Possible participation of calmodulin in stimulation of leucine transport by concanavalin A in human lymphocytes

[Studies on the cytological function of the biomembrane and the neurons]

Na(+)-dependent and -independent transport sites were elucidated for glycine and L-leucine, respectively, in Chang liver cells, a human culture cell line. Findings of acceleration of the L-leucine uptake by the cells in the acidic medium and synchronized acidification within the cell membrane vesicles with the uptake by them all suggested contransport of L-leucine and proton and the uptake of L-leucine dependent on the inward proton gradient in Chang liver cells. Cotransport of L-leucine and proton was also demonstrated in human peripheral lymphocytes and accelerated by the addition of concanavalin A, probably accompanied by membrane hyperpolarization. It was shown that the Na(+)-gradient-dependent uptake of glycine can be regulated by insulin and 17 beta-estradiol in the rat uterus and by Ca(2+)-calmodulin and membrane potential in Chang liver cells. D-Aspartate uptake as a model of glutamate transport was characterized in rat hippocampal slices and found to consist of Na(+)-dependent (higher-affinity) and -independent (lower-affinity) components. The vulnerability of hippocampal neurons to the Alzheimer beta-amyloid protein was confirmed in vitro with primary cultured rat hippocampal neurons in the presence of the amyloid protein beta 1-42 or its core fragments. The toxicity of the amyloid protein could be blocked by the addition of insulin and several other growth factors to the medium. The addition of genipin, a plant-derived iridoid, was demonstrated to prevent the toxicity of a synthetic fragment of beta 1-42, beta 25-35. Genipin had a neuritogenic activity in PC12h cells, a rat pheochromocytoma cell line, an activity extremely sensitive to inhibitors of the nitrogen oxide (NO) synthase and soluble guanylate cyclase and an NO scavenger. It was also demonstrated in PC12h cells that the activation of the MAP kinase cascade was essential for the neuritogenesis of genipin. These properties of genipin are very comparable to those of nerve growth factor in the cells. It is considered likely that various useful, neurotrophic substances and their extracts will be found in plants in future.

Mechanism of carbachol-stimulated diacylglycerol formation in rat parotid acinar cells

We studied the relationship between phosphoinositide hydrolysis, phosphatidylcholine hydrolysis, and sn-1,2-diacylglycerol (DAG) formation in response to carbachol stimulation in rat parotid acinar cells. Previously, we demonstrated that DAG formation stimulated with 1 microM carbachol was biphasic: the first peak occurred at 5 min and the second one at 20 min. It was also demonstrated that the second peak was regulated in part by a calmodulin/protein kinase C-dependent mechanism. Based on the kinetic analysis of DAG formation and [32P]phosphoinositide breakdown, the first peak of carbachol (1 microM)-stimulated DAG accumulation was found to be related to the breakdown of [32P]phosphatidylinositol 4-monophosphate ([32P]PIP) and [32P]phosphatidylinositol 4,5-bisphosphate ([32P]PIP2). The second peak was found to be related to [32P]PIP2 breakdown. Carbachol stimulated the release of [3H]phosphocholine into the medium, indicating that the predominant pathway for phosphatidylcholine hydrolysis was via phospholipase C. Moreover, carbachol stimulated the release of [3H]choline metabolites in a time- and dose-dependent manner. This agonist slightly stimulated the release of [3H]ethanolamine metabolites. A calmodulin/protein kinase C-dependent mechanism was also studied and was found to be involved in carbachol-stimulated phosphatidylcholine hydrolysis; W-7, a calmodulin inhibitor and staurosporine, a protein kinase C inhibitor, inhibited the carbachol (1-microM)-induced release of [3H]choline metabolites at 20 min in a dose-dependent manner, but did not have inhibitory effects at 5 min. These results suggest that the first peak of DAG accumulation induced by carbachol is predominantly associated with the breakdown [32P]PIP and of [32P]PIP2 and that the second peak is predominantly associated with [32P]PIP2 breakdown and phosphatidylcholine hydrolysis.

Protein kinase C-dependent diacylglycerol formation is mediated via Ca2+/calmodulin in parotid cells

The kinetics of carbachol-induced sn-1,2-diacylglycerol (DAG) formation and the underlying mechanism(s) involved in parotid acinar cells were investigated. Supramaximal concentrations of carbachol for amylase secretion (10 microM) caused a transient rise in DAG levels at 10 s. In contrast, this rapid rise was not elicited by 1 microM carbachol, which is the maximally effective concentration for amylase secretion. Carbachol (10 microM) also increased DAG levels linearly up to 20 min, which were sustained for up to a further 10 min. DAG formation stimulated by 1 microM carbachol was biphasic; the first peak was observed after 5 min and the second after 20 min. DAG formation induced by 0.01-0.1 microM carbachol was concentration-dependent and monophasic, peaking at 5 min. The second peak evoked by carbachol was partly inhibited by Ca2+ deprivation from the extracellular space, whereas the first peak was not. Similar results were obtained in experiments using Ca2+ antagonists such as verapamil and LaCl3. The protein kinase C inhibitors, 1-(5-isoquinolinesulfonyl)-2-methylpiperazine (H-7) and staurosporine, and a calmodulin antagonist, N-(6-aminohexyl)-5-chloro-1-naphthalenesulfonamide (W-7), significantly inhibited the second DAG peak produced by 1 microM carbachol, but did not alter the first peak. The degree of inhibition of the second peak by these antagonists was comparable. Furthermore, the inhibitory effect of staurosporine and W-7 was concentration-dependent. The A23187-induced accumulation of DAG also was abolished by both staurosporine and W-7. These data indicate that a protein kinase C-dependent mechanism(s) is involved in mediating the second DAG accumulation peak induced by 1 microM carbachol and is mainly regulated by the Ca(2+)-calmodulin complex.