Anthony R. Poteete

Systematic mutation of bacteriophage T4 lysozyme

Amber mutations were introduced into every codon (except the initiating AUG) of the bacteriophage T4 lysozyme gene. The amber alleles were introduced into a bacteriophage P22 hybrid, called P22 e416, in which the normal P22 lysozyme gene is replaced by its T4 homologue, and which consequently depends upon T4 lysozyme for its ability to form a plaque. The resulting amber mutants were tested for plaque formation on amber suppressor strains of Salmonella typhimurium. Experiments with other hybrid phages engineered to produce different amounts of wild-type T4 lysozyme have shown that, to score as deleterious, a mutation must reduce lysozyme activity to less than 3% of that produced by wild-type P22 e416. Plating the collection of amber mutants covering 163 of the 164 codons of T4 lysozyme, on 13 suppressor strains that each insert a different amino acid substitutions at every position in the protein (except the first). Of the resulting 2015 single amino acid substitutions in T4 lysozyme, 328 were found to be sufficiently deleterious to inhibit plaque formation. More than half (55%) of the positions in the protein tolerated all substitutions examined. Among (N-terminal) amber fragments, only those of 161 or more residues are active. The effects of many of the deleterious substitutions are interpretable in light of the known structure of T4 lysozyme. Residues in the molecule that are refractory to replacements generally have solvent-inaccessible side-chains; the catalytic Glu11 and Asp20 residues are notable exceptions. Especially sensitive sites include residues involved in buried salt bridges near the catalytic site (Asp10, Arg145 and Arg148) and a few others that may have critical structural roles (Gly30, Trp138 and Tyr161).

PCR-mediated gene replacement in Escherichia coli.

The hyper-recombinogenic properties of an E. coli strain in which the recBCD genes have been replaced by lambda red recombination functions were exploited in the development of a general PCR-mediated gene replacement scheme for Escherichia coli. Linear DNA substrates generated by recombinant PCR are introduced by electroporation into strains containing the recBCDDelta::red substitution. This technique allows for gene replacement in E. coli without prior cloning of the gene of interest. In addition, the counter-selectable marker sacB has been used to construct unmarked precise gene deletions without the need to form sacB-containing plasmid integrates. In other experiments, electroporation of recBCDDelta::red strains with high concentrations of linear DNA fragments (derived from plasmid digests) gave linear transformation rates approaching 1% of the survivors of electroporation. The placement of lambda red and gam at a locus in the chromosome other than recBCD (galK) resulted in a strain that was as hyper-rec as one containing the lambda red for recBCD substitution. The gene replacement technique described here has been used for the construction of deletion-substitution alleles of lacZ and sulA, as well as six genes important for general homologous recombination in E. coli. Three of these replacements were performed without prior cloning of the genes.

Correlation of DNA adenine methylase activity with spontaneous mutability in Escherichia coli K-12

Using a multicopy plasmid in which the tac promoter has been placed in front of the dam gene of Escherichia coli K-12, we show that levels of DNA adenine methylase activity are correlated with the spontaneous mutation frequency.

Phage P22 lysis genes: Nucleotide sequences and functional relationships with T4 and λ genes

Abstract Wild-type and amber mutant alleles of the lysis genes of P22 were cloned and sequenced. Gene 13 encodes an 11,520-Da basic hydrophobic protein that has 89% amino acid homology to λ S protein. Gene 19 encodes a protein that has a small degree of amino acid homology with T4 lysozyme, but we could detect no homology to λ R or RZ proteins. The protein product of gene 19 was purified; its amino terminal amino acid sequence is as predicted by the DNA sequence. It starts with a single amino terminal methionine residue and is a basic protein with a molecular weight of 15,968. Plasmids expressing P22 gene 19 , λ genes R and RZ , and T4 gene e were constructed. All of these plasmids were able to complement both λ R − and P22 19 − .

λ red-dependent growth and recombination of phage P22

Plasmids that express lambda recombination functions singly and in combinations, at controllable levels, have been constructed. These plasmids were placed in Escherichia coli and Salmonella strains, and their ability to complement lambda and P22 strains lacking recombination functions was examined. The combination of lambda bet and exo constitutes a minimal system that can substitute for the recombination system of P22 in allowing efficient growth and recombination in a recA- host.

Nucleotide sequence of the bacteriophage P22 gene 19 to 3 region: Identification of a new gene required for lysis

The nucleotide sequence of a 2558-bp region of bacteriophage P22 at the right end of the genetic map between genes 19 and 3 was determined. A new gene that is partially required for lytic growth, named gene 15, was noted. P22 mutants were constructed which lack gene 15 function, and the gene 15 product was found to be required for lysis in the presence of some divalent cations. It has extensive amino acid sequence similarity with the phage lambda Rz gene, which has a similar function, and weak similarity to the phage T7 18.5 gene which previously had no known function. A hybrid P22 phage, in which the T7 18.5 gene replaces the P22 gene 15, exhibits the plating properties of wild-type P22, strongly suggesting that the two genes have similar functions. In addition, deletions were constructed which show that phage P22 has no additional genes required for lytic growth of lysogeny between genes 19 and 3.

Domain structure and quaternary organization of the bacteriophage P22 Erf protein

The structure and activities of the recombination-promoting P22 Erf protein were examined in vitro. Treatment of the protein with elastase produces a stable amino-terminal fragment, consisting of amino acid residues 1 to (approximately) 136. We have purified this fragment, designated fragment B, to apparent homogeneity by gel filtration chromatography. Fragment B retains the oligomeric structure and single-stranded DNA binding specificity of intact Erf. It differs, however, in lacking the ability of intact Erf to bind single-stranded DNA into large aggregates following mild heat treatment of the protein. In addition, its binding to DNA may be weaker than that of intact Erf. Intact Erf sediments through a sucrose gradient as a discrete species with an apparent S20,w of approximately 11 X 7 S. Its sedimentation behavior is affected little, if at all, by concentration. Fragment B also sediments as a discrete species at approximately 10 X 4 S. In the electron microscope, intact Erf appears as rings, with 10 to 14 small projecting structures resembling the teeth of a gear. Fragment B is similar, except that it appears to lack the peripheral structures. From these observations, we conclude that Erf consists of at least two structurally and functionally distinct domains, and that it has a discrete ring-like oligomeric structure.

Genetic requirements of phage lambda red-mediated gene replacement in Escherichia coli K-12

Recombination between short linear double-stranded DNA molecules and Escherichia coli chromosomes bearing the red genes of bacteriophage lambda in place of recBCD was tested in strains bearing mutations in genes known to affect recombination in other cellular pathways. The linear DNA was a 4-kb fragment containing the cat gene, with flanking lac sequences, released from an infecting phage chromosome by restriction enzyme cleavage in the cell; formation of Lac(-) chloramphenicol-resistant bacterial progeny was measured. Recombinant formation was found to be reduced in ruvAB and recQ strains. In this genetic background, mutations in recF, recO, and recR had large effects on both cell viability and on recombination. In these cases, deletion of the sulA gene improved viability and strain stability, without improving recombination ability. Expression of a gene(s) from the nin region of phage lambda partially complemented both the viability and recombination defects of the recF, recO, and recR mutants and the recombination defect of ruvC but not of ruvAB or recQ mutants.

Amplification of lac Cannot Account for Adaptive Mutation to Lac+ in Escherichia coli

When the Lac- strain of Escherichia coli, FC40, is incubated with lactose as its sole carbon and energy source, Lac+ revertants arise at a constant rate, a phenomenon known as adaptive mutation. Two alternative models for adaptive mutation have been proposed: (i) recombination-dependent mutation, which specifies that recombination occurring in nongrowing cells stimulates error-prone DNA synthesis, and (ii) amplification-dependent mutation, which specifies that amplification of the lac region and growth of the amplifying cells creates enough DNA replication to produce mutations at the normal rate. Here, we examined several of the predictions of the amplification-dependent mutation model and found that they are not fulfilled. First, inhibition of adaptive mutation by a gene that is toxic when overexpressed does not depend on the proximity of the gene to lac. Second, mutation at a second locus during selection for Lac+ revertants is also independent of the proximity of the locus to lac. Third, mutation at a second locus on the episome occurs even when the lac allele under selection is on the chromosome. Our results support the hypothesis that most Lac+ mutants that appear during lactose selection are true revertants that arise in a single step from Lac- cells, not from a population of growing or amplifying precursor cells.

Location and sequence of the erf gene of phage P22

The erf (essential recombination function) gene of Salmonella phage P22 was mapped by complementation between plasmids carrying parts of the P22 chromosome and superinfecting erf− phage. A segment of DNA shown by this method to contain the erf gene was sequenced. The sequence contains an open reading frame of 205 codons, starting with ATG, and followed by two tandem termination codons. Two erf− amber mutations result in changes in two different CAG codons in this sequence to TAG. The DNA sequence predicts an Erf protein monomer molecular weight of approximately 23,000. Two other conclusions emerge from the phage-plasmid complementation assay: Gene 17 of P22 is located between genes erf and c2; and phage λ encodes a function, possibly redβ, that can complement P22 erf−.