Identification of the site of autophosphorylation of the bacterial protein kinase/phosphatase NRII

Previous studies have established that the Escherichia coli protein kinase/phosphatase nitrogen regulator II (NRII also known as NtrB) becomes autophosphorylated on a histidine residue when incubated with ATP. We show that the major site at which NRII was autophosphorylated was contained within a peptide consisting of amino acid residues 136-142 of NRII, and thus probably corresponds to His-139. A minor site of phosphorylation, accounting for about 2% of the phosphate in NRII-P, was found in a peptide that corresponds to residues 158-169.     

Phosphate sensing in <Emphasis Type="Italic">Synechocystis</Emphasis> sp. PCC 6803: SphU and the SphS–SphR two-component regulatory system

The Pho regulon is controlled by the histidine kinase-response regulator pair SphS–SphR in many cyanobacteria and up-regulation of the Pho regulon can be monitored by measuring alkaline phosphatase activity. However, the mechanism regulating signal transduction between SphS and SphR has not been described. We have created a cyanobacterial strain allowing the introduction of mutations into the transmitter domain of SphS. Mutations at Thr-167, adjacent to the H motif of SphS, introduce elevated alkaline phosphatase activity in the presence of phosphate and an enhancement of alkaline phosphatase activity, when compared to the control strain, in phosphate-limiting media. SphU acts as a negative regulator of the SphS–SphR system in Synechocystis sp. PCC 6803 and we show that constitutive alkaline phosphatase activity in the absence of SphU requires signal transduction through SphS and SphR. However, constitutive activity in the absence of SphU is severely attenuated in the ΔSphU:SphS-T167N mutant. Our data suggest that Thr-167 contributes to the mechanism underlying regulation by SphU. We have also assembled a deletion mutant system allowing the introduction of mutations into SphR and show that Gly-225 and Trp-236, which are both conserved in SphR from cyanobacteria, are essential for activation of the Pho regulon under phosphate-limiting conditions.     

Genetic and biochemical analysis of phosphatase activity of Escherichia coli NRII (NtrB) and its regulation by the PII signal transduction protein

Mutant forms of Escherichia coli NRII (NtrB) were isolated that retained wild-type NRII kinase activity but were defective in the PII-activated phosphatase activity of NRII. Mutant strains were selected as mimicking the phenotype of a strain (strain BK) that lacks both of the related PII and GlnK signal transduction proteins and thus has no mechanism for activation of the NRII phosphatase activity. The selection and screening procedure resulted in the isolation of numerous mutants that phenotypically resembled strain BK to various extents. Mutations mapped to the glnL (ntrB) gene encoding NRII and were obtained in all three domains of NRII. Two distinct regions of the C-terminal, ATP-binding domain were identified by clusters of mutations. One cluster, including the Y302N mutation, altered a lid that sits over the ATP-binding site of NRII. The other cluster, including the S227R mutation, defined a small surface on the "back" or opposite side of this domain. The S227R and Y302N proteins were purified, along with the A129T (NRII2302) protein, which has reduced phosphatase activity due to a mutation in the central domain of NRII, and the L16R protein, which has a mutation in the N-terminal domain of NRII. The S227R, Y302N, and L16R proteins were specifically defective in the PII-activated phosphatase activity of NRII. Wild-type NRII, Y302N, A129T, and L16R proteins bound to PII, while the S227R protein was defective in binding PII. This suggests that the PII-binding site maps to the "back" of the C-terminal domain and that mutation of the ATP-lid, central domain, and N-terminal domain altered functions necessary for the phosphatase activity after PII binding.     

The ntr genes of Escherichia coli activate the hut and nif operons of Klebsiella pneumoniae

Regulation of the synthesis of glutamine synthetase and of the arginine and glutamine transport systems (Ntr phenotype) in Salmonella have been shown to require two regulatory genes on the C-terminal side of the glnA gene (McFarland et al., 1981). We have cloned a HindIII-EcoRI DNA fragment from Escherichia coli coding for analogous properties with respect to the Ntr phenotype in E. coli. A plasmid containing this E. coli DNA fragment joined to another fragment carrying a cyanobacterial glnA gene (but no functional regulatory genes) was introduced into a Klebsiella pneumoniae mutant with a Gln-Ntr- phenotype, i.e., which could not derepress nitrogenase. The cyanobacterial gene made the Klebsiella strain Gln+ and the E. coli DNA fragment made the strain Ntr+, including the ability to derepress nitrogenase fully. Thus the products of the glnA-linked ntr genes of E. coli can regulate expression of the Ntr-dependent genes of Klebsiella.