Myosin II activity regulates neurite outgrowth and guidance in response to chondroitin sulfate proteoglycans

Chondroitin sulfate proteoglycans (CSPGs) are major components of the extracellular matrix in the CNS that inhibit axonal regeneration after CNS injury. Signaling pathways in neurons triggered by CSPGs are still largely unknown. In this study, using well-characterized in vitro assays for neurite outgrowth and neurite guidance, we demonstrate a major role for myosin II in the response of neurons to CSPGs. We found that the phosphorylation of myosin II regulatory light chains is increased by CSPGs. Specific inhibition of myosin II activity with blebbistatin allows growing neurites to cross onto CSPG-rich areas and increases the length of neurites of neurons growing on CSPGs. Using specific gene knockdown, we demonstrate selective roles for myosin IIA and IIB in these processes. Time lapse microscopy and immunocytochemistry demonstrated that CSPGs also inhibit cell adhesion and cell spreading. Inhibition of myosin II selectively accelerated neurite initiation without altering cell adhesion and spreading on CSPGs.     

Migration Behavior of Granule Cell Neurons in Cerebellar Cultures I. A PKH26 Labeling Study in Microexplant and Organotypic Cultures

Granule cells were dissociated from early postnatal mouse cerebella and labeled with a fluorescent dye probe PKH26. Small number of the labeled cells were mixed with cerebellar cortical microexplant cultures or transplanted into cerebellar cortical organotypic explants, and their time-dependent morphological changes during cultures were examined with fluorescence microscopy. Granule cell neurons first extended asymmetrical short bipolar processes in both cultures, and migrated actively in microexplant cultures. After elongation of symmetrically bipolar long and thin neurites, they sprouted short thick processes from cell bodies and migrated perpendicular to neurite bundles that were devoid of glia in microexplant cultures, or migrated vertically inward into the internal granular layer in the organotypic explant. During such migrations, they extended short thick processes in front and thin processes behind the cell body. The latter processes were connected to thin long neurites with T- or Y-shaped junctions in both cultures. Finally, they extended many short thick processes from cell bodies in both cultures. Such behaviors of granule cell neurons in microexplant cultures were, thus, similar to those in organotypic explant cultures despite of the absence of Bergmann glial cells. These migration patterns may be closely related to migration of granule cells in histogenesis of the cerebellar cortex.     

Steps in the formation of a bipolar outgrowth pattern by cultured neurons, and their substrate dependence.

We studied the steps in the formation of the bipolar outgrowth pattern of cultured adult Anterior Pagoda (AP) neurons of the leech growing on a central nervous system (CNS) homogenate as substrate. This pattern, which consists of two primary neurites directed in opposite directions plus some bifurcations, resembles their embryonic pattern but is different from the patterns they develop in culture on leech laminin or Concanavalin A as substrates. In eight neurons that were studied, one primary neurite formed and branched several hours before the second one. Time-lapse video analysis showed that between 12 and 36 h of growth, the more proximal branch of the early neurite migrated retrogradely, rotated, and formed the second primary branch. Both neurites elongated until the total neurite length reached 130-160 microm, when the elongation of primary neurites became synchronous with the retraction of secondary processes, suggesting competition. The substrate dependence of these events was tested by plating AP neurons on leech laminin. On this substrate AP neurons produced multiple independent primary neurites with branches. Retraction of some large branches was followed by their regrowth, and did not correlate with the changes in other neurites. We propose that the dynamics in the formation of the bipolar outgrowth pattern of AP neurons arise from inhibitory extracellular matrix molecules, which reduce the synthesis of precursors for neurite formation.     

Interleukin-1 receptor antagonist inhibits metastatic potential by down-regulating CXCL12/CXCR4 signaling axis in colorectal cancer

Wnt signaling plays key roles in cellular and physiological processes, including cell proliferation, differentiation and migration during development and tissue homeostasis in adults. This pathway can be defined as Wnt/β-catenin-dependent or β-catenin-independent or “non-canonical”, both signaling are involved in neurite and synapse development/maintenance. Porcupine (PORCN), an acylase that o-acylates Wnt ligands, a major modification in secretion and interaction with its receptors. We use Wnt-C59, a specific PORCN inhibitor, to block the secretion of endogenous Wnts in embryonic hippocampal neurons (DIV 4). Under these conditions, the activity of exogenous Wnt ligands on the complexity of the dendritic tree and axonal polarity were evaluated Cultured primary embryonic hippocampal neurons obtained from Sprague–Dawley rat fetuses (E18), were cultured until day in vitro (DIV) 4 (according to Banker´s protocol) and treated with Wnt-C59 for 24 h, Wnt ligands were added to the cultures on DIV 3 for 24 h. Dendritic arbors and neurites were analysis by fluorescence microscopy. Transfection with Lipofectamine 2000 on DIV 2 of plasmid expressing eGFP and KIF5-Cherry was carried out to evaluate neuronal polarity. Immunostaining was performed with MAP1B and Tau protein. Immunoblot analysis was carried out with Wnt3a, β-catenin and GSK-3β (p-Ser9). Quantitative analysis of dendrite morphology was carried out with ImageJ (NIH) software with Neuron J Plugin. We report, here, that Wnt-C59 treatment changed the morphology of the dendritic arbors and neurites of embryonic hippocampal neurons, with decreases β-catenin and Wnt3a and an apparent increase in GSK-3β (p-Ser9) levels. No effect was observed on axonal polarity. In sister cultures, addition of exogenous Wnt3a, 5a and 7a ligands rescued the changes in neuronal morphology. Wnt3a restored the length of neurites to near that of the control, but Wnt7a increased the neurite length beyond that of the control. Wnt5a also restored the length of neurites relative to Wnt concentrations. Results indicated that Wnt ligands, added exogenously, restored dendritic arbor complexity in embryonic hippocampal neurons, previously treated with a high affinity specific Porcupine inhibitor. We proposed that PORCN is an emerging molecular target of interest in the search for preclinical options to study and treat Wnt-related diseases.     

Inhibition of neurite initiation and growth by taxol

We cultured sensory neurons from chick embryos in media containing the alkaloid taxol at concentrations from 7 X 10(-9) to 3.5 X 10(-6) M. When plated at taxol concentrations above 7 X 10(-8) M for 24 h, neurons have short broad extensions that do not elongate on the culture substratum. When actively growing neurites are exposed to these levels of taxol, neurite growth stops immediately and does not recommence. The broad processes of neurons cultured 24 h with taxol contain densely packed arrays of microtubules that loop back at the ends of the process. Neurofilaments are segregated from microtubules into bundles and tangled masses in these taxol-treated neurons. At the ends of neurites treated for 5 min with taxol, microtubules also turn and loop back abnormally toward the perikaryon. In the presence of 7 X 10(-9) M taxol neurites do grow, although they are broader and less branched than normally. The neurites of these cells appear to have normal structure except for a large number of microtubules. Taxol probably stimulates microtubule polymerization in these cultured neurons. At high levels of the drug, this action inhibits neurite initiation and outgrowth by removing free tubulin from the cytoplasm and destroying the normal control of microtubule assembly in growing neurites. The rapid inhibition suggests that microtubule assembly may occur at neurite tips. At lower concentrations, taxol may slightly enhance the mechanisms of microtubule assembly in neurons, and this alteration of normal processes changes the morphogenetic properties of the growing neurites.     

Steps in the formation of a bipolar outgrowth pattern by cultured neurons,and their substrate dependence

We studied the steps in the formation of the bipolar outgrowth pattern of cultured adult Anterior Pagoda (AP) neurons of the leech growing on a central nervous system (CNS) homogenate as substrate. This pattern, which consists of two primary neurites directed in opposite directions plus some bifurcations, resembles their embryonic pattern but is different from the patterns they develop in culture on leech laminin or Concanavalin A as substrates. In eight neurons that were studied, one primary neurite formed and branched several hours before the second one. Time‐lapse video analysis showed that between 12 and 36 h of growth, the more proximal branch of the early neurite migrated retrogradely, rotated, and formed the second primary branch. Both neurites elongated until the total neurite length reached 130–160 μm, when the elongation of primary neurites became synchronous with the retraction of secondary processes, suggesting competition. The substrate dependence of these events was tested by plating AP neurons on leech laminin. On this substrate AP neurons produced multiple independent primary neurites with branches. Retraction of some large branches was followed by their regrowth, and did not correlate with the changes in other neurites. We propose that the dynamics in the formation of the bipolar outgrowth pattern of AP neurons arise from inhibitory extracellular matrix molecules, which reduce the synthesis of precursors for neurite formation. © 2002 Wiley Periodicals, Inc. J Neurobiol 50: 106–117, 2002; DOI 10.1002/neu.10017     

Ultrastructural analysis of interneuronal syncytial perforations

The structural regularities of the organization of interneuronal syncytial cytoplasmic connections between neuronal bodies in gyrus dentatus and CA1 and CA2 (CA is cornu ammonis) of hippocampus, as well as between cell neurites of the caudal mesenteric ganglion were studied by transmission electron microscopy. The syncytial perforations are located only on the base of tight junctions. The perforations have rounded edges corresponding to the fusion edges of perforated membranes of adjacent neurons – or where their edges have a form of thinned plate – a remnant of the tight junction. In the lumen of the perforations, remnants of contact membranes – residual bodies – are revealed. On living neurons in tissue culture, the syncytial connection of two contacting processes of different neurons is found during the death of the body of one of them, but with preservation of viability of its processes that contact with other neurons.     

Chemotransduction properties of nodose ganglion cardiac afferent neurons in guinea pigs

To determine the chemotransduction characteristics of ventricular sensory neurites associated with nodose ganglion afferent neurons, various chemicals were applied individually to epicardial sensory neurites associated with individual afferent neurons in anesthetized guinea pigs. The following ion channel-modifying agents were tested: barium chloride, cadmium chloride, calcium chloride, the chelating agent EGTA, nickel chloride, potassium chloride, tetraethylammonium chloride, and veratridine. An acidic solution (pH 6.0) and oxygen-derived free radicals (H(2)O(2)) were tested. The following chemicals were also tested: adenosine, alpha- and beta-adrenergic agonists, angiotensin II, bradykinin, calcitonin gene-related peptide (CGRP), histamine, nicotine, the nitric oxide donor nitroprusside, substance P, and vasoactive intestinal peptide. A total of 102 cardiac afferent neurons was identified, of which approximately 66% were sensitive to mechanical stimuli applied to their epicardial sensory fields. Application of individual ion channel-modifying agents to epicardial sensory fields modified most associated afferent neurons, with barium chloride affecting each neuron studied. Ventricular sensory neurites associated with most identified neurons were also responsive to the other tested chemicals, with hydrogen peroxide, adenosine, angiotensin II, bradykinin, CGRP, clonidine, and nicotine inducing responses from at least 75% of the neurons studied. It is concluded that 1) the ventricular sensory neurites associated with nodose ganglion afferent neurons transduce a much wider variety of chemical stimuli than considered previously, 2) these sensory neurites employ a variety of membrane ion channels in their transduction processes in situ, and 3) adrenergic agents influence on sensory neurites associated with cardiac afferent neurons suggests the presence of a cardiac feedback mechanism involving local catecholamine release by adjacent sympathetic efferent postganglionic nerve terminals.     

Growth cone localization of neural cell adhesion molecule on central nervous system neurons in vitro

Ultrastructural analysis of colloidal gold immunocytochemical staining and immunofluorescence microscopy has been used to study the presence of neural cell adhesion molecule (NCAM) on the surface of neuronal growth cones. The studies were carried out with cultures of rat hypothalamic and ventral mesencephalic cells, using morphology and expression of tyrosine hydroxylase, neurofilaments, and glial fibrillary acidic protein as differential markers for neurons and glia. NCAM was found on all plasmalemmal surfaces of neurons including perikarya and neurites. The density of NCAM varied for different neurons growing in the same culture dish, and neurons had at least 25 times more colloidal gold particles on their plasmalemmal membranes than astroglia. Of particular interest in the present study was a strong labeling for NCAM on all parts of neuritic growth cones, including the lamellar and filopodial processes that extend from the tip of the axon. The density of NCAM was similar on different filopodia of the same growth cone. Therefore, in situations where homophilic (NCAM-NCAM) binding might contribute to axon pathfinding, a choice in direction is more likely to reflect differences in the NCAM content of the environment, rather than the distribution of NCAM within a growth cone. On the other hand, the variation in NCAM levels between single neurons in culture was significant and could provide a basis for selective responses of growing neurites.     

A microtubule-based, dynein-dependent force induces local cell protrusions: Implications for neurite initiation

A key event in neurite initiation is the accumulation of microtubule bundles at the neuron periphery. We hypothesized that such bundled microtubules may generate a force at the plasma membrane that facilitates neurite initiation. To test this idea we observed the behavior of microtubule bundles that were induced by the microtubule-associated protein MAP2c. Endogenous MAP2c contributes to neurite initiation in primary neurons, and exogeneous MAP2c is sufficient to induce neurites in Neuro-2a cells. We performed nocodazol washout experiments in primary neurons, Neuro-2a cells and COS-7 cells to investigate the underlying mechanism. During nocodazol washout, small microtubule bundles formed rapidly in the cytoplasm and immediately began to move toward the cell periphery in a unidirectional manner. In neurons and Neuro-2a cells, neurite-like processes extended within minutes and concurrently accumulated bundles of repolymerized microtubules. Speckle microscopy in COS-7 cells indicated that bundle movement was due to transport, not treadmilling. At the periphery bundles remained under a unidirectional force and induced local cell protrusions that were further enhanced by suppression of Rho kinase activity. Surprisingly, this bundle motility was independent of classical actin- or microtubule-based tracks. It was, however, reversed by function-blocking antibodies against dynein. Suppression of dynein expression in primary neurons by RNA interference severely inhibited the generation of new neurites, but not the elongation of existing neurites formed prior to dynein knockdown. Together, these cell biological data suggest that neuronal microtubule-associated proteins induce microtubule bundles that are pushed outward by dynein and locally override inward contraction to initiate neurite-like cell protrusions. A similar force-generating mechanism might participate in spontaneous initiation of neurites in developing neurons. Electronic Supplementry Materials: Supplementary Materials are available in the online version of this article at     

Light and electron microscopic localization of a monoclonal antibody in neurons in situ in the head region of Hydra

A mouse monoclonal antibody to Hydra attenuata was used to demonstrate immunoreactive product in neurons in situ, in both whole mount and sectioned hypostomes and tentacles of H. oligactis and H. littoralis. Immunoreactive cells were concentrated around the mouth and scattered along the length of the tentacles. In the hypostome, nerve cells sent one or more processes orally and the others aborally but the processes were more distinctly stained in H. oligactis. A thin strand of five to six perihypostomal neurons was present close to the hypostome-tentacle junction. In the tentacles, neurons with long processes contacted up to five different batteries of nematocysts. Neural processes were associated with nematocyst batteries in three ways: 1) forming a perikaryal loop to encircle a centrally located stenotele, 2) branching at a distance from the perikaryon to contact a variety of nematocysts, and 3) terminal branching by one or more neurons with contacts on one to several nematocysts within a battery. Immunocytochemical localization of neurons in Hydra by light microscopy was correlated for the first time with electron microscopy. Peroxidase-antiperoxidase (PAP)-positive sensory cells were concentrated around the mouth opening. PAP-positive ganglion cells were predominant in the tentacles. Sensory cells were elongate or spindle-shaped (unipolar), triangular with two oppositely directed processes (bipolar), and multipolar (tripolar or tetrapolar) with one of the processes extending to the epidermal surface. Ganglion cells were either unipolar or bipolar or multipolar, with neurites paralleling the mesoglea and occasionally having processes abut on it.     

The initiation of neurite outgrowth by sympathetic neurons grown in vitro does not depend on assembly of microtubules [published erratum appears in J Cell Biol 1995 Feb;128(3):443]

Neurite formation by dissociated chick sympathetic neurons in vitro begins when one of the many filopodia that emanate from the cell body of a neuron is invaded by cytoplasm containing microtubules and other components of axoplasm (Smith, 1994). This study was undertaken to determine whether this process depends on assembly of microtubules. To inhibit microtubule assembly, neurons were grown in medium containing nocodazole or colchicine. In one series of experiments, neurons first were exposed to the microtubule-stabilizing drug, taxol, so that existing microtubules would remain intact while assembly of new microtubules was inhibited. The ability of neurons to form neurites was assessed by time-lapse video microscopy. Neurons subsequently were stained with antibodies against the tyrosinated and acetylated forms of alpha-tubulin and examined by laser confocal microscopy to visualize microtubules. Neurons were able to form short processes despite inhibition of microtubule assembly and they did so in a way that closely resembled process formation in control medium. Processes formed by neurons that had not been pretreated with taxol were devoid of microtubules. However, microtubules were present in processes of taxol- pretreated neurons. These microtubules contained acetylated alpha- tubulin, as is typical of stable microtubules, but not tyrosinated alpha-tubulin, the form present in recently assembled microtubules. These findings show that the initial steps in neurite formation do not depend on microtubule assembly and suggest that microtubules assembled in the cell body can be translocated into developing neurites as they emerge. The results are compatible with models of neurite formation which postulate that cytoplasm from the cell body is transported into filopodia by actomyosin-based motility mechanisms.     

Denervation and age modify neuromuscular positional selectivity

The rostrocaudal position of neurons within the spinal motor pool maps systematically onto the surface of several muscles in mammals. In an effort to understand the mechanisms that generate such maps, we have been studying choices made by embryonic spinal cord neurons on muscle membrane substrates in the in vitro stripe assay. In this report we explore the effects of postnatal age of the muscle on neurite choice, and how prior denervation modifies this choice. Our results further differentiate rostral from caudal motor neurons in preferring one substrate to another. First, caudal neurites prefer to grow on P6 neonatal caudal over rostral membranes, but lose this ability to distinguish axial position of origin in older muscles. Rostral neurites prefer growth on rostral membranes, but this preference also diminishes with age. Second, when adult muscles have been denervated, both rostral and caudal neurites regain their positional growth selectivity. Third, caudal neurites are particularly sensitive to substrate choice. When growing on a preferred substrate (gluteus) caudal neurites prefer neonatal over adult membranes. These results support the concept of fundamental differences in the growth preferences of rostral and caudal spinal neurites. These differences will assist in the identification of molecular guidance cues that determine the formation of neuromuscular positional maps.     

Axon guidance in the inner ear

Statoacoustic ganglion (SAG) neurons send their peripheral processes to navigate into the inner ear sensory organs where they will ultimately become post-synaptic to mature hair cells. During early ear development, neuroblasts delaminate from a restricted region of the ventral otocyst and migrate to form the SAG. The pathfinding mechanisms employed by the processes of SAG neurons as they search for their targets in the periphery are the topic of this review. Multiple lines of evidence exist to support the hypothesis that a combination of cues are working to guide otic axons to their target sensory organs. Some pioneer neurites may retrace their neuronal migratory pathway back to the periphery, yet additional guidance mechanisms likely complement this process. The presence of chemoattractants in the ear is supported by in vitro data showing that the otic epithelium exerts both trophic and tropic effects on the statoacoustic ganglion. The innervation of ectopic hair cells, generated after gene misexpression experiments, is further evidence for chemoattractant involvement in the pathfinding of SAG axons. While the source(s) of chemoattractants in the ear remains unknown, candidate molecules, including neurotrophins, appear to attract otic axons during specific time points in their development. Data also suggest that classical axon repellents such as Semaphorins, Eph/ephrins and Slit/Robos may be involved in the pathfinding of otic axons. Morphogens have recently been implicated in guiding axonal trajectories in many other systems and therefore a role for these molecules in otic axon guidance must also be explored.     

Rho‐associated kinase (ROCK) inhibitor,Y27632, promotes neurite outgrowth in PC12 cells in the absence of NGF

Neurite extension and retraction are very important processes in the formation of neuronal networks. A strategy for fostering axonal regrowth/regeneration of injured adult neurons is attractive therapeutically for various diseases such as traumatic brain injury, stroke and Alzheimer's disease. The Rho family of small GTPases, including Rac and Cdc42 have been shown to be involved in promoting neurite outgrowth. On the other hand, activation of RhoA induces collapse of growth cone and retraction of neurites. Rho‐associated kinase (ROCK) an effector molecule of RhoA, is downstream of a number of axonal outgrowth and growth cone collapse inhibition mechanisms. In the present study, we sought to identify the role of ROCK in neurite outgrowth in PC12 cells. Y27632, a specific inhibitor of ROCK, induced a robust increase in neurite outgrowth in these cells within 24–48 h as visualized by phase contrast microscopy. Staining with FITC‐tubulin or phalloidin show extended neurites in PC12 cells treated with Y27632, comparable to that with 100 ng/mL of NGF. Assessment of other biochemical markers of neurite outgrowth such as GAP43, neurofilament and tyrosine hydroxylase phosphorylation further indicates that inhibition of ROCK in PC12 cells causes differentiation of these cells to a neuronal phenotype.     

Development of an artificial neuronal network with post-mitotic rat fetal hippocampal cells by polyethylenimine

The selection of appropriate surface materials that promote cellular adhesion and growth is an important consideration when designing a simplified neuronal network in vitro. In the past, extracellular matrix proteins such as laminin (LN) or positively charged substances such as poly-l-lysine (PLL) have been used. In this study, we examined the ability of another positively charged polymer, polyethyleneimine (PEI), to promote neuronal adhesion, growth and the formation of a functional neuronal network in vitro. PEI, PLL and LN were used to produce grid-shape patterns on glass coverslips by micro-contact printing. Post-mitotic neurons from the rat fetal hippocampus were cultured on the different polymers and the viability and morphology of these neurons under serum-free culture conditions were observed using fluorescent microscopy and atomic force microscopy (AFM). We show that neurons cultured on the PEI- and PLL-coated surfaces adhered to and extended neurites along the grid-shape patterns, whereas neurons cultured on the LN-coated coverslips clustered into clumps of cells. In addition, we found that the neurons on the PEI and PLL-coated grids survived for more than 2 weeks in serum-free conditions, whereas most neurons cultured on the LN-coated grids died after 1 week. Using AFM, we observed some neurosynapse-like structures near the neuronal soma on PEI-coated coverslips. These findings indicate that PEI is a suitable surface for establishing a functional neuronal network in vitro.     

Initial stages of neural regeneration in Helisoma trivolvis are dependent upon PLA2 activity

Neuronal regeneration after damage to an axon tract requires the rapid sealing of the injured plasma membrane and the subsequent formation of growth cones that can lead regenerating processes to their appropriate target. Membrane sealing and growth cone formation are Ca(2+)-dependent processes, but the signaling pathways activated by Ca(2+) to bring about these effects remain poorly understood. An in vitro injury model was employed in which neurites from identified snail neurons (Helisoma trivolvis) were transected with a glass microknife, and the formation of new growth cones from the distal portions of transected neurites was recorded at defined times after transection. This study presents three main results. First, phospholipase A(2) (PLA(2)), a calcium-activated enzyme, is necessary for membrane sealing in vitro. Second, PLA(2) activity is also required for the formation of a new growth cone after the membrane has sealed successfully. Thus, PLA(2) plays a dual role by affecting both growth cone formation and membrane sealing. Third, the injury-induced activation of PLA(2) by Ca(2+) controls growth cone formation through the production of leukotrienes, secondary metabolites of PLA(2) activity. Taken together, these results suggest that the injury-induced Ca(2+) influx acts via PLA(2) and leukotriene production to assure growth cone formation. These findings indicate that events that cause an inhibition of PLA(2) or lipoxygenases, enzymes that produce leukotrienes, could result in the inability of neurites to regenerate.     

Neuronal properties of monkey adrenal medulla in vitro

Summary Chromaffin cells from the monkey adrenal medulla were maintained in vitro in the presence of nerve growth factor (NGF) and the neuronal properties of these cells were assessed. Single-cell preparations were obtained by collagenase-trypsin treatment of the minced adrenal medulla tissue. Cells assumed a glandular to epithelioid morphology after twenty-four hours of culture. Twelve percent of these cells were shown to extend neurites spontaneously after five days. NGF-stimulated neuritic outgrowth from most cells after five days of culture and these neurites remained for at least three weeks. Cells exhibited intense histofluorescence for catecholamines even after three weeks in vitro in the presence of NGF and positive staining for tyrosine hydroxylase and dopamine beta hydroxylase could be detected by immunocytochemistry. Moreover, the chromaffin cells were shown to bind tetanus toxin, which is a specific marker for neurons. Tetanus toxin labelling was not dependent upon the presence of neurites on these cells. Transmission electron microscopy indicated that cultured cells contained numerous dense-core vesicles similar to noncultured medulla cells. Many of the neurites possessed the morphological features of axons; long varicose processes resembling noradrenergic fibers were identified by catecholamine histofluorescence and tyrosine hydroxylase immunocytochemistry. Microtubular arrays, in an axonal-like organization pattern, were seen ultrastructurally along with the presence of many dense-core vesicles. These data support the potential of adult primate chromaffin cells as a source of sympathetic neuronal tissue for neural transplantation.Supported in part by a Grant from the Alzheimer's Disease and Related Disorders Association, Inc.     

Growth cones isolated from identified Aplysia neurons in vitro: biochemical and morphological characterization

The right upper quadrant (RUQ) cells (R3-R13) of Aplysia regenerating in dissociated cell culture form unusually large growth cones. The movement of these growth cones was observed by time-lapse phase microscopy and their ultrastructure was examined by transmission electron microscopy. Their behavior and ultrastructure have features that are typical of growth cones in vitro. Additionally, they contain neurosecretory granules similar to those found in these cells in vivo. Because RUQ growth cones are large, they can be isolated by manual dissection. RUQ cells were grown in the presence of [35S]methionine and the labeled proteins transported to the growth cones were analyzed by SDS-PAGE. These proteins were compared to those in RUQ cell bodies, RUQ neurites, and to those in the neurites and cell bodies of other identified neurons grown in vitro. Most proteins synthesized by RUQ cells in vitro are transported to their growth cones, including several glycoproteins and the precursor to the R3-R14 neuropeptide. Neuropeptides are also synthesized by a number of other Aplysia neurons growing in vitro. We examined R2, LPL1, R15, and left upper quadrant neurons and found that their precursor peptides, like those of R3-R14, are readily recognized as major cell-specific radiolabeled bands on SDS gels. The presence in regenerating growth cones of neuropeptides, neurosecretory granules, and glycoproteins known to be rapidly transported toward synapses in vivo supports the emerging view that the growth cone in vitro contains not only a motility apparatus but also a macromolecular assembly capable of forming an active synapse immediately upon or shortly after contacting targets.     

The response of primary cultured adult mouse sensory neurons to ethanol,propanol, acetaldehyde and acrolein treatments

Primary cultures of adult mouse sensory neurons maintained for 8 days in vitro (8 div), in both the presence of non-neuronal cell (NNC) outgrowth and in NNC-reduced cultures, were exposed to doses of ethanol, propanol, acetaldehyde and acrolein. The effects on cell viability were monitored: LD50’s of 600 μM acrolein and 100 mM propanol were obtained after 24 h exposures and after 48 h with 1 mM acetaldehyde and 500 mM ethanol. Morphological effects were evident by scanning electron microscopy with sub-acute doses for each agent, using both lower concentrations and shorter exposures. Membrane pitting of the perikaryon and a reduction in the proportion of neurons bearing neurites were common signs of toxic insult. The neurites of treated cells were thicker and more irregular than those of untreated cells; this proved a good indicator of specific neurotoxicity rather than merely a cytotoxic response. Fetal calf serum in the medium lessened the response of neurons to ethanol treatments. Comparison with other in vitro studies suggests these primary cultures are a more sensitive system than established cell lines of neuronal origin for use in neurotoxicity testing.