Expression of the kil gene of the ColE1 plasmid in Escherichia coli Kilr mutants causes release of periplasmic enzymes and of colicin without cell death.

Expression of the kil gene of the ColE1 plasmid in certain classes of Escherichia coli mutants (Kilr) resistant to kil-caused cell death brought about release of periplasmic enzymes and of colicin. Phospholipase A was present but was not activated by kil expression in any of the mutants. This indicates that in these mutants the various effects of kil gene expression have become dissociated.

Expression of the cloned ColE1 kil gene in normal and Kilr Escherichia coli.

The kil gene of the ColE1 plasmid was cloned under control of the lac promoter. Its expression under this promoter gave rise to the same pattern of bacterial cell damage and lethality as that which accompanies induction of the kil gene in the colicin operon by mitomycin C. This confirms that cell damage after induction is solely due to expression of kil and is independent of the cea or imm gene products. Escherichia coli derivatives resistant to the lethal effects of kil gene expression under either the normal or the lac promoter were isolated and found to fall into several classes, some of which were altered in sensitivity to agents that affect the bacterial envelope.

Identification of the plasmid-encoded immunity protein for colicin E1 in the inner membrane of Escherichia coli.

A set of plasmids containing portions of the Col E1 plasmid were transformed into recA- cells. These cells, after UV irradiation, only incorporate labelled amino acids into plasmid-encoded proteins. UV-irradiated cells label a 14.5 kDa band if they are phenotypically immune to colicin E1, and do not contain this band if they are sensitive to colicin E1. We conclude that the 14.5 kDa protein is the colicin E1 immunity protein. When the inner and outer membranes of these cells are fractionated, the labelled band appears in the inner membrane. The immunity protein must be an intrinsic inner membrane protein, confirming the predictions made by hydrophobicity calculations from primary sequence data.

Genetic study of the functional organization of the colicin E1 molecule.

Colicin E1 fragments obtained by genetic manipulations of the ColE1 plasmid were tested for bactericidal activity, binding to bacterial cells, and reactions with a series of anticolicin monoclonal antibodies. Two of the fragments were also tested for ability to form channels in liposomal vesicles. The results are in agreement with studies from chemically and enzymatically derived colicin fragments, assigning the receptor binding activity to the central part of the molecule and the killing activity to a region near the carboxyl terminus.

Enhancing activity of rat tissue extracts for induction of lambda prophage by L-azaserine.

We studied the effect of rat tissue extracts on induction of lambda prophage in Escherichia coli (lambda) by L-azaserine. Hepatic and pancreatic extracts, primarily the cytosolic fraction, markedly increased the rate of induction. Hepatic extracts from lipotrope-deficient rats were somewhat more active than extracts from normal rats. The enhancing activity in normal rat hepatic cytosol was partially characterized. It reduced by about one-half the dose of azaserine required for a given purpose. The enhancement was increased by preincubating the bacterial cells with cytosol; cells retained the effect after cytosol was removed. Enhancing activity was inhibited strongly by the amino acids phenylalanine, tryptophan, and tyrosine; to lesser extents by leucine, methionine, and serine; and not at all by proline or glutamine. It was eliminated by dialysis of the cytosol and reduced by omission of nicotinamide adenine dinucleotide phosphate (NADP) from the reaction mixture. Heating the cytosol to 60 degrees C or 80 degrees C or varying the pH of the reaction mixture from 6 to 8 had no significant effect. Treating the cytosol with trypsin appeared to release an inhibitor of the activity. Glutathione, cysteine, and beta-mercaptoethanol also enhanced lambda induction by azaserine, but the cytosolic activity was not affected by the thiol-inactivating compound diethylmaleate (DEM). The results suggest that factors in cytosol interact with bacterial cells to facilitate transport of azaserine into the cells, primarily through the aromatic amino acid transport system. A small molecule, not a free thiol compound, appears to be involved. It may serve to establish reducing conditions protective for azaserine, the probable mechanism of action of sulfhydryl compounds.

cea-kil operon of the ColE1 plasmid.

We isolated a series of Tn5 transposon insertion mutants and chemically induced mutants with mutations in the region of the ColE1 plasmid that includes the cea (colicin) and imm (immunity) genes. Bacterial cells harboring each of the mutant plasmids were tested for their response to the colicin-inducing agent mitomycin C. All insertion mutations within the cea gene failed to bring about cell killing after mitomycin C treatment. A cea- amber mutation exerted a polar effect on killing by mitomycin C. Two insertions beyond the cea gene but within or near the imm gene also prevented the lethal response to mitomycin C. These findings suggest the presence in the ColE1 plasmid of an operon containing the cea and kil genes whose product is needed for mitomycin C-induced lethality. Bacteria carrying ColE1 plasmids with Tn5 inserted within the cea gene produced serologically cross-reacting fragments of the colicin E1 molecule, the lengths of which were proportional to the distance between the insertion and the promoter end of the cea gene.

Alternative forms of lethality in mitomycin C-induced bacteria carrying ColE1 plasmids.

We have studied the physiological effects of mitomycin C induction on cells carrying ColE1 plasmids with differing configurations of three genes: the structural gene coding for colicin (cea), a gene responsible for mitomycin C lethality (kil) that we located as part of an operon with cea, and the immunity (imm) gene, which lies near cea but is not in the same operon. kil is close to or overlaps imm. When cea(+) plasmids are present mitomycin C induction results in 100-fold or greater increases in the level of colicin. Within an hour after induction more than 90% of cells carrying cea(+)kil(+) plasmids are killed and macromolecular synthesis stops, capacity for transport of proline, thiomethyl beta-D-galactoside, and alpha-methyl glucoside is lost, and the membrane becomes abnormally permeable as indicated by an increased accessibility of intracellular beta-galactosidase to the substrate o-nitrophenyl beta-D-galactoside. All of these events occur when a cea(-)kil(+)imm(+) plasmid is present and none does when the plasmid is cea(+)kil(-)imm(+), so the damage can be attributed solely to the Kil function and not to the presence of colicin. However, cells carrying a cea(+)kil(-)imm(-) plasmid are killed upon induction, apparently by action of endogenous colicin on the nonimmune cytoplasmic membrane. The pattern of accompanying physiological damage is distinguished from the kil(+)-associated damage by an enhancement of alpha-methyl glucoside uptake and accumulation and efflux of alpha-methyl glucoside 6-phosphate and by an absence of the alteration in membrane permeability for o-nitrophenyl beta-D-galactoside. These features are typical of colicin E1 action on the membrane. The induced damage is not prevented by trypsin and occurs in cells of a strain specifically tolerant to exogenous colicin E1, indicating that the attack is from inside the cell.

Macromolecular syntheses in an Escherichia coli adk mutant.

Preferential inhibition by high temperatures of synthesis of newly induced enzymes in Escherichia coli K-12 CR341T28 adk is only apparent; syntheses of all macromolecules cease simultaneously.