The bof gene of bacteriophage P1: DNA sequence and evidence for roles in regulation of phage c1 and ref genes.

The C1 repressor of bacteriophage P1 acts via 14 or more distinct operators. This repressor represses its own synthesis as well as the synthesis of other gene products. Previously, mutation of an auxiliary regulatory gene, bof, has been shown to increase expression of some C1-regulated P1 genes (e.g., ref) but to decrease expression of others (e.g., ban). In this study the bof gene was isolated on the basis of its ability to depress stimulation of Escherichia coli chromosomal recombination by the P1 ref gene, if and only if a source of C1 was present. C1 alone, but not Bof alone, was partially effective. The bofDNA sequence encodes an 82-codon reading frame that begins with a TTG codon and includes the sites of the bof-1(Am) mutation and a bof::Tn5 null mutation. Expression of ref::lacZ and cl::lacZ fusion genes was partially repressed in trans by a P1 bof-1 prophage or by plasmid-encoded C1 alone, which was in agreement with effects on Ref-stimulated recombination and with previous indirect evidence for c1 autoregulation. Repression of both fusion genes by plasmid-encoded C1 plus Bof or by a P1 bof+ prophage was more complete. When the C1 source also included a 0.7-kilobase region upstream from C1 which encodes the coi gene, repression of both c1::lacZ and ref::lacZ by C1 alone or by C1 plus Bof was much less effective, as if Coi interfered with C1 repressor function.     

Mutations in the Escherichia coli RNA-polymerase beta-subunit gene cloned in a multicopy plasmid

A multicopy plasmid pLMN1 expressing a wild type rpoB gene encoding Escherichia coli RNA polymerase beta subunit gene was constructed. Introduction of this plasmid into rifampicin-resistant RpoB mutants makes them rifampicin-sensitive. Rifampicin-resistant clones appear in such strains with frequencies up to 10(-3), due to recombinational (recA-dependent) transfer of rif-r mutations from chromosome to pLMN1. This provides a simple selection procedure for transfer of any rpoB mutation, together with a rif-r mutation from a chromosome to pLMN1. In this way, we transferred rpoB22 amber mutation to pLMN1 for localization of the mutant codon by DNA sequencing.     

Purification and DNA binding properties of the blaI gene product, repressor for the beta-lactamase gene, blaP, of Bacillus licheniformis.

The location of the repressor gene, blaI, for the beta-lactamase gene blaP of Bacillus licheniformis 749, on the 5' side of blaP, was confirmed by sequencing the bla region of the constitutive mutant 749/C. An amber stop codon, likely to result in a nonfunctional truncated repressor, was found at codon 32 of the 128 codon blaI open reading frame (ORF) located 5' to blaP. In order to study the DNA binding activity of the repressor, the structural gene for blaI, from strain 749, with its ribosome binding site was expressed using a two plasmid T7 RNA polymerase/promotor system (S. Tabor and C. C. Richardson. Proc. Natl. Acad. Sci. 82, 1074-1078 (1985). Heat induction of this system in Escherichia coli K38 resulted in the production of BlaI as 5-10% of the soluble cell protein. Repressor protein was then purified by ammonium sulfate fractionation and cation exchange chromatography. The sequence of the N-terminal 28 amino acid residues was determined and was as predicted from the DNA. Binding of BlaI to DNA was detected by the slower migration of protein DNA complexes during polyacrylamide gel electrophoresis. BlaI was shown to selectively bind DNA fragments carrying the promoter regions of blaI and blaP.     

The c1 repressor of bacteriophage P1: I. Isolation of the c1 protein and determination of the P1 DNA region to which it Binds

A bacteriophage P1-specific DNA binding protein has been partially purified from P1-infected Escherichia coli and identified as the P1c1 repressor. This protein is absent from non-suppressing cells infected with a P1c1 amber mutant. The binding activity of the protein isolated from cells infected with a c1ts mutant is thermolabile in vitro, so the repressor protein is the product of the c1 gene. Studies on P1 DNA fragments generated by restriction endonuclease digestion indicate that the c1 repressor binds preferentially in vitro at a site or sites located close to the c1 gene itself.     

Purification and properties of Gal repressor:pL-galR fusion in pKC31 plasmid vector

The galR gene, which encodes the Gal repressor protein in Escherichia coli, has been fused to the strong pL promoter of bacteriophage lambda in plasmid pKC31. The pL promoter is kept repressed by a thermolabilie lambda repressor, CIts857, to prevent cell killing. Heat induction of the pL-galR fusion plasmid synthesizes large amounts of active Gal repressor. The protein has been purified to homogeneity in three steps. The purification is greatly aided by the reversible insolubility of active repressor in crude extract at salt concentrations of less than 200 mM. The amino-terminal amino acid sequence determined by automated Edman degradation is: N-Ala-Thr-Ile-Lys-Asp-Val-Ala-Arg-Leu-Ala-Gly-Val-Ser-Val-Ala-Thr-Val-. Comparison of this sequence with that deduced from the DNA sequence of the galR gene showed that the formyl methionine residue preceding alanine at position 1 is cleaved off. The repressor is present in solution as a dimer of a 37-kDa subunit. The protein binds to gal DNA containing wild type and not mutant operator sequences. As predicted, this sequence-specific binding is inhibited by the presence of D-galactose or D-fucose, both of which are in vivo inducers of the gal operon. Gal repressor inhibits the expresison of gal operon by binding to two spatially separated operators which flank, but do not overlap, the gal promoter segment. Experiments to study the mechanism of repressor action are discussed.     

Effect of the deletion of the σ32-dependent promoter (P1) of the Escherichia coli topoisomerase I gene on thermotolerance

Topoisomerase I and DNA gyrase are the major topoisomerase activities responsible for the regulation of DNA supercoiling in the bacterium Escherichia coli . The P1 promoter of topA has previously been shown to be a σ³²-dependent heat-shock promoter. A mutant strain with a deletion of P1 was constructed. This mutant is >10-fold more sensitive to heat treatment (52°C) than the wild type. After brief treatment at 42°C, wild-type Escherichia coli acquires an enhanced resistance to the effects of a subsequent 52°C treatment. This is not the case for the P1 deletion mutant, which, and under these conditions, is about 100-fold less thermotolerant than the wild type. The presence of a plasmid expressing topoisomerase I restored the heat-survival level of the mutant to that of the wild type. During heat shock, the superhelical density of a plasmid with the heat-inducible rpoD promoter is increased in the P1 deletion mutant. We also note that the pulse-labelling pattern of proteins at 42°C (displayed on SDS–polyacrylamide gels) is different in the mutant, and, most notably, the amounts of DnaK and of GroEL protein are reduced. A model is proposed in order to unify these observations.     

Protein engineering with synthetic Escherichia coli amber suppressor genes

We have constructed synthetic genes encoding different Escherichia coli suppressor tRNAs for use in amino acid substitution studies and protein engineering. We used oligonucleotides to assemble the genes for different tRNAs with the anticodon 5' CTA 3'. The suppressor genes are expressed from a synthetic promoter derived from the promoter sequence of the E. coli lipoprotein gene. The genes have been used to suppress an amber mutation in a protein coding sequence, and the resulting altered protein has been subjected to sequence analysis to determine the nature of the amino acid inserted at the amber site. Twelve amino acids can now be added in response to the amber codon. We have employed these suppressors to study amino acid substitutions in the lac repressor.     

High-level expression of a semisynthetic dam gene in Escherichia coli

We constructed a semisynthetic gene encoding a DNA-adenine-methyltransferase (Dam) that codes for the same amino acid sequence as the wild type (wt) Escherichia coli dam gene. Since for unknown reasons the entire wt sequence, from the start codon to the end of the gene, could not be cloned, a gene was constructed consisting of a chemically synthesized 5' portion and a 3' portion from the E. coli chromosome. Introduction of this semisynthetic gene into a suitable vector allows overproduction of E. coli Dam in mg amounts per liter E. coli culture, with optimum expression of the gene in the vector pJLA503. This plasmid places the target gene under control of the strong, tandemly arranged pR pL promoters from bacteriophage lambda, regulated by a temperature-sensitive lambda repressor. A rapid, two-column purification protocol is described that allows for very fast purification of the protein. The 32-kDa recombinant protein methylates the sequence GATC.     

Mechanism of replication of bacteriophage phi X174. XXII. Site-specific mutagenesis of the A* gene reveals that A* protein is not essential for phi X174 DNA replication

The A and A* proteins of phage phi X174 are encoded in the same reading frame in the viral genome; the smaller A protein is the result of a translational start signal with the A gene. To differentiate their respective functions, oligonucleotide-directed site-specific mutagenesis was used to change the ATG start codon of the phi X 174 A* gene, previously cloned into pCQV2 under lambda repressor control, into a TAG stop codon. The altered A gene was then inserted back into phi X replicative form DNA to produce an amber mutant, phi XamA*. Two different Escherichia coli amber suppressor strains infected with this mutant produced viable progeny phage with only a slight reduction in yield. In Su+ cells infected with phi XamA*, phi X gene A protein, altered at one amino acid, was synthesized at normal levels; A* protein was not detectable. These observations indicate that the A* protein increases the replicative efficiency of the phage, perhaps by shutting down host DNA replication, but is not required for replication of phi X174 DNA or the packaging of the viral strand under the conditions tested.     

A single amino acid substitution in the enzyme 5-enolpyruvylshikimate-3-phosphate synthase confers resistance to the herbicide glyphosate

The enzyme 5-enolpyruvylshikimate-3-phosphate synthase (EC 2.5.1.19), encoded by the aroA locus, is a target site of glyphosate inhibition in bacteria. A glyphosate-resistant aroA allele has been cloned in Escherichia coli from a mutagenized strain of Salmonella typhimurium. Subcloning of this mutant aroA allele shows the gene to reside on a 1.3-kilobase segment of S. typhimurium DNA. Nucleotide sequence analysis of this mutant gene indicates a protein-coding region 427 amino acids in length. Comparison of the mutant and wild type aroA gene sequences reveals a single base pair change resulting in a Pro to Ser amino acid substitution at the 101st codon of the protein. A hybrid gene fusion between mutant and wild type aroA gene sequences was constructed. 5-Enolpyruvylshikimate-3-phosphate synthase was prepared from E. coli cells harboring this construct. The glyphosate-resistant phenotype is shown to be associated with the single amino acid substitution described above.     

Gene X of bacteriophage f1 is required for phage DNA synthesis. Mutagenesis of in-frame overlapping genes

The gene II protein of bacteriophage f1 is a site-specific endonuclease required for initiation of phage viral strand DNA synthesis. Within gene II is another gene, X, encoding a protein of unknown function identical to the C-terminal 27% of the gene II protein, and separately translated from codon 300 (AUG) of gene II. By oligonucleotide mutagenesis, we constructed phage mutants in which this codon has been changed to UAG (amber) or UUG (leucine), and propagated them on cells carrying a cloned copy of gene X on a plasmid. The amber mutant makes no gene X protein, and cannot grow in the absence of the complementing plasmid; the leucine-inserting mutant can make gene X protein, and grows normally without the plasmid. Without gene X protein, phage DNA synthesis (particularly viral strand synthesis) is impaired. We discuss this finding in the context of other known in-frame overlapping genes (particularly genes A and A* of phage phi X174), many of which are also involved in the specific initiation of DNA synthesis, and suggest applications for the mutagenic strategy we employed.     

P1 plasmid replication: replicon structure

Bacteriophage P1 lysogenizes Escherichia coli as a unit-copy plasmid. We have undertaken to define the plasmid-encoded elements implicated in P1 plasmid maintenance. We show that a 2081 base-pair fragment of the 90,000 base P1 plasmid confers the capacity for controlled plasmid replication. DNA sequence analysis reveals several open reading frames in this fragment. The largest is shown to encode a 32,000 Mr protein required for plasmid replication. The corresponding gene, repA, has been identified genetically. A set of five 19 base-pair repeats is located upstream from repA; a set of nine similar repeats is located immediately downstream from repA. Each set of repeats, when cloned into pBR322, exerts incompatibility towards a P1 replicon. The upstream set, designated incC, consists of direct repeats that are spaced about two turns of the DNA helix apart; the downstream set, designated incA, consists of nine repeats arranged three in one orientation and six in the other. Spacing between incA repeats were three or four turns of the helix apart. The organization of the plasmid maintenance regions of P1 and the unit-copy sex factor plasmid, F, is strikingly similar. Although the DNA sequences of this region in the two plasmids exhibit little homology, a 9 base-pair sequence that appears four times in the origin region of members of the Enterobacteriaceae also occurs twice as direct repeats in similar positions in P1 and F. This sequence, where it occurs in E. coli, has been postulated to be the binding site for the essential replication protein determined by dnaA. The dnaA protein appears not to be essential for the replication of either plasmid; therefore, the function of the sequence in P1 and F may be regulatory.     

Location by DNA sequence analysis of cop mutations affecting the number of plasmid copies of prophage P1

Summary The DNA sequence of six P1 cop mutants, which are altered in the control of copy number of the plasmid prophage, was compared to that of P1 wild type. Each cop mutant differs from the wild type by a single base substitution. All of these substitutions are located within a 400 base pair region of P1 DNA that also encodes rep, a gene whose product is required for P1 replication.     

Spleen necrosis virus gag polyprotein is necessary for particle assembly and release but not for proteolytic processing.

The nature of spleen necrosis virus pol gene expression and the role of gag and gag-pol polyproteins in virion assembly was investigated. The DNA sequence of the gag-pol junction revealed that the two genes occupy the same open reading frame but are separated by an in-frame amber stop codon. Biochemical analysis of gag-pol translational readthrough in vitro and in Escherichia coli suggests that, in a manner similar to that in other mammalian type C retroviruses, amber stop codon suppression is required for pol gene expression. Removal of the gag stop codon had little or no effect on synthesis or cleavage of the polyprotein but interrupted particle assembly. This block could be overcome by complementation with wild-type gag protein.     

Second-site revertants of the P1 copN22 copy mutant.

Miniplasmids with the P1 copN22 mutation have a copy number about seven times that of the wild type. Selection for reduced copy number from this plasmid led to the isolation of second-site pseudorevertants, called poc mutants. DNA sequence analysis showed that all six independent poc mutants have a single base change in the same codon of the repA gene. This implicates the amino acid at this location, either directly or indirectly, in interactions important for copy number control.