Exposure to Toxicants Affects Everyone, Especially the Very Young.

Toxicology is an incredibly complex and diverse area of biomedical science that includes numerous areas of specialization [...].

Mercury Toxicity and Neurogenesis in the Mammalian Brain.

The mammalian brain is formed from billions of cells that include a wide array of neuronal and glial subtypes. Neural progenitor cells give rise to the vast majority of these cells during embryonic, fetal, and early postnatal developmental periods. The process of embryonic neurogenesis includes proliferation, differentiation, migration, the programmed death of some newly formed cells, and the final integration of differentiated neurons into neural networks. Adult neurogenesis also occurs in the mammalian brain, but adult neurogenesis is beyond the scope of this review. Developing embryonic neurons are particularly susceptible to neurotoxicants and especially mercury toxicity. This review focused on observations concerning how mercury, and in particular, methylmercury, affects neurogenesis in the developing mammalian brain. We summarized information on models used to study developmental mercury toxicity, theories of pathogenesis, and treatments that could be used to reduce the toxic effects of mercury on developing neurons.

Effects of methyl mercury exposure on pancreatic beta cell development and function.

Methyl mercury is an environmental contaminant of worldwide concern. Since the discovery of methyl mercury exposure due to eating contaminated fish as the underlying cause of the Minamata disaster, the scientific community has known about the sensitivity of the developing central nervous system to mercury toxicity. Warnings are given to pregnant women and young children to limit consumption of foods containing methyl mercury to protect the embryonic, fetal and postnatally developing central nervous system. However, evidence also suggests that exposure to methyl mercury or various forms of inorganic mercury may also affect development and function of other organs. Numerous reports indicate a worldwide increase in diabetes, particularly type 2 diabetes. Quite recently, methyl mercury has been shown to have adverse effects on pancreatic beta (ß) cell development and function, resulting in insulin resistance and hyperglycemia and may even lead to the development of diabetes. This review discusses possible mechanisms by which methyl mercury exposure may adversely affect pancreatic ß cell development and function, and the role that methyl mercury exposure may have in the reported worldwide increase in diabetes, particularly type 2 diabetes. While additional information is needed regarding associations between mercury exposure and specific mechanisms of the pathogenesis of diabetes in the human population, methyl mercury's adverse effects on the body's natural sources of antioxidants suggest that one possible therapeutic strategy could involve supplementation with antioxidants. Thus, it is important that additional investigation be undertaken into the role of methyl mercury exposure and reduced pancreatic ß cell function. Copyright © 2016 John Wiley & Sons, Ltd.

Transmission electron microscopic evaluation of neuronal changes in methylmercury-exposed zebrafish embryos (Danio rerio).

Our work aimed to elucidate the ultrastructural changes associated with brain neurons in wild-type zebrafish embryos exposed to different concentrations of methylmercury. Zebrafish embryos were exposed to one of five concentrations of methylmercury (0 [negative control], 5, 10, 50, and 80 parts per billion) starting at six hours post fertilization (hpf). At 96 hpf, cells in the zebrafish embryo brains were examined using transmission electron microscopy. The developing neurons of the control embryos sowed normal cellular ultrastructure. Few alterations were observed among the neurons of zebrafish embryos exposed to 5 ppb methylmercury. The cells of the embryos exposed to 10 ppb methylmercury showed slight cellular degeneration as demonstrated by the accumulation of electron dens bodies which were presumably lysosomes in different stages of formation. In embryos exposed to 50 ppb methylmercury, the neuronal cytoplasm conained large electron dense lysosomes and the rough endoplasmic reticulum appeared to be reduced and irregular in shape. Furthermore, the embryonic brain neurons exposed to 80 ppb methylmercury showed the most severe ultrastructural changes, including some that were consistent with different stages of the cell death process. Obvious cellular changes were observed in this highest exposure group included: disrupted or degenerating nuclei; fragmentation or vacuolization of mitochondrial cristae; and loss of mitochondrial matrix density. Based on these observations, we conclude that these different morphological patterns of cellular changes may reflect either different stages of the cell death process or different types of cell death due to 24 hours of exposure to 80 ppb methylmercury.

Pluripotent state induction in mouse embryonic fibroblast using mRNAs of reprogramming factors.

Reprogramming of somatic cells has great potential to provide therapeutic treatments for a number of diseases as well as provide insight into mechanisms underlying early embryonic development. Improvement of induced Pluripotent Stem Cells (iPSCs) generation through mRNA-based methods is currently an area of intense research. This approach provides a number of advantages over previously used methods such as DNA integration and insertional mutagenesis. Using transfection of specifically synthesized mRNAs of various pluripotency factors, we generated iPSCs from mouse embryonic fibroblast (MEF) cells. The genetic, epigenetic and functional properties of the iPSCs were evaluated at different times during the reprogramming process. We successfully introduced synthesized mRNAs, which localized correctly inside the cells and exhibited efficient and stable translation into proteins. Our work demonstrated a robust up-regulation and a gradual promoter de-methylation of the pluripotency markers, including non-transfected factors such as Nanog, SSEA-1 (stage-specific embryonic antigen 1) and Rex-1 (ZFP-42, zinc finger protein 42). Using embryonic stem cells (ESCs) conditions to culture the iPS cells resulted in formation of ES-like colonies after approximately 12 days with only five daily repeated transfections. The colonies were positive for alkaline phosphatase and pluripotency-specific markers associated with ESCs. This study revealed the ability of pluripotency induction and generation of mouse mRNA induced pluripotent stem cells (mRNA iPSCs) using transfection of specifically synthesized mRNAs of various pluripotency factors into mouse embryonic fibroblast (MEF) cells. These generated iPSCs exhibited molecular and functional properties similar to ESCs, which indicate that this method is an efficient and viable alternative to ESCs and can be used for further biological, developmental and therapeutic investigations.

The effect of methylmercury exposure on behavior and cerebellar granule cell physiology in aged mice.

Epidemiology studies have clearly documented that the central nervous system is highly susceptible to methylmercury toxicity, and exposure to this neurotoxicant in humans primarily results from consumption of contaminated fish. While the effects of methylmercury exposure have been studied in great detail, comparatively little is known about the effects of moderate to low dose methylmercury toxicity in the aging central nervous system. We examined the toxic effects of a moderate dose of methylmercury on the aging mouse cerebellum. Male and female C57BL/6 mice at 16-20 months of age were exposed to methylmercury by feeding a total dose of 5.0 mg kg(-1) body weight and assessed using four behavioral tests. Methylmercury-treated aged mice performed significantly worse in open field, footprint analysis and the vertical pole test compared with age-matched control mice. Isolated cerebellar granule cells from methylmercury-treated aged mice exhibited higher levels of reactive oxygen species and reduced mitochondrial membrane potentials, but no differences in basal intracellular calcium ion levels compared with age-matched control mice. When aged mice were exposed to a moderate dose of methylmercury, they exhibited a similar degree of impairment when compared with young adult mice exposed to the same moderate dose of methylmercury, as reported in earlier studies from this laboratory. Thus, at least in mice, exposure of the aged brain to moderate concentrations methylmercury does not pose greater risk compared with the young adult brain exposed to similar concentrations of methylmercury.

Smoking during pregnancy: lessons learned from epidemiological studies and experimental studies using animal models.

Numerous epidemiological studies in the human population clearly indicate that smoking while pregnant has deleterious effects on fetal development as well as long-term adverse consequences on postnatal development and maturation of several organ systems. Low birth weight, sudden infant death syndrome (SIDS), behavioral disorders including attention deficit hyperactivity disorder (ADHD), externalizing and internalizing behavioral problems and conduct disorders in children have all been linked to prenatal exposure to tobacco smoke. The major pharmacologically active chemical found in tobacco smoke is nicotine, and prenatal exposure to nicotine has been shown to have significant effect on the development of multiple organ systems, including the nervous, respiratory, and cardiovascular systems. In this review, we define mainstream and sidestream smoke, summarize the major classes of compounds found in cigarette smoke, and describe how use of laboratory animal models can be used to assess mechanisms of toxicity and risk in the human population in general. We then discuss the association with smoking during pregnancy and the occurrence of reduced lung function, low birth weight, the incidence of congenital structural malformations, SIDS, ADHD, cognitive impairment, and mood disorders in children, and review pertinent experimental studies using a variety of animal models of developmental nicotine exposure, including, rats, mice, monkeys, lambs, and pigs that have increased our understanding of the pathophysiology of these disorders.

Adult neurogenesis in the mammalian dentate gyrus.

Earlier observations in neuroscience suggested that no new neurons form in the mature central nervous system. Evidence now indicates that new neurons do form in the adult mammalian brain. Two regions of the mature mammalian brain generate new neurons: (a) the border of the lateral ventricles of the brain (subventricular zone) and (b) the subgranular zone (SGZ) of the dentate gyrus of the hippocampus. This review focuses only on new neuron formation in the dentate gyrus of the hippocampus. During normal prenatal and early postnatal development, neural stem cells (NSCs) give rise to differentiated neurons. NSCs persist in the dentate gyrus SGZ, undergoing cell division, with some daughter cells differentiating into functional neurons that participate in learning and memory and general cognition through integration into pre-existing neural networks. Axons, which emanate from neurons in the entorhinal cortex, synapse with dendrites of the granule cells (small neurons) of the dentate gyrus. Axons from granule cells synapse with pyramidal cells in the hippocampal CA3 region, which send axons to synapse with CA1 hippocampal pyramidal cells that send their axons out of the hippocampus proper. Adult neurogenesis includes proliferation, differentiation, migration, the death of some newly formed cells and final integration of surviving cells into neural networks. We summarise these processes in adult mammalian hippocampal neurogenesis and discuss the roles of major signalling molecules that influence neurogenesis, including neurotransmitters and some hormones. The recent controversy raised concerning whether or not adult neurogenesis occurs in humans also is discussed.

Morphological and functional comparison of lingual papillae in suckling and adult feral cats: Forensic evidence.

Feral cats are considered as strays and are more likely to hunt in the street. We investigated the effect of environmental adaptations on the structures of lingual papillae in feral cats, which could be used as forensic evidence for their identification. There are no reported studies about the structural comparison of lingual papillae between suckling and adult feral cats. The present study described the lingual papillae of both suckling and adult cats macroscopically and microscopically via light and scanning electron microscopy. A total of nine tongue samples each for suckling and adult feral cats were examined grossly and histologically. Papillae distributions of suckling cats were similar to those observed in adult cats. Meanwhile, the shapes of those papillae were markedly different from that of corresponding papillae in adults. The change in taste bud position and size seemed to be related to the progressive growth of the papillae between adult and suckling cats; absence of taste buds in foliate papillae of feral cats at any stage; and marginal papillae which were a characteristic feature for all suckling cats. All previous elements could be affected by the specific feeding behaviour and mastication mode adaptation in suckling and adult feral cats which might help to identify suckling and adult feral cats among other breeds and animal species. We anticipate these findings may provide promising forensic evidence to discriminate between adult and suckling feral cat remains as well as prediction of environmental harshness and feeding behaviour.

Chronic, low-dose prenatal exposure to methylmercury impairs motor and mnemonic function in adult C57/B6 mice.

Methylmercury (MeHg) has cytotoxic effects on animals and humans, and a major target organ for MeHg is the central nervous system (CNS). It is well known that the developing CNS is extremely vulnerable to MeHg-induced changes in comparison to the mature brain. Most studies have concentrated on the direct effects of high levels of prenatal MeHg exposure. Surprisingly, behavioral outcomes found in adult offspring exposed developmentally to the neurotoxic effects of chronic, low-dose mercury more akin to ingestion in humans are not well characterized. The objective of this study was to determine whether such exposure produces deleterious effects on behavior in adult mice, including motor/coordination abilities, overall activity and mnemonic function. Developing mouse fetuses were exposed in utero during gestational days 8-18 by giving pregnant C57Bl/6J female mice food containing MeHg at a daily dose of 0.01 mg/kg body weight. Adult mice prenatally exposed to MeHg exhibited significant deficits in motor abilities, coordination, and overall activity, as measured by rotarod, footprint analysis and open field. In addition, MeHg-exposed mice were impaired with respect to reference memory but not in a visible, cued version of the Morris water maze task. These results indicate that prenatal exposure to the lowest dose of MeHg examined to date can have long-lasting motor and cognitive consequences on adult offspring. These findings have far reaching implications related to putative safe levels of MeHg ingestion, particularly during pregnancy, and increasing rates of cognitive and psychological disorders (e.g. attention hyperactivity deficit disorder, autism) in our society.

Analysis of calcium ion homeostasis and mitochondrial function in cerebellar granule cells of adult CaV 2.1 calcium ion channel mutant mice.

CaV 2.1 voltage-gated calcium channels (VGCC) are highly expressed by cerebellar neurons, and their dysfunction is linked to human disorders including familial hemiplegic migraine, episodic ataxia type 2 and spinocerebellar ataxia type 6. Altered calcium homeostasis, due to dysfunctional Ca(V 2.1 VGCC can severely affect mitochondrial function, eventually leading to neuronal cell death. We study leaner and tottering mice, which carry autosomal recessive mutations in the gene coding for the alpha 1A pore-forming subunit of CaV 2.1 VGCC. Both leaner and tottering mice exhibit cerebellar ataxia and epilepsy. Excessive leaner cerebellar granule cell (CGC) death starts soon after postnatal day 10, but it is not known whether the degree of CGC cell death observed in adult leaner mice is significantly different from wild type mice. We used Fluoro-Jade and TUNEL staining to quantify apoptotic cell death in leaner and wild type CGC. We investigated calcium homeostasis, mitochondrial function and generation of reactive oxygen species (ROS) in isolated CGC, using indicator dyes Fura-2AM, TMRM and CMH2DCFDA, respectively. We observed a small but significant increase in number of apoptotic adult leaner CGC. Calcium homeostasis and mitochondrial function also were altered in leaner CGC. However, no significant differences in ROS levels were observed. It is possible that CGC death in leaner mice may be related to mitochondrial dysfunction but may not be directly related to decreased basal intracellular calcium.

Effects of quillaja saponin (Quillaja saponaria) on early embryonic zebrafish (Danio rerio) development.

Although much attention has focused on environmental contamination by heavy metals, pesticides, and polychlorinated biphenyls, potential deleterious effects of naturally occurring organic compounds have received much less consideration. Saponins, which are glycosides found in many plants, are important, environmentally ubiquitous organic compounds. Saponins have both beneficial and deleterious effects in adults, but little is known about how saponins effect early vertebrate embryonic development. The authors tested the toxicity of quillaja saponin using a zebrafish embryo assay. Quillaja saponin, extracted from bark of the tree, Quillaja saponaria, is a common foaming agent used in foods and beverages. At 6 h post fertilization, zebrafish embryos were exposed to five concentrations (0 [negative control], 1, 5, 10 or 20 micro g) of quillaja saponin per milliliter of medium. Zebrafish embryos exposed to 2% ethanol were positive controls (100% embryonic death). Embryos were assessed at 30, 54, and 72 h post fertilization for changes in embryonic development, mortality, time of hatching, and morphological deformities. Embryos exposed to 1 and 5 micro g saponin were healthy, showed no obvious deformities, but exhibited shrinkage of the chorion. Hatching time for zebrafish embryos exposed to 1 and 5 micro g/ml saponin decreased by 18 h compared to unexposed embryos. Zebrafish embryos treated with 5 micro g/ml saponin responded less to touch than embryos treated with 1 micro g/ml saponin or controls. Zebrafish embryos exposed to more than 5 micro g/ml saponin exhibited 100% embryonic mortality. These results indicate that exposure to 5 micro g/ml or less of quillaja saponin acts as a growth promoter, whereas concentrations of 10 micro g/ml or greater are lethal.

Survey of nuclear progesterone receptor expression in the uterus of the cyclic and pregnant camel (Camelus dromedarius).

Progesterone receptors (PR) are necessary to mediate the biological effects of progesterone and are integral to the regulation of a number of different aspects of reproduction in mammals including ovulation of the oocyte, implantation of the conceptus and maintenance of pregnancy. This study investigated the expression and localization of progesterone receptors in the uterine wall of both pregnant and cyclic (nonpregnant) camels. Uterine tissue samples were collected from healthy animals and processed for routine histological and immunohistochemical staining techniques to reveal nuclear PR. Demonstration of PR was performed by indirect immunohistochemical techniques using monoclonal antibodies raised against human PR. Immunolocalization of PR was more intense in all four endometrial zones (I-IV) as well as the myometrium of non pregnant (cyclic) animals (animals with newly formed corpus luteum). In contrast, PR immunostaining in both the endometrium and the myometrium was greatly reduced in pregnancy, particularly in the latest stage examined (approximately 366 days of gestation). In conclusion, a better understanding of the expression of steroid hormones and their receptors, including progesterone and the PR is critical to improving the reproductive health and pregnancy in the domesticated dromedary camel.

Robust Cell Detection for Large-Scale 3D Microscopy Using GPU-Accelerated Iterative Voting.

High-throughput imaging techniques, such as Knife-Edge Scanning Microscopy (KESM),are capable of acquiring three-dimensional whole-organ images at sub-micrometer resolution. These images are challenging to segment since they can exceed several terabytes (TB) in size, requiring extremely fast and fully automated algorithms. Staining techniques are limited to contrast agents that can be applied to large samples and imaged in a single pass. This requires maximizing the number of structures labeled in a single channel, resulting in images that are densely packed with spatial features. In this paper, we propose a three-dimensional approach for locating cells based on iterative voting. Due to the computational complexity of this algorithm, a highly efficient GPU implementation is required to make it practical on large data sets. The proposed algorithm has a limited number of input parameters and is highly parallel.

Developmental expression of neuronal nitric oxide synthase in P/Q-type voltage-gated calcium ion channel mutant mice, leaner and tottering.

Nitric oxide (NO) is a diffusible messenger molecule produced primarily by neuronal nitric oxide synthase (nNOS) in the central nervous system. Both nNOS expression and NO production are regulated by calcium ions. Leaner and tottering mice carry a mutation in the pore forming subunit (alpha1A) of P/Q-type voltage-gated calcium ion channels, which decreases calcium ion current through the affected channels and disrupts calcium homeostasis. We have previously shown that nNOS expression is altered in adult leaner and tottering cerebella. In addition, leaner and tottering mice have been shown to have abnormal cerebellar granule cell-Purkinje cell synapses and leaner cerebellar granule cells undergo abnormal apoptosis during early postnatal development. Since NO production has been linked to several developmental roles including neuronal cell death, synaptogenesis and neuronal cell survival, our objective was to evaluate the expression of nNOS in developing leaner and tottering cerebella. Our results show that nNOS is differentially expressed in leaner and tottering cerebella compared to wild type cerebella and compared to each other. In whole cerebella, Western blotting revealed a significant increase in nNOS expression at postnatal day 12 in tottering but not leaner or wild type cerebella. At the cellular level the NADPH-diaphorase marker for nNOS revealed a significant increase in nNOS expression in basket cell interneurons in both mutant mice. nNOS expression in granule cells in the internal granule cell layer in tottering mice was increased at P12, while granule cells of leaner mice exhibited decreased nNOS expression at P20. The changes in nNOS expression at P12 did not correlate with a change in overall NO production, but rather maintained wild type NO concentrations. These findings suggest that changes in nNOS expression in the leaner and tottering cerebella are compensatory in nature with NO most likely functioning as a calcium-regulated neuroprotective/neurotrophic factor in postnatal cerebellar development.

Functional compensation by other voltage-gated Ca2+ channels in mouse basal forebrain neurons with Ca(V)2.1 mutations.

Tottering (tg/tg) and leaner (tg(la)/tg(la)) mutant mice exhibit distinct mutations in the gene encoding the voltage-activated Ca(2+) channel alpha(1A) subunit (CACNA1A), the pore-forming subunit of the Ca(V)2.1 (P/Q type) Ca(2+) channels. These mice exhibit absence seizures and deficiencies in motor control and other functions. Previous work in cerebellar Purkinje neurons has shown that these mutations cause dramatic reductions in calcium channel function. Because Purkinje cell somata primarily express the Ca(V)2.1 channels, the general decrease in Ca(V)2.1 channel function is observed as a profound decrease in whole-cell current. In contrast to Purkinje cells, basal forebrain (BF) neurons express all of the Ca(2+) channel alpha(1) subunits, with Ca(V)2.1 contributing approximately 30% to the whole-cell current in wild-type (+/+) mice. Here, we show that whole-cell Ba(2+) current densities in BF neurons are not reduced in the mutant genotypes despite a reduction in the Ca(V)2.1 contribution. By blocking the different Ca(2+) channel subtypes with specific pharmacological agents, we found a significant increase in the proportion of Ca(V)1 Ca(2+) current in mutant phenotypes. There was no change in tissue mRNA expression of calcium channel subtypes Ca(V)2.1, Ca(V)2.2, Ca(V)1.2, Ca(V)1.3, and Ca(V)2.3 in the tottering and leaner mutant mice. These results suggest that Ca(V)1 channels may functionally upregulate to compensate for reduced Ca(V)2.1 function in the mutants without an increase in Ca(v)1 message. Single-cell reverse transcription polymerase chain reaction (RT-PCR) experiments in a subset of sampled neurons revealed that approximately 90% of the cells could be considered cholinergic based on choline acetyltransferase (ChAT) mRNA expression.

Inherited tertiary hypothyroidism in Sprague-Dawley rats.

Thyroid hormones (THs) are important in the development and maturation of the central nervous system (CNS). The significant actions of THs during CNS development occur at the time when TH levels are lower than those in the mother and the hypothalamic-thyroid (HPT) axis is not fully functional. In the developing rat nervous system, primarily the cerebellum, the first three postnatal weeks represent a period of significant sensitivity to thyroid hormones. This study presents a spontaneous, inherited recessive hypothyroidism in Sprague-Dawley rats with devastating functional consequences to the development of the CNS. The clinical signs develop around 14 day's postnatal (dpn) and are characterized by ataxia, spasticity, weight loss and hypercholesterolemia. The afflicted rats died at 30 days due to severe neurological deficits. The deterioration affects the entire CNS and is characterized by progressive neuronal morphological and biochemical changes, demyelination and astrogliosis. The cerebellum, brain stem, neocortex, hippocampus and adrenal gland medulla appear to be most affected. Thyroid Stimulating Hormone (TSH), T3 and T4 levels were significantly lower in hypothyroid rats than control. Immunohistochemistry and RT-PCR demonstrated a reduction of Thyrotropin Releasing Hormone (TRH) in the hypothalamus of hypothyroid rats. The weight of both thyroid and pituitary glands were significantly less in hypothyroid rats than the corresponding normal littermate controls. Transmission electron microscopy demonstrates consistent postsynaptic dendritic, synaptic and spine alterative changes in the brain of hypothyroid rats. These data suggest that we discovered a tertiary form of inherited hypothyroidism involving the hypothalamus.

Assessment of mercury concentrations in mouse brain using different routes of administration and different tissue preparations.

ABSTRACT The objective of this study was to determine the best method for preparing brain tissue for mercury analysis from mice exposed to methylmercury either through subcutaneous (SC) injection or through ingestion. C57BL/6 J mice at postnatal day 29 were exposed to 0.0 or 5.0 mg/kg methylmercuric chloride (MMC) given SC or through food containing MMC. Eighteen mice received vehicle (sodium bicarbonate; SC) and 18 additional mice received 5.0 mg/kg MMC (SC). Whole brain tissue was prepared using one of four tissue preparation methods: rapid freezing, saline perfusion, 4% paraformaldehyde perfusion fixation, or 4% paraformaldehyde immersion fixation. Brains from vehicle-treated mice exhibited minimal levels of mercury (0.0007 to 0.0018 ppm) in all preparation methods. Mercury content in rapidly frozen control brains differed statistically from immersion-fixed control brain tissue. There was no significant difference in mercury content from mice given 5.0 mg/kg MMC (SC) in all preparation methods (0.2660 to 0.3650 ppm). Additional mice were divided into groups of six mice each: single oral dose of 5.0 mg/kg MMC; total oral dose of 5.0 mg/kg MMC divided into five doses; and vehicle only. Forebrain (0.3243 ppm) and hindbrain (0.1908 ppm) mercury content in MMC-treated mice given multiple doses was 10 times higher than in brain tissue from mice given a single 5.0 mg/kg dose. Brain mercury content following administration of 5.0 mg/kg MMC via the oral route (0.5354 ppm) differed statistically from the SC route (0.3430 ppm). In conclusion, different tissue preparation methods do not significantly affect brain mercury content, but route of administration and dosing regimen can influence total brain mercury content.

Fast submicrometer-scale imaging of whole zebrafish using the knife-edge scanning microscope.

Advances in high-resolution 3D microscopy have enabled the investigation of subcellular microstructures in biological specimen. For a full understanding of the organism's structure and function, it is mandatory to obtain data from the whole animal, not just parts of it. In this paper, we present our work with the Knife-Edge Scanning Microscope (KESM) for imaging a Nissl-stained whole zebrafish larva. KESM combines a diamond microtome and line-scan imaging for simultaneous sectioning and imaging in 3D. We show that using the KESM, a zebrafish, less than 3 mm long and diameter less than 500 µm, can be imaged within 1 hour at a resolution of 0.6 µm × 0.7 µm × 1.0 µm. We also present new results on using a vibrating microtome to improve sectioning and imaging robustness.

Neural cell proliferation and survival in the hippocampus of adult CaV 2.1 calcium ion channel mutant mice.

Tottering mutant mice carry a mutation in the pore-forming subunit (α1A) of CaV2.1 (P/Q-type) voltage-gated calcium ion (Ca2+) channels resulting in reduced neuronal Ca2+ current density. We assessed male tottering mice for spatial learning using the Morris water maze. Tottering mice performed worse than wild type mice, suggesting abnormal hippocampal function. Because Ca2+ influx via voltage-dependent Ca2+ channels regulates neuronal survival and function, we assessed hippocampus volume and cell density using hematoxylin and eosin stained serial sections. Adult hippocampal neurogenesis was assessed using 5-bromo-2'-deoxyuridine (BrdU) labeling with fluorescent immunohistochemistry (IHC) and proliferating cell nuclear antigen (PCNA) with diaminobenzidine IHC. We double-labeled neurons using fluorescence IHC with BrdU-neuronal nuclei (Neu-N) or double labeling of astrocytes using BrdU-glial fibrillary protein, respectively, to assess cell proliferation and survival. We assessed numbers of dying cells using fluoro-Jade histochemistry. Decreased hippocampal volume, increased dentate hilar and hippocampal CA1 cell densities were observed in tottering mice compared to wild type mice. Cell proliferation was increased in the hilus and CA2 region of tottering mice compared to wild type mice. Dendritic intersections in Sholl analysis were decreased for tottering mouse CA1 pyramidal neurons compared to wild type mice. The increased regional cell density coincides with increases in cell proliferation in similar, non-neurogenic areas of the hippocampus of tottering mice. Thus, hippocampal alterations observed in adult tottering mice appear to result from changes in neuronal morphology and proliferation in non-neurogenic areas of the hippocampus, and less through altered adult hippocampal neurogenesis or cell death.