Glucose permease of Escherichia coli. The effect of cysteine to serine mutations on the function, stability, and regulation of transport and phosphorylation

The glucose permease (IIGlc/IIIGlc complex) of the bacterial phosphotransferase system mediates sugar transport across the cytoplasmic membrane concomitant with sugar phosphorylation. It contains 3 cysteine residues, of which Cys-204 and Cys-326 are localized in the hydrophobic part and Cys-421 in the hydrophilic part of the IIGlc subunit. The cysteines were replaced, one at a time, by serines, and the effect of these mutations on stability, regulation, and catalytic properties of IIGlc was investigated in vivo and in vitro. Cys-204 and Cys-326 are not required for catalytic function and are not involved in the membrane potential-dependent regulation of IIGlc activity (Robillard, G. T., and Konings, W. N. (1982) Eur. J. Biochem. 127, 597-604). Replacement of these cysteines by serines results, however, in reduced stability of IIGlc in vivo (C204S) and in vitro (C204S and C326S), indicating that these substitutions in a hydrophobic environment can destabilize the protein structure. Cys-421 is absolutely required for transport and phosphorylation of glucose. C421S can neither be phosphorylated by phospho-IIIGlc nor catalyze the phosphoryl exchange between [14C] glucose and glucose 6-phosphate at equilibrium. C421S does not interfere with the activity of simultaneously expressed wild-type IIGlc. Unexpectedly C421S and wild-type IIGlc support growth on maltose of Escherichia coli ZSC112L (Curtis, S. J., and Epstein, W. (1975) J. Bacteriol. 122, 1189-1199), a strain which otherwise does not grow on this disaccharide as the only carbon source. C421S appears to facilitate the efflux of a growth inhibiting intermediate (glucose?) of maltose. Wild-type IIGlc catalyzes the intracellular phosphorylation of glucose derived from maltose. It is concluded that the cytoplasmic domain of IIGlc interacts with IIIGlc, the cytoplasmic subunit of the glucose permease, and also participates in phosphorylation of glucose, and that phosphorylation occurs independently of transport, although transport of glucose by wild-type IIGlc cannot occur without concomitant phosphorylation.     

A functional protein hybrid between the glucose transporter and the N-acetylglucosamine transporter of Escherichia coli.

The glucose and N-acetylglucosamine-specific transporters (IIGlc/IIIGlc and IIGlcNAc) of the bacterial phosphotransferase system mediate carbohydrate uptake across the cytoplasmic membrane concomitant with substrate phosphorylation. The two transporters have 40% amino acid sequence identity. Eight chimeric proteins between the two transporters were made by gene reconstruction. All hybrid proteins could be expressed, some inhibited cell growth, and one was active. The active hybrid transporter consists of the transmembrane domain (residues 1-386) of the IIGlc subunit and the two hydrophilic domains (residues 370-648) of IIGlcNAc. The N-terminal hydrophilic domain of IIGlcNAc contains the transiently phosphorylated cysteine-412. The hybrid protein is specific for glucose, which indicates that the sugar specificity determinant is in the transmembrane domain and that the cysteine from which the phosphoryl group is transferred to the substrate is not part of the binding site. The protein sequence (LKTPGRED) at which the successful fusion occurred has the characteristic properties of an interdomain oligopeptide linker (Argos, P., 1990, J. Mol. Biol. 211, 943-958).     

Glucose permease of Escherichia coli. Purification of the IIGlc subunit and functional characterization of its oligomeric forms

The membrane subunit (IIGlc) of the glucose permease has been purified from overproducing Escherichia coli. About 2 mg of pure protein was obtained from 10 g (wet weight) of cells. IIGlc of E. coli and Salmonella typhimurium are functionally indistinguishable. A small difference was revealed, however, by a monoclonal antibody which neutralizes glucose phosphorylation activity of IIGlc from S. typhimurium, but does not cross-react with IIGlc of E. coli. A dimeric form of purified IIGlc can be detected by chemical cross-linking and by zonal sedimentation at 4 degrees C. Upon mild oxidation a disulfide bond is formed between the subunits of the dimer. Oxidized IIGlc is more stable than the reduced form but is inactive because it cannot be phosphorylated by the cytoplasmic subunit (IIIGlc) of the glucose permease. Cys-421 could be identified as the oxidation-sensitive residue, using a novel assay to detect IIIGlc-dependent phosphorylation of nitrocellulose-bound IIGlc that has been purified by gel electrophoresis. No dimeric form of phosphorylated IIGlc could be detected. Because phosphorylated IIGlc is a catalytic intermediate it is concluded that catalytically active IIGlc is a monomer and that the dimeric form is an artefact observed only with purified resting IIGlc. That IIGlc is active as a monomer is further supported by the observation that monomeric IIGlc catalyzes phosphoryl exchange between glucose and glucose 6-phosphate at equilibrium and that an excess of inactive IIGlc with a serine replacing Cys-421 does not interfere with the activity of wild-type IIGlc as would be expected if interaction between the subunits in a dimer were essential for activity.     

Glucose-specific permease of the bacterial phosphotransferase system: phosphorylation and oligomeric structure of the glucose-specific IIGlc-IIIGlc complex of Salmonella typhimurium

The glucose-specific membrane permease (IIGlc) of the bacterial phosphoenolpyruvate-dependent phosphotransferase system (PTS) mediates active transport and concomitant phosphorylation of glucose. The purified permease has been phosphorylated in vitro and has been isolated (P-IIGlc). A phosphate to protein stoichiometry of between 0.6 and 0.8 has been measured. Phosphoryl transfer from P-IIGlc to glucose has been demonstrated. This process is, however, slow and accompanied by hydrolysis of the phosphoprotein unless IIIGlc, the cytoplasmic phosphoryl carrier protein specific to the glucose permease (IIGlc) of the PTS, is added. Addition of unphosphorylated IIIGlc resulted in rapid formation of glucose 6-phosphate with almost no hydrolysis of P-IIGlc accompanying the process. A complex of IIGlc and IIIGlc could be precipitated from bacterial cell lysates with monoclonal anti-IIGlc immunoglobulin. The molar ratio of IIGlc:IIIGlc in the immunoprecipitate was approximately 1:2. Analytical equilibrium centrifugation as well as chemical cross-linking showed that purified IIGlc itself is a dimer (106 kDa), consisting of two identical subunits. These results suggest that the functional glucose-specific permease complex comprises a membrane-spanning homodimer of IIGlc to which four molecules of IIIGlc are bound on the cytoplasmic face.     

The glucose permease of the phosphotransferase system of Bacillus subtilis: evidence for IIGlc and IIIGlc domains

Glucose is taken up in Bacillus subtilis via the phosphoenolpyruvate:glucose phosphotransferase system (glucose PTS). Two genes, orfG and ptsX, have been implied in the glucose-specific part of this PTS, encoding an Enzyme IIGlc and an Enzyme IIIGlc, respectively. We now show that the glucose permease consists of a single, membrane-bound, polypeptide with an apparent molecular weight of 80,000, encoded by a single gene which will be designated ptsG. The glucose permease contains domains that are 40-50% identical to the IIGlc and IIIGlc proteins of Escherichia coli. The B. subtilis IIIGlc domain can replace IIIGlc in E. coli crr mutants in supporting growth on glucose and transport of methyl alpha-glucoside. Mutations in the IIGlc and IIIGlc domains of the B. subtilis ptsG gene impaired growth on glucose and in some cases on sucrose. ptsG mutants lost all methyl alpha-glucoside transport but retained part of the glucose-transport capacity. Residual growth on glucose and transport of glucose in these ptsG mutants suggested that yet another uptake system for glucose existed, which is either another PT system or regulated by the PTS. The glucose PTS did not seem to be involved in the regulation of the uptake or metabolism of non-PTS compounds like glycerol. In contrast to ptsl mutants in members of the Enterobacteriaceae, the defective growth of B. subtilis ptsl mutants on glycerol was not restored by an insertion in the ptsG gene which eliminated IIGlc. Growth of B. subtilis ptsG mutants, lacking IIGlc, was not impaired on glycerol. From this we concluded that neither non-phosphorylated nor phosphorylated IIGlc was acting as an inhibitor or an activator, respectively, of glycerol uptake and metabolism.     

Analysis of mutations that uncouple transport from phosphorylation in enzyme IIGlc of the Escherichia coli phosphoenolpyruvate-dependent phosphotransferase system.

Mutations that uncouple glucose transport from phosphorylation were isolated in plasmid-encoded Escherichia coli enzyme IIGlc of the phosphoenolpyruvate-dependent phosphotransferase system (PTS). The uncoupled enzymes IIGlc were able to transport glucose in the absence of the general phosphoryl-carrying proteins of the PTS, enzyme I and HPr, although with relatively low affinity. Km values of the uncoupled enzymes IIGlc for glucose ranged from 0.5 to 2.5 mM, 2 orders of magnitude higher than the value of normal IIGlc. Most of the mutant proteins were still able to phosphorylate glucose and methyl alpha-glucoside (a non-metabolizable glucose analog specific for IIGlc), indicating that transport and phosphorylation are separable functions of the enzyme. Some of the uncoupled enzymes IIGlc transported glucose with a higher rate and lower apparent Km in a pts+ strain than in a delta ptsHI strain lacking the general proteins enzyme I and HPr. Since the properties of these uncoupled enzymes IIGlc in the presence of PTS-mediated phosphoryl transfer resembled those of wild-type IIGlc, these mutants appeared to be conditionally uncoupled. Sequencing of the mutated ptsG genes revealed that all amino acid substitutions occurred in a hydrophilic segment within the hydrophobic N-terminal part of IIGlc. These results suggest that this hydrophilic loop is involved in binding and translocation of the sugar substrate.     

Stereochemical course of the reactions catalyzed by the bacterial phosphoenolpyruvate:glucose phosphotransferase system

The overall stereochemical course of the reactions leading to the phosphorylation of methyl alpha-D-glucopyranoside by the glucose-specific enzyme II (enzyme IIGlc) of the Escherichia coli phosphotransferase system has been investigated. With [(R)-16O,17O,18O]phosphoenolpyruvate as the phosphoryl donor and in the presence of enzyme I, HPr, and enzyme IIIGlc of the phosphotransferase system, membranes from E. coli containing enzyme IIGlc catalyzed the formation of methyl alpha-D-glucopyranoside 6-phosphate with overall inversion of the configuration at phosphorus (with respect to phosphoenolpyruvate). It has previously been shown that sequential covalent transfer of the phosphoryl group of phosphoenolpyruvate to enzyme I, to HPr, and to enzyme IIIGlc occurs before the final transfer from phospho-enzyme IIIGlc to the sugar, catalyzed by enzyme IIGlc. Because overall inversion of the configuration of the chiral phospho group of phosphoenolpyruvate implies an odd number of transfer steps, the phospho group has been transferred at least five times, and transfer from phospho-enzyme IIIGlc to the sugar must occur in two steps (or a multiple thereof). On the basis that no membrane protein other than enzyme IIGlc is directly involved in the final phospho transfer steps, our results imply that a covalent phospho-enzyme IIGlc is an intermediate during transport and phosphorylation of glucose by the E. coli phosphotransferase system.     

The glucose permease of Bacillus subtilis is a single polypeptide chain that functions to energize the sucrose permease

Biochemical, immunological, and sequence analyses demonstrated that the glucose permease of Bacillus subtilis, the glucose-specific Enzyme II of the phosphoenolpyruvate-dependent phosphotransferase system, is a single polypeptide chain with a C-terminal Enzyme III-like domain. A flexible hydrophilic linker, similar in length and amino acid composition to linkers previously identified in other regulatory or sensory transducing proteins, functions to tether the Enzyme IIIGlc-like domain of the protein to the membrane-embedded Enzyme IIGlc. Evidence is presented demonstrating that the Enzyme IIIGlc-like domain of the glucose permease plays a dual role and functions in the transport and phosphorylation of both glucose and sucrose. The sucrose permease appears to lack a sucrose-specific Enzyme III-like domain or a separate, soluble IIIScr protein. Enzyme IIScr was capable of utilizing the IIIGlc-like domain of the glucose permease regardless of whether the IIIGlc polypeptide was provided as a purified, soluble protein, as a membrane-bound protein within the same membrane as Enzyme IIScr, or as a membrane-bound protein within membrane fragments different from those bearing Enzyme IIScr. These observations suggest that the IIIGlc-like domain is an autonomous structural unit that assumes a conformation independent of the hydrophobic, N-terminal intramembranal domain of Enzyme IIGlc. Preferential uptake and phosphorylation of glucose over sucrose has been demonstrated by both in vivo transport studies and in vitro phosphorylation assays. Addition of the purified IIIGlc-like domain strongly stimulated the phosphorylation of sucrose, but not that of glucose, in phosphorylation assays that contained the two sugars simultaneously. The results suggest that the preferential uptake of glucose over sucrose is determined by competition of the corresponding sugar-specific permeases for the common P approximately IIIGlc/Scr domain.     

Properties of the glucose phosphotransferase system of Clostridium acetobutylicum NCIB 8052.

The glucose phosphotransferase system (PTS) of Clostridium acetobutylicum was studied by using cell extracts. The system exhibited a Km for glucose of 34 microM, and glucose phosphorylation was inhibited competitively by mannose and 2-deoxyglucose. The analogs 3-O-methylglucoside and methyl alpha-glucoside did not inhibit glucose phosphorylation significantly. Activity showed no dependence on Mg2+ ions or on pH in the range 6.0 to 8.0. The PTS comprised both soluble and membrane-bound proteins, which interacted functionally with the PTSs of Clostridium pasteurianum, Bacillus subtilis, and Escherichia coli. In addition to a membrane-bound enzyme IIGlc, sugar phosphorylation assays in heterologous systems incorporating extracts of pts mutants of other organisms provided evidence for enzyme I, HPr, and IIIGlc components. The HPr was found in the soluble fraction of C. acetobutylicum extracts, whereas enzyme I, and probably also IIIGlc, was present in both the soluble and membrane fractions, suggesting a membrane location in the intact cell.     

Properties of the glucose phosphotransferase system of Clostridium acetobutylicum NCIB 8052.

The glucose phosphotransferase system (PTS) of Clostridium acetobutylicum was studied by using cell extracts. The system exhibited a Km for glucose of 34 microM, and glucose phosphorylation was inhibited competitively by mannose and 2-deoxyglucose. The analogs 3-O-methylglucoside and methyl alpha-glucoside did not inhibit glucose phosphorylation significantly. Activity showed no dependence on Mg2+ ions or on pH in the range 6.0 to 8.0. The PTS comprised both soluble and membrane-bound proteins, which interacted functionally with the PTSs of Clostridium pasteurianum, Bacillus subtilis, and Escherichia coli. In addition to a membrane-bound enzyme IIGlc, sugar phosphorylation assays in heterologous systems incorporating extracts of pts mutants of other organisms provided evidence for enzyme I, HPr, and IIIGlc components. The HPr was found in the soluble fraction of C. acetobutylicum extracts, whereas enzyme I, and probably also IIIGlc, was present in both the soluble and membrane fractions, suggesting a membrane location in the intact cell.     

Suppression of IIIGlc-defects by Enzymes IINag and IIBgl of the PEP:carbohydrate phosphotransferase system

The Enzymes II of the PEP:carbohydrate phosphotransferase system (PTS) specific for N-acetylglucosamine (IINag) and beta-glucosides (IIBgl) contain C-terminal domains that show homology with Enzyme IIIGlc of the PTS. We investigated whether one or both of the Enzymes II could substitute functionally for IIIGlc. The following results were obtained: (i) Enzyme IINag, synthesized from either a chromosomal or a plasmid-encoded nagE+ gene could replace IIIGlc in glucose, methyl alpha-glucoside and sucrose transport via the corresponding Enzymes II. An Enzyme IINag with a large deletion in the N-terminal domain but with an intact C-terminal domain could also replace IIIGlc in IIGlc-dependent glucose transport. (ii) After decryptification of the Escherichia coli bgl operon, Enzyme IIBgl could substitute for IIIGlc. (iii) Phospho-HPr-dependent phosphorylation of methyl alpha-glucoside via IINag/IIGlc is inhibited by antiserum against IIIGlc as is N-acetylglucosamine phosphorylation via IINag. (iv) In strains that contained the plasmid which coded for IINag, a protein band with a molecular weight of 62,000 D could be detected with antiserum against IIIGlc. We conclude from these results that the IIIGlc-like domain of Enzyme IINag and IIBgl can replace IIIGlc in IIIGlc-dependent carbohydrate transport and phosphorylation.     

The phosphoenolpyruvate:glucose phosphotransferase system of Salmonella typhimurium. The phosphorylated form of IIIGlc

Enzyme IIIGlc of the phosphoenolpyruvate: sugar phosphotransferase system (PTS) of Salmonella typhimurium can occur in two forms: phosphorylated and nonphosphorylated. Phosphorylated IIIGlc (P-IIIGlc) has a slightly lower mobility during sodium dodecyl sulphate/polyacrylamide gel electrophoresis than IIIGlc. In bacterial extracts both phosphoenolpyruvate (the physiological phosphoryl donor of the PTS) as well as ATP can phosphorylate IIIGlc. The ATP-catalyzed reaction is dependent on phosphoenolpyruvate synthase, however, and is due to prior conversion of ATP to phosphoenolpyruvate. The phosphoryl group of phosphorylated IIIGlc is hydrolysed after boiling in sodium dodecyl sulfate but phosphorylated IIIGlc can be discriminated from IIIGlc if treated with this detergent at room temperature. We have used the different mobilities of IIIGlc and P-IIIGlc to estimate the proportion of these two forms in intact cells. Wild-type cells contain predominantly P-IIIGlc in the absence of PTS sugars. In an S. typhimurium mutant containing a leaky ptsI17 mutation (0.1% enzyme I activity remaining) both forms of IIIGlc occur in approximately equal amounts. Addition of PTS sugars such as glucose results, both in wild-type and mutant, in a dephosphorylation of P-IIIGlc. This correlates well with the observed inhibition of non-PTS uptake systems by PTS sugars via nonphosphorylated IIIGlc.     

The glucose transporter of the Escherichia coli phosphotransferase system: linker insertion mutants and split variants

The IICB(Glc) subunit of the glucose transporter acts by a mechanism which couples vectorial translocation with phosphorylation of the substrate. It contains 8 transmembrane segments connected by 4 periplasmic, 2 short, 1 long (80 residues), cytoplasmic loops and an independently folding cytoplasmic domain at the C-terminus. Random DNase I cleavage, EcoRI linker insertion, and screening for transport-active mutants afforded 12 variants with between 46% and 116% of wild-type sugar phosphorylation activity. They carried inserts of up to 29 residues and short deletions in periplasmic loops 1, 2, and 3, in the long cytoplasmic loop 3, and in the linker region between the membrane spanning IIC(Glc) and the cytoplasmic IIB(Glc) domains. Disruption of the gene at the sites of linker insertion decreased the expression level and diminished phosphotransferase activity to between 7% and 32%. IICB(Glc) with a discontinuity in the cytoplasmic loop was purified to homogeneity as a stable complex. It was active only if encoded by a dicistronic operon but not if encoded by two genes on two different replicons, suggesting that spatial proximity of the nascent polypeptide chains is important for folding and membrane assembly.     

Mechanism of phosphoryl transfer in the dimeric IIABMan subunit of the Escherichia coli mannose transporter

The mannose transporter of bacterial phosphoenolpyruvate:sugar phosphotransferase system (PTS) mediates uptake of mannose, glucose, and related hexoses by a mechanism that couples translocation with phosphorylation of the substrate. It consists of the transmembrane IICMan.IIDMan complex and the cytoplasmic IIABMan subunit. IIABMan has two domains (IIA and IIB) that are linked by a 60-A long alanine-proline-rich linker. IIABMan transfers phosphoryl groups from the phospho-histidine-containing phospho-carrier protein of the PTS to His-10 on IIA, hence to His-175 on IIB, and finally to the 6'-OH of the transported hexose. IIABMan occurs as a stable homodimer. The subunit contact is mediated by a swap of beta-strands and an extensive contact area between the IIA domains. The H10C and H175C single and the H10C/H175C double mutants were used to characterize the phosphoryl transfer between IIA to IIB. Subunits do not exchange between dimers under physiological conditions, but slow phosphoryl transfer can take place between subunits from different dimers. Heterodimers of different subunits were produced in vitro by GuHCl-induced unfolding and refolding of mixtures of two different homodimers. With respect to wild-type homodimers, the heterodimers have the following activities: wild-type.H10C, 50%; wild-type.H175C 45%; H10C.H175C, 37%; and wild-type.H10C/H175C (double mutant), 29%. Taken together, this indicates that both cis and trans pathways contribute to the maximal phosphotransferase activity of IIABMan. A phosphoryl group on a IIA domain can be transferred either to the IIB domain on the same or on the second subunit in the dimer, and interruption of one of the two pathways results in a reduction of the activity to 70-80% of the control.     

Role of IIIGlc of the phosphoenolpyruvate-glucose phosphotransferase system in inducer exclusion in Escherichia coli.

The phosphoenolpyruvate-D-glucose phosphotransferase system of Enterobacteriaceae is thought to regulate the synthesis and activity of a number of catabolite uptake systems, including those for maltose, lactose, and glycerol, via the phosphorylation state of one of its components, IIIGlc. We have investigated the proposal by Kornberg and co-workers (FEBS Lett. 117(Suppl.):K28-K36, 1980) that not IIIGlc, but an unknown protein, the product of the iex gene, is responsible for the exclusion of the above-mentioned compounds from the cell. The iex mutant HK738 of Escherichia coli contains normal amounts of IIIGlc as measured by specific antibodies, in contrast to crr mutants that lack IIIGlc. The IIIGlc of the iex strain functions normally in glucose and methyl alpha-glucoside transport, and the specific activity in in vitro phosphorylation is approximately 60% of that of the parent. The IIIGlc activity of the iex strain is, however, heat labile, in contrast to the parental IIIGlc, suggesting that the mutant contains an altered IIIGlc. This is supported by the observation that IIIGlc from the iex strain cannot bind to the lactose carrier. Thus it cannot inhibit the carrier, and this explains why the uptake of non-phosphotransferase system compounds in an iex strain is resistant to phosphotransferase system sugars. The introduction of a plasmid containing a wild-type crr+ allele into the iex strain restores the iex phenotype to that of the iex+ parent. The IIIGlc produced from the plasmid in the iex strain is heat stable and binds normally to the lactose carrier. These results lead to the conclusion that the iex mutation is most likely allelic with crr and results in an altered, temperature-sensitive IIIGlc that is still able to function D-glucose and methyl alpha-glucoside uptake and phosphorylation and in the activation of adenylate cyclase, but is unable to bind to and inhibit the lactose carrier.     

Identification of the cAMP-dependent protein kinase and protein kinase C phosphorylation sites within the major intracellular domains of the beta 1, gamma 2S, and gamma 2L subunits of the gamma-aminobutyric acid type A receptor.

Gamma-aminobutyric acid Type A (GABAA) receptors are the major sites of synaptic inhibition in the central nervous system. These receptors are thought to be pentameric complexes of homologous transmembrane glycoproteins. Molecular cloning has revealed a multiplicity of different GABAA receptor subunits divided into five classes, alpha, beta, gamma, delta, and rho, based on sequence homology. Within the proposed major intracellular domain of these subunits, there are numerous potential consensus sites for protein phosphorylation by a variety of protein kinases. We have used purified fusion proteins of the major intracellular domain of GABAA receptor subunits produced in Escherichia coli to examine the phosphorylation of these subunits by cAMP-dependent protein kinase (PKA) and protein kinase C (PKC). The purified fusion protein of the intracellular domain of the beta 1 subunit was an excellent substrate for both PKA and PKC. PKA and PKC phosphorylated the beta 1 subunit fusion protein on serine residues on a single tryptic phosphopeptide. Site-directed mutagenesis of serine 409 in the intracellular domain of the beta 1 subunit to an alanine residue eliminated the phosphorylation of the beta 1 subunit fusion protein by both protein kinases. The purified fusion proteins of the major intracellular domain of the gamma 2S and gamma 2L subunits of the GABAA receptor were rapidly and stoichiometrically phosphorylated by PKC but not by PKA. The phosphorylation of the gamma 2S subunit occurred on serine residues on a single tryptic phosphopeptide. Site-directed mutagenesis of serine 327 of the gamma 2S subunit fusion protein to an alanine residue eliminated the phosphorylation of the gamma 2S fusion protein by PKC. The gamma 2L subunit is an alternatively spliced form of the gamma 2S subunit that differs by the insertion of 8 amino acids (LLRMFSFK) within the major intracellular domain of the gamma 2S subunit. The PKC phosphorylation of the gamma 2L subunit occurred on serine residues on two tryptic phosphopeptides. Site-specific mutagenesis of serine 343 within the 8-amino acid insert to an alanine residue eliminated the PKC phosphorylation of the novel site in the gamma 2L subunit. No phosphorylation of a purified fusion protein of the major intracellular loop of the alpha 1 subunit was observed with either PKA or PKC. These results identify the specific amino acid residues within GABAA receptor subunits that are phosphorylated by PKA and PKC and suggest that protein phosphorylation of these sites may be important in regulating GABAA receptor function.(ABSTRACT TRUNCATED AT 400 WORDS)     

Transport of trehalose in Salmonella typhimurium.

We have studied trehalose uptake in Salmonella typhimurium and the possible involvement of the phosphoenolpyruvate:carbohydrate phosphotransferase system (PTS) in this process. Two transport systems could recognize and transport trehalose, the mannose PTS and the galactose permease. Uptake of trehalose via the latter system required that it be expressed constitutively (due to a galR or galC mutation). Introduction of a ptsM mutation, resulting in a defective IIMan/IIIMan system, in S. typhimurium strains that grew on trehalose abolished growth on trehalose. A ptsG mutation, eliminating IIGlc of the glucose PTS, had no effect. In contrast, a crr mutation that resulted in the absence of IIIGlc of the glucose PTS prevented growth on trehalose. The inability of crr and also cya mutants to grow on trehalose was due to lowered intracellular cyclic AMP synthesis, since addition of extracellular cyclic AMP restored growth. Subsequent trehalose metabolism could be via a trehalose phosphate hydrolase, if trehalose phosphate was formed via the PTS, or trehalase. Trehalose-grown cells contained trehalase activity, but we could not detect phosphoenolpyruvate-dependent phosphorylation of trehalose in toluenized cells.     

IkappaB kinases phosphorylate NF-kappaB p65 subunit on serine 536 in the transactivation domain.

Recent investigations have elucidated the cytokine-induced NF-kappaB activation pathway. IkappaB kinase (IKK) phosphorylates inhibitors of NF-kappaB (IkappaBs). The phosphorylation targets them for rapid degradation through a ubiquitin-proteasome pathway, allowing the nuclear translocation of NF-kappaB. We have examined the possibility that IKK can phosphorylate the p65 NF-kappaB subunit as well as IkappaB in the cytokine-induced NF-kappaB activation. In the cytoplasm of HeLa cells, the p65 subunit was rapidly phosphorylated in response to TNF-alpha in a time dependent manner similar to IkappaB phosphorylation. In vitro phosphorylation with GST-fused p65 showed that a p65 phosphorylating activity was present in the cytoplasmic fraction and the target residue was Ser-536 in the carboxyl-terminal transactivation domain. The endogenous IKK complex, overexpressed IKKs, and recombinant IKKbeta efficiently phosphorylated the same Ser residue of p65 in vitro. The major phosphorylation site in vivo was also Ser-536. Furthermore, activation of IKKs by NF-kappaB-inducing kinase induced phosphorylation of p65 in vivo. Our finding, together with previous observations, suggests dual roles for IKK complex in the regulation of NF-kappaB.IkappaB complex.     

Structure of integrin, a glycoprotein involved in the transmembrane linkage between fibronectin and actin

We describe the isolation, characterization, and sequence of cDNA clones encoding one subunit of the complex of membrane glycoproteins that forms part of the transmembrane connection between the extracellular matrix and the cytoskeleton. The cDNA sequence encodes a polypeptide of 89 kd that has features strongly suggesting the presence of a large N-terminal extracellular domain, a single transmembrane segment, and a small C-terminal cytoplasmic domain. The extracellular domain contains a threefold repeat of a novel 40 residue cysteine-rich segment, and the cytoplasmic domain contains a tyrosine residue that is a potential site for phosphorylation by tyrosine kinases. We propose the name integrin for this protein complex to denote its role as an integral membrane complex involved in the transmembrane association between the extracellular matrix and the cytoskeleton.