Binding of porcine sperm plasma membrane proteins to sheep, hamster and mouse oocyte plasma membrane

Four porcine sperm plasma membrane proteins were previously identified as putative ligands for the oocyte plasma membrane. The present study examined the binding of these proteins and two additional porcine sperm membrane proteins to oocytes from sheep, mice and hamsters as a first step in assessing potential conservation of these putative sperm ligands across species and across mammalian orders. Plasma membrane vesicles were isolated from porcine sperm, solubilised, and the proteins separated by one-dimensional gel electrophoresis. The 7, 27, 39 and 62 kDa porcine sperm protein bands demonstrating predominant binding of the porcine oocyte plasma membrane on ligand blots, a 90 kDa protein band demonstrating minor binding, and a 97 kDa protein band that did not bind the oocyte plasma membrane probe were electroeluted. Proteins were biotinylated, and incubated with zona-free oocytes. Bound biotinylated protein was labelled with fluorescent avidin and the oocytes examined with a confocal microscope. The 7 kDa, 27 kDa and the 39 kDa proteins bound to the sheep oocytes but not to a majority of the hamster or mouse oocytes. The 62 kDa protein bound to sheep oocytes and mouse oocytes but not to a majority of the hamster oocytes. The 90 kDa protein bound to oocytes from all three species. The 97 kDa protein, which did not recognise the porcine oocyte probe on a Western ligand blot, did not bind to oocytes from any species and served as a negative control. These observations are consistent with significant conservation of molecule and function among species within the same mammalian order. Hence, one species may be a good model for other species from the same order. Only limited conservation of binding activity of porcine sperm plasma membrane proteins to rodent oocytes was observed, suggesting a greater divergence either in molecular structure or in function among species from different orders.     

Binding-protein-dependent glucose transport by Agrobacterium radiobacter grown in glucose-limited continuous culture

Agrobacterium radiobacter NCIB 11883 was grown in glucose-limited continuous culture at low dilution rate. Whole cells transported glucose using an energy-dependent mechanism which exhibited an accumulation ratio greater than 2000. Three major periplasmic proteins were purified and their potential role as glucose-binding proteins (GBP) were investigated using equilibrium dialysis. Two of these, GBP1 (Mr 36,500) and GBP2 (Mr 33,500), bound D-glucose with high affinity (KD 0.23 and 0.07 microM respectively), whereas the third protein (Mr 30,500) showed no binding ability. Competition experiments using various analogues showed that those which differed from glucose at C-6 (e.g. 6-chloro-6-deoxy-D-glucose and 6-deoxy-D-glucose) variably decreased the binding of glucose to both GBP1 and GBP2, whereas those which differed at C-4 (e.g. D-galactose) were only effective with GBP1. The rate of glucose uptake and the concentration of the glucose-binding proteins increased in parallel during prolonged growth under glucose-limitation due to the emergence of new strains in which GBP1 (e.g. strain AR18) or GBP2 (e.g. strain AR9), but not both, was hyperproduced and accounted for at least 27% of the total cell protein. It is concluded that A. radiobacter synthesizes two distinct periplasmic binding proteins which are involved in glucose transport, and that these proteins are maximally derepressed during growth under glucose limitation.     

Use of mild detergent gel electrophoresis for isolation and characterization of the kidney brush border D-glucose transporter

Gradient gel electrophoresis was performed under mild detergent conditions to separate pig kidney brush border membrane proteins and to identify the smallest functional molecular protein entity of the D-glucose transporter. The various protein bands obtained from the nondenaturing gel system in a semipreparative scale were eluted by electrodialysis. These proteins were then reintegrated into proteoliposomes and tested for D-glucose-inhibitable [3H]phlorizin binding. The D-glucose transporter had a molecular mass of 70 kDa in mild detergent electrophoresis conditions and in subsequent SDS analysis.     

Determination of Triton X-100 binding to membrane proteins by polyacrylamide gel electrophoresis

The molecular weight of proteins in protein-detergent complexes can be determined from ultracentrifugation experiments if the amount of bound detergent is known. A new sensitive method to measure the binding of the nonionic detergent Triton X-100 to proteins has been developed. For the membrane proteins studied, less than 50 μg of protein was required to achieve an accuracy of 10% in the determination of the detergent-protein weight ratio.The proteins were equilibrated with the detergent by electrophoresis into polyacrylamide gels containing radioactively labelled Triton X-100. The gels were then sliced and the amount of bound detergent calculated from the increase in radioactivity in the slices containing the protein zone. The amounts of protein were determined by amino acid analysis of identical protein zones cut from gels running parallel .     

Photoreactive insulin analogues used to characterise the insulin receptor

Three photoreactive insulin analogues (“photoprobes”) have been prepared in which an aryl azide group was substituted at either the A1, B1 or B29 positions of the insulin molecule. When incubated with rat liver plasma membranes and irradiated all three photoprobes covalently labelled specific insulin binding sites within the membrane. SDS-polyacrylamide gel electrophoresis of plasma membranes covalently tagged with either of the three ¹²⁵I-photoprobes resolved one major specifically labelled polypeptide with an apparent molecular weight of 130,000. The labelled polypeptide migrated anomalously in SDS-polyacrylamide gels and a molecular weight of 90,000 for the polypeptide was determined from a ‘Ferguson’ plot using the combined results from gels of different acrylamide concentrations. Column chromatography of detergent solubilised photoprobe-labelled membranes indicated that the labelled polypeptide may be a subunit of a larger protein complex.     

Radiation inactivation studies of the renal brush-border membrane phlorizin-binding protein

Renal brush-border membrane vesicles were irradiated in the frozen state with a high energy electron beam. The integral membrane proteins, alkaline phosphatase and 5'-nucleotidase, each showed a single exponential loss of activity with radiation dose, indicating target sizes of 67,000 and 58,000 daltons, respectively. Inactivation of sodium-dependent phlorizin binding to the brush-border membrane D-glucose transporter was more complex. One-half of the phlorizin binding sites were lost after even the smallest doses of radiation suggestive of large functional units (greater than 4 X 10(6) daltons) for a subpopulation of phlorizin binding proteins. The remaining sites behaved as a single radiation target of 110,000 +/- 8,000 daltons and retained the kinetic characteristics commonly associated with phlorizin binding to the glucose transporter. Thus, the data are consistent with the assignment of a molecular weight of 110,000 to the phlorizin binding moiety of the brush-border membrane D-glucose transport protein.     

Phlorizin-receptor interactions in fat cell plasma membranes

The rate but not the extent of phlorizin binding to purified fat cell plasma membranes was temperature dependent and this binding was a saturable process. A Scatchard plot revealed a population of sites which exhibited a dissociation constant of about 0.35 mM and a maximum binding capacity of about 8 nmoles/mg membrane protein. Under the conditions of these experiments neither glucose, phloretin, nor cytochalasin B inhibited [³H]phlorizin binding. These data demonstrate the presence in fat cell plasma membrane of specific receptors for phlorizin which may mediate the inhibitory effects of this agent on hexose trasport.     

Interaction of the sugar carrier of intestinal brush-border membranes with HgCl2

HgCl2 was used as an inhibitor and potential label for the glucose carrier of intestinal brush-border membranes. Half-maximal inhibition of Na+-dependent D-glucose uptake was reached with micromolar concentrations of HgCl2 when the protein concentration was 1.2 mg/ml. Similar concentrations were found to inhibit the binding of [3H]phlorizin, a reversible competitive inhibitor of sugar transport. Inhibition was reversed by dithioerythritol but only marginally by EDTA. The data support the involvement of a sulfhydryl group in the inhibitory process. Deoxycholate-extracted membranes, which are enriched in specific phlorizin binding activity, were used for labeling studies using 203HgCl2. The polypeptides were separated by gel electrophoresis and analyzed by protein staining and autoradiography. Non-specific 203HgCl2 labeling was minimized by pre-treatment with sulfhydryl reagents which do not inhibit phlorizin binding. Several bands, which are lost from the autoradiographic pattern during a negative purification of the phlorizin binding sites, could be ruled out as essential components of the sugar carrier. The polypeptide profile was also analyzed following proteolysis, which abolished phlorizin binding. Those radioactive bands of which apparent Mr values were alterd by the treatment were considered as possible candidates. Finally, samples in which inhibition was reversed by thiols were also studied. The possible identity of the polypeptide(s) involved in glucose translocation is disussed in the light of these observations.     

Isotope-dilution analysis of rate-limiting steps and pools affecting the incorporation of thymidine and deoxycytidine into cultured thymus cells

1. Ox brain microsomal fractions were labelled with [(32)P]ATP in the presence of Na(+) and the reaction was stopped with sodium dodecyl sulphate. The Na(+)-dependent bound phosphate was isolated on Sephadex G-25 and by acetone precipitation. The bound phosphate isolated under these neutral conditions was labile to hydroxylamine and gave the same pH profile of hydrolysis as that isolated by precipitation with strong acids. 2. When membrane protein was labelled with [(32)P]ATP, solubilized with sodium dodecyl sulphate and fractionated on Sepharose 6B, the Na(+)-dependent label emerged in a peak corresponding to protein of molecular weight 570000-580000. On fractionation of this protein peak on polyacrylamide gels containing detergent and urea, the Na(+)-dependent label occurred in a single band corresponding to a protein of molecular weight 102000. 3. Fractionation on Sepharose 6B of protein labelled with [(32)P]ATP in the absence of Na(+) revealed three labelled peaks, one of which corresponded in position to the Na(+)-dependent label. Electrophoresis of this peak material on polyacrylamide gels showed that most of the label occurred in two fast-running bands. Cyclic AMP stimulated the labelling in these two bands, but had no effect on the labelling of the band corresponding in position to the Na(+)-dependent label. 4. Di-isopropyl [(32)P]phosphorofluoridate also labelled the band corresponding to the Na(+)-dependent label on gel electrophoresis. The labelling of this band by the reagent was inhibited by 50-60% by 3mm-ATP, but there was no evidence to suggest that the group labelled is normally phosphorylated by ATP.     

Solubilization of brush borders of hamster small intestine and fractionation of some of the components

About 90% of the protein of hamster intestinal brush borders was solubilised in 0.25% (w/v) sodium dodecyl sulphate without total loss of biological activity. Detergent-polyacrylamide gel electrophoresis of the solubilised protein separated 10–15 bands and partially resolved maltase, lactase, sucrase-maltase, trehalase and alkaline phosphatase activities. The disaccharidases, which were associated with the higher molecular weight proteins, were preferentially solubilised with 0.1%. (w/v) Triton X-100, butanol or papain, whereas Tris and NaI extracted only the lower molecular weight proteins, possible derived from the core filaments.Electrophoresis of brush border proteins metabolically labelled with [¹⁴C] glucosamine suggested that many of the membrane-bound enzymes are glycoproteins. However, chromatography of a papain digest on Sephadex G-200 showed that the sucrase-maltase complex can be separated nearly free of carbohydrate without total loss of activity.The importance of characterizing membrane proteins solubilised by a number of techniques is discussed.     

High-affinity phlorizin binding in Mytilus gill.

The gill of the marine mussel, Mytilus, contains a high affinity, Na-dependent D-glucose transporter capable of accumulating glucose directly from sea water. We examined the ability of the beta-glucoside, phlorizin, to act as a high-affinity ligand of this process in intact gills and isolated brush border membrane vesicles (BBMV). The time course of association of nanomolar [3H]phlorizin to gills and BBMV was slow, with t50 values between 10 and 30 min, and a half-time for dissociation of approx. 30 min. 1 mM D-glucose reduced equilibrium binding of 1 nM phlorizin by 90-95%, indicating that there was little non-specific binding of this ligand to the gill. In addition, there was little, if any, hydrolysis by the gill of phlorizin to its constituents, glucose and phloretin. Phlorizin binding to gills and BBMV was significantly inhibited by the addition of 50 microM concentrations of D-glucose and alpha-methyl-D-glucose, and unaffected by the addition of L-glucose and fructose. Binding to gills and BBMV was reduced by greater than 90% when Na+ was replaced by K+. Replacement of Na+ by Li+ effectively blocked binding to the intact gill, although Li+ did support a limited amount of glucose-specific phlorizin binding in BBMV. The Kd values for glucose-specific phlorizin binding in intact gills and BBMV were 0.5 nM and 6 nM, respectively. We conclude that phlorizin binds with extremely high affinity to the Na-dependent glucose transporter of Mytilus gill, which may be useful in future efforts to isolate and purify the protein(s) involved in integumental glucose transport.     

A method for measuring apical glucose transporter site density in intact intestinal mucosa by means of phlorizin binding

Summary Phlorizin binding has been widely used to estimate the site density of glucose transporters on intestinal and renal brush-border vesicles. Glucose transport measurements in the intact intestinal mucosa show that changes in transport rate postulated to arise from changes in site density occur under many physiological and pathological conditions. Exploring the basis of these regulatory phenomena would be facilitated by comparing changes in transport rate and site density measured in the same preparation. Hence we developed methods for measuring phlorizin binding in everted sleeves of intact mouse intestine. Specific binding of phlorizin to glucose carriers reached an asymptotic value within 120 sec, while nonspecific binding continued to rise thereafter. Hence we used 120-sec incubations. The rate of dissociation of specifically bound phlorizin was accelerated by Na⁺-free solutions and even more by 50mm glucose, while the rate of dissociation of nonspecifically bound phlorizin was independent of these solution changes. Hence we chose a 20-sec rinse in Ringer+50mm mannitol, because it washes out 30–40% of the nonspecifically bound phlorizin but virtually none of the specifically bound phlorizin. Ligand-binding analysis of specific binding against phlorizin concentration suggested two classes of binding sites, of which the one with stronger affinity for phlorizin probably has the higher capacity for glucose transport in mouse jejunum. The calculated affinity and capacity of this component are independent of whether one estimates the specific component of total binding by adding glucose or by removing Na⁺.     

Purification of a putative Na+/D-glucose cotransporter from pig kidney brush border membranes on a phlorizin affinity column

Phlorizin, a potent inhibitor of the Na+/D-glucose cotransporter, was derivatised to 3-aminophlorizin and subsequently coupled to Affi-Gel 15. Affinity chromatography of pig kidney brush border membranes solubilised in Triton X-100 allowed the purification of a 60 kDa protein on this resin. We consider this protein to be the Na+/D-glucose cotransporter, or part of it, for the following reasons: (i) binding of this protein to Affi-Gel 15 specifically requires phlorizin covalently attached to the resin and is lowered when phlorizin is replaced by phloretin; (ii) binding of the 60 kDa protein to a phlorizin affinity column requires the presence of Na+; (iii) polyclonal as well as monoclonal antibodies against the 60 kDa protein inhibit binding of phlorizin to brush border membranes from rabbit and pig kidney.     

D-Glucose-recognition and phlorizin-binding sites in human sodium/D-glucose cotransporter 1 (hSGLT1): a tryptophan scanning study

In order to gain a better understanding of the structure-function relation in hSGLT1, single Trp residues were introduced into a functional hSGLT1 mutant devoid of Trps at positions that previously had been postulated to be involved in sugar recognition/translocation and/or phlorizin binding. The mutant proteins were expressed in Pichia pastoris, purified, and reconstituted into liposomes. In transport experiments the putative sugar binding site mutants W457hSGLT1 and W460hSGLT1 showed a drastic decrease in affinity toward alpha-methyl-d-glucopyranoside with Km values of 13.3 and 5.26 mM compared to 0.4 mM of the Trp-less hSGLT1. In addition, a strong decrease in the inhibitory effect of phlorizin was observed. In Trp fluorescence studies the position of the emission maxima of the mutants, their sensitivity to N-bromosuccinimide oxidation, and their interaction with water soluble quenchers demonstrate that Trp457 and Trp460 are in contact with the hydrophilic extravesicular environment. In both mutants Trp fluorescence was quenched significantly, but differently, by various glucose analogues. They also show significant protection by d-glucose and phlorizin against acrylamide, KI, or TCE quenching. W602hSGLT1 and W609hSGLT1, the putative aglucone binding site mutants, exhibit normal sugar and phlorizin affinity, and show fluorescence properties which indicate that these residues are located in a very hydrophilic environment. Phlorizin and phloretin, but not d-glucose, protect both mutants against collisional quenchers. Depth-calculations using the parallax method suggest a location of Trp457 and Trp460 at an average distance of 10.8 A and 7.4 A from the center of the bilayer, while Trp602 and Trp609 are located outside the membrane. These results suggest that in the native carrier residues Gln at position 457 and Thr at position 460 reside in a hydrophilic access pathway extending 5-7 A into the membrane to which sugars as well as the sugar moiety of inhibitory glucosides bind. Residues Phe602 and Phe609 contribute by their hydrophobic aromatic residues toward binding of the aglucone part of phlorizin. Thereby in the phlorizin-carrier complex a close vicinity between these two subdomains of the transporter is established creating a phlorizin binding pocket with the previously estimated dimensions of 10 x 17 x 7 A.     

Identification of a high density lipoprotein binding protein from adrenocortical membranes

A protein band with an apparent molecular weight of 78,000 daltons has been identified in the solubilised plasma membrane extract of sheep adrenal cortex which binds HDL3 devoid of E apolipoprotein. Following 'Western' blotting, and development of the nitrocellulose strips with appropriate antisera and color reagent, the same band, unlike other cortical membrane proteins or albumin, bound AI and AII apolipoproteins. Human LDL bound weakly to the same band but more strongly to another two proteins of higher molecular weight. These studies confirm the same degree of specificity of HDL3 binding found with cultured adrenal cells and strengthen the suggested existence of a specific HDL receptor.     

Electron spin resonance investigation of the interaction of the anion and glucose transport inhibitor, p-azidobenzylphlorizin, with the human red cell membrane

The membrane perturbations caused by the interaction of p-azidobenzylphlorizin (p-AzBPhz), a potential photoaffinity labeling agent of the anion and D-glucose transporters in the human erythrocyte, have been studied using electron spin resonance (ESR) spectrometry. Two lipid-specific spin labels have been employed; one of these agents, a hexadecyl-quarternary amine with the nitroxide reporter group covalently attached to the cationic nitrogen, (CAT-16), has been used to monitor changes in the physical state of the membrane's extracellular phospholipid/water interface. The other spin label, 5-doxylstearic acid (5-NS), is designed to examine the order and motion of the lipid bilayer near the cell surface. In separate experiments, intact human red cells labeled with these lipid-specific spin labels were exposed to small amounts of the phlorizin azide. A dose-dependent alteration in CAT-16 motion was observed, but the p-AzBPhz interaction with the membrane had no effect on the spectrum of 5-NS. The half-maximal effect of the phlorizin derivative on the CAT-16 spectrum occurred when about 2 million molecules were bound to each cell. This is also the combined amount of band 3 and band 4.5 present in the red cell membrane and represents the concentration necessary to inhibit both anion and glucose transport. Our results suggest that the first p-AzBPhz molecules binding to the red cell membrane interact with the anion and sugar transporters, and not with the bulk lipid bilayer.     

Kainate Receptors in Xenopus Central Nervous System: Solubilisation with n-Octyl-β-d-Glucopyranoside

[3H]Kainate binding to membrane homogenates and detergent extracts prepared from Xenopus central nervous system was evaluated in 50 mM Tris-citrate buffer, pH 7.0. In membrane fragment preparations, [3H]kainate bound with a KD of 54.4 nM to a large number of sites (Bmax = 27.8 pmol/mg of protein). Up to 80% of the total number of membrane-bound binding sites were solubilised using the nonionic detergent n-octyl-beta-D-glucopyranoside. Values for the KD of [3H]kainate for solubilised binding sites were 46.0 nM and 53.6 nM derived from equilibrium and kinetic binding experiments, respectively. Competitive binding studies revealed that a variety of ligands had similar Ki values in both membranes and solubilised extracts, with domoate and kainate being the most potent inhibitors of [3H]kainate binding. The dissociation rate of [3H]kainate from solubilised binding sites was 0.022 min-1. The binding component migrated in sucrose density gradients in a single 8.6S peak. These results demonstrate that the kainate receptor in Xenopus central nervous system, although similar to the [3H]kainate binding site from goldfish brain, differs in a number of important respects. In particular, the slower dissociation rate and higher affinity of [3H]kainate suggest that Xenopus provides the most convenient model system yet investigated for biochemical analysis of kainate receptors.     

Detection of actin-binding proteins in human platelets by 125I-actin overlay of polyacrylamide gels

Actin-binding proteins have been identified in human platelets with a gel-overlay technique that uses 125I-G-actin. Platelet proteins were separated on SDS polyacrylamide gels using the buffer system of Laemmli (1970, Nature [Lond.] 227:680-685). The proteins were fixed in the gels with methanol-acetic acid, the SDS was washed out, and the proteins were renatured. The gels were incubated with 125I-G-actin from rabbit skeletal muscle that was radiolabeled with 125I according to the method of Bolton and Hunter (1973, Biochem. J. 133:529-538) and has been shown to retain biological activity. After nonspecifically bound radioactivity was washed out, gels were dried and processed for autoradiography. The 125I-G-actin binds to several proteins in human platelets, platelet extracts, and the particulate fraction. Control experiments demonstrate that the 125I-G-actin can be displaced by use of increasing amounts of unlabeled actin, that the binding is stable to 0.6 M NaCl, and that preheating the 125I-G-actin to 90 degrees C for 3 min eliminates all binding. Prominent 125I-G-actin-binding activities were present at Mr 90,000 and 40,000. The binding to the 90,000 Mr protein appears to be at least partially Ca++ sensitive, whereas the binding to the 40,000 Mr protein does not. 125I-G-actin bound to proteins in the SDS gels can be fixed in situ and compared directly with the stained gel. This technique should prove generally useful in identification and purification of some actin-binding proteins from cells and tissues.     

The binding of labelled basic proteins by boar spermatozoa.

Seminal plasma basic proteins were labelled with 131I. The efficiency of the labelling was studied by superimposing protein density traces on a radioactive fractionation plot. These labelled proteins were incubated with spermatozoa and shown to bind more readily to spermatozoa from boars after the removal of the vesicular glands than to spermatozoa obtained from their normal litter mates. Most of the labelled protein became bound to the membranes which were isolated by sucrose density gradient centrifugation. The membranes were separated into two bands which equilibrated at the relative densities of 1-150 and 1-165. These fractions consisted of membrane vesicles of different size; the smaller band on the gradient, which equilibrated at 1-165, consisted of denser membrane material.     

Structural and thermal stability characterization of Escherichia coli D-galactose/D-glucose-binding protein

The effect of temperature and glucose binding on the structure of the galactose/glucose-binding protein from Escherichia coli was investigated by circular dichroism, Fourier transform infrared spectroscopy, and steady-state and time-resolved fluorescence. The data showed that the glucose binding induces a moderate change of the secondary structure content of the protein and increases the protein thermal stability. The infrared spectroscopy data showed that some protein stretches, involved in alpha-helices and beta strand conformations, are particularly sensitive to temperature. The fluorescence studies showed that the intrinsic tryptophanyl fluorescence of the protein is well represented by a three-exponential model and that in the presence of glucose the protein adopts a structure less accessible to the solvent. The new insights on the structural properties of the galactose/glucose-binding protein can contribute to a better understanding of the protein functions and represent fundamental information for the development of biotechnological applications of the protein.