Multiple pathways for ligand internalization in rat hepatocytes. II: Effect of hyperosmolarity and contribution of fluid-phase endocytosis.

In a companion report (Moss and Ward: J. Cell. Physiol 149:313-318, 1991) evidence was presented for multiple pathways for insulin internalization based on differences between the internalization of insulin and that of two other ligands, asialofetuin (Afet) and epidermal growth factor (EGF), in the presence of several perturbations of endocytosis. In the present study we have explored the characteristics of three internalization pathways and the contribution of each to overall insulin uptake. Freshly isolated hepatocytes were incubated with radiolabeled ligands in the presence of hyperosmolar sucrose, treatment that is thought to inhibit the coated pit pathway of endocytosis. Insulin internalization was decreased approximately 39%, but much greater decreases were observed with Afet (86%) and EGF (62%). Competition between uptake of radiolabeled and unlabeled insulin was observed in hyperosmolar-treated cells, suggestive of endocytosis by a receptor-mediated noncoated-pit pathway. Uptake of radiolabeled insulin that persisted in the presence of hyperosmolarity and high concentrations of unlabeled insulin suggested a third uptake pathway: fluid-phase endocytosis. A rate of fluid-phase endocytosis of 7.2 microL/hr/10(6) cells was determined from the uptake of the fluid-phase marker lucifer yellow. At high insulin concentrations (greater than or equal to 250 ng/ml), fluid-phase endocytosis appears to be the predominant pathway for insulin uptake, but at lower insulin concentrations (physiological) the coated pit and noncoated pit pathways are the primary routes for insulin internalization.     

Composite response of naive T cells to stimulation with the autologous lymphoblastoid cell line is mediated by CD4 cytotoxic T cell clones and includes an Epstein-Barr virus-specific component.

We have approached the challenge of generating a primary T cell response to Epstein-Barr virus (EBV) in vitro by stimulating naive T cells with the autologous EBV-transformed lymphoblastoid cell line (LCL), a rich source of EBV-associated cytotoxic T lymphocyte (CTL) epitopes. Responsive T cells from three EBV-seronegative donors were cloned in agarose, phenotyped for T cell markers by flow cytometry, and their cytotoxic properties analyzed in the 51Cr release assay. Most clones (greater than 95%) expressed the CD4 phenotype and 59% of these clones showed cytotoxic properties. The dominant CTL response was specific for FCS-associated epitopes presented by FCS-grown autologous LCL target cells and was restricted by class II HLA antigens. Other clonal components included: (i) an EBV-specific response by HLA-restricted CD4 CTL clones that did not discriminate between A- and B-type EBV transformants; (ii) an EBV-specific response by an HLA-restricted CD4 CTL clone that discriminated between A- and B-type transformants, and (iii) a nonspecific cytotoxic response by CD3+,4+,8-, CD3+,4-,8-, and CD3-,4-,8- clones that were broadly allotypic or restricted to the lysis of K562 target cells. The EBV-specific CTL clones did not lyse the autologous EBV-negative B or T cell blasts and their specificity patterns of lysis were supported by the cold target competition data. These studies highlight the role of CD4 CTL in the establishment in vitro of a primary immune response to a human virus.     

Localization of lysosomal antigens in activated T-lymphocytes

Summary The lysosomal compartment has been examined in activated T-lymphocytes by immunogold electron microscopy and subcellular fractionation. Immunoprecipitation and sodium dodecyl sulphate-polyacrylamide gel, electrophoresis (SDS-PAGE) of radiolabelled extracts of the T-cells showed that they contained three antigens which are fundamental to normal lysosomal function: a representative lysosomal enzyme -glucuronidase, a lysosomal associated membrane protein (LAMP-1), and the cation-independent mannose 6-phosphate lysosomal enzyme targeting receptor (MPR). Immunogold labelling showed that -glucuronidase was present in the rough endoplasmic reticulum, the Golgi complex and Golgi-associated vesicles. The enzyme was also found to accumulate in distinct, non-Golgi organelles in which LAMP-1 was co-localized, probably lysosomes. LAMP-1 was also found in tubular elements of the golgi and in a complex of vesicles clustered near the nucleus where MPR was also present at high density.Fractionation of homogenates from lymphocytes on Percoll gradients revealed that -glucuronidase was distributed throughout the low density region containing rough endoplasmic reticulum, Golgi and plasma membrane components, and the high density region which contained only lysosomal activity. Multiple immunogold electron microscopy of the latter fraction showed the presence of homogenous vesicles which had large amounts of -glucuronidase within the lumen, LAMP-1 at the periphery and no MPR. These vesicles were probably mature lysosomes, arising from pre-lysosomal organelles enriched for LAMP-1 and MPR.     

Degradation of Microtubule-Associated Protein 2 and Brain Spectrin by Calpain: A Comparative Study

The in vitro degradation of microtubule-associated protein 2 (MAP-2) and spectrin by the calcium-dependent neutral protease calpain was studied. Five major results are reported. First, MAP-2 isolated from twice-cycled microtubules (2 X MT MAP-2) was extremely sensitive to calpain-induced hydrolysis. Even at an enzyme-to-substrate ratio (wt/wt) of 1:200, 2 X MT MAP-2 was significantly degraded by calpain. Second, MAP-2 purified from the total brain heat-stable fraction (total MAP-2) was significantly more resistant to calpain-induced hydrolysis compared with 2 X MT MAP-2. Third, MAP-2a and MAP-2b were proteolyzed similarly by calpain, although some relative resistance of MAP-2b was observed. Fourth, the presence of calmodulin significantly increased the extent of calpain-induced hydrolysis of the alpha-subunit of spectrin. Fifth, the two neuronal isoforms of brain spectrin (240/235 and 240/235E, referred to as alpha/beta N and alpha/beta E, respectively) showed different sensitivities to calpain. alpha N-spectrin was significantly more sensitive to calpain-induced degradation compared to alpha E-spectrin. Among other things, these results suggest a role for the calpain-induced degradation of MAP-2, as well as spectrin, in such physiological processes as alterations in synaptic efficacy, dendritic remodeling, and in pathological processes associated with neurodegeneration.     

Myosin light chain 2 modulates calcium-sensitive cross-bridge transitions in vertebrate skeletal muscle.

We investigated the mechanism of the Ca2+ sensitivity of cross-bridge transitions that limit the rate of force development in vertebrate skeletal muscle. The rate of force development increases with Ca2+ concentration in the physiological range. We show here that at low concentrations of Ca2+ the rate of force development increases after partial extraction of the 20-kD light chain 2 subunit of myosin, whereas reconstitution with light chain 2 fully restores native sensitivity to Ca2+ in skinned single skeletal fibers. Furthermore, elevated free Mg2+ concentration reduces Ca2+ sensitivity, an effect that is reversed by extraction of the light chain but not by disruption of thin-filament activation by partial removal of troponin C, the Ca2+ binding protein of the thin filament. Our findings indicate that the Ca2+ sensitivity of the rate of force development in vertebrate skeletal muscle is mediated in part by the light chain 2 subunit of the myosin cross-bridge.     

Slow voltage inactivation of Ca2+ currents and bursting mechanisms for the mouse pancreatic beta-cell

Summary Recent whole-cell electrophysiological data concerning the properties of the Ca²⁺ currents in mouse -cells are fitted by a two-current model of Ca²⁺ channel kinetics. When the -cell K⁺ currents are added to this model, only large modifications of the measured Ca²⁺ currents will reproduce the bursting pattern normally observed in mouse islets. However, when the measured Ca²⁺ currents are modified only slightly and used in conjunction with a K⁺ conductance that can be modulated dynamically by ATP concentration, reasonable bursting is obtained. Under these conditions it is the K-ATP conductance, rather than the slow voltage inactivation of the Ca²⁺ current, that determines the interburst interval. We find that this latter model can be reconciled with experiments that limit the possible periodic variation of the K-ATP conductance and with recent observations of intracellular Ca²⁺ bursting in isletsThis work was supported in part by NSF grant DIR-90-06104 and the Agricultural Experiment Station of the University of California. P.S. gratefully acknowledges financial support from an NRC Fellowship. We have benefited from numerous conversations with Drs. John Rinzel, Arthur Sherman, Daniel Cook, and Leslie Satin