Induction of RNA polymerase synthesis in Escherichia coli

Expression of cloned rpoB gene of Escherichia coli: a genetic system for the isolation of dominant negative mutations and overproduction of defective beta subunit of RNA polymerase

The rifampin resistance rifD18 allele of rpoB, carried on the expression plasmid pXT7 beta, is controlled by a strong bacteriophage T7 late promoter and two weak Escherichia coli promoters. Depending on the host strain, pXT7 beta specifies different levels of Rifr beta subunit, providing a system for the isolation, maintenance, and overexpression of dominant lethal alleles of rpoB. In rpoB+ hosts, pXT7 beta confers the Rifr phenotype on the Rifs host. Negative rpoB mutations in the plasmid DNA can thus be scored by screening transformants for Rifs. In an rpoB(Am) supD(Ts) host in which chromosomal rpoB expression is decreased as the temperature goes up, some of the negative plasmid-borne rpoB mutations displayed a dominant phenotype. In a host harboring inducible T7 RNA polymerase, the defective beta subunits could be overexpressed independently of the E. coli transcriptional machinery. With this system, we isolated several negative rpoB mutations induced in vitro by hydroxylamine. Seven of the mutant rpoB alleles, when overexpressed, were found to specify normal-size beta polypeptides. Two of them displayed the dominant lethal phenotype in the rpoB(Am) supD(Ts) background. We also constructed a mutation (rpoB1800) in which 24 carboxy-terminal amino acids were substituted with a random 19-amino-acid sequence. The nonfunctional rpoB1800 beta polypeptide was isolated and assembled in vitro into the core enzyme molecule.

Genetic studies on the beta subunit of Escherichia coli RNA polymerase. I. The effect of known, single amino acid substitutions in an essential protein

The use of five different nonsense suppressors, in conjunction with a collection of 95 independent, spontaneously-occurring amber mutants affecting expression of rpoB, allows the generation of a maximum of 475 potential variants of the beta subunit of E. coli RNA polymerase, each carrying a known amino acid substitution at a particular site. The effect of these amino acid exchanges has been investigated in vivo. A significant majority (363/475) of substitutions lead to cellular death and altered properties--temperature sensitivity, apparently altered transcription termination and a changed stringent response--indicating that RNA polymerase function (unlike that of dispensable proteins) is extremely sensitive to such single site changes.

Direct measurement of absolute suppressor efficiency

We have devised a system for measuring the degree of translational readthrough past a nonsense mutation which is based upon the quantitation of the two translation products, the suppressed polypeptide and the nonsense fragment. The absolute efficiency of four different amber suppressors (Su1, Su2, Su3, and Su7) has been determined at two unique amber sites in the structural gene for the beta subunit of Escherichia coli RNA polymerase.

dnaB125, a dnaB nonsense mutation

A temperature-sensitive dnaB mutation, dnaB125, was shown to be a suppressed amber mutation. The effects of inserting different amino acids at the mutated site via amber suppressors were examined for both Escherichia coli and bacteriophage gamma growth. In addition, the dnaB125 amber allele was shown to be different from the previously described dnaB amber allele, dnaB266. The extent of residual deoxyribonucleic acid synthesis observed in a supF(Ts) dnaB125 strain at high temperature revealed that the dnaB protein was present in excess and that deoxyribonucleic acid synthesis could continue for several generation equivalents without further production of dnaB protein.

Chemistry and biology of E. coli ribosomal protein L12

E. coli ribosomal protein L12, because of its unique features, has been studied in more detail than perhaps any of the other ribosomal proteins. Unlike the other ribosomal proteins that are generally present in stoichiometric amounts, there are four copies of L12 per ribosome, some of which are acetylated on the N-terminal serine. The acetylated species, referred to as L7, has not been shown, as yet, to possess any different biological activity than L12. A specific enzyme that acetylates L12 to form L7, using acetyl-CoA as the acetyl donor, has been purified from E. coli extracts. L12 is also unique in that it does not contain cysteine, tryptophan, histidine, or tyrosine, is very acidic (pI: 4.85) and has a high content of ordered secondary structure (approximately 50%). The protein is normally found in solution as a dimer and also forms a tight complex with ribosomal protein L10. There are three methionine residues in L12, located in the N-terminal region of the protein, one or more of which are essential for biological activity. Oxidation of the methionines to methionine sulfoxide prevents dimer formation and inactivates the protein. The four copies of L12 are located in the crest region(s) of the 50S ribosomal subunit. There is good evidence that the soluble factors, such as IF-2, EF-Tu, EF-G and RF, interact with L12 on the ribosome during the process of protein synthesis. This interaction is essential for the proper functioning of each of the factors and for GTP hydrolysis associated with the individual partial reactions of protein synthesis. The L12 gene is located on an operon that contains the genes for L10 and beta beta' subunits of RNA polymerase at about 88 min on the bacterial chromosome. DNA-directed in vitro systems have been used to study the unique regulation of the expression of these genes. Autogenous regulation, translational control, and transcription attenuation are regulatory mechanisms that function to control the synthesis of these proteins.

Analysis of a cell cycle model for Escherichia coli

Ribosome and protein synthesis, DNA replication and cell division in Escherichia coli cells are described by a mathematical model that integrates previous descriptions in quantitative terms and proposes a new formalization to relate ribosome net synthesis to cell growth. The model assumes a cell size control of DNA replication and therefore is structurally divided into two subsystems: the first, whose state variables are ribosomes and protein, and the second, which is activated when the protein level reaches a threshold and which is comprised of DNA replication and cell division. The dynamics of the entire system is set only by the first subsystem: the values of its parameters determine whether the cells will be in a resting condition or will grow exponentially and in the latter case the resulting duplication time, while the structure and the parameter values of the second subsystem determine the size and the composition of the cell and the timing of DNA replication during the cycle. Relationships are derived that allow a simple determination of the time of initiation and of termination of DNA replication and the number of chromosome origins involved in any possible cell cycle as well as the macromolecular levels at the beginning of a cycle and on the average in a population of cells in balanced exponential growth.

Escherichia coli RNA polymerase binding and initiation of transcription on fragments of lambda rifd 18 DNA containing promoters for lambda genes and for rrnB, tufB, rplC,A, rplJ,L, and rpoB,C genes

Promoters of genes for bacteriophage lambda and for Escherichia coli ribosomal RNA (rrnB), elongation factor Tu (tufB), ribosomal proteins L11 (rplK), L1 (rplA), L10 (rplJ), and L7/L12 (rplL), and RNA polymerase subunits beta (rpoB) and beta' (rpoC) were studied by use of two types of filter binding assays which measured E. coli RNA polymerase binding and initiation of transcription on restriction fragments of lambda rifd 18 DNA. The DNA fragments selectively retained on filters were eluted, concentrated, and analyzed by gel electrophoresis. The binding characteristics of these promotor fragments were qualitatively determined by varying the RNA polymerase, salt, and glycerol concentrations in the polymerase binding assay with HaeIII fragments of lambda rifd 18 DNA. The approximate map locations of these small HaeIII fragments were determined by HaeIII digestion of the larger, previously mapped EcoRI, HindIII, and SmaI restriction fragments of the phage DNA. The base compositions proximal to the 5' ends of mRNA's from promoters on these DNA fragments were elucidated by the polymerase initiation assay, in which the addition of various combinations of nucleoside triphosphates to the reaction allowed RNA polymerase to form high-salt-resistant initiation complexes with some of the known SmaI + EcoRI, EcoRI + HindIII, or HaeIII restriction fragments of lambda rifd 18 DNA. The data obtained by this technique are consistent with the map positions and 5' mRNA base sequences of the known lambda promotors p'R, po, pR and pL. In the main focus of this work, we have determined the approximate map locations and 5' mRNA base compositions of several promoters for known E. coli genes including rrnB, tufB, rplK,A, and rplJ,L. No promoter was detected between rplL and the rpoB,C genes. Thus our data are consistent with the conclusion of Yamamoto and Nomura (1978) that the beta and beta' mRNA is probably cotranscribed from the promoter for rplJ,L. Finally, the approximate map positions and the NTP combinations which initiated transcription of several unknown lambda and E. coli in vitro promoters are reported. The methods reported should prove useful for studying the characteristics of promoters on other cloned DNA regions.

Identification of a single promoter in E. coli for rplJ, rplL and rpoBC

A set of restriction fragments cloned into phage lambda vectors has allowed us to locate a site necessary for full rpoBC expression. We find that these genes for the two large subunits of RNA polymerase and the genes, rplL and rplJ, for two ribosomal proteins, form a single operon.

Genetic mapping of a putative temperature-sensitive transcription mutation in Escherichia coli K12

A putative temperature-sensitive transcription mutant described earlier (Jabbar and Jayaraman, 1976) has been genetically mapped. The locus maps at 38 min to the left of aroD. The mutation is recessive to the wild type and it affects a gene probably other than the genes coding for the alpha and beta subunits of phenylalanine tRNA synthetase and protein synthesis initiation factor IF-3 which also map in the same region.

Over-synthesis and instability of sigma protein in a merodiploid strain of Escherichia coli

We have used two different methods to study the rates of RNA polymerase subunit synthesis in haploid Escherichia coli K12, and a KLF10 rPOB, C+ merodiploid derivative, when grown in glucose-minimal medium at 37 degrees C. Our results indicate that the haploid strain produces beta, beta', alpha and sigma in the molar ratios 1.01:0.99: less than or equal to 2.90:0.26; and that all these subunits are reasonably stable during subsequent growth. The merodiploid produces alpha at the same rate as the haploid, beta and beta' at a 42% higher rate, and sigma at twice the rate. Some 40% of the newly synthesised beta and beta' is degraded within one hour; the residuum is as stable as in the haploid. Alpha is stable throughout. By contrast, sigma is subject to a marked and continuous turnover in the merodiploid. These results are discussed in terms of gene dosage and regulatory effects.

Identification of an amber fragment of the beta subunit of Escherichia coli RNA polymerase: a yardstick for measuring controls on RNA polymerase subunit synthesis

An amber fragment of the beta subunit of Escherichia coli RNA polymerase has been recovered from strains carrying the rpoB12 amber mutation, indicating that the B12 mutation resides in the structural gene for the beta subunit. The fragment is readily assayed and can be used to determine the degree of expression of a single rpoB cistron in strains haploid or diploid for this region. These studies confirm that the bacterial mechanism, which can compensate for reduced translation of the beta message, operates by the co-ordinate induction of rpoB and rpoC. Furthermore, I show that rpo control depends upon cistron(s) located on the F' factor, KLF10, whose product(s) can act negatively in trans on rpoBC expression.