Changes in microtubule polarity orientation during the development of hippocampal neurons in culture

Microtubules in the dendrites of cultured hippocampal neurons are of nonuniform polarity orientation. About half of the microtubules have their plus ends oriented distal to the cell body, and the other half have their minus ends distal; in contrast, microtubules in the axon are of uniform polarity orientation, all having their plus ends distal (Baas, P.W., J.S. Deitch, M. M. Black, and G. A. Banker. 1988. Proc. Natl. Acad. Sci. USA. 85:8335-8339). Here we describe the developmental changes that give rise to the distinct microtubule patterns of axons and dendrites. Cultured hippocampal neurons initially extend several short processes, any one of which can apparently become the axon (Dotti, C. G., and G. A. Banker. 1987. Nature [Lond.]. 330:477-479). A few days after the axon has begun its rapid growth, the remaining processes differentiate into dendrites (Dotti, C. G., C. A. Sullivan, and G. A. Banker. 1988. J. Neurosci. 8:1454-1468). The polarity orientation of the microtubules in all of the initial processes is uniform, with plus ends distal to the cell body, even through most of these processes will become dendrites. This uniform microtubule polarity orientation is maintained in the axon at all stages of its growth. The polarity orientation of the microtubules in the other processes remains uniform until they begin to grow and acquire the morphological characteristics of dendrites. It is during this period that microtubules with minus ends distal to the cell body first appear in these processes. The proportion of minus end-distal microtubules gradually increases until, by 7 d in culture, about equal numbers of dendritic microtubules are oriented in each direction. Thus, the establishment of regional differences in microtubule polarity orientation occurs after the initial polarization of the neuron and is temporally correlated with the differentiation of the dendrites.     

The establishment of polarity by hippocampal neurons: the relationship between the stage of a cell's development in situ and its subsequent development in culture

Neurons removed from the embryonic hippocampus and placed into culture develop structurally and functionally distinct axonal and dendritic processes. The central issue addressed in this study concerns the extent to which the sequence of events which results in the differentiation of neurites by hippocampal neurons in culture is influenced by the cell's state of development in situ. [3H]thymidine was administered to pregnant rats either on Embryonic Day 15 (E15) or on E18.5 to label hippocampal neurons at known stages of their development. All fetuses were sacrificed on E19. Some of the fetal brains were sectioned and examined by autoradiography to determine the location of labeled cells in the hippocampus. The remaining brains were used to prepare hippocampal cell cultures. Neurons labeled at E18.5 remained confined to the ventricular zone at E19. Those labeled at E15 had completed their migration to the cortical plate. Other data suggest that the former cells had not yet initiated process outgrowth, while the latter cells had begun to elaborate both axons and dendrites. When introduced into culture, both populations of cells developed axons and dendrites and both compartmentalized MAP2 to the dendritic domain. Moreover, despite marked differences in their developmental state at the time of introduction into culture, both underwent the same sequence of developmental events leading to axonal and dendritic development. In a few cases cells that incorporated [3H]thymidine in situ at E18.5 apparently underwent mitosis in culture. These neurons also developed axons and dendrites appropriately. These results indicate that hippocampal neurons become polarized in culture, even if they have never developed axons or dendrites in situ, and do so as efficiently as cells that have become polarized before being placed into culture. Moreover, they indicate that the same sequence of events leading to the establishment of polarity occurs for hippocampal neurons with different developmental histories prior to culturing.     

The effects of triethyl lead on the development of hippocampal neurons in culture

Triethyl lead is the major metabolite of tetraethyl lead, which is used in industrial processes and as an antiknock additive to gasoline. We tested the hypothesis that low levels of triethyl lead (0.1 nmol/L to 5mol/L) interfere with the normal development of cultured E18 rat hippocampal neurons, possibly through increases in intracellular free calcium ion concentration, [Ca²⁺]_in. The study assessed survival and differentiation using morphometric analysis of individual neurons. We also looked at short-term (up to 3.75-h) changes in intracellular calcium using the calcium-sensitive dye fura-2. Survival of neurons was significantly reduced at 5 mol/L, and overall production of neurites was reduced at 2 mol/L. The length of axons and the number of axons and dendrites were reduced at 1 mol/L. Neurite branching was inhibited at 10 nmol/L for dendrites and 100 nmol/L for axons. Increases in intracellular calcium were observed during a 3.75-h exposure of newly plated neurons to 5 mol/L triethyl lead. These increases were prevented by BAPTA-AM; which clamps [Ca²⁺]_in at about 100 nmol/L. Culturing neurons with BAPTA-AM and 5 mol/L triethyl lead did not reverse the effects of triethyl lead, suggesting that elevation of [Ca²⁺]_in is not responsible for decreases in survival and neurite production. Triethyl lead has been shown to disrupt cytoskeletal elements, particularly neurofilaments, at very low levels, suggesting a possible mechanism for its inhibition of neurite branching at nanomolar concentrations.Abbreviations BAPTA-AM 1,2-bis(2-aminophenoxy)ethane-N,N,N,N-tetraacetic acid acetoxymethyl ester - [Ca²⁺]_in intracellular free calcium ion concentration - DMSO dimethyl sulfoxide - E18 embryonic day 18 - FBS fetal bovine serum - fura-2AM fura-2 acetoxymethyl ester - HBSS Hanks' Balanced Salt Solution - MEM Eagle's Minimum Essential Medium     

Myelination of rodent hippocampal neurons in culture

Axons of various hippocampal neurons are myelinated mainly postnatally, which is important for the proper function of neural circuits. Demyelination in the hippocampus has been observed in patients with multiple sclerosis, Alzheimer's disease or temporal lobe epilepsy. However, very little is known about the mechanisms and exact functions of the interaction between the myelin-making oligodendrocytes and the axons within the hippocampus. This is mainly attributable to the lack of a system suitable for molecular studies. We recently established a new myelin coculture from embryonic day (E) 18 rat embryos consisting of hippocampal neurons and oligodendrocytes, with which we identified a novel intra-axonal signaling pathway regulating the juxtaparanodal clustering of Kv1.2 channels. Here we describe the detailed protocol for this new coculture. It takes about 5 weeks to set up and use the system. This coculture is particularly useful for studying myelin-mediated regulation of ion channel trafficking and for understanding how neuronal excitability and synaptic transmission are regulated by myelination.     

Effect of ethanol on the interaction of hippocampal neurons in tissue culture

Background unit activity and that evoked by ethanol of neighbouring neurones in hippocampal tissue culture of 9-19 div was studied by means of cross-correlational analysis. The results obtained point to a possibility of existence of complex neuronal networks consolidated by functional synaptic connections, even in such a simple model system as neuronal tissue culture. Excitatory interactions of neighbouring neurones were more sensitive to ethanol than the inhibitory ones. The effect of ethanol administration consisted mainly in a weakening of correlational connections. Such changes are supposed to be the basis for different coordination disorders in the work of brain structures observed during chronic alcoholic intoxication.     

Levetiracetam protects hippocampal neurons in culture against hypoxia-induced injury

Many experimental studies indicate that some antiepileptic drugs possess neuroprotective properties in varied models of neuronal injury. Levetiracetam is a second-generation antiepileptic drug with a novel mechanism of action. In the present study, we evaluated the putative neuroprotective effect of levetiracetam on primary hippocampal cultures at seven day in vitro. Cell death was induced by incubation of neural cultures in hypoxic conditions over 24 hours. Neuronal injury was assessed by morphometric investigation of death/total ratio of neurons in light microscopy using Trypan blue staining and by evaluation of lactate dehydrogenase (LDH) release in the culture medium. Our results indicate that pre-conditioning of hippocampal cultures with high concentrations of levetiracetam (100 μM and 300 μM) protects neurons against hypoxia-induced death. Two-fold higher number of neurons remained viable as compared to control cultures without drug. Lack of neuroprotective action of the drug on hippocampal neural cultures was observed, when a low concentration (10 μM) of levetiracetam was used.     

An immunofluorescence study of neurofilament protein expression by developing hippocampal neurons in tissue culture

We have studied the development of intermediate filament proteins in the neurons found in hippocampal cell cultures using single and double label immunofluorescence with both monoclonal and polyclonal antibodies. Neurons in these cultures are known to differentiate in a manner similar to their counterparts in situ: in particular they develop axonal and dendritic processes which differ from each other in form, in ultrastructure, and in synaptic polarity. During the first days in culture, developing neurons could not be stained with antibodies against any of the neurofilament proteins, although many cells reacted with anti-vimentin. Later in the first week, antibody staining revealed clearly filamentous staining for the L (68 000 daltons) and the M (145 000 daltons) neurofilament subunits, though M reactivity was much stronger at this earlier stage of development. Some neurofilament positive profiles in many cells could also be stained with vimentin, though the vimentin immunoreactivity became progressively less pronounced during further development, and disappeared after about two weeks in culture. Also at about two weeks in vitro we noted the first appearance of neurofilament H protein (200 000 daltons) immunoreactivity, which was localized to a subset of long neurites which could be identified on morphological grounds as axons. These processes lacked staining for microtubule associated protein 2 (MAP2), a dendritic marker. They tended to be close to islands of glial cells, suggesting that H induction may require complex neuron-glial interactions. These results are consistent with the suggestion that H protein immunoreactivity is a marker for axonal outgrowth. In addition to obvious filamentous staining, we were able to localize neurofilament antigens to an interesting class of small ring-like structures, found increasingly frequently as the cultures aged. We also present evidence that tyrosinated alpha-tubulin is present both within dendrites and axons of neurons in these cultures.     

Differential subcellular localization of particular mRNAs in hippocampal neurons in culture

In situ hybridization was used to assess the subcellular distribution of mRNAs encoding several important neuronal proteins in hippocampal neurons in culture. mRNA encoding GAP-43, a protein that is largely excluded from dendrites, was restricted to nerve cell bodies, as were mRNAs encoding neurofilament-68 and beta-tubulin, which are prominent constituents of dendrites and of axons. In contrast, mRNA encoding MAP-2, a protein that is selectively distributed in dendrites and cell bodies, was present in both dendrites and cell bodies. These results demonstrate that different mRNAs are differentially distributed within individual hippocampal neurons. Taken together with previous findings from other laboratories, our results suggest that only a limited set of mRNAs are available for local translation within dendrites.     

大鼠海马神经元膜离子通道随培养时间变化的特点

目的和方法:采用膜片钳全细胞记录技术观察新生大鼠海马神经元体外分散培养过程中,基本离子通道和膜参数随培养天数延长而变化的规律.结果:在7 d,14 d和21 d时电压依赖性钠电流(Voltage-dependent Na cur-rent,ⅠNa)和延迟整流性钾电流(Delayed rectifier K current,Ⅰk)的幅度无显著性差异.电压依赖性钙电流(Voltage-dependent Ca2 current,ⅠCa)和ⅠCa密度则持续增大,进一步研究表明,L型钙通道(L-type voltage-dependent Ca2 channel,L-VDCC)的增加是其主要原因.NMDA诱发电流随培养时间延长而明显增加.结论:钙通道和NMDA受体所介导的Ca2 内流是神经元易感于衰老和死亡的重要机制之一.     

Balanced GABAergic and glutamatergic synapse development in hippocampal neurons

Coordinated development of excitatory and inhibitory synapses is crucial for normal function of neuronal circuits. Using homo- and heterochronic cultures of hippocampal neurons, we compared the formation of glutamatergic and GABAergic synapses at different stages and asked whether the age of dendrites affects their ability to accept new glutamatergic and GABAergic synapses. Neurons were transfected with either CFP-actin as a dendritic marker or GFP-synaptophysin as a presynaptic marker. We found that GFP-synaptophysin clusters formed on CFP-actin-labeled dendrites at similar density regardless of pre- and postsynaptic cell type or the age of dendrites (0-2 weeks) upon co-culturing. Therefore, the age of mature dendrites does not affect their ability to accept new synapses. Because GABAergic transmission switches from depolarizing to hyperpolarizing during 1-2 weeks in these cultures, our observations also suggest that this developmental switch does not alter the formation of GABAergic synapses.     

Nanoparticle targeting to neurons in a rat hippocampal slice culture model

We have previously shown that CdSe/ZnS core/shell luminescent semiconductor nanocrystals or QDs (quantum dots) coated with PEG [poly(ethylene glycol)]-appended DHLA (dihydrolipoic acid) can bind AcWG(Pal)VKIKKP₉GGH₆ (Palm1) through the histidine residues. The coating on the QD provides colloidal stability and this peptide complex uniquely allows the QDs to be taken up by cultured cells and readily exit the endosome into the soma. We now show that use of a polyampholyte coating [in which the neutral PEG is replaced by the negatively heterocharged CL4 (compact ligand)], results in the specific targeting of the palmitoylated peptide to neurons in mature rat hippocampal slice cultures. There was no noticeable uptake by astrocytes, oligodendrocytes or microglia (identified by immunocytochemistry), demonstrating neuronal specificity to the overall negatively charged CL4 coating. In addition, EM (electron microscopy) images confirm the endosomal egress ability of the Palm1 peptide by showing a much more disperse cytosolic distribution of the CL4 QDs conjugated to Palm1 compared with CL4 QDs alone. This suggests a novel and robust way of delivering neurotherapeutics to neurons.     

Some observations on polarity and regeneration in Enteromorpha

The regeneration of two types of Enteromorpha has been investigated. Small tubular sections cut from the thallus develop rhizoids along the basal cut edge and papillae from the apical cut edge. The capacity for regeneration is greatest in segments from the middle and base of the thallus and least in apical sections. Regeneration in various liquid culture media at different light intensities and temperatures and on solid agar media has been tested. The addition of growth substances and extracts from Enteromorpha thalli always stimulate regeneration but in no way alter the polarity. The results are compared with previous conflicting accounts of regeneration of Enteromorpha.     

Differential effects of NgCAM and N-cadherin on the development of axons and dendrites by cultured hippocampal neurons

A fundamental step in neuronal development is the acquisition of a polarized form, with distinct axons and dendrites. Although the ability to develop a polarized form appears to be largely an intrinsic property of neurons, it can be influenced by environmental cues. For example, in cell cultures substrate and diffusible factors can enhance and orient axonal development. In this study we examine the effects of growth on each of two cell adhesion molecules (CAMs), NgCAM and N-cadherin, on the development of polarity by cultured hippocampal neurons. We find that although the same pattern of development occurs on control substrates and the CAMs, the CAMs greatly accelerate the rate and extent of development of axons—axons form sooner and grow longer on the CAMs than on the control substrate. In contrast, the CAMs have opposite effects on dendritic development—N-cadherin enhances, but NgCAM reduces dendritic growth compared to control. These results provide further evidence that the development of polarity is largely determined by a cell-autonomous program, but that environmental cues can independently regulate axonal and dendritic growth.     

Polyamines and the development of isolated neurons in cell culture

The possible role of polyamines in the development of isolated neuroblasts from the cerebral cortex of embryonic chick brain was studied by means of three enzyme activated irreversible inhibitors of ornithine decarboxylase. -Difluoromethylornithine (MDL 71782) showed no effects on development at doses which depleted dramatically neuronal putrescine and spermidine levels. In contrast, the two other inhibitors, (E)--(fluoromethy)dehydroputrescine (MDL 72197) and 6-heptyne-2,5-diamine (MDL 72175) blocked the formation of neuronal outgrowths completely at 100 M and higher concentrations. Their effects on neuronal polyamines differed at this concentration considerably. The growth inhibitory effect of the ornithine decarboxylase inhibitors was in all cases reversible: cells which were grown after 3 days of exposure to the drugs in normal medium produced neuronal networks. The presence of putrescine at 10M concentration in the culture medium prevented the growth inhibitory effect of 100 M concentrations of the drugs. This concentration of putrescine was not only capable of preventing, but also of reversing growth inhibition by the ornithine decarboxylase inhibitors. Although the cellular polyamine levels were not correlated with the morphological development of chick embryo cortical neurons, the present study leaves no doubt that putrescine plays an essential role in neuronal differentiation.     

Seizure-like activity and cellular damage in rat hippocampal neurons in cell culture

Neurons dissociated from the hippocampal formations of neonatal rats were grown in medium containing kynurenic acid (a glutamate receptor antagonist) and elevated Mg2+. Such chronically blocked neurons, when first exposed to medium without blockers (after 0.5-5.0 months), generated intense seizure-like activity. This consisted of bursts of synchronous electrical responses that resembled paroxysmal depolarization shifts and sustained depolarizations that, in some neurons, nearly abolished the resting potential. Sustained depolarizations were usually reversed by timely application of kynurenate or 2-amino-5-phosphonovalerate, indicating that continuous activation of glutamate receptors was required for their maintenance. Prolonged periods of intense seizure-like activity usually killed most neurons in the culture. This system allows seizure-related cellular mechanisms to be studied in long-term cell culture.     

Transient increase in the high affinity [3H]-L-glutamate uptake activity during in vitro development of hippocampal neurons in culture

The glial GLAST and GLT-1 glutamate transporters are transiently expressed in hippocampal neurons as shown by immunocytochemistry (Plachez et al., 2000. J. Neurosci. Res., 59, 587-593). In order to test if this transient expression is associated to a transient glutamate uptake activity, [3H]-glutamate uptake was studied during the in vitro development of embryonic hippocampal neurons cultured in a defined (serum free) medium. In these cultures, the ratio of the number of glial cells to the number of neurons increased from 1.7 to 11.3% during the first 10 days of culture, while 77% of the neurons died. The number of neurons then remains stable up to 23 days of culture. The initial glutamate uptake velocity at 20 and 200 microM [3H]-glutamate usually increased about five times between 1 and 10 days in vitro (DIV). Interestingly, at 2 microM [3H]-glutamate, the uptake initial velocity showed a biphasic pattern, with a transient peak between 1 and 6 DIV, the maximum being reached at 2 DIV and a delayed regular increase from 8 to 23 DIV. The concentration-dependent curves were best fitted with two saturable sites high and low affinities, at both 2 and 10 DIV. To pharmacologically characterize the transient increased glutamate uptake activity, four uptake inhibitors, L-threo-3-hydroxy-aspartic acid (THA), L-trans-pyrrolidine-2,4-dicarboxylic acid (L-trans-2,4-PDC), dihydrokainate (DHK), and DL-threo-beta-benzyloxyaspartate (TBOA) were tested. THA, L-trans-2,4-PDC and DL-TBOA inhibited glutamate uptake both at 2 and 10 DIV, while the GLT-1 selective uptake inhibitor DHK neither strongly affected the uptake at 2, nor at 10 DIV. These data indicated that, besides the regular increase in the glial-dependent glutamate uptake activity, a transient high-affinity, DHK insensitive, glutamate transport activity in hippocampal neurons in culture is present. This latter activity could potentially be related to the transient expression of the glial GLAST transporter in neurons.     

Altered distribution of mitochondria impairs calcium homeostasis in rat hippocampal neurons in culture

The specificity of Ca2+ signals is conferred in part by limiting changes in cytosolic Ca2+ to subcellular domains. Mitochondria play a major role in regulating Ca2+ in neurons and may participate in its spatial localization. We examined the effects of changes in the distribution of mitochondria on NMDA-induced Ca2+ increases. Hippocampal cultures were treated with the microtubule-destabilizing agent vinblastine, which caused the mitochondria to aggregate and migrate towards one side of the neuron. This treatment did not appear to decrease the energy status of mitochondria, as indicated by a normal membrane potential and pH gradient across the inner membrane. Moreover, electron microscopy showed that vinblastine treatment altered the distribution but not the ultrastructure of mitochondria. NMDA (200 micro m, 1 min) evoked a greater increase in cytosolic Ca2+ in vinblastine-treated cells than in untreated cells. This increase did not result from impaired Ca2+ efflux, enhanced Ca2+ influx, opening of the mitochondrial permeability transition pore or altered function of endoplasmic reticulum Ca2+ stores. Ca2+ uptake into mitochondria was reduced by 53% in vinblastine-treated cells, as reported by mitochondrially targeted aequorin. Thus, the distribution of mitochondria maintained by microtubules is critical for buffering Ca2+ influx. A subset of mitochondria close to a Ca2+ source may preferentially regulate Ca2+ microdomains, set the threshold for Ca2+-induced toxicity and participate in local ATP production.     

Polarized sorting of viral glycoproteins to the axon and dendrites of hippocampal neurons in culture

Cultured hippocampal neurons were infected with a temperature-sensitive mutant of vesicular stomatitis virus (VSV) and a wild-type strain of the avian influenza fowl plague virus (FPV). The intracellular distribution of viral glycoproteins was monitored by immunofluorescence microscopy. In mature, fully polarized neurons the VSV glycoprotein (a basolateral protein in epithelial MDCK cells) moved from the Golgi complex to the dendritic domain, whereas the hemagglutinin protein of FPV (an apically sorted protein in MDCK cells) was targeted preferentially, but not exclusively, to the axon. The VSV glycoprotein appeared in clusters on the dendritic surface, while the hemagglutinin was distributed uniformly along the axonal membrane. Based on the finding that the same viral glycoproteins are sorted in a polarized fashion in both neuronal and epithelial cells, we propose that the molecular mechanisms of surface protein sorting share common features in the two cell types.     

Intracellular routing of wild-type and mutated polymeric immunoglobulin receptor in hippocampal neurons in culture

Certain epithelial cells synthesize the polymeric immunoglobulin receptor (pIgR) to transport immunoglobulins (Igs) A and M into external secretions. In polarized epithelia, newly synthesized receptor is first delivered to the basolateral plasma membrane and is then, after binding the Ig, transcytosed to the apical plasma membrane, where the receptor-ligand complex is released by proteolytic cleavage. In a previous work (Ikonen et al., 1993), we implied the existence of a dendro-axonal transcytotic pathway for the rabbit pIgR expressed in hippocampal neurons via the Semliki Forest Virus (SFV) expression system. By labeling surface-exposed pIgR in live neuronal cells, we now show (a) internalization of the receptor from the dendritic plasma membrane to the dendritic early endosomes, (b) redistribution of the receptor from the dendritic to the axonal domain, (c) inhibition of this movement by brefeldin A (BFA) and (d) stimulation by the activation of protein kinase C (PKC) via phorbol myristate acetate (PMA). In addition, we show that a mutant form of the receptor lacking the epithelial basolateral sorting signal is directly delivered to the axonal domain of hippocampal neurons. Although this mutant is internalized into early endosomes, no transcytosis to the dendrites could be observed. In epithelial Madin-Darby Canine Kidney (MDCK) cells, the mutant receptor could also be internalized into basolaterally derived early endosomes. These results suggest the existence of a dendro-axonal transcytotic pathway in neuronal cells which shares similarities with the basolateral to apical transcytosis in epithelial cells and constitute the basis for the future analysis of its physiological role.     

Interactions between entorhinal axons and target hippocampal neurons: a role for glutamate in the development of hippocampal circuitry

A coculture system consisting of input axons from entorhinal cortex explants and target hippocampal pyramidal neurons was used to demonstrate that glutamate, released spontaneously from afferent axons, can influence both dendritic geometry of target neurons and formation of presumptive synaptic sites. Dendritic outgrowth was reduced in hippocampal neurons growing on entorhinal axons when compared with neurons growing off the axons. Presumptive presynaptic sites were observed in association with hippocampal neuron dendrites and somas. HPLC analysis showed that glutamate was released from the explants in an activity- and Ca2(+)-dependent manner. The general glutamate receptor antagonist D-glutamylglycine significantly increased dendritic outgrowth in pyramidal neurons associated with entorhinal axons and reduced presumptive presynaptic sites. Tetrodotoxin and reduction of extracellular Ca2+ also promoted dendritic outgrowth and reduced the formation of presumptive synaptic sites. The results suggest that the neurotransmitter glutamate may play important roles in the development of hippocampal circuitry.