Glucose transporter isotypes switch in T-antigen-transformed pancreatic beta cells growing in culture and in mice.

High-level expression of the low-Km glucose transporter isoform GLUT-1 is characteristic of many cultured tumor and oncogene-transformed cells. In this study, we tested whether induction of GLUT-1 occurs in tumors in vivo. Normal mouse beta islet cells express the high-Km (approximately 20 mM) glucose transporter isoform GLUT-2 but not the low-Km (1 to 3 mM) GLUT-1. In contrast, a beta cell line derived from an insulinoma arising in a transgenic mouse harboring an insulin-promoted simian virus 40 T-antigen oncogene (beta TC3) expressed very low levels of GLUT-2 but high levels of GLUT-1. GLUT-1 protein was not detectable on the plasma membrane of islets or tumors of the transgenic mice but was induced in high amounts when the tumor-derived beta TC3 cells were grown in tissue culture. GLUT-1 expression in secondary tumors formed after injection of beta TC3 cells into mice was reduced. Thus, high-level expression of GLUT-1 in these tumor cells is characteristic of culture conditions and is not induced by the oncogenic transformation; indeed, overnight culture of normal pancreatic islets causes induction of GLUT-1. We also investigated the relationship between expression of the different glucose transporter isoforms by islet and tumor cells and induction of insulin secretion by glucose. Prehyperplastic transgenic islet cells that expressed normal levels of GLUT-2 and no detectable GLUT-1 exhibited an increased sensitivity to glucose, as evidenced by maximal insulin secretion at lower glucose concentrations, compared with that exhibited by normal islets. Further, hyperplastic islets and primary and secondary tumors expressed low levels of GLUT-2 and no detectable GLUT-1 on the plasma membrane; these cells exhibited high basal insulin secretion and responded poorly to an increase in extracellular glucose. Thus, abnormal glucose-induced secretion of insulin in prehyperplastic islets in mice was independent of changes in GLUT-2 expression and did not require induction of GLUT-1 expression.     

Function of the CD4 and CD8 molecules on human cytotoxic T lymphocytes: regulation of T cell triggering

The function of the T cell differentiation antigens CD4 (Leu-3/T4) and CD8 (Leu-2/T8) on human cytotoxic T lymphocytes (CTL) is presently seen only in conjugate formation between CTL and target cell via class II or class I MHC antigens rather than in the later killing steps. In this study, human CD4+ and CD8+ CTL clones were used to investigate the effects of monoclonal antibodies against these differentiation antigens on nonspecific triggering of cytotoxicity. Cytotoxicity was induced either by antibodies against the CD3 (T3) antigen or by the lectins Con A and PHA. Anti-CD4 or anti-CD8 antibodies specifically inhibited all types of cytotoxicity of CD4+ or CD8+ CTL, respectively, regardless of the specificity of the CTL for class I or class II HLA antigens and regardless of whether target cells expressed class I or class II antigens. These results are incompatible with an exclusive role of the CD4 and CD8 molecules in MHC class recognition and are discussed with respect to a function as negative signal receptors for these molecules on CTL.     

Site-site interaction in the phospholipid activation of D-beta-hydroxybutyrate dehydrogenase

D-beta-Hydroxybutyrate dehydrogenase is a lipid-requiring enzyme with absolute specificity for phosphatidylcholine (PC). The enzyme devoid of lipid, the apodehydrogenase, inserts spontaneously into phospholipid vesicles where it exists as a tetramer. We now find the lipid activation to be limited by the mole fraction of PC in the total phospholipid. These studies suggest that the concentration of the enzyme-PC complex, which is essential for enzymic activity, becomes diffusion limited at lower PC concentration. The lipid activation and the tryptophan fluorescence of purified D-beta-hydroxybutyrate dehydrogenase were studied in the presence of a constant "bilayer background" of approximately 100 nonactivating phospholipid molecules/enzyme monomer. Activation by PC was half-maximal at 20 PC molecules/enzyme monomer. This value was doubled when the amount of "background" phospholipid was doubled. Activation proceeded with positive cooperativity having a Hill coefficient of approximately 2.4. These data indicate interactions between at least three PC-binding sites. The quenching of tryptophan fluorescence by the phospholipid activator, 1-palmitoyl-2-(1-pyrenyl)-decanoyl-PC (2-pyrenyl-PC), gives a saturation curve with half-maximal quenching of 6 quencher molecules/enzyme monomer. This value is equivalent to an apparent phospholipid-protein dissociation constant in the two-dimensional membrane and corresponds to approximately 6 mol % of total phospholipid. In distinct contrast to the phospholipid activation curve, the fluorescence quenching saturation curve was hyperbolic and there was no specificity for PC. The fluorescence quenching by 2-pyrenyl-PC could be diminished by using a several-fold excess of PC or other phospholipids so as to reduce the mole fraction of quencher in the bilayer. It would appear that formation of enzyme-PC complex is a dynamic process consisting of at least two discernible steps: 1) a primary interaction, as measured by tryptophan quenching, which is hyperbolic and not specific for lecithin. This interaction is independent from and precedes 2) phospholipid activation of D-beta-hydroxybutyrate dehydrogenase, which is cooperative in nature and specific for lecithin.     

The determination of the separate Ca pump protein and phospholipid profile structures within reconstituted sarcoplasmic reticulum membranes via X-ray and neutron diffraction

We have previously compared the electron density profiles for several highly-functional reconstituted sarcoplasmic reticulum membranes with that for the isolated sarcoplasmic reticulum membrane (Herbette, L., Scarpa, A., Blasie, J.K., Wang, C.T., Saito, A. and Fleischer, S. (1981) Biophys. J. 36, 47–72). In this paper, we compare the separate calcium pump protein profile within these reconstituted sarcoplasmic reticulum membranes, as derived by X-ray and neutron diffraction methods, with that within isolated sarcoplasmic reticulum membranes. In addition, the time-average perturbation of the lipid bilayer by the incorporated calcium pump protein within these reconstituted sarcoplasmic reticulum membranes has been determined in some detail.     

Morphology of isolated triads

The triad is the junctional association of transverse tubule with sarcoplasmic reticulum terminal cisternae. A procedure for the isolation of highly enriched triads from skeletal muscle has been described in the previous paper. In the present study, the structural features of isolated triads have been examined by thin-section, negative-staining, and freeze-fracture electron microscopy. In isolated triads, key features of the structure observed in situ have been retained, including the osmiophilic "feet," junctional structures between the transverse tubule and terminal cisternae. New insight into triad structure is obtained by negative staining, which also enables visualization of feet at the junctional face of the terminal cisternae, whereas smaller surface particles, characteristic of calcium pump protein, are not visualized there. Therefore, the junctional face is different from the remainder of the sarcoplasmic reticulum membrane. Junctional feet as viewed by thin section or negative staining have similar periodicity and extend approximately 100 A from the surface of the membrane. Freeze-fracture of isolated triads reveals blocklike structures associated with the membrane of the terminal cisternae at the junctional face, interjunctional connections between the terminal cisternae and t-tubule, and intragap particles. The intragap particles can be observed to be closely associated with the t-tubule. The structure of isolated triads is susceptible to osmotic and salt perturbation, and examples are given regarding differential effects on transverse tubules and terminal cisternae. Conditions that adversely affect morphology must be considered in experimentation with triads as well as in their preparation and handling.     

Purification of morphologically intact triad structures from skeletal muscle

A procedure has been devised for isolation of triads (t-tubule/sarcoplasmic reticulum (SR) junctional complexes) from rabbit skeletal muscle. The procedure consists of preparation of a heavy microsomal fraction followed by two sequential 90-min sucrose gradient centrifugations to enrich the triads. A pyrophosphate/phosphate/magnesium buffer system was introduced to decrease aggregation in order to achieve effective separation. The preparation time is 12 h. Some differences between purified triads isolated by two variants of this method are noted. The purity of the triad fractions has been estimated by particle counting to be in the vicinity of 50%. There is good retention of morphology and Ca++-loading activity and enrichment in Na+,K+-ATPase and adenylate cyclase. The triads are practically devoid of contractile elements, mitochondria, and free plasmalemma, and low in content of light SR. The method for obtaining enriched triads is reproducible, and sufficient yields are obtained for structural, biochemical, and functional characterization.     

Study of water and oil diffusion in rape seeds with sorption-desorption and NMR techniques.

The sorption and desorption of water in rape seeds was measured. From the sorption isotherm it follows that for water content greater than about 6% the water molecules tend to form clusters. The mutual diffusion coefficient of water into and out of the seeds was determined from the time dependence of sorption and desorption. There is a pronounced hysteresis in the sorption-desorption process, desorption proceeds faster than sorption. The self-diffusion of water (at maximum humidity of the seeds) and oil within the seeds was investigated by the pulsed field gradient NMR. The measurement of oil self-diffusion shows restricted diffusion of the oil within droplets and allows the determination of the droplet radii and their distribution width.     

The use of amphipathic maleimides to study membrane-associated proteins

A series of amphiphilic polymethylenecarboxymaleimides has been synthesized for use as sulfhydryl reagents applicable to membrane proteins. Physical properties of the compounds which are relevant to their proposed mode of action have been determined. By comparing rates of reaction in aqueous and aprotic solvents, the compounds have been shown to react exclusively with the thiolate ion. The effects of the reagents on three membrane-associated proteins are reported, and in two cases a comparative study has been made of the effects on the proteins in the absence of membranes. A mechanism is proposed whereby the reagents are anchored at the lipid/water interface by the negatively charged carboxyl group, thus siting the reactive maleimide in a plane whose depth is defined by the length of the reagent. Supporting evidence for this model is provided by the inability of the reagents to traverse membranes, and variation of their inhibitory potency with chain length when the proteins are embedded in the membrane, but not when extracted into solution. As examples of general use of the reagents to probe sulfhydryl groups in membrane proteins, the reagents have been used to (a) determine the depths in the membrane at which two populations of sulfhydryl groups occur in the mitochondrial phosphate transporter; (b) locate a single sulfhydryl associated with the active site ofD--hydroxybutyrate dehydrogenase in the inner mitochondrial membrane; (c) examine sulfhydryl groups in theD-3-glyceraldehyde phosphate dehydrogenase associated with the human red blood cell membrane.     

Localization of calmodulin binding sites on the ryanodine receptor from skeletal muscle by electron microscopy.

Calmodulin (CaM) is a regulator of the calcium release channel (ryanodine receptor) of the sarcoplasmic reticulum of skeletal and cardiac muscle. The locations where CaM binds on the surface of the skeletal muscle ryanodine receptor were determined by electron microscopy. Wheat germ CaM was labeled specifically at Cys-27 with a maleimide derivative of a 1.4-nm-diameter gold cluster, and the gold-cluster-labeled CaM was bound to the purified ryanodine receptor. The complexes were imaged in the frozen-hydrated state by cryoelectron microscopy with no stains or fixatives present. In the micrographs, gold clusters were frequently observed near the corners of the square-shaped images of the ryanodine receptors. In some images, all four corners of the receptor were occupied by gold clusters. Image averaging allowed the site of CaM binding to be determined in two dimensions with an estimated precision of 4 nm. No changes were apparent in the quaternary structure of the ryanodine receptor upon binding CaM to the resolution attained, about 3 nm. Side views of the ryanodine receptor, in which the receptor is oriented approximately perpendicular to the much more frequent fourfold symmetric views, were occasionally observed, and showed that the CaM binding site is most likely on the surface of the receptor that faces the cytoplasm. We conclude that the CaM binding site is at least 10 nm from the transmembrane channel of the receptor and, consequently, that long-range conformational changes are involved in the modulation of the calcium channel activity of the receptor by CaM.