G. David Lange

Transplanted bone marrow generates new neurons in human brains.

Adult bone marrow stem cells seem to differentiate into muscle, skin, liver, lung, and neuronal cells in rodents and have been shown to regenerate myocardium, hepatocytes, and skin and gastrointestinal epithelium in humans. Because we have demonstrated previously that transplanted bone marrow cells can enter the brain of mice and differentiate into neurons there, we decided to examine postmortem brain samples from females who had received bone marrow transplants from male donors. The underlying diseases of the patients were lymphocytic leukemia and genetic deficiency of the immune system, and they survived between 1 and 9 months after transplant. We used a combination of immunocytochemistry (utilizing neuron-specific antibodies) and fluorescent in situ hybridization histochemistry to search for Y chromosome-positive cells. In all four patients studied we found cells containing Y chromosomes in several brain regions. Most of them were nonneuronal (endothelial cells and cells in the white matter), but neurons were certainly labeled, especially in the hippocampus and cerebral cortex. The youngest patient (2 years old), who also lived the longest time after transplantation, had the greatest number of donor-derived neurons (7 in 10,000). The distribution of the labeled cells was not homogeneous. There were clusters of Y-positive cells, suggesting that single progenitor cells underwent clonal expansion and differentiation. We conclude that adult human bone marrow cells can enter the brain and generate neurons just as rodent cells do. Perhaps this phenomenon could be exploited to prevent the development or progression of neurodegenerative diseases or to repair tissue damaged by infarction or trauma.

Embryonic and early postnatal hippocampal cells respond to nanomolar concentrations of muscimol

Embryonic and early postnatal tissue taken from rat hippocampi were papain digested in order to obtain cell suspensions suitable for analysis in a fluorescence-activated cell sorter (FACS). Cell suspensions consisted of two major peaks of forward-angle light scatter (FALS). FACS analysis showed that the population which stained intensely with the vital dye Acridine orange (AO) scattered significant levels of light (high FALS) and amounted to 85% of the total events collected in embryonic cell suspensions and 65% in postnatal (PN) samples. Two minor populations were weakly stained with AO and scattered little light. Oxonol, a voltage-sensitive indicator dye, was used to detect membrane polarization changes. The AO and oxonol staining patterns were very similar. All the events exposed to media containing 50 mM KCl were depolarized (increase in intensity of oxonol fluorescence). The depolarizing effect of veratridine, a sodium channel activator, was more pronounced in the high FALS subpopulation. In embryonic hippocampal cell suspensions nanomolar concentrations of GABAA agonists depolarized the high FALS subpopulation in a dose-dependent manner. This effect was prevented by preincubation with bicuculline or picrotoxin. In hippocampal cell suspensions obtained from 5-7-day-old rat pups (PN5-7), GABAA agonists depolarized one cell subpopulation and hyperpolarized another. Our results indicate that physiological responses can be resolved in subpopulations of hippocampal cell suspensions by FACS analysis. This technique seems to be a sensitive assay to measure physiological responses (changes in membrane potential) as a parameter of receptor expression. GABAA agonists induced pure depolarizing responses in embryonic and early postnatal hippocampus when active neurogenesis is taking place. The response become hyperpolarizing-depolarizing ones after inhibitory synapses appear.

Allosteric regulation and spatial distribution of kainate receptors bound to ancillary proteins.

A diverse range of accessory proteins regulates the behaviour of most ligand‐ and voltage‐gated ion channels. For glutamate receptor 6 (GluR6) kainate receptors, two unrelated proteins, concanavalin‐A (Con‐A) and postsynaptic density protein 95 (PSD‐95), bind to extra‐ and intracellular domains, respectively, but are reported to exert similar effects on GluR6 desensitization behaviour. We have tested the hypothesis that distinct allosteric binding sites control GluR6 receptors via a common transduction pathway. Rapid agonist application to excised patches revealed that neither Con‐A nor PSD‐95 affect the onset of desensitization. The rate of desensitization elicited by 10 mm l‐glutamate was similar in control (τfast= 5.5 ± 0.4 ms), Con‐A‐treated patches (τfast= 6.1 ± 0.5 ms) and patches containing PSD‐95 and GluR6 receptors (τfast= 4.7 ± 0.6 ms). Likewise, the time course of recovery from GluR6 desensitization was similar in both control and Con‐A conditions, whereas PSD‐95 accelerated recovery almost twofold. Peak and steady‐state (SS) dose‐response relationships to glutamate were unchanged by lectin treatment (e.g. control, EC50(SS)= 31 ± 28 μmvs Con‐A, EC50(SS)= 45 ± 9 μm, n= 6), suggesting that Con‐A does not convert non‐conducting channels with high agonist affinity into an open conformation. Instead, we demonstrate that the effects of Con‐A on macroscopic responses reflect a shift in the relative contribution of different open states of the channel. In contrast, the effect of PSD‐95 on recovery behaviour suggests that the association between kainate receptors and cytoskeletal proteins regulates signalling at glutamatergic synapses. Our results show that Con‐A and PSD‐95 regulate kainate receptors via distinct allosteric mechanisms targeting selective molecular steps in the transduction pathway.

Electrical and chemical excitability appear one week before birth in the embryonic rat spinal cord

Embryonic rat spinal cord cells were acutely dissociated with the enzyme papain, stained with a voltage-sensitive oxonol dye and incubated with various pharmacological agents. Changes in the fluorescence intensity and, by inference, membrane potential of the cells were analyzed in a flow cytometer. Veratridine caused depolarization of the cells in a TTX-sensitive manner from as early as embryonic day 13. Depolarizing responses to muscimol and kainate appeared slightly later, at embryonic days 14 and 15, and were blocked by the antagonists bicuculline and CNQX, respectively. Responses to veratridine and kainate did not occur in sodium-free medium. The emergence of these excitable membrane properties coincides with postmitotic differentiation and synaptic development in the embryonic spinal cord.

GABAergic cells and signals appear together in the early post-mitotic period of telencephalic and striatal development

Single cell suspensions derived from embryonic telencephala taken from embryos of gestational day 13 (E13) as well as rat striatal tissue from E14, 15 and 17 were prepared by tissue digestion with papain. Cell suspensions were analyzed by flow cytometry or plated onto poly-D-lysine-coated culture dishes for either nuclear staining or immunocytochemistry. Experiments on functional Na+ channels and GABAA receptor expression were carried out using a fluorescence-activated cell sorter (FACS) and a negatively charged fluorescent indicator dye (oxonol). FACS analysis of embryonic cell suspensions at E13-17 consistently revealed one major subpopulation accounting for 85-90% of the events and one minor subpopulation (10-15% of the total). When sorted, the major subpopulation consisted of phase-bright cells of 5-7 microns diameter some of which had neurites. The minor population consisted of phase-dark cells and resealed membranes of 0.5-4 microns diameter as well as debris. Almost all the cells obtained in the high FALS (forward-angle light scatter) subpopulation at E17 expressed 200-kDa neurofilament and tetanus toxin antigens while the small diameter cells seldom expressed tetanus toxin and particles never did. A small number of GABA-containing neurons were detected in the telencephalon at E13 (3%) and in the developing striatum at E14 (6%). All of the GABA-containing neurons expressed neurofilament. In the embryonic rat striatum, nanomolar concentrations of muscimol (GABAA agonist) induced depolarizing responses. A small number of cells in the high FALS subpopulation were responsive to muscimol starting at embryonic day 14, and the number of responsive cells increased at E15.(ABSTRACT TRUNCATED AT 250 WORDS)

Reciprocal expression of cell-cell coupling and voltage-dependent Na current during embryogenesis of rat telencephalon

Using whole-cell patch-clamp techniques in situ (whole-tissue and tissue slices), we have studied two aspects of rat telencephalic cell development during the period of embryogenesis starting at E12. The first aspect was related to junctional coupling as revealed by low input resistance, intercellular dye spread and pharmacologic blockade. Coupling appeared to decrease with time, both in extent and occurrence. The second aspect dealt with cell excitability as revealed by voltage-dependent Na current (INa) expression. Immature action potentials and their underlying INaS were present in a small proportion of E12 cells. These currents were blocked 36% and 78% by 10(-7) M and 10(-6) M tetrodotoxin (TTX), respectively. From then onward, INaS got larger and more prevalent while no obvious changes in kinetics were observed. At E21, INaS were abolished by 10(-7) M TTX and channel density apparently was sufficient to support overshooting yet still immature action potentials.

Flow cytometric analysis of membrane potential in embryonic rat spinal cord cells

Flow cytometric analysis of membrane potential in suspensions of embryonic rat spinal cord cells was carried out in a fluorescence-activated cell sorter (FACS) using anionic voltage-sensitive, fluorescent dyes (oxonols). The FACS or flow cytometer is an analytical instrument that measures optical properties of large cell populations at a single cell level of resolution. The incorporation of oxonol allows relative measurements of membrane potential, since the partition of oxonol within the plasmalemma is directly related to the degree of cell depolarization. Incubation of cells in elevated K+ concentrations or with the Na+ channel agonist batrachotoxin (BTX) changed the fluorescence intensity distribution pattern of the live-cell population; these changes were consistent with the depolarizing effects of these manipulations. Fluorescence shifts were either undetectable or minimal in the dead-cell population. The BTX-induced shift was blocked by tetrodotoxin (TTX) and was reversed in Na+-free medium, indicating embryonic expression of functional Na+ channels. Fluorescence microscopy of sorted cells showed that live cells typically exhibited circumferential ring-like patterns, whose intensities were enhanced under depolarizing conditions. The results show that flow cytometry combined with oxonol dyes can be used to measure the relative membrane potential of large numbers of individual central nervous system cells. The analysis of the changes in the distributions of these membrane potentials can be used to reveal the development of functional ion conductance mechanisms.