Effect of ganglioside GM1 on arachidonic acid release in bovine aortic endothelial cells.

A role for the ganglioside GM1 in arachidonic acid release in bovine aortic endothelial cells (BAEC) was investigated. [3H]Arachidonic acid-labeled BAEC were preincubated with GM1 and incubated with one of four different stimulators. GM1 inhibited arachidonic acid release when stimulated with maitotoxin or melittin but not with ionomycin or thapsigargin. A 10 microM GM1 concentration achieved a 50% and 100% inhibition of the maitotoxin and melittin responses, respectively. The selective inhibition displayed by GM1 on the maitotoxin and melittin responses was not due to its ability to bind calcium since all four drugs, maitotoxin, melittin, ionomycin, and thapsigargin, required extracellular calcium. The effect of GM1 was not specific to arachidonic acid release. GM1 at 50 microM inhibited phosphatidylinositol polyphosphate (PIP) hydrolysis mediated by melittin, but did not affect hydrolysis mediated by ionomycin. Moreover, the activity of GM1 was not restricted to phospholipid metabolism since it also inhibited calcium influx that was stimulated by maitotoxin or melittin but not by ionomycin. We conclude that GM1 is not a specific inhibitor of phospholipases in bovine aortic endothelial cells, but rather its activity is dependent on the type of stimulant used to activate the cell.

Retinal microvessels express less gamma-glutamyl transpeptidase than brain microvessels.

In this investigation we localized and compared the level of gamma-glutamyl transpeptidase (GGTP) activity in retinal and brain preparations using histochemical, enzymatic and in situ hybridization assays. We compared GGTP distribution to another microvessel specific enzyme, alkaline phosphatase (AP). In the rat brain, GGTP activity was observed in microvessels and choroid plexus by a histochemical method. Similar studies in the rat retina revealed activity in the pigment epithelium but only a very weak reaction in microvessels. Histochemical staining for alkaline phosphatase was observed in both retinal and brain microvessels choroid plexus and pigment epithelium. Biochemical analysis verified that GGTP activity was significantly lower in retinal than brain microvessels, while alkaline phosphatase activity was similar in both types of microvessels. GGTP specific activity of bovine brain and retinal microvessels was 185 +/- 39 mUnits and 8.5 +/- 1.5 mUnits (p less than 0.001), respectively. By contrast, alkaline phosphatase specific activity in brain and retinal microvessels was 732 +/- 139 and 471 +/- 114 (p greater than 0.1), respectively. Choroid plexus and retinal pigment epithelium exhibited similar levels of GGTP and alkaline phosphatase. Differences in GGTP expression between retinal and brain microvessels were also observed on the mRNA level. In situ hybridization studies revealed that brain microvessels expressed four times more GGTP specific mRNA than retinal microvessels. We conclude that retinal microvessels do not express high levels of GGTP which may make them more vulnerable than brain microvessels to injuries mediated by leukotrienes and oxidative stress.

Phosphorylation of membrane proteins in erythrocytes treated with lead.

In immature rat microvessels, endothelial cells and glioma cells, exposure to lead results in an increase in the level of protein kinase C in membranes. In this paper we have extended these studies to human erythrocytes and, in addition, studied the phosphorylation of membrane proteins. A significant increase in the phosphorylation of membrane cytoskeletal proteins of molecular mass 120, 80, 52 and 45 kDa was observed in human erythrocytes treated for 60 min with lead acetate at concentrations greater than 100 nM. These same proteins were phosphorylated when erythrocytes were treated for 10 min with 50 nM phorbol 12-myristate 13-acetate (PMA). Similarly, protein kinase C activity was elevated and an increase in the amount of protein kinase C-alpha was observed in membranes from erythrocytes exposed to concentrations of lead acetate above 100 nM. No changes, however, in the activities of cAMP-dependent protein kinase, protein phosphatases I and IIA or casein kinase were observed. Phosphorylation of these membrane proteins stimulated by lead acetate or by PMA was not observed in erythrocytes depleted of protein kinase C by a 72-h treatment with 500 nM phorbol 12,13-dibutyrate. Finally, no changes in the levels of calcium or diacylglycerol were observed in erythrocytes stimulated with 100 nM lead acetate. These results indicate that, in erythrocytes, lead acetate stimulates the phosphorylation of membrane cytoskeletal proteins by a mechanism dependent on protein kinase C. Since levels of calcium or diacylglycerols did not increase, it appears that lead may activate the enzyme by a direct interaction.

Gamma-glutamyl transpeptidase activity in brain microvessels exhibits regional heterogeneity.

Brain microvessels form a tight blood-tissue permeability barrier and express high levels of specific enzymes, including gamma-glutamyl transpeptidase (GGTP). This differentiation is thought to be induced by perivascular astrocytes. By using histochemical methods, we found that the percentage of GGTP-positive vessels varied considerably in different areas of rat brain. Enzyme activity was not found in the pineal gland or the median eminence, where the blood-brain barrier is not expressed. In areas where the blood-brain barrier is expressed, the percentage of GGTP-positive vessels varied from 8% in the optic nerve to 100% in the anterior commissure. The neocortex showed a lower percentage of GGTP-positive vessels (2-15%) than anterior olfactory nucleus (42%), subiculum (70%), hippocampus (48%), and striatum (50-58%). Alkaline phosphatase, another brain microvessel-enriched enzyme, did not show these marked regional differences. The morphometric histochemical results were verified by enzymatic assays in homogenates of different regions from rat and bovine brain and in microvessel preparations of bovine putamen and neocortex. During the postnatal development of rat brain, the difference between neocortex and striatum appeared after day 20. The regional heterogeneity of brain microvessels may be caused by astrocytic heterogeneity and reflect regional heterogeneity in microvascular function.

Distinct mechanisms of neurotransmitter release from PC 12 cells exposed to lead.

Two enzymes, protein kinase C and microsomal Ca(2+)-ATPase help regulate levels of Ca2+ in many types of cells. Since proteins that regulate Ca2+ often influence sensitivity to Pb2+, we determined the possible roles played by protein kinase C and microsomal Ca(2+)-ATPase for the Pb(2+)-evoked release of norepinephrine (NOR) in PC cells. NOR release was observed at 10 microM Pb2+ when PC 12 cells were stimulated with inhibitors of microsomal Ca(2+)-ATPase such as thapsigargin, cyclopiazonic acid, or 2,5-di-(t-butyl)-hydroquinone. At 5 microM, Pb2+ evoked the release of NOR in PC 12 cells stimulated with activators of protein kinase C such as phorbol 12-myristate 13-acetate (PMA) or (-)-7-octylindolactam. NOR release was observed at 1 microM Pb2+ in the presence of both PMA and thapsigargin. Ni2+ and Cd2+ blocked NOR release stimulated by Pb2+ in the presence of thapsigargin but not by PMA. NOR released by thapsigargin stimulation was not altered in PC 12 cells depleted of protein kinase C. Two proteins found in vesicles, chromogranin B and secretogranin-II were released with NOR. Our results indicate that in PC 12 cells, PB(2+)-evokes the release of neurotransmitters. Furthermore, thapsigargin and PMA increase the cell's sensitivity to Pb2+ by different pathways.

Inhibition of astroglia-induced endothelial differentiation by inorganic lead: a role for protein kinase C.

Microvascular endothelial function in developing brain is particularly sensitive to lead toxicity, and it has been hypothesized that this results from the modulation of protein kinase C (PKC) by lead. We examined the effects of inorganic lead on an in vitro model of central nervous system endothelial differentiation in which astroglial cells induce central nervous system endothelial cells to form capillary-like structures. Capillary-like structure formation within C6 astroglial-endothelial cocultures was inhibited by lead acetate with 50% maximal inhibition at 0.5 microM total lead. Inhibition was independent of effects on cell viability or growth. Under conditions that inhibited capillary-like structure formation, we found that lead increased membrane-associated PKC in both C6 astroglial and endothelial cells. Prolonged exposure of C6 cells to 5 microM lead for up to 16 h resulted in a time-dependent increase in membranous PKC as determined by immunoblot analysis. Membranous PKC increased after 5-h exposures to as little as 50 nM lead and was maximal at approximately 1 microM. Phorbol esters were used to determine whether PKC modulation was causally related to the inhibition of endothelial differentiation by lead. Phorbol 12-myristate 13-acetate (10 nM) inhibited capillary-like structure formation by 65 +/- 5%, whereas 4 alpha-phorbol 12,13-didecanoate was without effect. These findings suggest that inorganic lead induces cerebral microvessel dysfunction by interfering with PKC modulation in microvascular endothelial or perivascular astroglial cells.