We tested the effect of systematic destruction of all three lac operators of the chromosomal lac operon of Escherichia coli on repression by Lac repressor. Absence of just one ‘pseudo‐operator’ O2 or O3 decreases repression by wild‐type tetrameric Lac repressor approximately 2‐ to 3‐fold; absence of both ‘pseudo‐operators’ decreases repression greater than 50‐fold. O1 alone represses under these conditions only approximately 20‐fold. Dimeric active Lac repressor (iadi) represses the wild‐type lac operon to about the same low extent. This indicates that cooperative interaction between lac operators is due to DNA loop formation mediated by tetrameric Lac repressor. Under conditions where loop formation is impossible, occupation of O3 but not of O2 may lead to weak repression. This suggests that under these conditions CAP activation may be inhibited and that stopping transcription at O2 does not significantly contribute to repression.
Repression of the lac promoter may be achieved in two different ways: either by interference with the action of RNA polymerase or by interference with CAP activation. We investigated cooperative repression of the Escherichia coli lac operon by systematic conversion of its three natural operators (O1, O2 and O3) on the chromosome. We find that cooperative repression by tetrameric Lac repressor increases with both quality and proximity of the interacting operators. A short distance of 92 bp allows effective repression by two very weak operators (O3, O3). The cooperativity of lac operators is discussed in terms of a local increase of repressor concentration. This increase in concentration depends on flexible DNA which allows loop formation.
Much of the information about the function of D. melanogaster genes has come from P-element mutagenesis. The major drawback of the P element, however, is its strong bias for insertion into some genes (hotspots) and against insertion into others (coldspots). Within genes, 59-UTRs are preferential targets. For the successful completion of the Drosophila Genome Disruption Project, the use of transposon vectors other than P will be necessary. We examined here the suitability of the Minos element from Drosophila hydei as a tool for Drosophila genomics. Previous work has shown that Minos, a member of the Tc1/mariner family of transposable elements, is active in diverse organisms and cultured cells; it produces stable integrants in the germ line of several insect species, in the mouse, and in human cells. We generated and analyzed 96 Minos integrations into the Drosophila genome and devised an efficient ''jumpstarting'' scheme for production of single insertions. The ratio of insertions into genes vs. intergenic DNA is consistent with a random distribution. Within genes, there is a statistically significant preference for insertion into introns rather than into exons. About 30% of all insertions were in introns and 55% of insertions were into or next to genes that have so far not been hit by the P element. The insertion sites exhibit, in contrast to other transposons, little sequence requirement beyond the TA dinucleotide insertion target. We further demonstrate that induced remobilization of Minos insertions can delete nearby sequences. Our results suggest that Minos is a useful tool complementing the P element for insertional mutagenesis and genomic analysis in Drosophila. O NE of the main goals of modern genetics is to link the many thousands of genes identified through the sequencing of whole genomes of model organisms to gene function. The most powerful technique for this purpose so far has been transgenesis with mobile elements. This technique is a means to disrupt, overexpress, or misexpress single genes to identify expression patterns and also to characterize genetic pathways and their interactions. One of the main advantages of insertional mutagenesis over the classical method of chemical mutagenesis is the ease with which the targeted gene can be identified, since it carries an inserted tag.The P element was the first mobile element that enabled germ-line transformation of an insect species (Rubin and Spradling 1982). Since then, thousands of single P-element insertions causing lethality, semilethality, sterility, semisterility, and visible phenotypes have been created and analyzed in Drosophila (Cooley et al.
Gel‐filtration experiments indicate that a peptide (P2) composed of the basic region of GCN4 fused to the leucine heptad repeats of Lac repressor forms tetrameric aggregates. Gel‐shift experiments were performed to determine the orientation of the helices in the tetrameric P2 aggregate. Sandwich‐complex formation of peptide P2 with two DNA fragments containing two symmetrical CRE binding sites (5′‐ATGACGTCAT‐3′) at a distance of 21 bp suggests antiparallel aggregation of the Lac leucine heptad repeats. Thus, we conclude that the leucine heptad repeats of Lac repressor have the ability to form homomeric 4‐helical bundles with an antiparallel arrangement of the helices. This topology enables the two DNA fragments in the sandwich complexes to be held together by two tetramers of peptide P2. Replacement of the uncharged amino acids of the helical g and e positions of peptide P2 by the corresponding charged residues of GCN4 (peptide P4) results in a dimeric and parallel aggregation of the leucine heptad repeats, and consequently abolishes the potential to form sandwich structures. Similarly, a hybrid Lac repressor in which the GCN4 leucine zipper replaces the natural Lac leucine heptad repeats forms dimers only. It regains the ability to form tetramers when the charged amino acids in helical positions g and e are replaced by uncharged alanines.
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