The microRNA-29a Modulates Serotonin 5-HT7 Receptor Expression and Its Effects on Hippocampal Neuronal Morphology.

miRNAs are master regulators of gene expression in diverse biological processes, including the modulation of neuronal cytoarchitecture. The identification of their physiological target genes remains one of the outstanding challenges. Recently, it has been demonstrated that the activation of serotonin receptor 7 (5-HT7R) plays a key role in regulating the neuronal structure, synaptogenesis, and synaptic plasticity during embryonic and early postnatal development of the central nervous system (CNS). In order to identify putative miRNAs targeting the 3'UTR of 5-HT7R mouse transcript, we used a computational prediction tool and detected the miR-29 family members as the only candidates. Thus, since miR-29a is more expressed than other members in the brain, we investigated its possible involvement in the regulation of neuronal morphology mediated by 5-HT7R. By luciferase assay, we show that miR-29a can act as a post-transcriptional regulator of 5-HT7R mRNA. Indeed, it downregulates 5-HT7R gene expression in cultured hippocampal neurons, while the expression of other serotonin receptors is not affected. From a functional point of view, miR-29a overexpression in hippocampal primary cultures impairs the 5HT7R-dependent neurite elongation and remodeling through the inhibition of the ERK intracellular signaling pathway. In vivo, the upregulation of miR-29a in the developing hippocampus parallels with the downregulation of 5-HT7R expression, supporting the hypothesis that this miRNA is a physiological modulator of 5-HT7R expression in the CNS.

Quantifying barcodes of dendritic spines using entropy-based metrics.

Spine motility analysis has become the mainstay for investigating synaptic plasticity but is limited in its versatility requiring complex, non automatized instrumentations. We describe an entropy-based method for determining the spatial distribution of dendritic spines that allows successful estimation of spine motility from still images. This method has the potential to extend the applicability of spine motility analysis to ex vivo preparations.

The serotonin receptor 7 promotes neurite outgrowth via ERK and Cdk5 signaling pathways.

Serotonergic neurotransmission is mediated by at least 14 subtypes of 5-HT receptors. Among these, the CNS serotonin receptor 7 (5-HTR7) is involved in diverse physiological processes. Here we show that treatment of murine striatal and cortical neuronal cultures with 5-HTR7 agonists (8-OH-DPAT and LP-211) significantly enhances neurite outgrowth. This effect is abolished by the selective 5-HTR7 antagonist SB-269970, by the ERK inhibitor U0126, by the cyclin-dependent kinase 5 (Cdk5) inhibitor roscovitine, as well as by cycloheximide, an inhibitor of protein synthesis. These data indicate that 5-HTR7 activation stimulates extensive neurite elongation in CNS primary cultures, subserved by ERK and Cdk5 activation, and de novo protein synthesis. Two-dimensional (2D) gel electrophoresis coupled to Western blot analyses reveals both qualitative and quantitative expression changes in selected cytoskeletal proteins, following treatment of striatal primary cultures with LP-211. In particular, the 34 kDa isoform of MAP1B is selectively expressed in stimulated cultures, consistent with a role of this protein in tubulin polymerization and neurite elongation. In summary, our results show that agonist-dependent activation of the endogenous 5-HTR7 in CNS neuronal primary cultures stimulates ERK- and Cdk5-dependent neurite outgrowth, sustained by modifications of cytoskeletal proteins. These data support the hypothesis that the 5-HTR7 might play a crucial role in shaping neuronal morphology and behaviorally relevant neuronal networks, paving the way to new approaches able to modulate CNS connectivity.

Methylphenidate to adolescent rats drives enduring changes of accumbal Htr7 expression: implications for impulsive behavior and neuronal morphology.

Methylphenidate (MPH) administration to adolescent rodents produces persistent region-specific changes in brain reward circuits and alterations of reward-based behavior. We show that these modifications include a marked increment of serotonin (5-hydroxy-tryptamine) receptor type 7 (Htr7) expression and synaptic contacts, mainly in the nucleus accumbens, and a reduction of basal behavioral impulsivity. We show that neural and behavioral consequences are functionally related: administration of a selective Htr7 antagonist fully counteracts the MPH-reduced impulsive behavior and enhances impulsivity when administered alone in naive rats. Agonist-induced activation of endogenous Htr7 significantly increases neurite length in striatal neuron primary cultures, thus suggesting plastic remodeling of neuronal morphology. The mixed Htr (1a/7) agonist, 8-OH-DPAT, reduces impulsive behavior in adolescent rats and in naive adults, whose impulsivity is enhanced by the Htr7 antagonist. In summary, behavioral pharmacology experiments show that Htr7 mediates self-control behavior, and brain primary cultures experiments indicate that this receptor may be involved in the underlying neural plasticity, through changes in neuronal cytoarchitecture.

Chronic cocaine administration modulates the expression of transcription factors involved in midbrain dopaminergic neuron function.

Chronic cocaine use leads to pronounced alterations in neuronal functions in brain circuits associated with reward. In the present study, we examined in the rat midbrain the effects of acute, subchronic (5 days) and chronic cocaine treatments (14 days) on the gene expression of transcription factors involved in the development and maintenance of dopaminergic neurons. We show that chronic, but not acute or subchronic, cocaine administration downregulates Nurr1 and Pitx3 transcripts whereas En1 transcripts are upregulated. Conversely, Lmx1b and En2 transcripts are not affected by the drug treatment, indicating that the modulation of the midbrain transcription factors analyzed is highly selective. Interestingly, modification of the gene expression for these transcription factors persists in midbrain as long as two weeks after the last drug administration, suggesting that it may account for some of the enduring alterations in midbrain dopaminergic circuits associated with chronic cocaine use.

The end of the central dogma of neurobiology: stem cells and neurogenesis in adult CNS.

Until the 1990s, neurologists were practising their profession under the doctrine established in the late 19th to early 20th century by the prominent histologist Ramon y Cajal: "Once the development was ended, the founts of growth and regeneration of the axons and dendrites dried up irrevocably. In the adult centers, the nerve paths are something fixed, ended, and immutable. Everything may die, nothing may be regenerated. It is for the science of the future to change, if possible, this harsh decree." Similarly, Giulio Bizzozero, the most prominent Italian histologist and mentor of Camillo Golgi, classified the tissues of the human body into "labile, stable and perennial". Among the latter were the nerve cells, believed to be unable to proliferate in the postnatal brain. This classification was taught until a few years ago to generations of medical students and biologists all over the world. We have investigated the historical, methodological and technical reasons why this "central dogma of neurology", so influential in clinical and experimental neurology, has lasted so long. We examined how this dogma was broken and who contributed, and the difficulties encountered by the "heretical" researchers who contributed to this goal, especially between the 1960s and the early 1990s, when at last neurogenesis in the adult brain could no longer be denied. Finally, we propose that the understanding of the mechanisms underlying various neurological diseases and the interpretations of clinical syndromes, as well as the design of new therapies, are being revolutionised by the breaking of this dogma and the discovery of the presence of neural stem cells in the adult brain.

Ontogeny of AMPA receptor gene expression in the developing rat midbrain and striatum.

AMPA receptors mediate most of the fast excitatory synaptic transmission in the mammalian CNS. Their ontogeny during embryonic (E) and postnatal (P) development is still poorly understood. We have studied the expression of the genes encoding for AMPA glutamate receptor subunits (GlurA, GlurB, GlurC and GlurD) in the rat ventral mesencephalon (MES) and striatum (STR) and in fetal midbrain primary cultures. Each receptor subunit shows unique area- and temporal-expression pattern. In MES, GluRA, GlurB and GlurC mRNA are detectable from the earliest embryonic stage studied (E13) and raise thereafter between E15 and E17, to plateau at E19 to adult values. Differently, GlurD mRNA increases throughout embryonic and postnatal development reaching its highest levels in the adult MES. The pattern of AMPA proteins corresponded to the mRNA levels for all subunits. In the STR, GlurA gene expression increases between E15 and E19, GlurB mRNA levels are sustained from the first embryonic stages analyzed (E15) until E19 and gradually decrease thereafter toward adult levels, GlurC gene expression increases gradually throughout ontogeny to reach its highest levels in the adult. STR GlurD transcripts remain at constant levels in all stages studied. In embryonic MES primary cultures, every subunit show a characteristic expression profile similar to that observed in vivo. They all decrease significantly during the second week in vitro. Thus, all the AMPA receptor subunit transcripts appear independently regulated during development, probably depending on the tissue-specific environment, which seems preserved in MES cultures.

Regionalized neurofilament accumulation and motoneuron degeneration are linked phenotypes in wobbler neuromuscular disease.

Abnormal neurofilament aggregates are pathological hall-mark of most neurodegenerative diseases, although their pathogenic role remains unclear. Increased expression of medium neurofilament (NFM) is an early molecular marker of wobbler mouse, an animal model of motoneuron disease. In the wr/wr, a vacuolar neuronal degeneration (VND) starts at 15 days postnatally, selectively in cervical spinal cord and brain stem motoneurons. Here we show that nfm gene hyperexpression is restricted to the aforementioned motoneurons and is specific for wr mutation. NF proteins accumulate in wr/wr before VND. wr/+ mice, which are asymptomatic, show intermediate NF accumulation between wr/wr and +/+ littermates, suggesting a gene dosage dependence of the wobbler pathology. Altogether our data indicate that NF hyperexpression and regionalized motoneuron degeneration are linked to the wr mutation, although with a still unknown relationship to the mutant gene activity.

Genetic and epigenetic control of midbrain dopaminergic neuron development.

The relatively few dopaminergic (DA) neurons in the mammalian brain regulate many important neural functions, including motor integration, neuroendocrine hormone release, cognition, emotive behaviors and reward. A number of laboratories, including ours, have contributed to unravel the mechanisms of DA phenotype induction and maturation and elucidated the role of epigenetic factors involved in specification, development and maintenance of midbrain dopaminergic functions. DA progenitors are first "committed" to give rise to DA neurons by the action of two secreted factors, Sonic hedgehog and fibroblast growth factor 8 (FGF8). Subsequently, the function of selectively activated transcription factors, Nurr1 and Ptx3, is required for the DA final determination. Further development of DA neurotransmission requires specific interactions with the developing target striatal cells, which modulate key DA functions, namely synthesis and uptake of the neurotransmitter. Committed and determined DA neurons express the key genes involved in DA neurotransmission at different times in development. In rodents, synthesis and intracellular accumulation of DA is achieved shortly after expression of Nurr1, while the onset of high affinity uptake, responsible for ending the neurotransmission, takes place after a few days. Cell contacts between the presynaptic DA neurons and target striatal neurons are apparently necessary for the fine modulation of DA function, in vivo and in vitro. Strikingly, the in situ maturation and phenotypic specialization of DA neurons grafted into the adult striatum/caudate-putamen parallels the normal development of committed fetal dopamine neurons during neurogenesis. The correct matching between the right presynaptic and postsynaptic neurons is required also for grafted DA cells.

Epigenetic cues in midbrain dopaminergic neuron development.

Midbrain dopaminergic (DA) neurons subserve complex and varied neural functions in vertebrate CNS. Their progenitors give rise to DA neurons by the action of two extracellular inducers, Sonic Hedgehog and FGF8. After this first commitment, the function of selectively activated transcription factors, like the orphan steroid nuclear receptor Nurr1, is required for DA final determination. Subsequently, DA function is selectively modulated by specific interaction with the developing striatal target tissue. Committed and determined DA neurons express the key genes involved in DA neurotransmission at different times in development. Synthesis and intracellular accumulation of DA is achieved shortly after expression of Nurr1, while high affinity uptake, responsible for ending the neurotransmission, takes place after a few days. Cell contacts between the presynaptic DA neurons and target striatal neurons are apparently necessary for the fine modulation of DA function, in vivo and in vitro.

Multiplex semi-quantitative reverse transcriptase-polymerase chain reaction of low abundance neuronal mRNAs.

The sequential use of reverse transcriptase and the polymerase chain reaction (RT-PCR) has provided molecular biology research with an exquisitely sensitive and fast technique for studying gene expression. This method is particularly useful to study transcripts in the nervous system, which are on average present at low levels and the amount of tissue or cells to be analyzed is often limited. Here, we describe a RT-PCR assay which allows the simultaneous detection and semi-quantitation of several transcripts (multiplex). Multiple PCR primer pairs are used to detect different target transcripts in a single reaction, together with a pair of primers able to amplify the hypoxantine-phosphoribosyl-transferase (HPRT), a gene constitutively expressed at low levels throughout the nervous system. HPRT levels remain constant also during neurogenesis and it is thus apt to be used in developmental neurobiology. This internal standard is the mRNA of reference to evaluate sample variation in RT and PCR reactions and to monitor the degradation and recovery of RNAs. Normalization with respect to HPRT cDNA allows to estimate the relative abundance of each target mRNA.

Neuronal and glial properties coexist in a novel mouse CNS immortalized cell line.

A mes-c-myc A1 (A1) cell line was generated by retroviral infection of cultured embryonic mesencephalic cells and selected by neomycin resistance. A1 cells cease to divide and undergo morphological differentiation after serum withdrawal or addition of c-AMP. Proliferating or morphologically differentiated A1 cells are all positive for vimentin and nestin, a marker of neural precursor, and show neuronal markers such as microtubule-associated protein 1, neuron-specific enolase and peripherin, and the glial marker glial fibrillary acidic protein. Neuronal and glial markers coexist in single cells. Furthermore, A1 cells show presence of glutamic acid decarboxylase 67 mRNA and its embryonic form EP10 and accumulate the neurotransmitter GABA. Electrophysiological studies demonstrate that morphologically differentiated A1 cells display voltage-gated sodium and potassium channels in response to depolarizing stimuli. A1 cells thus represent a novel, bipotent neural cell line useful for studying CNS differentiation and plasticity, as well as the molecular mechanisms underlying development of GABAergic neurotransmission.

Establishment and characterization of a human neuroectodermal cell line (TB) from a cerebrospinal fluid specimen.

We have established a cell line (TB) from a cerebrospinal fluid (CSF) specimen of a patient with a primary leptomeningeal melanomatosis. TB cell line was immunoreactive with the antibodies for low molecular weight neurofilament protein, vimentin, neuron-specific enolase, chromogranin, synaptophysin and HMB-45 (an antibody sensitive and specific for melanoma). When TB cells were transplanted into nude mice, the same immunohistochemical pattern present in cultured cells was found but surprisingly, a positive staining for desmin was observed. Significant amounts of serotonin and its metabolite were detectable. Retinoic acid but not nerve growth factor was able to induce differentiation towards a neuronal phenotype. In summary, TB cells represent primitive neuroectodermal cells having the potential for neuronal, myoblastic and possibly melanoblastic differentiation.

Epigenetic factors and midbrain dopaminergic neurone development.

In the mammalian brain dopamine systems play a central role in the control of movement, hormone release, emotional balance and reward. Alteration of dopaminergic neurotransmission is involved in Parkinson's disease and other movement disorders, as well as in some psychotic syndromes. This review summarises recent findings, which shed some light on signals and cellular interactions involved in the specification and maturation of the dopaminergic function during neurogenesis. In particular we will focus on three major issues: (1) the differentiation of dopaminergic neurones triggered by direct contact with the midbrain floor plate cells through the action of sonic hedgehog; (2) the neurotrophic factors acting on dopaminergic neurones; and (3) the role of target striatal cells on the survival and the axonal growth of developing or grafted dopaminergic neurones.

Dopamine transporter gene expression in rat mesencephalic dopaminergic neurons is increased by direct interaction with target striatal cells in vitro.

By using a semi-quantitative reverse transcriptase-PCR assay (RT-PCR) we have analyzed dopamine transporter (DAT), tyrosine hydroxylase (TH) and synaptic vesicle monoamine transporter (VMAT2) gene expression in rat mesencephalic (MES) primary cultures. Consistent with previous data obtained during rat MES ontogeny, the onset of DAT transcription in vitro is delayed in embryonic day (E)13, but not in E16, MES neurons when compared to that of TH and VMAT2. In co-culture, the addition of target striatal cells (STR) to E13 MES selectively increases DAT mRNA level in DA neurons during the first 3 days in vitro; cortical cells are ineffective. On the contrary, DAT gene does not appear up-regulated in E16 MES co-cultured with target STR cells, indicating that MES DA neurons respond to STR stimulation only at defined developmental stages. Up-regulation of DAT mRNA level by STR in E13 MES seems to require direct cell interactions since target cells do not exert their effect on DAT transcription when are separated from MES cells by a porous barrier, which only allows diffusion of soluble molecules. Thus maturation of DA neurotransmission in vitro appears to follow a developmental program which can be specifically modulated by their target STR cells.

Early upregulation of medium neurofilament gene expression in developing spinal cord of the wobbler mouse mutant.

Homozygous wobbler mouse mutants develop a progressive paralysis due to spinal motoneuron degeneration. To understand the molecular aspect underlying the genetic defect we have studied the embryonic (from E13) and postnatal expression of the three neurofilament and choline acetyltransferase genes in each member from several wild-type (wt) and wobbler (wr) progenies. There are no variations among wt littermates at all ages studied. In contrast, analyses of neurofilament mRNA reveals a 3-4-fold increase of medium neurofilament (NFM) mRNA in wobbler mice (wr/wr). The pattern of increased NFM mRNA during development, prior to the appearance of the wobbler phenotype, among littermates (from heterozygous carriers) conforms to a mendelian inheritance of a single gene defect 1:2:1 (wr/wr:wr/+:+/+). Light and heavy neurofilament mRNA levels are also increased later in development exclusively in those individuals with high NFM mRNA values indicating that increase of the latter is associated with increase of the light and heavy subunit expression. Also NF proteins are increased. Expression of choline acetyltransferase gene is instead always comparable to normal control. Our study provides novel insights into the nature of the wobbler defect, strengthening the hypothesis that neurofilament accumulation plays a pivotal role in the etiopathogenesis of motoneuron degeneration.

Acetylcholine esterase and peripherin mRNA level decrease in wobbler mouse.

Homozygote wobbler mice develop motoneurone degeneration. Throughout development the expression of choline acetyltransferase, of trkC receptor and F3 adhesion molecule genes is similar in wobbler and wild-type spinal cord. Acetylcholinesterase mRNA level instead is decreased to about 50% with respect to wild-type values in one forth of P5 and P10 wobbler progeny, putative wr/wr individuals; at P21 its expression is equally highly reduced in known homozygotes and it is reduced to 35% of normal values in about one half of the progeny, putative heterozygotes. Thus, similarly to medium neurofilament gene over-expression, reduced acetylcholinesterase gene expression is an early molecular marker for the wobbler mutation before onset of the illness.

Target cells modulate dopamine transporter gene expression during brain development.

We have analysed the expression of the dopamine transporter (DAT) gene and compared it with that of tyrosine hydroxylase, neuronal GABA transporter and synaptic vesicle monoamine transporter genes during pre- and post-natal development of rat mesencephalic dopaminergic (DA) neurones. Our results show that DAT transcripts are not detectable until embryonic day (E) 15, whilst those of the other genes analysed are already present at E12. In vitro, the level of DAT gene transcription in mesencephalic E13 DA neurones is increased in coculture with target striatal cells. Thus striatal targets cells regulate, at the transcriptional level, a key step of dopaminergic neurotransmission during DA neurone development.

Excitatory amino acid response in cultured rat striatal neurons results in a developmentally regulated cGMP formation.

Glutamate and its analogues play a central role in excitatory neurotransmission throughout the brain. Their signal in the postsynaptic cells can be transduced by several second messengers. Here we show that in primary cultures of embryonic rat striatum, excitatory amino acid receptor stimulation increases cyclic GMP intracellular concentration and the magnitude of this response depends upon the time in culture. Formation of cyclic GMP appears to be mediated by both N-methyl-D-aspartate (NMDA) and non-NMDA type excitatory amino acid receptors, it is blocked by specific excitatory amino acid antagonists and requires extracellular Ca++. The effect mediated via the NMDA receptor is also regulated by extracellular Mg++. These results show that excitatory amino acids make use of cyclic GMP for signal transduction in striatal neurons in vitro. We suggest that cyclic GMP may be an independent second messenger possibly important in the development of a defined population of striatal neurons.

Two functionally different glutamate receptors of the kainate subtype in embryonic rat mesencephalic cells.

The amino acid glutamate is a widespread excitatory neurotransmitter in the brain. It activates cation-selective channels expressed by nearly every neuron and by glial cells; also various second messenger cascades. Little is known about the ontogeny of glutamate neurotransmission during neurogenesis. We have analyzed the development and differentiation of excitatory amino acid responses and Na+ channels in cells dissociated from embryonic rat ventral mesencephalon and striatum as well as cortex and cerebellum using fluorescent voltage-sensitive oxonol dyes and flow cytometry. Analysis of fluorescence distribution revealed complex profiles under resting conditions which changed in a characteristic manner over the period studied (Embryonic (E) Days 12-20). The response to the Na+ channel agonist veratridine appeared at E12/13 in the mesencephalon. At E13 L-glutamate and kainate evoked changes in membrane potential interpreted as cellular hyperpolarization. At E15 some cells still responded by hyperpolarizing but an equal number began to depolarize. By E18 most cells depolarized. Both hyper- and depolarizations were eliminated by a specific antagonist at kainate receptors (6-cyano-7-nitroquinoxyline-2,3-dione) and by resuspending the cells in Na(+)-free medium. Both responses exhibited a concentration dependency with higher doses evoking stronger effects. In contrast, there was little effect of veratridine in the striatum at E15-E16, and the response to kainate or L-glutamate was predominantly depolarizing during the same embryonic period, with little or no effect until E18. These data show that in the developing CNS, sodium channel responses as well as excitatory aminoacid neurotransmitter responses first become functional in the mesencephalon and subsequently in the striatum, thus suggesting an anatomical gradient of expression. Our results also show that glutamate receptor-coupled functions vary with embryonic age and with regional distribution, suggesting possible roles of glutamate in early CNS embryogenesis, as morphogens or modulators of synaptic plasticity.