胶质细胞在突触形成及突触传导中的作用

近年来,对胶质细胞功能的研究迅速发展.诸多研究都表明胶质细胞不仅为神经元功能发挥提供良好环境,而且还直接影响突触形成及其功能完善.此外胶质细胞也可以通过自身释放化学递质与神经元形成突触联系,参与对神经元兴奋性及突触传导的调节.     

Transmitter control of voltage-dependent currents

At one time neurotransmitters were thought of as chemical agents that simply depolarized or hyperpolarized a postsynaptic cell. Now it is known that transmitters can do much more. Biochemical processes, most notably the consequences of activation of adenylate cyclase, are subject to neurotransmitter control. Transmitters can alter a cell's sensitivity to another neurotransmitter; this is exemplified by the action of aspartate in enhancing responses to glutamate. Another action of transmitters is the subject of this review: control of voltage-dependent neuronal currents.Voltage-dependent processes are necessary for the normal function of neuronal systems. Potassium, sodium, and calcium currents that turn on and off with changes in membrane potential are responsible for action potentials and slow-wave (or burst firing) activity. Transmitter control of these ionic currents allows direct synaptic regulation of basic electrophysiological events.Discussion of the voltage-dependent actions of transmitters in neuronal systems will be divided into four areas: (a) broadening and narrowing of action potentials, (b) modulation of burst firing activity, (c) blockade of a voltage-dependent potassium conductance, and (d) induction of a voltage-dependent calcium current. The membrane currents underlying voltage-dependent events will be reviewed only as necessary to understanding transmitter effects. The reader is referred to a recent review for further details on some of these currents (1).     

Communication between neurons and astrocytes: relevance to the modulation of synaptic and network activity

Neuromodulation is a fundamental process in the brain that regulates synaptic transmission, neuronal network activity and behavior. Emerging evidence demonstrates that astrocytes, a major population of glial cells in the brain, play previously unrecognized functions in neuronal modulation. Astrocytes can detect the level of neuronal activity and release chemical transmitters to influence neuronal function. For example, recent findings show that astrocytes play crucial roles in the control of Hebbian plasticity, the regulation of neuronal excitability and the induction of homeostatic plasticity. This review discusses the importance of astrocyte-to-neuron signaling in different aspects of neuronal function from the activity of single synapses to that of neuronal networks.     

Cerebral expression of the alpha2-subunit of soluble guanylyl cyclase is linked to cerebral maturation and sensory pathway refinement during postnatal development

Soluble guanylyl cylase (sGC) has been identified for being a receptor for the gaseous transmitters nitric oxide and carbon monoxide. Currently four subunits alpha1, alpha2, beta1, and beta2 have been characterized. Heterodimers of alpha and beta-subunits as well as homodimers of the beta2-subunit are known to constitute functional sGC which use GTP to form cGMP a potent signal molecule in a multitude of second messenger cascades. Since NO-cGMP signaling plays a pivotal role in neuronal development we analyzed the maturational expression pattern of the newly characterized alpha2-subunit of sGC within the brain of Wistar rats by means of RNase protection assay and immunohistochemistry. alpha2-subunit mRNA as well as immunoreactive alpha2-protein increased during postnatal cerebral development. Topographical analysis revealed a selective high expression of the alpha2-subunit in the choroid plexus and within developing sensory systems involving the olfactory and somatosensory system of the forebrain as well as parts of the auditory and visual system within the hindbrain. In cultured cortical neurons the alpha2-subunit was localized to the cell membrane, especially along neuronal processes. During the first 11 days of postnatal development several cerebral regions showed a distinct expression of the alpha2-subunit which was not paralleled by the alpha1/beta1-subunits especially within the developing thalamo-cortical circuitries of the somatosensory system. However, at later developmental stages all three subunits became more homogenously distributed among most cerebral regions, indicating that functional alpha1/beta1 and alpha2/beta1 heterodimers of sGC could be formed. Our findings indicate that the alpha2-subunit is an essential developmentally regulated constituent of cerebral sensory systems during maturation. In addition the alpha2-subunit may serve other functions than forming a functional heterodimer of sGC during the early phases of sensory pathway refinement.     

Segregation of the classical transmitters norepinephrine and acetylcholine and the neuropeptide Y in sympathetic neurons: Modulation by ciliary neurotrophic factor or prolonged growth in culture

Recent evidence has demonstrated that cotransmission from mammalian neurons is not uniquely achieved by costorage and corelease of transmitters and cotransmitters from single varicosities, but also by the concurrent release of mediators segregated in separate synapses of individual neurons. An important question to be addressed is whether neurons show defined patterns of segregation or whether this is a plastic feature. We addressed this question by exploring the segregation pattern of the classical sympathetic transmitters norepinephrine (NE) and acetylcholine (ACh) and the cotransmitter neuropeptide Y (NPY) in sympathetic ganglionic neurons cocultured with cardiac myocytes. Using antibodies against NPY and the vesicular NE and ACh transporters VMAT2 and vesicular acetylcholine transporter (VAChT), we investigated the effect of ciliary neurotrophic factor (CNTF) or long (three weeks) culture periods on the segregation of VMAT2, VAChT, and NPY to separate varicosities. We found that although ganglionic neurons showed cell body coexpression of all the markers examined after three days, VMAT2 was segregated from VAChT in 43% of the VAChT‐positive varicosities. In contrast, VMAT2 was only segregated from NPY in 16.3% of the NPY‐positive varicosities. Cotransmitter segregation and VAChT expression was potentiated by both CNTF and longer times in culture. We also found two types of varicosities: one was smaller and located further from neuronal somata, and the other was larger, proximal to neuronal somata and had a higher level of segregation. These data demonstrate segregation of classical transmitters in sympathetic neurons and plasticity of neurotransmitter segregation. Finally, we discuss a possible functional correlate of segregation in sympathetic neurons. © 2010 Wiley Periodicals, Inc. Develop Neurobiol 70: 913–928, 2010     

Low expression of the ClC-2 chloride channel during postnatal development: a mechanism for the paradoxical depolarizing action of GABA and glycine in the hippocampus.

In early postnatal development, during the period of synapse formation, gamma-aminobutyric acid (GABA) and glycine, the main inhibitory transmitters in the adult brain, paradoxically excite and depolarize neuronal membranes by an outward flux of chloride. The mechanisms of chloride homeostasis are not fully understood. It is known that in adult neurons intracellular chloride accumulation is prevented by a particular type of chloride channel, the ClC-2. This channel strongly rectifies in the inward direction at potentials negative to ECl thus ensuring chloride efflux. We have tested the hypothesis that in the developing hippocampus, a differential expression or regulation of ClC-2 channels may contribute to the depolarizing action of GABA and glycine. We have cloned a truncated form of ClC-2 (ClC-2nh) from the neonatal hippocampus which lacks the 157 bp corresponding to exon 2. In situ hybridization experiments show that ClC-2nh is the predominant form of ClC-2 mRNA in the neonatal brain. ClC-2nh mRNA is unable to encode a full-length protein due to a frameshift, consequently it does not induce any currents upon injection into Xenopus oocytes. Low expression of the full-length ClC-2 channel, could alter chloride homeostasis, lead to accumulation of [Cl-]i and thereby contribute to the depolarizing action of GABA and glycine during early development.     

The neurobiology of female puberty

In this review, studies are described indicating that the increase in pulsatile release of gonadotropin releasing hormone that signals the initiation of puberty requires both changes in transsynaptic communication and the activation of glia-to-neuron signaling pathways. The major players in the transsynaptic control of puberty are neurons that utilize excitatory and inhibitory amino acids as transmitters. Glial cells employ a combination of trophic factors and small cell-cell signaling molecules to regulate neuronal function and thus promote sexual development. A neuron-to-glia signaling pathway mediated by excitatory amino acids serves to coordinate the simultaneous activation of transsynaptic and glia-to-neuron communication required for the advent of sexual maturity.     

Neurotransmitter metabolism in murine neuroblastoma cells.

Murine neuroblastoma cells in culture are able to synthesize the putative neurotransmitters--acetylcholine, dopamine, norepinephrine, tyramine, octopamine, histamine, serotonin and γ-aminobutyric acid (GABA). They possess not only synthetic, but also degradative enzymes involved in metabolism of these transmitters, and many of these enzymes increase in activity as the cells “differentiate”. Catecholamines, and perhaps other transmitters, appears to be stored within membrane-limited vesicles which accumulate within the process endings of these cells. Uptake of some transmitters, GABA, glycine, dopamine and norepinephrine, shows characteristics of the high affinity transport systems observed in other neuronal populations; uptake of choline and other amino acids is similar to that in non-neuronal populations. Cells show receptor sensitivities to acetyl-choline, dopamine, norepinephrine, prostaglandins E₁ and morphine, as demonstrated by electrophysiologic, toxin binding and cyclic nucleotide studies.     

Transmitter mediated regulation of energy metabolism in nervous tissue at the cellular level

The Monoamines 5-hydroxytryptamine (5-HT), noradrenaline (NA) and histamine, and the peptide Vasoactive Intestinal Polypeptide (VIP), regulate energy metabolism in nervous tissue, in addition to producing excitation and/or inhibition. These transmitters induce glycogen hydrolysis in a concentration dependent manner. The glycogen breakdown is brought about by increased cyclic AMP formation, or translocation of calcium ions to activate phosphorylase, and is partially localized in glial cells. Data from a diversity of nervous systems, including leech and snail ganglia, and rodent cortex, point towards important roles for neurons containing these transmitters in the regulation of the glycogen turnover. It is proposed that energy metabolism may be controlled within domains defined by the geometric arrangements of the neurons releasing these transmitters. The different domains may overlap temporally and spatially to coordinate energy metabolism in relation to increases in neuronal activity. The non-myelin forming glial cells, which contain glycogen whose turnover rate is altered by the transmitters, appear to be important in the local supply of energy substrate to neurons.     

Presynaptic modulation of transmitter release via alpha2-adrenoceptors: nonsynaptic interactions

It is generally accepted that neurochemical transmission occurring at the synapse is the primary way of sending messages from one neuron to another. Neurotransmitters released from axon terminal in a [Ca2+]0-dependent manner act transsynaptically on the postsynaptic site. The past 30 years have witnessed something of a revolution in the understanding of how neurons communicate with each other. It has been shown that the exocytotic release of transmitters from axon terminals is subject to presynaptic modulation via presynatic hetero- and auto-receptors. For example via stimulation of alpha2-adrenoceptors expressed on varicosities and coupled to G-protein the stimulation-evoked release of different transmitters can be inhibited. This review will focus on nonsynaptic interactions between axon terminals. The present data clearly show that transmitters released from axon terminals without synaptic contact play an important role in the fine tuning of communication between neurons within a neuronal circuit.     

A cytokine-dependent switch for glial-neuron interactions

Though transmitters can be released from astrocytes, the conditions that permit their modulation of synaptic transmission are under debate. Santello et al. in this issue of Neuron now show that TNFα promotes a burst mode of glial transmitter release that escapes reuptake processes allowing access to neuronal NMDA receptors.     

Non-neuronal cell conditioned medium stimulates peptidergic expression in sympathetic and sensory neurons in vitro

Regulation of peptide neurotransmitter metabolism was examined in dissociated cell cultures of neonatal rat sympathetic and sensory ganglia. Previous studies have shown that pineal gland conditioned medium (PCM) influences substance P (SP) and somatostatin (SS) metabolism in sympathetic neurons in vitro. The present study examines mechanisms mediating these effects, and compares the actions of PCM on sympathetic and sensory neurons. PCM treatment increased SP levels in a dose-dependent manner without altering SS content of sympathetic neurons cultured in the presence of ganglion non-neuronal cells. Conversely, treatment of pure sympathetic neuron cultures resulted in a dose-dependent increase in SS, while SP was virtually undetectable at all doses. By contrast, dorsal root ganglion, trigeminal ganglion, and nondose ganglion sensory neurons contained SP both in the presence and absence of ganglion non-neuronal cells. Moreover, in each of these neuronal populations treatment with PCM increased SP levels both in the presence and in the absence of ganglion non-neuronal cells. These observations suggest that ganglion non-neuronal cells are necessary for sympathetic but not sensory neuron expression of SP. Moreover, PCM apparently stimulates SP in neurons which already contain the peptide, but the factor cannot foster de novo expression of the phenotype. PCM also influenced other transmitter traits in sympathetic neurons, suggesting linkage between mechanisms regulating peptides and other transmitters. In cultures containing both sympathetic neurons and non-neuronal cells, PCM treatment increased cholineacetyltransferase (CHAC) activity as well as SP, and decreased tyrosine hydroxylase (TOH) activity. By contrast, PCM treatment of pure sympathetic neuron cultures led to parallel increases in SS and TOH activity with negligible levels of SP and CHAC. These observations suggest that in sympathetic neurons, SS may be linked with noradrenergic expression, while SP is associated with cholinergic development, although more data are required to confirm this relationship. Moreover, there may be a reciprocal relationship between SP and SS expression by sympathetic neurons analogous to previous observations regarding cholinergic-noradrenergic expression (P. H. Patterson and L. L. Y. Chun, Proc. Natl. Acad. Sci. USA 71, 3607-3610, 1974; Dev. Biol. 56, 263-280, 1977). Consequently, neurotransmitter phenotypic expression is a complex process in which the environment regulates a balance among multiple transmitters.     

Neuropeptides in flatworms

The use of well-characterized antibodies raised to neuronal signal substances and their application through immunocytochemistry and confocal scanning laser microscopy has revolutionized studies of the flatworm nervous system (NS). Data about flatworm neuropeptides and the spatial relationship between neuropeptides and other neuronal signal substances and muscle fibers are presented. Neuropeptides form a large part of the flatworm NS. Neuropeptides are especially important as myoexcitatory transmitters or modulators, controlling the musculature of the attachment organs, the stomatogastric and the reproductive systems.     

Developmental and Activity-Dependent miRNA Expression Profiling in Primary Hippocampal Neuron Cultures

MicroRNAs (miRNAs) are evolutionarily conserved non-coding RNAs of ∼22 nucleotides that regulate gene expression at the level of translation and play vital roles in hippocampal neuron development, function and plasticity. Here, we performed a systematic and in-depth analysis of miRNA expression profiles in cultured hippocampal neurons during development and after induction of neuronal activity. MiRNA profiling of primary hippocampal cultures was carried out using locked nucleic-acid-based miRNA arrays. The expression of 264 different miRNAs was tested in young neurons, at various developmental stages (stage 2–4) and in mature fully differentiated neurons (stage 5) following the induction of neuronal activity using chemical stimulation protocols. We identified 210 miRNAs in mature hippocampal neurons; the expression of most neuronal miRNAs is low at early stages of development and steadily increases during neuronal differentiation. We found a specific subset of 14 miRNAs with reduced expression at stage 3 and showed that sustained expression of these miRNAs stimulates axonal outgrowth. Expression profiling following induction of neuronal activity demonstrates that 51 miRNAs, including miR-134, miR-146, miR-181, miR-185, miR-191 and miR-200a show altered patterns of expression after NMDA receptor-dependent plasticity, and 31 miRNAs, including miR-107, miR-134, miR-470 and miR-546 were upregulated by homeostatic plasticity protocols. Our results indicate that specific miRNA expression profiles correlate with changes in neuronal development and neuronal activity. Identification and characterization of miRNA targets may further elucidate translational control mechanisms involved in hippocampal development, differentiation and activity-depended processes.     

Purinergic P2Y1 Receptors Control Rapid Expression of Plasma Membrane Processes in Hippocampal Astrocytes

Astrocytes regulate neuronal activity and blood brain barrier through tiny plasma membrane branches or astrocytic processes (APs) making contact with synapses and brain vessels. Several transmitters released by astrocytes and exerting their action on several receptor classes expressed by astrocytes themselves influence their physiology. Here we found that APs are dynamically modulated by purines. In live imaging experiments carried out in rat hippocampal astrocytes, Gq-coupled P2Y1 receptor blockade with the selective antagonist MRS2179 (1 μM) or inhibition of its effector phospholipase C using U73122 (3 μM) produced APs retraction, while stimulation of the same receptor with the selective agonist 2MeSADP (100 μM) increased their number. Since astrocytes, among other transmitters, release ATP by several mechanisms including connexin hemichannels, we used the connexin hemichannel inhibitor carbenoxolone (100 μM) and APs retraction was observed. In our system we then measured expression or function of channels important for modulation of volume transmission and K+ buffering, aquaporin-4, and K+ inward rectifying (Kir) channels, respectively. Aquaporin-4 expression level did not change whereas, in whole-cell patch-clamp recordings performed to measure Kir current, we observed an increase in K+ current in all conditions where APs number was reduced. These data are supporting the idea of a dynamic modulation of astrocytic processes by purinergic signal, strengthening the role of purines in brain homeostasis.     

Neurocalcin-like immunoreactivity in embryonic stages of the gastropod molluscs Aplysia californica and Lymnaea stagnalis

Abstract. Neurocalcin is a calcium-binding protein that has been localized in neural and non-neural tissues of vertebrates, the arthropod Drosophila melanogaster , and in juveniles and adults of the mollusc Aplysia californica . We examine the distribution of neurocalcin in pre-hatching stages of the molluscs A. californica and Lymnaea stagnalis to elucidate where this calcium-binding protein functions in early development, as well as to localize novel neuronal populations in early stages of ontogeny. Aplysia neurocalcin (ApNc)-like immunoreactivity was localized in shell-secreting cells in embryonic stages of both A. californica and L. stagnalis . In A. californica , central and anterior regions of the embryo were diffusely labeled, as were a few identifiable neurons in veliger stages, On the other hand, in L. stagnalis , ApNc-like immunoreactivity was clearly detected in cells and fibers in the same locations as neuronal elements that have been previously identified very early in development and throughout the embryonic period using techniques to localize specific transmitters and peptides. Furthermore, additional neurons are also identified with anti- ApNc in this species. Establishing the distribution of neurocalcin-like proteins in embryonic stages of these two molluscs provides the first step to understanding the role of such proteins during development.     

Histochemistry and functional significance of putative neocortical transmitter substances: a review

1. Intrinsic neuronal chains of the neocortex communicate most probably with amino acid transmitters. These involve both excitatory (glutamate, aspartate--Nadler et al. 1976) both inhibitory (GABA--Ribak 1978) amino acids, and ensure fast, ionotropic postsynaptic actions (Eccles, McGeer 1979). 2. Some interneurons of the neocortex seemingly operate with the peptide transmitter VIP (Lorén et al. 1979). Presumably, this is a metabotropic, slowly acting substance (Dodd, Kelly and Said 1979). 3. The existence of intrinsic cholinergic neurons in the neocortex is a matter of question (Krnjevic and Silver 1965). It is worth to mention that in the periphery, cholinergic terminals also contain and release VIP (H?kfelt et al. 1980). It is not known, whether this transmitter dualism can be found in neocortex, too. An ascending cholinergic system projecting from the basal forebrain to the neocortex exists and exerts profound influence on cortical function (Shute and Lewis 1967). 4. Diffusely terminating, ascending monoamine axons innervate the neocortex and modulate interneuronal transmission (Thiery et al. 1977; Morrison et al. 1981, Lidov et al. 1981). 5. The neuropeptide SP excites cortical neurons (Phillis and Limacher 1974), and its presence in thin axons can be demonstrated immunohistochemically (H?kfelt et al. 1976). 6. Neocortical efferents to the thalamus and striatum seemingly use glutamate or aspartate (Fonnum et al. 1981). The transmitters of other corticofugal projections are not known. 7. The transmitters of specific thalamic afferents and those of callosal and association projections are unknown, too. 8. The main task of future histochemistry is to explore the synaptology of neocortical neurons and afferent systems with identified or evidenced transmitters, viz. to explore the neurochemical subsystems of cortical organization. The tool for it could be the immunohistochemistry, and future development depends mainly on the synthesis and purification of suitable antigens. The knowledge on the synaptology of identified neurochemical units of the cortex would be the basis of the understanding at least partly of the pharmacological effects exerted by the putative neocortical transmitters.     

The aging brain: protein phosphorylation as a target of changes in neuronal function.

There is evidence that senescence affects neurotransmission at different levels. In particular, this review summarizes the studies on age-dependent modifications in protein phosphorylation, which represents the final pathway in the action of transmitters and hormones at neuronal level. Cyclic AMP-dependent protein kinase and protein kinase C have been reported to be modified during aging in various cerebral areas; the changes may involve either enzyme activity or substrate availability. These findings can be related to the alterations in neurotransmitter function and synaptic efficiency observed in the senescent brain. The activity of the other types of protein kinases (tyrosine-, cGMP-, calcium/calmodulin-dependent) during aging needs to be explored. An emerging point is the role of protein phosphorylation in the transfer of membrane signals to the nucleus, for the activation or disactivation of specific genes responsible for long-term neuronal events. Along this view, alterations in protein kinase pathway during senescence would ultimately affect gene expression, resulting in long term modifications of cell function. The reviewed literature opens the perspective of restoring some of the deficits associated with senescence by modulating protein phosphorylation pathway.     

Neuronal messengers in the human cerebral circulation

In recent years our knowledge of the nervous control of the cerebral circulation has increased. The use of denervations and retrograde tracing in combination with immunohistochemical techniques has demonstrated that cerebral vessels are supplied with sympathetic, parasympathetic, and sensory nerve fibers and possibly central pathways containing a multiplicity of new transmitter substances in addition to the classical transmitters. The majority of these transmitters are neuropeptides. More recently it has been suggested that a gaseous transmitter, nitric oxide (NO) also could participate in the neuronal regulation of cerebral blood flow. Although little is known about the physiological actions and inter-relationships among all these putative neurotransmitters, their presence within cerebrovascular nerve fibers will make it necessary to revise our view on the mechanisms of cerebrovascular neurotransmission.