Perinatal exposure to lead induces morphological, ultrastructural and molecular alterations in the hippocampus.

The aim of this paper is to examine if pre- and neonatal exposure to lead (Pb) may intensify or inhibit apoptosis or necroptosis in the developing rat brain. Pregnant experimental females received 0.1% lead acetate (PbAc) in drinking water from the first day of gestation until weaning of the offspring; the control group received distilled water. During the feeding of pups, mothers from the experimental group were still receiving PbAc. Pups were weaned at postnatal day 21 and the young rats of both groups then received only distilled water until postnatal day 28. This treatment protocol resulted in a concentration of Pb in rat offspring whole blood (Pb-B) below the threshold of 10 µg/dL, considered safe for humans.We studied Casp-3 activity and expression, AIF nuclear translocation, DNA fragmentation, as well as Bax, Bcl-2 mRNA and protein expression as well as BDNF concentration in selected structures of the rat brain: forebrain cortex (FC), cerebellum (C) and hippocampus (H). The microscopic examinations showed alterations in hippocampal neurons.Our data shows that pre- and neonatal exposure of rats to Pb, leading to Pb-B below 10 µg/dL, can decrease the number of hippocampus neurons, occurring concomitantly with ultrastructural alterations in this region. We observed no morphological or molecular features of severe apoptosis or necrosis (no active Casp-3 and AIF translocation to nucleus) in young brains, despite the reduced levels of BDNF. The potential protective factor against apoptosis was probably the decreased Bax/Bcl-2 ratio, which requires further investigation. Our findings contribute to further understanding of the mechanisms underlying Pb neurotoxicity and cognition impairment in a Pb-exposed developing brain.

Expression of glutamate transporters GLT-1 and GLAST in different regions of rat brain during the course of experimental autoimmune encephalomyelitis.

Demyelination and oligodendroglial cell death accompanied by axonal injury are dominating features of multiple sclerosis (MS) a chronic demyelinating disease of the CNS. Accumulation of extracellular glutamate, observed during MS, is implicated in excitotoxic injury of nerve and oligodendroglial cells as a result of over-activation of glutamate receptors. The appropriate concentration of extracellular glutamate is maintained by glutamate transporters, the most predominant of which is glial transporter GLT-1 (excitatory amino acid transporter (EAAT) 2). The aim of this study is to determine the time-course of GLT-1 and glutamate-aspartate transporter (GLAST) expression in forebrain and cerebellum of rats subjected to experimental autoimmune encephalomyelitis (EAE). Our findings revealed that: (1) GLT-1 mRNA and to a lower extent GLAST mRNA are overexpressed in forebrain and cerebellum of EAE rats (2) expression of GLT-1 transporter mRNA shows a similar temporal pattern throughout the course of EAE in both structures examined, and is closely correlated with the appearance of neurological symptoms; and (3) the expression of GLT-1 and GLAST protein does not mirror mRNA changes during EAE and exhibits a differential spatial pattern. The protein levels of GLT-1 in cerebellum and GLAST in both structures are significantly reduced just before the acute phase and later during the recovery. The results imply that transcriptional up-regulation of the GLT-1 gene occurs early in both the forebrain and the cerebellum of the EAE rat model. This up-regulation is associated with the severity of symptoms but tends to precede the onset of maximal neurological deficits. The observations confirm the involvement of glutamate in the pathogenesis of EAE and provide an indication of the protective role of this glutamate transporter. However, changes in protein expression of both transporters suggest the existence of post-translational disturbances or the influence of regulating factors connecting with EAE conditions that may lead to the insufficient protection against glutamate excitotoxicity.

Myelin glycoproteins targeted by lead in the rodent model of prolonged exposure.

The aim of these experiments was to discern whether prolonged exposure of rats to lead (Pb) in water, as occurs in typical environmental exposure, affects the structure of myelin in the brain, the protein levels of the myelin glycoproteins myelin associated glycoprotein (MAG) and myelin oligodendrocyte glycoprotein (MOG). During chronic lead intoxication, Pb levels in myelin fractions significantly increases. Prolonged lead exposure was found to decrease the expression of both MAG and MOG to a similar degree (80-85% of control values). Additionally, the electron microscopic studies have indicated the existence of structural changes in the axonal myelin sheath by revealing disintegration of its multilamellar structure. These morphological disturbances in Pb-intoxicated rats were paralleled by changes in myelin membrane fluidity as measured by spectrofluorometry and electron paramagnetic resonance (EPR) techniques employing a fatty acid spin label. In Pb-treated rats, enhanced membrane fluidity was observed, as indicated both by decreased anisotropy of the membrane and decreased order parameter. These results suggest that Pb influences the integrity of the myelin sheath in brain of adult rats and decreased level of both glycoproteins may significantly contribute to that effect.

Astroglial reaction during the early phase of acute lead toxicity in the adult rat brain.

The developing nervous system is susceptible to lead (Pb) exposure but less is known about the effect of this toxic agent in adult rat brain. Since astrocytes serve as a cellular Pb deposition site, it is of importance to investigate the response of astroglial cells in the adult rat brain in a model of acute lead exposure (25 mg/kg b.w. of lead acetate, i.p. for 3 days). An increased immunoreactivity of glial fibrillary acidic protein (GFAP) on Western blots was noticeable in fractions of astroglial origin-glial plasmalemmal vesicles (GPV) and in homogenates from the hippocampus and cerebral cortex but not in the cerebellum. The features of enhanced astrocytic reactivity (i.e. large accumulation of mitochondria, activated Golgi apparatus and increment of gliofilaments) were observed in electron microscopy studies in the same tissues. Total glutathione levels increased both in GPV fractions and in brain homogenates-in the cerebellum (120% above control) and in hippocampus (30% above control). The results of current studies indicate that acute lead exposure is accompanied by astrocyte activation connected with the presence of the enhanced expression of GFAP. It may indicate lead-induced neuronal injury. At the same time, a regional enhancement of detoxicative mechanisms (GSH) was noticed, suggesting activation of astrocyte-mediated neuroprotection against toxic Pb action.

Acute lead intoxication in vivo affects myelin membrane morphology and CNPase activity.

The aim of the present study was to assess the sensitivity of central nervous system myelin to acute Pb-toxicity in an animal model, that imitates lead toxicity in occupationally exposed workers, or in occasional incidents of poisoning. Our results indicated that in vivo acute lead intoxication affected both the morphology of myelin and enzymatic activity of the myelin marker, CNPase (2'3'-cyclic nucleotide 3'-phosphodiesterase). The multilayered structure of myelin sheaths was regionally disturbed, with loosely arranged membranes or ovoid-shaped swollen fragments. The activity of CNPase was diminished and Michaelis-Menten kinetics showed a decreased affinity and lower velocity of the enzyme. These data suggest that the disturbances in CNPase activity may contribute, in some extent, to the changes in myelin morphology observed in acute Pb-intoxication.

The protective role of astroglia in the early period of experimental lead toxicity in the rat.

Although the clinical manifestations of lead (Pb) neurotoxicity are documented, the subcellular mechanisms of its action are still an open question. The purpose of this study was to assess the function of nerve ending particles after acute lead exposure and to investigate whether it exerts a toxic effect on astroglial functions. The studies were performed using the rodent model of acute lead toxicity. Cellular fractions were used in biochemical measurements--synaptosomes and glial plasmalemmal vesicles (GPV). Since a procedure for the isolation of the fraction of astroglial origin has been developed, it becomes possible to investigate lead-astroglia interactions after in vivo exposure. It is of importance because most of the studies concerning lead toxicity were performed using astroglial culture systems. It was found that the uptake of glutamate (Glu) to the synaptosomes was lowered and KCl-dependent release was increased, suggesting the impairment of glutamatergic transmission leading to the elevation of extracellular amino acid concentration. In contrast, glutamate uptake to the GPV fraction was significantly elevated. The activity of the marker enzyme--glutamine synthetase (GS) was also significantly increased in the GPV fraction. The activation of glial functions suggest a regulatory role for these cells in the early period of acute lead toxicity.

Lead-induced abnormalities in blood-brain barrier permeability in experimental chronic toxicity.

The aim of this paper was to determine whether prolonged drinking of lead acetate-containing water by adult rats, which imitates environmental exposure to lead (Pb), affects some morphological and biochemical properties of rat brain microvessels. We noted a significant increase of lead level in capillaries and synaptosomes obtained from brains of rats under chronic toxicity conditions. Intravenously injected horseradish peroxidase (HRP) was used to evaluate the functional state of the blood-brain barrier (BBB). The results indicate that, systematically administered at low doses, lead induces BBB dysfunction. The changes, revealed in light microscopy and confirmed by electron microscopic studies, are typical for "leaky" microvessels, reported for variety of neuropathological conditions associated with BBB damage. Enhanced pinocytotic activity of the endothelial cells and the opening of interendothelial tight junctions, together with enormous phagocytizing action of the pericytes, are the most characteristic ultrastructural features noted. The presence of specific type of perivascular cells containing droplets of lipids in the cytoplasm, together with changes in phospholipid profile in brain capillaries, suggest that altered lipid composition of membranes may, at least in part, be responsible for changes in observed membrane permeability.

Acute lead toxicity and energy metabolism in rat brain synaptosomes.

Although the neurotoxic effects of lead (Pb) are well documented, the subcellular mechanisms of its action in the central nervous system are not fully understood. The present work examined some parameters of energy metabolism in nerve endings of the brains of adult rats exposed to Pb. We applied the model of acute Pb toxicity in vivo, imitating the acute action of lead observed in occupationally exposed workers or in occasional incidents of poisoning. The measurement of Pb levels in the synaptosomal fraction exhibited its significant accumulation under applied conditions. Oxygen consumption increased in synaptosomes from Pb-treated rats whereas the activity of cytochrome c oxidase did not change. The intrasynaptosomal levels of ATP and CrP were significantly elevated, as was the activity of creatine kinase, suggesting the activation of the CrP/CK system. On the other hand, the activity of the synaptosomal Na+,K(+)-ATP-ase decreased. We suggest that under acute Pb toxicity conditions the mobilization of CrP/CK system may take place to protect the cell against the effects of decreased Na+,K(+)-ATP-ase activity.

Does lead provoke the peroxidation process in rat brain synaptosomes?

Up to now there has been no information concerning the effect of lead on the peroxidation process in brain nerve endings. We have examined whether lead acetate (in chronic and acute models of toxicity in vivo and in vitro) affected the level of free radicals in synaptosomes obtained from rat brain. Simultaneously, we have checked the effect of peroxidation of Pb2+ on brain homogenates and microsomal fraction. Our results indicated that the lead level in synaptosomal fraction obtained from lead-treated rats was much higher than in controls. We did not observe induction of spontaneous and Fe(3+)-dependent peroxidation either in synaptosomes or in homogenates and brain microsomes after chronic and acute lead administration to the rats. Lead itself also did not enhance both processes when added in vitro to the control brain synaptosomes in micromolar concentrations. The lack of the lead effect on the peroxidation process in subcellular fractions of brain was rather surprising, because lead is known to be the accelerator of Fe(3+)-dependent peroxidation processes in liver. Additionally, livers from rats under the same toxicity conditions were examined. We have found that lead did not provoke spontaneous peroxidation in liver, but contrary to brain fractions, it drastically increased iron-dependent peroxidation in liver homogenates and microsomes. The lack of the effect of lead on inducing peroxidation processes in brain is probably the consequence of the brain having stronger protective mechanisms against its toxicity than the liver.

Is lead toxicosis a reflection of altered energy metabolism in brain synaptosomes?

The aim of the experiments presented here was to discern whether prolonged consumption of leaden water, that imitates environmental exposure, affects some energetic parameters in nerve endings of adult rat brains. Our results indicated that during chronic lead intoxication the oxidation chain of synaptic mitochondria remains intact. The oxygen consumption by synaptosomes and activity of cytochrom oxidase in synaptic and pericarionic mitochondria obtained from intoxicated rats did not change in comparison to those from the control samples. Compared with the control samples, the concentration of ATP decreased and the concentration of creatine phosphate (CrP) increased drastically in fractions obtained from Pb2+ intoxicated animals with simultaneously increased activity of creatine kinase (CK). It seems likely that, the CrP/Cr/CK system constitutes a satisfactory regulatory mechanism for chronic Pb2+ toxicity effects on energy metabolism in nerve endings of the adult rats.

Effect of acute and chronic lead exposure on the level of sulfhydryl groups in rat brain.

Lead is known to be a potent neurotoxic agent. The interactions of lead with proteins are considered to be at least one of the mechanisms due to which lead exerts its toxicity. In the present work we demonstrate that acute and chronic models of exposure to lead affected the level of total and protein-bound SH groups in homogenates and synaptosomes obtained from rat brains. The concentrations of SH groups were lowered significantly (P < 0.05) in both types of poisoning. Different classes of cellular proteins were considered to play a role in high affinity binding of lead to these ligands.

The effect of lead on dopamine, GABA and histidine spontaneous and KCl-dependent releases from rat brain synaptosomes.

The effect of lead on the release of [14C]GABA, [3H]dopamine and [14C]histidine (as a precursor of histamine) was studied in synaptosomes obtained from chronically lead-treated rats and in synaptosomes with in vitro lead added. In vivo treatment of rats with lead acetate results in a decrease in the K(+)-depolarization-dependent release of GABA and dopamine and histidine. Lead given in vitro itself (independently of depolarizing condition) stimulated the release of previously accumulated neurotransmitters in synaptosomes (GABA and dopamine). This effect depends on lead acetate concentration. On the other hand lead, in different concentrations, did not cause changes in the histidine release. The results show that lead can attack the synaptic neurotransmission in two ways: by depressing the Ca-KCl-evoked release of GABA, dopamine and histidine and by a selective stimulation of a spontaneous release (independent of depolarization conditions) of GABA and dopamine but not histidine.