Endothelial cells reestablish functional integrity after reversible permeabilization.

Permeabilization is an important tool in cell biology that allows manipulation of intracellular mechanisms by introduction of probes and regulatory molecules into the cell cytoplasm. We found that incubation of endothelial cells (ECs) with glass beads resulted in nonspecific permeabilization of human and bovine ECs without removal of the cells from monolayer culture. This poration of the plasma membrane allowed the introduction of macromolecules (dextrans less than or equal to 152 kd and immunoglobulins) as well as small, charged molecules (Lucifer Yellow). We found that nonspecific permeabilization of the EC was transient and defined the conditions under which integrity of the plasma membrane was reestablished. This process was dependent on time, temperature, and the presence of extracellular calcium. We also demonstrated that permeabilized ECs regain functional characteristics. This was defined by a number of criteria, including the ability to rapidly reestablish confluent monolayer morphology, to extrude Lucifer Yellow, to adhere and spread after passage, and to synthesize biologically active molecules after stimulation with a receptor-mediated agonist. Thus, transiently porated ECs loaded with appropriate probes can be used in studies of regulatory mechanisms while remaining in monolayer culture, a condition in which many phenotypic features are similar to in situ endothelium. Furthermore, the porated EC may be a useful model for defining the mechanisms that influence the repair of endothelial plasma membrane injury.

Synthesis of platelet-activating factor by endothelial cells. The role of G proteins.

Production of the potent lipid autacoid, platelet-activating factor (PAF), is a stimulated response of the endothelium which has important physiologic consequences including mediating adherence of inflammatory cells to the endothelium. Consequently, an understanding of the mechanisms that regulate PAF synthesis by the endothelium is important. To this end, we investigated the role of G proteins as a component of the signal transduction pathway that couples hormonal stimuli to PAF production. The addition of aluminum fluoride (AlF-4) to endothelial cells resulted in production of PAF with a maximal effect at 20 mM fluoride and within 20-60 min of exposure. Alf-4 also augmented the production of PAF which occurs in response to hormonal agonists. In addition, submaximal concentrations of AlF-4 converted an ineffective hormonal agonist (thrombin in bovine cells) to a maximally effective agonist. The adherence of neutrophils to endothelial cells that had been exposed previously to AlF-4 was increased in a manner that paralleled PAF production. PAF production in response to AlF-4 was not consistently affected by pertussis or cholera toxin. Introduction of guanosine 5'-O-(3-thiotriphosphate) (GTP gamma S) into permeabilized endothelial cells also resulted in PAF production, with reversal by guanosine 5'-O-(2-thiodiphosphate) (GDP beta S), consistent with an effect mediated by a G protein. G protein activation with AlF-4 or GTP gamma S resulted in entry of extracellular Ca2+ as determined using 45Ca2+ flux studies and Indo-1 spectrofluorometry. Our data are consistent with the hypothesis that G proteins couple hormone-receptor binding to opening of a membrane calcium channel, a key step in the initiation of PAF production in endothelial cells.