Differential activation of protein kinase C isoforms following chemical ischemia in rat cerebral cortex slices.

The aim of the current study was to characterize the effects of chemical ischemia and reperfusion at the transductional level in the brain. Protein kinase C isoforms (alpha, beta(1), beta(2), gamma, delta and epsilon) total levels and their distribution in the particulate and cytosolic compartments were investigated in superfused rat cerebral cortex slices: (i) under control conditions; (ii) immediately after a 5-min treatment with 10mM NaN(3), combined with 2mM 2-deoxyglucose (chemical ischemia); (iii) 1h after chemical ischemia (reperfusion). In control samples, all the PKC isoforms were detected; immediately after chemical ischemia, PKC beta(1), delta and epsilon isoforms total levels (cytosol+particulate) were increased by 2.9, 2.7 and 9.9 times, respectively, while alpha isoform was slightly reduced and gamma isoform was no longer detectable. After reperfusion, the changes displayed by alpha, beta(1), gamma, delta and epsilon were maintained and even potentiated, moreover, an increase in beta(2) (by 41+/-12%) total levels became significant. Chemical ischemia-induced a significant translocation to the particulate compartment of PKC alpha isoform, which following reperfusion was found only in the cytosol. PKC beta(1) and delta isoforms particulate levels were significantly higher both in ischemic and in reperfused samples than in the controls. Conversely, following reperfusion, PKC beta(2) and epsilon isoforms displayed a reduction in their particulate to total level ratios. The intracellular calcium chelator, 1,2-bis(2-aminophenoxy)ethane-N,N,N',N'-tetraacetic acid, 1mM, but not the N-methyl-d-asparate receptor antagonist, MK-801, 1muM, prevented the translocation of beta(1) isoform observed during ischemia. Both drugs were effective in counteracting reperfusion-induced changes in beta(2) and epsilon isoforms, suggesting the involvement of glutamate-induced calcium overload. These findings demonstrate that: (i) PKC isoforms participate differently in neurotoxicity/neuroprotection events; (ii) the changes observed following chemical ischemia are pharmacologically modulable; (iii) the protocol of in vitro chemical ischemia is suitable for drug screening.

Effects of chemical ischemia on cerebral cortex slices: focus on mitogen-activated protein kinase cascade.

A variety of harmful stimuli, among them energy depletion occurring during transient brain ischemia, are thought to unbalance protein kinase cascades, ultimately leading to neuronal damage. In superfused, electrically stimulated rat cerebral cortex slices, chemical ischemia (CI) was induced by a 5-min treatment with the mitochondrial toxin, sodium azide (10 mM), combined with the glycolysis blocker, 2-deoxyglucose (2 mM). Thereafter, 1 h reperfusion (REP) with normal medium followed. Western blot analysis of p21Ras, extracellular signal-regulated protein kinases (ERK)1/2 (p44/42), phospho-ERK1/2, mitogen-activated protein kinase (MAPK)-p38, phospho-p38, stress-activated protein kinases/c-Jun NH2-terminal protein kinases (SAPK/JNK), phospho-SAPK/JNK was carried out. The level of p21Ras was increased by 40% immediately after CI, and did not return to control values following REP. Both ERK1 and ERK2 levels were reduced by CI and recovered to control values following REP; no significant change in their phosphorylation degree (phosphorylated to total level ratio, about 50% in the controls) was observed. Neither p38 levels, nor phosphorylation degree were changed following CI/REP. The activation of SAPK/JNK was significantly reduced under CI, and did not recover following REP. All CI/REP-induced effects were prevented by the NMDA receptor antagonist MK-801, 10 microM, suggesting the involvement of glutamate. The present findings show that although CI stimulates the p21Ras protein, MAPK levels and/or phosphorylation are reduced, possibly because of acute energy depletion. Because the activation of SAPK/JNK has been related to both apoptosis and neuroprotection, the decrease observed under CI/REP conditions may instead be related to nonapoptotic neuronal death. These results could be of interest in developing preventive treatments for ischemia/REP-induced brain damage.

Studies on the apoptotic activity of natural and synthetic retinoids: discovery of a new class of synthetic terphenyls that potently support cell growth and inhibit apoptosis in neuronal and HL-60 cells.

New terphenyl derivatives have been synthesized and tested for their effect on cell survival in serum-free cultures. These compounds protected HL60 cells from death and supported their growth with an activity higher than that of the natural 14-hydroxy-retro-retinol. Terphenyls 26 and 28 also possess antiapoptotic activity on neuronal cells, proving them as possible candidates for the treatment of neurodegenerative and ischemic diseases.

Synthesis and pharmacology of 6-substituted benztropines: discovery of novel dopamine uptake inhibitors possessing low binding affinity to the dopamine transporter.

A series of 6alpha- and 6beta-substituted benztropines were synthesized. A marked enantioselectivity was observed for the 6beta-methoxylated benztropines, the (1R)-isomers being more potent than the corresponding (1S) compounds. The racemic 6alpha-methoxy-3-(4',4' '-difluorodiphenylmethoxy)tropane (5 g) was the most potent compound. It has been found that modifications at the 6-position of benztropine might reduce the DAT binding affinity, maintaining otherwise a significant dopamine uptake inhibitory activity. A reinvestigation of the absolute configuration of 6beta-methoxytropinone proved the 6R configuration for the (+)-enantiomer.

Direct and indirect inhibition by nociceptin/orphanin FQ on noradrenaline release from rodent cerebral cortex in vitro.

1 The modulation exerted by nociceptin/orphanin FQ (NC) on noradrenaline (NE) release in rodent cerebral cortex slices and synaptosomes was studied. 2 Rat, mouse and guinea-pig cortical slices and synaptosomes were preincubated with 0.1 micro M [(3)H]-NE and superfused. NE release was evoked by 2 min of electrical (3 Hz) stimulation in slices and by 1 min pulse of 10 mM KCl in synaptosomes. 3 In rat cortical slices, 0.01-3 micro M NC reduced the evoked [(3)H]-NE efflux (E(max)-54%), with a bell-shaped concentration-response curve, which regained its monotonic nature in the presence of either 0.1 micro M naloxone (NX) or 30 micro M bicuculline. In synaptosomes, the NC effect curve was sygmoidal in shape and reached a plateau at 1 micro M concentration. 4 In the rat, both 1 micro M [Phe(1)psi(CH(2)-NH)Gly(2)]NC(1-13)NH(2) and 10 micro M [Nphe(1)]NC(1-13)NH(2) (NPhe) antagonised NC-induced inhibition, without per se modifying [(3)H]-NE efflux. The effects of 0.3-1 micro M NC concentrations were partially prevented by 1 micro M NX; 1 micro M D-Phe-Cys-Thr-D-Trp-Orn-Thr-Pen-Thr-NH(2) (CTOP) was also an effective antagonist, but 0.1 micro M norbinaltorphimine was not. 5 In the mouse cerebral cortex, NC-induced inhibition of NE release (pEC(50) 6.87, E(max)-61%, in the slices) was prevented by Nphe but was NX-insensitive. In guinea-pig cortical slices, NC effect (pEC(50) 6.22, E(max)-38%) was prevented by Nphe, but was NX-insensitive. 6 These findings demonstrate that NC inhibits NE release from rodent cerebral cortex via presynaptically located ORL(1) receptors. In the rat, micro opioid and GABA(A) receptors are involved as well.

Nociceptin inhibition of acetylcholine efflux from different brain areas.

The effects of nociceptin on [3H]choline [3H](Ch) efflux from electrically-stimulated rat cortical, hippocampal and caudatal slices as well as from KCl-depolarized synaptosomes and tetrodotoxin-pretreated slices have been studied. The inhibition of electrically evoked [3H]Ch efflux by nociceptin (0.03-3 microM) was moderate (max -33%), more evident in the neocortex than in the hippocampus and was prevented by [Nphe1]NC(1-13)NH(2) 10 microM. This effect was absent in the caudate nucleus, in cortical synaptosomes and in tetrodotoxin-pretreated cortical slices. These data point to a distinct localization of NOP receptors in the different brain areas and to a prevailing inhibitory control by nociceptin on the cortical cholinergic input at pre-terminal level. However, the reported impairment of neocortical and hippocampal function by nociceptin may be referred to the inhibition not only of the cholinergic signal but also of other transmitters such as glutamate.