Regeneration of catalytic activity of glutamine synthetase mutants by chemical activation: exploration of the role of arginines 339 and 359 in activity.

In order to understand the nature of ATP and L-glutamate binding to glutamine synthetase, and the involvement of Arg 339 and Arg 359 in catalysis, these amino acids were changed to cysteine via site-directed mutagenesis. Individual mutations (Arg-->Cys) at positions 339 and 359 led to a sharp drop in catalytic activity. Additionally, the Km values for the substrates ATP and glutamate were elevated substantially above the values for wild-type (WT) enzyme. Each cysteine was in turn chemically modified to an arginine "analog" to attempt to "rescue" catalytic activity by covalent modification; 2-chloroacetamidine (CA) (producing a thioether) and 2,2'-dithiobis (acetamidine)(DTBA) (producing a disulfide) were the reagents used to effect these chemical transformations. Upon reaction with CA, both R339C and R359C mutants showed a significant regain of catalytic activity (50% and 70% of WT, respectively) and a drop in Km value for ATP close to that for WT enzyme. With DTBA, chemically modified R339C had a greater kcat than WT glutamine synthetase, but chemically modified R359C only regained a small amount of activity. Modification with DTBA was quantitative for each mutant and each modified enzyme had similar Km values for both ATP and glutamate. The high catalytic activity of DTBA-modified R339C could be reversed to that of unmodified R339C by treatment with dithiothreitol, as expected for a modified enzyme containing a disulfide bond. Modification of each cysteine-containing mutant to a lysine "analog" was accomplished using 3-bromopropylamine (BPA).(ABSTRACT TRUNCATED AT 250 WORDS)

Control of cell division in Escherichia coli: regulation of transcription of ftsQA involves both rpoS and SdiA-mediated autoinduction.

The conditioning of culture medium by the production of growth-regulatory substances is a well-established phenomenon with eukaryotic cells. It has recently been shown that many prokaryotes are also capable of modulating growth, and in some cases sensing cell density, by production of extracellular signaling molecules, thereby allowing single celled prokaryotes to function in some respects as multicellular organisms. As Escherichia coli shifts from exponential growth to stationary growth, many changes occur, including cell division leading to formation of short minicells and expression of numerous genes not expressed in exponential phase. An understanding of the coordination between the morphological changes associated with cell division and the physiological and metabolic changes is of fundamental importance to understanding regulation of the prokaryotic cell cycle. The ftsQA genes, which encode functions required for cell division in E. coli, are regulated by promoters P1 and P2, located upstream of the ftsQ gene. The P1 promoter is rpoS-stimulated and the second, P2, is regulated by a member of the LuxR subfamily of transcriptional activators, SdiA, exhibiting features characteristic of an autoinduction (quorum sensing) mechanism. The activity of SdiA is potentiated by N-acyl-homoserine lactones, which are the autoinducers of luciferase synthesis in luminous marine bacteria as well as of pathogenesis functions in several pathogenic bacteria. A compound(s) produced by E. coli itself during growth in Luria Broth stimulates transcription from P2 in an SdiA-dependent process. Another substance(s) enhances transcription of rpoS and (perhaps indirectly) of ftsQA via promoter P1. It appears that this bimodal control mechanism may comprise a fail-safe system, such that transcription of the ftsQA genes may be properly regulated under a variety of different environmental and physiological conditions.

Transcriptional regulation of bioluminesence genes from Vibrio fischeri.

The phenomenon of cell-density-dependent control of gene expression, called autoinduction, has long been a subject of interest and investigation in bioluminescent marine bacteria. It is now becoming clear that many other bacteria, including animal and plant pathogens, use an autoinduction mechanism to regulate a variety of functions. Cell-density-dependent gene expression provides an excellent example of multicellular behaviour in the prokaryotic kingdom where a single cell is able to communicate and sense when a minimal population unit, a 'quorum' of bacteria, is achieved in order for certain behaviour of the population to be performed efficiently. Regulation of bacterial bioluminescence has been studied for many years and represents the best model system for understanding the mechanism of cell-density-dependent gene expression. This review will focus on transcriptional regulation of the Vibrio fischeri luminescence genes emphasizing the role of the transcriptional activator LuxR and possible autoinduction mechanisms that occur in E. coli. Alternative views and opinions regarding the molecular details of the autoinduction mechanism will be discussed.

Effect of metal-ligand mutations on phosphoryl transfer reactions catalyzed by Escherichia coli glutamine synthetase.

Glutamine synthetase (GS) converts glutamate to glutamine in the presence of ATP and ammonia and requires two divalent metal ions, designated n1 and n2, for catalysis. The first intermediate, gamma-glutamyl phosphate, is formed during catalysis by the transfer of the gamma-phosphate of ATP to the gamma-carboxylate of glutamate. Efficient phosphoryl transfer between these two negatively charged moieties is thought to be mediated by the n2 metal. To explore the role of the n2 metal in catalysis, histidine 269, a ligand to the n2 metal, was changed to aspartate, asparagine, glutamate, and glutamine by site-directed mutagenesis. All of the mutants bind two manganese ions as determined by EPR titration. The mutations had little effect on the substrate Km's except in the case of H269E which exhibited a Km Glu = 92 mM, a 1000-fold increase compared to that for WT (Km Glu = 70 microM). The ability of these mutants to catalyze phosphoryl transfer to glutamate or to the inhibitor phosphinothricin was examined by rapid quench kinetic experiments. Phosphorylated phosphinothricin was detected by 31P NMR and shown to be produced by both mutants and WT. The rate of phosphoryl transfer to PPT for H269E is reduced 100-fold (0.030 s-1) compared to WT (8 s-1). The extra negative charge around the n2 metal ion contributed by glutamate 269 severely reduces the ability of the n2 metal to mediate efficient glutamate binding in the presence of negatively charged ATP and weakens the interactions between metal ion and the reactants in the transition state, thus resulting in a lower rate of phosphoryl transfer.

Analogs of the autoinducer of bioluminescence in Vibrio fischeri.

The enzymes for luminescence in Vibrio fischeri are induced only when a sufficient concentration of a metabolic product (autoinducer) specifically produced by this species accumulates. It has previously been shown that the autoinducer is 3-oxohexanoyl homoserine lactone and that it enters the cells by simple diffusion. To further study the mechanism of induction, we have synthesized several analogs of the autoinducer. The analogs were tested with V. fischeri for their inducing activity and for their ability to inhibit the action of the natural autoinducer. The compounds were found to display various combinations of inducing and inhibiting abilities. None of the compounds tested appeared to have any effect on cells of V. harveyi strain MAV or Photobacterium leiognathi strain 721, but several of the compounds decreased light output by P. phosphoreum strain 8265. These studies show that 1) the site of action of the autoinducer is not highly sterically constrained 2) the autoinducers of other species of luminous bacteria are likely to be quite different from that of V. fischeri and 3) a simple mode in which one autoinducer molecule binds to a single receptor protein site and thus initiates luciferase synthesis is inadequate. The analogs should prove useful in the study of the binding site and mode of action of the autoinducer.

Inhibition of Escherichia coli glutamine synthetase by alpha- and gamma-substituted phosphinothricins.

We have investigated the inhibition of Escherichia coli glutamine synthetase (GS) with alpha- and gamma-substituted analogues of phosphinothricin [L-2-amino-4-(hydroxymethylphosphinyl)butanoic acid (PPT)], a naturally occurring inhibitor of GS. These compounds display inhibition of bacterial GS that is competitive vs L-glutamate, with Ki values in the low micromolar range. At concentrations greater than Ki the phosphinothricins caused time-dependent loss of enzyme activity, while dilution after enzyme inactivation resulted in recovery of enzyme activity. ATP was required for inactivation; the nonhydrolyzable ATP analogue AMP-PCP failed to support inhibition of GS by the phosphinothricins. The binding of these inhibitors to the enzyme was also characterized by measurement of changes in protein fluorescence, which provided similar inactivation rate constants k1 and k2 for the entire series of compounds. Rate constants koff for recovery were also determined by fluorescence measurement and were comparable for both PPT and the gamma-hydroxylated analogue GHPPT and significantly greater for the alpha- and gamma-alkyl-substituted compounds. Electron paramagnetic resonance spectra provided information on the interaction of the phosphinothricins with the manganese form of the enzyme in the absence of ATP, and significant binding was observed for PPT and GHPPT. 31P NMR experiments confirmed that enzyme inactivation is accompanied by hydrolysis of ATP, although phosphorylated phosphinothricins could not be detected in solution. The kinetic behavior of these compounds is consistent with a mechanism involving inhibitor phosphorylation, followed by release from the active site and simultaneous hydrolysis to form Pi and free inhibitor.