Principal sigma subunit of the Caulobacter crescentus RNA polymerase.

We have identified the gene encoding the Caulobacter crescentus principal sigma subunit, RpoD. The rpoD gene codes for a polypeptide of 653 amino acids with a predicted molecular mass of 72,623 Da (sigma 73). The C. crescentus sigma subunit has extensive amino acid sequence homology with the principal sigma factors of a number of divergent procaryotes. In particular, the segments designated region 2 that are involved in core polymerase binding and promoter recognition were identical among these bacteria despite the fact that the -10 region recognized by the C. crescentus sigma 73 differs significantly from that of the other bacteria. Thus, it appears that additional sigma factor regions must be involved in -10 region recognition. This conclusion was strengthened by a heterologous complementation assay in which C. crescentus sigma 73 was capable of complementing the Escherichia coli rpoD285 temperature-sensitive mutant. Furthermore, C. crescentus sigma 73 conferred new specificity on the E. coli RNA polymerase, allowing the expression of C. crescentus promoters in E. coli. Thus, the C. crescentus sigma 73 appears to have a broader specificity than does the sigma 70 of the enteric bacteria.     

Characterization of unstable poly (A)-RNA in Caulobacter crescentus

Antabuse (disulfiram) is widely used in the treatment of chronic alcoholism. We have examined the effect of this drug on malignant transformation by Rous sarcoma virus, on eukaryotic cell synthesis, and on nucleic acid binding. It was found that: (1) Disulfiram inhibits the activity of the RNA dependent DNA polymerase of Rous sarcoma virus and inactivates the ability of the virus to malignantly transform chick embryo cells. The monomer of disulfiram, diethyldithiocarbamate does not affect the virus. (2) Disulfiram induced the synthesis of four proteins in normal chick embryo and human foreskin cells. The monomer diethyldithiocarbamate, induced these proteins also. Cellular DNA synthesis is more sensitive to disulfiram than are RNA and protein synthesis. (3) Disulfiram binds to neither DNA or RNA in the presence or absence of copper. However, diethyldithiocarbamate in the presence of, but not in the absence of, copper binds to HeLa cell DNA and to Rous sarcoma virus 70 S genome RNA. These results indicate that this compound, which causes no symptoms in people who do not consume alcohol, may have significant effects on a cellular level.     

Characterization of unstable poly(A)-RNA in Caulobacter crescentus

A significant amount of poly(A)-RNA in Caulobacter crescentus is located on polysomes and the size distribution of this polysomal poly(A)-RNA is small compared to the total pulse-labeled RNA in these cells. These observations suggest that the poly(A)-RNA represents a subset of small messenger RNA molecules. Poly(A)-RNA, and presumably the poly(A) portion of these molecules, is extremely unstable: as assayed by binding to oligo(dT)-cellulose the poly(A)-RNA turns over with a chemical half-life of 15–20 s compared to a half-life of approx. 2 min for total cellular messenger RNA. The presence of adenosine in hydrolysates of poly(A) tracts showed that these sequences are located at the 3′-OH end of the RNA. The ratios of AMP/adenosine in the samples confirmed that the length of the A-tracts is approx. 13–17 nucleotides (Ohta, N., Sanders, M. and Newton, A. (1975) Proc. Natl. Acad. Sci. U.S.A. 72, 2343–2346).     

Association of poly(A) polymerase with U1 RNA

Previous studies (Stetler, D. A., and Jacob, S. T. (1984) J. Biol. Chem. 259, 7239-7244) have shown that poly(A) polymerase from adult rat liver (liver-type) is structurally and immunologically distinct from the corresponding rat hepatoma (tumor-type) enzyme. When hepatoma 7777 (McA-RH 7777) cells were labeled with [32P]inorganic phosphate, followed by immunoprecipitation with anti-hepatoma poly(A) polymerase antibodies and analysis of the RNAs in the immunoprecipitate, only one labeled small nuclear RNA corresponding to U1 RNA was found. Preimmune sera did not form a complex with U1 RNA. Hepatoma poly(A) polymerase antisera did not immunoprecipitate U1 RNA or any other small nuclear RNA from a cell line (H4-11-EC3) which does not contain the tumor-type poly(A) polymerase. Immunoblot analysis of hepatoma 7777 nuclear extract or purified poly(A) polymerase with anti-ribonucleoprotein antisera did not show any cross-reactivity of the latter sera with poly(A) polymerase. The major RNA immunoprecipitated from the hepatoma nuclear extracts using trimethyl cap (m3G) antisera corresponded to the RNA immunoprecipitated with poly(A) polymerase antisera. These data indicate that U1 RNA is closely associated with poly(A) polymerase and suggest the potential involvement of this RNA in the cleavage/polyadenylation of mRNA precursor.     

A study on the unprimed poly (dA-dT) synthesis catalyzed by preparations of E. coli DNA polymerase I.

Evidence was obtained indicating that the initiation of poly (dA-dT) de novo synthesis is provided by deoxynucleoside diphosphate: oligonucleotide deoxynucleotidyl transferase (dNDP-transferase present in preparations of E. coli DNA polymerase I and capable of catalyzing the unprimed polymerization of dNDP. dNDP-transferase synthesyzes short oligonucleotides which form template-primer complexes repeatedly replicated by DNA polymerase I. This conclusion was based on the following observations: the abolition of the lag period of poly (dA-dT) synthesis by preincubation of DNA-polymerase I preparations with dADP and dTDP; the presence of oligo (dA-dT) among the preincubation products; the suppressive effect of dithiothreitol and N-ethylmaleimide (inhibitors of dNDP-transferase) on the de novo, but not on the primed synthesis of poly (dA-dT), catalyzed by preparations of DNA-polymerase I.     

Nuclear penetration and stimulation of nucleic acids synthesis by poly(A)-poly(U) in mammalian cells

The rapid penetration of poly(A)-poly(U) into cell nuclei is shown by radioautography, by recovery of acid-precipitable material from isolated nuclei and by sucrose gradient centrifugation of nuclear lysates. The majority of poly(A)-poly(U) remains intact in the nuclei for at least h. This penetration is increased 20-fold by pretreatment of the cells with DEAE Dextran. In cells treated with DEAE Dextran, DNA and RNA syntheses are stimulated by poly(A)-poly(U) from the time the polymer complex is added and for at least h.     

A poly(U) polymerase in tobacco leaves.

A poly(U) polymerizing enzyme has been found in healthy and tobacco mosaic virus-infected tobacco leaves and has been partially purified by affinity chromatography on a gel prepared from agarose with chemically coupled RNA. The enzyme is stimulated by Mn-2+ and dependent on a polynucleotide, preferentially poly(A). The synthesis proceeds optimally at pH 7.6 and 25 degrees C. The enzyme is highly specific for UTP and is inhibited by other ribonucleoside triphosphates. The product was partly sensitive to pancreatic ribonuclease. The synthetic reaction is inhibited in the presence of pyrophosphate but insensitive to 10 mM orthophosphate and high levels of cordycepin, rifampicin and actinomycin D. A molecular weight of about 40,000 has been estimated by sucrose gradient analysis and partition cell ultracentrifugation.     

In vitro synthesis of uniform poly(dG)-poly(dC) by Klenow exo- fragment of polymerase I

In this paper, we describe a production procedure of the one-to-one double helical complex of poly(dG)–poly(dC), characterized by a well-defined length (up to 10 kb) and narrow size distribution of molecules. Direct evidence of strands slippage during poly(dG)–poly(dC) synthesis by Klenow exo⁻ fragment of polymerase I is obtained by fluorescence resonance energy transfer (FRET). We show that the polymer extension results in an increase in the separation distance between fluorescent dyes attached to 5′ ends of the strands in time and, as a result, losing communication between the dyes via FRET. Analysis of the products of the early steps of the synthesis by high-performance liquid chromatography and mass spectroscopy suggest that only one nucleotide is added to each of the strand composing poly(dG)–poly(dC) in the elementary step of the polymer extension. We show that proper pairing of a base at the 3′ end of the primer strand with a base in sequence of the template strand is required for initiation of the synthesis. If the 3′ end nucleotide in either poly(dG) or poly(dC) strand is substituted for A, the polymer does not grow. Introduction of the T-nucleotide into the complementary strand to permit pairing with A-nucleotide results in the restoration of the synthesis. The data reported here correspond with a slippage model of replication, which includes the formation of loops on the 3′ ends of both strands composing poly(dG)–poly(dC) and their migration over long-molecular distances (μm) to 5′ ends of the strands.     

Template-independent poly(A) x poly(U) synthesizing activity of different forms of Bacillus subtilis RNA polymerase

The steady-state kinetic parameters of the tripeptides D-Val-Leu-Lys-, Ala-Phe-Lys-, and < Glu-Phe-Lys- in which the free carboxyl group was substituted with p-nitroaniline (substrate) or chloromethane (inhibitor), towards the serine proteinases plasmin (EC 3.4.21.7), thrombin (EC 3.4.21.5), urokinase, factor Xa, and trypsin (EC 3.4.21.4) were investigated. The p-nitroanilide derives were found to be very good substrates for plasmin, 2.5--40-times less efficient towards trypsin and very poor (100--10 000-times less efficient) substrates for thrombin, factor Xa and urokinase. The chloromethyl ketone derivatives were comparably efficient inhibitors of plasmin and trypsin and in general very poor (100--10 000-times weaker) inhibitors of thrombin, factor Xa and urokinase. D-Val-Leu-Lys-pNA however was a very poor substrate but D-Val-Leu-Lys-CH2Cl a very efficient inhibitor for thrombin. The variability in susceptibility of the substrates towards the enzymes was due to differences in their Michaelis constant, in their deacylation rate constant or both. the variable efficiency of the inhibitors was mostly due to differences in their dissociation constant and much less to differences in their alkylation rate constant. Only a poor correlation (r = 0.25) was found between the efficiency of the p-nitroanilides as substrate and their homologous chloromethyl ketones as inhibitor. The most notable discrepancy was observed with the D-Val-Leu-Lys derivatives towards thrombin.     

Functional role of zinc in poly(A) synthesis catalyzed by nuclear poly(A) polymerase.

Three methods, chromatographic, spectrophotometric and tritium-release assay, were used and compared for the assay of deoxycytidylate methyltransferase. All three methods can be used for assay of this enzyme but the tritium-release assay appears to be the most simple and convenient. With the help of this assay the deoxycytidylate methyltransferase has been isolated and purified from sonically disrupted cells of Xp12-infected Xanthomonas oryzae. Using a procedure that involves fractionation with streptomycin sulfate and ammonium sulfate, filtration through Sephadex G-100 and chromatography on DEAE-cellulose, a 214-fold increase in specific activity was obtained. The enzyme displays a narrow pH optimum at 6.0 Among the buffers tested, 6-morpholinoethane sulfonate with the addition of Mg2 is the best. The enzyme can utilize dCMP as a substrate. The enzyme can also convert tetrahydrofolic acid into dihydrofolic acid. The Km value for dCMP is 31.3 micrometer and the Km value for tetrahydrofolic acid is 71.4 micrometer. There is no absolute requirement of ions for the activity of the enzyme; however, the presence of ions causes stimulating or inhibiting effects on enzyme activity that are dependent on the variety and concentration of ions used.     

Heat shock protein synthesis during development in Caulobacter crescentus.

Caulobacter crescentus cells respond to a sudden increase in temperature by transiently inducing the synthesis of several polypeptides. Two of the proteins induced, Hsp62 and Hsp70, were shown to be analogous to the heat shock proteins of Escherichia coli, GroEL and DnaK, respectively, by immunological cross-reactivity with antibodies raised against the E. coli proteins. Two-dimensional gel electrophoretic resolution of extracts of cells labeled with [35S]methionine during heat shock led to the identification of 20 distinct Hsps in C. crescentus which are coordinately expressed, in response to heat, at the various stages of the cell division cycle. Thus, a developmental control does not seem to be superimposed on the transient activation of the heat shock genes. Nonetheless, under normal temperature conditions, four Hsps (Hsp70, Hsp62, Hsp24b, and Hsp23a) were shown to be synthesized, and their synthesis was cell cycle regulated.     

Metabolism of aromatic compounds by Caulobacter crescentus.

Cultures of Caulobacter crescentus were found to grow on a variety of aromatic compounds. Degradation of benzoate, p-hydroxybenzoate, and phenol was found to occur via beta-ketoadipate. The induction of degradative enzymes such as benzoate 1,2-dioxygenase, the ring cleavage enzyme catechol 1,2-dioxygenase, and cis, cis-muconate lactonizing enzyme appeared similar to the control mechanism present in Pseudomonas spp. Both benzoate 1,2-dioxygenase and catechol 1,2-dioxygenase had stringent specificities, as revealed by their action toward substituted benzoates and substituted catechols, respectively.     

Utilization of histidine by Caulobacter crescentus

Caulobacter crescentus has an inducible pathway which is responsible for the degradation of histidine. Induction of this pathway occurs in the presence of both glucose and ammonia. Growth yield experiments indicate that only two of the three available nitrogens are used for growth suggesting that formamide may be produced as a waste product. However, formamide was not detected in the culture fluid and formate was formed instead. These results suggest that histidine may be degraded in a novel pathway which results in the production of 1 mol each of ammonia, glutamate and formate per mol of histidine. The third nitrogen from histidine appears to be sequestered in some kind of secondary metabolite.     

Antisera to poly(A)-poly(U)-poly(I) contain antibody subpopulations specific for different aspects of the triple helix.

Rabbit antibodies to the triple-helical polynucleotide poly(A)-poly(U)-poly(I) were fractionated into three major antibody populations, each recognizing a different conformational feature of the triple-helical immunogen. Two distinct populations were purified from precipitates made with poly(A)-poly(U)-poly(U) and poly(A)-poly(I)-poly(I). The former reacted with double-stranded poly(A)-poly(U) or poly(I)-poly(C), and similar populations could be purified with either double-stranded form. The second population recognized the poly(A)-poly(I) region of the triple helix, and the third required all three strands for reactivity. These immunochemical studies suggest that the poly(A) and poly(U) have the same orientation in the triple-helicical poly(A)-poly(U)-poly(I) as in the double-helical poly(A)-poly(U), in which they have Watson-Crick base pairing.     

Stalkless mutants of Caulobacter crescentus.

A stalk, a single falgellum, several pili, and deoxyribonucleic acid (DNA) phage receptors are polar surface structures expressed at a defined time in the Caulobacter crescentus cell cycle. When mutants were isolated as DNA phage phiCbK-resistant or ribonucleic acid (RNA) phage phiCp2-resistant, as well as nonmotile, strains, 5 out of 30 such mutant isolates were found not to possess stalks, but did possess inactive flagella. These stalkless mutants were resistant simultaneously to both DNA and RNA phages and did not possess pili and DNA pendent stalkless mutants. All motile revertants simultaneously regained the capacity to form stalks and susceptibility to DNA and RNA phages. It is suggested that a single mutation pleiotropically affects stalk formation, flagella motility, and coordinate polar morphogenesis of pili and DNA phage receptors. The stalkless mutants grew at a generation time similar to that of the wild-type strain at 30 degrees C. Cell size and morphology of a stalkless mutant, C. crescentus CB13 pdr-819, were also similar to those of the wild-type strain, except for the absence of a stalk. In addition, the CB13 pdr-819 predivisional cells were partitioned into smaller and larger portions, indicating asymmetrical cell division, as in the wild-type strain. From these results, it is suggested that swarmer cells undergo transition to cells of a stalked-cell nature without stalk formation and that the cell cycle of the stalkless mutant proceeds in an ordered sequence similar to that defining the wild-type cell cycle.     

Dinucleoside polyphosphates stimulate the primer independent synthesis of poly(A) catalyzed by yeast poly(A) polymerase.

Novel properties of the primer independent synthesis of poly(A), catalyzed by the yeast poly(A) polymerase are presented. The commercial enzyme from yeast, in contrast to the enzyme from Escherichia coli, is unable to adenylate the 3'-OH end of nucleosides, nucleotides or dinucleoside polyphosphates (NpnN). In the presence of 0.05 mm ATP, dinucleotides (at 0.01 mm) activated the enzyme velocity in the following decreasing order: Gp4G, 100; Gp3G, 82; Ap6A, 61; Gp2G, 52; Ap4A, 51; Ap2A, 41; Gp5G, 36; Ap5A, 27; Ap3A, 20, where 100 represents a 10-fold activation in relation to a control without effector. The velocity of the enzyme towards its substrate ATP displayed sigmoidal kinetics with a Hill coefficient (nH) of 1.6 and a Km(S0.5) value of 0.308 +/- 0.120 mm. Dinucleoside polyphosphates did not affect the maximum velocity (Vmax) of the reaction, but did alter its nH and Km(S0.5) values. In the presence of 0.01 mm Gp4G or Ap4A the nH and Km(S0.5) values were (1.0 and 0.063 +/- 0.012 mm) and (0.8 and 0.170 +/- 0.025 mm), respectively. With these kinetic properties, a dinucleoside polyphosphate concentration as low as 1 micro m may have a noticeable activating effect on the synthesis of poly(A) by the enzyme. These findings together with previous publications from this laboratory point to a potential relationship between dinucleoside polyphosphates and enzymes catalyzing the synthesis and/or modification of DNA or RNA.