The promoters of the genes for colicin production, release and immunity in the ColA plasmid: effects of convergent transcription and Lex A protein.
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The initiation sites of transcription in vivo for the three genes caa, cai and cal encoding respectively colicin A (Caa), the immunity protein (Cai) and the pColA lysis protein (Cal) have been analysed by nuclease S1 mapping. This analysis demonstrates that caa and cal form an operon. cai is located between these two genes and transcribed in the opposite direction from its own promoter. The start sites for caa and cai have also been determined in vitro. For caa, the same start site was found in vivo and in vitro. In contrast, for cai the most efficient start site in vitro was not used in vivo. LexA protein strongly repressed the in vivo and in vitro transcription of the caa-cal operon. As determined by DNase 1 protection experiments, LexA protein binds with a high affinity to an approximately 40 bp long sequence just downstream of the Pribnow box. The sequence of the binding site is composed of two overlapped "SOS boxes". Two transcripts of the caa-cal operon were detected by blot hybridization. The longer mRNA can direct the synthesis of both Caa and Cal while the shorter one is terminated at the end of caa. When the transcription of the caa-cal operon is induced, there is a strong interference with cai transcription. (+info)
Location of the antigenic determinants of conjugative F-like pili.
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The amino terminus of the pilin protein constitutes the major epitope of F-like conjugative pili studied to date (F, ColB2, R1-19, R100-1, and pED208). Anti-pED208 pilus antibodies were passed through a CNBr-Sepharose affinity column linked to bovine serum albumin which was conjugated to a synthetic peptide, AcP(1-12), containing the major epitope at the amino terminus of pED208 pilin. This allowed the separation of two classes of antibodies; one was specific for the amino terminus and bound to the column, while the other, which recognizes a second epitope on the pilus, did not bind to the column. In addition, antibodies were raised against two amino-terminal peptide-bovine serum albumin conjugates [AcP(1-8) and AcP(1-12)] to ensure a source of pure, high-titer antibodies directed against the amino terminus. The location of these antibodies on intact pili was assayed by immunoelectron microscopy with a protein A-gold technique. The amino terminus-specific antibodies did not bind to the sides of the pili but appeared to be associated with the pilus tip. In addition, these antibodies were found to bind to the vesicle-like structure at the base of the pilus. The anti-pilus antibodies not specific for the amino terminus (unbound immunoglobulin G) were found to bind to the sides of the pilus. Anti-F and anti-ColB2 pilus antibodies bound to the sides of F, ColB2, and R1-19 pili, which have only their secondary epitope in common. The carboxyl-terminal lysine of R1-19 pilin prevents the absorption of anti-F plus antiserum but not anti-ColB2 pilus antiserum to the sides of the pilus, presumably by interfering with the recognition of this secondary epitope. (+info)
Nucleotide sequence of the colicin B activity gene cba: consensus pentapeptide among TonB-dependent colicins and receptors.
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Colicin B formed by Escherichia coli kills sensitive bacteria by dissipating the membrane potential through channel formation. The nucleotide sequence of the structural gene (cba) which encodes colicin B and of the upstream region was determined. A polypeptide consisting of 511 amino acids was deduced from the open reading frame. The active colicin had a molecular weight of 54,742. The carboxy-terminal amino acid sequence showed striking homology to the corresponding channel-forming region of colicin A. Of 216 amino acids, 57% were identical and an additional 19% were homologous. In this part 66% of the nucleotides were identical in the colicin A and B genes. This region contained a sequence of 48 hydrophobic amino acids. Sequence homology to the other channel-forming colicins, E1 and I, was less pronounced. A homologous pentapeptide was detected in colicins B, M, and I whose uptake required TonB protein function. The same consensus sequence was found in all outer membrane proteins involved in the TonB-dependent uptake of iron siderophores and of vitamin B12. Upstream of cba a sequence comprising 294 nucleotides was identical to the sequence upstream of the structural gene of colicin E1, with the exception of 43 single-nucleotide replacements, additions, or deletions. Apparently, the region upstream of colicins B and E1 and the channel-forming sequences of colicins A and B have a common origin. (+info)
Control of ColE1 replication: low affinity specific binding of Rop (Rom) to RNAI and RNAII.
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We have studied the interactions between the three molecules Rop, RNAI and RNAII that are involved in the regulatory mechanism controlling the replication of ColE1 plasmids. We show that it is possible to purify the two RNA molecules by passing an RNA mixture through an affinity column containing Rop immobilized to a solid support. The dissociation constants of the Rop-RNAI and Rop-RNAII complexes are of the order of 10(-4) M, several orders of magnitude higher than dissociation constants of stable protein-nucleic acid complexes (10(-10) M in the lambda repressor system). Although complete RNAI molecules have higher affinity, stem-and-loop I alone can also bind Rop, suggesting that this structure plays an important role in the interaction. Rop protects the stems of RNAI and RNAII from digestion by RNases while the sensitivity of the loops to digestion by RNase T1 is not affected by high concentrations of Rop. We propose a model for Rop-RNAI/RNAII interaction in which the dimeric protein acts as an adaptor between stem structures to position the two RNAs in the correct position for loop interaction. (+info)
Conditional high copy number ColE1 mutants: resistance to RNA1 inhibition in vivo and in vitro.
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We describe three independently isolated copy number mutants of a plasmid ColE1 derivative which undergo temperature- and growth-phase-dependent DNA amplification in Escherichia coli. These mutants have single base-pair alterations in a highly localized region of the plasmid genome encoding the replication primer RNA. The mutations map immediately upstream of the RNA1 transcript, altering the sequence between conserved elements of the RNA1 promoter. These mutants have 2- to 4-fold increased copy number relative to wild-type plasmids in exponential growth at 37 degrees C but undergo 20-fold amplification of copy number relative to wild-type when cells enter stationary phase. Cells containing these plasmids grow with normal kinetics at 37 degrees C but grow poorly at 42 degrees C. The poor growth is associated with high-level plasmid amplification. Both the temperature and growth phase plasmid DNA amplification are suppressed if the ColE1 rop gene product is provided in trans from a compatible plasmid. Analysis of steady-state RNA1 levels indicates that DNA amplification occurs in the presence of RNA1 made by the mutant plasmid. Thus, the DNA amplification of the copy mutant is not due to an inability to synthesize RNA1. Using an in vitro transcription system containing RNase H, we show that mutant primer processing by RNase H is resistant to levels of the replication initiation inhibitor RNA1 that inhibit wild-type primer processing. The defect in inhibition appears not to be at the level of association of RNA1 with nascent primer. These results indicate that mutant plasmid amplification is due to the ability of its primer precursor transcripts to serve as substrates for RNase H despite the presence of RNA1. (+info)
Preparative separation of the complementary strands of DNA restriction fragments by alkaline RPC-5 chromatography.
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High pressure reversed phase chromatography (RPC-5) at pH 12 was used for preparative separation of the complementary strands of the smaller DNA fragments which are generated by the Hae III restriction endonuclease digestion of Col El DNA. A single high pressure RPC-5 chromatographic step at neutral pH served to purify duplex fragments 70, 172, 250 and 440 base pairs long; each of these yielded two elution peaks upon chromatography under alkaline denaturing conditions. (+info)
Characterization of a purF operon mutation which affects colicin V production.
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A mini-Tn10-kan insertion mutation identified a gene in the chromosome of Escherichia coli required for colicin V production from plasmid pColV-K30. With the complete restriction map of E. coli, the mutation was rapidly mapped to 50.0 min, within the purF operon. Sequence analysis showed that the insertion occurred in a gene with no previously known function which is located directly upstream of purF. We designated this gene cvpA for colicin V production. The mutant requires adenine for growth, probably because of a polar effect on purF expression. However, an adenine auxotroph showed no defect in colicin V production, suggesting that the cvpA mutation is responsible for the effect on colicin V production. Two possible models of cvpA1 allele function are discussed. (+info)
An evolutionary relationship between the ColE5-099 and the ColE9-J plasmids revealed by nucleotide sequencing.
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The nucleotide sequence of a 1124 bp fragment of the ColE5-099 plasmid which encodes colicin E5 immunity, a lys gene involved in colicin release from the host cell, and the 3' end of the colicin E5 structural gene has been determined. Open reading frames corresponding to the three genes have been located by analogy with similar sequences from other E colicin plasmids. The location of these open reading frames corresponds with the position of the genes as determined by subcloning and transposon mutagenesis. The amino acid sequence of the carboxy-terminal 107 amino acid residues of the colicin E5 gene shows no homology with any other E colicin, suggesting a different mode of action in killing sensitive cells. A comparison of the nucleotide sequence of this region of the ColE5-099 plasmid with that of the equivalent region of the ColE9-J plasmid suggests a close evolutionary relationship between these two plasmids. (+info)