Synthesis of RNA polymerase in Escherichia coli B-r growing at different rates

Polyacrylamide gel electrophoresis of unfractionated sodium dodecyl sulfate lysates of Escherichia coli$\text{B}\text{r}$ has been used to investigate the synthesis of β and β′ subunits of RNA polymerase as a function of bacterial growth rate. In succinate (μ = 0.67 doublings/h), glucose (μ = 1.36 doublings/h) and glucose/amino acids (μ = 2.10 doublings/h) supplemented media, the fraction of [¹⁴C]leucine-labeled β and β′ protein/total protein was found to be 1.05, 1.31 and 1.56%, respectively. Comparison of these values with recent estimates from this laboratory of the differential rate of synthesis of functioning RNA polymerase suggests an excess of total over functioning RNA polymerase. The significance of these data in reference to the regulation of RNA polymerase synthesis is discussed.     

The relationships among RNA synthesis,RNA polymerase synthesis and guanosine tetraphosphate levels in Escherichia coli during nutritional shift-up

The relationships among the rate of RNA synthesis, RNA polymerase synthesis and activity, and guanosine tetraphosphate levels were investigated following nutritional shift-up in Escherichia coli. RNA synthesis continues at the preshift rate for 1.5 min after which an increase is observed that reaches a new steady-state rate at between 2 and 2.5 min. RNA polymerase activity measured in crude extracts increases immediately and by 10 min has increased 50%. RNA polymerase synthesis as measured by the synthesis of the β and β′ subunits lags for 2.5 min and then increases 75% by 10 min. Guanosine tetraphosphate levels decrease 50% by 3 min to levels characteristic of steady-state post-shift-up cells. The significance of these data to the regulation of RNA synthesis during shift-up is discussed.     

Limited digestion of RNA polymerase from Escherichia coli by trypsin (effect of rifamycin and DNA on the integrity of sigma subunit)

A modified polyacrylamide gel electrophoresis technique is used to separate the polypeptides after digestion of $\text{E. coli}$ RNA polymerase with various concentration of trypsin. The subunits β and β′ and two large breakdown products of molecular weight of 147,000 and 141,000 are distinctly separated. At a very low level of trypsin σ and α are not cleaved while two major breakdown products of molecular weights of 110,000 and 43,000 appear from the larger subunits. At a still higher level of trypsin σ is converted to a polypeptide of molecular weight of 86,000 and other small fragments. DNA protects, to some extent, the σ and this polypeptide and also β and the two large breakdown products from trypsin digestion. It is also observed that rifamycin, an inhibitor of RNA synthesis, enhances the tryptic digestion of σ, only in the absence of MgCl₂.     

Localization of the structural gene for the ' subunit of RNA polymerase in Escherichia coli

A minicell-producing strain of $\text{E.}$$\text{coli}$ carrying an F′ factor, KLF10-1, forms minicells that contain plasmid but not chromosomal DNA. These minicells were found to synthesize two polypeptides corresponding precisely to the β and β′ subunits of RNA polymerase in SDS-polyacrylamide gel electrophoresis. In contrast, minicells obtained from an isogenic strain carrying F13-1 do not synthesize these proteins under similar conditions. These results indicate that the structural genes for the β′ as well as β subunits of the polymerase are located on the chromosomal segment (78 to 81 min on the standard genetic map of $\text{E.}$$\text{coli}$) carried by KLF10-1.     

Biosynthesis of the beta and beta' subunits of RNA polymerase in Escherichia coli

The amounts of the β and β′ subunits of the DNA-dependent RNA polymerase relative to the amount of total protein synthesized have been determined under a number of growth conditions in two strains of Escherichia coli. The results of these measurements have been expressed as the relative rate of synthesis of core RNA polymerase, α_p, assuming the four constituent subunits (2α, 1β and 1β′) to be synthesized in equivalent amounts.This quantity, α_p, was found not to vary greatly with the growth rate μ. For glucose-grown cells of E. coli B/r (μ = 1.5 doublings/h) α_p = 1.4%, corresponding to about 7000 molecules of core RNA polymerase per cell. For slowgrowing cells the value obtained for α_p is lower and for fast-growing cells somewhat 3 higher. The comparison of these values with the number of RNA polymerase molecules estimated to be actively engaged in RNA synthesis indicates that both slow- and fast-growing cells contain a surplus of RNA polymerase, if the catalytic unit is assumed to be the monomer of core RNA polymerase.In addition to the measurements of cells during balanced growth at various rates, α_p has been determined during the transition from one growth rate to another and during synchronous growth. During a shift-up the rate of synthesis of polymerase follows closely the rate of total protein synthesis, α_p being nearly constant for a period of twenty minutes after the shift. In a synchronously dividing culture of E. coli B/r, α_p was seen to be fairly constant during two cycles of synchronous division. It appears that α_p is rather insensitive to the effect of gene doubling during the cell cycle.     

Molecular cloning and characterization of the cDNA encoding the largest subunit of mouse RNA polymerase I

We describe the cloning and analysis of mRPA1, the cDNA encoding the largest subunit (RPA194) of murine RNA polymerase I. The coding region comprises an open reading frame of 5151?bp that encodes a polypeptide of 1717 amino acids with a calculated molecular mass of 194?kDa. Alignment of the deduced protein sequence reveals homology to the β′ subunit of Escherichia coli RNA polymerase in the conserved regions a-h present in all large subunits of RNA polymerases. However, the overall sequence homology among the conserved regions of RPA1 from different species is significantly lower than that observed in the corresponding β′-like subunits of class II and III RNA polymerase. We have raised two types of antibodies which are directed against the conserved regions c and f of RPA194. Both antibodies are monospecific for RPA194 and do not cross-react with subunits of RNA polymerase II or III. Moreover, these antibodies immunoprecipitate RNA polymerase I both from murine and human cell extracts and, therefore, represent an invaluable tool for the identification of RNA polymerase I-associated proteins.     

Chromatographic resolution of the subunits of calf brain tubulin

Two procedures are described for column chromatographic separation of the α and β subunits of brain tubulin using hydroxylapatite in the presence of (i) urea or (ii) sodium dodecyl sulfate and β-mercaptoethanol. In the first system the α and β chains are partially resolved, and in the second the subunits are resolved into three peaks which we designate α₁, α₂, and β.     

Isolation and characterization of temperature-sensitive mutations in the gene (rpb3 ) for subunit 3 of RNA polymerase II in the fission yeast Schizosaccharomyces pombe

Subunit 3 (Rpb3) of eukaryotic RNA polymerase II is a homologue of the α subunit of prokaryotic RNA polymerase, which plays a key role in subunit assembly of this complex enzyme by providing the contact surfaces for both β and β′ subunits. Previously we demonstrated that the Schizosaccharomyces pombe Rpb3 protein forms a core subassembly together with Rpb2 (the β homologue) and Rpb11 (the second α homologue) subunits, as in the case of the prokaryotic α₂β complex. In order to obtain further insight into the physiological role(s) of Rpb3, we subjected the S. pombe rpb3 gene to mutagenesis. A total of nine temperature-sensitive (Ts) and three cold-sensitive (Cs) S. pombe mutants have been isolated, each (with the exception of one double mutant) carrying a single mutation in the rpb3 gene in one of the four regions (A–D) that are conserved between the homologues of eukaryotic subunit 3. The three Cs mutations were all located in region A, in agreement with the central role of the corresponding region in the assembly of prokaryotic RNA polymerase; the Ts mutations, in contrast, were found in all four regions. Growth of the Ts mutants was reduced to various extents at non-permissive temperatures. Since the metabolic stability of most Ts mutant Rpb3 proteins was markedly reduced at non-permissive temperature, we predict that these mutant Rpb3 proteins are defective in polymerase assembly or the mutant RNA polymerases containing mutant Rpb3 subunits are unstable. In accordance with this prediction, the Ts phenotype of all the mutants was suppressed to varying extents by over-expression of Rpb11, the pairing partner of Rpb3 in the core subassembly. We conclude that the majority of rpb3 mutations affect the assembly of Rpb3, even though their effects on subunit assembly vary depending on the location of the mutation considered.     

Phosphorylation of Escherichia coli RNA polymerase by rabbit skeletal muscle protein kinase

Rabbit skeletal muscle protein kinase catalyzes the phosphorylation of DNA-dependent RNA polymerase of Escherichia coli in the presence of adenosine 3′,5′-monophosphate and ATP. The phosphorylation occurs on one (or more) serine residue(s) in the σ-factor under reaction conditions similar to those employed for RNA synthesis. The phosphorylation of RNA polymerase and its stimulation by protein kinase are inhibited by a specific heat-stable inhibitor from rabbit skeletal muscle. With conditions more favorable for the protein kinase reaction, phosphorylation of RNA polymerase also occurs on the β subunit of the core enzyme, but this reaction occurs at a much slower rate than the phosphorylation of the σ-factor.     

A Gene Located at 56F1-2 inDrosophila melanogasterEncodes a Novel Metazoan β-like Subunit of Casein Kinase II

Drosophila melanogastercasein kinase II (DmCKII) is composed of catalytic α and regulatory β subunits associated as an α₂β₂heterotetramer. Using the two-hybrid system, we have screened aDrosophilaembryo cDNA library for proteins that interact with DmCKII α. One of the cDNAs encodes a novel β-like polypeptide, which we designate β′.In situhybridization localizes the corresponding gene to 56F1-2, a site distinct from that of both the β gene and theStellatefamily of β-like sequences. The predicted sequence of β′ is more closely related to the β subunit ofDrosophilaand other metazoans than to the Stellate family of proteins, suggesting that it is a second regulatory subunit.In vitroreconstitution studies show that a GST-β′ fusion protein associates with the α subunit to generate a tetrameric complex with regulatory properties similar to those of the native α₂β₂holoenzyme. The data are consistent with the proposed role of the β′ subunit as an integral component of the holoenzyme.     

Structural and molecular characterization of the prefoldin beta subunit from Thermococcus strain KS-1

Prefoldin (PFD) is a heterohexameric molecular chaperone that is found in eukaryotic cytosol and archaea. PFD is composed of α and β subunits and forms a “jellyfish-like” structure. PFD binds and stabilizes nascent polypeptide chains and transfers them to group II chaperonins for completion of their folding. Recently, the whole genome of Thermococcus kodakaraensis KOD1 was reported and shown to contain the genes of two α and two β subunits of PFD. The genome of Thermococcus strain KS-1 also possesses two sets of α (α1 and α2) and β subunits (β1 and β2) of PFD (TsPFD). However, the functions and roles of each of these PFD subunits have not been investigated in detail. Here, we report the crystal structure of the TsPFD β1 subunit at 1.9 Å resolution and its functional analysis. TsPFD β1 subunits form a tetramer with four coiled-coil tentacles resembling the jellyfish-like structure of heterohexameric PFD. The β hairpin linkers of β1 subunits assemble to form a β barrel “body” around a central fourfold axis. Size-exclusion chromatography and multi-angle light-scattering analyses show that the β1 subunits form a tetramer at pH 8.0 and a dimer of tetramers at pH 6.8. The tetrameric β1 subunits can protect against aggregation of relatively small proteins, insulin or lysozyme. The structural and biochemical analyses imply that PFD β1 subunits act as molecular chaperones in living cells of some archaea.     

Biosynthesis of RNA polymerase in Escherichia coli VI. Distribution of RNA polymerase subunits between nucleoid and cytoplasm.

The distribution of DNA-dependent RNA polymerase in Escherichia coli was analysed by measuring enzyme subunits in nucleoid (folded chromosome) and cytoplasm. Two independent methods, two-dimensional polyacrylamide gel electrophoresis of total proteins and sodium dodecyl sulphate/polyacrylamide gel electrophoresis of antibody precipitates, gave essentially the same results; with wild-type cells growing at a doubling time of 70 minutes, about two-thirds of the core enzyme but little σ subunit are present in the nucleoid. Pulse-chase experiments indicated that the distribution of the pulse-labelled proteins was at equilibrium within 1·5 minutes for β′, 5 minutes for β, and 15 minutes for α subunit. This order of appearance of the newly synthesized core subunits into the nueleoid is in good agreement with that into complete enzyme structure. This finding, together with the known sequence of subunit assembly (2α → α₂ → α₂β → α₂ββ′ → E), indicates that the assembly of RNA polymerase takes place in the cytoplasm. In concert with the conclusion, the amounts of pulse-labelled subunits in the cytoplasm of temperature-sensitive assembly defective mutants coincide well with those of intermediate subassemblies accumulated in the mutant cells. However, it is not known if the premature core is activated in cytoplasm prior to binding to the nucleoid or shortly after association with the nucleoid.     

Regulation of Rous sarcoma virus RNA-dependent DNA polymerase isoenzymes by in vitro phosphorylation-dephosphorylation

The activity of the αβ form of Rous sarcoma virus RNA-dependent DNA polymerase was stimulated upon treatment with the protein kinase purified from the same virus. This enhancement was observed for both DNA-dependent and RNA-dependent DNA polymerase activities, whereas the RNase H activity associated with the polymerase was not affected. On the other hand, the protein kinase did not induce detectable changes in the activities of the α-polymerase isoenzyme. Treatment with Escherichia coli alkaline phosphatase resulted in a reduction of the polymerase activities of the αβ isoenzyme with no effects on RNase H as well as on the α form of the DNA polymerase. Preincubations of the αβ- and α-oncornaviral polymerase isoenzymes with two other protein kinases—from avian myeloblastosis virus and from beef heart (catalytic subunit)—had no substantial effects on DNA polymerase and RNase H activities of both polymerase isoenzymes. Both α and β subunits of the polymerase isoenzymes were phosphorylated in vitro by all three protein kinases employed, although only the β subunit was shown previously to be phosphorylated in vivo.