Applications of combined DNA microarray and chromosome sorting technologies.

The sequencing of the human genome has led to the availability of an extensive mapped clone resource that is ideal for the construction of DNA microarrays. These genomic clone microarrays have largely been used for comparative genomic hybridisation studies of tumours to enable accurate measurement of copy number changes (array-CGH) at increased resolution. We have utilised these microarrays as the target for chromosome painting and reverse chromosome painting to provide a similar improvement in analysis resolution for these studies in a process we have termed array painting. In array painting, chromosomes are flow sorted, fluorescently labelled and hybridised to the microarray. The complete composition and the breakpoints of aberrant chromosomes can be analysed at high resolution in this way with a considerable reduction in time, effort and cytogenetic expertise required for conventional analysis using fluorescence in situ hybridisation. In a similar way, the resolution of cross-species chromosome painting can be improved and we present preliminary observations of the organisation of homologous DNA blocks between the white cheeked gibbon chromosome 14 and human chromosomes 2 and 17.

Structure/function analysis of the PII signal transduction protein of Escherichia coli: genetic separation of interactions with protein receptors.

The PII protein, encoded by glnB, is known to interact with three bifunctional signal transducing enzymes (uridylyltransferase/uridylyl-removing enzyme, adenylyltransferase, and the kinase/phosphatase nitrogen regulator II [NRII or NtrB]) and three small-molecule effectors, glutamate, 2-ketoglutarate, and ATP. We constructed 15 conservative alterations of PII by site-specific mutagenesis of glnB and also isolated three random glnB mutants affecting nitrogen regulation. The abilities of the 18 altered PII proteins to interact with the PII receptors and the small-molecule effectors 2-ketoglutarate and ATP were examined by using purified components. Results with certain mutants suggested that the specificity for the various protein receptors was altered; other mutations affected the interaction with all three receptors and the small-molecule effectors to various extents. The apex of the large solvent-exposed T loop of the PII protein (P. D. Carr, E. Cheah, P. M. Suffolk, S. G. Vasudevan, N. E. Dixon, and D. L. Ollis, Acta Crytallogr. Sect. D 52:93-104, 1996), which includes the site of PII modification, was not required for the binding of small-molecule effectors but was necessary for the interaction with all three receptors. Mutations altering residues of this loop or affecting the nearby B loop of PII, which line a cleft between monomers in the trimeric PII, affected the interactions with protein receptors and the binding of small-molecule ligands. Thus, our results support the predictions made from structural studies that the exposed loops of PII and cleft formed at their interface are the sites of regulatory interactions.

Altered bioelectrical and mechanical activities of rat gastric smooth muscle preparations by inhibiting enterocytogenin.

Inhibiting enterocytogenin (IEG), a 4.5 kDa nucleopeptide isolated from pig intestinal mucosa induced dose-dependent alterations in the spontaneous contractile and bioelectric activities of rat gastric smooth muscle when applied at 10(-8) to 10(-4) M. Two separate phases were apparent in the effects observed, an initial contractile phase followed by a relaxation phase. The depolarization and the related contraction were reduced by amiloride and to a lesser extent by nifedipine. This reduction resulted in a corresponding decrease in the magnitude of the subsequent relaxation phase. Charybdotoxin and apamin caused a statistically significant decrease in the hyperpolarization and the magnitude of the relaxation phase and increased the duration of the contractile phase. On a caffeine or noradrenaline background the effects induced by IEG were diminished, suggesting that they are mediated through Ca2+ release from the intracellular Ca2+ stores. We hypothesize that the depolarization induced by IEG involves activation of the voltage-dependent Ca2+ channels with subsequent stimulation of the Ca(2+)-dependent K+ channels and late development of hyperpolarization.

The Escherichia coli PII signal transduction protein is activated upon binding 2-ketoglutarate and ATP.

Nitrogen regulation of transcription in Escherichia coli requires sensation of the intracellular nitrogen status and control of the dephosphorylation of the transcriptional activator NRI-P. This dephosphorylation is catalyzed by the bifunctional kinase/phosphatase NRII in the presence of the dissociable PII protein. The ability of PII to stimulate the phosphatase activity of NRII is regulated by a signal transducing uridylyltransferase/uridylyl-removing enzyme (UTase/UR), which converts PII to PII-UMP under conditions of nitrogen starvation; this modification prevents PII from stimulating the dephosphorylation of NRI approximately P. We used purified components to examine the binding of small molecules to PII, the effect of small molecules on the stimulation of the NRII phosphatase activity by PII, the retention of PII on immobilized NRII, and the regulation of the uridylylation of PII by the UTase/UR enzyme. Our results indicate that PII is activated upon binding ATP and either 2-ketoglutarate or glutamate, and that the liganded form of PII binds much better to immobilized NRII. We also demonstrate that the concentration of glutamine required to inhibit the uridylyltransferase activity is independent of the concentration of 2-ketoglutarate present. We hypothesize that nitrogen sensation in E. coli involves the separate measurement of glutamine by the UTase/UR protein and 2-ketoglutarate by the PII protein.

Preliminary X-ray diffraction analysis of crystals of the PII protein from Escherichia coli.

PII protein, which carries metabolic signals regulating the transcription and activity of glutamine synthetase in nitrogen assimilation in Escherichia coli, has been crystallized in space group P2(1) with a = 47.8 A, b = 62.9 A, c = 52.8 A and beta = 100.3 degrees and space group P2(1)2(1)2(1) with a = 52.2 A. b = 64.9 A and c = 100.1 A. Both the monoclinic crystals, which diffract beyond 3.0 A, and the orthorhombic crystals, which diffract beyond 2.5 A, probably have three molecules of 12,400 Da each in the crystallographic asymmetric unit.

Reversible uridylylation of the Escherichia coli PII signal transduction protein regulates its ability to stimulate the dephosphorylation of the transcription factor nitrogen regulator I (NRI or NtrC).

We have reconstituted the signal transduction system responsible for the negative regulation of the transcription of the Escherichia coli glnA gene, encoding glutamine synthetase, by glutamine. This signal transduction system consists of four proteins: the transcription factor NRI (NtrC), which activates glnA transcription when it is phosphorylated, the kinase/phosphatase protein NRII (NtrB) that directly controls the extent of NRI phosphorylation, the PII signal transduction protein that controls the phosphatase activity of NRII, and the uridylyltransferase/uridylyl-removing (UTase/UR) enzyme that is regulated by glutamine and controls the activity of PII. In the reconstituted system, the removal of uridylyl groups from the PII protein, catalyzed by the UTase/UR protein in the presence of glutamine, resulted in the stimulation of NRI approximately P dephosphorylation. In contrast, the uridylylated form of the PII protein had no discernible effect on NRI phosphorylation. The uridylylation of the trimeric PII protein by the monomeric UTase/UR protein is a non-cooperative reaction in which the partially modified species accumulated and were readily observed. Partially modified PII trimers were partially active in stimulating the dephosphorylation of NRI approximately P. Thus, both the PII-UTase/UR and PII-NRII interactions display the continuous variability characteristic of rheostats as opposed to the binary variability characteristic of toggle switches.

Effect of mutations in Escherichia coli glnL (ntrB), encoding nitrogen regulator II (NRII or NtrB), on the phosphatase activity involved in bacterial nitrogen regulation.

We examined the effects of mutations in glnL, encoding the signal-transducing kinase/phosphatase nitrogen regulator II (NRII), on the regulated phosphatase activity involved in nitrogen regulation. With wild-type NRII, this phosphatase activity was only observed in the presence of the signal transduction protein II (PII). Three different glnL mutations result in altered NRII proteins that had phosphatase activity in the absence of PII. The most active of these contained an alteration of the site of NRII autophosphorylation, histidine 139, to asparagine (H139N). The phosphatase activity of the NRII-H139N protein was further stimulated by the PII protein and by ATP. This suggests that the PII protein is not directly involved in a catalytic step of the regulated phosphatase activity but rather plays a regulatory role. We also measured the effect on the regulated phosphatase activity of alterations at conserved residues in the kinase/phosphatase domain of NRII and the effect of deleting the non-conserved N-terminal domain of NRII. For this we used fusion proteins containing the Escherichia coli maltose-binding protein (MBP) linked to the protein of interest. A protein consisting of MBP linked to wild-type NRII was a less active kinase than was wild-type NRII but in the presence of PII had wild-type phosphatase activity. A protein consisting of MBP linked to just the C-terminal domain of wild-type NRII had kinase activity but lacked phosphatase activity. Alterations at the highly conserved residues Asp-287, Gly-289, and Gly-291 in NRII affected both activities. A fusion of MBP to the NRII-H139N protein lacked kinase activity but had phosphatase activity in the absence of PII. Thus, while the kinase and phosphatase activities of NRII could be genetically separated, some of the highly conserved residues in the C-terminal domain of NRII (Asp-287, Gly-289, Gly-291) are apparently important for both activities.

Biological effects of a novel intestinal peptide--inhibiting enterocytogenin on cultured 3T3 mouse fibroblasts and L5178Y mouse lymphoma cells.

The effects of a new intestinal peptide, inhibiting enterocytogenin (IEG) derived from pig intestinal mucosa were studied in vitro on 3T3 mouse fibroblasts and L5178Y mouse lymphoma cell line. IEG caused considerable growth inhibition together with specific morphological changes, necrotic effects as well as formation of monolayers at the highest concentration applied (1000 micrograms/ml). A biologically active fraction (IEG-BAF) derived by further purification of IEG by gel-filtration, proved to possess most of the described activity. The concentrations of IEG and IEG-BAF inhibiting the growth of L5178Y lymphoma cells by 50% (IC50 values) were calculated to be 759 micrograms/ml and 192 micrograms/ml, respectively. IEG-BAF has a molecular mass of 4450 +/- 180 Da and is most probably a peptidylnucleotidate as revealed by spectral analysis.

Sensory components controlling bacterial nitrogen assimilation.

In enteric bacteria, the transcription of the Ntr regulon is regulated by a signal transduction system that measures and transmits information on the nitrogen status of the cell. Four of the components of this signal transduction apparatus have been previously identified, and the roles of these are known, to a first approximation, from studies with purified components. The sensor is a uridylyltransferase/uridylyl-removing enzyme (UTase/UR) that controls the uridylylation state of the PII protein. PII indirectly regulates the transcription of the Ntr regulon by acting through the kinase/phosphatase protein NRII. In the absence of unmodified PII, NRII autophosphorylates on a histidine residue, and these phosphoryl groups are transferred to the transcription factor NRI, resulting in the conversion of NRI to the form able to activate transcription. In the presence of PII and NRII, NRI approximately P is rapidly dephosphorylated, preventing the activation of Ntr transcription. This PII-dependent dephosphorylation of NRI approximately P is referred to as the regulated phosphatase activity. In this report, we describe improved methods for the purification of the UTase/UR and PII, and the crystallization of PII. We also present improved methods for the assay of the activities of the UTase/UR protein and PII. The results of our assays indicate that purified PII is effective in eliciting the regulated phosphatase activity, but does not affect the autophosphorylation of NRII or affect the transfer of phosphoryl groups from NRII approximately P to NRI. In addition, we demonstrate that the elicitation of the regulated phosphatase activity by PII is strongly dependent on the ratio of NRI approximately P to NRI, and that the isolated N-terminal domain of NRI, once phosphorylated, is dephosphorylated by the regulated phosphatase activity.

Mechanism of autophosphorylation of Escherichia coli nitrogen regulator II (NRII or NtrB): trans-phosphorylation between subunits.

Nitrogen regulator II (NRII or NtrB) is a homodimeric signal-transducing protein kinase/phosphatase responsible for the transcriptional regulation of the Ntr regulon in Escherichia coli. NRII is a member of a large family of proteins that are part of the related two-component signal transduction systems. We studied the mechanism of NRII autophosphorylation by using purified components. Alteration of the site of NRII autophosphorylation to asparagine (H-139-->N [H139N]) or deletion of the C-terminal 59 amino acids of NRII (ter291) resulted in proteins that were not autophosphorylated upon incubation with ATP. Alteration of glycine 313 to alanine resulted in a protein (G313A) that was phosphorylated to a lesser extent than the wild-type protein. Unlike wild-type NRII and H139N, G313A could not be efficiently cross-linked to [alpha-32P]ATP, suggesting that the G313A mutation affects nucleotide binding. Fusion of maltose-binding protein (MBP) to the N-terminal end of NRII resulted in a protein (MBP-NRII) that autophosphorylated normally. We developed a procedure for forming mixed dimers in vitro from these proteins. In mixed dimers consisting of MBP-NRII and H139N, only the MBP-NRII subunit is phosphorylated. In contrast, in mixed dimers consisting of MBP-NRII and G313A, phosphorylation is predominantly on the G313A subunit. We also demonstrated that the G313A and H139N proteins could complement for the autophosphorylation reaction when they were treated so as to permit the formation of mixed dimers and that the wild-type and H139N proteins could phosphorylate the ter291 protein. These results indicate that the autophosphorylation reaction occurs within the dimer by a trans, intersubunit mechanism in which one subunit binds ATP and phosphorylates the other subunit.

Altered levels of phosphatidylinositol phospholipase C activity in rat liver cells in response to insulin, epinephrine, acetylcholine and bacterial phospholipase C.

Rat liver cells were homogenized and subsequently fractionated by a simplified method based on microfiltration, which proved to give a high recovery of membrane-bound phosphatidylinositol phospholipase C (PI-PLC) activity. The effects of insulin, acetylcholine (AC), epinephrine (EN) and bacterial phospholipase C (bPLC) on the PI-PLC activity were studied after in vitro treatment of isolated membranes or after in situ application in rat liver. A dose-dependent increase of membranous PI-PLC (up to 3-fold) and corresponding 36 to 72% decline of the cytosolic activity were established upon treatment with supraphysiological doses of insulin or with bPLC, respectively. AC induced a biphasic response with a maximal stimulation in the micromolar range. On the other hand EN promoted a slight but significant dose-dependent inhibition of PI-PLC in both cytosol and membranes. Sodium fluoride was also a potent inhibitor of the membrane-associated PI-PLC with an EC50 value of about 5 mM. The combined assay with NaF and EN revealed no additivity between their inhibitory effects, suggesting a common step in the mechanism(s) of inhibition caused by the two agents. The stimulatory effects of insulin and AC were partially reduced by soluble cytosolic factors, which still remain to be identified. When insulin and AC were applied in combination in the presence of cytosol, this resulted in a 56% inhibition of PI-PLC below the control level.