Development of dissociated cryopreserved rat cortical neurons in vitro

Dissociated neuronal cultures of various brain regions are commonly used to study physiological and pathophysiological processes in vitro. The data derived from these studies are often viewed to have relevance to processes taking place in the mature brain. However, due to the practical challenges associated with lengthy neuronal culture, neurons are often kept for 14 days in vitro (DIV), or less, before being subject to experimentation. Non-proliferative cultures such as primary neuronal cultures can be maintained for more than 42 DIV if water evaporation from culture media is monitored and corrected. To determine appropriate time points corresponding to the stages of cortical development, we compared characteristics of cryopreserved cortical neurons in cultures at various DIV using immunofluorescence, biochemical measurements and multielectrode array recordings. Compared to 21 and 35 DIV, at 14 DIV, cultures are still undergoing developmental changes and are not representative of adult in vivo brain tissue. Specifically, we noted significant lack in immunoreactivity for synaptic markers such as synapsin, vesicular GABA transporter and vesicular glutamate transporter at 14 DIV, relative to 21 and 35 DIV. Moreover, multielectrode array analysis indicated an increase in network firing up to 46 DIV with patterned firing peaking at 35 DIV. Our results provide specific evidence of the maturational stages of neurons in culture that can be used to more successfully plan various types of in vitro experimentation.     

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.     

Phenotype Specification of Cortical Neurons During a Period of Molecular Plasticity

The transient expression of neuropeptide transmitters is a common feature of the developing cortex. We have now analysed the role of cortical afferents in shaping the neurochemical architecture of rat visual cortex using organotypic cultures. Deafferented cortex monocultures prepared from newborn rats reveal a constant NPY mRNA expression in 6–8% of all cortical neurons up to 90 days in vitro (DIV). In contrast, afferent thalamocortical and corticocortical axonal innervation elicits a progressive reduction in the percentage of NPY mRNA expressing neurons from initially 6–8% in 30DIV cocultures to 2–3% and 3–4% respectively in 60DIV cocultures, which is maintained for up to 90DIV. This phenotype restriction is not observed in only efferently connected corticocollicular cocultures. Further, axonal innervation does not change the percentage of GAD mRNA-expressing neurons, which remains at 13% in mono- and cocultures. When feeding thalamocortical cocultures with monoculture-conditioned medium between 3–20DIV followed by normal medium up to 60DIV, the phenotype restriction fails to occur in the cocultured cortex. We conclude that cortex-derived factors secreted into the medium by a monoculture suppress the phenotype-restricting capacity of the afferents, but only when present within the first 14DIV during the period of formation of axonal connections. To elucidate the nature of the cortex-derived factors, brain-derived neurotrophic factor was applied to the medium. When applied for the first 14DIV, it does not prevent the phenotype restriction from occurring. This suggests that epigenetic factors such as axonal innervation and cortex-derived factors other than brain-derived neurotrophic factor govern a phenotype decision in neocortical neurons during a period of molecular plasticity.     

Effects of Cerebrolysin on the outgrowth and protection of processes of cultured brain neurons

Summary. Cerebrolysin (Cere, EBEWE Arzneimittel, Austria), a peptidergic drug produced by a standardised enzymatic breakdown of porcine brain proteins, consists of a mixture of 75% free amino acids and 25% low molecular weight peptides (<10 k DA). Cerebrolysin was shown to protect against MAP2 loss in primary embryonic chick neuronal cultures after brief histotoxic hypoxia and in a rat model of acute brain ischemia. Since MAP2 is involved in processes like neuronal growth, plasticity and dendritic branching, we address the question whether Cere is protecting processes against degeneration in a chronic low serum (2% FCS) cell stress model and whether the spontaneous outgrowth of axon-like processes is influenced. This was accomplished by quantification of the neurite lengths of embryonic chicken telencephalon neurons after 4 and 8 days. Additionally, time-laps video microscopy was performed to study a possible influence of Cere on the growth cone behaviour of axon-like processes. To distinguish between effects caused by the peptide fraction and the effects related to free amino acids, we used an artificial amino acid solution (AA-mix). Results demonstrate a process outgrowth promoting effect of the AA-mix and Cere after 4 DIV. After 8 days neuronal network degeneration occurred in the AA-mix treated cultures, whereas Cere treated cultures still presented a well differentiated neuronal network. Dying neurons could release factors possibly impeding neurite outgrowth and Cere was shown to increase the viability of chicken cortical neurons. Neither the addition of BDNF nor serum supplementation (5% and 10% FCS) could protect the neuronal network against degeneration after 8 DIV, although these treatments were shown to ameliorate the viability of chicken telencephalon neurons. This result together with the finding obtained using the artificial amino acid solution points to the peptide fraction of Cere to be responsible for the protection of processes against degeneration. Time-laps studies of Cere treated cultures revealed a significant decrease of the velocities characterising random growth cone movements, which is thought to be responsible for an increase in the length of axon-like processes after 4 DIV. Received September 21, 2000; accepted November 22, 2000     

Expression of synaptophysin and neuron-specific enolase during neuronal differentiation in vitro: effects of dimethyl sulfoxide

Neural development in dissociated cell cultures of fetal rat brain can be expected to depend on synaptic interactions between cultured neurons. Therefore, an attempt was made to obtain a quantitative measure of the time course of synaptogenesis in such a culture system by assessing the level of the secretory vesicle-associated protein synaptophysin (p38). The developmental schedule of p38 was compared to that of neuron-specific enolase (NSE), an established marker of neuronal differentiation. Cultures were raised from dissociated 14 day-old fetal rat diencephalon. In cultures grown for 1-2 days in vitro (DIV), p38-immunoreactivity was preferentially located in neuronal perikarya. After 10-16 DIV, neurons in culture had formed a dense neuritic network, and almost all of the p38-immunoreactivity occurred in the form of fine punctate deposits associated with neuronal processes that often outlined neuronal cell bodies in a basket-like fashion. Electron-microscopic immunocytochemistry proved the punctate deposits to be presynaptic elements, mostly in the form of axonal varicosities. Quantitative immunoblotting showed that levels of p38 increased from the start of cultivation to DIV 4, stayed fairly constant from DIV 4 to DIV 8, and rose again steeply to peak at DIV 12. In contrast, levels of NSE rose continuously up to DIV 12. After DIV 12, levels of both p38 and NSE fell again. Treatment of cultures with dimethyl sulfoxide (DMSO), an agent known to induce differentiation in various normal and malignant cell types, resulted in a significant increase of p38 levels and in a decrease of NSE levels. The amount of p38 continued to increase beyond DIV 12, whereas NSE diminished after having reached a maximum at DIV 12.(ABSTRACT TRUNCATED AT 250 WORDS)     

Regeneration of entorhinal fibers in mouse slice cultures is age dependent and can be stimulated by NT-4, GDNF, and modulators of G-proteins and protein kinase C

Axonal regeneration after lesions is normally not possible in the mature central nervous system, but occurs in the embryonic and neonatal nervous system. Slice cultures offer a convenient experimental system to study the decline of axonal regeneration with increasing maturation of central nervous system tissue. We have used mouse entorhinohippocampal slice cultures to assess regeneration of entorhinal fibers after mechanical lesions in vitro. We found that entorhinal axons regenerate well in cultures derived from postnatal days 5-7 mouse pups when the lesion is made at the second and fourth days in vitro (DIV 2 and DIV 4). Only little regenerative outgrowth is seen after lesions made at DIV 6 and DIV 10. This indicates that a maturation of the cultures occurs within a short time period in vitro resulting in a loss of the regenerative potential. We have used this system to screen for neurotrophic factors and pharmacological compounds that may promote axonal regeneration. Treatments were added to the cultures 1 day before the lesion was made. We found that most added factors did not promote regeneration. Only treatment with the neurotrophic factors NT-4 and GDNF stimulated regeneration in cultures where normally little regeneration is found. A similar improvement of regeneration was found after treatment with pertussis toxin, an inhibitor of G(i)-proteins, and with GF109203X, an inhibitor of protein kinase C. These substances may promote regeneration by interfering with intracellular signaling pathways activated by outgrowth inhibitors. Our findings indicate that the application of neurotrophic factors and the modulation of intracellular signal transduction pathways could be useful strategies to enhance axonal regeneration in a complex microenvironment.     

Differential effects of GDNF and BDNF on cultured ventral mesencephalic neurons

Previous studies have shown that brain derived neurotrophic factor (BDNF) and glial cell line-derived neurotrophic factor (GDNF) can enhance the survival of dopaminergic neurons in the ventral mesencephalon (VM). Here we compared several non-survival functions of the two factors in VM neurons in culture. We found that both BDNF and GDNF elicited an increase in the depolarization-induced release of dopamine, but had no effect on GABA release, in the VM cultures. BDNF, but not GDNF, significantly enhanced the expression of the calcium binding protein calbindin and synaptic protein SNAP25. In contrast, treatment of the cultures with GDNF, but not BDNF, elicited a marked fasciculation of the processes of the VM neurons. Thus, although both act on VM neurons, BDNF and GDNF have distinct functions.     

Localization of cholecystokinin-octapeptide-like-immunoreactivity in neurons cultured from rat cerebral cortex

Cholecystokinin-octapeptide-like-immunoreactivity (CCK-8-LI) is demonstrable by the indirect immunofluorescent technique in cerebral cortical neurons cultured from fetal rats. Prominent and widespread staining is seen in widely ramifying cellular processes throughout the cultures. Staining in neuronal cell bodies is enhanced by treatment of the cultures with colchicine prior to fixation and can be seen to extend from the perikaryal region into dendrites and axonal processes. While several morphological types of neurons contain CCK-8-LI, there is a relative preponderance of small and moderate-sized bipolar and, to a lesser extent, multipolar neurons. These findings are in concordance with the findings of several investigators in studies of brain sections. The further finding of frequent groupings of CCK-8 neurons is noted and discussed.     

Developmental changes in environmentally induced analgesia

Cholecystokinin-octapeptide-like-immunoreactivity (CCK-8-LI) is demonstrable by the indirect immunofluorescent technique in cerebral cortical neurons cultured from fetal rats. Prominent and widespread staining is seen in widely ramifying cellular processes throughout the cultures. Staining in neuronal cell bodies is enhanced by treatment of the cultures with colchicine prior to fixation and can be seen to extend from the perikaryal region into dendrites and axonal processes. While several morphological types of neurons contain CCK-8-LI, there is a relative preponderance of small and moderate-sized bipolar and, to a lesser extent, multipolar neurons. These findings are in concordance with the findings of several investigators in studies of brain sections. The further finding of frequent groupings of CCK-8 neurons is noted and discussed.     

A unique membrane protein is expressed on early developing limbic system axons and cortical targets

The limbic system-associated membrane protein (LAMP) is a 64 kDa protein that, in the adult brain, is present in cortical and subcortical regions comprising the limbic system (Levitt, 1984). The developmental expression of LAMP was studied in fetal rat brains to determine the specific patterns of distribution and the cellular elements that exhibit LAMP immunoreactivity. Light microscopic immunocytochemical analysis revealed that LAMP is expressed on neurons and their growing axons early in fetal development, at a time coincident with pathway formation and differentiation of limbic system nuclei. In the forebrain, where limbic system structures are heavily concentrated, immunoreactivity appears on subpopulations of axons in a temporal sequence that correlates with the time of formation of pathways carrying limbic system axons. Thus, staining is evident first at embryonic day (E) 15 on fibers within the internal capsule coursing from the diencephalon to cortex. LAMP immunoreactivity appears over the next 3 d in the anterior commissure, fornix, and corpus callosum. Ultrastructural immunocytochemical analysis reveals dense surface staining of fascicles of developing axons and growth cones. The axonal staining is transient, disappearing during the second postnatal week of development. In cerebral cortex, cells in presumptive limbic cortical regions such as lateral perirhinal sulcal cortex and prefrontal cortex are LAMP immunoreactive from the inception of the cortical plate. These cortical regions are clearly delineated from surrounding unstained nonlimbic areas as early as E15. Thus, LAMP expression in the cortex may represent one of the earliest markers of specific cytoarchitectonic areas.(ABSTRACT TRUNCATED AT 250 WORDS)     

Localization of alpha-, beta-, and gamma-synuclein during neuronal development and alterations associated with the neuronal response to axonal trauma

Genetic and protein studies have indicated abnormalities in alpha-synuclein in neurodegenerative diseases. However, the developmental localization and cellular role of synuclein isoforms is contentious. We investigated the cellular localization of alpha-, beta-, and gamma-synuclein in developing cultured rat neurons and following axonal transection of relatively mature neurons, a model that disrupts the axonal cytoskeleton and results in regenerative sprouting. Cortical neurons were grown up to 21 days in vitro (DIV). Axon bundles at 21 DIV were transected and cellular changes examined at 4 and 24 h post-injury. Immunohistochemistry demonstrated that alpha- and beta-synuclein were localized to cellular cytosol and growth cones at 3DIV, with accumulating puncta-like labeling within axons and growth cones by 10-21DIV. In contrast, gamma-synuclein immunoreactivity was limited at all time points. By 21DIV, alpha- and beta-synuclein were present in the same neurons but largely in separate subregions, only 26% of puncta contained both alpha- and beta-synuclein immunoreactivity. Less than 20% of alpha-, beta-, and pan-synuclein immunoreactive puncta directly colocalized to synaptophysin profiles at 10DIV, decreasing to 10% at 21DIV. Both alpha- and beta-synuclein accumulated substantially within damaged axons at 21DIV and were localized to cytoskeletal abnormalities. At latter time points post-injury, alpha- and beta-synuclein immunoreactive puncta were localized to growth cone-like structures in regenerating neurites. This study shows that alpha- and beta-synuclein have a precise localization within cortical neurons and are generally nonoverlapping in their distribution within individual neurons. In addition, synuclein proteins accumulate rapidly in damaged axons and may have a role in regenerative sprouting.     

Metallothionein-III inhibits initial neurite formation in developing neurons as well as postinjury,regenerative neurite sprouting

Human metallothionein-III (MT-III) is an inhibitory factor deficient in the Alzheimer's disease (AD) brain. MT-III has been identified as an inhibitor of neurite sprouting, and its deficiency has been proposed to be involved in the formation of neurofibrillary tangles (NFT) in the neuropathology of AD. However, there has been limited investigation of the proposed neurite growth inhibitory properties of MT-III. We have applied recombinant human MT-III to both single cell embryonic cortical neurons (to investigate initial neurite formation), as well as mature (21 days postplating) clusters of cortical neurons (to investigate the regenerative sprouting response following injury). We report that MT-III inhibited the initial formation of neurites by rat embryonic (E18) cortical neurons. This was based on both the percentage of neurite positive neurons and the number of neurites per neuron (45 and 30% inhibition, respectively). Neurite inhibition was only observed in the presence of adult rat brain extract, and was also reversible following replacement of MT-III-containing medium. MT-III inhibited the formation and growth of both axons and dendrites. Of more physiological significance, MT-III also inhibited the regenerative neurite sprouting response following axonal transection. The morphology of sprouting neurites was also altered, with the distal tip often ending in bulb-like structures. Based on these results, we propose that MT-III, in the presence of brain extract, is a potent inhibitor of neurite sprouting, and may be involved in abnormal sprouting potentially underlying both AD and epilepsy.     

Adenoviral-mediated transfection of the lac-z geneinto rat dissociated embryonic central nervous systemcells before and after seeding

The adenovirus carrying a reporter gene—the Lac-Z gene—is well known toinfect central nervous system (CNS) cells in primary cell cultures. The percentage of infectedneurons with respect to the total number of neurons was studied in primary dissociated culturesas a function of the day of inoculation and the age of three rat CNS cultures : spinal cord,mesencephalon and cortex. Two methods of viral inoculation were compared : the firstinoculation was performed on the cultured cells at 2, 3 or 6 days in vitro (DIV) whereas the second inoculation was performed on the cell suspensions before seeding. All theinfected CNS cells had the same aspect as the control cultures. In the spinal cord and themesencephalic cultures, the glial cells were preferentially infected, especially when the cells wereinoculated at 6 DIV. In the cortical cultures, there were more infected neurons than infected glialcells. The number of CNS cells was lower when inoculation was performed at 6 DIV ascompared with 3 DIV. Very few infected GABA cells were found in the cultures. A highpercentage of infected neuronal cells relative to the total number of neuronal cells was foundwhen infection of the three types of cultures was performed on the dissociated embryonic cellsuspension before seeding.     

The importance of fasciculation and elongation protein zeta-1 in neural circuit establishment and neurological disorders

The human brain contains an estimated 100 billion neurons that must be systematically organized into functional neural circuits for it to function properly. These circuits range from short-range local signaling networks between neighboring neurons to long-range networks formed between various brain regions. Compelling converging evidence indicates that alterations in neural circuits arising from abnormalities during early neuronal development or neurodegeneration contribute significantly to the ...     

Time lapse study of neurite growth in hypothalamic dissociated neurons in culture: sex differences and estrogen effects.

Cultures of dissociated hypothalamic cells taken from rat fetuses of 19 days of gestation were studied using time-lapse recording and sequential microphotography from 1 to 5 days in vitro (DIV) and at 7 and 21 DIV. Cultures were seeded with cells taken from fetuses grouped by sex or sexually mixed; experimental cultures were raised in medium containing 17-beta-estradiol 100 nM (E2). Cells were plated on poly-D-lysine-coated coverslips at a culture density of approximately 4,000 cells/cm2. Immunocytochemistry of cell cultures was performed using a Tau monoclonal antibody (clone Tau-1 PC1C6) and a monoclonal antibody against MAP-2 (clone AP-20). Cells started to produce lamellipodia and neuritic processes approximately 4 hr after plating. Forty-eight hours later a few neurons had defined their morphological polarity by the differentiation of an axon-like process that grows faster than the others; at 5 DIV almost all neurons had defined their axons. At this time, monoclonal antibody against MAP-2 clearly stained soma and dendrites, but not axons. Tau immunoreactivity (lots CCA101 and CCA101N from Boeringher Mannheim) was differentially distributed, with a clear predominance in axon and soma. Results on the morphometric analysis of control and E2 treated neurons provide direct evidence for the existence of sex related differences in the neurite outgrowth response of hypothalamic neurons, since cultured neurons taken from female fetuses differentiated axons later and had fewer primary neurites and shorter dendrites than neurons taken from male fetuses or sexually mixed cultures. Also, it was demonstrated in living neurons that E2 effectively enhances outgrowth and elongation in axons. The frequency distribution curves of axonal length for control and E2 treated cultures was unimodal, suggesting that the effect of E2 was a uniform increase in the axonal length of all neurons. The structural differences between neurons from both sexes and the changes induced by E2 may contribute to explain the differences in brain function found between the sexes.     

Foreign gene expression in an organotypic culture of cortical anlage after in vivo electroporation.

A high level of foreign gene expression in organotypic cultures of the cerebral cortical anlage was achieved by electroporation-mediated gene transfer in vivo. A mammalian expression plasmid for green fluorescent protein (GFP) gene was injected into the lateral ventricle of rat embryos. Immediately after the plasmid DNA injection, the head of the embryo was electroporated between a pair of tweezer-type electrodes. The cortical anlage was isolated and maintained organotypically up to 21 days in vitro (DIV). The GFP-transgene was expressed intensely in neural progenitor cells at 1 DIV. GFP-expressing cells were still detectable and were demonstrated to differentiate into neurons and glia at 21 DIV. This system is expected to be useful for molecular analysis of cerebral cortical development and function.     

Oligodendrocyte proliferation and CNS myelination in cultures containing dissociated embryonic neuroglia and dorsal root ganglion neurons

In this report we have described several aspects of glial development in cultures containing dissociated DRG neurons and glial cells obtained from dissociated spinal cord at least a week prior to the onset of in vivo myelination. With time in culture the dissociated neurons and glia interact and become organized into 3-dimensional structures possessing many features characteristic of developing CNS in vivo. We have presented evidence that some of the glial cells proliferate and differentiate into galactocerebroside positive (GC+) cells and that some produce myelin sheaths. Thymidine was incorporated into precursors of GC+ cells, but not into cells which were already GC+. Nearly all the astrocytes in areas where neurons were present participated in the formation of large fascicles, and it was within such fascicles that most myelin was formed, suggesting a possible role for astrocytes in creating a favorable microenvironment for myelination. Both the formation of myelin sheaths and the morphological maturity of the oligodendrocytes within the fascicles indicated that oligodendrocyte differentiation proceeded practically to completion in these cultures. In conclusion we believe that the culture system herein described provides an excellent model for in vitro studies of CNS development, while retaining some of the advantages of dissociated cell cultures as well as the possibility of separating and re-uniting the various cell types of interest.     

The participation of a putative cell surface receptor for laminin and fibronectin in peripheral neurite extension

We have used the CSAT (cell substrate attachment) monoclonal antibody (Mab), which is directed against a putative laminin and fibronectin receptor, to examine its role in the adhesive phenomena of neurons. This antibody was previously found to disturb the adhesion of several classes of fibroblasts and muscle. Here we report its effects upon neuronal-substrate adhesion. Two sources of neurons were investigated--the dorsal root and ciliary ganglia. Both responded similarly. Neurons plated in the presence of the CSAT Mab did not adhere to the substratum and process formation was inhibited completely for at least 24-48 hr. In explant cultures, when neurons were first allowed to extend processes prior to addition of the CSAT Mab, the results depended on the particular substrate. With some substrates, the neurites bundled and detached from the substratum; with others, they retracted and regrew to form large fascicles or bundles of processes. In dissociated cultures that already had extended processes, neurites fasciculated and cell bodies aggregated in response to the presence of the CSAT Mab. The magnitude of this response varied, depending upon the substrate. The antigen was localized, using immunofluorescence, on neuronal cell bodies, axons, and growth cones. This distribution correlated with its biological effects on all parts of the neuron. The antigen was isolated from neuronal cultures by immunoaffinity purification. It migrated in the molecular weight range of 140 kDa on reducing SDS-PAGE. This antigen is very similar to that isolated from fibroblasts, which is an integral membrane glycoprotein complex. The data presented implicate the participation of the CSAT antigen in neurite extension and fasciculation.     

AL-1-induced Growth Cone Collapse of Rat Cortical Neurons is Correlated with REK7 Expression and Rearrangement of the Actin Cytoskeleton

Previous experiments identified AL-1 as a glycosylphosphatidylinositol (GPI)-linked ligand for the Eph-related receptor, REK7, and showed that a REK7-IgG fusion protein blocks axon bundling in co-cultures of cortical neurons on astrocytes, suggesting a role for REK7 and AL-1 in axon fasciculation. Subsequent identification of RAGS, the chick homologue of AL-1, as a repellent axon guidance molecule in the developing chick visual system led to speculation that AL-1, expressed on astrocytes, provides a repellent stimulus for cortical axons, inducing them to bundle as an avoidance mechanism. Using a growth cone collapse assay to test this hypothesis, we show that a soluble AL-1-IgG fusion protein is a potent collapsing factor for embryonic rat cortical neurons. The response is strongly correlated with REK7 expression, implicating REK7 as a receptor mediating AL-1-induced collapse. Morphological collapse is preceded by an AL-1-IgG-induced reorganization of the actin cytoskeleton that resembles the effects of cytochalasin D. This suggests a pathway whereby REK7 activation by AL-1 leads to perturbation of the actin cytoskeleton, possibly by an effect on actin polymerization, followed by growth cone collapse. We further show that AL-1-IgG causes collapse of rat hippocampal neurons and rat retinal ganglion cells. These data suggest a role for REK7 and AL-1 in the patterning of axonal connections in the developing cortex, hippocampus and visual system.     

Structure and function of long-lived olfactory organotypic cultures from postnatal mice

The first synapse in the olfactory pathway mediates a significant transfer of information given the restricted association of specific olfactory receptor neurons with specific glomeruli in the olfactory bulb. To understand better how this connection is made and what the functional capacities of the participating cells are, we created a long-lived culture system composed of olfactory epithelium and olfactory bulb tissues. Using the roller tube method of culturing, we grew epithelium-bulb cocultures, explanted from 1-4-day-old Swiss Webster mice, on Aclar for periods ranging from 18 hr to 68 days. The explants flattened so that in some areas the culture was only a few cells thick, making individual cells distinguishable. From 107 cultures studied, we identified the following cell types by expression of specific markers (oldest culture expressing marker, days in vitro, DIV): olfactory receptor neurons (neural cell adhesion molecule, 42 DIV); mature receptor neurons (olfactory marker protein, 28 DIV); postmitotic olfactory receptor neurons and olfactory bulb neurons (beta-tubulin, 68 DIV); astrocytes (glial fibrillary acidic protein, glutamate/aspartate transporter, 68 DIV); olfactory horizontal basal cells (cytokeratin, 22 DIV). Neuronal processes formed glomeruli in 2-4-week-old cultures. We also recorded electro-olfactography responses to puffs of vapor collected over an odorant mixture containing ethyl butyrate, eugenol, (+) carvone, and (-) carvone from cultures as old as 21 DIV. These features of our olfactory culture system make this model useful for studying properties of immature and mature olfactory receptor neurons, pathfinding strategies of receptor axons, and mechanisms of information transfer in the olfactory glomerulus.