Transforming growth factor alpha promotes sequential conversion of mature astrocytes into neural progenitors and stem cells.

An instability of the mature cell phenotype is thought to participate to the formation of gliomas, primary brain tumors deriving from astrocytes and/or neural stem cells. Transforming growth factor alpha (TGFalpha) is an erbB1 ligand overexpressed in the earliest stages of gliomas, and exerts trophic effects on gliomal cells and astrocytes. Here, we questioned whether prolonged TGFalpha exposure affects the stability of the normal mature astrocyte phenotype. We first developed astrocyte cultures devoid of residual neural stem cells or progenitors. We demonstrate that days of TGFalpha treatment result in the functional conversion of a population of mature astrocytes into radial glial cells, a population of neural progenitors. TGFalpha-generated radial glial cells support embryonic neurons migration, and give birth to cells of the neuronal lineage, expressing neuronal markers and the electrophysiological properties of neuroblasts. Lengthening TGFalpha treatment to months results in the delayed appearance of cells with neural stem cells properties: they form floating cellular spheres that are self-renewing, can be clonally derived from a single cell and differentiated into cells of the neuronal lineage. This study uncovers a novel population of mature astrocytes capable, in response to a single epigenetic factor, to regress progressively into a neural stem-like cell stage via an intermediate progenitor stage.

Transforming growth factor alpha acts as a gliatrophin for mouse and human astrocytes.

Astrocyte death has been implicated in several neuropathological diseases, but the identification of molecules susceptible of promoting astrocyte survival has been elusive. We investigated whether transforming growth factor alpha (TGFalpha), an erbB1/EGFR ligand, which promotes glioma progression and affects astrocyte metabolism at embryonic and adult stages, regulates astrocyte survival. Primary serum-free astrocyte cultures from post-natal mouse and fetal human cortices were used. Transforming growth factor alpha protected both species of astrocytes from staurosporine-induced apoptosis. In serum-free medium, mouse astrocytes did not survive beyond 2 months while TGFalpha-treated astrocytes survived up to 12 months. Transforming growth factor alpha also promoted long-term survival of human astrocytes. We additionally extended TGFalpha proliferative effects to human astrocytes. After 3 days of permanent application, TGFalpha induced a major downregulation of both erbB1 and erbB2. This downregulation did not impair the functional activation of the receptors, as ascertained by their tyrosine phosphorylation and the continuous stimulation of both ERK/MAPK and PI3K/Akt pathways up to 7 days, the longest time examined. The full cellular effects of TGFalpha required activation of both transduction pathways. Enhanced proliferation and survival thus define TGFalpha as a gliatrophin for mammalian astrocytes. These results demonstrate that in normal, non-transformed astrocytes, sustained and functional erbBs activation is achieved without bypassing ligand-induced receptors downregulation.

Galpha(olf) levels are regulated by receptor usage and control dopamine and adenosine action in the striatum.

In the striatum, dopamine D(1) and adenosine A(2A) receptors stimulate the production of cAMP, which is involved in neuromodulation and long-lasting changes in gene expression and synaptic function. Positive coupling of receptors to adenylyl cyclase can be mediated through the ubiquitous GTP-binding protein Galpha(S) subunit or through the olfactory isoform, Galpha(olf), which predominates in the striatum. In this study, using double in situ hybridization, we show that virtually all striatal efferent neurons, identified by the expression of preproenkephalin A, substance P, or D(1) receptor mRNA, contained high amounts of Galpha(olf) mRNA and undetectable levels of Galpha(s) mRNA. In contrast, the large cholinergic interneurons contained both Galpha(olf) and Galpha(s) transcripts. To assess the functional relationship between dopamine or adenosine receptors and G-proteins, we examined G-protein levels in the striatum of D(1) and A(2A) receptor knock-out mice. A selective increase in Galpha(olf) protein was observed in these animals, without change in mRNA levels. Conversely, Galpha(olf) levels were decreased in animals lacking a functional dopamine transporter. These results indicate that Galpha(olf) protein levels are regulated through D(1) and A(2A) receptor usage. To determine the functional consequences of changes in Galpha(olf) levels, we used heterozygous Galpha(olf) knock-out mice, which possess half of the normal Galpha(olf) levels. In these animals, the locomotor effects of amphetamine and caffeine, two psychostimulant drugs that affect dopamine and adenosine signaling, respectively, were markedly reduced. Together, these results identify Galpha(olf) as a critical and regulated component of both dopamine and adenosine signaling.

Galpha(olf) is necessary for coupling D1 and A2a receptors to adenylyl cyclase in the striatum.

In the brain, dopamine and adenosine stimulate cyclic AMP (cAMP) production through D1 and A2a receptors, respectively. Using mutant mice deficient in the olfactory isoform of the stimulatory GTP-binding protein alpha subunit, Galpha(olf), we demonstrate here the obligatory role of this protein in the adenylyl cyclase responses to dopamine and adenosine in the caudate putamen. Responses to dopamine were also dramatically decreased in the nucleus accumbens but remained unaffected in the prefrontal cortex. Moreover, in the caudate putamen of mice heterozygous for the mutation, the amounts of Galpha(olf) were half of the normal levels, and the efficacy of dopamine- and CGS 21680 A(2) agonist-stimulated cAMP production was decreased. Together, these results identify Galpha(olf) as a critical parameter in the responses to dopamine and adenosine in the basal ganglia.

Autophosphorylation of Tyr397 and its phosphorylation by Src-family kinases are altered in focal-adhesion-kinase neuronal isoforms.

In brain, focal adhesion kinase (FAK) is regulated by neurotransmitters and has a higher molecular mass than in other tissues, due to alternative splicing. Two exons code for additional peptides of six and seven residues ('boxes' 6 and 7), located on either side of Tyr(397), which increase its autophosphorylation. Using in situ hybridization and a monoclonal antibody (Mab77) which does not recognize FAK containing box 7, we show that, although mRNAs coding for boxes 6 and 7 have different patterns of expression in brain, FAK+6,7 is the main isoform in forebrain neurons. The various FAK isoforms fused to green fluorescent protein were all targeted to focal adhesions in non-neuronal cells. Phosphorylation-state-specific antibodies were used to study in detail the phosphorylation of Tyr(397), a critical residue for the activation and function of FAK. The presence of boxes 6 and 7 increased autophosphorylation of Tyr(397) independently and additively, whereas they had a weak effect on FAK kinase activity towards poly(Glu,Tyr). Src-family kinases were also able to phosphorylate Tyr(397) in cells, but this phosphorylation was decreased in the presence of box 6 or 7, and abolished in the presence of both. Thus the additional exons characteristic of neuronal isoforms of FAK do not alter its targeting, but change dramatically the phosphorylation of Tyr(397). They increase its autophosphorylation in vitro and in transfected COS-7 cells, whereas they prevent its phosphorylation when co-transfected with Src-family kinases.

FAK and PYK2/CAKbeta in the nervous system: a link between neuronal activity, plasticity and survival?

A major aim of neurobiology today is to improve understanding of the signaling pathways that couple rapid events, such as the action potential and neurotransmitter release, to long-lasting changes in synaptic strength and increased neuronal survival. These adaptations involve interactions of neurons with other cells and with the extracellular matrix. They use, in part, the same molecular machinery that controls adhesion, motility or survival in non-neuronal cells. This machinery includes two homologous non-receptor tyrosine kinases, FAK and PYK2/CAKbeta, and the associated SRC-family tyrosine kinases. Specific brain isoforms of FAK with distinct properties are regulated by neurotransmitters, whereas PYK2/CAKbeta is highly sensitive to depolarization. The multiplicity of the pathways that can be activated by these tyrosine kinases indicates their importance in signal transduction in the adult brain.

Alternatively spliced focal adhesion kinase in rat brain with increased autophosphorylation activity.

pp125 focal adhesion kinase (FAK), a cytoplasmic tyrosine kinase transducing signals initiated by integrin engagement and G protein-coupled receptors, is highly expressed in brain. FAK from brain had a higher molecular weight and an increased autophosphorylation activity, than from other tissues. In addition to a 9-base insertion in the 3'-coding region, which defines FAK+, rat striatal FAK mRNAs contained several additional short exons, coding for peptides of 28, 6, and 7 residues, respectively (termed boxes 28, 6, and 7), surrounding the autophosphorylated Tyr-397. In transfected COS 7 cells, the presence of boxes 6 and 7 conferred an increased overall tyrosine phosphorylation, a higher phosphorylation of Tyr-397 assessed with a phosphorylation state-specific antibody, and a more active autophosphorylation in immune precipitates. The presence of box 28 did not alter further these parameters. Two-dimensional phosphopeptide maps of hippocampal FAK were identical to those of FAK+6,7. The presence of the various exons did not alter the interaction of FAK with c-Src, n-Src, or Fyn. Thus, several splice isoforms of FAK are preferentially expressed in rat brain, some of which have an increased autophosphorylation activity, suggesting that FAK may have specific properties in neurons.

A 19-kDa protein belonging to a new family is expressed in the Golgi apparatus of neural cells.

The mouse 8.5 mRNA encodes a 171-residue novel protein which displays a highly significant similarity with the product of the previously characterized neuronal p1A75 cDNA (Sutcliffe, J.G., Milner, R.J., Shinnick, T.M., and Bloom, F.E. (1983) Cell 33, 671-682). Northern blot and in situ hybridization experiments indicated that the 8.5 mRNA is specifically expressed in neural and neuroendocrine tissues. An affinity-purified antibody directed against the recombinant 8.5 protein demonstrated the existence of the 19-kDa natural protein in brain and evidenced its prominent juxtanuclear Golgi-like localization in cultured neurons. Ultrastructural analysis of the same preparation revealed a specific labeling of all the Golgi saccules and of some vesicles in the Golgi zone. In transfected COS cells, the exogenous protein was also detected in the Golgi area, indicating, therefore, the presence of a Golgi targeting signal in its primary sequence.

An abundant mRNA of the embryonic brain persists at a high level in cerebellum, hippocampus and olfactory bulb during adulthood.

In order to identify markers of the two neuronal populations which are successively involved in forebrain ontogenesis, we performed a differential screening of a murine cDNA library with two radiolabelled probes corresponding to striatal mRNAs extracted at embryonic day (E) 17 and E20, i.e. before and after the invasion of the striatum by the late-born matrix neurons. One of the selected clones, the 3.1 cDNA, corresponds to a very abundant embryonic neuronal transcript enriched in the germinal zones at E17 and in superficial cortical layers and striatum at E20, suggesting that it is expressed mainly in neurons belonging to a late migration wave. During adulthood, it persists at a high level in the granular layer of the cerebellum, the hippocampus and the olfactory bulb, which are the sites of postnatal neurogenesis and intense synaptic plasticity. This 2000 base RNA is enriched in polysomal fractions and encodes a small putative 68 amino acid polypeptide which is conserved in mouse and man.

Cholecystokinin: Corelease with dopamine from nigrostriatal neurons in the cat.

Halothane-anaesthetized cats were implanted with push-pull cannulae to demonstrate the in vivo release of cholecystokinin-like immunoreactivity (CCK-LI) in the substantia nigra and the ipsilateral caudate nucleus. The spontaneous and the calcium-dependent potassium-evoked release of CCK-LI were observed in both structures. In addition, the local application of tetrodotoxin (10-6 M) reduced the spontaneous release of the peptide. 6-OHDA lesions made in the substantia nigra pars compacta led to a complete destruction of nigrostriatal dopaminergic neurons. CCK-LI levels were not affected in the caudate nucleus but were reduced substantially in the substantia nigra. The activation of dopaminergic cells induced by the nigral application of alpha-methyl-para-tyrosine (10-4 M) stimulated the release of CCK-LI and dopamine in the ipsilateral caudate nucleus, whilst opposite effects were seen in the substantia nigra. Similar results were obtained when dopaminergic transmission was blocked in the caudate nucleus suggesting that the evoked release of CCK-LI by the alpha-methyl-para-tyrosine treatment originates from dopaminergic nerve terminals and not from other CCK-LI containing fibres in response to released dopamine. Dopamine (10-7 M) as well as the D1 agonist SKF 38393 (10-5 M) stimulated CCK-LI release when applied into the caudate nucleus while the D2 agonist, LY 171555 (10-6 M) slightly reduced peptide release. The local application of cholecystokinin-8 sulfate (CCK-8S) (10-8 M, for 30 min) into the substantia nigra pars compacta increased the firing rate of dopaminergic cells and stimulated the release of newly synthesized 3H-dopamine from dendrites and nerve terminals. These results suggest, but do not definitively prove, that, in the cat, CCK-LI and dopamine are coreleased from nigrostriatal mixed dopaminergic/CCK-LI neurons and that CCK-LI released from dendrites is, like dopamine, involved in the regulation of the activity of these cells.

Lesion of dopaminergic terminals in the amygdala produces enhanced locomotor response to D-amphetamine and opposite changes in dopaminergic activity in prefrontal cortex and nucleus accumbens.

In a previous study using differential pulse voltammetry we demonstrated an interaction between dopaminergic activity in the amygdala and the nucleus accumbens. In the present study, by post-mortem biochemical measurements, we showed that bilateral 6-OHDA lesions of DA innervation of the amygdala leads to an increase in DA activity in the nucleus accumbens (DOPAC/DA ratio +24%) and a reduction (DOPAC/DA ratio -40%) in the prefrontal cortex. In addition, after these lesions in the amygdala, there was an increased behavioral sensitivity to D-amphetamine, demonstrated by enhanced locomotor activity. Increased understanding of the interregulations between dopaminergic activity in forebrain structures may help explain forebrain functions and/or dysfunctions.

Extensive co-localization of neurotensin with dopamine in rat meso-cortico-frontal dopaminergic neurons.

In mammalian brain, dopaminergic (DA) cell bodies located in the ventral mesencephalon give rise to meso-cortical, meso-limbic and meso-striatal systems. Among these, the meso-cortical DA pathway is particularly involved in the processing of emotional and cognitive responses. We demonstrate that the rat meso-cortical neurons specifically contain, in addition to DA, another transmitter, Neurotensin. If this co-localization exists in man, it may provide an anatomical substratum for the biological theory of schizophrenia as well as an indication that potential anti-psychotic drugs which act differentially on the DA ascending transmissions can be developed.

Behavioural deficits induced by an electrolytic lesion of the rat ventral mesencephalic tegmentum are corrected by a superimposed lesion of the dorsal noradrenergic system.

The bilateral electrolytic lesion of the ventral mesencephalic tegmentum (VMT) induces, in the rat, behavioural deficits such as locomotor hyperactivity and disappearance of spontaneous alternation ('VMT syndrome'). When a specific 6-hydroxy dopamine (6-OHDA) destruction of the dorsal noradrenergic (NA) ascending pathway was superimposed to an electrolytic lesion of the VMT, animals recovered a normal locomotor activity and the possibility to alternate. Since many studies indicate that the development of the 'VMT syndrome' is linked to the disruption of the dopaminergic (DA) meso-cortico-limbic transmission, it is proposed that the recovery observed is due to an interaction between NA and DA ascending systems in cortical and/or subcortical structures; noradrenergic innervation would have a permissive role on the expression of the 'VMT syndrome', possibly via a mechanism of heteroregulation of DA receptors by NA fibers.

Immunochemical and biochemical characterization of gastrin/cholecystokinin-like peptides in Palaemon serratus (Crustacea Decapoda): intermolt variations.

Gastrin/cholecystokinin (G/CCK)-like peptides cross-reacting with an antiserum specific for the carboxyamide terminal pentapeptide of gastrin and CCK have been detected in the eyestalks and in the stomach of the prawn Palaemon serratus using immunocytochemical methods. In the eyestalks, immunoreactivity is present in the neuroendocrine cells, the X organ-sinus gland tractus and the neurohemal organ itself. This suggests, for the first time, the existence of a neuroendocrine secretion of G/CCK-like peptides. Hemolymph G/CCK level is about 18 pM. In the stomach, G/CCK-like material has been observed in epithelial cells in the cuticle and in the lumen. Molecular sieving of crude extracts of the medulla terminalis from the eyestalks, the stomach, and the hemolymph samples on a Sephadex G-50 filtration column exhibited a molecular heterogeneity of the G/CCK immunoreactive material. Large components were observed principally in the medulla terminalis and in the hemolymph, and smaller forms in the stomach. A fraction common for the three tissues had an apparent molecular weight of 2500 Da. That fraction was characterized further by HPLC and shown to be more hydrophobic than human G17 I. By radioimmunoassay relatively low levels were detected in all the aforementioned organs. Although the concentration of the G/CCK-like components varies during the intermolt cycle, this was the case mainly in the hemolymph and in the stomach. These observations suggest a possible role of G/CCK-like peptides in molting processes.

Autoradiography of CCK receptors in the rat brain using [(3)H]Boc[Nle(28)(31)]CCK(27)-(33) and [(125)I]bolton-hunter CCK(8). Functional significance of subregional distributions.

[(3)H]Boc[Nle(28,31)]CCK(27)-(33) ([(3)H]BDNL-CCK(7)) is a new ligand for cholecystokinin (CCK) receptors, endowed with a high specific activity (100 Ci/mmol). Binding sites for this ligand were visualized in the rat brain by autoradiography [(3)H]BDNL-CCK(7) binds specifically to an apparent single class of CCK receptors on rat striatum sections with a K(d) of 1.76 nM and a B(max) of 57 fmol/mg protein. Unsulfated CCK(8) was two times less potent than sulfated CCK(8) to displace binding of [(3)H]BDNL-CCK(7). Binding sites for [(3)H]BDNL-CCK(7) were present in many brain regions, the highest concentrations occurring in cortex, olfactory bulbs, nucleus accumbens, and medium to high concentrations in striatum, hippocampus, and several nuclei of thalamus, hypothalamus and amygdala. In the same experimental conditions, the binding sites for [(125)I]BH-CCK(8) showed similar specificity and localization. We thus used both ligands to investigate the subregional distributions of CCK receptors in nucleus accumbens and hippocampus, where a highly organized topography of action of CCK has been reported. In nucleus accumbens, the CCK binding sites were concentrated in the anterior portion of the nucleus, whereas very low densities were observed within medial posterior nucleus accumbens, where injection of CCK has been shown to potentiate dopamine-induced hyperlocomotion. p]In hippocampus, CCK receptors were concentrated in the polymorphic zone of the hilus of the dentate gyrus and in stratum lacunosum moleculare of Ammon's horn. Very few receptors were observed in other regions of hippocampus, including stratum pyramidale and stratum moleculare. This is in contrast with the presence of numerous CCK terminals and the potent effect of CCK in these areas. The distributions of CCK receptors reported here in both nucleus accumbens and hippocampus were discussed in correlation with the distribution of CCK neurons and terminals, the related anatomical pathways, and the pharmacological profiles of the effects of CCK in these regions.

Partial protection by desmethylimipramine of the mesocortical dopamine neurones from the neurotoxic effect of 6-hydroxydopamine injected in ventral mesencephalic tegmentum. The role of noradrenergic innervation.

As shown in the rat by estimation of dopamine (DA) and noradrenaline (NA) levels, bilateral 6-hydroxydopamine (6-OHDA, 4 micrograms/microliter) lesions made in the ventral mesencephalic tegmentum (VMT) destroy both ascending DA and NA neurones. Pretreatment of rats with desmethylimipramine (DMI, 30 mg/kg, i.p.), 30 min before microinjection of 6-OHDA into the VMT partially prevented the destruction of the DA neurones innervating the prefrontal and cingulate cortices but not those innervating subcortical structures (nucleus accumbens, olfactory tubercles, septum). Results obtained from the prefrontal cortex of rats with extensive lesions of the ascending NA neurones performed 15 days prior to the 6-OHDA lesions of the VMT in the presence of DMI, imply that NA innervation of the VMT seems to be required for DMI to protect the cortical DA neurons from the neurotoxic effect of 6-OHDA.

Dopaminergic control of 125I-labeled neurotensin binding site density in corticolimbic structures of the rat brain.

In the rat brain, destruction of dopaminergic cell groups by injections of 6-hydroxydopamine into the ventral mesencephalic tegmentum results in large decreases in the number of neurotensin binding sites in the mesencephalon and the striatum. In contrast, these lesions produce an increase in the number of 125I-labeled neurotensin binding sites in the lateral part of the prefrontal cortex despite a large decrease in cortical dopamine levels. Increases in the number of 125I-labeled neurotensin binding sites in this cortical area as well as in the entorhinal cortex, the nucleus accumbens, and the central part of the striatum were also obtained after chronic blockade of dopamine neurotransmission by a long-acting neuroleptic pipotiazine palmitic ester. We propose that dopamine inputs regulate the density of postsynaptic neurotensin binding sites through cortical and subcortical dopamine receptors. Therefore, some of the clinical effects of neuroleptics in schizophrenic patients could be partly related to changes in neurotensin neurotransmission.

Opposite effects of sulfated cholecystokinin on DA-sensitive adenylate cyclase in two areas of the rat nucleus accumbens.

The nucleus accumbens of the rat receives a mixed DA/CCK8 innervation in its posterior part while its anterior part is innervated by distinct DA and CCK8 fibres. In vitro, the addition of CCK8 (0.3-1 microM) potentiated the activating effect of DA (10-30 microM) on adenylate cyclase in tissue homogenates obtained from the posterior part of the nucleus accumbens, whilst this activating effect was reduced by CCK8 in the anterior part. These results suggest the existence of two types of regulation of the D1 receptor by CCK8 depending on the identity (mixed or not mixed) of their innervating fibres.