDK13 chimera, suggesting the following orthology relationships: Bur1 ↔ CDK9 and Ctk1 ↔ CDK12/13. Finally, we show that siRNA knockdown of hCDK12 in HeLa cells results in alterations in the CTD phosphorylation state. Our findings demonstrate that metazoan CDK12 and CDK13 are CTD kinases, and that CDK12 is orthologous to yeast Ctk1.

Published

2010

16. Comparative genome-wide screening identifies a conserved doxorubicin repair network that is diploid specific in Saccharomyces cerevisiae.

Author

Westmoreland TJ, Wickramasekara SM, Guo AY, Selim AL, Winsor TS, Greenleaf AL, Blackwell KL, Olson JA Jr, Marks JR, and Bennett CB

Subjects

Cell Cycle, DNA Damage, DNA Repair, Gene Deletion, Genomics, Killer Factors, Yeast pharmacology, Mitochondria metabolism, Mutation, Proteomics methods, Recombination, Genetic, Saccharomyces cerevisiae Proteins metabolism, Diploidy, Doxorubicin pharmacology, Genome, Fungal, Saccharomyces cerevisiae metabolism

Abstract

The chemotherapeutic doxorubicin (DOX) induces DNA double-strand break (DSB) damage. In order to identify conserved genes that mediate DOX resistance, we screened the Saccharomyces cerevisiae diploid deletion collection and identified 376 deletion strains in which exposure to DOX was lethal or severely reduced growth fitness. This diploid screen identified 5-fold more DOX resistance genes than a comparable screen using the isogenic haploid derivative. Since DSB damage is repaired primarily by homologous recombination in yeast, and haploid cells lack an available DNA homolog in G1 and early S phase, this suggests that our diploid screen may have detected the loss of repair functions in G1 or early S phase prior to complete DNA replication. To test this, we compared the relative DOX sensitivity of 30 diploid deletion mutants identified under our screening conditions to their isogenic haploid counterpart, most of which (n = 26) were not detected in the haploid screen. For six mutants (bem1Delta, ctf4Delta, ctk1Delta, hfi1Delta,nup133Delta, tho2Delta) DOX-induced lethality was absent or greatly reduced in the haploid as compared to the isogenic diploid derivative. Moreover, unlike WT, all six diploid mutants displayed severe G1/S phase cell cycle progression defects when exposed to DOX and some were significantly enhanced (ctk1Delta and hfi1Delta) or deficient (tho2Delta) for recombination. Using these and other "THO2-like" hypo-recombinogenic, diploid-specific DOX sensitive mutants (mft1Delta, thp1Delta, thp2Delta) we utilized known genetic/proteomic interactions to construct an interactive functional genomic network which predicted additional DOX resistance genes not detected in the primary screen. Most (76%) of the DOX resistance genes detected in this diploid yeast screen are evolutionarily conserved suggesting the human orthologs are candidates for mediating DOX resistance by impacting on checkpoint and recombination functions in G1 and/or early S phases.

Published

2009

17. The essential sequence elements required for RNAP II carboxyl-terminal domain function in yeast and their evolutionary conservation.

Author

Liu P, Greenleaf AL, and Stiller JW

Subjects

Amino Acid Motifs, Amino Acid Sequence, Mutant Proteins metabolism, Phenotype, Phosphorylation, Protein Binding, Protein Kinases metabolism, Protein Structure, Tertiary, Recombinant Fusion Proteins metabolism, Repetitive Sequences, Amino Acid, Saccharomyces cerevisiae cytology, Structure-Activity Relationship, Conserved Sequence, Evolution, Molecular, RNA Polymerase II chemistry, RNA Polymerase II metabolism, Saccharomyces cerevisiae enzymology

Abstract

The carboxyl-terminal domain (CTD) of eukaryotic RNA polymerase II is the staging platform for numerous proteins involved in transcription initiation, mRNA processing, and general coordination of nuclear events. Concordant with these central roles in cellular metabolism, the consensus sequence, tandemly repeated structure, and core functions of the CTD are conserved across diverse eukaryotic lineages; however, in other eukaryotes, the CTD has been allowed to degenerate completely. Even in groups where the CTD is strongly conserved, genetic analyses and comparative genomic investigations show that a variety of individual substitutions and insertions are permissible. Therefore, the specific functional constraints reflected by the CTD's conservation across much of eukaryotic evolution have remained somewhat puzzling. Here we propose a hypothesis to explain that strong conservation in budding yeast, based on both comparative and experimental evidence. Through genetic complementation for CTD function, we identify 2 sequence elements contained within pairs of heptapeptides, "Y(1)-Y(8)" and "S(2)-S(5)-S(9)," which are required for all essential CTD functions in yeast. The dual requirements of these motifs can account for strong purifying selection on the canonical CTD heptapeptide. Further, in vitro analysis of GST-CTD fusion proteins as substrates for multiple CTD-directed kinases show reduced phosphorylation efficiencies with increased distance between functional units. This indicates that requirements of the RNAP II phosphorylation cycle are most likely responsible for the strong purifying selection on tandemly repeated CTD structure.

Published

2008

18. Yeast screens identify the RNA polymerase II CTD and SPT5 as relevant targets of BRCA1 interaction.

Author

Bennett CB, Westmoreland TJ, Verrier CS, Blanchette CA, Sabin TL, Phatnani HP, Mishina YV, Huper G, Selim AL, Madison ER, Bailey DD, Falae AI, Galli A, Olson JA, Greenleaf AL, and Marks JR

Subjects

BRCA1 Protein genetics, Cell Cycle, DNA Damage, Genes, Lethal, Genomic Instability, Humans, Hydrolysis, BRCA1 Protein metabolism, Chromosomal Proteins, Non-Histone metabolism, RNA Polymerase II metabolism, Transcriptional Elongation Factors metabolism

Abstract

BRCA1 has been implicated in numerous DNA repair pathways that maintain genome integrity, however the function responsible for its tumor suppressor activity in breast cancer remains obscure. To identify the most highly conserved of the many BRCA1 functions, we screened the evolutionarily distant eukaryote Saccharomyces cerevisiae for mutants that suppressed the G1 checkpoint arrest and lethality induced following heterologous BRCA1 expression. A genome-wide screen in the diploid deletion collection combined with a screen of ionizing radiation sensitive gene deletions identified mutants that permit growth in the presence of BRCA1. These genes delineate a metabolic mRNA pathway that temporally links transcription elongation (SPT4, SPT5, CTK1, DEF1) to nucleopore-mediated mRNA export (ASM4, MLP1, MLP2, NUP2, NUP53, NUP120, NUP133, NUP170, NUP188, POM34) and cytoplasmic mRNA decay at P-bodies (CCR4, DHH1). Strikingly, BRCA1 interacted with the phosphorylated RNA polymerase II (RNAPII) carboxy terminal domain (P-CTD), phosphorylated in the pattern specified by the CTDK-I kinase, to induce DEF1-dependent cleavage and accumulation of a RNAPII fragment containing the P-CTD. Significantly, breast cancer associated BRCT domain defects in BRCA1 that suppressed P-CTD cleavage and lethality in yeast also suppressed the physical interaction of BRCA1 with human SPT5 in breast epithelial cells, thus confirming SPT5 as a relevant target of BRCA1 interaction. Furthermore, enhanced P-CTD cleavage was observed in both yeast and human breast cells following UV-irradiation indicating a conserved eukaryotic damage response. Moreover, P-CTD cleavage in breast epithelial cells was BRCA1-dependent since damage-induced P-CTD cleavage was only observed in the mutant BRCA1 cell line HCC1937 following ectopic expression of wild type BRCA1. Finally, BRCA1, SPT5 and hyperphosphorylated RPB1 form a complex that was rapidly degraded following MMS treatment in wild type but not BRCA1 mutant breast cells. These results extend the mechanistic links between BRCA1 and transcriptional consequences in response to DNA damage and suggest an important role for RNAPII P-CTD cleavage in BRCA1-mediated cancer suppression.

Published

2008

19. Phosphorylation and functions of the RNA polymerase II CTD.

Author

Phatnani HP and Greenleaf AL

Subjects

Animals, Cell Nucleus enzymology, Cell Nucleus genetics, Cell Nucleus physiology, Phosphorylation, Protein Binding, Protein Structure, Tertiary, RNA Polymerase II chemistry, Transcription, Genetic, RNA Polymerase II metabolism

Abstract

The C-terminal repeat domain (CTD), an unusual extension appended to the C terminus of the largest subunit of RNA polymerase II, serves as a flexible binding scaffold for numerous nuclear factors; which factors bind is determined by the phosphorylation patterns on the CTD repeats. Changes in phosphorylation patterns, as polymerase transcribes a gene, are thought to orchestrate the association of different sets of factors with the transcriptase and strongly influence functional organization of the nucleus. In this review we appraise what is known, and what is not known, about patterns of phosphorylation on the CTD of RNA polymerases II at the beginning, the middle, and the end of genes; the proposal that doubly phosphorylated repeats are present on elongating polymerase is explored. We discuss briefly proteins known to associate with the phosphorylated CTD at the beginning and ends of genes; we explore in more detail proteins that are recruited to the body of genes, the diversity of their functions, and the potential consequences of tethering these functions to elongating RNA polymerase II. We also discuss accumulating structural information on phosphoCTD-binding proteins and how it illustrates the variety of binding domains and interaction modes, emphasizing the structural flexibility of the CTD. We end with a number of open questions that highlight the extent of what remains to be learned about the phosphorylation and functions of the CTD.

Published

2006

20. NMR assignment of the SRI domain of human Set2/HYPB.

Author

Li M, Phatnani HP, Greenleaf AL, and Zhou P

Subjects

Binding Sites, Humans, Nuclear Magnetic Resonance, Biomolecular, Sequence Deletion, DNA-Binding Proteins chemistry, Methyltransferases chemistry, Saccharomyces cerevisiae Proteins chemistry

Published

2006

21. Solution structure of the Set2-Rpb1 interacting domain of human Set2 and its interaction with the hyperphosphorylated C-terminal domain of Rpb1.

Author

Li M, Phatnani HP, Guan Z, Sage H, Greenleaf AL, and Zhou P

Subjects

Amino Acid Sequence, Humans, Methyltransferases genetics, Models, Molecular, Molecular Sequence Data, Mutation genetics, Nuclear Magnetic Resonance, Biomolecular, Phosphorylation, Protein Binding, Protein Structure, Tertiary, Sequence Alignment, Sequence Homology, Amino Acid, Methyltransferases chemistry, Methyltransferases metabolism, RNA Polymerase II chemistry, RNA Polymerase II metabolism

Abstract

The phosphorylation state of the C-terminal repeat domain (CTD) of the largest subunit of RNA polymerase II changes as polymerase transcribes a gene, and the distinct forms of the phospho-CTD (PCTD) recruit different nuclear factors to elongating polymerase. The Set2 histone methyltransferase from yeast was recently shown to bind the PCTD of elongating RNA polymerase II by means of a novel domain termed the Set2-Rpb1 interacting (SRI) domain. Here, we report the solution structure of the SRI domain in human Set2 (hSRI domain), which adopts a left-turned three-helix bundle distinctly different from other structurally characterized PCTD-interacting domains. NMR titration experiments mapped the binding surface of the hSRI domain to helices 1 and 2, and Biacore binding studies showed that the domain binds preferably to [Ser-2 + Ser-5]-phosphorylated CTD peptides containing two or more heptad repeats. Point-mutagenesis studies identified five residues critical for PCTD binding. In view of the differential effects of these point mutations on binding to different CTD phosphopeptides, we propose a model for the hSRI domain interaction with the PCTD.

Published

2005

22. A novel domain in Set2 mediates RNA polymerase II interaction and couples histone H3 K36 methylation with transcript elongation.

Author

Kizer KO, Phatnani HP, Shibata Y, Hall H, Greenleaf AL, and Strahl BD

Subjects

Alleles, Amino Acid Substitution, Chromatin metabolism, Chromatin Immunoprecipitation, Conserved Sequence, Lysine metabolism, Methylation, Methyltransferases metabolism, Protein Interaction Mapping, Protein Structure, Tertiary genetics, Protein Structure, Tertiary physiology, Saccharomyces cerevisiae drug effects, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae Proteins metabolism, Sequence Deletion, Transcription, Genetic genetics, Uracil pharmacology, Histones metabolism, Methyltransferases chemistry, Methyltransferases physiology, RNA Polymerase II metabolism, Saccharomyces cerevisiae physiology, Saccharomyces cerevisiae Proteins chemistry, Saccharomyces cerevisiae Proteins physiology, Transcription, Genetic physiology, Uracil analogs & derivatives

Abstract

Histone methylation and the enzymes that mediate it are important regulators of chromatin structure and gene transcription. In particular, the histone H3 lysine 36 (K36) methyltransferase Set2 has recently been shown to associate with the phosphorylated C-terminal domain (CTD) of RNA polymerase II (RNAPII), implying that this enzyme has an important role in the transcription elongation process. Here we show that a novel domain in the C terminus of Set2 is responsible for interaction between Set2 and RNAPII. This domain, termed the Set2 Rpb1 interacting (SRI) domain, is encompassed by amino acid residues 619 to 718 in Set2 and is found to occur in a number of putative Set2 homologs from Schizosaccharomyces pombe to humans. Unexpectedly, BIACORE analysis reveals that the SRI domain binds specifically, and with high affinity, to CTD repeats that are doubly modified (serine 2 and serine 5 phosphorylated), indicating that Set2 association across the body of genes requires a specific pattern of phosphorylated RNAPII. Deletion of the SRI domain not only abolishes Set2-RNAPII interaction but also abolishes K36 methylation in vivo, indicating that this interaction is required for establishing K36 methylation on chromatin. Using 6-azauracil (6AU) as an indicator of transcription elongation defects, we found that deletion of the SRI domain conferred a strong resistance to this compound, which was identical to that observed with set2 deletion mutants. Furthermore, yeast strains carrying set2 alleles that are catalytically inactive or yeast strains bearing point mutations at K36 were also found to be resistant to 6AU. These data suggest that it is the methylation by Set2 that affects transcription elongation. In agreement with this, we have determined that deletion of SET2, its SRI domain, or amino acid substitutions at K36 result in an alteration of RNAPII occupancy levels over transcribing genes. Taken together, these data indicate K36 methylation, established by the SRI domain-mediated association of Set2 with RNAPII, plays an important role in the transcription elongation process.

Published

2005

23. C-terminal repeat domain kinase I phosphorylates Ser2 and Ser5 of RNA polymerase II C-terminal domain repeats.

Author

Jones JC, Phatnani HP, Haystead TA, MacDonald JA, Alam SM, and Greenleaf AL

Subjects

Amino Acid Sequence, Antibodies, Monoclonal immunology, Molecular Sequence Data, Phosphorylation, Protein Kinases chemistry, RNA Polymerase II chemistry, Saccharomycetales enzymology, Serine metabolism, Substrate Specificity, Protein Kinases metabolism, RNA Polymerase II metabolism, Repetitive Sequences, Amino Acid

Abstract

The C-terminal repeat domain (CTD) of the largest subunit of RNA polymerase II is composed of tandem heptad repeats with consensus sequence Tyr1-Ser2-Pro3-Thr4-Ser5-Pro6-Ser7. In yeast, this heptad sequence is repeated about 26 times, and it becomes hyperphosphorylated during transcription predominantly at serines 2 and 5. A network of kinases and phosphatases combine to determine the CTD phosphorylation pattern. We sought to determine the positional specificity of phosphorylation by yeast CTD kinase-I (CTDK-I), an enzyme implicated in various nuclear processes including elongation and pre-mRNA 3'-end formation. Toward this end, we characterized monoclonal antibodies commonly employed to study CTD phosphorylation patterns and found that the H5 monoclonal antibody reacts with CTD species phosphorylated at Ser2 and/or Ser5. We therefore used antibody-independent methods to study CTDK-I, and we found that CTDK-I phosphorylates Ser5 of the CTD if the CTD substrate is either unphosphorylated or prephosphorylated at Ser2. When Ser5 is already phosphorylated, CTDK-I phosphorylates Ser2 of the CTD. We also observed that CTDK-I efficiently generates doubly phosphorylated CTD repeats; CTD substrates that already contain Ser2-PO(4) or Ser5-PO(4) are more readily phosphorylated CTDK-I than unphosphorylby ated CTD substrates.

Published

2004

24. The RNA polymerase II CTD kinase CTDK-I affects pre-mRNA 3' cleavage/polyadenylation through the processing component Pti1p.

Author

Skaar DA and Greenleaf AL

Subjects

Amino Acid Sequence, Genes, Essential, Genes, Fungal, Molecular Sequence Data, Peptide Fragments chemistry, Poly A metabolism, Protein Subunits chemistry, Protein Subunits genetics, Protein Subunits metabolism, RNA Polymerase II chemistry, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae growth & development, Sequence Alignment, Sequence Homology, Amino Acid, Substrate Specificity, Transcription, Genetic, mRNA Cleavage and Polyadenylation Factors, Protein Kinases metabolism, Protein Serine-Threonine Kinases metabolism, RNA Polymerase II genetics, RNA Polymerase II metabolism, RNA Precursors metabolism, Saccharomyces cerevisiae enzymology, Saccharomyces cerevisiae Proteins

Abstract

There are several kinases in Saccharomyces cerevisiae that phosphorylate the CTD of RNA polymerase II, but specific and distinct functions of the phospho-CTDs generated by the different kinases are not well understood. A genetic screen for suppressors of loss of yeast CTD kinase I (CTDK-I) function (by deletion of the catalytic subunit gene CTK1) identified PTI1, a potential 3' cleavage/polyadenylation factor. Genetic and physical interactions connect Pti1p to components of CF IA and CF II/CPF, and mutations of PTI1 or CTK1 affect 3' cleavage site choice and transcript abundance of particular genes. Therefore, one important function of the CTDK-I-generated phospho-CTD appears to be the coupling of transcription to 3' processing of pre-mRNAs by a Pti1p-containing complex.

Published

2002

25. Hyperphosphorylated C-terminal repeat domain-associating proteins in the nuclear proteome link transcription to DNA/chromatin modification and RNA processing.

Author

Carty SM and Greenleaf AL

Subjects

Cell Fractionation, Chromatin genetics, DNA genetics, DNA metabolism, DNA-Binding Proteins metabolism, HeLa Cells, Humans, Protein Structure, Tertiary, Recombinant Proteins metabolism, Cell Nucleus metabolism, Chromatin metabolism, Nuclear Proteins metabolism, Proteome metabolism, RNA Processing, Post-Transcriptional, Transcription, Genetic

Abstract

Using an interaction blot approach to search in the human nuclear proteome, we identified eight novel proteins that bind the hyperphosphorylated C-terminal repeat domain (phosphoCTD) of RNA polymerase II. Unexpectedly, five of the new phosphoCTD-associating proteins (PCAPs) represent either enzymes that act on DNA and chromatin (topoisomerase I, DNA (cytosine-5) methyltransferase 1, poly(ADP-ribose) polymerase-1) or proteins known to bind DNA (heterogeneous nuclear ribonucleoprotein (hnRNP) U/SAF-A, hnRNP D). The other three PCAPs represent factors involved in pre-mRNA metabolism as anticipated (CA150, NSAP1/hnRNP Q, hnRNP R) (note that hnRNP U/SAF-A and hnRNP D are also implicated in pre-mRNA metabolism). Identifying as PCAPs proteins involved in diverse DNA transactions suggests that the range of phosphoCTD functions extends far beyond just transcription and RNA processing. In view of the activities possessed by the DNA-directed PCAPs, it is likely that the phosphoCTD plays important roles in genome integrity, epigenetic regulation, and potentially nuclear structure. We present a model in which the phosphoCTD association of the PCAPs poises them to act either on the nascent transcript or on the DNA/chromatin template. We propose that the phosphoCTD of elongating RNA polymerase II is a major organizer of nuclear functions.

Published

2002

26. Co-transcriptional splicing of pre-messenger RNAs: considerations for the mechanism of alternative splicing.

Author

Goldstrohm AC, Greenleaf AL, and Garcia-Blanco MA

Subjects

Animals, Humans, Models, Biological, RNA Polymerase II metabolism, RNA Precursors metabolism, RNA, Messenger genetics, RNA, Messenger metabolism, Alternative Splicing, RNA Precursors genetics, Transcription, Genetic genetics

Abstract

Nascent transcripts are the true substrates for many splicing events in mammalian cells. In this review we discuss transcription, splicing, and alternative splicing in the context of co-transcriptional processing of pre-mRNA. The realization that splicing occurs co-transcriptionally requires two important considerations: First, the cis-acting elements in the splicing substrate are synthesized at different times in a 5' to 3' direction. This dynamic view of the substrate implies that in a 100 kb intron the 5' splice site will be synthesized as much as an hour before the 3' splice site. Second, the transcription machinery and the splicing machinery, which are both complex and very large, are working in close proximity to each other. It is therefore likely that these two macromolecular machines interact, and recent data supporting this notion is discussed. We propose a model for co-transcriptional pre-mRNA processing that incorporates the concepts of splice site-tethering and dynamic exon definition. Also, we present a dynamic view of the alternative splicing of FGF-R2 and suggest that this view could be generally applicable to many regulated splicing events.

Published

2001

27. Juglone, an inhibitor of the peptidyl-prolyl isomerase Pin1, also directly blocks transcription.

Author

Chao SH, Greenleaf AL, and Price DH

Subjects

DNA, Recombinant, Dose-Response Relationship, Drug, HeLa Cells, Humans, NIMA-Interacting Peptidylprolyl Isomerase, Peptidylprolyl Isomerase genetics, Peptidylprolyl Isomerase metabolism, Plasmids genetics, RNA Polymerase II chemistry, RNA Polymerase II genetics, RNA Polymerase II metabolism, Sulfhydryl Compounds chemistry, Transcription, Genetic drug effects, Enzyme Inhibitors pharmacology, Naphthoquinones pharmacology, Peptidylprolyl Isomerase antagonists & inhibitors

Abstract

The C-terminal domain (CTD) of the large subunit of RNA polymerase II plays a role in transcription and RNA processing. Yeast ESS1, a peptidyl-prolyl cis/trans isomerase, is involved in RNA processing and can associate with the CTD. Using several types of assays we could not find any evidence of an effect of Pin1, the human homolog of ESS1, on transcription by RNA polymerase II in vitro or on the expression of a reporter gene in vivo. However, an inhibitor of Pin1, 5-hydroxy-1,4-naphthoquinone (juglone), blocked transcription by RNA polymerase II. Unlike N-ethylmaleimide, which inhibited all phases of transcription by RNA polymerase II, juglone disrupted the formation of functional preinitiation complexes by modifying sulfhydryl groups but did not have any significant effect on either initiation or elongation. Both RNA polymerases I and III, but not T7 RNA polymerase, were inhibited by juglone. The primary target of juglone has not been unambiguously identified, although a site on the polymerase itself is suggested by inhibition of RNA polymerase II during factor-independent transcription of single-stranded DNA. Because of its unique inhibitory properties juglone should prove useful in studying transcription in vitro.

Published

2001

28. The splicing factor, Prp40, binds the phosphorylated carboxyl-terminal domain of RNA polymerase II.

Author

Morris DP and Greenleaf AL

Subjects

Amino Acid Sequence, Binding Sites, Electrophoresis, Polyacrylamide Gel, Fungal Proteins chemistry, Fungal Proteins metabolism, Molecular Sequence Data, Phosphorylation, Sequence Homology, Amino Acid, Protein Serine-Threonine Kinases metabolism, RNA Polymerase II metabolism, RNA Splicing, Ribonucleoprotein, U4-U6 Small Nuclear metabolism

Abstract

We showed previously that the WW domain of the prolyl isomerase, Ess1, can bind the phosphorylated carboxyl-terminal domain (phospho-CTD) of the largest subunit of RNA Polymerase II. Analysis of phospho-CTD binding by four other WW domain-containing Saccharomyces cerevisiae proteins indicates the splicing factor, Prp40, and the RNA polymerase II ubiquitin ligase, Rsp5, can also bind the phospho-CTD. The identification of Prp40 as a phospho-CTD binding protein represents the first demonstration of direct interaction between a documented splicing factor and the phospho-CTD. Domain dissection studies reveal that phospho-CTD binding occurs at multiple locations in Prp40, including sites in both the WW and FF domain regions. Because the conserved repeats of the CTD make it an ideal ligand for multi-site binding events, the implications of multi-site binding are discussed. Our data suggest a mechanism by which the phospho-CTD of elongating RNA polymerase II facilitates commitment complex formation by juxtaposing the 5' and 3' splice sites.

Published

2000

29. Protein-interaction modules that organize nuclear function: FF domains of CA150 bind the phosphoCTD of RNA polymerase II.

Author

Carty SM, Goldstrohm AC, Suñé C, Garcia-Blanco MA, and Greenleaf AL

Subjects

Base Sequence, Cell Nucleus metabolism, DNA Primers, HeLa Cells, Humans, Phosphorylation, Protein Binding, Transcriptional Elongation Factors, RNA Polymerase II metabolism, Trans-Activators metabolism

Abstract

An approach for purifying nuclear proteins that bind directly to the hyperphosphorylated C-terminal repeat domain (CTD) of RNA polymerase II was developed and used to identify one human phosphoCTD-associating protein as CA150. CA150 is a nuclear factor implicated in transcription elongation. Because the hyperphosphorylated CTD is a feature of actively transcribing RNA polymerase II (Pol II), phosphoCTD (PCTD) binding places CA150 in a location appropriate for performing a role in transcription elongation-related events. Several recombinant segments of CA150 bound the PCTD. Predominant binding is mediated by the portion of CA150 containing six FF domains, compact modules of previously unknown function. In fact, small recombinant proteins containing the fifth FF domain bound the PCTD. PCTD binding is the first specific function assigned to an FF domain. As FF domains are found in a variety of nuclear proteins, it is likely that some of these proteins are also PCTD-associating proteins. Thus FF domains appear to be compact protein-interaction modules that, like WW domains, can be evolutionarily shuffled to organize nuclear function.

Published

2000

30. Kin28, the TFIIH-associated carboxy-terminal domain kinase, facilitates the recruitment of mRNA processing machinery to RNA polymerase II.

Author

Rodriguez CR, Cho EJ, Keogh MC, Moore CL, Greenleaf AL, and Buratowski S

Subjects

Mutation, Protein Serine-Threonine Kinases metabolism, RNA Polymerase II metabolism, RNA Precursors genetics, RNA Precursors metabolism, RNA, Fungal metabolism, RNA, Messenger metabolism, Saccharomyces cerevisiae, Cyclin-Dependent Kinases, Protein Serine-Threonine Kinases genetics, RNA Polymerase II genetics, RNA, Fungal genetics, RNA, Messenger genetics, Saccharomyces cerevisiae Proteins, Transcription, Genetic

Abstract

The cotranscriptional placement of the 7-methylguanosine cap on pre-mRNA is mediated by recruitment of capping enzyme to the phosphorylated carboxy-terminal domain (CTD) of RNA polymerase II. Immunoblotting suggests that the capping enzyme guanylyltransferase (Ceg1) is stabilized in vivo by its interaction with the CTD and that serine 5, the major site of phosphorylation within the CTD heptamer consensus YSPTSPS, is particularly important. We sought to identify the CTD kinase responsible for capping enzyme targeting. The candidate kinases Kin28-Ccl1, CTDK1, and Srb10-Srb11 can each phosphorylate a glutathione S-transferase-CTD fusion protein such that capping enzyme can bind in vitro. However, kin28 mutant alleles cause reduced Ceg1 levels in vivo and exhibit genetic interactions with a mutant ceg1 allele, while srb10 or ctk1 deletions do not. Therefore, only the TFIIH-associated CTD kinase Kin28 appears necessary for proper capping enzyme targeting in vivo. Interestingly, levels of the polyadenylation factor Pta1 are also reduced in kin28 mutants, while several other polyadenylation factors remain stable. Pta1 in yeast extracts binds specifically to the phosphorylated CTD, suggesting that this interaction may mediate coupling of polyadenylation and transcription.

Published

2000

31. Phospho-carboxyl-terminal domain binding and the role of a prolyl isomerase in pre-mRNA 3'-End formation.

Author

Morris DP, Phatnani HP, and Greenleaf AL

Subjects

Chromatography, Affinity, NIMA-Interacting Peptidylprolyl Isomerase, Peptide Fragments metabolism, Peptidylprolyl Isomerase isolation & purification, Protein Binding, Protein Kinases metabolism, Protein Structure, Tertiary, RNA Polymerase II genetics, Recombinant Fusion Proteins metabolism, Saccharomyces cerevisiae, Saccharomyces cerevisiae Proteins, Peptidylprolyl Isomerase metabolism, Phosphoproteins metabolism, RNA Polymerase II metabolism, RNA Precursors metabolism, RNA, Messenger metabolism

Abstract

A phospho-carboxyl-terminal domain (CTD) affinity column created with yeast CTD kinase I and the CTD of RNA polymerase II was used to identify Ess1/Pin1 as a phospho-CTD-binding protein. Ess1/Pin1 is a peptidyl prolyl isomerase involved in both mitotic regulation and pre-mRNA 3'-end formation. Like native Ess1, a GSTEss1 fusion protein associates specifically with the phosphorylated but not with the unphosphorylated CTD. Further, hyperphosphorylated RNA polymerase II appears to be the dominant Ess1 binding protein in total yeast extracts. We demonstrate that phospho-CTD binding is mediated by the small WW domain of Ess1 rather than the isomerase domain. These findings suggest a mechanism in which the WW domain binds the phosphorylated CTD of elongating RNA polymerase II and the isomerase domain reconfigures the CTD though isomerization of proline residues perhaps by a processive mechanism. This process may be linked to a variety of pre-mRNA maturation events that use the phosphorylated CTD, including the coupled processes of pre-mRNA 3'-end formation and transcription termination.

Published

1999

32. Modulation of RNA polymerase II elongation efficiency by C-terminal heptapeptide repeat domain kinase I.

Author

Lee JM and Greenleaf AL

Subjects

Dichlororibofuranosylbenzimidazole pharmacology, HeLa Cells, Humans, Isoquinolines pharmacology, Nucleic Acid Synthesis Inhibitors pharmacology, Subcellular Fractions metabolism, Cell Nucleus metabolism, Protein Kinases metabolism, RNA Polymerase II metabolism, Transcription, Genetic drug effects

Abstract

Hyperphosphorylation of the C-terminal heptapeptide repeat domain (CTD) of the RNA polymerase II largest subunit has been suggested to play a key role in regulating transcription initiation and elongation. To facilitate investigating functional consequences of CTD phosphorylation we developed new templates, the double G-less cassettes, which make it possible to assay simultaneously the level of initiation and the efficiency of elongation. Using these templates, we examined the effects of yeast CTD kinase I or CTD kinase inhibitors on transcription and CTD phosphorylation in HeLa nuclear extracts. Our results showed that polymerase II elongation efficiency and CTD phosphorylation are greatly reduced by CTD kinase inhibitors, whereas both are greatly increased by CTD kinase I; in contrast, transcription initiation is much less affected. These results demonstrate that CTD kinase I modulates the elongation efficiency of RNA polymerase II and are consistent with the idea that one function of CTD phosphorylation is to promote effective production of long transcripts by stimulating the elongation efficiency of RNA polymerase II.

Published

1997

33. Analyses of promoter-proximal pausing by RNA polymerase II on the hsp70 heat shock gene promoter in a Drosophila nuclear extract.

Author

Li B, Weber JA, Chen Y, Greenleaf AL, and Gilmour DS

Subjects

Amanitins pharmacology, Animals, Cell Nucleus metabolism, DNA Footprinting, DNA Transposable Elements, Drosophila melanogaster genetics, Drosophila melanogaster physiology, Genes, Insect, Kinetics, Potassium Permanganate, Time Factors, HSP70 Heat-Shock Proteins biosynthesis, HSP70 Heat-Shock Proteins genetics, Promoter Regions, Genetic, RNA Polymerase II metabolism, Transcription, Genetic

Abstract

Analyses of Drosophila cells have revealed that RNA polymerase II is paused in a region 20 to 40 nucleotides downstream from the transcription start site of the hsp70 heat shock gene when the gene is not transcriptionally active. We have developed a cell-free system that reconstitutes this promoter-proximal pausing. The paused polymerase has been detected by monitoring the hyperreactivity of thymines in the transcription bubble toward potassium permanganate. The pattern of permanganate reactivity for the hsp70 promoter in the reconstituted system matches the pattern found on the promoter after it has been introduced back into files by P-element-mediated transposition. Matching patterns of permanganate reactivity are also observed for a non-heat shock promoter, the histone H3 promoter. Further analysis of the hsp70 promoter in the reconstituted system reveals that pausing does not depend on sequence-specific interactions located immediately downstream from the pause site. Sequences upstream from the TATA box influence the recruitment of polymerase rather than the efficiency of pausing. Kinetic analysis indicates that the polymerase rapidly enters the paused state and remains stably in this state for at least 25 min. Further analysis shows that the paused polymerase will initially resume elongation when Sarkosyl is added but loses this capacity within minutes of pausing. Using an alpha-amanitin-resistant polymerase, we provide evidence that promoter-proximal pausing does not require the carboxy-terminal domain of the polymerase.

Published

1996

34. Drosophila RNA polymerase II mutants that affect transcription elongation.

Author

Chen Y, Chafin D, Price DH, and Greenleaf AL

Subjects

Animals, In Vitro Techniques, Kinetics, Mutation, Peptide Elongation Factors pharmacology, Quaternary Ammonium Compounds pharmacology, RNA Polymerase II metabolism, Transcription, Genetic drug effects, Drosophila enzymology, Drosophila genetics, RNA Polymerase II genetics

Abstract

We have examined the properties of two Drosophila RNA polymerase II mutants, C4 and S1, during elongation, pyrophosphorolysis, and DmS-II-stimulated transcript cleavage. The C4 and S1 mutants contain a single amino acid substitution in the largest and second largest subunits, respectively. Compared with wild type, C4 had a lower elongation rate and was less efficient at reading through intrinsic elongation blocks. S1 had a higher elongation rate than wild type and was more efficient at reading through the same blocks. During elongation, C4 and wild type responded similarly to DmS-II and NH4+ whereas the S1 mutant was less responsive to both. Differences between the two mutants also appeared during DmS-II-mediated transcript cleavage and pyrophosphorolysis. During extended pyrophosphorolysis, S1 polymerase was fastest and C4 polymerase was slowest at generating the final pattern of shortened transcripts. S1 and wild type were equal in the rate of extended DmS-II mediated transcript cleavage, and C4 was slower. Our results suggest that the S1 mutation increases the time spent by the polymerase in elongation competent mode and that the C4 mutation may affect the movement of the polymerase.

Published

1996

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

Author

Egyházi E, Ossoinak A, Pigon A, Holmgren C, Lee JM, and Greenleaf AL

Subjects

Amanitins pharmacology, Animals, Antibody Specificity, Chromosomes chemistry, Dichlororibofuranosylbenzimidazole pharmacology, Enzyme Induction drug effects, Phosphorylation drug effects, Protein Structure, Tertiary, RNA Polymerase II antagonists & inhibitors, RNA Polymerase II metabolism, Salivary Glands chemistry, Chironomidae genetics, Genes, Insect genetics, Transcription, Genetic physiology

Abstract

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.

Published

1996

36. The yeast carboxyl-terminal repeat domain kinase CTDK-I is a divergent cyclin-cyclin-dependent kinase complex.

Author

Sterner DE, Lee JM, Hardin SE, and Greenleaf AL

Subjects

Amino Acid Sequence, Base Sequence, Cloning, Molecular, Cold Temperature, Cyclins metabolism, Genes, Fungal genetics, Molecular Sequence Data, Mutation, Protein Kinases metabolism, Restriction Mapping, Saccharomyces cerevisiae enzymology, Saccharomyces cerevisiae growth & development, Sequence Analysis, DNA, Cyclin-Dependent Kinases genetics, Cyclin-Dependent Kinases metabolism, Protein Kinases genetics, Saccharomyces cerevisiae genetics

Abstract

Saccharomyces cerevisiae CTDK-I is a protein kinase complex that specifically and efficiently hyperphosphorylates the carboxyl-terminal repeat domain (CTD) of RNA polymerase II and is composed of three subunits of 58, 38, and 32 kDa. The kinase is essential in vivo for normal phosphorylation of the CTD and for normal growth and differentiation. We have now cloned the genes for the two smaller kinase subunits, CTK2 and CTK3, and found that they form a unique, divergent cyclin-cyclin-dependent kinase complex with the previously characterized largest subunit protein CTK1, a cyclin-dependent kinase homolog. The CTK2 gene encodes a cyclin-related protein with limited homology to cyclin C, while CTK3 shows no similarity to other known proteins. Copurification of the three gene products with each other and CTDK-I activity by means of conventional chromatography and antibody affinity columns has verified their participation in the complex in vitro. In addition, null mutations of each of the genes and all combinations thereof conferred very similar growth-impaired, cold-sensitive phenotypes, consistent with their involvement in the same function in vivo. These characterizations and the availability of all of the genes encoding CTDK-I and reagents derivable from them will facilitate investigations into CTD phosphorylation and its functional consequences both in vivo and in vitro.

Published

1995

37. Functional studies of the carboxy-terminal repeat domain of Drosophila RNA polymerase II in vivo.

Author

Brickey WJ and Greenleaf AL

Subjects

Animals, Animals, Genetically Modified, Blotting, Northern, Blotting, Southern, DNA genetics, Drosophila melanogaster enzymology, Genetic Complementation Test, Mutation, RNA Polymerase II biosynthesis, RNA, Messenger genetics, Drosophila melanogaster genetics, RNA Polymerase II genetics, Repetitive Sequences, Nucleic Acid

Abstract

To understand the in vivo function of the unique and conserved carboxy-terminal repeat domain (CTD) of RNA polymerase II largest subunit (RpII215), we have studied RNA polymerase II biosynthesis, activity and genetic function in Drosophila RpII215 mutants that possessed all (C4), half (W81) or none (IIt) of the CTD repeats. We have discovered that steady-state mRNA levels from transgenes encoding a fully truncated, CTD-less subunit (IIt) are essentially equal to wild-type levels, whereas the levels of the CTD-less subunit itself and the amount of polymerase harboring it (Pol IIT) are significantly lower than wild type. In contrast, for the half-CTD mutant (W81), steady-state mRNA levels are somewhat lower than for wild type or IIt, while W81 subunit and polymerase amounts are much less than wild type. Finally, we have tested genetically the ability of CTD mutants to complement (rescue) partially functional RpII215 alleles and have found that IIt fails to complement whereas W81 complements partially to completely. These results suggest that removal of the entire CTD renders polymerase completely defective in vivo, whereas eliminating half of the CTD results in a polymerase with significant in vivo activity.

Published

1995

38. Identifying a transcription factor interaction site on RNA polymerase II.

Author

Skantar AM and Greenleaf AL

Subjects

Animals, Base Sequence, Binding Sites, Drosophila genetics, Genes, Insect, Molecular Sequence Data, Peptide Fragments metabolism, Protein Binding, Protein Structure, Tertiary, RNA Polymerase II chemistry, RNA Polymerase II genetics, Recombinant Fusion Proteins metabolism, beta-Galactosidase genetics, RNA Polymerase II metabolism, Transcription Factors metabolism

Abstract

We have generated a series of fusion proteins carrying portions of subunit IIc, the second largest subunit of Drosophila RNA polymerase I, and have used them in a domain interference assay to identify a fragment of the IIc subunit that carries the binding site for a basal transcription factor. Fusion proteins carrying a subunit IIc fragment spanning residues Ala519-Gly992 strongly inhibit promoter-driven transcription in both unfractionated nuclear extracts and in reconstituted systems. The same fusion proteins similarly inhibit dTFIIF stimulation of Pol II elongation on dC-tailed templates, suggesting that the IIc(A519-G992) fragment, which carries conserved regions D-H, interferes with transcription by binding to dTFIIF. Finally, dTFIIF can be specifically cross-linked to a GST-IIc(A519-G992) fusion protein or to subunit IIc in intact Pol II.

Published

1995

39. A positive addition to a negative tail's tale.

Author

Greenleaf AL

Subjects

Amino Acid Sequence, Animals, Gene Expression Regulation, Molecular Sequence Data, Phosphoproteins metabolism, Phosphorylation, Phosphotyrosine, Protein-Tyrosine Kinases metabolism, RNA, Messenger genetics, Repetitive Sequences, Nucleic Acid, Tyrosine analogs & derivatives, Tyrosine metabolism, RNA Polymerase II chemistry

Published

1993

40. Locus-specific variation in phosphorylation state of RNA polymerase II in vivo: correlations with gene activity and transcript processing.

Author

Weeks JR, Hardin SE, Shen J, Lee JM, and Greenleaf AL

Subjects

Amino Acid Sequence, Animals, Antibodies, Drosophila, Heat-Shock Proteins genetics, Microscopy, Fluorescence, Molecular Sequence Data, Phosphorylation, RNA Polymerase II chemistry, RNA, Messenger genetics, Chromosomes chemistry, RNA Polymerase II physiology, Transcription, Genetic physiology

Abstract

To investigate functional differences between RNA polymerases IIA and IIO (Pol IIA and Pol IIO), with hypo- and hyperphosphorylated carboxy-terminal repeat domains (CTDs), respectively, we have visualized the in vivo distributions of the differentially phosphorylated forms of Pol II on Drosophila polytene chromosomes. Using phosphorylation state-sensitive antibodies and immunofluorescence microscopy with digital imaging, we find Pol IIA and Pol IIO arrayed in markedly different, locus- and condition-specific patterns. Major ecdysone-induced puffs, for example, stain exclusively for Pol IIO, indicating that hyperphosphorylated Pol II is the transcriptionally active form of the enzyme on these genes. In striking contrast, induced heat shock puffs stain strongly for both Pol IIA and Pol IIO, suggesting that heat shock genes are transcribed by a mixture of hypo- and hyperphosphorylated forms of Pol II. At the insertion sites of a transposon carrying a hybrid hsp70-lacZ transgene, we observe only Pol IIA before heat shock induction, consistent with the idea that Pol II arrested on the hsp70 gene is form IIA. After a 90-sec heat shock, we detect heat shock factor (HSF) at the transposon insertion sites; and after a 5-min shock its spatial distribution on the induced transgene puffs is clearly resolved from that of Pol II. Finally, using antibodies to hnRNP proteins and splicing components, we have discerned an apparent overall correlation between the presence and processing of nascent transcripts and the presence of Pol IIO.

Published

1993

41. Mapping mutations in genes encoding the two large subunits of Drosophila RNA polymerase II defines domains essential for basic transcription functions and for proper expression of developmental genes.

Author

Chen Y, Weeks J, Mortin MA, and Greenleaf AL

Subjects

Amino Acid Sequence, Animals, Base Sequence, Cloning, Molecular, DNA, Drosophila melanogaster enzymology, Drosophila melanogaster growth & development, Genes, Insect, Molecular Sequence Data, Polymerase Chain Reaction, RNA Polymerase II metabolism, Sequence Homology, Amino Acid, Drosophila melanogaster genetics, Gene Expression Regulation, Mutation, RNA Polymerase II genetics, Transcription, Genetic

Abstract

We have mapped a number of mutations at the DNA sequence level in genes encoding the largest (RpII215) and second-largest (RpII140) subunits of Drosophila melanogaster RNA polymerase II. Using polymerase chain reaction (PCR) amplification and single-strand conformation polymorphism (SSCP) analysis, we detected 12 mutations from 14 mutant alleles (86%) as mobility shifts in nondenaturing gel electrophoresis, thus localizing the mutations to the corresponding PCR fragments of about 350 bp. We then determined the mutations at the DNA sequence level by directly subcloning the PCR fragments and sequencing them. The five mapped RpII140 mutations clustered in a C-terminal portion of the second-largest subunit, indicating the functional importance of this region of the subunit. The RpII215 mutations were distributed more broadly, although six of eight clustered in a central region of the subunit. One notable mutation that we localized to this region was the alpha-amanitin-resistant mutation RpII215C4, which also affects RNA chain elongation in vitro. RpII215C4 mapped to a position near the sites of corresponding mutations in mouse and in Caenorhabditis elegans genes, reinforcing the idea that this region is involved in amatoxin binding and transcript elongation. We also mapped mutations in both RpII215 and RpII140 that cause a developmental defect known as the Ubx effect. The clustering of these mutations in each gene suggests that they define functional domains in each subunit whose alteration induces the mutant phenotype.

Published

1993

42. Reverse genetics of Drosophila RNA polymerase II: identification and characterization of RpII140, the genomic locus for the second-largest subunit.

Author

Hamilton BJ, Mortin MA, and Greenleaf AL

Subjects

Animals, Blotting, Western, Chromosome Mapping, Cloning, Molecular, Drosophila melanogaster enzymology, Gene Library, In Situ Hybridization, Transcription, Genetic, Drosophila melanogaster genetics, RNA Polymerase II genetics

Abstract

We have used a reverse genetics approach to isolate genes encoding two subunits of Drosophila melanogaster RNA polymerase II. RpII18 encodes the 18-kDa subunit and maps cytogenetically to polytene band region 83A. RpII140 encodes the 140-kDa subunit and maps to polytene band region 88A10:B1,2. Focusing on RpII140, we used in situ hybridization to map this gene to a small subinterval defined by the endpoints of a series of deficiencies impinging on the 88A/B region and showed that it does not represent a previously known genetic locus. Two recently defined complementation groups, A5 and Z6, reside in the same subinterval and thus were candidates for the RpII140 locus. Phenotypes of A5 mutants suggested that they affect RNA polymerase II, in that the lethal phase and the interaction with developmental loci such as Ubx resemble those of mutants in the gene for the largest subunit, RpII215. Indeed, we have achieved complete genetic rescue of representative recessive lethal mutations of A5 with a P-element construct containing a 9.1-kb genomic DNA fragment carrying RpII140. Interestingly, the initial construct also rescued lethal alleles in the neighboring complementation group, Z6, revealing that the 9.1-kb insert carries two genes. Deleting coding region sequences of RpII140, however, yielded a transformation vector that failed to rescue A5 alleles but continued to rescue Z6 alleles. These results strongly support the conclusion that the A5 complementation group is equivalent to the genomic RpII140 locus.

Published

1993

43. CTD kinase large subunit is encoded by CTK1, a gene required for normal growth of Saccharomyces cerevisiae.

Author

Lee JM and Greenleaf AL

Subjects

Amino Acid Sequence, Base Sequence, Chromosome Deletion, Cloning, Molecular, Gene Library, Molecular Sequence Data, Mutation, Phosphorylation, Protein Conformation, Protein Kinases chemistry, RNA Polymerase II metabolism, Saccharomyces cerevisiae enzymology, Sequence Homology, Nucleic Acid, Protein Kinases genetics, Saccharomyces cerevisiae genetics

Abstract

We previously purified a yeast protein kinase that specifically hyperphosphorylates the carboxyl-terminal repeat domain (CTD) of RNA polymerase II largest subunit and showed that this CTD kinase consists of three subunits of 58, 38, and 32 kDa. We have now cloned, sequenced, and characterized CTK1, the gene encoding the 58 kDa alpha subunit. The CTK1 gene product contains a central domain homologous to catalytic subunits of other protein kinases, notably yeast CDC28, suggesting that the 58 kDa subunit is catalytic. Cells that carry a disrupted version of the CTK1 gene lack the characterized CTD kinase activity, grow slowly and are cold-sensitive, demonstrating that the CTK1 gene product is essential for CTD kinase activity and normal growth. While ctk1 mutant cells do contain phosphorylated forms of the RNA polymerase II largest subunit, these forms differ from those found in wild type cells, implicating CTK1 as a component of the physiologically significant CTD phosphorylating machinery. As befitting an enzyme with a nuclear function, the N-terminal region of the CTK1 protein contains a nuclear targeting signal.

Published

1991

44. The carboxyl-terminal repeat domain of RNA polymerase II is not required for transcription factor Sp1 to function in vitro.

Author

Zehring WA and Greenleaf AL

Subjects

Animals, Base Sequence, Cells, Cultured, Drosophila enzymology, Drosophila genetics, Heat-Shock Proteins genetics, Molecular Sequence Data, Oligonucleotide Probes, Promoter Regions, Genetic, RNA Polymerase II metabolism, Sp1 Transcription Factor, Transcription, Genetic, DNA-Binding Proteins metabolism, RNA Polymerase II genetics, Repetitive Sequences, Nucleic Acid, Transcription Factors metabolism

Abstract

We show that the mammalian transcription Sp1 stimulates accurate transcription in a partially fractionated RNA polymerase II-dependent system from Drosophila cultured cells. Moreover, the extent of stimulation is equal for intact RNA polymerase II (polymerase IIA) and polymerase lacking the unique carboxyl-terminal domain of the largest subunit (polymerase IIB). We conclude that in this system Sp1 interacts with a component of the transcription machinery, other than the carboxyl-terminal domain, which is preserved between mammals and insects.

Published

1990

45. Identification of a structural gene for a RNA polymerase II polypeptide in Drosophila melanogaster and mammalian species.

Author

Ingles CJ, Biggs J, Wong JK, Weeks JR, and Greenleaf AL

Subjects

Animals, Cricetinae, Cricetulus, Drosophila melanogaster enzymology, Mesocricetus, Mutation, Nucleic Acid Hybridization, Peptides genetics, Species Specificity, Transcription, Genetic, Cloning, Molecular, DNA-Directed RNA Polymerases genetics, Drosophila melanogaster genetics, Genes, RNA Polymerase II genetics

Abstract

Using subclones representing 14 kilobase pairs (kb) of DNA from the Drosophila melanogaster RNA polymerase II (EC 2.7.7.6) X-linked genetic locus, RpII, we have identified four poly(A)+ RNA transcripts in adult flies. The DNA encoding only one of these, a 7-kb transcript, cross-hybridized to mammalian DNA. DNA from alpha-amanitin-resistant (AmaR) Chinese hamster ovary (CHO) and human cells was used to transform the temperature-sensitive (TS) RNA polymerase II Syrian hamster mutant TsAF8. The acquisition of the TS+ AmaR RNA polymerase II phenotype was accompanied by the appearance of donor-DNA-specific restriction fragments that cross-hybridize to the D. melanogaster 7-kb transcript DNA. This D. melanogaster DNA and the related DNA detected in mammalian species must therefore be the structural gene for a RNA polymerase II polypeptide.

Published

1983

46. Properties of mutationally altered RNA polymerases II of Drosophila.

Author

Coulter DE and Greenleaf AL

Subjects

Animals, Cations, Divalent, Drosophila melanogaster genetics, Embryo, Nonmammalian enzymology, Kinetics, Osmolar Concentration, RNA Polymerase II isolation & purification, RNA Polymerase II metabolism, DNA-Directed RNA Polymerases genetics, Drosophila melanogaster enzymology, Mutation, RNA Polymerase II genetics

Abstract

We tested and compared several in vitro properties of wild type and mutant RNA polymerases II from Drosophila melanogaster, using several different mutants of a single X-linked genetic locus, RpIIC4 (Greenleaf, A. L., Weeks, J. R., Voelker, R. A., Ohnishi, S., and Dickson, B. (1980) Cell 21, 785-792); the mutants tested included the original amanitin-resistant mutant, C4, which is nonconditional, plus the temperature-sensitive mutants A9, C20, E28, and 1Fb40. Using a tritium-labeled amanitin derivative, we demonstrated that C4 polymerase has a reduced binding affinity for amanitin. The C4 polymerase was as stable to thermal denaturation as the wild type enzyme, and the two enzymes had similar specific activities, ionic strength and Mn2+ requirements, and apparent Km values for UTP and GTP when assayed in the presence of Mn2+. However, with Mg2+ as the divalent cation, C4 polymerase was less active than wild type and had 2-fold higher apparent Km values for UTP and GTP. Three of the temperature-sensitive mutants, A9, C20, and E28, were derived from the amanitin-resistant mutant C4; the polymerase II activities from these mutants displayed resistance to alpha-amanitin in vitro identical with that of the C4 enzyme. C20, E28, and 1Fb40 polymerases were markedly less stable to thermal denaturation in vitro than wild type polymerase. The results presented indicate that the mutations at the RNA polymerase locus (RpIIC4-) directly alter the structure of the enzyme, providing conclusive evidence that the locus is a structural gene for a polymerase II subunit.

Published

1982

47. Localization of RNA polymerase in polytene chromosomes of Drosophila melanogaster.

Author

Jamrich M, Greenleaf AL, and Bautz EK

Subjects

Animals, Chromosomes ultrastructure, Fluorescent Antibody Technique, Histones metabolism, Hot Temperature, RNA Polymerase II immunology, Sex Chromosomes metabolism, Chromosomes metabolism, DNA-Directed RNA Polymerases metabolism, Drosophila melanogaster metabolism, RNA Polymerase II metabolism

Abstract

RNA polymerase (RNA nucleotidyltransferase) B (or II) and histone H1 of Drosophila melanogster were localized on salivary gland polytene chromosomes using the indirect immunofluorescence technique. RNA polymerase B is present almost exclusively in puffs and interband regions, whereas histone H1 is found primarily in bands. The puff at region 3C, known to be transcriptionally active in larval salivary glands, gives a bright fluorescence with antibodies against RNA polymerase B. This fluorescence disappears after exposure of the larvae to 37 degrees for 45 min. The heat shock treatment results in a general reduction of fluorescence intensity with the appearance of brightly staining heat shock puffs. Heat-induced removal of RNA polymerase molecules from a puff does not immediately alter its morphology. We propose than an interband represents that fraction of the total number of gene copies in a band that are active, the inactive copies being present in a condensed form in the adjacent band. Large puffs would originate through the decondensation and activation of most or all gene copies in a band.

Published

1977

48. Dynamic interaction between a Drosophila transcription factor and RNA polymerase II.

Author

Price DH, Sluder AE, and Greenleaf AL

Subjects

Animals, Drosophila genetics, Kinetics, Protein Conformation, Transcription Factors isolation & purification, Transcription, Genetic, Drosophila metabolism, RNA Polymerase II metabolism, Transcription Factors metabolism

Abstract

We have purified factor 5, a Drosophila RNA polymerase II transcription factor. Factor 5 was found to be required for accurate initiation of transcription from specific promoters and also had a dramatic effect on the elongation properties of RNA polymerase II. Kinetic studies suggested that factor 5 stimulates the elongation rate of RNA polymerase II on a dC-tailed, double-stranded template by reducing the time spent at the numerous pause sites encountered by the polymerase. The factor was found to be composed of two polypeptides (34 and 86 kilodaltons). Both subunits bound tightly to pure RNA polymerase II but were not bound to polymerase in elongation complexes. Our results suggest that factor 5 interacts briefly with the paused polymerase molecules and catalyzes a conformational change in them such that they adopt an elongation-competent conformation.

Published

1989

49. Identification, molecular cloning, and mutagenesis of Saccharomyces cerevisiae RNA polymerase genes.

Author

Ingles CJ, Himmelfarb HJ, Shales M, Greenleaf AL, and Friesen JD

Subjects

Animals, Base Sequence, DNA analysis, DNA Restriction Enzymes, Drosophila melanogaster enzymology, Escherichia coli genetics, Nucleic Acid Hybridization, RNA Polymerase II genetics, Saccharomyces cerevisiae enzymology, Transcription, Genetic, Cloning, Molecular, DNA-Directed RNA Polymerases genetics, Genes, Genes, Fungal, Saccharomyces cerevisiae genetics

Abstract

Three different regions of Saccharomyces cerevisiae DNA were identified by using as hybridization probe a fragment of Drosophila melanogaster DNA that encodes an RNA polymerase II (EC 2.7.7.6) polypeptide. Two of these regions have been molecularly cloned. Each contains a sequence related not only to the D. melanogaster DNA fragment that was used as a probe in its isolation but also to the immediately adjacent DNA fragment of the D. melanogaster RNA polymerase II gene. The two cloned S. cerevisiae DNA sequences are each the template for single transcripts in vivo, one of 5.9 kilobases and the other of 4.6 kilobases. In vitro translation of hybrid-selected cellular RNA indicated that the former locus encodes a protein of Mr 220,000, equal in size to the largest polypeptide subunit of S. cerevisiae RNA polymerase II. Disruption of either gene by targeted integration of URA3+ DNA demonstrated that each is single-copy and essential in a haploid genome. We suggest that these S. cerevisiae loci are members of a family of related genes encoding the largest subunit polypeptides of RNA polymerases I, II, and III.

Published

1984

50. Immunological studies of RNA polymerase II using antibodies to subunits of Drosophila and wheat germ enzyme.

Author

Weeks JR, Coulter DE, and Greenleaf AL

Subjects

Animals, Antibodies, Cattle, Fluorescent Antibody Technique, Immunodiffusion, Macromolecular Substances, RNA Polymerase II antagonists & inhibitors, Thymus Gland enzymology, Triticum enzymology, DNA-Directed RNA Polymerases immunology, Drosophila enzymology, Epitopes analysis, Plants enzymology, RNA Polymerase II immunology

Abstract

We induced goat antibodies to Drosophila RNA polymerase II and rabbit antibodies to the isolated 215,000-dalton and 140,000-dalton polymerase II subunits (P215 and P140, respectively). Similarly, we induced rabbit antibodies to wheat germ RNA polymerase II and to the 220,000-dalton subunit and 140,000-dalton subunit (P220 and P140, respectively). Anti-polymerase antibodies precipitated the homologous native enzyme and inhibited its activity in vitro, while several of the anti-subunit sera did neither. The anti-Drosophila P215 serum specifically labeled RNA polymerase II fixed in situ on polytene chromosomes. We reacted the antibodies with polymerase subunits separated by sodium dodecyl sulfate gel electrophoresis and electrophoretically transferred to nitrocellulose ("protein blotting"). Each antibody to whole polymerase reacted with multiple subunits, while the anti-subunit sera each reacted specifically with the subunit employed as immunogen. The anti-subunit sera also cross-reacted with the analogous subunit from several heterologous polymerases II (from yeast, wheat germ, Drosophila, and calf thymus), demonstrating shared subunit-specific determinants in polymerase II from widely divergent organisms. The anti-polymerase sera also showed cross-reactivity with subunits of heterologous enzymes, but only in one case did the cross-reactivity involve subunits other than the two largest ones. Specifically, the goat anti-Drosophila polymerase serum displayed easily detectable cross-reactivity with four low molecular weight subunits of calf thymus polymerase II, providing a unique demonstration of antigenic relatedness of small RNA polymerase II subunits from different higher eukaryotes.

Published

1982