Molecular Mechanisms of Lead Neurotoxicity

Epidemiological studies have shown a strong relationship between the level of lead in blood and bone as assessed by performance on IQ tests and other psychometric tests. Approximately 1 out of 10 children in the United States have blood lead levels above 10g/dl, which has been established as the level of concern. Studies on experimental animals exposed to lead after birth have shown learning deficits at similar blood lead levels. Since learning requires the remodeling of synapses in the brain, lead may specifically affect synaptic transmission. Although the molecular targets for lead are unknown, a vast amount of evidence accumulated over many years has shown that lead disrupts processes that are regulated by calcium. Our laboratory has been studying the effect of lead on protein kinase C, a family of isozymes some of which require calcium for activity. We and others have shown that picomolar concentrations of lead can replace micromolar concentrations of calcium in a protein kinase C enzyme assay. Furthermore, lead activates protein kinase C in intact cells and induces the expression of new genes by a mechanism dependent on protein kinase C. We propose that the learning deficits caused by lead are due to events regulated by protein kinase C that most likely occur at the synapse.     

Molecular and Cellular Mechanisms of Ecstasy-Induced Neurotoxicity: An Overview

“Ecstasy” [(±)-3,4-methylenedioxymethamphetamine, MDMA, XTC, X, E] is a psychoactive recreational hallucinogenic substance and a major worldwide drug of abuse. Several reports raised the concern that MDMA has the ability to induce neurotoxic effects both in laboratory animals and humans. Despite more than two decades of research, the mechanisms by which MDMA is neurotoxic are still to be fully elucidated. MDMA induces serotonergic terminal loss in rats and also in some mice strains, but also a broader neuronal degeneration throughout several brain areas such as the cortex, hippocampus, and striatum. Meanwhile, in human “ecstasy” abusers, there are evidences for deficits in seronergic biochemical markers, which correlate with long-term impairments in memory and learning. There are several factors that contribute to MDMA-induced neurotoxicity, namely, hyperthermia, monoamine oxidase metabolism of dopamine and serotonin, dopamine oxidation, the serotonin transporter action, nitric oxide, and the formation of peroxinitrite, glutamate excitotoxicity, serotonin 2A receptor agonism, and, importantly, the formation of MDMA neurotoxic metabolites. The present review covered the following topics: history and epidemiology, pharmacological mechanisms, metabolic pathways and the influence of isoenzyme genetic polymorphisms, as well as the acute effects of MDMA in laboratory animals and humans, with a special focus on MDMA-induced neurotoxic effects at the cellular and molecular level. The main aim of this review was to contribute to the understanding of the cellular and molecular mechanisms involved in MDMA neurotoxicity, which can help in the development of therapeutic approaches to prevent or treat the long-term neuropsychiatric complications of MDMA abuse in humans.     

Mechanisms of Suppression of {alpha}-Synuclein Neurotoxicity by Geldanamycin in Drosophila

Parkinson's disease is a common neurodegenerative disease characterized by the loss of dopaminergic neurons in the substantia nigra pars compacta and the accumulation of the protein alpha-synuclein into aggregates called Lewy bodies and Lewy neurites. Parkinson's disease can be modeled in Drosophila where directed expression of alpha-synuclein induces compromise of dopaminergic neurons and the formation of Lewy body-like aggregates. The molecular chaperone Hsp70 protects cells from the deleterious effects of alpha-synuclein, indicating a potential therapeutic approach to enhance neuron survival in Parkinson's disease. We have now investigated the molecular mechanisms by which the drug geldanamycin protects neurons against alpha-synuclein toxicity. Our studies show that geldanamycin sensitizes the stress response within normal physiological parameters to enhance chaperone activation, offering protection against alpha-synuclein neurotoxicity. Further, geldanamycin uncouples neuronal toxicity from Lewy body and Lewy neurite formation such that dopaminergic neurons are protected from the effects of alpha-synuclein expression despite the continued presence of (and even increase in) inclusion pathology. These studies indicate that compounds that modulate the stress response are a promising approach to treat Parkinson's disease.     

A Model of Glutamate Neurotoxicity and Mechanisms of the Development of the Typical Pathological Process

Biophysics - A glutamate model of stroke was analyzed from the standpoint of the development of a typical pathological process that is thought to occur when major regulatory mechanisms are...     

Use of Bullfrog Tadpoles (Rana catesbeiana) to Examine the Mechanisms of Lead Neurotoxicity

Sublethal exposure to lead elicits changes in behavior, particularlylearning. Previously, we had shown that bullfrog tadpoles exposedto 1 mg Pb/liter for 7 days exhibit learning deficits in a discriminateavoidance learning assay. The precise mechanisms involved inthese lead-induced learning deficits are not understood, butCNS monoamine neurotransmitter systems have been implicatedin the learning process. In the present study, we exposed bullfrogtadpoles to 1.7± 0.2 mg Pb/liter for 7 days and thencompared concentrations of neurotransmitters from whole brainsamples with those of controls. Serotonin or 5-hydroxytryptamine(5-HT) was significantly decreased in the lead exposed groupwhile the serotonin metabolite, 5-hydroxyindoleacetic acid,(5-HIAA) was similar to controls. No changes were observed inthe catecholamines epinephrine and norepinephijine followinglead exposure. The ratio of 5-HIAA/5-HT was significantly increasedin lead exposed animals as a result of the decrease in 5-HT,suggesting a decrease in 5-HT biosynthesis rather than an increasein 5-HT metabolism. These findings are the first to suggestthat lead exposure in bullfrog tadpoles affects the monoamineneurotransmitters that are implicated in the learning process.The results of the present study, in conjunction with previousevidence of learning deficits following lead exposure, offerthe possibility of correlating lead exposure with learning deficitsand alterations in CNS neurotransmitters in bullfrog tadpoles.The use of this tadpole model shows promise as a means to examineand understand the mechanisms involved in lead neurotoxicity.     

Puerarin Ameliorates 3-Nitropropionic Acid-Induced Neurotoxicity in Rats: Possible Neuromodulation and Antioxidant Mechanisms

Puerarin (daidzein-8-C-glucoside), a major isoflavone glycoside purified from Pueraria lobata, is well reported to have a neuroprotective effect primarily by the antioxidant mechanisms. This investigation was designed to evaluate the efficacy of Puerarin (Pur) to offset 3-nitropropionic acid (3-NP) induced neurotoxicity. Male Wistar strain rats were given 3-NP (20 mg/kg, s.c.) over five consecutive days, whereas Pur (200 mg/kg, i.p.) was administrated 30 min before 3-NP. Rats treated with 3-NP exhibited significant weight loss, reduction of the prepulse inhibition, locomotor hypoactivity and hypothermia. The striata, hippocampi and cortices of the 3-NP treated rats showed abnormal levels of neurotransmitters, oxidative damage and characteristic histopathological lesions. Treatment with Pur ahead of 3-NP, significantly prevented weight loss, PPI deficit, locomotor hypoactivity and hypothermia. Pur treatment blocked the 3-NP-induced neurotransmitters abnormalities (GABA, DA, 5-HT and NE), and normalized the oxidative stress biomarkers (lipid peroxidation, reduced glutathione, glutathione peroxidase). Histopathological examination further affirmed Pur’s neuroprotective effect against 3-NP-induced neurotoxicity. In conclusion, Pur protected the brain tissues from 3-NP induced neurotoxicity primarily by its neuromodulation and antioxidant effect.     

Crocin Inhibits Apoptosis and Astrogliosis of Hippocampus Neurons Against Methamphetamine Neurotoxicity via Antioxidant and Anti-inflammatory Mechanisms

Methamphetamine (METH) is a stimulant drug, which can cause neurotoxicity and increase the risk of neurodegenerative disorders. The mechanisms of acute METH intoxication comprise intra-neuronal events including oxidative stress, dopamine oxidation, and excitotoxicity. According to recent studies, crocin protects neurons by functioning as an anti-oxidant, anti-inflammatory, and anti-apoptotic compound. Accordingly, this study aimed to determine if crocin can protect against METH-induced neurotoxicity. Seventy-two male Wistar rats that weighed 260–300 g were randomly allocated to six groups of control (n?=?12), crocin 90 mg/kg group (n?=?12), METH (n?=?12), METH?+?crocin 30 mg/kg (n?=?12), METH?+?crocin 60 mg/kg (n?=?12), and METH?+?crocin 90 mg/kg (n?=?12). METH neurotoxicity was induced by 40 mg/kg of METH in four injections (e.g., 4?×?10 mg/kg q. 2 h, IP). Crocin was intraperitoneally (IP) injected at 30 min, 24 h, and 48 h after the final injection of METH. Seven days after METH injection, the rats’ brains were removed for biochemical assessment using the ELISA technique, and immunohistochemistry staining was used for caspase-3 and glial fibrillary acidic protein (GFAP) detection. Crocin treatment could significantly increase superoxide dismutase (P?<?0.05) and glutathione (P?<?0.01) levels and reduce malondialdehyde and TNF-α in comparison with the METH group (P?<?0.05). Moreover, crocin could significantly decline the level of caspase-3 and GFAP-positive cells in the CA1 region (P?<?0.01). According to the results, crocin exerts neuroprotective effects on METH neurotoxicity via the inhibition of apoptosis and neuroinflammation.     

Presynaptic Mechanisms of Lead Neurotoxicity: Effects on Vesicular Release,Vesicle Clustering and Mitochondria Number

Childhood lead (Pb²⁺) intoxication is a global public health problem and accounts for 0.6% of the global burden of disease associated with intellectual disabilities. Despite the recognition that childhood Pb²⁺ intoxication contributes significantly to intellectual disabilities, there is a fundamental lack of knowledge on presynaptic mechanisms by which Pb²⁺ disrupts synaptic function. In this study, using a well-characterized rodent model of developmental Pb²⁺ neurotoxicity, we show that Pb²⁺ exposure markedly inhibits presynaptic vesicular release in hippocampal Schaffer collateral-CA1 synapses in young adult rats. This effect was associated with ultrastructural changes which revealed a reduction in vesicle number in the readily releasable/docked vesicle pool, disperse vesicle clusters in the resting pool, and a reduced number of presynaptic terminals with multiple mitochondria with no change in presynaptic calcium influx. These studies provide fundamental knowledge on mechanisms by which Pb²⁺ produces profound inhibition of presynaptic vesicular release that contribute to deficits in synaptic plasticity and intellectual development.     

Neurotoxicity of Ammonia

Abnormal liver function has dramatic effects on brain functions. Hyperammonemia interferes profoundly with brain metabolism, astrocyte volume regulation, and in particular mitochondrial functions. Gene expression in the brain and excitatory and inhibitory neurotransmission circuits are also affected. Experiments with a number of pertinent animal models have revealed several potential mechanisms which could underlie the pathological phenomena occurring in hepatic encephalopathy.     

L-Cysteine influx in type 2 diabetic erythrocytes

Erythrocyte oxidative stress has been implicated in the pathogenesis of diabetes mellitus, and the deficiency of antioxidant defense by the glutathione (GSH) pathway is thought to be one of the factors responsible for development of complications in diabetes. Erythrocytes require L-cysteine for the synthesis of GSH and the rate of synthesis is determined only by L-cysteine availability. In the present study we have found that the L-cysteine influx in erythrocytes from type 2 diabetic patients was significantly lower compared to age-matched controls. The decreased influx may be one of the factors leading to low GSH concentration observed in type 2 diabetes. Since L-cysteine is the limiting amino acid in GSH synthesis, any strategy aimed to increase L-cysteine influx in erythrocytes may be beneficial for type 2 diabetic patients.     

假单胞菌L-半胱氨酸合成酶的纯化和性质研究

假单胞菌TS-1138的细胞浆液通过硫铵沉淀、SephadexG-75凝胶过滤、DEAE-Cellulose52离子交换、SephadexG 100凝胶过滤等分离纯化手段分别将从L-ATC合成L 半胱氨酸的两个酶——L-ATC水解酶和L-SCC水解酶纯化了 83.9和 90.3倍。SDS-PAGE鉴定均为单一条带 ,两种酶的相对分子质量分别为 37.5和 42.8kD ;酶反应的最适温度均为 35℃ ,最适pH分别为 7.0和 8.0 ;酶的米氏常数分别为 0.67mmol L和 0.15mmol L ,     

Neurotoxicity of depleted uranium

Depleted uranium (DU) is a byproduct of the enrichment process of uranium for its more radioactive isotopes to be used in nuclear energy. Because DU is pyrophoric and a dense metal with unique features when combined in alloys, it is used by the military in armor and ammunitions. There has been significant public concern regarding the use of DU by such armed forces, and it has been hypothesized to play a role in Gulf War syndrome. In light of experimental evidence from cell cultures, rats, and humans, there is justification for such concern. However, there are limited data on the neurotoxicity of DU. This review reports on uranium uses and its published health effects, with a major focus on in vitro and in vivo studies that escalate concerns that exposure to DU might be associated with neurotoxic health sequelae.     

L-Cysteine increases Agrobacterium-mediated T-DNA delivery into soybean cotyledonary-node cells

A major limitation in producing transgenic soybeans [Glycine max (L.) Merrill] using the Agrobacterium-mediated cotyledonary-node method is low-frequency T-DNA transfer from Agrobacterium tumefaciens into cotyledonary-node cells. We increased Agrobacterium infection from 37% to 91% of explants in the cotyledonary-node region by amending the solid co-cultivation medium with L-cysteine, which resulted in a fivefold increase in stable T-DNA transfer in newly developed shoot primordia. Southern analysis detected greater than a twofold increase in transformation efficiency, as determined by the number of independent fertile, transgene plants per explants inoculated. Enzymatic browning on explant tissue was also reduced, which suggests cysteine may interact with wound- and pathogen-defense responses in the soybean explant, resulting in an increased T-DNA delivery into the cotyledonary-node cells.     

Adoptive Autophagy Activation: a Much-Needed Remedy Against Chemical Induced Neurotoxicity/Developmental Neurotoxicity

The profound significance of autophagy as a cell survival mechanism under conditions of metabolic stress is a well-proven fact. Nearly a decade-long research in this area has led scientists to unearth various roles played by autophagy other than just being an auto cell death mechanism. It is implicated as a vital cell survival pathway for clearance of all the aberrant cellular materials in case of cellular injury, metastasis, disease states, cellular stress, neurodegeneration and so on. In this review, we emphasise the critical role of autophagy in the environmental stressors-induced neurotoxicity and its therapeutic implications for the same. We also attempt to shed some light on the possible protective role of autophagy in developmental neurotoxicity (DNT) which is a rapidly growing health issue of the human population at large and hence a point of rising concern amongst researchers. The intimate association between DNT and neurodegenerative disorders strongly indicates towards adopting autophagy activation as a much-needed remedy for DNT.     

Neurotoxicity of methamphetamine and 3,4-methylenedioxymethamphetamine

Amphetamines are a class of psychostimulant drugs that are widely abused for their stimulant, euphoric, empathogenic and hallucinogenic properties. Many of these effects result from acute increases in dopamine and serotonin neurotransmission. Subsequent to these acute effects, methamphetamine and 3,4 methylenedioxymethamphetamine (MDMA) produce persistent damage to dopamine and serotonin nerve terminals. This review summarizes the numerous interdependent mechanisms including excitotoxicity, mitochondrial damage and oxidative stress that have been demonstrated to contribute to this damage. Emerging non-neuronal mechanisms by which the drugs may contribute to monoaminergic terminal damage, as well as the neuropsychiatric consequences of this terminal damage are also presented. Methamphetamine and 3,4-methylenedioxymethamphetamine (MDMA) have similar chemical structures and pharmacologic properties compared to other abused substances including cathinone (khat), as well as a relatively new class of novel synthetic amphetamines known as ‘bath salts’ that have gained popularity among drug abusers.     

Free Radical-Generated Neurotoxicity of 6-Hydroxydopamine

Abstract: Albino rats were lesioned bilaterally with 6-hydroxydopamine (6-OHDA) hydrochloride (4 µg/µl, dissolved in saline with 0.1% ascorbic acid) into the striatum, and 72 h after the injection, levels of lipid peroxidation, GSH, superoxide dismutase (SOD), glutathione peroxidase (GSH-Px), lipid class, membrane fluidity, and intracellular calcium concentrations were studied and the results were compared with those in the sham-operated controls. The malonaldialdehyde level and the level of conjugated dienes were increased by 43 and 40%, respectively, in corpus striatum, and GSH, SOD, and GSH-Px levels were decreased (24–30%) following 6-OHDA treatment. Total phospholipid content was also decreased (18%), whereas cholesterol content remained unaffected. Among the different phospholipids only phosphatidylcholine and phosphatidylinositol were decreased in level. Membrane fluidity was decreased (23%), whereas the intracellular calcium concentration was elevated (100%) in corpus striatum compared with control rats. The results suggest that these alterations in membrane-related events by 6-OHDA could be due to free radical generation.