A novel aspect of the inhibition by arsenicals of binding-protein-dependent galactose transport in gram-negative bacteria.

The inhibitory effects of arsenate and arsenite on binding-protein-dependent transport systems are reconsidered. It is shown that arsenate inhibits binding-protein-dependent galactose transport in proteoliposomes energized either by dihydrolipoamide and NAD+ or by a membrane potential (under conditions where ATP metabolism is not implicated); this result is in contradiction with the current interpretation of arsenate inhibition of binding-protein-dependent transport systems (which is based on ATP depletion) and can be explained by reference to the recently discovered ATP inhibition of the binding-protein-dependent galactose transport. In whole cells, the greater inhibition by arsenate of lipoamide-dependent transport than of protonmotive-force-dependent transport may be explained by a modification by arsenate of the pools of several compounds metabolized by 2-oxo-acid dehydrogenases (which have been implicated in binding-protein-dependent transport). The inhibition of binding-protein-dependent galactose transport by arsenite is probably linked to the inhibition by arsenite of the galactose-stimulated lipoamide dehydrogenase activity implicated in this transport and is reminiscent of the known arsenite inhibition of lipoamide dehydrogenases.     

Substrate recognition at the cytoplasmic and extracellular binding site of the lactose transport protein of Streptococcus thermophilus

The lactose transport protein (LacS) of Streptococcus thermophilus catalyzes the uptake of lactose in an exchange reaction with intracellularly formed galactose. The interactions between the substrate and the cytoplasmic and extracellular binding site of LacS have been characterized by assaying binding and transport of a range of sugars in proteoliposomes, in which the purified protein was reconstituted with a unidirectional orientation. Specificity for galactoside binding is given by the spatial configuration of the C-2, C-3, C-4, and C-6 hydroxyl groups of the galactose moiety. Except for a C-4 methoxy substitution, replacement of the hydroxyl groups for bulkier groups is not tolerated at these positions. Large hydrophobic or hydrophilic substitutions on the galactose C-1 alpha or beta position did not impair transport. In fact, the hydrophobic groups increased the binding affinity but decreased transport rates compared with galactose. Binding and transport characteristics of deoxygalactosides from either side of the membrane showed that the cytoplasmic and extracellular binding site interact differently with galactose. Compared with galactose, the IC(50) values for 2-deoxy- and 6-deoxygalactose at the cytoplasmic binding site were increased 150- and 20-fold, respectively, whereas they were the same at the extracellular binding site. From these and other experiments, we conclude that the binding sites and translocation pathway of LacS are spacious along the C-1 to C-4 axis of the galactose moiety and are restricted along the C-2 to C-6 axis. The differences in affinity at the cytoplasmic and extracellular binding site ensure that the transport via LacS is highly asymmetrical for the two opposing directions of translocation.     

A lipoamide dehydrogenase from Neisseria meningitidis has a lipoyl domain

A protein of molecular weight of 64 kDa (p64k) found in the outer membrane of Neisseria meningitidis shows a high degree of homology with both the lipoyl domain of the acetyltransferase and the entire sequence of the lipoamide dehydrogenase, the E2 and E3 components of the dehydrogenase multienzyme complexes, respectively. The alignment of the p64k with lipoyl domains and lipoamide dehydrogenases from different species is presented. The possible implications of this protein in binding protein-dependent transport are discussed. This is the first lipoamide dehydrogenase reported to have a lipoyl domain. © 1995 Wiley-Liss, Inc.     

Reconstitution of the binding protein-dependent galactose transport of Salmonella typhimurium in proteoliposomes.

Binding protein-dependent transport systems mediate the accumulation of diverse substrates in bacteria. The binding protein-dependent galactose transport of Salmonella typhimurium has been reconstituted in proteoliposomes. The proteoliposomes were made with proteins solubilized and renatured from inclusion bodies produced by a bacterial strain containing a plasmid with the mgl (methylgalactose permease) operon of Salmonella typhimurium. Galactose transport is dependent both on the addition of the purified galactose binding protein to the transport assay, and on ATP. The interaction between the liganded galactose binding protein and proteoliposomes displays Michaelis type kinetics with a Km of around 15 microM. Galactose transport is coupled to ATP hydrolysis with a stoichiometry (ATP/galactose) of 2.5:1. Galactose transport in proteoliposomes is not significantly inhibited by the uncoupler carbonylcyanide m-chlorophenylhydrazone, but is inhibited by 0.5 mM vanadate. The present reconstitution of galactose transport in proteoliposomes suggests that the MglA, MglC and MglE proteins have been solubilized and renatured in an active form from the inclusion bodies of the mgl hyperproducing strain.     

Properties of the galactose binding protein of Salmonella typhimurium and Escherichia coli.

The galactose binding protein implicated in transport and in chemotaxis has been purified to homogeneity from the shock fluids of Salmonella typhimurium and Escherichia coli. Both proteins are monomers of molecular weight 33 000 and exhibit cross-reactivity with antibody. The Salmonella galactose receptor showed binding of 1 mol of [14C]galactose or 1 mol of [14C]glucose at saturation. The dissociation constants were 0.38 and 0.17 muM, respectively. In light of the previously published report that the E. coli protein contains two binding sites with two different affinities, the binding characteristics of this protein were reexamined. Using highly purified radiolabeled substrate and homogeneous protein, a single binding site and single binding affinity were seen galactose (KD = 0.48 muM) or for glucose (KD = 0.21 muM). The competition between glucose and galactose for the same site is intriguing in view of the competition between ribose and galactose at the receptor level.     

Purification of the MglC/E membrane proteins of the binding protein-dependent galactose transport system of Salmonella typhimurium.

The high affinity galactose transport system of Salmonella typhimurium consists of four proteins, a periplasmic galactose binding protein (the MglB protein), and three inner membrane-associated proteins, the MglA, MglC and MglE proteins. We purified the MglC/E proteins from an MglC/E hyperproducing strain after solubilisation of inclusion bodies in guanidine hydrochloride followed by renaturation in a detergent-containing buffer and affinity chromatography on a MglB-Sepharose column. The MglC/E proteins are devoid of ATPase activity and they complement an extract from a strain carrying a plasmid with the mglA gene for reconstitution of the MglB-dependent galactose transport in proteoliposomes.     

Associative properties of the Escherichiacoli galactose binding protein and maltose binding protein

The periplasmic galactose binding protein and maltose binding protein of $\text{Escherichia}\text{coli}$ are recovered mostly in dimeric form when purified, from osmotically-shocked bacteria, in the presence of protease inhibitors and 2-mercaptoethanol without dialysis and concentration of the shock fluid. The specific ligands, galactose (but not glucose) for galactose binding protein, and maltose for maltose binding protein, provoque the monomerisation of the dimeric native forms. These results are discussed in relation to the function of both binding proteins in transport and chemotaxis.     

Characterization of the mgl operon of Escherichia coli by transposon mutagenesis and molecular cloning

We used transposon insertion mutagenesis, molecular cloning, and a novel procedure for in vitro construction of polar and nonpolar insertion mutations to characterize the genetic organization and gene products of the beta-methylgalactoside (Mgl) transport system, which utilizes the galactose-binding protein. The data indicate that the mgl operon contained three genes, which were transcribed in the order mglB, mglA, and mglC. The first gene coded for the 31,000 Mr galactose-binding protein, which was synthesized as a 3,000-dalton-larger precursor form. The mglA product was a 50,000 Mr protein which was tightly associated with the membrane, and the mglC product was a 38,000 Mr protein which was apparently loosely associated with the membrane and was probably located on the internal face of the cytoplasmic membrane. Identification of gene products was facilitated by in vitro insertion of a fragment of Tn5 containing the gene conferring kanamycin resistance into a restriction site in the operon. The fragment proved to have a polar effect on the expression of promoter-distal genes only when inserted in one of the two possible orientations. The three identified gene products were necessary and apparently sufficient for transport activity, but only the binding protein was required for chemotaxis towards galactose. The transport system appeared to contain the minimum number of components for a binding protein-related system: a periplasmic recognition component, a transmembrane protein, and a peripheral membrane protein that may be involved in energy linkage.     

The x-ray structure of the periplasmic galactose binding protein from Salmonella typhimurium at 3.0-A resolution

The x-ray structure of the periplasmic galactose binding protein from Salmonella typhimurium, the specific receptor for taxis toward, and high-affinity transport of, galactose has been solved at 3.0-A resolution using multiple isomorphous replacement. The path of the polypeptide chain has been traced, and a model structure consisting of 292 amino acids has been fit to the electron density map. The overall shape of the molecule is that of a prolate ellipsoid, with dimensions 35 X 35 X 65 A. The protein consists of two similar domains of roughly equal size, related by an axis of pseudosymmetry, and separated by a deep cleft about 8 A wide. Each domain has a core of parallel beta sheet surrounded by five alpha helices, built by alternating strands of sheet and helix in a repeating pattern. Approximately 36% of the residues are involved in alpha helices, and 27% in beta sheet. The tertiary structure has been compared to that of the Escherichia coli arabinose binding protein (Gilliland, G.L., and Quiocho, F. A. (1981) J. Mol. Biol. 146, 341-362), a periplasmic receptor which is involved in transport, but not in chemotaxis. The overall folding of these two molecules is very similar, with the exception of two areas on the surface of the molecule on the long sides of the prolate ellipsoid. The observed variations are adequate to explain the differences in interaction of L-arabinose binding protein and galactose binding protein with the membrane proteins for transport and chemotaxis.     

Active transport of maltose in membrane vesicles obtained from Escherichia coli cells producing tethered maltose-binding protein.

Attempts to reconstitute periplasmic binding protein-dependent transport activity in membrane vesicles have often resulted in systems with poor and rather inconsistent activity, possibly because of the need to add a large excess of purified binding protein to the vesicles. We circumvented this difficulty by using a mutant which produces a precursor maltose-binding protein that is translocated across the cytoplasmic membrane but is not cleaved by the signal peptidase (J. D. Fikes and P. J. Bassford, Jr., J. Bacteriol. 169:2352-2359, 1987). The protein remains tethered to the cytoplasmic membrane, presumably through the hydrophobic signal sequence, and we show here that the spheroplasts and membrane vesicles prepared from this mutant catalyze active maltose transport without the addition of purified maltose-binding protein. In vesicles, the transport requires electron donors, such as ascorbate and phenazine methosulfate or D-lactate. However, inhibition by dicyclohexylcarbodiimide and stimulation of transport by the inculsion of ADP or ATP in the intravesicular space suggest that ATP (or compounds derived from it) is involved in the energization of the transport. The transport activity of intact cells can be recovered without much inactivation in the vesicles, and their high activity and ease of preparation will be useful in studies of the mechanism of the binding protein-dependent transport process.     

Membrane events leading to interferon-gamma induction by antigens

Mitogenic induction of interferon-gamma in human peripheral blood mononuclear cells (PBMC) is prevented by enzymatic cleavage of galactose residues on the cell membrane, and by calcium depletion, suggesting that oxidation of galactose on the membrane glycoproteins and activation of a calcium flux across the membrane are critical events for interferon-gamma induction in nonspecifically stimulated human PBMC. The same experimental design has been applied to human PBMC cultures enriched of specifically sensitized lymphocytes and stimulated with the respective antigens. The results of these experiments show that also antigenic induction of interferon-gamma by purified protein derivative, tetanus toxoid, and MLR requires integrity of galactose residues and calcium intake suggesting that alteration of membrane-bound galactose and activation of a calcium flow are critical triggering events for both specific and nonspecific lymphocyte activation.     

Properties of Mutants in Galactose Taxis and Transport

beta-Methylgalactoside (mgl) permease mutants of Escherichia coli, which are defective in three genes, mglA, mglB, and mglC, were assayed for galactose taxis and galactose transport. The mglB product is the galactose-binding protein. Previous evidence, supported by our new findings, shows that the galactose-binding protein is the recognition component for galactose taxis as well as for galactose transport. Most mutants defective in mglB showed strong effects on both chemotaxis and transport; however, a couple showed effects chiefly on one process or the other, thus allowing a separation of chemotaxis and transport. The mglA and mglC products have not yet been identified, but they must be components of the galactose transport machinery since mutants defective in mglA or mglC, or both, showed strongly reduced transport. Although some of these mutants showed little chemotaxis, most gave close to wild-type chemotactic responses. Thus, transport is not required for galactose taxis. The bacteria detect changes in the fraction of binding protein associated with galactose, not changes in the rate of transport.     

The tRNA N2,N2-dimethylguanosine-26 methyltransferase encoded by gene trm1 increases efficiency of suppression of an ochre codon in Schizosaccharomyces pombe

The plant toxin ricin has proven valuable as a membrane marker in studies of endocytosis as well as studies of different intracellular transport steps. The toxin, which consists of two polypeptide chains, binds by one chain (the B-chain) to both glycolipids and glycoproteins with terminal galactose at the cell surface. The other chain (the A-chain) enters the cytosol and inhibits protein synthesis enzymatically. After binding the toxin is endocytosed by different mechanisms, and it is transported via endosomes to the Golgi apparatus and the endoplasmic reticulum before translocation of the A-chain to the cytosol. The different transport steps have been analyzed by studying trafficking of ricin as well as modified ricin molecules.     

Functional characterization of roles of GalR and GalS as regulators of the gal regulon.

An isorepressor of the gal regulon in Escherichia coli, GalS, has been purified to homogeneity. In vitro DNase I protection experiments indicated that among operators of the gal regulon, GalS binds most strongly to the external operator of the mgl operon, which encodes the high-affinity beta-methylgalactoside galactose transport system, and with less affinity to the operators controlling expression of the gal operon, which codes for enzymes of galactose metabolism. GalS has even less affinity for the external operator of galP, which codes for galactose permease, the major low-affinity galactose transporter in the cell. This order of affinities is the reverse of that of GalR, which binds most strongly to the operator of galP and most weakly to that of mgl. Our results also show that GalS, like its homolog, GalR, is a dimeric protein which in binding to the bipartite operators of the gal operon selectively represses its P1 promoter. Consistent with the fact that GalR is the exclusive regulator of the low-affinity galactose transporter, galactose permease, and that the major role of GalS is in regulating expression of the high-affinity galactose transporter encoded by the mgl operon, we found that the DNA binding of GalS is 15-fold more sensitive than that of GalR to galactose.     

Contrasting effects of selenite and tellurite on lipoamide dehydrogenase activity suggest a different biological behaviour of the two chalcogens

The effects of selenite and tellurite on the mammalian enzyme lipoamide dehydrogenase were compared. Selenite acts as a substrate of lipoamide dehydrogenase in a process requiring the presence of lipoamide. In contrast, tellurite is a potent inhibitor, effective in the low micromolar range. The inhibitory effect of tellurite on lipoamide dehydrogenase is partially reverted by dithiothreitol indicating the participation of the thiol groups of the enzyme. Tellurite, but not selenite, stimulates the diaphorase activity of lipoamide dehydrogenase. In a mitochondrial matrix protein preparation, which contains lipoamide dehydrogenase, an inhibitory action similar to that observed on the purified enzyme was also elicited by tellurite. Human embryonic kidney cells (HEK 293 T) treated with tellurite show a partial inhibition of lipoamide dehydrogenase. In addition to the toxicological implications of tellurium compounds, the reported results suggest that tellurite and its derivatives can be used as potential tools for studying biochemical reactions.     

Purification of a human plasma membrane glycoprotein from human red blood cells by affinity chromatography using a monoclonal antibody

Using the monoclonal antibody LICR-LON-Fib75.1 coupled to Sepharose as an affinity chromatography column, a membrane glycoprotein with an apparent molecular weight of 18,000 on sodium dodecyl sulfate-polyacrylamide gels has been purified from human red blood cells. The purified protein contained 25% carbohydrate by weight, the predominant sugars being galactose, mannose, and glucosamine. Amino acid analysis indicated that the protein was relatively rich in aspartate, glutamate, valine, and leucine and had a low proline and methionine content. The molecule could be removed from intact red blood cells by trypsin and could be labeled with iodine by lactoperoxidase-catalyzed cell surface iodination of red blood cells. The protein could also be labeled using the lipidsoluble photoactivatable reagent 3-(trifluoromethyl)-3-(m-[125I]iodophenyl) diazirine) and partitioned into the lower phase of the phase-separable detergent Triton X-114. During size-exclusion chromatography in different detergents alterations were observed in the apparent molecular weight of the protein. These results suggest that this Fib75.1-binding protein is an external red blood cell membrane glycoprotein which is capable of binding detergent. Proteins with a similar molecular weight have also been isolated from two human tumor cell lines by immunoprecipitation with this monoclonal antibody.     

Transport of Glycerol by Pseudomonas aeruginosa

In Pseudomonas aeruginosa, the transport of glycerol was shown to be genetically controlled and to be dependent on induction by glycerol. Accumulation of (14)C-glycerol was almost completely absent in uninduced cells and in a transport-negative mutant. Kinetic studies with induced cells suggested that glycerol may be transported by two systems with different affinities for glycerol. Osmotically shocked cells did not transport glycerol, and the supernatant fluid from shocked cells contained glycerol-binding activity demonstrable by equilibrium dialysis. The binding protein was not glycerol kinase. Binding activity was absent in shock fluids from the transport-negative mutant and from uninduced cells. The glycerol-binding protein was partially purified by precipitation with ammonium sulfate. Mild heat treatment completely eliminated the binding activity of shock fluid and of the partially purified protein. Sodium azide and N-ethylmaleimide inhibited both transport by whole cells and binding of glycerol by shock fluid. It is concluded that transport of glycerol by P. aeruginosa involves a binding protein responsible for recognition of glycerol and may occur by facilitated diffusion or active transport. A requirement for energy has not been demonstrated.     

Ganglioside from eel serum high density lipoprotein (HDL) and its role as a ligand for HDL binding protein

First, we attempted to isolate glycosphingolipids from eel serum HDL. A single ganglioside containing N-acetylneuraminic acid (NeuAc), which is positive with resorcinol and orcinol reactions, was purified. The mobilities of the purified ganglioside and its lyso-form on high performance TLC were similar as those of authentic GM4 and its lyso-form, respectively. The mass of the purified ganglioside was determined by TOF mass spectrometer, and the mass of its oligosaccharide was the same as that of authentic GM4 from human brain consisting of disaccharide of NeuAc and galactose. The ganglioside from eel HDL was not hydrolyzed by recombinant endoglycoceramidase II, which cannot hydrolyze between galactose and ceramide of gangliosides, but hydrolyzes between glucose and ceramide. We concluded from these results that the ganglioside purified from eel serum HDL is GM4. Second, we investigated the effects of the ganglioside on binding of HDL labeled with fluorescein isothiocyanate (FITC-HDL) to cultured eel hepatocytes and on FITC-HDL ligand blotting by using plasma membrane proteins of the hepatocytes. Stimulatory effect of GM4 on FITC-HDL binding to the hepatocytes and FITC-HDL ligand blotting suggests strongly that GM4 is a ligand for HDL binding protein of eel hepatocytes.     

Lipoamide dehydrogenase of Staphylococcus aureus: nucleotide sequence and sequence analysis.

A complex of four proteins was previously isolated from Staphylococcus aureus. The complex had a strong interaction with membrane bound ribosomes, which suggested that it may be involved in protein secretion. However, the complex was identified as pyruvate dehydrogenase (PDH), which disproved the direct role of the complex in protein secretion. Here we report the nucleotide sequence of the last gene of the S. aureus pyruvate dehydrogenase operon, pdhD, which encodes lipoamide dehydrogenase (LPD). The pdhD gene encodes a protein of 468 amino acids, with a molecular mass of 49.5 kDa. The protein is closely related to other lipoamide dehydrogenases from bacteria and eukaryotes. The possible role of membrane bound lipoamide dehydrogenase is briefly discussed.     

Resolution of branched-chain oxo acid dehydrogenase complex of Pseudomonas aeruginosa PAO.

Branched-chain oxo acid dehydrogenase was purified from Pseudomonas aeruginosa strain PAO with the objective of resolving the complex into its subunits. The purified complex consisted of four proteins, of Mr 36,000, 42,000, 49,000 and 50,000. The complex was resolved by heat treatment into the 49,000 and 50,000-Mr proteins, which were separated by chromatography on DEAE-Sepharose. The 49,000-Mr protein was identified as the E2 subunit by its ability to catalyse transacylation with a variety of substrates, with dihydrolipoamide as the acceptor. P. aeruginosa, like P. putida, produces two lipoamide dehydrogenases. One, the 50,000-Mr protein, was identified as the specific E3 subunit of branched-chain oxo acid dehydrogenase and had many properties in common with the lipoamide dehydrogenase LPD-val of P. putida. The second lipoamide dehydrogenase had Mr 54,000 and corresponded to the lipoamide dehydrogenase LPD-glc of P. putida. Fragments of C-terminal CNBr peptides of LPD-val from P. putida and P. aeruginosa corresponded closely, with only two amino acid differences over 31 amino acids. A corresponding fragment at the C-terminal end of lipoamide dehydrogenase from Escherichia coli also showed extensive homology. All three peptides had a common segment of eight amino acids, with the sequence TIHAHPTL. This homology was not evident in any other flavoproteins in the Dayhoff data base which suggests that this sequence might be characteristic of lipoamide dehydrogenase.