The effects of lead poisoning on calcium transport by brain in 30-day-old albino rabbits

Kinetic analysis of glutamate transport by the miniswine choroid plexus in vitro

Transport of glutamic acid by the choroid plexus, the blood-cerebrospinal fluid (CSF) barrier, was investigated by using the isolated choroid plexi from the fourth (FVCP) and lateral ventricles (LVCP) of the young adult miniswine in vitro. Glutamic acid uptake was very pronounced, with concentrations 7-fold (LVCP) and 2.4-fold (FVCP) higher in tissue than in medium after only 5 min of incubation with 1 microM glutamic acid. Tissue/medium ratios reached steady state by 15 min at 30-fold (LVCP) and 11-fold (FVCP). Uptake was energy-dependent and inhibited by ouabain and hypothermia. L-Aspartic acid was shown to be inhibitory in a concentration-dependent manner, suggesting that it shares a common transport system, whereas neither octanoic acid nor okadaic acid (transported by a separate fatty acid system) inhibited glutamic acid transport. At the same temperature, the labeled metabolite of glutamate (glutamine) in the tissue was 64.7%, 73.2%, and 72.5% of total radioactivity at 5, 30, and 60 min, respectively. The estimated Km values for glutamate uptake by the choroid plexus are 264 microM (FVCP) and 196 microM (LVCP); Vmax values are 87 (FVCP) and 147 (LVCP) nmol/g/min, respectively. These results indicate that, in addition to the metabolism of glutamate to glutamine, an active uptake mechanism is present in the choroid plexus of miniswine which may serve to regulate glutamic acid concentration in the CSF.

Kinetic analysis of L-carnitine uptake by the choroid plexus

Choroid plexuses from the lateral (LVCP) and fourth ventricles (FVCP) of rats or rabbits were incubated in artificial cerebrospinal fluid (CSF) containing 1 microM [14C]L-carnitine with various concentrations of L-carnitine ranging from 0.01 mM to 1.0 mM. The time course of 1 microM [14C]L-carnitine uptake by the choroid plexus indicated that it increased linearly for the first 15 min. Steady-state levels were reached by 30 min with tissue concentrations more than 20 (FVCP)- to 30 (LVCP)-fold greater than the concentration in the medium. The uptake of [14C]L-carnitine was increased with increasing concentrations of the substrate in the medium and this uptake followed Michaelis-Menten kinetics. The uptake by the rat choroid plexus took place against a concentration gradient via a saturable process and kinetic analysis revealed Km of 32 microM (LVCP) and 34 microM (FVCP) and Vmax of 21 (LVCP) and 17 nmol/ml/min (FVCP), respectively. Ouabain inhibited the uptake by 51% (FVCP) and 48% (LVCP) and hypothermia (0 degrees C) produced inhibition by 97% (FVCP) and 96% (LVCP), respectively. However, the uptake of L-carnitine was not sensitive to probenecid or tyrosine, which indicates the presence of an independent carrier for L-carnitine in the choroid plexus. Similar results were obtained with the rabbit choroid plexus.

2,4-Dichlorophenoxyacetic acid intoxication increases its accumulation within the brain

Exposure to the phenoxyacetic acid herbicides has been shown to produce neurotoxicity. Therefore, adult mice (pregnant) and rabbits were used to examine the accumulation and regional distribution of 2,4-dichlorophenoxyacetic acid (2,4-D) within the brain following intraperitoneal injection of a low dose (0.2-0.4 mg/kg) of [14C]2,4-D. Controls, i.e. animals not previously exposed to 2,4-D, were compared to animals acutely pretreated with higher doses (40-160 mg/kg) of unlabeled 2,4-D. Both autoradiography and direct tissue analysis showed that in control animals brain levels were much lower than plasma in both adult (approximately 4%) and fetus (approximately 8%). In both species, small variations were seen between the brain regions, with brainstem and cerebellum somewhat higher than other regions. Pretreatment with unlabeled 2,4-D caused a 5- to 10-fold increase in accumulation of [14C]2,4-D in both mice and rabbits. On the other hand, 2-deoxyglucose entry into the brain was not altered by 2,4-D pretreatment. Thus, there was no generalized increase in blood-brain barrier permeability. Instead, increased 2,4-D accumulation appeared to be caused by its decreased elimination from the brain. Pretreatment with 40 mg/kg led to a CSF 2,4-D concentration of 10 microM, a concentration sufficient to inhibit choroid plexus transport of [14C]2,4-D by nearly 50% in vitro. These results suggest that exposure to organic anions like 2,4-D may lead to the retention of potentially toxic anions within the CNS via competitive inhibition of the organic anion transport system which normally reduces their brain and CSF concentrations to very low levels.

Effects of 2,4,5-trichlorophenoxyacetic acid and quinolinic acid on 5-hydroxy-3-indoleacetic acid transport by the rabbit choroid plexus: pharmacology and electron microscopic cytochemistry

2,4,5-Trichlorophenoxyacetic acid (2,4,5-T) reduced the uptake of 5-hydroxy-3-indoleacetic acid (5-HIAA) by the choroid plexus in a dose-related manner, while treatment with quinolinic acid at comparable concentrations did not inhibit 5-HIAA uptake. The role of carrier-mediated transport in the clearance of 5-HIAA from cerebrospinal fluid (CSF) was also evaluated in vivo by ventriculocisternal perfusion. Steady-state clearance of 5-HIAA from CSF exceeded that of inulin and was reduced competitively in the presence of 2,4,5-T. However, the clearance was not affected by quinolinic acid. The effect of 2,4,5-T on transport enzyme systems was also studied by electron microscopic cytochemistry. Na+-K+-ATPase and cytochrome oxidase activities in the choroid plexus were reduced by 2,4,5-T. Since this transport system in the choroid plexus is normally responsible for the excretion of the serotonin metabolite from the brain to the plasma, accumulation of endogenously produced organic acids in the CSF and the brain, secondary to reduced clearance by the choroid plexus, could be a contributing factor in the development of neurotoxicity.

Uptake of inorganic lead in vitro by isolated mitochondria and tissue slices of rat renal cortex

Slices of rat renal cortex were shown to take up Pb2+ during incubation in vitro; Pb2+ was also shown to enter mitochondria within the slices. The uptake of Pb2+ by isolated mitochondria was inhibited by N-3, La3+ and ruthenium red. A steady state of uptake was attained within 60 sec. The concentration dependence of uptake was complex; maximum uptake was attained at 25 microM and inhibition ensued at higher concentrations. A substantial inhibitor-resistant component of Pb2+ uptake was noted, especially at medium Pb2+ concentrations greater than 25 microM, and these concentrations also inhibited respiration state 3. The effects on respiration were reduced if the mitochondria had been preincubated with ruthenium red. Slices of renal cortex incubated at 1 degree in medium with various concentrations of Pb2+ showed two fractions of uptake, one saturating at 50-100 microM external Pb2+ and the other at 150-200 microM. Subsequent incubation for 60 min at 25 degrees led to further uptake at all concentrations. Upon isolation of mitochondria from incubated slices, significant amounts of Pb2+ were detected in the mitochondria within 5 min of addition of Pb2+ (200 microM), with maximum attained at 30 min. Electron microscopy of slices showed electron-dense particles, apparently of Pb2+, in the cortical cells but the greatest concentration was deposited in the basement membranes. The results indicate the importance of the basement membrane in limiting access of Pb2+ to cortical cells, and of mitochondria in accumulating Pb2+ once it is in the cells. They also illustrate the importance of interactions between Pb2+ and Ca2+.

L-carnitine: therapeutic strategy for metabolic encephalopathy

The organic anion transport system in the choroid plexus is responsible for excretion of organic anions from brain to plasma. Disruption of this system could then result in accumulation of encephalopathic acyl groups in brain in a variety of metabolic disorders. Octanoate produced inhibition of this transport system associated with disruption of mitochondrial ultrastructure. Octanoylcarnitine and L-carnitine had no effect. These compounds represent those seen in the medium chain acyl CoA dehydrogenase deficiency. L-Carnitine may be useful for protecting the central nervous system through formation of the non-toxic acylcarnitine in this and other metabolic disorders characterized by accumulation of encephalopathic metabolites.

Effects of Pb2+ added in vitro on Ca2+ movements in isolated mitochondria and slices of rat kidney cortex

We have studied the effects of Pb2+ added in vitro on the movements of Ca2+ in renal cortical mitochondria and tissue slices. The isolated mitochondria rapidly accumulated 45Ca2+ at 25 degrees by a mechanism that was dependent on respiration and inhibited 96% by ruthenium red. A concentration of 10 microM Pb2+ inhibited the Ca2+ accumulation at least as effectively as did ruthenium red. About 20% of the Ca2+ accumulation persisted at 1 degrees with a similar sensitivity to inhibitors, including 60% inhibition by Pb2+. Similar results were obtained when the accumulation of Ca2+ at 25 degrees was measured by means of a calcium-sensitive electrode, Pb2+ inhibiting by 80%. Calcium that had been accumulated by mitochondria at 25 degrees was released completely by the ionophore A23187 or by 10 microM Pb2+. The release induced by Pb2+ was greatly inhibited by ruthenium red. The Ca2+ content of tissue slices of renal cortex increased 4-fold during incubation at 1 degree while the Ca2+ content of mitochondria within the slices more than doubled, the latter being determined by isolation of mitochondria from the slices after incubation. The presence of Pb2+ (200 microM) in the incubation medium of the slices substantially reduced the entry of Ca2+ into the whole slices and into mitochondria within the slices. When the slices preincubated at 1 degree were warmed to 25 degrees in oxygenated medium, they brought about a net extrusion of Ca2+, some of which was derived from the mitochondria; Pb2+ did not alter the final level of Ca2+ then attained in the slices, but it caused a significant decrease in the quantity retained in the mitochondria. We conclude that Pb2+ both inhibits the uptake of Ca2+ by renal cortical mitochondria and displaces Ca2+ from them, these effects occurring whether the mitochondria are isolated or in situ.

Effect of increasing carbon chain length on organic acid transport by the choroid plexus: a potential factor in Reye's syndrome

Transport of the anionic herbicide 2,4-dichlorophenoxyacetic acid by choroid plexus is inhibited significantly by several short and medium chain acids. For both monocarboxylic and dicarboxylic homologs, inhibition clearly increases with chain length. It appears that organic acid compounds of longer chain length, higher brain uptake index, and highest inhibition of choroid plexus transport would be the ones producing the most significant increases in intracranial pressure in metabolic encephalopathy such as Reye's syndrome.