Regional distribution of calcium channel ligand (1,4-dihydropyridine) binding sites and 45Ca2+ uptake processes in rat brain

Widespread Neonatal Brain Damage following Calcium Channel Blockade

An abundance of evidence exists that shows calcium channel blockade promotes injury in cultured neurons. However, few studies have addressed the in vivo toxicity of such agents. We now show that the L-type calcium channel antagonist nimodipine promotes widespread and robust injury throughout the neonatal rat brain, in an age-dependent manner. Using both isolated neuronal as well as brain slice approaches, we address mechanisms behind such injury. These expanded studies show a consistent pattern of injury using a variety of agents that lower intracellular calcium. Collectively, these observations indicate that postnatal brain development represents a transitional period for still developing neurons, from being highly sensitive to reductions in intracellular calcium to being less vulnerable to such changes. These observations directly relate to current therapeutic strategies targeting neonatal brain injury.

Plasma concentration and CNS effects of Ca antagonists darodipine and nimodipine after single-dose oral administration to healthy volunteers

The dynamics at the brain level (quantitative EEG), plasma kinetics and effects on blood pressure and heart rate of the Ca antagonists, darodipine (slow-release, 50- 200 mg) and nimodipine (30 mg), were compared in a double-blind cross-over study on healthy volunteers during a 9-hour period following single drug/placebo administration. Increased EEG total power was observed after 100 and 200 mg daropidine; a concomitant decrease of 14.5-32.0 Hz relative power was observed at 100 mg. The 50-mg dose proved ineffective. These effects were correlated with the darodipine plasma concentration only at the 100-mg dose, with indications of an active concentration interval at approximately 5-10 ng/ml; a reduction in diastolic blood pressure and increased heart rate proved to be linearly correlated with the drug plasma concentration throughout the entire concentration range. Comparable EEG effects were observed after nimodipine, but they did not correlate with the plasma concentration. Implications of the predictability of the brain effect from the drug plasma concentration and differential thresholds for the brain action and effects on (peripheral) circulation are suggested.

Information processing in mammalian olfactory system

In recent years, considerable progress has been made in understanding how the olfactory system uses neural space to encode sensory information. In this review, we focus on recent studies aimed at understanding the organizational strategies used by the mammalian olfactory system to encode information. The odorant receptor gene family is discussed in the context of its genomic organization as well as the specificity of olfactory sensory neurons. These data have important consequences for the mechanisms of odorant receptor gene choice by a given sensory neuron. Division of the olfactory epithelium into zones that express different sets of odorant receptors is the first level of input organization. The topographical relationship between periphery and olfactory bulb represents a further level of processing of information and results in the formation of a highly organized spatial map of information in the olfactory bulb. There, local circuitry refines the sensory input through various lateral interactions. Finally, the factors that may drive the development of such a spatial map are discussed. The onset of expression and the establishment of the zonal organization of odorant receptor genes in the epithelium are not dependent upon the presence of the olfactory bulb, suggesting that the functional identity of olfactory sensory neurons is determined independently of target selection.

Differential contribution of L- and N-type calcium channels on rat hippocampal acetylcholine release

Bay K 8644, nimodipine and omega-conotoxin GVIA (omega-CgTx) were used to study the different contribution of voltage-sensitive calcium channels (VSCC) to [3H]acetylcholine ([[3H]ACh) release in rat hippocampal synaptosomes. In our experimental conditions, the percentage of calcium-dependent ACh release was approximately 80%. Nimodipine (0.01-10 microM) and Bay 8644 (0.01-10 microM) were not able to modify the [3H]ACh release under stimulating conditions (15 mM K+). Nevertheless, when K+ concentration was reduced to 8 mM, a significant increase in [3H]ACh release was observed at 1 and 10 microM of Bay K 8644. Nimodipine (0.01-10 microM) failed to reverse the effect of Bay K 8644 on [3H]ACh release. Finally, omega-CgTx (0.001-1 microM) caused a concentration-dependent reduction of [3H]ACh release in K+ (15 mM)-stimulating conditions. These results suggest that the N-type VSCC probably play a predominant role in regulating the [3H]ACh release in synaptosomes from rat hippocampus.

Favorable amphiphilicity of nimodipine facilitates its interactions with brain membranes

Nimodipine is a 1,4-dihydropyridine (DHP) calcium channel blocker which is used in the treatment of neurological deficits associated with subarachnoid hemorrhage. Small angle x-ray diffraction, differential scanning calorimetry, and equilibrium and kinetic binding techniques were used to study the interaction of nimodipine with bovine brain phosphatidylcholine (BBPC) membranes of varying cholesterol content. At concentrations (5 x 10(-10) M) near its Kd, the membrane partition coefficient of nimodipine was inversely related to the cholesterol to phospholipid (C:P) mole ratio in both model and native (rat synaptoneurosome) membranes. The nonspecific dissociation rate of nimodipine from BBPC was significantly slower at low C:P mole ratio (0.1:1) than at high C:P mole ratio (0.6:1). Calorimetric analysis showed that nimodipine decreased both the main phase transition temperature and cooperative unit size of melt for dimyristoyl phosphatidylcholine, dependent on membrane cholesterol content. Small angle x-ray diffraction analysis showed that nimodipine occupies a position in BBPC approx +/- 15 A from the center of the hydrocarbon core, near the hydrocarbon core/water interface. These data indicate that nimodipine is an amphiphilic molecule which rapidly washes out of and transports across membrane bilayers, facilitating its interactions with membranes and possibly its transport across the blood-brain barrier.

Ion homeostasis in rat brain in vivo: intra- and extracellular [Ca2+] and [H+] in the hippocampus during recovery from short-term, transient ischemia

Changes in intra- and extracellular [Ca2+] and [H+], together with alterations in tissue PO2 and local blood flow, were measured in areas CA1 and CA3 of the hippocampus during recovery (up to 8 h) after an 8-min period of low-flow ischemia. Restoration of blood supply was followed by an immediate rise in flow and tissue PO2 above normal, with large fluctuations in both persisting for up to 4 h. In area CA1, [Ca2+]i decreased rapidly from an ischemic mean value of 30 microM to a control mean level of 73.1 nM in 20-30 min, whereas normalization of [Ca2+]e took approximately 1 h. Recovery of [Ca2+]i was accelerated by preischemic administration of a calcium antagonist, nifedipine, and a free radical scavenger, N-tert-butyl-alpha-phenylnitrone (PBN), but not by MK-801, a blocker of N-methyl-D-aspartate receptors. There was a secondary rise in [Ca2+]i in many cells beginning approximately 2 h after reperfusion. This was attenuated somewhat by PBN but not clearly influenced by either nifedipine or MK-801. Changes of [Ca2+]i in area CA3 were much smaller and slightly slower than in area CA1 and were not affected by the drugs mentioned above. In both areas CA1 and CA3, pHe and pHi fell during ischemia to an average value of 6.2, from which there was a rapid initial recovery in the first 5-10 min when blood flow was restored. Thereafter tissue pH rose slowly and did not reach control levels for approximately 1 h, and in some microareas not at all. It is concluded that (a) effective mechanisms for restoring normal [Ca2+]i remain intact after 8 min of low-flow ischemia; (b) in neurons of area CA1, some insidious change in the homeostasis of calcium triggers a secondary rise in its free cytosolic concentration, which may be causally related to activation of irreversible cell damage; and (c) the changes in [Ca2+]i and [Ca2+]e during and following 8 min of ischemia can be adequately accounted for by movements of a fixed pool of Ca between intra- and extracellular compartments, and possible mechanisms are discussed.

Voltage-dependent L-type calcium channels in the development and plasticity of mouse barrel cortex

Entry of calcium ions into the neuron is a triggering signal for initiation of several processes which may lead to modification of synaptic connectivity. The developmental changes of voltage-dependent L-type calcium channel (VDLCC) were studied using [3H]PN 200 110 nifedipine displaceable binding in the barrel cortex of mice, a model structure for studying cortical plasticity. In vitro binding autoradiography was used to examine quantitatively the pattern of [3H]PN 200 110 binding to brains of animals aged from 3 to 70 days. The binding values in the somatosensory cortex rose two-fold in the period examined, reaching a plateau in the 4th postnatal week. The laminar pattern of binding changed during development, with the locus of heaviest labeling shifting from layer IV to II/III in the third postnatal week and thin bands of labeling developing in layers IV and VI. A very faint barrel-like pattern of labeling in the barrel field was observed. Neither this pattern nor the binding values were altered by unilateral neonatal removal of all vibrissal follicles. Saturation studies of binding to crude synaptosomal fractions of cerebral cortex of mice aged 3, 15, 28 and 70 days revealed the presence of a single binding site, with Bmax increasing from 48.7 +/- 5.1 fmol/mg protein at postnatal day 3 to 191.7 +/- 9.6 fmol/mg protein at day 70. No developmental changes in KD values were found. No correlation was found between the critical period for cytoarchitectonic plasticity of the barrels and the time when high values of VDLCC binding were observed.

Nimodipine enhances spontaneous activity of hippocampal pyramidal neurons in aging rabbits at a dose that facilitates associative learning

The functional activity of hippocampal neurons is strongly correlated with behavioral performance in a vertebrate model learning system, rabbit eyeblink conditioning. Using this system, we have previously shown that (a) complete removal of the hippocampus blocks acquisition of the conditioned response; (b) a calcium-dependent postsynaptic afterhyperpolarization is reduced in pyramidal cells recorded intracellularly in hippocampal slices taken from conditioned rabbits; and (c) nimodipine, a 1,4-dihydropyridine calcium-channel antagonist, facilitates acquisition of the conditioned response in aging rabbits. Although calcium-channel antagonists directly block neuronal calcium currents in vitro, they also alter cerebral blood flow in vivo. Thus, the effects of nimodipine on hippocampal neuronal activity in awake animals were examined, with controls for cerebrovascular changes. A total of 457 pyramidal cells and 160 theta cells were studied. During infusion of nimodipine, pyramidal cell firing activity was enhanced and theta interneuron activity was suppressed at all doses tested in aging animals. This effect was rapidly reversed when infusion of the drug ceased. The greatest enhancement of neuronal firing was seen at the most behaviorally effective dose of nimodipine. The enhancement of pyramidal cell firing was age-dependent, with greater increases in firing activity seen in aging than in young animals, but with a similar dose-dependent pattern of effects in the two age groups. Two other calcium-channel antagonists, nifedipine and flunarizine, did not significantly alter spontaneous firing rates of hippocampal neurons. A calcium-channel agonist, BAY-K-8644, produced less easily interpretable results. BAY-K-8644 enhanced interneuron activity at one dose, but enhanced pyramidal cell activity at a dose one log unit higher. The calcium-channel agonist's enhancement of pyramidal cell activity at the highest dose was sustained up to 1 h after drug infusion. Nimodipine's enhancement of the activity of hippocampal pyramidal cells is consistent with the hypothesis that these neurons, which play a necessary role in some forms of learning, may mediate the calcium-channel antagonist's behavioral effects.

Dihydropyridines alter adenosine sensitivity in the rat hippocampal slice

1. The effects of adenosine and a range of adenosine analogues, which are resistant to uptake processes, were studied in the presence of dihydropyridines and verapamil on the population spike potential recorded from the CA1 area of the hippocampal slice. 2. Nifedipine and Bay K 8644, a calcium channel antagonist and activator respectively, enhanced the inhibitory action of adenosine in a concentration-dependent manner. This was in contrast to their effect on adenosine analogues where the inhibition of the population potential was significantly attenuated. Similar interactions between the adenosine compounds and the dihydropyridines were also displayed in studies on spontaneous epileptiform activity in the CA3 region. 3. This effect of nifedipine and Bay K 8644 was not shown by the dihydropyridines, nimodipine or nitrendipine, or by the phenylalkylamine, verapamil. 4. Addition of the adenosine uptake blocker dipyridamole reversed the action of nifedipine on adenosine, so that inhibition by adenosine was now attenuated by nifedipine in a similar manner to that observed with the adenosine analogues. 5. These results can be explained with reference to binding studies that show displacement of adenosine analogues from the adenosine receptor by dihydropyridines. An action at the adenosine uptake site by the dihydropyridines explains the enhancement of adenosine inhibition. 6. The possible sites for this interaction are discussed.

Inhibition of adenosine responses of rat hippocampal neurones by nifedipine and BAYK 8644

The application of adenosine to hippocampal slices caused a suppression of evoked population spikes in the CA1 region. This effect was enhanced by nifedipine and BAYK 8644 in control slices but was reduced by these dihydropyridines in the presence of dipyridamole. Several analogues of adenosine which are not substrates for the uptake system also depressed the population spikes in the CA1 region but these responses were inhibited by nifedipine and BAYK 8644. Other dihydropyridines including nimodipine and nitrendipine did not affect sensitivity to adenosine or its analogues. It is concluded that some agonist and antagonist dihydropyridines can inhibit adenosine uptake and thus potentiate its effects but can also antagonise receptor activation. Structural features of nifedipine and BAYK 8644 may be specific for a population of dihydropyridine receptors closely linked functionally with the adenosine receptor.

Central neurochemical effects of dihydropyridine calcium antagonists

Recent advances in central dihydropyridine (DHP)-binding sites are reviewed. DHP-binding sites are pre-synaptically and post-synaptically localized in the brain. The functional role of post-synaptic sites is still unknown, whereas pre-synaptic sites seem to contribute to the control of calcium uptake and of neurotransmitter release. DHP-binding sites may be modualated in physiological (age, sex) and pathological events (hypertension, ischaemia, neurological diseases) or after drug treatments (alcohol, morphine, etc.). The reviewed data suggest new therapeutic implications of DHP calcium channel antagonists in the treatment of other diseases and of drug withdrawal syndrome.

Activators and inactivators of calcium channels: effects in the central nervous system

The interactions of calcium antagonists or channel activators with the different classes of calcium channel are reviewed with particular emphasis on interactions with neuronal tissue; reasons for the failure of calcium antagonists to inhibit neurotransmitter release under normal circumstances are outlined. Calcium antagonists may be protective in several pathological situations and the possibilities of protection against ischaemic damage in the central nervous system are evaluated.

Characterization of dihydropyridine-sensitive calcium channels in rat brain synaptosomes

We examined the effects of dihydropyridine Ca2+-channel agonists on synaptosomal voltage-dependent Ca2+ entry and endogenous dopamine release. The (-) isomer of Bay K 8644 and the (+) isomer of Sandoz compound 202-791 were 100-1000 times more potent than their respective opposite enantiomers in enhancing Ca2+ uptake and dopamine release from striatal synaptosomes. The active isomer of each of these compounds increased Ca2+ entry and dopamine release to the same extent at a concentration of 1 nM. Fast-phase Ca2+ entry into synaptosomes isolated from cerebellum, cortex, and hippocampus was sensitive to nanomolar concentrations of Bay K 8644. No effect of Bay K 8644 was observed in synaptosomes isolated from brainstem. Bay K 8644 increased synaptosomal Ca2+ uptake and endogenous dopamine release from striatal synaptosomes only during the initial seconds of KCl-induced depolarization. The greatest increase was observed during the first second of depolarization. No effect was observed after greater than or equal to 5 sec of depolarization. Bay K 8644 did not alter Ca2+ uptake or dopamine release under resting conditions (5 mM KCl) or in response to KCl at greater than 15 mM. The activity of Bay K 8644 was also attenuated by lowering the concentrations of divalent cations in the incubation medium. Agonist activity was observed at Mg2+ concentrations greater than 500 microM (Ca2+ held at 100 microM) and Ca2+ concentrations greater than 100 microM (Mg2+ held at 1000 microM). These results suggest that the Ca2+ channels present in synaptosomes are sensitive to nanomolar concentrations of dihydropyridine agonists under a narrow range of experimental conditions.

Use of tissue culture models to study neuronal regulatory trophic and toxic factors in the aged brain

Dementia is believed to result from the loss of selective neurons within the brain, but approaches for systematic study of that degenerative process are hampered by the complexity of the neuronal milieu. Tissue culture models provide a means to reduce dramatically the variables inherent in the study of neuronal plasticity. Three levels of complexity can be described: cellular and molecular diversity; primary and secondary interconnections; and finally, the dynamics influenced by age. The following review discusses the advantages and disadvantages of tissue culture models for the detailed study of neuronal trophic and toxic factors. Our selection of factors is broadened to include ions, intermediate metabolites, antioxidants, steroids, neuropeptides, gangliosides, metals, neurotransmitters, brain extracts, and protein molecules. Most of these factors have been shown to be altered in the aged brain, to have a significant effect on cultured neurons, or both. This multilevel analysis provides the reader with an overview of the events regulating neuronal survival, differentiation and death. An understanding of these basic questions is necessary to sequence the molecular events resulting in neuronal death.

Kainic acid lesions decrease striatal dopamine receptors and 1,4-dihydropyridine sites

The effects of intrastriatal injection of kainic acid (2 microliters, 1 mg/ml) in the rat were determined. Four weeks after the lesioning, striatal dopamine receptors and 1,4-dihydropyridine sites were measured by radioligand binding with [3H]spiperone and [3H]nimodipine, respectively. Dopamine receptor and 1,4-dihydropyridine binding densities were decreased by 58% and 43% respectively, with no change in binding affinity for either ligand. 1,4-Dihydropyridine-sensitive Ca2+ channels may be located primarily on postsynaptic elements.