Two functionally different glutamate receptors of the kainate subtype in embryonic rat mesencephalic cells

In vitro maturation of dopaminergic neurons derived from mouse embryonic stem cells: implications for transplantation

The obvious motor symptoms of Parkinson's disease result from a loss of dopaminergic neurons from the substantia nigra. Embryonic stem cell-derived neural progenitor or precursor cells, adult neurons and fetal midbrain tissue have all been used to replace dying dopaminergic neurons. Transplanted cell survival is compromised by factors relating to the new environment, for example; hypoxia, mechanical trauma and excitatory amino acid toxicity. In this study we investigate, using live-cell fluorescence Ca²⁺ and Cl⁻ imaging, the functional properties of catecholaminergic neurons as they mature. We also investigate whether GABA has the capacity to act as a neurotoxin early in the development of these neurons. From day 13 to day 21 of differentiation [Cl⁻]_i progressively dropped in tyrosine hydroxylase positive (TH⁺) neurons from 56.0 (95% confidence interval, 55.1, 56.9) mM to 6.9 (6.8, 7.1) mM. At days 13 and 15 TH⁺ neurons responded to GABA (30 µM) with reductions in intracellular Cl⁻ ([Cl⁻]_i); from day 21 the majority of neurons responded to GABA (30 µM) with elevations of [Cl⁻]_i. As [Cl⁻]_i reduced, the ability of GABA (30 µM) to elevate intracellular Ca²⁺ ([Ca²⁺]_i) did also. At day 13 of differentiation a three hour exposure to GABA (30 µM) or L-glutamate (30 µM) increased the number of midbrain dopaminergic (TH⁺ and Pitx3⁺) neurons labeled with the membrane-impermeable nuclear dye TOPRO-3. By day 23 cultures were resistant to the effects of both GABA and L-glutamate. We believe that neuronal susceptibility to amino acid excitotoxicity is dependent upon neuronal maturity, and this should be considered when isolating cells for transplantation studies.

The release of excitatory amino acids, dopamine, and potassium following transplantation of embryonic mesencephalic dopaminergic grafts to the rat striatum, and their effects on dopaminergic neuronal survival in vitro

A major limitation to the effectiveness of grafts of fetal ventral mesencephalic tissue for parkinsonism is that about 90-95% of grafted dopaminergic neurones die. In rats, many of the cells are dead within 1 day and most cell death is complete within 1 week. Our previous results suggest that a major cause of this cell death is the release of toxins from the injured CNS tissue surrounding the graft, and that many of these toxins have dissipated within 1 h of inserting the grafting cannula. In the present experiments we measured the change over time in the concentration of several potential toxins around an acutely implanted grafting cannula. We also measured the additional effect of injecting suspensions of embryonic mesencephalon, latex microspheres, or vehicle on these concentrations. Measurements of glutamate, aspartate, and dopamine by microdialysis showed elevated levels during the first 20-60 min, which then declined to baseline. In the first 20 min glutamate levels were 10.7 times, aspartate levels 5 times, and dopamine levels 24.3 times baseline. Potassium levels increased to a peak of 33 +/- 10.6 mM 4-5 min after cannula insertion, returning to baseline of <5 mM by 30 min. Injection of cell suspension, latex microspheres, or vehicle had no significant effect on these levels. We then assayed the effect of high concentrations of glutamate, aspartate, dopamine, and potassium on dopaminergic neuronal survival in E14 ventral mesencephalic cultures. In monolayer cultures only dopamine at 200 microM showed toxicity. In three-dimensional cultures only the combination of raised potassium, dopamine, glutamate, and aspartate together decreased dopaminergic neuronal survival. We conclude that toxins other than the ones measured are the main cause of dopaminergic cell death after transplantation, or the effects of the toxins measured are enhanced by anoxia and metabolic challenges affecting newly inserted grafts.

Ontogeny of kainate receptor gene expression in the developing rat midbrain and striatum

Kainate (KA) receptors are a family of ionotropic glutamate receptors, which mediate the excitatory synaptic transmission in various areas of the mammalian CNS. We have studied the expression pattern of the genes encoding for KA receptor subunits (Glur5-1, Glur5-2, Glur6, Glur7, KA1 and KA2) in rat prenatal (E), postnatal and adult ventral mesencephalon (MES) and striatum (STR) and in fetal midbrain primary cultures. Each receptor subunit shows a unique area- and temporal-expression pattern. In MES the onset of both Glur5 subunits is delayed when compared to the other subunits. In addition, most of the transcripts for KA subunits gradually increase during embryonic development and show a slight decrease during the first postnatal week. Differently, Glur6 and KA2 mRNAs show a sharp increase at E14.5 and decrease thereafter, reaching the lowest levels during late embryonic and postnatal development. In the STR, the gene expression of all KA subunit mRNAs is higher during embryonic development than after birth, except KA1 transcripts, that show a peak at P5. In embryonic MES primary cultures, Glur5-2, Glur6 and KA2 mRNAs are higher at the beginning of the culture when compared to older cultures, while the other subunit mRNAs do not show significant variation throughout the days in vitro. Thus, all the KA receptor subunit transcripts appear independently regulated during MES and STR development, probably contributing to the establishment of the fine tuning of the excitatory circuits reciprocally established between these CNS areas.

Dual video microscopic imaging of membrane potential and cytosolic calcium of immunoidentified embryonic rat cortical cells

Membrane potential (MP) and cytosolic Ca2+ (Ca2+(c)) constitute important components involved in the physiological regulation of a myriad of cell functions in eukaryotic organisms. In particular, during development of the central nervous system, both properties are thought to be important in the regulation of cell cycle, cell migration, cell differentiation, cell-cell communication, and naturally occurring cell death. However, obtaining insight into the precise relationship between these two parameters of cell function is relatively limited either by technical difficulties inherent in using electrical recordings of membrane properties in conjunction with optical imaging of single cells or by employing optical imaging of either one or another property alone. Here, we describe in detail a novel strategy to record changes in both MP and Ca2+(c) from many intact single cells in a noninvasive manner using digital video microscopy. This method involves double-loading the cells with voltage- and calcium-sensitive fluorescent indicator dyes, green oxonol, and fura-2, which can be sequentially excited with a mercury arc lamp filtered at appropriate wavelengths and their resulting emissions can be captured with an intensified charged-coupled device camera at 1-s intervals. As an example of the utility of dual-recording strategy, we present data on a distinct functional expression of excitable membrane and cytoplasmic calcium properties in proliferating and differentiating embryonic rat cerebral cortical cells.

Postnatal development of calretinin- and parvalbumin-positive interneurons in the rat neostriatum: an immunohistochemical study

On the basis of cytochemical and morphologic differences, two classes of gamma-aminobutyric acidergic (GABAergic) interneurons expressing calcium-binding proteins have been identified in the striatum of adult animals: neurons expressing either parvalbumin (PV) or calretinin (CR). The function of these calcium-binding proteins is not clear, however, they are associated with distinct classes of inhibitory interneurons within the adult neostriatum. By using immunocytochemical techniques, we analyzed the postnatal maturation and the spatiotemporal distribution of PV- and CR-positive neurons in the rat neostriatum compared with a third class of interneurons characterized by the expression of the acetylcholine-synthesizing enzyme, choline acetyltransferase (ChAT). PV-positive cells appeared initially on postnatal day 9 in the lateral region of the striatum. During postnatal weeks 2 and 3, the numbers of PV-positive neurons increased, and this cell population spread progressively in a lateromedial direction. In contrast, CR-expressing neurons were present at birth. During the first few days after birth, the number of CR-immunoreactive cells increased, reaching a peak on postnatal day 5 before declining during the following 2 weeks. A mediolateral gradient was evident temporarily. ChAT-containing neurons were detectable at birth in the lateral striatum. During postnatal weeks 1 and 2, the neurons matured along a lateral-to-medial gradient. The results indicate that the maturation of striatal interneurons is regulated differentially during postnatal development, resulting in a distinct spatiotemporal genesis of phenotypes. The sequential expression of CR and PV suggests a stage-dependent development of subsets of inhibitory interneurons and, hence, the stage-dependent maturation of functionally distinct inhibitory circuits within the neostriatum.

Neurotransmitters, KCl and antioxidants rescue striatal neurons from apoptotic cell death in culture

Striatal neurons grown in low density culture on serum-free media and in the absence of glia die within 3 days of plating. In this study, we sought to determine the mechanism of cell death (e.g., apoptosis) and whether trophic influences, such as, growth factors, neurotransmitters, antioxidants or KCl-mediated depolarization could improve their survival. We found that striatal neurons grown in this manner die via apoptosis unless treated with one of several different rescuing agents. One way to prevent the death of most striatal neurons was continual treatment with 5-20 microM dopamine (DA) or other monoamines. Although the survival effect of DA was mimicked by the specific D1 receptor agonist, SKF38393, no D1 or D2 receptor antagonists blocked the effect. As with DA, chronic depolarization with KCl (12-39 mM) or treatment with antioxidants, such as the vitamin E analog, Trolox (10-10-500 microM), or the hormone, melatonin (10-10-500 microM) also rescued striatal neurons from impending cell death. Surprisingly, growth factors, such as BDNF, bFGF, GDNF, NGF, NT3 and EGF, demonstrated no ability to rescue striatal neurons in this model, suggesting that death was not solely caused by the absence of essential trophic factors. We conclude that a variety of agents, but not growth factors, can prevent the demise of striatal neurons, presumably by neutralizing damage at one or more steps in the death cascade.

Buoyant density gradient fractionation and flow cytometric analysis of embryonic rat cortical neurons and progenitor cells

We have used the property of natural cell buoyant density to selectively fractionate embryonic rat neocortical cells into 20 subpopulations ranging in phenotype from proliferatively active progenitors to terminally postmitotic neurons. Immunocytochemical and cell cycle analysis of the cellular fractions with flow cytometry revealed an inverse relationship between cell buoyant density and neuronal differentiation. The most buoyant fractions contained predominantly terminally postmitotic, tubulin betaIII-positive, tetanus toxin-positive, and nestin-negative differentiating neurons, while immature, bromodeoxyuridine-positive and nestin-positive proliferating cells were more prevalent in less buoyant fractions. Double loading of isolated cells with voltage- and Ca2+-sensitive fluorescent indicator dyes followed by simultaneous recordings of membrane potential and cytoplasmic [Ca2+] ([Ca2+]c]) using flow cytometry revealed that >50% of the least buoyant cells produced functional responses to veratridine, a Na+ channel agonist, and muscimol, a GABA(A) receptor agonist, but <10% responded to kainic acid, an agonist of a subset of glutamate receptors. As cells became more buoyant the percentage of cells that depolarized and produced a rise in [Ca2+]c to each ligand increased, particularly in response to kainic acid. Short-term culture of select fractions revealed a marked enrichment for cells with morphologies and epitopes characteristic of neuronal and progenitor cell subpopulations. The results show that embryonic cortical cells exhibit a range of naturally occurring buoyant densities that can be used to expeditiously fractionate cortical cells according to their pre- or postmitotic status, thus providing ready access for cellular and molecular studies of proliferation and differentiation.

Potentiometric study of resting potential, contributing K+ channels and the onset of Na+ channel excitability in embryonic rat cortical cells

Resting membrane potential (RMP), K+ channel contribution to RMP and the development of excitability were investigated in the entire population of acutely dissociated embryonic (E) rat cortical cells over E11-22 using a voltage-sensitive fluorescent indicator dye and flow cytometry. During the period of intense proliferation (E11-13), two cell subpopulations with distinct estimated RMPs were recorded: one polarized at approximately -70 mV and the other relatively less-polarized at approximately -40 mV. Ca2+o was critical in sustaining the RMP of the majority of less-polarized cells, while the well-polarized cells were characterized by membrane potentials exhibiting a approximately Nernstian relationship between RMP and [K+]o. Analysis of these two subpopulations revealed that > 80% of less-polarized cells were proliferative, while > 90% of well-polarized cells were postmitotic. Throughout embryonic development, the disappearance of Ca2+o-sensitive, less-polarized cells correlated with the disappearance of the proliferating population, while the appearance of the K+o-sensitive, well-polarized population correlated with the appearance of terminally postmitotic neurons, immuno-identified as BrdU-, tetanus toxin+ cells. Differentiating neurons were estimated to contain increased K+i relative to less-polarized cells, coinciding with the developmental expression of Cs+/Ba2+-sensitive and Ca2+-dependent K+ channels. Both K+ channels contributed to the RMP of well-polarized cells, which became more negative toward the end of neurogenesis. Depolarizing effects of veratridine, first observed at E11, progressively changed from Ca2+o-dependent and tetrodotoxin-insensitive to Na+o-dependent and tetrodotoxin-sensitive response by E18. The results reveal a dynamic development of RMP, contributing K+ channels and voltage-dependent Na+ channels in the developing cortex as it transforms from proliferative to primarily differentiating tissue.

Modulation of neuronal mitochondrial membrane potential by the NMDA receptor: role of arachidonic acid

Activation of NMDA receptors in dissociated cerebellar granule cells reduced mitochondrial membrane potential (MMP), as measured by rhodamine 123 fluorescence in a flow cytometer. This effect was inhibited by several NMDA-receptor antagonists with the following rank order of potency: MK-801 > PCP > TCP > dextrorphan > dichlorokynurenic acid > D-AP5 > dextromethorphan. Neither spermine nor arcaine modified the NMDA-induced reduction in MMP, whereas ifenprodil and eliprodil inhibited this response in the micromolar range. The mechanism responsible for the alteration of MMP mediated by NMDA was studied. Mepacrine and dibucaine prevented the MMP reduction induced by NMDA, as did W13 (calmodulin antagonist). In contrast, this effect was not blocked by cyclooxygenase or lipooxygenase inhibitors, H7 (a protein kinase C inhibitor) or nitroarginine (nitric oxide synthase inhibitor). These data suggest a direct interaction between NMDA-receptor activation and arachidonic acid formation, and indicate that NMDA receptor-mediated effect on MMP could involve arachidonic acid.

Effect of glutamate receptor ligands on mitochondrial membrane potential in rat dissociated cerebellar cells

The effect of three different glutamate receptor ligands on mitochondrial membrane potential has been studied in rat pup dissociated cerebellar cells by measuring rhodamine 123 fluorescence. L-glutamate, NMDA (N-methyl-D-aspartate) and kainate (from 10(-8) to 10(-3) M) decreased in a concentration-dependent manner the mitochondrial membrane potential with EC50 values of 6.7 +/- 1.7, 3.8 +/- 0.5, and 37.4 +/- 14 microM, respectively. Dizocilpine ((+)MK 801) was able to inhibit the NMDA- and L-glutamate-induced decrease in rhodamine 123 fluorescence, while kainate-induced fluorescence-decreases were unaffected. However, 6-cyano-7-nitroquinoxaline-2, 3-dione (CNQX) totally prevented the effect of kainate on mitochondrial membrane potential, but failed to block the L-glutamate effect. It is concluded that, in our cell preparation, L-glutamate exerts its action mainly through NMDA-subtype receptors, and that Ca2+ and Na+ entry through ionotropic glutamate receptors could be responsible for an impairment of mitochondrial membrane potential.

Slow fluorescent indicators of membrane potential: a survey of different approaches to probe response analysis

Basic tenets related to the use of three main classes of potentiometric redistribution fluorescent dyes (carbocyanines, oxonols, and rhodamines) are discussed in detail. They include the structure/function relationship, formation of nonfluorescent (H-type) and fluorescent (J-type) dimers and higher aggregates, probe partitioning between membranes and medium and binding to membranes and intracellular components (with attendant changes in absorption and emission spectra, fluorescence quantum yield and lifetime). The crucial importance of suitable probe-to-cell concentration ratio and selection of optimum monitored fluorescence wavelength is illustrated in schematic diagrams and possible artifacts or puzzling results stemming from faulty experimental protocol are pointed out. Special attention is paid to procedures used for probe-response calibration (potential clamping by potassium in the presence of valinomycin, use of gramicidin D in combination with N-methylglucamine, activation of Ca-dependent K-channels by A23187, the null-point technique). Among other problems treated are dye toxicity, interaction with mitochondria and other organelles, and possible effects of intracellular pH and the quantity of cytosolic proteins and/or RNA on probe response. Individual techniques using redistribution dyes (fluorescence measurements in cuvettes, flow cytometry and microfluorimetry of individual cells including fluorescence confocal microscopy) are discussed in terms of reliability, limitations and drawbacks, and selection of suitable probes. Up-to-date examples of application of slow dyes illustrate the broad range of problems in which these probes can be used.

Cocaine selectively alters neurotransmitter receptor mRNAs in mouse embryos

Alterations in gene expression due to in utero cocaine exposure may adversely affect nervous system development. The present study examined whether or not cocaine administration to pregnant mice alters embryonic mRNA levels for several developmentally-regulated genes. Antisense RNA amplification was performed using RNA from LM/Bc embryos at gestational days 9.5 and 10.5 after three days of cocaine treatment. This technique highlights simultaneous changes that occur in the expression of many genes after a teratogenic insult. Significant changes occurred in the expression pattern on only four genes from a total of 42 candidate cDNAs. These included increases in the relative levels of the alpha and beta 1 subunits of the GABAA receptor without concurrent changes in the non-NMDA glutamate receptor subunits. The results support the hypothesis that in utero cocaine exposure leads to specific changes in gene expression that may ultimately contribute to developmental abnormalities.

Embryonic hypothalamic expression of functional glutamate receptors

Glutamate can play a number of roles in the developing brain, including modulation of gene expression, cell motility, neurite growth and neuronal survival, all critical for the final organization and function of the mature brain. These functions are dependent on the early expression of glutamate receptors and on glutamate release in developing neurons. This subject has received little attention in the hypothalamus, despite glutamate's critical role as an excitatory transmitter in hypothalamic control of circadian rhythms, endocrine secretion, temperature regulation, and autonomic control. A total of 10,922 rat hypothalamic neurons were studied with digital Ca2+ imaging with the ratiometric dye fura-2 to examine their responses to glutamate receptor agonists and antagonists during embryonic development and maturation in vitro. Functional glutamate receptors were found very early in development (embryonic day 15-E15) with both Ca2+ imaging and with patch clamp recording. This is a time when the hypothalamus is beginning to undergo neurogenesis. Ca2+ responses from N-methyl-D-aspartate receptors developed later than those from non-N-methyl-D-aspartate ionotropic receptors that responded to kainate and alpha-amino-3-hydroxy-5-methyl-4-isoxazoleproprionate. The responses of immature E15 cells after one day in vitro were compared with more mature cells after six days in vitro to examine the response to repeated 3 min applications of 100 microM kainate (n = 108). Immature cells showed similar Ca2+ rises (+232nM Ca2+) with each kainate stimulation. In contrast, more mature cells showed an initial Ca2+ rise of 307 nM, with the second rise only to 147 nM above the initial baseline. Immature cells more quickly returned to their pre-kainate baseline than did older cells. The expression of metabotropic glutamate receptors was studied with the selective agonist trans-1-amino-cyclopentyl-1,3-dicarboxylic acid and with glutamate stimulation in the absence of extracellular Ca2+ and presence of 1 mM EGTA. After five days in vitro. E16 astrocytes showed a greater response than did neurons to conditions that would activate the metabotropic glutamate receptor. A dramatic increase in the percentage of cells that responded to N-methyl-D-aspartate was found after only a few days in culture. Only a small number of E15 cells studied on the day of culture (4% of 694 cells) showed a response to 100 microM N-methyl-D-aspartate. Thirty-eight percent of 120 E18 cells cultured for one day in vitro showed an N-methyl-D-aspartate response.(ABSTRACT TRUNCATED AT 400 WORDS)

Purification of cell populations from human fetal brain using flow cytometric techniques

We recently established primary cultures from dissociated second trimester human fetal brains using a novel spin seeding method and characterized cellular populations with distinct phenotypes in these cultures. Here, we report that these neural cultures can be dissociated to single-cell suspensions, sorted by size using flow cytometry and re-seeded to yield cultures selectively enriched for the neuronal and glial cell populations. Sorted neurons were highly homogeneous, viable and extended processes, by one day after re-seeding. These neurons expressed immunoreactivity for neurofilament protein, retained their GABAergic phenotype and were electrically excitable. Re-seeded astrocytes proliferated in culture and expressed glial fibrillary acidic protein. We describe the conditions required for the flow cytometric sorting and tissue culture assays as well as the morphological, immunocytochemical and electrophysiological characteristics of the sorted neuronal population.