The neuronal growth-associated protein GAP-43 interacts with rabaptin-5 and participates in endocytosis

Structural plasticity of nerve cells is a requirement for activity-dependent changes in the brain. The growth-associated protein GAP-43 is thought to be one determinant of such plasticity, although the molecular mechanism by which it mediates dynamic structural alterations at the synapse is not known. GAP-43 is bound by calmodulin when Ca2+ levels are low, and releases the calmodulin when Ca2+ levels rise, suggesting that calmodulin may act as a negative regulator of GAP-43 during periods of low activity in the neurons. To identify the function of GAP-43 during activity-dependent increases in Ca2+ levels, when it is not bound to calmodulin, we sought proteins with which GAP-43 interacts in the presence of Ca2+. We show here that rabaptin-5, an effector of the small GTPase Rab5 that mediates membrane fusion in endocytosis, is one such protein. We demonstrate that GAP-43 regulates endocytosis and synaptic vesicle recycling. Modulation of endocytosis by GAP-43, in association with rabaptin-5, may constitute a common molecular mechanism by which GAP-43 regulates membrane dynamics during its known roles in activity-dependent neurotransmitter release and neurite outgrowth.     

Immunocytochemical localization of a growth-associated protein (GAP-43) in rat adrenal gland

We have localized at light and electron-microscopic level the growth-associated protein GAP-43 in adrenal gland using single and double labelling immunocytochemistry. Clusters of GAP-43-immunofluorescent chromaffin cells and many immunofluorescent fibres were observed in the medulla. GAP-43-immunoreactive fibres also formed a plexus under the capsule, crossed the cortex and ramified in the zona reticulata. Double labelled sections showed the coexpression of GAP-43 with a subpopulation of tyrosine hydroxylase- and of dopamine-beta-hydroxylase-immunoreactive chromaffin cells. Dual colour immunofluorescence for GAP-43 and calcitonin gene-related peptide (CGRP) revealed that some of the GAP-43-immunoreactive fibres also express CGRP. Pre-embedding electron microscopy showed GAP-43 immunoreactivity associated with the plasma membranes and cytoplasm of noradrenaline-producing chromaffin cells, and with processes of nonmyelin-forming Schwann cells. Immunoreactive unmyelinated axons and terminals were also observed. The immunostained terminals made symmetrical synaptic contacts with chromaffin cells. Immunoreactive unmyelinated fibres and small terminals were present in the cortex. Our results show that GAP-43 is expressed in noradrenergic chromaffin cells and in various types of nerve fibres that innervate the adrenal. Likely origins for these fibres include preganglionic sympathetic fibres which innervate chromaffin cells, postganglionic sympathetic fibres in the cortex, and CGRP containing sensory fibres.     

Expression and interconversion of neuron-specific enolase in patient sera and extracts from small-cell lung cancer cells

The isoforms of gamma-enolase were characterized in serum from patients with small-cell lung cancer (SCLC) and in extracts from SCLC cell lines and malignant melanoma tumor tissue. Large variations in the expression of the 3 gamma-isoforms of enolase were observed. These forms probably represent the homodimeric gamma gamma-enolase, the heterodimeric alpha gamma-enolase and the monomeric forms of gamma-enolase. Only the dimeric forms are enzymatically active. The predominant gamma-enolase in the cell lines is the heterodimeric alpha gamma-enolase. The SCLC cell lines can be divided into two groups: one with negligible gamma gamma-enolase expression and considerable amounts of the nonneuronal alpha alpha-enolase and a second group with a large fraction of gamma gamma-enolase concomitant with a low expression of alpha-enolase. Similar patterns are observed in tissue extracts from malignant melanoma. When changing buffer conditions by increasing the ionic strength and decreasing the Mg2+ concentration, interconversions between the isozymes occur. In contrast to the predominant alpha gamma-enolase in extracts from cell lines, the multiple forms of gamma-enolase in serum might be caused by a subunit exchange facilitated by the low Mg2+ concentration in plasma. However, there seems to be a stable equilibrium between the isoforms in undiluted patient serum. The induction of subunit exchange by perturbation in ionic strength and/or Mg2+ concentration indicates a need for caution when choosing diluents for use in assays for neuron-specific enolase.     

Expression of high-affinity neuronal and glial glutamate transporters in the rat optic nerve

Recent studies have revealed that a dynamic axon-glial signaling occurs in the rat optic nerve, which is devoid of synapses. This interaction is postulated to be mediated by non-vesicular release of glutamate via a reversal of high-affinity glutamate transporters. Here we examined the expression of glial glutamate transporters (GLAST and GLT-1) and a neuronal transporter (EAAC1) in the rat optic nerve. RT-PCR analysis revealed the presence of mRNAs for GLT-1 and GLAST, but not EAAC1. RNase protection assays showed that of the two glial transporters, mRNA for GLAST was expressed at much higher level than was GLT-1. A similar expression pattern was found in primary astrocyte culture cells. GLAST mRNA level in the optic nerve was comparable to that in the cerebellum. Developmentally, GLAST mRNA level was highest at P2 and dropped slightly by adulthood. Nerve transection resulted in little or no change in mRNA levels for GLAST and GLT-1 assayed at 4 to 14 days post-transection, but GLAST mRNA level was decreased at 64 days. Western blot analysis revealed that the rat optic nerve showed immunoreactivity to antibodies against GLT-1, GLAST, and EAAC1. In conclusion, we suggest that glial and neuronal transporters are present in the rat optic nerve, where dynamic axon-glial interaction has been known to occur. In particular, the unusually high level of expression of GLAST in the optic nerve suggests a possible role for this glial transporter in protecting optic nerves from neurotoxicity during postnatal development.     

Gonadal steroids modulate the growth-associated protein GAP-43 (neuromodulin) mRNA in postnatal rat brain

Gonadal steroid hormone action during early postnatal life determines the growth and connectivity of certain neuronal populations in the hypothalamus. The results of recent studies indicate that steroid hormones modulate the growth-associated protein GAP-43 mRNA in the adult rodent hypothalamus. Since GAP-43 is concentrated in axonal growth cones and has been implicated in axonal elongation and synaptogenesis, the present study investigated the effect of various gonadal hormonal conditions on GAP-43 mRNA levels in postnatal rat brain. On postnatal day 1, male rats were castrated or sham-operated and injected with sesame oil. Additional intact female rats were also injected with oil, while a group of female pups were injected with testosterone propionate. On postnatal day 6, brains were frozen and 16-microns cryostat sections processed and hybridized with a 35S-labeled antisense riboprobe complimentary to GAP-43 mRNA. Slide-mounted sections were stringently washed, apposed to X-ray film and then dipped in liquid emulsion. Evaluation of slide and film autoradiograms revealed an extensive presence of GAP-43 mRNA in the medial preoptic nucleus, bed nucleus of the stria terminalis and cerebral cortex, while the intensity of hybridization signal in other brain regions including the striatum was low. Quantitative assessment of GAP-43 mRNA in the medial preoptic area revealed that the level of GAP-43 mRNA was highest in the sham-operated male, attenuated after male castration, low in the intact female and markedly augmented in the testosterone-treated female. The pattern of change in the bed nucleus of the stria terminalis and laminae II and III of the frontal cortex was similar to that observed in the preoptic area. The changes in hybridization signal were positively correlated with changes in serum testosterone levels as determined by RIA. The results of these studies indicate that GAP-43 mRNA levels in the medial preoptic area, bed nucleus of the stria terminalis and cerebral cortex are sexually dimorphic and modulated by changes in gonadal steroid hormone levels. The results further suggest that the differential regulation of GAP-43 mRNA by sex steroids in the male and female postnatal brain may influence the phenotype of forebrain neuronal circuitry and thereby determine the phenotype of adult neuronal function.     

Ca125 and neuron-specific enolase (NSE) as tumour markers for intra-abdominal desmoplastic small round-cell tumours

We have established a method for quantifying serum 16-dehydropregnenolone (3beta-hydroxy-5,16-pregnadien-20-one) sulfate (16-DHP S) by GC-MS. The levels of 16-DHP S at birth were compared in infants grouped as extremely immature (gestational age: 22-27 weeks), pre-term (gestational age: 28-36 weeks) and full-term (gestational age: 37-41 weeks). The average of the serum concentration of 16-DHP S in full-term infants was 0.172+/-0.104 micromol/l (n=10, mean+/-S.D.) which was significantly higher than the levels of the extremely immature (0.106+/-0.054 micromol/l, n=14, p<0.05) and pre-term infants (0.088+/-0.066 micromol/l, n=33, p<0.01). However, 16-DHP S in sera from normal adults (age 22-73 years, n=40) was not detected. We investigated chronological changes in serum levels of 16-DHP S during the early neonatal period. In extremely immature and pre-term infants, these levels were significantly higher at 2-7 d than those of 16-DHP S at day 0 (p<0.001). The levels at 8-18 d were still significantly higher than those at day 0 (p<0.05), but in full-term infants, these levels did not change at days 0 and 2-7. These results indicate that 16-DHP S is a steroid specific to fetuses and neonates and the involution of the fetal adrenal gland does not affect its serum levels in the early neonatal period.     

Hippocampal and cortical growth-associated protein-43 messenger RNA in schizophrenia

Growth-associated protein-43 is involved in maturational and plasticity-associated processes, and changes in growth-associated protein-43 expression are a marker of altered plasticity following experimental and neuropathological lesions. Using in situ hybridization, we have investigated growth-associated protein-43 mRNA in the medial temporal lobe and cerebral cortex in 11 normal subjects and 11 matched subjects with schizophrenia, a disorder in which perturbed neurodevelopment and aberrant plasticity are implicated. In the schizophrenia group, growth-associated protein-43 messenger RNA was decreased in the medial temporal lobe, primary visual cortex and anterior cingulate gyrus, but was unaltered in the superior temporal and dorsolateral prefrontal cortices. Correlations of growth-associated protein-43 messenger RNA signal between areas were stronger and more numerous in the schizophrenics than in the controls, suggesting a more global regulation of growth-associated protein-43 expression. Finally, the ratio of growth-associated protein-43 messenger RNA to synaptophysin messenger RNA--a putative index of the production of new synapses--was decreased in the medial temporal lobe in the schizophrenics. Our findings imply that neuronal plasticity as indexed by growth-associated protein-43 expression is impaired, and perhaps aberrantly regulated, in schizophrenia. The data support the emerging view that the disease pathophysiology is one which affects the hippocampal and cortical circuitry and that the abnormalities are reflected in the altered expression of specific neuronal genes.     

The protein tyrosine phosphatase SHP-2 is expressed in glial and neuronal progenitor cells, postmitotic neurons and reactive astrocytes

In this study we examined the distribution and developmental profile of the src homology 2 (SH2) domain-containing protein tyrosine phosphatase SHP-2 in the mouse brain. We found that SHP-2 is present in both mitotically active and postmitotic cells in the forebrains of embryonic day 12 (E12) mice. In a developmental study extending from embryonic day 12 to adulthood, Western blotting analysis demonstrated equivalent levels of SHP-2 protein at all of the ages examined. Expression of SHP-2 paralleled the level of enzymatic activity at the different developmental periods. In the adult brain SHP-2 was restricted to diverse classes of neurons, while the majority of glial cells did not express detectable levels of protein. However, reactive astrocytes in response to an ischemic brain injury showed SHP-2 immunolabelling. Our data suggest that SHP-2 may play a role in pathways of neuronal and glial progenitor cells, in a broad spectrum of neuronal responses in the adult brain and in the gliotic response to the injury.     

Neuronal damage and plasticity identified by microtubule-associated protein 2, growth-associated protein 43, and cyclin D1 immunoreactivity after focal cerebral ischemia in rats

BACKGROUND AND PURPOSE: An objective of therapeutic intervention after cerebral ischemia is to promote improved functional outcome. Improved outcome may be associated with a reduction of the volume of cerebral infarction and the promotion of cerebral plasticity. In the developing brain, neuronal growth is concomitant with expression of particular proteins, including microtubule-associated protein 2 (MAP-2), growth-associated protein 43 (GAP-43), and cyclin D1. In the present study we measured the expression of select proteins associated with neurite damage and plasticity (MAP-2 and GAP-43) as well as cell cycle (cyclin D1) after induction of focal cerebral ischemia in the rat. METHODS: Brains from rats (n=28) subjected to 2 hours of middle cerebral artery occlusion and 6 hours, 12 hours, and 2, 7, 14, 21, and 28 days (n=4 per time point) of reperfusion and control sham-operated (n=3) and normal (n=2) rats were processed by immunohistochemistry with antibodies raised against MAP-2, GAP-43, and cyclin D1. Double staining of these proteins for cellular colocalization was also performed. RESULTS: Loss of immunoreactivity of both MAP-2 and GAP-43 was observed in most damaged neurons in the ischemic core. In contrast, MAP-2, GAP-43, and cyclin D1 were selectively increased in morphologically intact or altered neurons localized to the ischemic core at an early stage (eg, 6 hours) of reperfusion and in the boundary zone to the ischemic core (penumbra) during longer reperfusion times. CONCLUSIONS: The selective expressions of the neuronal structural proteins (MAP-2 in dendrites and GAP-43 in axons) and the cyclin D1 cell cycle protein in neurons observed in the boundary zone to the ischemic core are suggestive of compensatory and repair mechanisms in ischemia-damaged neurons after transient focal cerebral ischemia.     

Modulation of neuronal activity by glial cells in the retina

Glial-neuronal communication was studied by monitoring the effect of intercellular glial Ca2+ waves on the electrical activity of neighboring neurons in the eyecup preparation of the rat. Calcium waves in astrocytes and Müller cells were initiated with a mechanical stimulus applied to the retinal surface. Changes in the light-evoked spike activity of neurons within the ganglion cell layer occurred when, and only when, these Ca2+ waves reached the neurons. Inhibition of activity was observed in 25 of 53 neurons (mean decrease in spike frequency, 28 +/- 2%). Excitation occurred in another five neurons (mean increase, 27 +/- 5%). Larger amplitude Ca2+ waves were associated with greater modulation of neuronal activity. Thapsigargin, which reduced the amplitude of the glial Ca2+ increases, also reduced the magnitude of neuronal modulation. Bicuculline and strychnine, inhibitory neurotransmitter antagonists, as well as 6-Nitro-7-sulphamoylbenzo[f]quinoxaline-2,3-dione (NBQX) and D(-)-2-amino-7-phosphonoheptanoic acid (D-AP7), glutamate antagonists, reduced the inhibition of neuronal activity associated with glial Ca2+ waves, suggesting that inhibition is mediated by inhibitory interneurons stimulated by glutamate release from glial cells. The results suggest that glial cells are capable of modulating the electrical activity of neurons within the retina and thus, may directly participate in information processing in the CNS.     

Gonadal steroid regulation of growth-associated protein GAP-43 mRNA expression in axotomized hamster facial motor neurons

Treatment with testosterone propionate (TP) after nerve injury is known to accelerate both the rate of axonal regeneration and functional recovery from facial paralysis in the adult male hamster. Peripheral nerve injury is also known to increase the expression of a 43 kilodalton growth-associated protein (GAP-43). In the intact brain, GAP-43 expression is affected by gonadal steroids. We thus postulated that steroidal modulation of GAP-43 gene expression may be a component of the neurotrophic action of TP in regenerating neurons. This issue was examined in hamster facial motor neurons (FMN) which contain androgen receptors and which have been shown to respond to exogenous steroids in a number of previous studies. Castrated adult male hamsters were subjected to right facial nerve transection and treated with either TP via subcutaneous hormone capsule implants, or left untreated (no hormone replacement). At post-injury/treatment times of 0.25, 2, 4, 7, and 14 d, the brain stem regions were harvested, cryostat sections were collected through the facial motor nucleus, and in situ hybridization was done using a 33P-labeled GAP-43 cDNA probe. Quantitative analysis of the autoradiograms by computer assisted grain counting revealed that axotomy produced a dramatic increase in GAP-43 mRNA levels in FMN by 2 d post-axotomy and that this increase remained through 14 d post-injury in both the TP-treated and the untreated group. In the nonhormone-treated group, there was a statistically significant dip in GAP-43 mRNA levels in FMN at 7 d post-operative, relative to 4 d post-operative levels. TP-treatment prevented this transient decline in GAP-43 mRNA levels in axotomized FMN.     

Mapping of antigenic sites in human neuron-specific enolase by expression subcloning

Human serum neuron-specific enolase (NSE) is a marker of neurons and of small-cell carcinoma of the lung; improved immunoassays of NSE remain an important goal. Here, we used overlapping complementary DNA (cDNA) clones for reconstruction to express full-length recombinant NSE, and also to express a set of cloned subfragments through the prokaryotic expression vectors pUEX and pUBEX. Subfragments expressed as fusion proteins were used to characterize immunogenic and antigenic regions and epitopes and, expressed as affinity matrices, to derive purified, fractionated polyclonal antibodies. NSE epitope data can be visualized with yeast enolase-1 crystal structure coordinates: The two protein sequences align almost perfectly and are 61% identical. This approach demonstrates the complementarity of cDNA expression with techniques of polyclonal antiserum and monoclonal antibody production and with chemical peptide synthesis in the refinement of immunodiagnostic reagents.     

Alterations in ultrastructural localization of growth-associated protein-43 (GAP-43) in periodontal Ruffini endings of rat molars during experimental tooth movement

It is known that orthodontic forces induce discomfort and/or abnormal sensation after application of an orthodontic appliance in patients, suggesting the adaptation of periodontal neural elements to environmental changes. However, no morphological data have been provided. The present study investigated, by immunoelectron microscopy, the localization of growth-associated protein-43 (GAP-43) in periodontal Ruffini endings in rat molars during experimental tooth movement. In the untreated control group, immunoelectron microscopy demonstrated that GAP-43-like immunoreactivity in the Ruffini endings was confined to the Schwann sheaths around the axon terminals, and was in neither the cell bodies of terminal Schwann cells nor the axon terminals themselves. Immunoelectron microscopic observation revealed alterations in the localization of GAP-43-like immunoreactivity in the periodontal Ruffini endings during experimental tooth movement. After 1 day of treatment, the cell bodies of the terminal Schwann cells associated with Ruffini endings appeared to contain immunoreaction products for GAP-43, and retained GAP-43-like immunoreactivity during tooth movement. From 5 to 7 days, a major population of the axoplasm of the periodontal Ruffini endings, which was immunonegative in control, filled the GAP-43 immunoreactions, showing a tendency to decrease in number later, and disappeared completely at 14 days. These findings suggest that orthodontic forces easily induce the remodeling of the mechanoreceptive Ruffini endings as well as the active tissue remodeling in a close relationship. Since the ultrastructural localization of GAP-43-like immunoreactivity was drastically changed in the Ruffini endings during tooth movement, GAP-43 functions as one of the key molecules in the remodeling of mechanoreceptive Ruffini endings during tooth movement.     

Ganglioside and neurotrophic growth factor interactions in retinal neuronal and glial cells

Ganglioside (GG) and neurotrophic growth factor (GF) interactions in retinal neuronal and glial cells have been very little studied. Rat retinas were mechanically separated into outer (photoreceptor or PR) and inner (other neurons, IR) halves by planar vibratome sectioning and retinal Müller glial (RMG) cells were isolated and cultured according to previously published methods. The distribution on a percent molar basis of individual GG was different between the two halves: PR were dominated by GD3 (48% total GG) and contained only trace amounts (< 4%) of complex species (GT1b, GQ); IR was more typical of mature brain tissue, exhibiting substantial amounts (approximately 25%) of more complex GG. The GG profile of RMG cells was also simple, dominated by GM3 (60%) and GD1a (20%). A single addition to the medium of 500 pM bFGF or EGF for 48 hr to cultured RMG cells led to significant increases in total GG levels of 30-40%. Such treatments by both growth factors induced increases in GM3, whereas longer exposure (96 hr) of confluent RMG to these factors additionally stimulated synthesis of more complex GG. Incubations of RMG with [3H]-glucosamine showed that GG synthesis was 2-fold stimulated by growth factors. We also tested the effect of GM3 on one of the bFGF receptor transduction pathways, namely PI-3 kinase activation. To our knowledge these data constitute the first demonstration of neurotrophic factor stimulation of GG levels in cells of CNS in vitro. Such complex interactions may have particularly important consequences for neural physiopathology.     

Growth-associated protein (GAP-43) in terminal Schwann cells of rat Pacinian corpuscles

Growth-associated protein (GAP-43) immunoreactivity was examined in Pacinian corpuscles of intact neonatal and adult rats as well as after denervation and reinnervation in adult rats. All immature Pacinian corpuscles were GAP-43 immunoreactive (GAP-43+) in their inner cores while only 46 +/- 5.6% of the mature corpuscles exhibited GAP-43+ inner cores. The frequency of GAP-43+ inner cores increased to 90 +/- 7.2% after their permanent denervation. The expression of GAP-43 in the inner cores was reduced by contact with regrowing axons, but 38 +/- 5.3% of Pacinian corpuscles retained GAP-43+ in their inner cores following reinnervation. These results indicate that GAP-43 regulation is not confined only to axons but also involves some extra-axonal cues, and support a role for this protein in the process formation by terminal Schwann cells.     

Localization of neuronal and glial glutamate transporters

The cellular and subcellular distributions of the glutamate transporter subtypes EAAC1, GLT-1, and GLAST in the rat CNS were demonstrated using anti-peptide antibodies that recognize the C-terminal domains of each transporter. On immunoblots, the antibodies specifically recognize proteins of 65-73 kDa in total brain homogenates. Immunocytochemistry shows that glutamate transporter subtypes are distributed differentially within neurons and astroglia. EAAC1 is specific for certain neurons, such as large pyramidal cortical neurons and Purkinje cells, but does not appear to be selective for glutamatergic neurons. GLT-1 is localized only to astroglia. GLAST is found in both neurons and astroglia. The regional localizations are unique to each transporter subtype. EAAC1 is highly enriched in the cortex, hippocampus, and caudate-putamen and is confined to pre- and postsynaptic elements. GLT-1 is distributed in astrocytes throughout the brain and spinal cord. GLAST is most abundant in Bergmann glia in the cerebellar molecular layer brain, but is also present in the cortex, hippocampus, and deep cerebellar nuclei.     

Development and differentiation of glial precursor cells in the rat cerebellum

The development and differentiation of bipotential glial precursor cells has been studied extensively in tissue culture, but little is known about the distribution and fate of these cells within intact animals. To analyze the development of glial progenitor cells in the developing rat cerebellum, we utilized immunofluorescent, immunocytochemical, and autoradiographic techniques. Glial progenitor cells were identified with antibodies against the NG2 chondroitin-sulfate proteoglycan, a cell-surface antigen of 02A progenitor cells in vitro, and the distribution of this marker antigen was compared to that of marker antigens that identify immature astrocytes, mature astrocytes, oligodendrocyte precursors, and mature oligodendrocytes. Cells expressing the NG2 antigen appeared in the cerebellum during the last 3-4 days of embryonic life. Over the first 10 days of postnatal life, the NG2-labeled cells incorporated 3H-thymidine into their nuclei and their total number increased. At all ages examined, the NG2-labeled cells did not contain either vimentin-like or glial fibrillary acidic protein (GFAP)-like immunoreactivity, suggesting that they do not develop along an astrocytic pathway. NG2-labeled cells of embryonic animals expressed GD3 ganglioside antigens, a property of oligodendrocyte precursors, whereas NG2-positive cells of postnatal animals did not express GD3 immunoreactivity. Nevertheless, the NG2-labeled cells of the nascent white matter expressed oligodendrocyte-specific marker antigens. Cells lying outside of the white matter continued to express the NG2 antigen. In adult animals, the NG2-labeled cells incorporated 3H-thymidine. Glial cells isolated from adult animals and grown in tissue culture express the NG2 antigen and display the phenotypic plasticity characteristic of 02A progenitor cells. These findings demonstrate that a population of glial progenitor cells is extensive within both young and adult animals.     

Comparison of the developmental effects of two mercury compounds on glial cells and neurons in aggregate cultures of rat telencephalon

A three-dimensional cell culture system was used as a model to study the influence of low levels of mercury in the developing brain. Aggregating cell cultures of fetal rat telencephalon were treated for 10 days either during an early developmental period (i.e., between days 5 and 15 in vitro) or during a phase of advanced maturation (i.e., between days 25 and 35) with mercury. An inorganic (HgCl2) and an organic mercury compound (monomethylmercury chloride, MeHgCl) were examined. By monitoring changes in cell type-specific enzymes activities, the concentration-dependent toxicity of the compounds was determined. In immature cultures, a general cytotoxicity was observed at 10(-6) M for both mercury compounds. In these cultures, HgCl2 appeared somewhat more toxic than MeHgCl. However, no appreciable demethylation of MeHgCl could be detected, indicating similar toxic potencies for both mercury compounds. In highly differentiated cultures, by contrast, MeHgCl exhibited a higher toxic potency than HgCl2. In addition, at 10(-6) M, MeHgCl showed pronounced neuron-specific toxicity. Below the cytotoxic concentrations, distinct glia-specific reactions could be observed with both mercury compounds. An increase in the immunoreactivity for glial fibrillary acidic protein, typical for gliosis, could be observed at concentrations between 10(-9) M and 10(-7) M in immature cultures, and between 10(-8) M and 3 x 10(-5) M in highly differentiated cultures. A conspicuous increase in the number and clustering of GSI-B4 lectin-binding cells, indicating a microglial response, was found at concentrations between 10(-10) M and 10(-7) M. These development-dependent and cell type-specific effects may reflect the pathogenic potential of long-term exposure to subclinical doses of mercury.     

Nerve growth factor contributes to the up-regulation of growth-associated protein 43 and preprotachykinin A messenger RNAs in primary sensory neurons following peripheral inflammation

Peripheral inflammation induced in adult rats by an intraplantar injection of complete Freund's adjuvant results in a rapid (6 h) increase in the expression of the messenger RNAs for the neuronal growth-associated protein 43 and for preprotachykinin A, the precursor for substance P, in dorsal root ganglion sensory neurons innervating the inflamed area. This increase peaks at 48 h and then declines by five days. The changes are present in the dorsal root ganglion cells innervating the inflamed skin (lumbar 4 or 5) but no elevation was found in the third lumbar dorsal root ganglion which innervates neighbouring non-inflamed skin. The increased growth-associated protein 43 messenger RNA in the dorsal root ganglion is followed by a marked increase in growth-associated protein 43-like immunoreactive fibres in the epidermis of the inflamed skin. Systemic administration of neutralizing anti-nerve growth factor antibodies immediately prior to the inflammation prevents the increase in growth-associated protein 43 and preprotachykinin A messenger RNAs in the sensory neurons. A subcutaneous injection of nerve growth factor (200 ng) into the hindpaw elevates preprotachykinin A but not growth-associated protein 43 messenger RNA in the fourth lumbar dorsal root ganglion 48 h post-injection and this could be prevented by co-administration of the anti-nerve growth factor serum. The production of nerve growth factor in inflamed target tissues leads to alterations in the phenotype of responsive adult primary sensory neurons which include a change in the levels of a growth-related protein and a peptide neuromodulator.(ABSTRACT TRUNCATED AT 250 WORDS)