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.     

Subunits of RNA polymerase in function and structure. IV. Enhancing role of sigma in the subunit assembly of Escherichia coli RNA polymerase

The in vitro reconstitution of DNA-dependent RNA polymerase of Escherichia coli is markedly enhanced by the σ subunit. This conclusion is based on the following observations: (1) the core activity was higher for the enzyme reconstituted from mixtures of α, β,β′ and σ subunits than from those devoid of the σ subunit; (2) the reconstituted enzyme lacking the σ subunit could never regain full activity even when the σ subunit was supplied before assay and (3) the recovery of enzyme activity increased in proportion to the amount of σ subunit present during reconstitution.This influence of the σ subunit was also observed when reconstitution was carried out by mixing the α₂β complex and the β′ subunit, the second step in the sequence of enzyme formation. The σ subunit-dependent assembly between the α₂β complex and the β′ subunit required an ionic strength of around 0.2 m-KC1 and was enhanced by higher temperatures. In contrast, formation of the α₂β complex, which exhibited no requirement for the σ subunit, was unaffected by the salt concentration used or the temperature of reaction. The enhancement was observed not only at neutral but also at alkaline pH. The native enzyme per se was greatly activated after brief exposure to alkali.     

Subunits of RNA polymerase in function and structure: VI. Sequence of the assembly in vitro of Escherichia coli RNA polymerase

Detailed analysis of the assembly in vitro of Escherichia coli RNA polymerase reveals that core enzyme subunits are assembled in the following sequence: $\text{2 α → α}{}_2\text{→}\text{β}\text{α}{}_2\text{β}\text{→}\text{β′}\text{α}{}_2\text{ββ′}$(premature core) → E (active core). Activation of the premature core enzyme, the rate-limiting step in this sequence, can be achieved in three different ways: self-reactivation, sigma subunit (σ or σ′)-promoted reactivation, and DNA-promoted reactivation.Although there has been disagreement on the enhancement of core enzyme maturation by sigma subunit or DNA, the discrepancy is resolved by the present finding that the premature core alone can be activated in the presence of high concentrations of salt or glycerol, whereas at a salt concentration as low as that in vivo, sigma subunit or DNA is required for maximum activation. However, the question remains unsolved as to which of the three ways operates in the in vivo process of RNA polymerase formation.     

Subunits of RNA polymerase in function and structure. 3. Accumulation of the intermediate alpha 2beta in the subunit assembly of Escherichia coli RNA polymerase by treatment with cyanate

The reactivation of DNA-dependent RNA polymerase, dissociated with 6 M-urea, was markedly reduced when aged solutions of urea were used without deionization. Cyanate, which is in equilibrium with urea in aged solutions, had similar effects on the reversible dissociation of the RNA polymerase suggesting that the inhibitor in aged urea solutions might be cyanate. The presence of dithiothreitol and MgCl₂ in the dissociation buffer prevented this inhibition and, moreover, these agents could activate inactive subunits. Thus, it is suggested that the inhibition might be due to carbamylation of cysteine residues of the subunits of the polymerase.Upon exposure to cyanate, the β′ subunit was preferentially inactivated; as a result, the α₂β complex, an intermediate in the sequence of the in vitro assembly of the RNA polymerase, accumulated when reconstitution was carried out with cyanate-treated subunits. This finding further strengthened the proposal that the subunits of this multimeric enzyme assemble in the following sequence: 2α + β + β′ → α₂β + β′ → α₂ββ′.     

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.     

Sulfhydryl group reactivity in the Escherichia coli CoA transferase.

The acetyl-CoA:acetoacetate CoA-transferase of Escherichia coli has the subunit structure α₂β₂ The enzyme contains six sulfhydryl groups, one per α chain and two per β chain, and no disulfides. The rates and extent of sulfhydryl group reactivity with 5,5′-dithiobis(2-nitrobenzoic acid) were compared in the free enzyme, the enzyme-CoA intermediate in the catalytic pathway, and a substrate analog-enzyme Michaelis complex. The analog used was acetylaminodesthio-CoA, a competitive inhibitor with respect to acetyl-CoA; the analog is not a substrate. The reactions were studied in the presence and absence of 10% glycerol. In the absence of glycerol, one sulfhydryl group reacted rapidly in the free enzyme and enzyme-CoA intermediate; relative to the free enzyme, the rate and number of subsequently reacting sulfhydryl groups were increased in the enzyme-CoA intermediate. In the presence of 10% glycerol, one sulfhydryl group reacted rapidly in the free enzyme, while two reacted rapidly in the enzyme-CoA compound; the rates and extents of subsequently reacting sulfhydryl groups were also enhanced in the enzyme-CoA compound. The data strongly suggested subunit interactions in the free enzyme and intermediate; glycerol abolished those interactions in the enzyme-CoA intermediate. In the absence of glycerol, sulfhydryl group reactivity in the Michaelis complex, enzyme-acetylaminodesthio-CoA, was similar to that in the free enzyme with one exception: One of the more slowly reacting sulfhydryl groups in the free enzyme reacted at a rate characteristic of the enzyme-CoA intermediate. The results obtained with N-ethylmaleimide were qualitatively similar. The fractional inactivation of the enzyme with N-ethylmaleimide as a function of sulfhydryl groups modified and the subunit location of those sulfhydryl groups indicated that the same sulfhydryl groups react in both enzyme species; however, those sulfhydryl groups reacted more rapidly in the enzyme-CoA compound. The data indicate both subunit interactions in the enzyme and characteristic conformational changes upon formation of an acyl-CoA-enzyme Michaelis complex and the enzyme-CoA intermediate.     

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.     

Coexpression and characterization of the human large-conductance Ca2+-activated K+ channel α + β1 subunits in HEK293 cells

Large-conductance Ca²⁺-activated K⁺ channel is formed by a tetramer of the pore-forming α-subunit and distinct accessory β-subunits (β1–β4) which contribute to BK_Ca channel molecular diversity. Accumulative evidences indicate that not only α-subunit alone but also the α + β subunit complex and/or β-subunit might play an important role in modulating various physiological functions in most mammalian cells. To evaluate the detailed pharmacological and biophysical properties of α + β1 subunit complex or β1-subunit in BK_Ca channel, we established an expression system that reliably coexpress hSloα + β1 subunit complex in HEK293 cells. The coexpression of hSloα + β1 subunit complex was evaluated by western blotting and immunolocalization, and then the single-channel kinetics and pharmacological properties of expressed hSloα + β1 subunit complex were investigated by cell-attached and outside-out patches, respectively. The results in this study showed that the expressed hSloα + β1 subunit complex demonstrated to be fully functional for its typical single-channel traces, Ca²⁺-sensitivity, voltage-dependency, high conductance (151 ± 7 pS), and its pharmacological activation and inhibition.     

Revealing secrets of the enigmatic omega subunit of bacterial RNA polymerase

The conserved omega (ω) subunit of RNA polymerase (RNAP) is the only nonessential subunit of bacterial RNAP core. The small ω subunit (7 kDa–11.5 kDa) contains three conserved α helices, and helices α2 and α3 contain five fully conserved amino acids of ω. Four conserved amino acids stabilize the correct folding of the ω subunit and one is located in the vicinity of the β′ subunit of RNAP. Otherwise ω shows high variation between bacterial taxa, and although the main interaction partner of ω is always β′, many interactions are taxon‐specific. ω‐less strains show pleiotropic phenotypes, and based on in vivo and in vitro results, a few roles for the ω subunits have been described. Interactions of the ω subunit with the β′ subunit are important for the RNAP core assembly and integrity. In addition, the ω subunit plays a role in promoter selection, as ω‐less RNAP cores recruit fewer primary σ factors and more alternative σ factors than intact RNAP cores in many species. Furthermore, the promoter selection of an ω‐less RNAP holoenzyme bearing the primary σ factor seems to differ from that of an intact RNAP holoenzyme.     

Crystallization,molecular replacement solution,and refinement of tetrameric β-amylase from sweet potato

Sweet potato β-amylase is a tetramer of identical subunits, which are arranged to exhibit 222 molecular symmetry. Its subunit consists of 498 amino acid residues (Mr 55,880). It has been crystallized at room temperature using polyethylene glycol 1500 as precipitant. The crystals, growing to dimensions of 0.4 mm × 0.4 mm × 1.0 mm within 2 weeks, belong to the tetragonal space group P4₂2₁2 with unit cell dimensions of a = b = 129.63 Å and c = 68.42 Å. The asymmetric unit contains 1 subunit of β-amylase, with a crystal volume per protein mass (V_M) of 2.57 ų/Da and a solvent content of 52% by volume. The three-dimensional structure of the tetrameric β-amylase from sweet potato has been determined by molecular replacement methods using the monomeric structure of soybean enzyme as the starting model. The refined subunit model contains 3,863 nonhydrogen protein atoms (488 amino acid residues) and 319 water oxygen atoms. The current R-value is 20.3% for data in the resolution range of 8–2.3 Å (with 2 σ cut-off) with good stereochemistry. The subunit structure of sweet potato β-amylase (crystallized in the absence of α-cyclodextrin) is very similar to that of soybean β-amylase (complexed with α-cyclodextrin). The root-mean-square (RMS) difference for 487 equivalent Cα atoms of the two β-amylases is 0.96 Å. Each subunit of sweet potato β-amylase is composed of a large (α/β)₈ core domain, a small one made up of three long loops [L3 (residues 91–150), LA (residues 183–258), and L5 (residues 300–327)], and a long C-terminal loop formed by residues 445–493. Conserved Glu 187, believed to play an important role in catalysis, is located at the cleft between the (α/β)₈ barrel core and a small domain made up of three long loops (L3, L4, and L5). Conserved Cys 96, important in the inactivation of enzyme activity by sulfhydryl reagents, is located at the entrance of the (α/β)₈ barrel. © 1995 Wiley-Liss, Inc.