Faculty Bibliography

In vivo effects of chronic lithium administration on dopaminergic and serotonergic receptor binding were studied in the striatum and cerebral cortex of the rat. [3H]Domperidone was used as the ligand for the dopaminergic receptor, and [3H]ketanserin for the serotonergic system. Long-term ingestion of lithium (2-3 months) resulted in high levels of lithium in the cerebral cortex and significantly higher potassium levels; the sodium content remained at normal levels. The kinetic constants (Kd and Bmax) of [3H]domperidone binding sites measured in the striatum did not show any deviation from control values, but the receptor concentration (Bmax) of [3H]ketanserin binding sites was significantly reduced in the cerebral cortex of lithium-treated rats. The apparent dissociation constant (Kd) was not changed. The results indicate that the serotonergic component of the [3H]spiperone binding site, which we had previously found to be affected by chronic lithium treatment and which was shown by Peroutka and Snyder to be the 5-HT2 receptor, is selectively affected by lithium

The present study examines the possible role of sodium channels in the behavioral effects of cocaine. Cocaine congeners are apparent competitive inhibitors of the scorpion toxin-enhanced binding of [3H]batrachotoxinin A 20-alpha-benzoate to sodium channels in mouse cerebrocortical synaptosomes. However, in agreement with the allosteric model for heterotropic cooperative interactions, the compounds produce a concentration-dependent increase in the rate of dissociation of binding. Concentrations that give a 2-fold increase of k-1 are close to Ki values for inhibiting equilibrium binding of [3H]bactrachotoxinin A 20-alpha-benzoate, suggesting that the inhibitory effect on binding results mostly from an increase of the apparent dissociation rate constant. The ester linkage between the tropane and benzoyl ring of cocaine is not essential for the inhibitory potency, and for both the C-2 and C-3 substituents the equatorial position results in a higher potency than the axial position. There is reasonable agreement between the rank order of potencies in blocking the sodium channel and in inhibiting locomotor behavior. The present results do not support a relationship between the capability of cocaine congeners in blocking sodium flux and in inhibiting uptake of dopamine into striatal synaptosomes. However, peak levels of cocaine in the brain of cocaine addicts could be high enough to interfere with sodium channel functioning, possibly contributing to some of cocaine's actions

Rates of protein synthesis were studied in immature and adult rat brain tissue. After an amino acid incorporation period, in vivo or in incubated slices from brain, the soluble protein was fractionated according to molecular weight by column chromatography. In examining soluble whole proteins, no direct correlation between molecular weights and synthesis rates could be established; the highest synthesis rates were found in fractions around 70,000 MW and below 10,000. Incorporation into the subunits after fractionation by SDS gel electrophoresis was proportional to subunit molecular weight, with rates of incorporation into the largest subunits being the highest. The results suggest a relationship between turnover rate and structure of subunits of brain proteins

We report here saturation analysis of [3H]cocaine binding in various mouse brain regions, and the necessary structure-activity relationships for cocaine congeners to inhibit Na+-dependent [3H]cocaine binding and [3H]dopamine uptake in the mouse striatum, and to inhibit [3H]cocaine binding that cannot be stimulated by Na+ and [3H]serotonin uptake in the mouse cerebral cortex. Generally similar structure-activity relationships were noted for all these processes. The ester linkage between the tropane and phenyl rings was not required for activity, in contrast to the configuration of the groups on C2, and to a lesser extent C3, in the tropane ring. Stereospecificity was evident from the differences between cocaine and (+)-pseudococaine, and between WIN 35,065-2 and WIN 35,065-3. There were remarkable differences between the above structure-activity relationships and those for local anesthetic activity of cocaine congeners, indicating that sodium channels were not labeled to a measurable extent with [3H]cocaine under the present conditions. Preliminary data indicated a significant correlation between the potencies of cocaine congeners in inhibiting the Na+-dependent binding of [3H]cocaine and their potencies in inducing stereotyped sniffing upon intraventricular administration

We tested the effect of glycine on phencyclidine (PCP)-induced hyperactivity in mice. Glycine antagonized the locomotor stimulating effect of PCP. Correlation was found between the degree of antagonistic effect and the size of the increase in glycine in the brain. The antagonism is not due to changes in uptake, since the elevation of glycine in plasma and brain had no effect on the cerebral uptake of PCP. This pharmacological action of glycine appears to be a central effect, but some peripheral effect can not be excluded. Since glycine is not toxic at levels needed for PCP antagonism, it could be considered for ameliorating PCP psychosis. The locomotor stimulating effect of PCP is strain dependent in mouse. Some strains are responsive, such as BALB/cBy and CXBK, and some are unresponsive, such as C57BL/6 and CXBH

The inhibition of spontaneous locomotor behavior of mice by norcocaine was antagonized neither by the adrenoceptor antagonists yohimbine and phentolamine, nor by the neuroleptics haloperidol and spiperone, at low doses aimed at presynaptic dopamine receptors. In contrast, the antagonists were effective in reducing the hypomotility induced by clonidine and apomorphine, respectively. These results make it unlikely that central alpha 2-adrenergic or presynaptic dopamine receptors are involved in the hypomotive effect of norcocaine

[3H]Cocaine dissociates from its binding sites in the mouse cerebral cortex with a half-time of 25 s. The dissociation kinetics in the striatum is consonant with the presence of two populations of sites with dissociation half times of 2 s and 27 s, comprising 88% and 12%, respectively, of the total binding sites. On the basis of previous pharmacological characterization of [3H]cocaine binding, we propose that the slowly dissociating component represents the sites associated with 5-hydroxytryptamine (serotonin) uptake, and the rapidly dissociating component the 3,4-dihydroxyphenylethylamine (dopamine)-related sites. Evidence is presented that the extremely high dissociation rates do not preclude the measurement of [3H]cocaine binding by rapid filtration. The dissociation of [3H]cocaine from cerebrocortical membranes is slowed to a small but statistically significant extent by serotonin

Incorporation of a flooding dose of valine into brain proteins was measured in vivo and in brain slices, according to subcellular fraction and to solubility. In particulate fractions in vivo in the immature brain, soluble cytosol proteins had the highest synthesis rates (2.0% per hr), followed by microsomes (1.7%), mitochondria, nuclei (1.4%), and synaptosomes (0.85%). In adult, the rates were about half of those of immature animals except for microsomes, which were the same. In young, rates of incorporation into particles in brain slices were about 80% of in vivo rates, and adult rates were 10-20% of the in vivo rates. When brain proteins were fractionated into four groups--isotonic soluble, hypotonic soluble, Triton X-100 soluble, and the remainder solubilized in 0.2% SDS--in both young and adult brain in vivo, the isotonic fraction had the highest rate of protein synthesis, followed by the Triton-soluble fraction, the SDS-soluble fraction, and the hypotonic fraction. Also, with this method of separation in vitro rates for immature brain were 10-20% lower than in vivo rates, while in vitro adult rates were 80-90% lower. The results indicate that the most proteins are synthesized at a higher rate in the immature brain, and that the difference between in vivo and brain slice protein synthesis is not as great in the immature as in the mature brain in all the fractions examined

We compared the rate of protein synthesis in immature and adult rat brain in vivo to that in brain slices. After the incorporation of a flooding dose of [14C]valine, in vivo and in brain slices, the label in proteins was measured in CNS regions and in neuron- and glia-enriched fractions. In regions in vivo in the adult, incorporation rates in corpus callosum were lower than in other regions, which were similar; in the young, cerebellum showed the highest rates and hypothalamus and cord the lowest. Since hypothalamus and cord were low in the young, there was no change during development in these two areas; in other areas incorporation rates in young were 2-3 times higher than in adult brain proteins. Incorporation rates in slices were lower than in vivo. In the young, cerebellum, olfactory bulb, and cord were close to in vivo, and other areas in slices from young incorporated at 60-90% of in vivo rates. In adult slices incorporation was 5-15% of that in vivo except in olfactory bulb, where it was 30%. In the cellular fractions, incorporation in vivo in young was close in the neuronal and glial fractions; in adults incorporation rates in neurons were higher, as the decrease in development was less in neurons than astrocytes. In slices in young, astrocytes incorporated amino acids at 100% of the in vivo rates, neurons at 60%; in adult slices, incorporation was at only 4-7% of the in vivo rate. The results show that developmental changes in protein metabolism occur in all brain areas and brain cells, with metabolic rates in young 2-3 times that in adult.(ABSTRACT TRUNCATED AT 250 WORDS)