Embryonic Rat Hippocampal Neurons Research Articles

Amyloid β peptide is not a candidate for the neurotrophic activities released from chromaffin cells

We have previously shown that chromaffin cells, the neuron-like cells of the adrenal medulla, release proteins, which promote in vitro survival of a large number of peripheral and central nervous system neurons (cf. Lachmund, A., Gehrke, D., Krieglstein, K. and Unsicker, K, Trophic factors from chromaffin granules promote survival of peripheral and central nervous system neurons. Neuroscience, 1994, 62, 361–370). In a search for the active molecules we are testing compounds that are known to be synthesized and released by chromaffin cells. Amyloid precursor protein (βAPP) is one of these factors (Bieger, S., Klafki, H.-W. and Unsicker, K., Synthesis and release of the β-amyloid precursor protein by bovine chromaffin cells. Neurosci. Lett., 1993, 162, 173–175). In the present study we have investigated the possibility that amyloid β peptide (AβP) generated from βAPP may have survival supporting effects for neurons from embryonic chick ciliary (CG) and dorsal root ganglia (DRG). Embryonic rat hippocampal neurons, for which promotion of short-term survival by AβP has been reported (Whitson, J. S., Selkoe, D. J. and Cotman, C. W., Amyloid β protein enhances the survival of hippocampal neurons in vitro. Science, 1989, 243, 1488–1490), were employed as a reference. AβP fragment 1–40, administered over a wide range of concentrations (1.5–100 μmg\\ml) did not promote the survival of CG and DRG neurons isolated from embryonic day (E) 8 chick embryos. The peptide also failed to toxically suppress survival of these neuron populations in the presence of survival promoting factors. In confirmation of previous reports, the 1–40 peptide, in comparison to the reverse 40–1 peptide, significantly enhanced survival of hippocampal neurons. These results suggest that AβP is not a trophic factor for the peripheral neuron populations tested and, most likely, not a neurotrophic component among the neurotrophic factors released by chromaffin cells.

Embryonic rat hippocampal neurons and GABAA receptor subunit-transfected non-neuronal cells release GABA tonically.

We used patch-clamp recording techniques to investigate the contribution of GABA to baseline membrane properties in cultured embryonic rat hippocampal neurons. Almost all of the neurons recorded with Cl--filled pipettes and clamped at negative potentials exhibited baselines that were noticeably noisy, with microscopic fluctuations superimposed on the macroscopic holding current. A gentle steam of saline applied to the neuronal surface rapidly and reversibly reduced the baseline current and fluctuations, both of which were completely eliminated by bicuculline. Fluctuation analysis showed that the variance in the baseline current signal was exponentially distributed with estimated kinetics comparable to those activated by submicromolar concentrations of exogenous GABA. The kinetics of Cl- channels activated by endogenous GABA displayed a potential sensitivity comparable to those activated by exogenous GABA. Non-neuronal cells stably transfected with alpha1 and gamma2 GABAA receptor subunits exhibited little baseline current variance when recorded with Cl--filled pipettes. Addition of micromolar GABA to the extracellular saline or to the pipette solution induced a saline- and bicuculline-sensitive baseline current signal comparable to that recorded in hippocampal neurons. Thus, both intra- and extracellular sources of GABA could contribute to the baseline properties recorded in these cultured neurons.

Developmental expression of GABA(A) receptor subunit mRNAs in individual hippocampal neurons in vitro and in vivo.

The GABA(A) receptor is a heterooligomeric protein complex composed of multiple receptor subunits. Developmental changes in the pattern of expression of 11 GABA(A) receptor subunits in individual rat embryonic hippocampal neurons on days 1-21 in culture and acutely dissociated hippocampal neurons from postnatal day (PND) 5 rat pups were investigated using the technique of single-cell mRNA amplification. We demonstrate that multiple GABA(A) receptor subunits are expressed within individual hippocampal neurons, with most cells simultaneously expressing alpha1, alpha2, alpha5, beta1, and gamma2 mRNAs. Further, relative expression of several GABA(A) receptor subunit mRNAs changes significantly in embryonic hippocampal neurons during in vitro development, with the relative abundance (compared with beta-actin) of alpha1, alpha5, and gamma2 mRNAs increasing 2.3-, 2.7-, and 3.8-fold, respectively, from days 1 to 14, and beta1 increasing 5-fold from days 1 to 21. In situ hybridization with antisense digoxigenin-labeled alpha1, beta1, and gamma2 RNA probes demonstrates a similar increase in expression of subunit mRNAs as embryonic hippocampal neurons mature in vitro. Relative abundances of alpha1, beta1, and gamma2 subunit mRNAs in acutely dissociated PND 5 hippocampal neurons are also significantly greater than in embryonic day 17 neurons on day 1 in vitro and exceed the peak values seen in cultured neurons on days 14-21, suggesting that GABA(A) receptor subunit mRNA expression within individual hippocampal neurons follows a similar, if somewhat delayed, developmental pattern in vitro compared with in vivo. These findings suggest that embryonic hippocampal neuronal culture provides a useful model in which to study the developmental regulation of GABA(A) receptor expression and that developmental changes in GABA(A) receptor subunit expression may underlie some of the differences in functional properties of GABA(A) receptors in neonatal and mature hippocampal neurons.

Electrophysiology of embryonic, adult and aged rat hippocampal neurons in serum-free culture

Methods were recently developed for culturing neurons from adult rat hippocampus using the serum-free medium Neurobasal with B27 supplement. To determine whether adult cultured neurons have normal electrical properties, we studied cultures from rats of three age groups: (1) embryonic; (2) 10–11 months old and (3) 35–36 months old. Neurons had a polarized morphology with a large branching apical dendrite and small basal dendrites. Mean resting potentials were similar in the three age groups. All neurons had nonlinear current-voltage relationships, indicating the presence of voltage-sensitive ion channels. Most neurons had a voltage-sensitive inward current followed by a sustained voltage-sensitive outward current. Tetrodotoxin blocked the inward current, which is likely to be a sodium current. The sustained outward current, which is likely to be a potassium current, reversed at −71 mV. Most neurons exhibited anomalous rectification. Calcium currents were present in both embryonic and adult neurons. Embryonic neurons would sometimes fire multiple action potentials but adult neurons fired only single action potentials. Our results indicate that both embryonic and adult cultured neurons retain a clearly neuronal electrophysiological phenotype in Neurobasal/B27 serum-free medium.

Secreted amyloid precursor protein α selectively suppresses N-methyl-d-aspartate currents in hippocampal neurons: involvement of cyclic GMP

The secreted form of β-amyloid precursor protein (sAPPα) is released from neurons in an activity-dependent manner; data suggest sAPPα may play roles in regulating neuronal excitability, plasticity, and survival. In cultured hippocampal neurons sAPPα can suppress elevation of [Ca2+]i induced by glutamate and can protect neurons against excitotoxicity. We now report whole-cell patch-clamp data from studies of cultured embryonic rat hippocampal neurons which demonstrate sAPPα selectively suppresses N-methyl-d-aspartate currents without affecting currents induced by α-amino-3-hydroxy-5-methylisoxazole-4-propionate or kainate. sAPPα suppressed N-methyl-d-aspartate current rapidly and reversibly at concentrations of 0.01–1nM. Suppression of N-methyl-d-aspartate current by sAPPα is apparently mediated by cyclic guanosine monophosphate because 8-bromo-cyclic guanosine monophosphate suppressed N-methyl-d-aspartate current in a manner similar to sAPPα, and two different inhibitors of cyclic guanosine monophosphate-dependent protein kinase prevented sAPPα-induced suppression of N-methyl-d-aspartate current. In addition, okadaic acid prevented suppression of N-methyl-d-aspartate-induced current suggesting the involvement of a protein phosphatase in modulation of N-methyl-d-aspartate current by sAPPα.These data identify a mechanism whereby sAPPα can modulate cellular responses to glutamate, and suggest important roles for sAPPα in the various physiological and pathophysiological processes in which N-methyl-d-aspartate receptors participate.

Contact guidance of CNS neurites on grooved quartz: influence of groove dimensions, neuronal age and cell type.

We used an in vitro system that eliminates competing guidance cues found in embryos to determine whether substratum topography alone provides important neurite guidance information. Dissociated embryonic Xenopus spinal cord neurons and rat hippocampal neurons were grown on quartz etched with a series of parallel grooves. Xenopus neurites grew parallel to grooves as shallow as 14 nm and as narrow as 1 microm. Hippocampal neurites grew parallel to deep, wide grooves but perpendicular to shallow, narrow ones. Grooved substrata determined the sites at which neurites emerged from somas: Xenopus neurites sprouted from regions parallel to grooves but presumptive axons on rat hippocampal neurons emerged perpendicular to grooves and presumptive dendrites emerged parallel to them. Neurites grew faster in the favored direction of orientation and turned through large angles to align on grooves. The frequency of perpendicular alignment of hippocampal neurites depended on the age of the embryos from which neurons were isolated, suggesting that contact guidance is regulated in development. Collectively, the data indicate that substratum topography is a potent morphogenetic factor for developing CNS neurons and suggest that in addition to a role in pathfinding the geometry of the embryo assists in establishing neuronal polarity. In the companion paper (A. M. Rajnicek and C. D. McCaig (1997) J. Cell Sci. 110, 2915-2924) we explore the cellular mechanism for contact guidance of growth cones.

Astrocytes regulate amino acid receptor current densities in embryonic rat hippocampal neurons

Embryonic rat hippocampal neurons were cultured in a serum-free defined medium (MEM/N3) either directly on poly-D-lysine (PDL) or on a confluent monolayer of postnatal cortical astrocytes, C6 glioma cells, or Rat2 fibroblasts. Neurons on PDL were grown in MEM/N3 or in MEM/N3 conditioned for 24 h by astrocytes or C6 cells. Membrane capacitance (Cm) and γ-aminobutyric acid (GABA)-, glycine-, kainate-, and N-methyl-D-aspartate (NMDA)-induced currents were quantified using whole-cell patch-clamp recordings. Cm as well as the amplitude and the density of these currents in neurons cultured on astrocytes were significantly greater than those in neurons grown on PDL after 24 and 48 h. C6 cells mimicked astrocytes in promoting Cm and GABA-, glycine-, and NMDA-evoked, but not kainate-evoked, currents. Cm and currents in neurons grown on Rat2 cells were comparable to those in neurons on PDL. Astrocytes maintained in culture for 3 months were noticeably less effective than freshly prepared ones just grown to confluence. Suppression of spontaneous cytoplasmic Ca2+ (Cac2+) elevations in astrocytes by 1,2-bis(2-aminophenoxy) ehane-N, N, N, N-tetraacetic acid acetoxymethyl ester (BAPTA-AM) loaded intracellularly blocked the observed modulatory effects. Medium conditioned by either astrocytes or C6 cells mimicked the effects of direct coculture of neurons on these cells in promoting Cm and amino acid-evoked currents. Inclusion of antagonists at GABA and glutamate receptors in coculture experiments blocked the observed effects. Thus, diffusible substances synthesized and/or secreted by astrocytes in a Cac2+-dependent manner can regulate neuronal growth and aminoacid receptor function, and these effects may involve neuronal GABA and glutamate receptors. © 1997 John Wiley & Sons, Inc. J Neurobiol 33: 848–864, 1997

Astrocytes regulate amino acid receptor current densities in embryonic rat hippocampal neurons

Embryonic rat hippocampal neurons were cultured in a serum-free defined medium (MEM/N3) either directly on poly-D-lysine (PDL) or on a confluent monolayer of postnatal cortical astrocytes, C6 glioma cells, or Rat2 fibroblasts. Neurons on PDL were grown in MEM/N3 or in MEM/N3 conditioned for 24 h by astrocytes or C6 cells. Membrane capacitance (Cm) and gamma-aminobutyric acid (GABA)-, glycine-, kainate-, and N-methyl-D-aspartate (NMDA)-induced currents were quantified using whole-cell patch-clamp recordings. Cm as well as the amplitude and the density of these currents in neurons cultured on astrocytes were significantly greater than those in neurons grown on PDL after 24 and 48 h. C6 cells mimicked astrocytes in promoting Cm and GABA-, glycine-, and NMDA-evoked, but not kainate-evoked, currents. Cm and currents in neurons grown on Rat2 cells were comparable to those in neurons on PDL. Astrocytes maintained in culture for 3 months were noticeably less effective than freshly prepared ones just grown to confluence. Suppression of spontaneous cytoplasmic Ca2+ (Ca[c]2+) elevations in astrocytes by 1,2-bis(2-aminophenoxy) ehane-N, N, N, N-tetraacetic acid acetoxymethyl ester (BAPTA-AM) loaded intracellularly blocked the observed modulatory effects. Medium conditioned by either astrocytes or C6 cells mimicked the effects of direct coculture of neurons on these cells in promoting Cm and amino acid-evoked currents. Inclusion of antagonists at GABA and glutamate receptors in coculture experiments blocked the observed effects. Thus, diffusible substances synthesized and/ or secreted by astrocytes in a Ca(c)2+-dependent manner can regulate neuronal growth and aminoacid receptor function, and these effects may involve neuronal GABA and glutamate receptors.

Effects of acidosis on the distribution of processing of the beta-amyloid precursor protein in cultured hippocampal neurons.

Reported increases in brain lactate production in Alzheimer disease led us to test the hypothesis that lactic acid acidosis alters the processing of the beta-amyloid precursor protein, beta PP, in neurons. To test this proposition, embryonic rat hippocampal neurons were first cultures for 4 d in serum-free B27/neurobasal medium. Lactic acid at 0.5 and 1 mg/mL (pH 7.1 and, 6.9, respectively) caused a dose-dependent increase in cellular beta-amyloid immunoreactivity detected with antibody 4G8. Acidosis did not affect secretion of beta PP or its derivatives into the medium. The cytoplasmic production of beta PP was slightly reduced by acidosis without a differential effect on maturation or proteolytic processing. In the substrate-bound material, which was insoluble in nonionic detergent, acidosis caused increases in an N-terminal 75-kDa band, a C-terminal 72-kDa band, and potentially amyloidogenic bands at 35 and 38 kDa. Processing to the 4-kDa amyloid beta protein was not observed in these early pure rat neuronal cultures. These results suggest that mild acidosis id sufficient to alter neuronal processing to the amyloid precursor protein into potentially amyloidogenic forms and increase certain beta PP fragments bound to the substrate. If a similar process occurs in the presence of other cell types in the aging brain, acidosis may stimulate an extracellular deposition of amyloid and contribute to the pathogenesis of Alzheimer disease.

Protein Targeting in Neurons and Endocrine Cells

The functional polarity of axons is reflected in the polarized distribution of a number of proteins, both membrane and cytoskeletal. Targeting to each domain of the neuron may require a specific signal; alternatively, targeting to only one domain may be specific, while localization to the other may occur by default. In addition to sorting to the proper domain, proteins in neurons must also be sorted to the correct subcellular organelle. For example, synaptic vesicle proteins synthesized in the endoplasmic reticulum (ER) and posttranslationally modified in the Golgi must first be targeted to the axon and then to the nerve terminal. A number of studies suggest that synaptic vesicle proteins are finally assembled into mature synaptic vesicles at the synapse; consequently, synaptic vesicle proteins may contain multiple targeting signals to reach their final destination. Research has been going on investigating the molecular basis for targeting of membrane proteins in neurons and to synaptic vesicles in two different systems. Using dissociated cultures of rat embryonic hippocampal neurons, the mechanism for sorting of proteins to dendrites or axons is examined. In the pheochromocytoma cell line PC12, the sequences that are necessary to target an exogenous protein to synaptic vesicles is being determined. It is found that the final stage of sorting to synaptic vesicles in neurons is mediated by similar processes as in PC12 cells. To determine this, chimeras are made between cDNAs encoding the synaptic vesicle protein SV2 and the glucose transporter GLUT1, in which the cytoplasmic loop between TM6 and TM7 is replaced by the cytoplasmic loop of SV2. The distribution of the chimeras have also been analyzied on sucrose gradients designed to separate large dense-core vesicles from endosomes, synaptic vesicles, and other membranes to determine if the same targeting information is used for both types of regulated secretory vesicles.

Myelin-associated glycoprotein inhibits neurite/axon growth and causes growth cone collapse.

We have previously shown that myelin-associated glycoprotein (MAG) inhibits neurite growth from a neuronal cell line. In this study we show that 60% of axonal growth cones of postnatal day 1 hippocampal neurons collapsed when they encountered polystyrene beads coated with recombinant MAG (rMAG). Such collapse was not observed with denatured rMAG. Neurite growth from rat embryonic hippocampal and neonatal cerebellar neurons was also inhibited about 80% on tissue culture substrates coated with rMAG. To investigate further the inhibitory activity of MAG in myelin, we purified myelin from MAG-deficient mice and separated octylglucoside extracts of myelin by diethylaminoethyl (DEAE) ion-exchange chromatography. Although there was no significant difference in neurite growth on myelin purified from MAG-/- and MAG+/+ mice, differences were observed in the fractionated material. The major inhibitory peak that is associated with MAG in normal mice was significantly reduced in MAG-deficient mice. These results suggest that although MAG contributes significantly to axon growth inhibition associated with myelin, its lack in MAG-deficient mice is masked by other non-MAG inhibitors. Axon regeneration in these mice was also examined after thoracic lesions of the corticospinal tracts. A very small number of anterogradely labeled axons extended up to 13.2 mm past the lesion in MAG-/- mice. Although there is some enhancement of axon generation, the poor growth after spinal cord injury in MAG-/- mice may be due to the presence of other non-MAG inhibitors. The in vitro studies, however, provide the first evidence that MAG modulates growth cone behavior and inhibits neurite growth by causing growth cone collapse.

Myelin‐associated glycoprotein inhibits neurite/axon growth and causes growth cone collapse

We have previously shown that myelin-associated glycoprotein (MAG) inhibits neurite growth from a neuronal cell line. In this study we show that 60% of axonal growth cones of postnatal day 1 hippocampal neurons collapsed when they encountered polystyrene beads coated with recombinant MAG (rMAG). Such collapse was not observed with denatured rMAG. Neurite growth from rat embryonic hippocampal and neonatal cerebellar neurons was also inhibited about 80% on tissue culture substrates coated with rMAG. To investigate further the inhibitory activity of MAG in myelin, we purified myelin from MAG-deficient mice and separated octylglucoside extracts of myelin by diethylaminoethyl (DEAE) ion-exchange chromatography. Although there was no significant difference in neurite growth on myelin purified from MAG-/- and MAG+/+ mice, differences were observed in the fractionated material. The major inhibitory peak that is associated with MAG in normal mice was significantly reduced in MAG-deficient mice. These results suggest that although MAG contributes significantly to axon growth inhibition associated with myelin, its lack in MAG-deficient mice is masked by other non-MAG inhibitors. Axon regeneration in these mice was also examined after thoracic lesions of the corticospinal tracts. A very small number of anterogradely labeled axons extended up to 13.2 mm past the lesion in MAG-/- mice. Although there is some enhancement of axon generation, the poor growth after spinal cord injury in MAG-/- mice may be due to the presence of other non-MAG inhibitors. The in vitro studies, however, provide the first evidence that MAG modulates growth cone behavior and inhibits neurite growth by causing growth cone collapse. © 1996 Wiley-Liss, Inc.

Short exposure to methylazoxymethanol causes a long‐term inhibition of axonal outgrowth from cultured embryonic rat hippocampal neurons

Methylazoxymethanol (MAM) is an alkylating agent that is used to induce microencephaly by killing mitotically active neuroblasts. We found that at later developmental times, MAM exposure can result in abnormal fiber growth in vivo. However, there have not been any previous studies on the effects of MAM on differentiating neurons. We examined the outcome of short exposure to MAM on postmitotic embryonic hippocampal cultures during the establishment of axonal polarity. At 0, 1, or 2 days in vitro (DIV), neurons were treated with 0.1 nM-1 μM MAM for 3 hr and then transferred to glial conditioned media. At 3 DIV, the cells were fixed and analyzed by immuno-fluorescent staining for neuron viability and differentiation. Control cells initiate several minor processes; one process elongates rapidly at about 1 DIV eventually becoming an axon, while extensive dendritic growth occurs after 3–4 DIV. Neurons treated with 1 μM MAM at 0 or 1 DIV showed a marked inhibition of neurite growth and withdrawal of axons without affecting cell viability. These cells continued to show minimal neurite outgrowth at 7 DIV, even when transferred to a glial coculture. In contrast, cells treated initially with MAM, after neuronal polarity is established at 2 DIV, showed no effect on axonal growth. To determine the effects of MAM on the neuronal cytoskeleton, we examined the in vitro assembly of brain microtubules in a one cycle assay. Exposure to MAM depleted the soluble pool of proteins, including microtubule-associated protein 1B (MAP1B) and MAP2, which are required for neurite outgrowth, through a nonspecific process. Under non-saturating conditions, there were no changes in the total amount of microtubules assembled or the coassembly of MAP1B and MAP2 in the presence of MAM. These results demonstrate that MAM can directly affect differentiating neurons, indicating that an early disruption of axonal outgrowth may have long-term effects. © 1996 Wiley-Liss, Inc.

Short exposure to methylazoxymethanol causes a long-term inhibition of axonal outgrowth from cultured embryonic rat hippocampal neurons.

Methylazoxymethanol (MAM) is an alkylating agent that is used to induce microencephaly by killing mitotically active neuroblasts. We found that at later developmental times, MAM exposure can result in abnormal fiber growth in vivo. However, there have not been any previous studies on the effects of MAM on differentiating neurons. We examined the outcome of short exposure to MAM on postmitotic embryonic hippocampal cultures during the establishment of axonal polarity. At 0, 1, or 2 days in vitro (DIV), neurons were treated with 0.1 nM-1 microM MAM for 3 hr and then transferred to glial conditioned media. At 3 DIV, the cells were fixed and analyzed by immunofluorescent staining for neuron viability and differentiation. Control cells initiate several minor processes; one process elongates rapidly at about 1 DIV eventually becoming an axon, while extensive dendritic growth occurs after 3-4 DIV. Neurons treated with 1 microM MAM at 0 or 1 DIV showed a marked inhibition of neurite growth and withdrawal of axons without affecting cell viability. These cells continued to show minimal neurite outgrowth at 7 DIV, even when transferred to a glial coculture. In contrast, cells treated initially with MAM, after neuronal polarity is established at 2 DIV, showed no effect on axonal growth. To determine the effects of MAM on the neuronal cytoskeleton, we examined the in vitro assembly of brain microtubules in a one cycle assay. Exposure to MAM depleted the soluble pool of proteins, including microtubule-associated protein 1B (MAP1B) and MAP2, which are required for neurite outgrowth, through a nonspecific process. Under non-saturating conditions, there were no changes in the total amount of microtubules assembled or the coassembly of MAP1B and MAP2 in the presence of MAM. These results demonstrate that MAM can directly affect differentiating neurons, indicating that an early disruption of axonal outgrowth may have long-term effects.

Neurotrophin-3 and brain-derived neurotrophic factor activate multiple signal transduction events but are not survival factors for hippocampal pyramidal neurons.

Expression of the neurotrophin-3 (NT-3) receptor (TrkC) and the effects of NT-3 on signal transduction were investigated in highly enriched populations of embryonic rat hippocampal pyramidal neurons grown in bilaminar cultures. PCR analysis revealed that the predominant trkC isoform is K1, which lacks an insert in the kinase domain. Polyclonal TrkC-specific antibodies stained > 90% of the neurons and revealed a single approximately 145-kDa protein in immunoblots of extracts from adult hippocampus and pyramidal neuron cultures. Addition of NT-3 (50 ng/ml) to these cultures induced the tyrosine phosphorylation of TrkC but not TrkB, as determined by anti-phosphotyrosine staining of immunoprecipitates; thus, all the effects of NT-3 are mediated through TrkC. NT-3 also increased the tyrosine phosphorylation of 42-, 44-, 49-, 55-, 95-, and 145-kDa proteins; the pattern induced by brain-derived neurotrophic factor (BDNF) was similar but not identical to that induced by NT-3, suggesting that subtle differences may exist in signaling by TrkB and TrkC receptors. Immunoprecipitation of p21ras from 32P-prelabeled cells showed that NT-3 increased the level of the GTP-bound form of the protein threefold over the control within 5 min. Mitogen-activated protein (MAP) kinase activity was maximally elevated by NT-3 within 2 min and then returned slowly toward baseline over the next 60 min. Tyrosine phosphorylation of phospholipase C-gamma increased rapidly after NT-3, suggesting that this enzyme becomes activated. Consistent with this, the neurotrophin rapidly increased protein kinase C activity as well as intracellular Ca2+ levels. The effects of both NT-3 and BDNF on Ca2+ levels were attenuated in Ca(2+)-free medium, suggesting that both neurotrophins increase Ca2+ flux across the plasma membrane as well as release from internal stores. NT-3 also increased c-Fos expression in > 80% of the cells; the effect peaked at 30 min and declined to baseline by 120 min. Despite the activation of ras-MAP kinase and phosphoinositide signaling pathways, neither NT-3 nor BDNF alone or in combination could sustain hippocampal pyramidal neurons deprived of glial support. We conclude that in this system NT-3 and BDNF do not appear to be acting as classical "neurotrophic" factors and that activation of the MAP kinase pathway is insufficient for the promotion of neuronal survival.

Thrombin causes cell spreading and redistribution of beta-amyloid immunoreactivity in cultured hippocampal neurons.

Culture of rat embryonic hippocampal neurons in serum-free B27/Neurobasal for 4 days enabled tests of the effect of added thrombin on differentiated cell morphology and processing of the amyloid precursor protein (APP). By fluorescence microscopy of neurons labeled with dil and by scanning electron microscopy, an increase in spreading of the neuron soma was clearly seen in cells treated with 1 microg/ml (27 nM) of thrombin for 24 h. This treatment also caused a dose-dependent increase in immunoreactive area/cell, detected with antibody 4G8 binding to the beta-amyloid region of APP. Thrombin treatment also produced a dose-dependent increase in immunoreactive brightness detected with the Alz-50 antibody. Thrombin did not affect viability or cause neurite retraction. The thrombin effect on 4G8 immunoreactivity required 24 h for full effect and could be blocked by the thrombin inhibitor antithrombin III or hirudin. A thrombin receptor appeared to be activated because a full immunoreactive response was observed by treatment of neurons with the thrombin receptor-activating peptide SFL-LRNPNNKYEPF. When cytoplasmic extracts were analyzed by western immunoblots or by pulse-chase radiolabeling, no thrombin-dependent changes in processing of 127- and 120-kDa bands were seen. Material migrating in the region of synthetic betaA4 was not found. Together, these results suggest that thrombin acts on neurons through a thrombin receptor to stimulate cell spreading and redistribution of APP without amyloidogenic changes. The adhesion responsible for this spreading could be important in altering synaptic connections in the brain.

Viable cultured neurons in ambient carbon dioxide and hibernation storage for a month.

Neurobasal is a bicarbonate-buffered medium optimized for the growth of embryonic rat hippocampal neurons at pH 7.3 in 5% CO2. Neurons die within hours in this or in other 26 mM bicarbonate buffers when transferred to ambient CO2 (0.2%). Death is associated with a rapid rise in medium pH to 8.1. A new CO2-independent modification of Neurobasal (Hibernate E), when supplemented with B27, can maintain neuron viability for at least 2 days in ambient CO2. This same medium can also be used to store viable brain tissue for up to a month with refrigeration. These advances should facilitate studies of neuron physiology outside the incubator as well as storing and transporting neuronal tissue.

Upregulation of GABAACurrent by Astrocytes in Cultured Embryonic Rat Hippocampal Neurons

Embryonic rat hippocampal neurons were cultured on poly-D-lysine (PDL) or a monolayer of postnatal cortical astrocytes to reveal putative changes in neuronal physiology that involve astrocyte-derived signals during the first 4 d of culture, GABA-induced Cl- current (IGABA) was quantified using outside-out and whole-cell patch-clamp recordings beginning at 30 min, when cells had become adherent. The amplitude and density (current normalized to membrane capacitance) of IGABA in neurons grown on astrocytes became statistically greater than that recorded in neurons grown on PDL after 2 hr in culture (HIC). Although the current density remained unchanged in neurons on astrocytes, that in neurons on PDL decreased and became statistically lower beginning after 2 HIC. The differences in amplitude and density of IGABA in the two groups of neurons were maintained during the 4 d experiment. The upregulation effect of astrocytes on neuronal IGABA required intimate contact between the neuronal cell body and underlying astrocytes. Suppression of spontaneous Cac2+ elevations in astrocytes by bis(2-aminophenoxy)ethane-N,N,N',N'-tetra-acetic acid that was loaded intracellularly decreased their modulatory effects on IGABA. IGABA in all cells was blocked completely by bicuculline and exhibited virtually identical affinity constants, Hill coefficients, and potentiation by diazepam in the two groups. Outside-out patch recordings revealed identical unitary properties of IGABA in the two groups. More channels per unit of membrane area could explain the astrocyte enhancement of IGABA. The results reveal that cortical astrocytes potentiate IGABA in hippocampal neurons in a contact-dependent manner via a mechanism involving astrocyte Cac2+ elevation.

Three distinct neuronal phenotypes exist in embryonic rat hippocampal neurons cultured in basic fibroblast growth factor

The possibility that neurons cultured in basic fibroblast growth factor (bFGF) are heterogeneous raises concerns about their subsequent use in gene transfection and transplantation studies. We have examined the fate of embryonic hippocampal neurons in bFGF culture, and now conclude that these cells are not only heterogeneous, but possess neurons of various stages of development. Morphological and immunocytochemical analysis reveal three distinct developmental classes of neurons are present in extended bFGF culture. This triparticle classification is supported by electrophysiological analysis, which reveals that upon depolarization, neurons with precursor and juvenile neuron morphologies are unable to fire action potentials. The third class of neurons, which resemble age-matched polarizes neurons in standard serum culture, fired multiple action potentials indicative of a mature phenotype. These data show neurons at multiple developmental stages co-exist in bFGF culture, and provide an experimental basis for their classification.

Deposits of Aβ fibrils are not toxic to cortical and hippocampal neurons in vitro

Amyloid β peptide (Aβ), which is deposited as insoluble fibrils in senile plaques, is thought to play a role in the neuropathology of Alzheimer's disease. We have developed a model in which rat embryonic cerebral cortical or hippocampal neurons are seeded onto culture dishes containing deposits of substrate-bound, fibrillar Aβ. The neurons attached rapidly to A β 1–40 and A β 1–42 substrates and extended long, branching neurites. Quantitative assessment demonstrated that survival of neurons on the Aβ matrices was equivalent to or better than on control substrates of poly L-lysine or poly L-ornithine. In contrast, preparations of Aβ fibrils added directly to the culture medium caused neuronal death as previously reported in the literature. These results reveal that the response of neurons to deposited A β 1–40 and A β 1–42 is substantially different from that observed with suspensions of the amyloid peptides, with the former serving as growth-promoting substrates for cortical and hippocampal neurons. This may thus imply that fibrillar Aβ of senile plaques is not sufficient by itself to cause the plaque-associated neuronal degeneration characteristic of AD.