Growth rate-dependent expression of thetrpoperon inEscherichia coli

Biochemical pathways and mechanisms nitrogen, amino acid, and carbon metabolism

For both nitrogen and carbon metabolism there exist specific regulatory mechanisms to enable cells to assimilate a wide variety of nitrogen and carbon sources. Superimposed are regulatory circuits, the so called nitrogen and carbon catabolite regulation, to allow for selective use of "rich" sources first and "poor" sources later. Evidence points to the importance of specific regulatory mechanisms for short term adaptations, while generalized control circuits are used for long term modulation of nitrogen and carbon metabolism. Similarly a variety of regulatory mechanisms operate in amino acid metabolism. Modulation of enzyme activity and modulation of enzyme levels are the outstanding regulatory mechanisms. In prokaryotes, attenuation and repressor/operator control are predominant, besides a so called "metabolic control" which integrates amino acid metabolism into the overall nutritional status of the cells. In eukaryotic cells compartmentation of amino acid metabolites as well as of part of the pathways becomes an additional regulatory factor; pathway specific controls seem to be rare, but a complex regulatory network, the "general control of amino acid biosynthesis", coordinates the synthesis of enzymes of a number of amino acid biosynthetic pathways.

Directed mutagenesis of a regulatory palindromic sequence upstream from the Brevibacterium lactofermentum tryptophan operon

A cloned 9.6-kb fragment of Brevibacterium lactofermentum DNA, carrying the entire trp operon and upstream regulatory sequences, produces a polycistronic 7.0-kb transcript as detected by hybridization with an internal probe. The transcription start point (tsp) was identified by S1 mapping. The operator-promoter (OP) region subcloned in Escherichia coli and B. lactofermentum promoter-probe vectors exhibited about tenfold higher activity in B. lactofermentum. A 14-bp wild-type (wt) palindrome located at bp -15 to -28 was mutated to change the conserved adenine adjacent to the axis of symmetry. The wt and mutated OP regions were coupled to the amy reporter gene (encoding alpha-amylase [Amy]) or to the 5' region (trpE and trpG genes) of the trp operon, for expression studies. Constructions with the regulatory signals coupled to the wt trpE-trpG genes were introduced in a B. lactofermentum trpE mutant (obtained by gene disruption). The mutation in the palindrome did not affect the promoter activity in B. lactofermentum or E. coli when grown in minimal medium. Tryptophan repressed the OP as assayed by the anthranilate synthase (AS) activity in B. lactofermentum in constructions with the wt OP region, but surprisingly, caused a large stimulation of either AS or the Amy reporter activity, in constructions with the mutated OP. The palindromic sequence is, therefore, involved in a dual repression-stimulation control of expression of the trp operon.