Characterization of dnaA gene carried by lambda transducing phage

Summary Specialized transducing phages dnaA were obtained by inducing lysogens in which tna was integrated at the tnaA region of the Escherichia coli chromosome; the tnA region is located in the vicinity of the dnaA gene. The dnaA ^- deletion derivatives of dnaA were isolated from the lysate of dnaA grown on bacteria carrying a transposon Tn3.The structures of various transducing phages thus obtained were determined by heteroduplex DNA mapping. From these results, the transducing fragment of 13.8-kb-long was divided into nine domains. Upon infection of UV-irradiated cells with the phage, production of polypeptides of 49 kD and 42 kD was specifically associated with infections by the dnaA and recF transducing phages. Polypeptides of 49 kD and 42 kD appeared to be coded for by dnaA and recF genes, respectively. The dnaA gene was assigned to the region of 2.8-kb-long which extends by 2.4 kb in the counterclockwise direction on the E. coli genetic map and 0.4 kb in the opposite direction, as measured from the nearest HindIII site close to the tnaA gene. The recF gene was also discovered to lie very close to dnaA in the order of tnaA-dnaA-recF.Merogenotes heterozygous for the dnaA gene were constructed by introducing F100-12 carrying dnaA into the recipients with different mutations at or near dnaA. For combinations, F(dnaA ⁺)/dnaA46 and F(dna ⁺)/dna-83, dnaA ⁺ was trans-dominant, whereas the dnaA ⁺ was recessive for F(dnaA ⁺)/dna-5. For F(dnaA ⁺)/dna-167, the result of the transdominance test was affected by the growth media employed; dnaA ⁺ was dominant on a -broth plate, and dna-167 was dominant on an M9-minimal plate. Thus, transdominance of dnaA ⁺ in heterozygotes is affected by difference in mutations and growth media.     

Variations in the rate of synthesis of beta and beta'' RNA polymerase polypeptides under the influence of certain factors.

Summary In merodiploid cells containing a double dose of structural genes of RNA polymerase subunits-rpoBand rpoC-the rate of and subunits synthesis is 2 times higher than in haploidcells. Missence mutation rpoC1 (tsX) alters polypeptide and inducesthe and subunits synthesis at increased rate, particularly at a nonpermissive temperature. When rpoBCoperon carrying mutation rpoC1 is duplicated no dosage effect is observed. In the rpoC ⁺/rpoC1 heterodiploid the rpoC1 mutation does not significantly accelerate RNA polymerase subunits synthesis i.e. is recessive with respect to rpoC ⁺ Rifampicin causes 6-fold stimulation of RNA polymerase subunits synthesis in a sensitive wild-type strain. The rpoC1 mutation itself accelerates the synthesis of these subunits 3-fold. In the presence of rifampicin the mutant strain produces 13–22-fold faster as compared to wild-type strain without the drug. Thus, the effects of rifampicin and the mutation are multiplied suggesting that these factors act independently. Similar data have also been obtained with rifampicin-treated cells of rpoB22 (ts22) amber-mutant.After UV-irradiation of cells and synthesis is depressed much stronger than the total protein synthesis. Infection with a transducing phage rif ^d-47 which carries rpoB gene provokes a higher rate of synthesis. When pre-irradiated cells (500 erg/mm²) are infected with this phage, the rate of synthesis grows 20-fold compared to irradiated, non-infected cells and 6.5-fold compared to intact cells.The data are discussed in terms of the possible regulatory mechanisms of RNA polymerase subunit synthesis.     

Conformation of the circular dumbbell d〈pCGC-TT-GCG-TT〉: Structure determination and molecular dynamics

Summary The circular DNA decamer 5-dpCGC-TT-GCG-TT-3 was studied in solution by means of NMR spectroscopy and molecular dynamics in H₂O. At a temperature of 269 K, a 50/50 mixture of two dumbbell structures (denoted L2L2 and L2L4) is present. The L2L2 form contains three Watson-Crick C-G base pairs and two two-residue loops in opposite parts of the molecule. On raising the temperature from 269 K to 314 K, the L2L4 conformer becomes increasingly dominant (95% at 314 K). This conformer has a partially disrupted G(anti)-C(syn) closing base pair in the 5-GTTC-3 loop with only one remaining (solvent-accessible) hydrogen bond between NH of the cytosine dC(1) and O6 of the guanine dG(8). The opposite 5-CTTG-3 loop remains stable. The two conformers occur in slow equilibrium (rate constant 2–20 s^–1). Structure determination of the L2L2 and L2L4 forms was performed with the aid of a full relaxation matrix approach (IRMA) in combination with restrained MD. Torsional information was obtained from coupling constants. Coupling constant analysis (³J_HH, ³J_HP, ³J_CP) gave detailed information about the local geometry around backbone torsion angles , , and , revealing a relatively high flexibility of the 5-GTTC-3 loop. The values of the coupling constants are virtually temperature-independent. Weakly constrained molecular dynamics in solvent was used to sample the conformational space of the dumbbell. The relaxation matrices from the MD simulation were averaged over r^–3 to predict dynamic NOE volumes. In order to account for the 1:1 conformational mixture of L2L2 and L2L4 present at 271 K, we also included S² factors and r^–6 averaging of the r^–3-averaged relaxation matrices. On matrix averaging, the agreement of NOE volumes with experiment improved significantly for protons located in the thermodynamically less stable 5-GTTC-3 loop. The difference in stability of the 5-CTTG-3 and 5-GTTC-3 loops is mainly caused by differences in the number of potential hydrogen bonds in the minor groove and differences in stacking overlap of the base pairs closing the minihairpin loops. The syn conformation for dC(1), favored at high temperature, is stabilized by solvation in the major groove. However, the conformational properties of the dC(1) base, as deduced from R-factor analysis and MD simulations, include a large flexibility about torsion angle .     

γδ T-cell receptor repertoire in human peripheral blood and thymus

T-cell clones expressing the T-cell receptor (Tcr) were generated from peripheral blood lymphocytes (PBLs) and from a thymus sample. In the panel of ten thymus-derived clones, four Tcr phenotypes [as defined by the reaction of monoclonal antibodies (mAbs) directed against known V and V regions] were identified. All the clones lacked expression of the V3 V region, while seven clones were V1+ . V1 was found in combination with V9 or with undefined VVregions. In addition, two other Tcr phenotypes were identified on these clones: V9⁺ V1^– V3^– and V9^– V1^– V3^– One of the clones expressed CD4 and another was CD8positive. The remaining clones were CD4^– CD8^–. In the panel of 76 PBL-derived, Tcr-bearing clones, five Tcr phenotypes could be identified. In contrast to the thymus-derived clones, 30% of the clones were V3⁺ whereas V1 was expressed by a minority of the clones only. One clone was CD4-positive and approximately 30% of the clones were CD8-positive. Four of the five mAb-defined Tcr phenotypes could be identified on both thymus and PBL-derived T-cell clones. However, biochemical analysis of the Tcrs demonstrates differences in the usage of Ct- and C2-encoded y chains by T cells derived from the thymus and PBLs. The results therefore indicate that, at the clonal level, similarities and differences exist between the Tcr repertoires expressed in the thymus and by PBLs. Furthermore, they indicate that combinatorial Tcr heterogeneity is larger than has so far been described. The receptor diversity, combined with the potential of Tcr+ cells to express CD4 or CD8, indicates that these cells are a heterogeneous population that might mediate a number of immune functions.     

Characterization of ribonucleic acid synthesis by nuclei isolated from Zea mays

Nuclei were isolated from the shoots of Zea mays and assayed for endogenous RNA polymerase activity in vitro. Maximum incorporation from radioactive precursors (70 pmol [³H]uridine 5 monophosphate/100 g DNA) was reached after incubation for 1 h at 25°C. The RNA product, analysed by polyacrylamide gel electrophoresis, was polydisperse in size with an upper limit of 2x10⁶ daltons. Discrete peaks of rRNA were not detected, probably because of endogenous ribonuclease activity. The inclusion of -amanitin (4 g/ml) in the incubation reduced the total incorporation by approximately 40% but did not significantly alter the size of the RNA product. Although 40% of the total activity could be attributed to RNA polymerase II, [³H]RNA synthesised in vitro was found not to contain long sequences of poly (A).Abbreviations oligo (dT) oligo (deoxythymidylic acid) - poly (A) poly (adenylic acid) - GTP guanosine 5 triphosphate - ATP adenosine 5 triphosphate - CTP cytidine 5 triphosphate - UTP utidine 5 triphosphate - UMP uridine 5 monophosphate - PPO 2,5-diphenyloxazole - POPOP 1,4-di-2-(5-phenyloxazolyl) benzene     

Feedback regulation of RNA polymerase subunit synthesis after the conditional overproduction of RNA polymerase in Escherichia coli

Summary The and subunit of RNA polymerase are thought to be controlled by a translational feedback mechanism regulated by the concentration of RNA polymerase holoenzyme. To study this regulation in vivo, an inducible RNA polymerase overproduction system was developed. This system utilizes plasmids from two incompatibility groups that carry RNA polymerase subunit genes under lac promoter/operator control. When the structural genes encoding the components of core RNA polymerase (, and ) or holoenzyme (, , and ⁷⁰) are present on the plasmids, induction of the lac promoter results in a two fold increase in the concentration of functional RNA polymerase. The induction of RNA polymerase overproduction is characterized by an initial large burst of synthesis followed by a gradual decrease as the concentration of RNA polymerase increases. Overproduction of RNA polymerase in a strain carrying an electrophoretic mobility mutation in the rpoB gene results in the specific repression of synthesis off the chromosome. These results indicate that RNA polymerase feedback regulation controls synthesis in vivo.     

Rifampicin-induced protein synthesis: A pre-requisite for increased expression of the ββ′ operon in Escherichia coli

Summary In a rif ^S/rif^R heterodiploid strain of E. coli, a 4 minute pulse of rifampicin can induce a prolonged (>60 min) increase in the rate of synthesis of the RNA polymerase subunits, and . The application of a constraint on the fidelity of protein synthesis during, but not after, the rifampicin pulse partially arrests the development of this capacity for subunit synthesis. I discuss the implications of these findings in relation to the control of the operon in E. coli.     

The Polymer Basis of Kinetics and Equilibria of Enzymes: The Accessible-Volume Origin of Entropy Changes in a Class Aβ-Lactamase

The occurrence of enzymatic catalysis, as for any chemical reaction, depends critically upon close contact of the reactants, since making/breaking of bonds occurs over distances of about 0.2 Å. Unlike small molecules, each enzyme molecule acts as an ordered solvent and reactant. Each group important to the enzyme reaction interacts with the substrate, then moves away, and subsequently binds another substrate. In other words, the group undergoes round trips in structure. For a round trip, the thermochemical state functions G, H, S, etc., are zero. As a consequence, control of the binding of substrate must reside in the nonbinding conformations of the polymer since they govern the different fractions of time the macromolecule is in the correct conformation for bonding. Applying standard macromolecular models to the enzymes suggests that the majority of free energy for an enzyme reaction resides in the enzyme structure as an entropic contribution. Enthalpic contributions come from bond formation with the substrates and substrate structural changes. Further, it is shown that the molecular mechanisms that can effect binding and allosteric control fall into only three classes. Three x-ray structures of class A -lactamases (native, mutant, and with substrate) show the individual binding groups at the active site change their accessible volumes depending on substrate binding and mutant form. From these volume differences, the S of reaction is calculated. The x-ray-derived G = –TS matches the G = –RT ln k₁ from changes in rate constants for the same set of -penicillinases.     

Sensitivity of Escherichia coli to viral nucleic acid. VI. Capacity of dna mutants and DNA polymerase-less mutants for multiplication of phiA and phiX 174

Summary Seven groups of dna mutants were tested for the capacity to support the growth of A and X174, using a calcium-dependent transfection system. At the restrictive temperature, two groups of mutants, dnaA and dnaF, allowed the viral multiplication. Group B, C, D, E and G mutants were nonpermissive at 43°C to SS¹ DNA as well as to double-stranded RF molecule. Evidence showing the dispensability for the viral growth of DNA polymerase I and recombination function was also presented. Double mutant deficient in DNA polymerase I and II supported the growth of A sufficiently.     

Three rpoBC mutations that suppress the termination defects of rho mutants also affect the functions of nusA mutants

Summary We have mapped three Escherichia coli RNA polymerase mutations selected by Guarente (1979) to suppress the termination defects of rho201. We find that two of the mutations are located in the 3 half of the rpoB gene encoding the subunit. The third mutation is in the rpoC gene, encoding the subunit. All three RNA polymerase mutations affect termination efficiency, even in rho ⁺ strains, suggesting that the C-terminal end of the as well as the subunit participates in termination. In addition we find that all three rpoBC alleles inhibit N-mediated antitermination at 30° C in a strain containing the nusA1 allele. It may be significant that the three other RNA polymerase mutations known to revert the termination defect of mutant rho alleles also affect N-mediated antitermination in nusA1 strains. The correlation of these two phenotypes suggests that both phenotypes may arise from the same functional defect in RNA polymerase.     

Pollen tube extract supports the movement of actin filaments in vitro

Summary Muscle actin filaments labeled with rhodamine-phalloidin were observed to move on the surface coated with a crude extract of pollen tubes ofLilium longiflorum with an average velocity of 1.99±0.55 m/sec. The movement required both Mg²⁺ and ATP. These results indicate that the extract of pollen tubes contains a myosin-like translocatorAbbreviations ATP adenosine-5-triphosphate - DTT dithiothreitol - EGTA ethyleneglycol-bis-(-aminoethylether)N,N,N,N-tetraacetic acid - PIPES piperazine-N,N-bis-(2-ethanesulfonic acid) - PMSF phenylmethylsulfonyl fluoride     

In vitro pollen selection in Brassica napus L. for resistance to phytotoxic compounds from Alternaria brassicicola (Schw.) Wilts

Summary Pollen samples from Brassica napus cvs Arran and Herkules were incubated for 1 h in a germination medium or in a medium to which 20 mg ml^–1 of a toxic extract from Alternaria brassicicola had been added. The pollen samples were then used to pollinate cv Primor. A number of the plants, obtained from pollinations using pollen incubated in the toxic extract, produced pollen with a significantly increased ability to germinate in medium containing 10 mg ml^–1 of the extract, evidence that some selection for resistance to the toxic compounds produced by A. brassicicola had occurred. The potential application of in vitro pollen selection and conditions necessary for its success are discussed.     

Reduced expression of a distal gene of the prn gene cluster in deletion mutants of Aspergillus nidulans: genetic evidence for a dicistronic messenger in an eukaryote.

Summary Temperature sensitive dnaAts46 mutants, in which initiation of chromosome replication is blocked at 42° C, are unable to maintain a dv plasmid at the permissive temperature unless the plasmid carries a mutation in gene P of the type permitting phage to grow in groP (dnaB) bacteria. The growth rate of dnaAts46 mutants seems to be impaired by the presence of the dvP mutant plasmid.Cold sensitive dnaAcos mutants which overinitiate replication at low temperature and grow normally only at 40° and above, can maintain efficiently dvP ⁺ plasmids as well as dvP mutants. Cold sensitivity of dnaAcos mutants is suppressed by the presence of the plasmid dvP ⁺ and by certain dvP mutants, but not by others.The gene P product seems to act by reducing the initiation potential of both types of dnaA mutants, aggravating the initiation defect in dnaAts46 and correcting the overinitiation of dnaAcos.     

Respiration rates of Chiloplacus sp. and other arctic nematodes at low and high temperatures

Summary Respiration of an undescribed species of soil nematode of the genus Chiloplacus from the Canadian High Arctic was measured at 2°, 5°, 10°, 15°, 20° and 25°C. The corresponding metabolic rates were 0.2697×10^-3 l, 0.3406×10^-3 l, 0.8408×10^-3 l, 0.8539×10^-3 l, 1.8420×10^-3 l and 2.9360×10^-3 l O₂ ind^-1 h^-1, respectively, for a nematode of 1.0 g dry weight. The relationship between respiration and dry weight for Chiloplacus sp. at 10°C is described by the function log R=-3.0693+0.8844 log W. Q₁₀ values for the 2°–5°, 5°–10°, 10°–15°, 15°–20° and 20°–25°C temperature intervals were 2.18, 6.09, 1.03, 4.65 and 2.54, respectively. Chiloplacus sp. showed raised metabolic rates at low tempetatures compared with species from warmer environments. Metabolic rates of representative samples of the soil, nematode fauna (dominated by individuals of the genus Plectus) from the same location were 0.1593×10^-3 l, 0.3603×10^-3 l and 0.5332×10^-3 l O₂ ind^-1 h^-1 at 5°, 10° and 15°C for an average nematode of 0.4297 g dry weight.     

RNA polymerase subunit biosynthesis in Bacillus subtilis

Summary The relative rates of RNA polymerase biosynthesis in Bacillus subtilis has been examined under steady-state growth conditions. The synthesis of RNA polymerase subunits (, , , ) has been followed by subunit fractionation of immunoprecipitated [³H]-labelled samples on SDS-polyacrylamide gels. The stoichiometries of ::: subunits have been determined from cultures pulse-labelled during steady-state growth. The results suggest that an unassembled pool of the -subunit exists from which the holoenzyme is formed.Upon shift-up from acetate to glycerol containing medium, a rapid rise in the differential rate of core enzyme synthesis was observed, while the rate of synthesis of the -subunit was not stimulated. During shift-down, a concomitant reduction in the rate of synthesis of all subunits occurred for the first 20 min after the shift; thereafter, a rate of synthesis characteristic of the new growth rate was established.As cultures enter sporulation, an immediate reduction in the rate of -subunit synthesis was demonstrated.     

Quantitation of RNA polymerase subunits in Escherichia coli during exponential growth and after bacteriophage T4 infection

Summary A method was developed to measure the amounts of RNA polymerase subunits, , , and in crude extracts of Escherichia coli. The proteins were labelled by growing the cells in ³⁵S-sulphate containing media. For measuring and , the cell lysate was electrophoresed on 6% polyacrylamide gels containing SDS and the and bands cut out and counted. For measuring and , the cell lysate was co-electrophoresed with dansylated RNA polymerase on 8% polyacrylamide gels containing SDS. The fluorescent bands were cut out, the proteins eluted, and the and subunits further purified on polyacrylamide gels containing 8 molar urea.The results are: (1) is the subunit of the core RNA polymerase which is present in limiting amount. (2) The core enzyme, as measured by , constitutes a constant fraction of total cellular protein (0.9%), independent of the bacterial growth rate. (3) The subunit is made in excess and is probably regulated independently. (4) The subunit is present in 0.3–0.4 times the amount of the core enzyme. (5) All four subunits are fully conserved after bacteriophage T4 infection.     

Identification of a ∼30S size non-ribosomal Saccharomyces cerevisiae RNA that is rapidly labeled on its 3′ end by ATP or UTP

Cell-free extracts prepared from S. cerevisiae cells were incubated in the presence of [-³²P]-labeled ATP, CTP, GTP or UTP. An RNA larger than ribosomal 25S RNA with an apparent size of approximately 30S was prominently labeled on its 3 end in the presence of ATP or UTP but not with CTP or GTP. This labeled RNA was not hybrid-selected by cloned yeast ribosomal DNA; in addition, this 30S RNA was not cleaved by RNase H in the presence of complementary deoxyribooligonucleotides to rRNA. These two lines of evidence show that this 30S RNA is not structurally related to ribosomal RNA gene repeat. The cell-free extracts prepared from yeast cells containing temperature-sensitive poly(A) polymerase adenylated this novel yeast RNA at restrictive temperature with efficiency similar to extracts prepared from wild-type yeast cells. These data show that the enzyme responsible for adenylation of this 30S RNA is distinct from mRNA poly(A) polymerase. While the human SRP RNA 3 adenylating enzyme in the HeLa cell extract adenylated human SRP or Alu RNAs, the yeast adenylating enzyme did not adenylate the human SRP or Alu RNAs in vitro; these data indicate species specificity for this adenylating enzyme.