Hydrocephalus following prenatal methylmercury poisoning

Maternal exposure to methylmercury causes an impairment in ependymal cilia motility in the third ventricle and dilation of lateral ventricles in mice offspring

BACKGROUND

Although maternal MeHg-exposure causes hydrocephalus in the offspring of mice, its pathogenesis has not been fully explained. In the present study, we examined the issue of how maternal MeHg-exposure in mice affects ependymal ciliary movement in the offspring and whether the lateral ventricles in offspring show dilation.

METHODS

Pregnant mice were given drinking water containing 0, 10, or 20 mg/L MeHg, or a single dose of 2 mg/kg MeHg. Brain slices were prepared from the offspring and the ependymal ciliary movement of ependymal cells in the third ventricle were observed by a high-speed digital camera. The dilation of the lateral ventricles in the offspring was assessed by histological examination.

RESULTS

The administration of MeHg in the drinking water of pregnant mice at levels of 10 mg/L and 20 mg/L MeHg from GD10 to birth caused a significant decrease of ciliary beating frequency (CBF) in ependymal cells of the third ventricle in the weaned offspring. The ependymal ciliary movement of the weaned offspring was particularly sensitive in the case of the administration of MeHg at GD10. Moreover, there was a significant dilation of cross-sectional areas of lateral ventricles in weaned offspring from the pregnant mice that had been administered MeHg. The CBF and the cross-sectional areas of the lateral ventricles improved with time.

CONCLUSIONS

These results suggest that the impairment of ependymal ciliary movement by maternal MeHg-exposure contributes to the development of hydrocephalus in the offspring.

Single-neuron axonal pathfinding under geometric guidance: low-dose-methylmercury developmental neurotoxicity test

Because the nervous system is most vulnerable to toxicants during development, there is a crucial need for a highly sensitive developmental-neurotoxicity-test model to detect potential toxicants at low doses. We developed a lab-on-chip wherein single-neuron axonal pathfinding under geometric guidance was created using soft lithography and laser cell-micropatterning techniques. After coating the surface with L1, an axon-specific member of the Ig family of cell adhesion molecules (CAMs), and optimizing microunit geometric parameters, we introduced low-dose methylmercury, a well-known, environmentally significant neurotoxicant, in the shared medium. Its developmental neurotoxicity was evaluated using a novel axonal pathfinding assay including axonal turning and branching rates at turning points in this model. Compared to the conventional neurite-outgrowth assay, this model's detection threshold for low-dose methylmercury was 10-fold more sensitive at comparable exposure durations. These preliminary results support study of developmental effects of known and potential neurotoxicants on axon pathfinding. This novel assay model would be useful to study neuronal disease mechanisms at the single-cell level. To our knowledge, the potential of methylmercury chloride to cause acute in vitro developmental neurotoxicity (DNT) at such a low dosage has not been reported. This is the first DNT test model with high reproducibility to use single-neuron axonal pathfinding under precise geometric guidance.

Embryotoxic and teratogenic effects of nickel in Swiss albino mice during organogenetic period

The present study evaluates potential hazardous of nickel (Ni(+2) as NiCl2 ·6H2O) to Swiss albino mice fetus. Ni was administered orally on body weight base from days 6 to 13 of gestation period. Based on LD50, Ni doses (46.125, 92.25, and 184.5) mg Ni/kg b.wt. were used. On day 18 of gestation, uteri of the sacrificed dams were examined. A dose-dependent decrease (P < 0.01) in the body weight of the pregnant females and fetuses during the gestation period was observed. Number of implant sites and placental weight at all the three dose levels was lower compared with their respective control groups. Average number of live fetuses/dams reduced significantly (P < 0.01) at 184.5 mg Ni/kg b.wt. with concomitant increase in the percentage of postimplantation death and percentage of resorbed, macerated, and dead fetuses, respectively. Exposure increased the fetal malformations, namely, hydrocephaly, open eyelids, microphthalmia, exophthalmia, club foot, umbilical hernia, and skeletal anomalies. Reduced ossification of nasal, frontal, parietal, intraparietal, and supraoccipital bones, absence/gap between the ribs, reduced/fused sternebrae, vertebral centra, and caudal vertebrae, reduced pelvic elements, absence of carpals, metacarpals, tarsals, metatarsals, and phalanges were distinct. This indicates vulnerability of the mice fetus to nickel during prenatal exposure.

Mercury-induced toxicity of rat cortical neurons is mediated through N-Methyl-D-Aspartate receptors

BACKGROUND

Mercury is a well-known neurotoxin implicated in a wide range of neurological or psychiatric disorders including autism spectrum disorders, Alzheimer's disease, Parkinson's disease, epilepsy, depression, mood disorders and tremor. Mercury-induced neuronal degeneration is thought to invoke glutamate-mediated excitotoxicity, however, the underlying mechanisms remain poorly understood. Here, we examine the effects of various mercury concentrations (including pathological levels present in human plasma or cerebrospinal fluid) on cultured, rat cortical neurons.

RESULTS

We found that inorganic mercuric chloride (HgCl₂--at 0.025 to 25 μM) not only caused neuronal degeneration but also perturbed neuronal excitability. Whole-cell patch-clamp recordings of pyramidal neurons revealed that HgCl₂ not only enhanced the amplitude and frequency of synaptic, inward currents, but also increased spontaneous synaptic potentials followed by sustained membrane depolarization. HgCl₂ also triggered sustained, 2-5 fold rises in intracellular calcium concentration ([Ca²⁺]i). The observed increases in neuronal activity and [Ca²⁺]i were substantially reduced by the application of MK 801, a non-competitive antagonist of N-Methyl-D-Aspartate (NMDA) receptors. Importantly, our study further shows that a pre incubation or co-application of MK 801 prevents HgCl₂-induced reduction of cell viability and a disruption of β-tubulin.

CONCLUSIONS

Collectively, our data show that HgCl₂-induced toxic effects on central neurons are triggered by an over-activation of NMDA receptors, leading to cytoskeleton instability.

Mercury chronic toxicity might be associated to some cases of hydrocephalus in adult humans?

Mercury accumulates in nervous tissue causing neurological and psychiatric manifestations. Numerous clinical findings have been described in patients that suffered chronic mercury intoxication. Some findings, such as hydrocephalus, have been described only in experimental studies. Following, we present a case of 50 year-old man with a 3-month history of severe frontal headache episodes and vision loss together with a history of asthenia, anorexia, muscle pain, fatigue and neuropsychiatric symptoms. The magnetic resonance imaging showed hydrocephalus and stenosis of aqueduct of Sylvius. This patient reported that he worked as laboratory metallurgic auxiliary for over 30 years. During this time, he had been chronically exposed to elemental mercury. The metals whole blood test was normal, except by his blood mercury level that was 61.5 μg/L (normal ~1 μg/L). In our best knowledge, hydrocephalus and stenosis of aqueduct of Sylvius have been described only in animals exposed to methylmercury during their gestation. We think that this case of hydrocephalus might be associated with the chronic mercury exposure and therefore this etiology must be taken in account in a patient with hydrocephalus of unknown etiology.

Maternal dental history, child's birth outcome and early cognitive development

Prenatal exposure to high levels of mercury, radiation and inflammation have been associated with adverse reproductive outcomes such as increases in preterm delivery, low birthweight and delayed neurodevelopment. Few data are available to evaluate the potential effects of prenatal low-level exposure to these factors as may occur during dental care. We evaluated maternal dental history prior to and during pregnancy in relation to birth outcomes and early communicative development among offspring in a large cohort (n = 7375) of British children born in 1991-92. Dental history was assessed by questionnaire. The child's communicative development was assessed using the MacArthur Communicative Development Inventory at 15 months of age. Total mercury was measured in umbilical cord tissue for a subset of the children. Overall, dental care, including amalgam fillings, was not associated with birth outcomes or language development. Having X-rays taken during pregnancy was not associated with birthweight measured continuously (b = 14.7, P = 0.4), but was associated with slightly increased odds of having a term, low-birthweight baby (OR 1.9, [95% confidence interval 1.0, 3.4]). More detailed evaluation of the potential adverse effects of elective dental treatment during pregnancy, particularly dental X-rays, may be warranted.

Hydrocephalus following prenatal exposure to ethanol

Pregnant rats were administered a liquid diet containing 5% (w/v) ethanol between gestational days 10 and 21, and the brains of nine offspring were examined at 8 weeks of age. Two ethanol-treated offspring showed obvious hydrocephalus characterized by markedly enlarged lateral ventricles. Most of the other ethanol-treated rats only showed a slight enlargement of the lateral ventricles. An ethanol-treated offspring showed no neuropathological signs of hydrocephalus. Histological observation of the hydrocephalic brains revealed dilation of the lateral ventricles, loosely bundled corpus callosum, hypoplasia of the septum and fimbria, and thinning of the cerebral cortices. There were no differences in the shape of the third ventricle and aqueduct between hydrocephalic and non-hydrocephalic rats. Ectopic cell clusters were found on the surface of the lateral ventricle and in the interventricular foramen in ethanol-treated rats with hydrocephalus. However, leptomeningeal heterotopias were found on the cortical surface in ethanol-exposed rats independently of whether or not they showed hydrocephalus. Thus, heterotopias within the ventricles may be related to the genesis of hydrocephalus following prenatal ethanol exposure. However, whether they could be a direct cause of the hydrocephalus is uncertain as they seem to be not enough large to block the current of the cerebrospinal fluid. We also examined the expression of L1, a cell adhesion molecule suspected of involvement in the genesis of hydrocephalus after prenatal ethanol exposure, in 1-day-old rats. Western blot analysis using specific antibody against L1 showed no significant change in L1 protein expression in ethanol-exposed rats. These data suggest that L1 protein expression is not affected by ethanol.

Brain barrier systems: a new frontier in metal neurotoxicological research

The concept of brain barriers or a brain barrier system embraces the blood-brain interface, referred to as the blood-brain barrier, and the blood-cerebrospinal fluid (CSF) interface, referred to as the blood-CSF barrier. These brain barriers protect the CNS against chemical insults, by different complementary mechanisms. Toxic metal molecules can either bypass these mechanisms or be sequestered in and therefore potentially deleterious to brain barriers. Supportive evidence suggests that damage to blood-brain interfaces can lead to chemical-induced neurotoxicities. This review article examines the unique structure, specialization, and function of the brain barrier system, with particular emphasis on its toxicological implications. Typical examples of metal transport and toxicity at the barriers, such as lead (Pb), mercury (Hg), iron (Fe), and manganese (Mn), are discussed in detail with a special focus on the relevance to their toxic neurological consequences. Based on these discussions, the emerging research needs, such as construction of the new concept of blood-brain regional barriers, understanding of chemical effect on aged or immature barriers, and elucidation of the susceptibility of tight junctions to toxicants, are identified and addressed in this newly evolving field of neurotoxicology. They represent both clear challenges and fruitful research domains not only in neurotoxicology, but also in neurophysiology and pharmacology.

Hydrocephalus in mice following X-irradiation at early gestational stage: possibly due to persistent deceleration of cell proliferation

The pathogenesis of X-ray-induced congenital hydrocephalus was studied. Pregnant mice were irradiated at 1.4 Gy on gestational day 7 (G7). Four hours after irradiation, extensive cell death was evident in the neuroepithelium and underlying mesoderm of the head region, and proliferating cell nuclear antigen (PCNA)-immunoreactive cells almost disappeared. Embryos with thinner lamina terminalis of the telencephalon, when compared with that of the control, were found in the irradiated group on G9. As early as G11 in some irradiated embryos the telencephalic wall was thinner and lateral ventricles were larger than those of the control. The choroid invagination from the lamina terminalis began on G11 in the control brain, but not in the affected brain. During the following development, fetuses with readily apparent hydrocephalus were consistently found among irradiated fetuses. In these brains the brain mantle was thinner, the corpus striatum and thalamic regions were smaller, and lateral ventricles were larger than those of the control. Even on G11 and G13 the frequencies of PCNA-positive cells in the brain mantle and other brain regions were lower in the hydrocephalic brain than those of the control, suggesting a decelerated proliferation of successive cell generations following exposure to X-rays. The cerebral aqueduct was open in the hydrocephalic brain during the fetal period when the lateral ventricles were dilated. The head was vaulted after birth but the cerebral aqueduct was not completely occluded even in these animals. These findings suggested that cell death in the neuroepithelium followed by a persistent deceleration of neural cell proliferation, resulting in the hypoplasia of brain parenchyma with compensatory ventricular dilatation, is important for the establishment of hydrocephalus.

Strain difference of the mouse in manifestation of hydrocephalus following prenatal methylmercury exposure

Genetic background may influence susceptibility to hydrocephalus. In the present experiment we compared the manifestation of hydrocephalus following prenatal methylmercury exposure among strains of mice which sporadically develop or never develop spontaneous hydrocephalus. Pregnant mice of the B10.D2 congenic strain were given a single oral dose of 10 mg/kg methylmercuric chloride on one of days 14 through 17 of pregnancy and allowed to give birth and rear their litters. The incidence of grossly apparent hydrocephalus in the offspring at 30 days of age following treatment on day 14, 15, 16, or 17 of pregnancy was 67, 88, 75, and 48%, respectively; that of sham-treated and untreated offspring was 5 and 4%, respectively. In addition, there were some brains showing slight dilatation of the lateral ventricles. Pregnant females of C57BL/10 (B10) or DBA/2 (D2) strain were also treated with 10 mg/kg methylmercury on day 15 of pregnancy. The incidence of hydrocephalus at 30 days of age in untreated and dosed B10 mice was 0.8 and 54%, respectively. Hydrocephalus failed to develop in D2 mice. The hydrocephalus is a communicating type. Occlusion of the cerebral aqueduct with glial reaction and caudal displacement of the cerebellum are considered to be secondary changes. The results indicate that the susceptibility to methylmercury-induced hydrocephalus is under genetic control in mice.