Arginine-modulated receptor-activated calcium influx via a NO/cyclic GMP pathway in human SK-N-SH neuroblastoma cells.

The effects of arginine on calcium mobilization in human SK-N-SH neuroblastoma cells were examined. It was found that arginine potentiated an increase in carbachol-induced Ca2+ from the external Ca2+ influx as opposed to an internal Ca2+ release from intracellular pools. The potentiation effect of arginine on carbachol-induced calcium mobilization was mimicked by either 8-bromo cyclic GMP or sodium nitroprusside. In addition, it was found that arginine induced NO production and an increase in cyclic GMP. Moreover, arginine-induced potentiation, NO production, and cyclic GMP increases were all suppressed after the preincubation of cells with N-methyl-L-arginine or N-nitro-L-arginine, nitric oxide synthase inhibitor. It is suggested that the NO production and subsequent cyclic GMP elevation induced by arginine are responsible for the potentiation of carbachol-induced Ca2+ increase. Our results show the existence of a NO/cyclic GMP pathway and an interconnection of NO and Ca2+ signaling pathways in human SK-N-SH neuroblastoma cells. We also observed that NO, which is produced by endothelial CPAE cells, has a modulating effect on cyclic GMP elevation in human SK-N-SH neuroblastoma cells. The intercellular communication role of NO and its cell-diffusing character may also affect the regulation of nonneuronal cells in their interactions with neuronal cells.

Interaction of acridines and tetrahydroacridines with DNA at low DNA/dye ratios.

This study examines certain aspects of the interaction of acridines with DNA. A comparative study of the methods available for the determination of the association constants (Kap) for compounds which interact with DNA has been pursued. A new equation which permits the spectrophotomeric determination of Kap has been derived. This equation can be applied to compounds which upon interaction with a polymer exhibit discrete absorption changes. Application of this equation to substituted acridines and tetrahydroacridines yields some preliminary information on the effect of ring substituents on the interaction of acridines with DNA. Low levels of DNA/dye ratios have been used in the studies reported herein.

Diacridines: bifunctional intercalators. I. Chemistry, physical chemistry and growth inhibitory properties.

The synthesis, as well as the rationale for synthesis of diacridines, double intercalators, as potential inhibitors of nucleic acid synthesis is presented. The syntheses of (9-acridyl)-putrescine and -spermine, and bis(-9-acridyl)-putrescine, -spermidine, -spermine diamines and of bis(6-chloro-2-methoxy-9-acridyl)-putrescine and -spermine diamines, all substituted on the terminal NH2 groups are described. In addition, the homologous series of diacridines connected by the amino groups of the diamines NH2(CH2)nNH2 (where n = 2,3,4,6,8,10,12,14,16,18) to the C-9 of the diacridines has been synthesized. The chemical properties of these compounds as well as their molecular relationship to DNA are presented. The effect of the double intercalators on the Tm of DNA and of (A)n - (U)n, (dA)n - (dT)n, (G)n - (C)n and on (dG)n - (dC)n have been determined. The double acridine intercalators produce a much greater increase of the Tm of these nucleic acids than do the single acridine intercalators. They also profoundly affect the Tm of DNA in physiological salt concentrations; under these latter conditions the single intercalators have no effect. The relationship between the length of the chain connecting the two acridine rings and the inhibition of the growth of P-388 cells in vitro and vivo is presented. Their growth inhibitory properties appear, in general, to parallel their intercalative abilities.