Oxidative modification of neurogranin by nitric oxide: an amperometric study.

Neurogranin (Ng) is a neuron-specific protein kinase C (PKC) substrate, which contains four cysteine (Cys) residues. Recently, it has been shown that Ng is a redox-sensitive protein and is a likely target of nitric oxide (NO) and other oxidants [F.-S. Sheu, C.W. Mahoney, K. Seki, K.-P. Huang, Nitric oxide modification of rat brain neurogranin affects its phosphorylation by protein kinase C and affinity for calmodulin, J. Biol. Chem. 271 (1996) 22407-22413: J. Li, J.H. Pak, F.L. Huang, K.-P. Huang, N-methyl-D-aspartate induces neurogranin/RC3 oxidation in rat brain slices, J. Biol. Chem. 274 (1999) 1294-1300]. In this study, we directly examine the redox reactions between dissolved NO and Cys as well as between NO and bacterial expressed Ng in its reduced form, at concentrations approximate to the physiological levels in phosphate buffer solution (PBS) under aerobic conditions. The reaction kinetics are measured directly by our newly developed electrochemical sensor. Our sensor is based on the chemical modification of electrode with immobilized nanoparticles of transition metal palladium (Pd) which serves as catalytic centers for the electrochemical oxidation of thiol and NO selectively and quantitatively at different potentials. It detects Cys and Ng in a linear range from nano to micromolar concentration at + 450 mV, vs. a saturated calomel reference electrode (SCE), while the detection of NO at the sensor can be optimally achieved at + 700 mV (vs. SCE) with a linear current-to-concentration range of nM to microM. It thus provides a selective control to monitor two reactants independently. With this sensor as a detector, we found that (1) the oxidation of either Cys or Ng by NO is a fast reaction which reaches a near completion within 1-2 min at its physiological concentration; and (2) after the completion of reaction, NO is mostly, if not all, regenerated, an observation consistent with the reaction mechanism involving the formation of S-nitrosothiol as an intermediate. The reaction kinetics of both NO to Cys and NO to Ng implies that NO can achieve local action on cellular proteins in addition to its effect on targets located in neighboring cells via concentration-gradient-dependent diffusion.

[Inhibitory effect of tripterine on activities of IL-1, IL-2 and release of PGE2].

Tripterine is one of the components isolated from Tripterygium wilfordii Hook. Previous studies demonstrated that tripterine inhibited not only humoral and cellular immune responses but also some inflammatory responses. The present investigation attempted to observe effect of the drug on productions of IL-1 from macrophages, IL-2 from splenocytes and PGE2 from synovial cells. The results showed that tripterine (0.1-1.0 microgram/ml) significantly inhibited IL-1 activity of murine peritoneal macrophages induced by LPS. Because both intracellular and extracellular IL-1 activities were decreased, so tripterine might be able to reduce the production and release of IL-1. Besides, inhibition of IL-1 production was observed when macrophages were pretreated with the drug for 8 h and 16 h. A good relationship was found between the effect and concentration of tripterine which inhibited IL-2 production from ConA-activated murine splenocytes. Kinetic study indicated that IL-2 production was decreased when splenocytes were pretreated with the drug for 3 h, 6 h and 12 h. Synovial cells obtained from rabbit knee joint were cultured successfully. A23187 was found to augment PGE2 synthesis modestly. Tripterine significantly reduced PGE2 release from synovial cells in a concentration dependent manner.

Novel endogenous protein kinase C substrate proteins, neutrinins, in brain synaptic membranes of maturing rat.

A new family of membrane phosphoproteins designated as P9, P12, P15, P16, and P20 with corresponding apparent molecular weights of 9K, 12K, 15K, 16K, and 20K was characterized from rat brain by using in vitro exogenous or endogenous phosphorylation and autoradiography. As the phosphorylation was selectively inhibited by the protein kinase C (PKC) inhibitor PKC19-31 or Ca(2+)-chelating reagents and again stimulated by the PKC activator phorbol 12, 13-dibutyrate, these proteins are thought to be the natural PKC substrates. Because P12, P15, P16, and P20 were neutral proteins (pl 7.0) and specifically distributed in neuronal membranes, the new family of membrane-associated PKC substrate proteins was referred to as neutrinins. Neutrinins were widely distributed in rat brain, being especially plentiful in the spinal cord, medulla oblongata, cerebellum, and midbrain, relatively scanty in the cerebral cortex, but lacking in cytosol of brain areas and cell membrane preparations of peripheral tissues. The expression of the developmental changes of neutrinins has been monitored by the in vitro exogenous phosphorylation approach, i.e., adding purified PKC to a deactivated synaptosomal plasma membrane system. Levels of all the neutrinin proteins in rat cerebral cortex, as represented by P12, P15, and P16, showed an ontogenetic increase from the early postnatal days to the adult. This appears to be correlated with the commencement of synaptogenesis.

ZNC(C)PR affects developmental changes of P46 phosphorylation in rat hippocampus.

Protein phosphorylation has been suggested to be correlated with brain development and with the molecular mechanism of behavioral effects of neuropeptides. The present study reports in vitro endogenous phosphorylation of P46, a membrane-associated protein that is changed during development of the rat hippocampus. This study indicated that the degree of endogenous phosphorylation may be correlated with the establishment of synaptic connections. Interestingly, P46 was proved to be identical to a well-known growth-associated protein B-50/GAP-43 in its identical apparent molecular weight, isoelectric point, phosphorylation dependence, and the cross immunoreaction of monoclonal anti-B-50/GAP-43 antibody and P46. Moreover, neonatal administration of neuropeptide ZNC(C)PR could facilitate the developmental progress of P46 endogenous phosphorylation. It is suggested that the changes in P46 phosphorylation could be involved in the cellular mechanism of ZNC(C)PR behavioral effects on learning.