Regional differences in in vitro growth of neural cell processes during development

Axogenic effect of estrogen in male rat hypothalamic neurons involves Ca(2+), protein kinase C, and extracellular signal-regulated kinase signaling

17-beta-Estradiol (E2) stimulates the growth of axons in male-derived hypothalamic neurons in vitro. This effect is not exerted through the classical intracellular estrogen receptor (ER) but depends on a membrane mechanism involving TrkB. In the present study, we investigate the intracellular signaling cascade that mediates the axogenic effect of E2. Treatment with an intracellular Ca(2+) chelator, a Ca(2+)-dependent protein kinase C (PKC) inhibitor, or two specific inhibitors of extracellular signal-regulated kinases (ERK) mitogen-activated protein kinases (MAPK) completely inhibited the E2-induced axogenesis. E2 and the membrane-impermeant construct E2BSA rapidly induced phosphorylation of ERK, which was blocked by the specific inhibitor of the ERK pathway UO126 but not by the ER antagonist ICI 182,780. Decrease of intracellular free Ca(2+) or disruption of PKC activation by Ro 32-0432 attenuated ERK activation, indicating the confluence of signals in the MAPK pathway. Subcellular analysis of ERK demonstrated that the phospho-ERK signal is augmented in the nucleus after 15 min of E2 stimulation. We have also shown that E2 increased phosphorylation of CREB via ERK signaling. In summary, this study demonstrates that E2, probably via a membrane-associated receptor, induces axonal growth by activating CREB phosphorylation through ERK signaling by a mechanism involving Ca(2+) and PKC activation.

Inhibition of tyrosine kinase receptor type B synthesis blocks axogenic effect of estradiol on rat hypothalamic neurones in vitro

17-beta-estradiol (E2) increases axonal growth and tyrosine kinase receptor (Trk)B levels of male-derived hypothalamic neurones in vitro. To investigate whether the axogenic response depends on the upregulation of TrkB, we analysed neuritic growth and neuronal polarization in cultures treated with an antisense oligonucleotide against TrkB mRNA. In cultures without E2, treatment with 7.5 or 10 micro m antisense reduced TrkB levels and the percentage of neurones showing an identifiable axon; the number and length of minor processes were increased. In cultures treated with 5 micro m antisense, morphometric parameters were normal although total TrkB levels were reduced. The same dose prevented the E2-dependent increase of TrkB levels and suppressed the axogenic effect of E2. These results indicate that TrkB is necessary for normal neuronal growth and maturation and further suggest that an increase in TrkB is necessary for E2 to exert its axogenic effect in male-derived neurones.

Astrocytes mediate cerebral cortical neuronal axon and dendrite growth, in part, by release of fibroblast growth factor

Astrocytes occupy a central role in central nervous system (CNS) function. In particular astyrocytes can support neurite growth, in part, by release of diffusable factors. We therefore performed biochemical analysis of astrocyte conditioned medium to examine possible mechanisms of astrocyte mediated axon and dendrite growth in the mammalian CNS. Culture medium was conditioned on purified astrocyte monolayers derived from P3 rat cerebral cortex or on fibroblasts. Conditioned medium (CM) was subject to protein denaturation, molecular weight fractionation, and heparin affinity chromatography. E18 mouse cerebral cortical neurons were then cultured in the various media or directly on astrocyte monolayers and axon and dendrite growth from 50 neurons in each condition quantified after 3 DIV using double-labeled immunohistochemical techniques. Axon and dendrite growth was supported by astrocyte CM and both were significantly greater than process growth from neurons incubated in fibroblast CM. Protein denaturation significantly reduced astrocyte CM support of axon and dendrite growth. Following ultrafiltration and dialysis dendrite and axon growth was observed in the molecular weight fraction between 10 and 100 kDa. Axon growth also was observed in the CM molecular weight fraction greater than 100 kDa. Conditioned medium was eluted on a heparin column; when the bound fragment was reconstituted in chemically defined medium extensive dendrite and axon growth was observed. Since fibroblast growth factor (FGF) has these biochemical characteristics we added anti-bFGF neutralizing antibodies to astrocyte monolayers or CM; this significantly reduced astrocyte support of process growth. By contrast, the addition of heparin, which helps activate FGF receptors, to astrocyte CM further enhanced process growth. Western blot analysis confirmed that bFGF was present in astrocyte CM. We then examined axon and dendrite growth from cortical neurons after the addition of various growth factors to chemically defined medium. Axon and dendrite growth, similar to that found in astrocyte CM was observed after the addition of bFGF or aFGF. Astrocyte support of cerebral cortical neuron axon and dendrite growth in vitro may be explained, in part, by FGF release.

Nongenomic mechanism mediates estradiol stimulation of axon growth in male rat hypothalamic neurons in vitro

The purpose of the present work was to investigate the participation of estradiol receptors (ER) in estrogen-induced axon growth in vitro. Hypothalamic neurons from 16 day (E16) male rat fetuses were cultured with or without 17-beta-estradiol at 1 x 10(-7) M in basal medium or medium conditioned by astroglia derived from ventral mesencephalon (CM). After 48 hr in vitro, neurite outgrowth was quantified by morphometric analysis. An axogenic effect could be demonstrated for estradiol added to CM. With RT-PCR, the mRNA transcript for ERalpha was found in the donor tissues as well as in the neuron cultures. In this model two specific nuclear ER blockers (tamoxifen and ICI 182,780) were ineffective in blocking the neuritogenic effect, and a membrane-impermeable estrogen-albumin construct (E2-BSA) was as effective as estradiol. These results indicate that the axogenic effect of estradiol at E16 is not exerted through the classical intracellular receptor signal transduction system and suggest the possibility of a membrane-mediated mechanism. The data are discussed in light of our previous findings pointing to the interdependent activation of the estrogenic and the trophic factor signaling pathways that mediate stimulated axon growth.

Dissociated functional recovery in parkinsonian monkeys following transplantation of astroglial cells

Bilateral astroglial transplantation into the neostriatum of 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP)-treated monkeys resulted in significant performance improvement in a spatial delayed response task, but failed to modify perseveration in an object retrieval detour task, or to improve motor clinical rating. Results suggest that brain circuits subserving various motor and cognitive performances can be functionally dissociated, and that remaining resources for the reorganization of neural circuits involved in spatial working memory performance in parkinsonian monkeys, appear to be responsive to striatal transplantation of subcultured, fetal striatal astroglial cells.

Heterochronous maturation of regional brain astroglia: neuronal modulation of striatal glial cells differentiation ex vivo

Subcultured astroglial cells from striatum, cerebral cortex and ventral mesencephalon obtained from primary cultures of fetal (E14, E17 and E21) or postnatal (days 5-6) rats showed different regional, age-dependent morphological response (stellation) to cyclic AMP. While most of the cerebral cortex and ventral mesencephalic astroglial cell population was responsive at all ages tested, striatal cells at E14 and E17 were not. At age E21 striatal astroglia showed a significant shift toward a mature-like type of response to cyclic AMP. Postnatal striatal astroglia responded to cyclic AMP as the cortical and ventral mesencephalic astroglia did, with generalized stellation. Prenatal striatal astroglia was characterized immunocytochemically as A2B5+, fibronectin+, vimentin+, S-100+ and GFAP-. Failure of early prenatal (E14, E17) striatal astroglia to differentiate in response to cyclic AMP, was overcome by previous (5-7 days) co-culture with primary cell dissociates from postnatal-, but not from prenatal donors, from all brain regions tested including a non-target region for striatal cells, such as septum. This effect was duplicated when striatal astroglia was co-cultured with cell populations enriched in neurons through Percoll gradients. Only cell-to-cell contact co-cultures were able to induce a change in the studied response. Dead neuron-enriched populations obtained following various types of physical treatments were also able to change significantly striatal cell response toward cyclic AMP. Enriched astroglial populations from postnatal donors did not change striatal astroglial response toward cyclic AMP, except for ventral mesencephalic astroglia which induced a comparatively reduced but significant increase in striatal cell responsiveness. It is concluded that astroglial maturation and potential for phenotype expression during brain development proceeds with regional heterochrony. Also, that maturation of prenatal striatal astroglia responsiveness toward cyclic AMP is inducible by non-diffusible factors, probably of neuronal origin, expressed in live or dead primary cultures from various, homotopic and heterotopic, postnatal brain regions. It is further suggested that striatal afferents and/or mature local striatal neurons express membrane associated molecules that regulate responsiveness for phenotype expression of striatal glial cells, thus reinforcing the concept of a highly interactive, continuous neuron-glial developmental process that takes place during brain organization.

Differential effect of oestradiol and astroglia-conditioned media on the growth of hypothalamic neurons from male and female rat brains

To determine whether soluble products from different CNS regions differ in their ability to support oestrogen-stimulated neurite growth, hypothalamic neurons from sexually segregated embryos were cultured with astroglia-conditioned medium (CM) derived from cortex, striatum and mesencephalon, with or without 17-beta-oestradiol 100 nM added to the medium. After 48 h in vitro, neurite outgrowth was quantified by morphometric analysis. Astroglia-CM from mesencephalon (a target for the axons of hypothalamic neurons) induced the greatest axogenic response in males and in this case only a neuritogenic effect could be demonstrated for oestradiol. On the other hand, astroglia-CM from regions that do not receive projections from ventromedial hypothalamus inhibited axon growth. A sexual difference in the response of hypothalamic neurons to astroglia-CM and oestradiol was found; growth of neurons from female foetuses was increased by astroglia-CM from mesencephalon, but no neuritogenic effect could be demonstrated for oestradiol in these cultures. Blot immunobinding demonstrated the presence of receptors for neurotrophic factors in cultures of hypothalamic neurons; Western blot analysis of these cultures demonstrated that oestradiol increased the concentration of trkB and IGF-I Rbeta, whereas trkA was not detected and the concentration of trkC was not modified. These results support the hypothesis that target regions produce some factor(s) that stimulate the growth of axons from projecting neurons and further indicate that in the case of males this effect is modulated by oestradiol, perhaps mediated through the upregulation of trkB and IGF-I receptors.

Cerebrospinal fluid from L-dopa-treated Parkinson's disease patients is dystrophic for various neural cell types ex vivo: effects of astroglia

Cerebrospinal fluid from L-dopa-treated Parkinson's disease patients and subjects without neurodegenerative diseases (controls) was explored in its trophic properties as culture medium on a variety of cells from neural origin. Primary cultures of regional brain dissociates from rat and Cebus apella monkey fetuses, immature rat adrenal chromaffin cells, phaeochromocytoma (PC12), and neuroblastoma (NB69) cell lines as well as subcultured fetal rat astroglia were used as target cells for 24- to 48-h culture periods. Most cerebrospinal fluid samples from L-dopa-treated patients had a general dystrophic effect. This phenomenon was more apparent on striatum and ventral mesencephalon than on cerebral cortex cell dissociates. The deleterious effect of these samples was abolished by previous exposure to fetal astroglial cells. Neuroblastoma cells showed no differential response when exposed to samples from control and L-dopa-treated patients. Phaeochromocytoma cells did not grow processes under any of the samples assayed in the time interval explored, but neither showed evidence of dystrophy. The relevance of these findings to the transplantation of different cell types as one of the possible therapies for Parkinson's disease is discussed. The suggestion is made that CSF testing prior to transplantation may aid in anticipating its possible outcome. Cotransplantation of neuronal cells with subcultured astroglia may foster survival and growth of the former cells.

NADPH-d positive neurons in the developing somatosensory cortex of the rat: effects of early and late environmental enrichment

The effects of environmental enrichment upon the topographic arrangement of NADPH diaphorase-positive neurons (NADPH-d+ neurons) was studied in the somatosensory cortex of 56 Sprague-Dawley albino rats during early stages of development (18th, 24th, 30th and 60th postnatal days). This diaphorase is easily demonstrable, providing a convenient marker for quantitative studies. Environmental enrichment diminished the number of NADPH-d+ neurons and exerted its maximal influence during lactation, a time of exceptional cortical susceptibility. This implies that the magnitude of such effects on the density of NADPH-d+ neurons is age-dependent. Furthermore, it was found that the experience-dependent cortical changes persisted after a subsequent period without environmental stimulation. The effects of early environmental enrichment did not occur uniformly throughout the cerebral hemispheres but, instead, such effects were maximal in the latero-ventral sector of the cerebral cortex where a dramatic reduction in the number of NADPH-d+ neurons was observed. Particularly striking was the existence of a latero-medial sequence of NADPH-d+ neurons in the infragranular layer and a reversed distribution of labeled cells, in the supragranular layer. Both ontogenetic sequences of NADPH-d+ neurons remained unchanged during postnatal development in controls and enriched subjects (18th-60th postnatal days).