Specific effects of ethanol on neurite-promoting proteoglycans of neuronal origin

Molecular and morphological changes in zebrafish following transient ethanol exposure during defined developmental stages

Alcohol is a teratogen that has diverse effects on brain and craniofacial development, leading to a constellation of developmental disorders referred to as fetal alcohol spectrum disorder (FASD). The molecular basis of ethanol insult remains poorly understood, as does the relationship between molecular and behavioral changes as a consequence of prenatal ethanol exposure. Zebrafish embryos were exposed to a range of ethanol concentrations (0.5-5.0%) during defined developmental stages, and examined for morphological phenotypes characteristic of FASD. Embryos were also analyzed by in situ hybridization for changes in expression of defined cell markers for neural cell types that are sonic hedgehog-dependent. We show that transient binge-like ethanol exposures during defined developmental stages, such as early gastrulation and early neurulation, result in a range of phenotypes and changes in expression of Shh-dependent genes. The severity of fetal alcohol syndrome (FAS) morphological phenotypes, such as microphthalmia, depends on the embryonic stage and concentration of alcohol exposure, as does diminution of retinal Pax6a or forebrain and hindbrain GAD1 gene expression. We also show that changes in eye and brain morphology correlate with changes in Pax6a and GAD1 gene expression. Our results therefore show that transient binge-like ethanol exposures in zebrafish embryos produce the stereotypical morphological phenotypes of FAS, with the severity of phenotypes depending on the developmental stage and alcohol concentration of exposure.

Effects of ethanol exposure on nervous system development in zebrafish

Alcohol (ethanol) is a teratogen that adversely affects nervous system development in a wide range of animal species. In humans numerous congenital abnormalities arise as a result of fetal alcohol exposure, leading to a spectrum of disorders referred to as fetal alcohol spectrum disorder (FASD). These abnormalities include craniofacial defects as well as neurological defects that affect a variety of behaviors. These human FASD phenotypes are reproduced in the rodent central nervous system (CNS) following prenatal ethanol exposure. While the study of ethanol effects on zebrafish development has been more limited, several studies have shown that different strains of zebrafish exhibit differential susceptibility to ethanol-induced cyclopia, as well as behavioral deficits. Molecular mechanisms underlying the effects of ethanol on CNS development also appear to be shared between rodent and zebrafish. Thus, zebrafish appear to recapitulate the observed effects of ethanol on human and mouse CNS development, indicating that zebrafish can serve as a complimentary developmental model system to study the molecular basis of FASD. Recent studies examining the effect of ethanol exposure on zebrafish nervous system development are reviewed, with an emphasis on attempts to elucidate possible molecular pathways that may be impacted by developmental ethanol exposure. Recent work from our laboratories supports a role for perturbed extracellular matrix function in the pathology of ethanol exposure during zebrafish CNS development. The use of the zebrafish model to assess the effects of ethanol exposure on adult nervous system function as manifested by changes in zebrafish behavior is also discussed.

Agrin function associated with ocular development is a target of ethanol exposure in embryonic zebrafish

BACKGROUND

Alcohol (ethanol) is a teratogen known to affect the developing eyes, face, and brain. Among the ocular defects in fetal alcohol spectrum disorder (FASD) are microphthalmia and optic nerve hypoplasia. Employing zebrafish as an FASD model provides an excellent system to analyze the molecular basis of prenatal ethanol exposure-induced defects because embryos can be exposed to ethanol at defined developmental stages and affected genetic pathways can be examined. We have previously shown that disruption of agrin function in zebrafish embryos produces microphthalmia and optic nerve hypoplasia.

METHODS

Zebrafish embryos were exposed to varying concentrations of ethanol in the absence or presence of morpholino oligonucleotides (MOs) that disrupt agrin function. In situ hybridization was used to analyze ocular gene expression as a consequence of ethanol exposure and agrin knockdown. Morphologic analysis of zebrafish embryos was also conducted.

RESULTS

Acute ethanol exposure induces diminished agrin gene expression in zebrafish eyes and, importantly, combined treatment with subthreshold levels of agrin MO and ethanol produces pronounced microphthalmia, markedly reduces agrin gene expression, and perturbs Pax6a and Mbx gene expression. Microphthalmia produced by combined agrin MO and ethanol treatment was rescued by sonic hedgehog (Shh) mRNA overexpression, suggesting that ethanol-mediated disruption of agrin expression results in disrupted Shh function.

CONCLUSIONS

These studies illustrate the strong potential for using zebrafish as a model to aid in defining the molecular basis for ethanol's teratogenic effects. The results of this work suggest that agrin expression and function may be a target of ethanol exposure during embryogenesis.

Ethanol inhibits development of dendrites and synapses in rat hippocampal pyramidal neuron cultures

Evidence suggests that some neuropathologic manifestations of Fetal Alcohol Syndrome (FAS) result from the disruption of neuromorphogenesis and synapse formation in the hippocampus. Prior research in this laboratory has shown that ethanol in the medium during the first 24 h in culture increases the number of minor processes (the precursors of axons and dendrites) and accelerates the rate at which axons are formed in low-density cultures of embryonic rat hippocampal neurons. The current study examined the effects of ethanol on the subsequent development of dendrites and synapses in these cultures. Quantitative morphometric analysis utilized double-immunofluorescent staining for MAP2 and synapsin I to visualize dendrites and synaptic specializations, respectively. Six days of ethanol (200, 400 or 600 mg/dl) in the medium, beginning at the time of plating, resulted in decreases in total dendritic length per cell, dendrite number per cell, length of individual dendrites and synapse number per innervated dendrite but had no effect on cell survival. The decrease in synapse number was correlated with dendrite length, suggesting that ethanol's effects on synapse number are secondary to its effects on dendritogenesis. Taken together with our previous findings, these results are the first to demonstrate that ethanol has differential effects on axonal and dendritic growth in a culture model of neurons that are vulnerable to ethanol-induced cytoarchitectural abnormalities during development in vivo.

Ethanol inhibits L1-mediated neurite outgrowth in postnatal rat cerebellar granule cells

The neuropathology of the effects of ethanol on the developing central nervous system are similar to those of patients with mutations in L1, a neural cell adhesion molecule. This observation suggests that inhibition of L1 plays a role in the pathogenesis of alcohol-related neurodevelopmental disorders. Here we examine the effects of ethanol on L1 homophilic binding and on L1-mediated neurite outgrowth. Ethanol had no effect on cell adhesion or aggregation in a myeloma cell line expressing full-length human L1. In contrast, the rate of L1-mediated neurite outgrowth of rat postnatal day 6 cerebellar granule cells grown on a substratum of NgCAM, the chick homologue of L1, was inhibited by 48.6% in the presence of ethanol with a half-maximal concentration of 4.7 mM. The same effect was found with soluble L1-Fc, thus showing that the inhibitory effect is not dependent on cell adhesion. In contrast, neither laminin nor N-cadherin-mediated neurite outgrowth was inhibited by physiologic concentrations of ethanol. We conclude that one mechanism of ethanol's toxicity to the developing central nervous system may be the inhibition of L1-mediated neurite outgrowth.

Effects of neuronal proteoglycans on activity-dependent growth responses of fetal hippocampal neurons

Excitatory amino-acid (EAA) neurotransmitters act as molecular signals influencing the structure of neurons during development. However, the signal transduction and effector mechanisms responsible for these effects have yet to be fully elucidated. We have previously provided evidence that EAA agonists induce the synthesis and release of proteoglycans (PGs) with neurite-promoting activity from fetal hippocampal neurons. In the present studies exposure of fetal hippocampal neurons to glutamate (100 microM) for 5 min resulted in increases in the neuron-specific growth-associated genes T alpha 1 alpha-tubulin (T alpha 1), microtubule-associated protein-2 (MAP-2) and growth-associated protein-43 (GAP-43). mRNA levels peaked at between 8 and 12 h following exposure as determined by competitive reverse transcription polymerase chain reaction (RT-PCR). Increases in neurite growth as measured by axonal length, the total length of dendrites, the number of branches per axon, the total length of branches per axon and the total neurite length were also observed 48 h after glutamate exposure. The increase in T alpha 1, MAP-2 and GAP-43 mRNA levels following glutamate exposure was mediated via both N-methyl-D-aspartate and metabotropic receptor activation. Heparin, which inhibits the neurite growth-promoting effects of PGs in vitro, and heparitinase, which catalyzes the cleavage of heparan sulphate, also inhibited the glutamate-dependent induction of T alpha 1, MAP-2 and GAP-43 mRNA expression and neurite growth when added to culture medium following glutamate exposure. Chondroitin sulphate and chondroitinase AC had no effects on the mRNA levels tested or on neurite growth. Therefore, these studies suggest that neuronal PGs regulated by activation of EAA receptors mediate neuronal growth responses.

Glycosaminoglycans in nerve injury: II. Effects on transganglionic degeneration and on the expression of neurotrophic factors

Injury to the sciatic nerve leads to the transganglionic degeneration of sensory axons and to the induction of neurotrophins and p75 nerve growth factor receptor synthesis by the denervated Schwann cells. Sciatic nerve axotomy caused a marked loss of substance P and of met-enkephalin in the lumbar cord. Substance P immunostaining and pre-proenkephalin mRNA expression were reduced in the dorsal horn layers I and II ipsilaterally to the lesion. Treating rats with low doses (0.25 mg/kg) of heparin or COS 8, a natural glycosaminoglycan mixture with low anticoagulant activity, the peptide loss was prevented and the content increased of about 50% above control values. The effects of COS 8 treatment were also evident on Schwann cells. COS 8 augmented the increase of nerve growth factor, brain-derived neurotrophic factor, and NT-3 mRNA expression in the distal stump of the axotomized sciatic nerve. Therefore, it can be concluded that glycosaminoglycans neuroprotective effects on lesioned sensory axons might have been mediated by the dramatic promotion of neurotrophin synthesis. Although the in vitro studies (Lesma et al.: J Neurosci Res, 1996) suggested also a likely direct effect as extracellular matrix components that is not mediated by trophic factors.

Glycosaminoglycans in nerve injury: 1. Low doses of glycosaminoglycans promote neurite formation

This study has shown that glycosaminoglycans added to the culture medium may affect neurite formation in SH-SY5Y neuroblastoma cells. The most effective glycosaminoglycans are heparin and COS 8, a preparation with low anticoagulant activity. Promotion of neuritogenesis was remarkable at concentrations as low as 10(-8) and 10(-10). When added at 10(-4) M both agents are inhibitory. Chondroitin-4 sulfate, dermatan sulfate, and heparan sulfate were also effective, the doses required were, however, as high as 10(-4) M for promoting and 10(-4) M for inhibiting neuritogenesis. Thereby low doses of glycosaminoglycans promote, while higher doses inhibit neurite formation. The effects were observed when neuritogenesis was promoted in neuroblastoma cultures either by deprivation of serum or by addition of retinoic acid, in the former case neuritogenesis occurred within 48 hr; in the latter, in 14 days. PC12 pheochromocytoma cells neuritogenesis was triggered by adding NGF to the culture medium. We have also observed that glycosaminoglycan supplementation to the culture medium lowered the quantity of NGF required to form neurites by PC12 cells. Glycosaminoglycans at the dose of 10(-8) M allow the formation of PC12 neurites even in presence of 1 ng/ml NGF, a dose that normally is ineffective.

Excitatory amino acid regulation of astrocyte proteoglycans

Activity-dependent enduring change in cellular communication is essential for specific connectivity during development of the nervous system and for adaptive responses of the mature nervous system. Here we report that glutamate activation of excitatory amino acid receptors induces the synthesis and release of proteoglycans (PGs) from fetal hippocampal-astrocytes in dissociated culture. PG synthesis and release are mediated via kainate and metabotropic receptor activation. Glutamate exposure did not regulate the release of a specific family of PG, but glutamate inhibited the synthesis of heparan sulfate (HS) PGs that appeared within the extracellular environment of the astrocyte. Particulate protein kinase C (PKC) activity was increased by glutamate and the PKC activator phorbol 10-myristate 13-acetate produced a dose-dependent increase in PG release. However, glutamate-induced PG release was not blocked by inhibition of PKC activity. These data suggest that PKC activation can lead to PG release, but is not necessary for it. Activity-dependent influences on a class of substrate-bound molecular species with growth-modulatory properties may be involved in spatial regulation of neuronal growth responses produced by excitatory amino acids.

Signal transduction mechanisms subserving activity-dependent release of neuronal proteoglycans

We demonstrate here using dissociated hippocampal neurons that glutamate-induced release of proteoglycans which have been shown to have neurite growth-promoting activity is regulated by serine/threonine kinases of the protein kinase C and calcium/calmodulin type II kinase families, and that the state of phosphorylation of hippocampal neurons is a determinant of the magnitude and duration of the release response. Nitric oxide is also involved in mediating glutamate-induced PG release.

Alterations of the thalamo-cortical system in rats prenatally exposed to ethanol are prevented by concurrent administration of acetyl-L-carnitine

We previously demonstrated that adult rats prenatally exposed to ethanol display permanent damages of thalamo-cortical connections [18,19,33]. Here the effect of simultaneous administration of ethanol and acetyl-L-carnitine has been investigated. Adult animals underwent cortical or thalamic injections of horseradish peroxidase and both anterograde and retrograde thalamic and cortical labeling have been analyzed. Ethanol-induced changes of thalamo-cortical circuits are prevented by concurrent administration of acetyl-L-carnitine. Possible mechanisms underlying this effect are discussed.

Increased cell death and reduced neural crest cell numbers in ethanol-exposed embryos: partial basis for the fetal alcohol syndrome phenotype

Fetal alcohol syndrome (FAS) is characterized by growth retardation, craniofacial malformations, and heart and neural defects; the cellular and molecular mechanism(s) responsible for ethanol's teratogenicity remains unknown. Although the phenotype suggests that prenatal ethanol exposure perturbs neural crest cell development, direct proof that these cells are an in utero target is still lacking. Previous research suggested that cranial neural crest cells are eliminated by ethanol-induced apoptosis. We tested this hypothesis using a chick embryo model of FAS. A single dose of ethanol, chosen to achieve a concentration of 35-42 mg/dl, was injected in ovo at gastrulation and resulted in growth retardation, craniofacial foreshortening, and disrupted hindbrain segmentation. Ethanol exposure enhanced cell death within areas populated by cranial neural crest cells, particularly in the hindbrain and craniofacial mesenchyme. In contrast, control embryos had limited cell death within these regions. Subsequent immunolabeling with neural crest cell-specific antibody revealed that ethanol treatment resulted in fewer neural crest cell numbers, whereas neural crest migration patterns were unaffected by ethanol. These results suggest that prenatal ethanol exposure leads to loss of cranial neural crest cells. Such a loss could result, in part, in the phenotype characteristic of FAS.

Multifaceted alterations of the thalamo-cortico-thalamic loop in adult rats prenatally exposed to ethanol

The thalamo-cortico-thalamic loop was investigated in adult rats exposed to ethanol during the last week of fetal life. Animals underwent either cortical or thalamic injections of lectin-conjugated horseradish peroxidase. Results demonstrate that prenatal exposure to ethanol causes permanent changes in the thalamocortical circuits. Alterations of thalamo-cortical and cortico-thalamic projections are concentrated at the level of axon terminal fields. The most severe thalamic damage is observed in the anterior intralaminar and midline nuclei; crossed cortico-thalamic projections also appear to be severely impaired. In the cortex, the damage to thalamic terminals displays a medio-lateral gradient of increasing severity through sensori-motor areas, with the lateral fields more impaired. Cells of origin of thalamo-cortical and cortico-thalamic projections are less affected by prenatal ethanol exposure: in the thalamus and layer 5 of sensori-motor cortex labeled cells exhibit normal values of areal numeric density. Conversely, cortico-thalamic neurons of layer 6, especially in the lateral agranular sensori-motor field, display smaller values of areal density than those of normal animals. Possible mechanisms underlying the establishment of these abnormalities are discussed.

Modulation of neurite promoting proteoglycans by neuronal differentiation

A human cell line committed to neuronal lineage was used to examine the influence of differentiation on proteoglycan synthesis and function. Where the LA-N-2 cells were stimulated to differentiate towards a phenotype of cholinergic neurons, proteoglycans of the heparan sulphate class increased relative to chondroitin sulphate proteoglycans and displayed more homogeneously shorter glycosaminoglycan chains with increasing degrees of sulphation. The changes were accompanied by increasing potency of the heparan sulphate proteoglycans in neurite growth-promoting activity when immobilized on a laminin substrate. These studies begin to address the role of activity-independent growth and differentiation on the synthesis and release by neurons of neurite growth-promoting proteoglycans. The observations have implications for understanding the role of proteoglycan overexpression and the production of dystrophic neurites in Alzheimer disease.

Differential changes in cell morphology, macromolecular composition and membrane protein profiles of neurons and astrocytes in chronic ethanol treated rats

Cellular morphology, macromolecular composition, (DNA, RNA and Protein content) marker enzyme activities for neurons [neuron specific enolase (NSE)] and astrocytes [glutamine synthetase (GS)] and plasma membrane protein profiles in the bulk isolated neurons and astrocytes from control and ethanol treated rats were studied. One month aged Wistar rats were given ethanol as sole drinking fluid for 10 weeks. Scanning electron microscopy revealed a characteristic cell surface smoothening in astrocytes due to ethanol treatment. DNA levels were unaltered, while RNA and Protein contents were decreased in astrocytes and neurons. Further, 3H-leucine incorporation into proteins was decreased in neurons and astrocytes derived from ethanol treated rats indicating reduced protein synthesis in neurons and astrocytes. GS activity was affected severely suggesting impairment in astrocytic functions. Plasma membrane protein composition was analyzed by 2-D electrophoresis. The analysis indicated several protein defects in the plasma membranes of neurons and astrocytes, which might be involved in 'membrane disorder' during ethanol challenge. 125I-Wheat Germ agglutinin binding studies showed three prominent proteins (160, 116 and 97 kDa) in astrocyte membrane fraction suggesting the possible involvement of N-terminal glycoproteins in altered astrocyte morphology during ethanol ingestion. Impairment in the astrocyte cell functions, protein changes in plasma membrane and cellular morphology studies suggest that astrocytes may be more vulnerable than neurons for ethanol effects.

A central nervous system keratan sulfate proteoglycan: localization to boundaries in the neonatal rat brain

During the development of the central nervous system (CNS), adhesive molecules promote the formation of axonal pathways and appropriate neuronal connections by facilitating cellular interactions. In addition to the interactions that bring neurons together, recent evidence suggests inhibition of neuronal interactions also plays a role by restricting axons to their appropriate pathways and forming boundaries between functional units of the developing CNS. The present study describes the distribution of a recently identified large keratan sulfate proteoglycan, ABAKAN, in the postnatal day 14 (P14) and adult rat brain. In the adult brain ABAKAN appears to be relatively evenly distributed throughout the CNS, while at P14 this proteoglycan is found at high concentrations between different functional units of the neonatal brain. For example, ABAKAN appears to separate different cortical areas and mark the boundaries between thalamic nuclei. In vitro assays demonstrate that this keratan sulfate proteoglycan is a potent inhibitor of neurite growth. The distribution of ABAKAN at P14 and the effects of this keratan sulfate proteoglycan on neurite growth suggest that ABAKAN functions as a molecular barrier to axonal growth in the developing rat brain.

Ethanol enhances neurite outgrowth in primary cultures of rat cerebellar macroneurons

Effects of ethanol on neurite outgrowth and morphometry were investigated in primary cultures of rat cerebella. Cell cultures were prepared from cerebella on embryonic day 17 (E17) for treatment with a series of ethanol concentrations (50, 75, 100, 150 and 200 mM). Ethanol did not reduce neuronal survival or attachment to the substrate at any of the concentrations that were used. Treatment with 75 mM ethanol significantly enhanced neurite outgrowth. Measurements from dissociated cultures exposed to 75 mM ethanol immediately after plating showed a significant increase in the percentage of neurite-bearing cells after 8 and 24 h in vitro. Measurements of the area and perimeter of neuronal cell bodies in dissociated cell cultures showed that the cell bodies of ethanol-treated neurons were also larger than those of control neurons. Ethanol was also associated with significant increases in the total neuritic length per cell and in the length of the longest neurite in each cell. The mean number of neurite branches was also greater in the ethanol-treated neurons. Measurements from suspension cell cultures, in which dissociated cells were suspended overnight in the presence of 75 mM ethanol prior to plating, corroborated these results. These findings suggest that ethanol may have distinct effects on neurite initiation and outgrowth and branching. The cellular mechanisms involved and the functional significance of these effects are currently not known. The present results also indicated that high concentrations of ethanol (150-200 mM) and long periods of exposure (4-7 days) were required to produce toxic effects on neurons and glial cells in this system.

Effects of 4-deoxy-L-threo-pentose, a novel carbohydrate, on neural cell proteoglycan synthesis and function

A novel carbohydrate, 4-deoxy-L-threo-pentose (4-deoxyxylose), was synthesized by way of reductive dechlorination of a chlorodeoxy sugar. This carbohydrate, an analogue of xylose which is required for the initiation of glycosaminoglycan (GAG) synthesis, was used to explore the function of GAG side chains in neurite outgrowth on a laminin substrate. 4-Deoxyxylose inhibited the incorporation of 35SO4 into the GAGs of neuronal and astrocytic proteoglycans, with no effect being seen on the incorporation of [3H]glucosamine into proteoglycan. Direct analysis of the heparan sulphate fraction from such cells using nitrous acid digestion confirmed that the GAGs were undersulphated. No inhibition of either 35SO4 or [3H]glucosamine incorporation was observed in primary mouse hepatocytes exposed to 4-deoxyxylose. 4-Deoxyxylose produced a direct dose-dependent inhibition of neurite outgrowth by sensory neurons, and medium conditioned by neurons or astrocytes in the presence of 4-deoxyxylose displayed less laminin-complexed neurite-promoting activity than medium conditioned in its absence. These data suggest that 4-deoxyxylose inhibits neurite outgrowth by altering the sulphation of the GAGs of heparan sulphate proteoglycans.

Effect of cocaine, ethanol or nicotine on ornithine decarboxylase activity in early chick embryo brain

Fetal drug exposure causes multiple deficits in the developing child. For both humans and animal models, the single most common drug-related problem is fetal growth suppression. This defect is associated with significant perinatal morbidity and mortality and may also be related to significant behavioral problems appearing later in life. Studies focussed on the molecular mechanism of fetal drug effects in placental models are complicated by multiple interactions of the drug with mother, placenta and fetus. Using early (76-168 h) chick embryos as a non-placental model, and three common drugs of abuse (nicotine, ethanol and cocaine) it was found that each drug suppressed the peak in fetal brain ornithine decarboxylase (ODC) activity that normally occurs at 120 h of development. For each drug, the decrease in ODC activity at 120 h was followed by a small but significant increase in ODC. Thus, although the drug-treated embryos were smaller in size, they appeared to be undergoing compensatory growth and, in fact, became equal in weight to the vehicle-treated animals, if allowed to hatch.

Influence of N-linked oligosaccharides on the processing and neurite-promoting activity of proteoglycans released by neurons in vitro

Inhibitors of enzymes involved in processing of N-linked oligosaccharides were used to examine biosynthesis and the neurite-promoting activity of proteoglycans produced by and released from dissociated chick embryo spinal cord neurons in vitro. In the cell compartment and in conditioned medium both castanospermine and swainsonine inhibited 3H-glucosamine incorporation into glycoprotein but only castanospermine reduced 3H-glucosamine incorporation into heparan sulphate and chondroitin sulphate proteoglycans. All of the neurite-promoting activity of neuron-conditioned medium that complexed to laminin was associated with heparan sulphate proteoglycans as determined by heparitinase digestion. Neuron-conditioned medium prepared in the presence of castanospermine displayed a 38 +/- 6% (mean +/- SD) reduction in 3H-glucosamine incorporation into heparan sulphate proteoglycans and a 30 +/- 5% reduction in substrate-attached neurite-promoting activity compared to control conditioned medium and to conditioned medium prepared in the presence of swainsonine. When neurons were coincubated with castanospermine, neurite growth on a laminin substrate was 50 +/- 10% of control growth or growth in the presence of swainsonine. However, when neuron-conditioned medium was used to pretreat the laminin substrate the inhibitory effect on neurite growth produced by castanospermine coincubation was reversed. Influences on neuronal processing of N-linked oligosaccharides alter neurite growth directly and also alter the neurite-promoting activity of neuron-conditioned medium by inhibiting the synthesis of heparan sulphate proteoglycans. These studies provide further evidence for an autocrine role for heparan sulphate proteoglycans in neurite growth.

Ethanol enhances growth factor-induced neurite formation in PC12 cells

Ethanol can injure the nervous system by disturbing the growth of neural processes. PC12 cells, which form neurites in response to nerve growth factor (NGF), fibroblast growth factor (FGF), and cAMP analogues, were used to study mechanisms by which ethanol alters process outgrowth. Ethanol potentiated NGF-induced neurite outgrowth in cells cultured on different substrata and in serum-containing or defined medium. Ethanol did not increase NGF receptor binding or internalization of NGF. Neurite outgrowth induced by basic FGF was also increased by ethanol but outgrowth induced by forskolin was not. Ethanol potentiated NGF-induced expression of Thy-1, but not of neural cell adhesion molecule (N-CAM), indicating that some, but not all actions of NGF are enhanced by ethanol. In some brain regions, chronic exposure to ethanol increases the growth of dendrites. This has been explained as a compensatory response of surviving neurons to the loss of neighboring cells, and not as a direct effect of ethanol. The present findings suggest that, in some cells, ethanol directly promotes growth factor-mediated neurite formation. This could harm the nervous system by disturbing the balanced development and organization of synapses.

Core protein of chondroitin sulfate proteoglycan promotes neurite outgrowth from cultured neocortical neurons

Chondroitin sulfate proteoglycan (CS-PG) was purified from rat brain and examined for its effect on neurite outgrowth in primary cultures of embryonic rat neocortical neurons. Neurite outgrowth was increased in culture wells coated with CS-PG. The core protein and glycosaminoglycan (GAG) prepared from the CS-PG were also examined for neurite-promoting activity. The activity was observed in culture wells coated with the core protein but not with GAG. These results suggest that CS-PG stimulates neurite outgrowth from the cultured neurons via its core protein.