Suppression of polarity of insertion mutations within the gal operon of E. coli.

Summary Phenotypic revertants of galOP::IS1 and galOP::IS2 mutations have been isolated after mutagenesis with nitrosoguanidine, they are probably caused by mutations in gene suA. The polarity suppressor mutations described in this study and a known mutation in gene suA isolated by D. Morse (Morse and Guertin, 1972) suppress polarity caused by IS1 more effectively than that caused by IS2 or IS4. Furthermore, suppressibility is influenced by the site and orientation of IS integration.The synthesis of the three enzymes in galOP::IS suA double mutants is constitutive and the ratio of the three enzymes is altered in comparison to the wild type. The reasons for constitutive synthesis of the galactose enzymes and for the altered ratio of enzyme synthesis are discussed.     

Suppression of polarity in the gal operon by ultraviolet irradiation.

The polarity of nonsense mutations in the galE gene of Escherichia coli can be suppressed by rho mutations (O. Reyes et al., J. Bacteriol. 126:1108-1112, 1976). We show here that this polarity can also be suppressed by ultraviolet irradiation. The effect is analogous to that already observed for polar nonsense mutations in phi X174 and S13 and suggests that ultraviolet irradiation suppression of polarity may be a general phenomenon.     

Disco-ordinate expression of the Escherichia coli gal operon after prophage lambda induction.

EcoRI endonuclease crystallizes in space group C2 with unit cell parameters $\text{a = 209}\text{A}\text{?}\text{, b = 129}\text{A}\text{?}\text{, c = 50}\text{A}\text{?}\text{and}\text{β = 98.4 °}$. Four 29,000 molecular weight subunits per asymmetric unit would give a reasonable V_m value of 2.87 ų/dalton. EcoRI endonuclease is the first protein which recognizes a specific sequence of bases in DNA to be crystallized in a form suitable for high resolution structure analysis.     

O0 and strong-polar mutations in the gal operon are insertions

Summary Three dg phages carrying strong-polar mutations in the gal operon are denser than the corresponding phages carrying the wildtype gal operon or reversions of the mutations to the Gal ⁺ phenotype. The latter phages have the same density. It is concluded that these strong-polar mutations are insertions of DNA into the gal operon.The amount of inserted DNA is different in the three mutations and is calculated to be 450, 1,080 and 1,800 nucleotide pairs respectively.The strong-polar phenotype is also found in a mutant supplied by A. Taylor which carries a Mu-1 phage integrated into the transferase gene.     

Analysis of mutations in the ninR region of bacteriophage lambda that bypass a requirement for lambda N antitermination.

Two mutations in the ninR region of bacteriophage lambda that bypass a requirement for antitermination have been studied. One mutation, byp, has been cloned and mapped by marker rescue to a 417-base-pair segment in the ninR region of the genome. Analysis of the byp mutation by using promoter detection vectors, DNA sequencing, and S1 nuclease analysis showed that the byp mutation created a new promoter that transcribed gene Q. The second mutation analyzed was the deletion nin3. Sequence analysis revealed that 2,485 base pairs of the ninR region were removed, beginning within the ren gene and ending in an open reading frame termed ninG. The tR2 and tR3 terminators, and probably others, were removed by the nin3 deletion, thereby allowing the phage to be N independent and to grow in hosts defective for Nus antitermination factors.     

Interaction between lambda or phi80 prophage induction and gal operon expression

When Escherichia coli cells are cultivated with fucose on a rich medium giving rise to a strong catabolite repression, λh80 or φ80 prophage thermo-induction triggers a significant escape of the gal operon activity.     

Bacterial mutants able to partly suppress the effect of N mutations in bacteriophage lambda

A method is described whereby bacterial mutants (sun) may be selected which are able to specifically suppress mutations in the N gene of bacteriophage lambda. The sun mutations seem to be allelic to suA mutations, which suppress the polarity of nonsense codons, since suA mutants have all of the properties of sun mutants and both are genetically linked to the ilv gene. In the light of these experiments and recent data by others, models originally suggested to explain polarity in bacterial operons, are discussed with regard to their possible relevance to the mechanism of N action.     

Isolation and characterization of mutations in the bacteriophage lambda terminase genes.

The terminase enzyme of bacteriophage lambda is a hetero-oligomeric protein which catalyzes the site-specific endonucleolytic cleavage of lambda DNA and its packaging into phage proheads; it is composed of the products of the lambda Nul and A genes. We have developed a simple method to select mutations in the terminase genes carried on a high-copy-number plasmid, based on the ability of wild-type terminase to kill recA strains of Escherichia coli. Sixty-three different spontaneous mutations and 13 linker insertion mutations were isolated by this method and analyzed. Extracts of cells transformed by mutant plasmids displayed variable degrees of reduction in the activity of one or both terminase subunits as assayed by in vitro lambda DNA packaging. A method of genetically mapping plasmid-borne mutations in the A gene by measuring their ability to rescue various lambda Aam phages showed that the A mutations were fairly evenly distributed across the gene. Mutant A genes were also subcloned into overproducing plasmid constructs, and it was determined that more than half of them directed the synthesis of normal amounts of full-length A protein. Three of the A gene mutants displayed dramatically reduced in vitro packaging activity only when immature (uncut) lambda DNA was used as the substrate; therefore, these mutations may lie in the endonuclease domain of terminase. Interestingly, the putative endonuclease mutations mapped in two distinct locations in the A gene separated by a least 400 bp.     

Exclusion of bacteriophage T1 by bacteriophage lambda. I. Early exclusion requires lambda N gene product and host factors involved in N gene expression.

Two modes of exclusion of T1 by lambda are distinguished. "Early" exclusion depends on gene N, but not on gene Q. It is at least partially ineffective against T1am23. "Late" exclusion depends on gene Q and effects T1am23 as well as T1+. Early exclusion is a direct effect of N gene product, rather than N gene being required for the expression of some other lambda gene. Three host mutations, groN, nusA, and nusB, known to interfere with lambda replication by affecting N gene expression, also interfere with the ability of lambda to exclude T1.