Phosphorylation of yeast DNA-dependent RNA polymerases in vivo and in vitro. Isolation of enzymes and identification of phosphorylated subunits

Nuclear Actin: From Discovery to Function

While actin was discovered in the nucleus over 50 years ago, research lagged for decades due to strong skepticism. The revitalization of research into nuclear actin occurred after it was found that cellular stresses induce the nuclear localization and alter the structure of actin. These studies provided the first hints that actin has a nuclear function. Subsequently, it was established that the nuclear import and export of actin is highly regulated. While the structures of nuclear actin remain unclear, it can function as monomers, polymers, and even rods. Furthermore, even within a given structure, distinct pools of nuclear actin that can be differentially labeled have been identified. Numerous mechanistic studies have uncovered an array of functions for nuclear actin. It regulates the activity of RNA polymerases, as well as specific transcription factors. Actin also modulates the activity of several chromatin remodeling complexes and histone deacetylases, to ultimately impinge on transcriptional programing and DNA damage repair. Further, nuclear actin mediates chromatin movement and organization. It has roles in meiosis and mitosis, and these functions may be functionally conserved from ancient bacterial actin homologs. The structure and integrity of the nuclear envelope and sub-nuclear compartments are also regulated by nuclear actin. Furthermore, nuclear actin contributes to human diseases like cancer, neurodegeneration, and myopathies. Here, we explore the early discovery of actin in the nucleus and discuss the forms and functions of nuclear actin in both normal and disease contexts. Anat Rec, 301:1999-2013, 2018. © 2018 Wiley Periodicals, Inc.

Site specific phosphorylation of yeast RNA polymerase I

All nuclear RNA polymerases are phosphoprotein complexes. Yeast RNA polymerase I (Pol I) contains approximately 15 phosphate groups, distributed to 5 of the 14 subunits. Information about the function of the single phosphosites and their position in the primary, secondary and tertiary structure is lacking. We used a rapid and efficient way to purify yeast RNA Pol I to determine 13 phosphoserines and –threonines. Seven of these phosphoresidues could be located in the 3D-homology model for Pol I, five of them are more at the surface. The single phosphorylated residues were systematically mutated and the resulting strains and Pol I preparations were analyzed in cellular growth, Pol I composition, stability and genetic interaction with non-essential components of the transcription machinery. Surprisingly, all Pol I phosphorylations analyzed were found to be non-essential post-translational modifications. However, one mutation (subunit A190 S685D) led to higher growth rates in the presence of 6AU or under environmental stress conditions, and was synthetically lethal with a deletion of the Pol I subunit A12.2, suggesting a role in RNA cleavage/elongation or termination. Our results suggest that individual major or constitutively phosphorylated residues contribute to non-essential Pol I-functions.

Localization of the Escherichia coli RNA polymerase beta' subunit residue phosphorylated by bacteriophage T7 kinase Gp0.7

During bacteriophage T7 infection, the Escherichia coli RNA polymerase beta' subunit is phosphorylated by the phage-encoded kinase Gp0.7. Here, we used proteolytic degradation and mutational analysis to localize the phosphorylation site to a single amino acid, Thr(1068), in the evolutionarily hypervariable segment of beta'. Using a phosphomimetic substitution of Thr(1068), we show that phosphorylation of beta' leads to increased rho-dependent transcription termination, which may help to switch from host to viral RNA polymerase transcription during phage development.

Rrn3 phosphorylation is a regulatory checkpoint for ribosome biogenesis

Cycloheximide inhibits ribosomal DNA (rDNA) transcription in vivo. The mouse homologue of yeast Rrn3, a polymerase-associated transcription initiation factor, can complement extracts from cycloheximide-treated mammalian cells. Cycloheximide inhibits the phosphorylation of Rrn3 and causes its dissociation from RNA polymerase I. Rrn3 interacts with the rpa43 subunit of RNA polymerase I, and treatment with cycloheximide inhibits the formation of a Rrn3.rpa43 complex in vivo. Rrn3 produced in Sf9 cells but not in bacteria interacts with rpa43 in vitro, and such interaction is dependent upon the phosphorylation state of Rrn3. Significantly, neither dephosphorylated Rrn3 nor Rrn3 produced in Escherichia coli can restore transcription by extracts from cycloheximide-treated cells. These results suggest that the phosphorylation state of Rrn3 regulates rDNA transcription by determining the steady-state concentration of the Rrn3.RNA polymerase I complex within the nucleolus.

A serine residue in the N-terminal acidic region of rat RPB6, one of the common subunits of RNA polymerases, is exclusively phosphorylated by casein kinase II in vitro

RPB6 is one of the common subunits of all eukaryotic RNA polymerases and is indispensable for the enzyme function. Here, we isolated a rat cDNA encoding RPB6. It contained 127 amino acid (a.a.) residues. From alignment of RPB6 homologues of various eukaryotes, we defined two conserved regions, i.e. an N-terminal acidic region and a C-terminal core. In this study, we investigated in vitro phosphorylation of rat RPB6 by casein kinase II (CKII), a pleiotropic regulator of numerous cellular proteins. Three putative CKII-phosphorylated a.a. within rat RPB6 were assigned. We found that serines were phosphorylated by CKII in vitro. Mutagenesis studies provided evidence that a serine at a.a. position 2 was exclusively phosphorylated. Finally, an RPB6-engaged in-gel kinase assay clarified that CKII was a prominent protein kinase in rat liver nuclear extract that phosphorylates RPB6. Therefore, RPB6 was implied to be phosphorylated by CKII in the nucleus. We postulate that the N-terminal acidic region of the RPB6 subunit has some phosphorylation-coupled regulatory functions.

A shared subunit belongs to the eukaryotic core RNA polymerase

The yeast RNA polymerase I is a multimeric complex composed of 14 distinct subunits, 5 of which are shared by the three forms of nuclear RNA polymerase. The reasons for this structural complexity are still largely unknown. Isolation of an inactive form of RNA Pol I lacking the A43, ABC23, and A14 subunits (RNA Pol I delta) allowed us to investigate the function of the shared subunit ABC23 by in vitro reconstitution experiments. Addition of recombinant ABC23 alone to the RNA Pol I delta reactivated the enzyme to up to 50% of the wild-type enzyme activity. The recombinant subunit was stably and stoichiometrically reassociated within the enzymatic complex. ABC23 was found to be required for the formation of the first phosphodiester bond, but it was not involved in DNA binding by RNA Pol I, as shown by gel retardation and surface plasmon resonance experiments, and did not recycle during transcription. Electron microscopic visualization and electrophoretic analysis of the subunit depleted and reactivated forms of the enzyme indicate that binding of ABC23 caused a major conformational change leading to a transcriptionally competent enzyme. Altogether, our results demonstrate that the ABC23 subunit is required for the structural and functional integrity of RNA Pol I and thus should be considered as part of the core enzyme.

A 14-kDa Arabidopsis thaliana RNA polymerase III subunit contains two alpha-motifs flanked by a highly charged C terminus

We have sequenced a cDNA and a gene, AtRPC14, from Arabidopsis thaliana (At) (ecotype Columbia) that encode a protein related to the yeast RNA polymerases (Pol) I and III subunits, yAC19. Polyclonal antibodies raised against the recombinant At polypeptide (AtC14) bind to the Pol I and/or III subunits of about 13-15 kDa, but do not bind to any Pol II subunit in Pol purified from cauliflower, wheat or At. The amino acid (aa) sequence derived from the AtRPC14 cDNA and genomic clones consists of 122 aa, as compared to the 142 aa in the yeast yAC19 subunit and 143 aa in a putative Caenorhabditis elegans CeAC16 subunit. AtC14, yAC19 and CeAC16 contain a conserved sequence of about 85 aa which is related to two motifs in the alpha subunit of Escherichia coli (Ec) Pol. AtC14 lacks a highly charged N terminus of about 50 aa found in both yAC19 and CeAC16, but has a highly charged C terminus of about 30 aa not found in yAC19 and CeAC16.

20-Hydroxyecdysone stimulates RNA polymerase I activity in silkmoth wing epidermis by increased synthesis and phosphorylation

The activities of RNA polymerases I and II in the wing epidermis of diapausing silkmoth pupae increased about tenfold during the first day after administration of either 20-hydroxyecdysone (20E) or 20E plus juvenile hormone (Katula et al., 1981a). The aim of these studies was to correlate these increases in RNA polymerase I and II activities to their amounts in hormone stimulated wing epidermis. The enzyme activities were measured by standard procedures while their amounts were determined by the application of a modified ELISA with subunit-specific monoclonal antibodies. Results showed that the increase in the amount of RNA polymerase I during the first 24 h accounted for only about 60% of the increase in activity. Alkaline phosphatase decreased the activity of the newly synthesized enzyme by 40-50%. These results indicate that hormone-stimulation of RNA polymerase I activity is due to a combination of synthesis of the enzyme and phosphorylation of the enzyme and/or tightly associated factors. RNA polymerases II and III determined by differential ELISA using a monoclonal antibody specific to a common subunit followed developmental changes similar to those of RNA polymerase I. The amounts and activity of the enzymes during the first 48 h were similar in wing tissue that followed the second pupal development (20E + juvenile hormone) compared to tissue that developed into adult wings (20E).

Phosphorylation of the C-terminal domain of RNA polymerase II

The CTD has become a focal point in the analysis of RNAP II. The unusual properties of the CTD, including its unique structure and high level of phosphorylation, have stimulated interest in understanding the role this domain plays in the transcription of protein-coding genes. Research during the past ten years suggests that the CTD may function at multiple steps in the transcription cycle and that its involvement is promoter dependent. The general idea, for which there is now considerable support, is that the CTD mediates the interaction of RNAP II with the transcription apparatus and that these interactions are influenced by the phosphorylation that occurs throughout the CTD. The temporal relationship between phosphorylation of the CTD and the progression of RNAP II through the transcription cycle has been established in a general sense. However, it is not clear that the modifications that occur at a given time are causally related to the progression of RNAP II beyond that point in the transcription cycle. The idea that phosphorylation of the CTD mediates the release of RNAP II from the preinitiation complex is an attractive one and consistent with a number of experimental results. However, an increasing number of observations suggest that CTD phosphorylation and promoter clearance may not be causally related. One possibility is that even though phosphorylation occurs concomitant with transcript initiation it plays no real role in the initiation process and is necessary only to establish an elongation competent form of the enzyme. Alternatively, CTD phosphorylation may play an essential role in the release of RNAP II from preinitiation complexes in vivo but may be dispensable in defined in vitro transcription systems. Finally it may be important to distinguish between promoter clearance as defined by RNAP moving off the transcriptional start site and the complete disruption of interactions between RNAP II and the preinitiation complex. Because of the extended nature of the CTD, RNAP II may remain tethered to factors assembled on the promoter even though a short transcript has been synthesized. Clearly additional research is necessary to (a) define the contacts made by the CTD in preinitiation complexes, (b) understand the relationship between the disruption of these contacts and CTD phosphorylation and (c) understand biochemically what is required to generate an elongation competent form of RNAP II. The possibility that the CTD plays a role in transcript elongation has been proposed since the discovery of the CTD [15].(ABSTRACT TRUNCATED AT 400 WORDS)

Subunits shared by eukaryotic nuclear RNA polymerases

RNA polymerases I, II, and III share three subunits that are immunologically and biochemically indistinguishable. The Saccharomyces cerevisiae genes that encode these subunits (RPB5, RPB6, and RPB8) were isolated and sequenced, and their transcriptional start sites were deduced. RPB5 encodes a 25-kD protein, RPB6, an 18-kD protein, and RPB8, a 16-kD protein. These genes are single copy, reside on different chromosomes, and are essential for viability. The fact that the genes are single copy, corroborates previous evidence suggesting that each of the common subunits is identical in RNA polymerases I, II, and III. Furthermore, immunoprecipitation of RPB6 coprecipitates proteins whose sizes are consistent with RNA polymerase I, II, and III subunits. Sequence similarity between the yeast RPB5 protein and a previously characterized human RNA polymerase subunit demonstrates that the common subunits of the nuclear RNA polymerases are well conserved among eukaryotes. The presence of these conserved and essential subunits in all three nuclear RNA polymerases and the absence of recognizable sequence motifs for DNA and nucleoside triphosphate-binding indicate that the common subunits do not have a catalytic role but are important for a function shared by the RNA polymerases such as transcriptional efficiency, nuclear localization, enzyme stability, or coordinate regulation of rRNA, mRNA, and tRNA synthesis.

A suppressor of a HIS4 transcriptional defect encodes a protein with homology to the catalytic subunit of protein phosphatases

Reversion analysis has identified four suppressor genes that permit transcription of the Saccharomyces cerevisiae HIS4 gene in the absence of GCN4, BAS1, and BAS2, trans-acting proteins normally required for activation of HIS4 transcription. These suppressor genes encode factors that affect the transcription of many diverse genes. Two of these suppressors, SIT1 and SIT2, are encoded by RPB1 and RPB2, the genes for the two largest subunits of RNA polymerase II. All strains containing suppressor mutations in RPB1 and RPB2 have reduced transcription of the INO1 gene and an inositol requirement. Mutations in SIT3 or high copy number SIT3 increase HIS4 transcription in the absence of GCN4, BAS1, and BAS2. This increase in HIS4 transcription by high copy number SIT3 or by sit3 alleles is largely independent of the HIS4 TATA sequence. The SIT4 protein is over 50% identical to the catalytic subunit of bovine type 2A protein phosphatase. sit4 mutations in combination with suppressor mutations in RPB1 or RPB2 (sit1, sit4 or sit2, sit4) are lethal, suggesting an interaction between SIT4 and RNA polymerase II.

Regulation of phosphatidylinositol kinase activity in Saccharomyces cerevisiae

The effects of growth phase and carbon source on membrane-associated phosphatidylinositol kinase in cell extracts of Saccharomyces cerevisiae were examined. Phosphatidylinositol kinase activity increased 2- and 2.5-fold in glucose- and glycerol-grown cells, respectively, in the stationary phase as compared with the exponential phase of growth. The increase in phosphatidylinositol kinase activity in the stationary phase of growth correlated with an increase in the relative amounts of phosphatidylinositol 4-phosphate, the product of the reaction. The increase in phosphatidylinositol kinase activity was not due to the presence of water-soluble effector molecules in cell extracts as indicated by mixing experiments. Phosphatidylinositol kinase activity decreased in cell extracts of exponential-phase cells preincubated under phosphorylation conditions which favor cyclic AMP-dependent protein kinase activity. Phosphatidylinositol kinase activity was not affected in cell extracts of stationary-phase cells preincubated under phosphorylation conditions.

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

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

Identification of a phosphorylated form of phosphoenolpyruvate carboxykinase from the yeast Saccharomyces cerevisiae

A phosphoprotein of 65 kDa, as determined by SDS-gel electrophoresis, has been isolated from yeast crude extracts. This phospho form copurifies with phosphoenolpyruvate carboxykinase in the enzyme purification procedure worked out in our laboratory (Tortora, P., Hanozet, G.M. and Guerritore, A. (1985) Anal. Biochem. 144, 179-185). Moreover, both proteins bind strongly to 5'AMP-Sepharose 4B in the presence of Mn2+, whereas a substantially lower binding occurs if Mn2+ is replaced by Mg2+. This binding pattern is consistent with the well-known Mn2+-dependence of yeast phosphoenolpyruvate carboxykinase. These data suggest that the 65-kDa protein might be a phosphorylation product of the native enzyme. Furthermore, although the phospho form is not immunoprecipitated by anti-phosphoenolpyruvate carboxykinase antibodies, addition of Protein A-Sepharose CL-4B to crude extracts preincubated with the antibodies results in the binding to the resin of the phospho form, thus providing immunological evidence for its identification as a modified form of native enzyme. The same 65-kDa phosphoprotein is detectable in extracts from cells grown in the presence of [32P]Pi, as well as in cell extracts incubated with [gamma-32P]ATP. Moreover, digestion of the phosphoprotein with BrCN or with Staphylococcus aureus V8 proteinase, yields two and three fragments, respectively, which appear parallel to digestion products of phosphoenolpyruvate carboxykinase, again supporting the proposed identification. Finally, analysis of the phosphorylated amino acids in the 65-kDa protein shows that phosphoserine is the only labelled phosphoamino acid.

The cAMP cascade in the nervous system: molecular sites of action and possible relevance to neuronal plasticity

Many intercellular messages regulate the activity of their target cells by altering the intracellular level of cAMP and, as a consequence, the phosphorylation state of proteins which serve as substrates for cAMP-dependent protein kinase. Such regulation plays a crucial role in neuronal development, neuronal function, and neuronal plasticity (e.g., elementary learning mechanisms). Ample information has been accumulated in recent years on the enzymes that regulate the level of cAMP or respond to it, on the regulation of cAMP synthesis by neurohormones, neurotransmitters, ions, and toxins, on neuronal-specific substrate proteins that are phosphorylated by the cAMP-dependent kinase, and on the interaction of the cAMP-cascade with other second-messenger systems within neurons. Such data, obtained by a combination of molecular-biological, biochemical, and cellular approaches, shed light on the detailed mechanisms by which modulation of a ubiquitous molecular cascade leads to a great variety of short-term as well as long-term specific neuronal responses and alterations.

Partial purification and characterization of the interconvertible forms of trehalase from Saccharomyces cerevisiae

Cryptic trehalase from Saccharomyces cerevisiae was purified about 3000-fold. The recovery of 970% of the original "activity" indicated the removal of an inhibitor of the enzyme. Active trehalase, obtained through phosphorylation of cryptic trehalase by cAMP-dependent protein kinase, was isolated by chromatography on DEAE-cellulose. A major phosphorylated protein, with an apparent Mr of 86,000, was detected after SDS-polyacrylamide gel electrophoresis. This protein band correlated exactly with the elution profile of trehalase activity and 32Pi incorporation into the enzyme on DEAE-cellulose chromatography. Partially purified active trehalase showed absolute specificity towards trehalose with an apparent Km of 4.79 X 10(-3) M. Both forms of the enzyme showed an apparent molecular weight of 160,000, by gel filtration. Centrifugation on a glycerol density gradient indicated multiple forms of trehalase-c, with Mr of 320,000, 160,000, and 80,000. After activation of each of these forms by protein kinase, a single form of trehalase-a was observed, with a Mr of 160,000. Trehalase-c appears to be a totally inactive form of the enzyme. The only mechanism of activation seems to be phosphorylation by cAMP-dependent protein kinase. When the protein kinase concentration was varied, at a fixed trehalase-c concentration, a sigmoidal activation plot was obtained. This result suggests the occurrence of multiple forms of cryptic trehalase.

Protein phosphorylation in peroxisomes

The possible presence of phosphorylated proteins in peroxisomes was studied in hepatocytes from nafenopin-treated and normal rats. A 63 kDa phosphorylated protein was consistently and exclusively found in the membrane of peroxisomes from hepatocytes incubated in the presence of 32P-phosphate. The peroxisomes were isolated in metrizamide isopycnic gradients of postnuclear supernatants and were subfractionated by alkaline extraction to separate the membrane and the matrix proteins. Polyacrylamide gel electrophoresis, autoradiography and densitometry were employed to characterize the proteins. The 63 kDa membrane protein copurifies with peroxisomes in metrizamide gradients and apparently can be phosphorylated, in purified peroxisomes, with ATP and catalytic subunit of cAMP-dependent protein kinase.

Eukaryotic RNA polymerases

This review will attempt to cover the present information on the multiple forms of eukaryotic DNA-dependent RNA polymerases, both at the structural and functional level. Nuclear RNA polymerases constitute a group of three large multimeric enzymes, each with a different and complex subunit structure and distinct specificity. The review will include a detailed description of their molecular structure. The current approaches to elucidate subunit function via chemical modification, phosphorylation, enzyme reconstitution, immunological studies, and mutant analysis will be described. In vitro reconstituted systems are available for the accurate transcription of cloned genes coding for rRNA, tRNA, 5 SRNA, and mRNA. These systems will be described with special attention to the cellular factors required for specific transcription. A section on future prospects will address questions concerning the significance of the complex subunit structure of the nuclear enzymes; the organization and regulation of the gene coding for RNA polymerase subunits; the obtention of mutants affected at the level of factors, or RNA polymerases; the mechanism of template recognition by factors and RNA polymerase.

On the phosphorylation of yeast RNA polymerases A and B

In exponentially growing cells, RNA polymerase B is exclusively form BI enzyme with several phosphorylated subunits: B220, B23 and possibly B44.5. In RNA polymerase A an average of fifteen phosphate groups are distributed on the five phosphorylated subunits: A190 (6), A43 (4), A34.5 (2), A23 (1-2) and A19 (1-2). Phosphorylation of enzyme A by a yeast protein kinase in vitro adds less than 1 mol phosphate/mol enzyme but occurs essentially at the physiological sites, as shown by a comparison of the peptide patterns obtained by limited proteolysis of subunits 32P-labelled in vivo and in vitro. No evidence was found in favor of a modulation of RNA polymerase activity in vitro or in vivo via phosphorylation.