All-trans retinoic acid promotes neural lineage entry by pluripotent embryonic stem cells via multiple pathways

Background  

All-trans retinoic acid (RA) is one of the most important morphogens with pleiotropic actions. Its embryonic distribution correlates with neural differentiation in the developing central nervous system. To explore the precise effects of RA on neural differentiation of mouse embryonic stem cells (ESCs), we detected expression of RA nuclear receptors and RA-metabolizing enzymes in mouse ESCs and investigated the roles of RA in adherent monolayer culture.     

Mechanisms of morphogen movement

Morphogens are defined as signaling molecules that are produced locally, yet act directly at a distance to pattern the surrounding field of cells in a concentration-dependent manner. In recent years many laboratories have devoted their attention to how morphogens actually reach distant cells. Several models have been proposed, including diffusion in the extracellular space and planar transcytosis. A combination of genetic, developmental, and cell-biological approaches have been taken to tackle this issue. I will present the models and discuss the types of experiments that have been designed to test them. It stands out that most of the work has been carried out in Drosophila. Morphogens contribute to patterning of the vertebrate nervous system, and the same signaling molecules have recently been shown to play important, possibly instructive, roles in axon guidance. Little, if anything, is known about the movement of morphogens in the context of nervous system development. The long-standing tradition of biophysical studies on diffusion in the brain extracellular space, along with the sophisticated in vitro culture systems developed in neurobiology laboratories, may provide new tools and ideas to test these models in a new context.     

Diet, central nervous system, and aging.

A variety of morphological, structural, and chemical changes have been described in the central nervous systems of aging humans and animals. Brain size and volume decline during senescence, and the brain atrophy is accompanied by changes in the number, size, and ultrastructural characteristics of nerve and glial cells. Moreover, recent evidence suggests that the ability of central nervous system cells to communicate with one another via the release of neurotransmitter compounds might be impaired in the elderly. Nutritional factors may play important roles in the aging process of the central nervous system by influencing brain neurotransmission, or by accelerating or retarding geriatric changes in central nervous system structure.     

Glycobiology of the synapse: the role of glycans in the formation,maturation, and modulation of synapses

Synapses, which are the fundamental functional unit of the nervous system, are considered to be highly specialized cell adhesion structures. Studies since the 1960s demonstrated that various carbohydrates and glycoproteins are expressed in synapses in the central and peripheral nervous system. Although the functional roles of these synaptic carbohydrates and glycoproteins remain to be determined, rapidly accumulating data suggest that they may play critical roles in the formation, maturation, and functional modulation of synapses.     

Glycobiology of the synapse: the role of glycans in the formation,maturation, and modulation of synapses

Synapses, which are the fundamental functional unit of the nervous system, are considered to be highly specialized cell adhesion structures. Studies since the 1960s demonstrated that various carbohydrates and glycoproteins are expressed in synapses in the central and peripheral nervous system. Although the functional roles of these synaptic carbohydrates and glycoproteins remain to be determined, rapidly accumulating data suggest that they may play critical roles in the formation, maturation, and functional modulation of synapses.     

Novel brain wiring functions for classical morphogens: a role as graded positional cues in axon guidance

During embryonic development, morphogens act as graded positional cues to dictate cell fate specification and tissue patterning. Recent findings indicate that morphogen gradients also serve to guide axonal pathfinding during development of the nervous system. These findings challenge our previous notions about morphogens and axon guidance molecules, and suggest that these proteins, rather than having sharply divergent functions, act more globally to provide graded positional information that can be interpreted by responding cells either to specify cell fate or to direct axonal pathfinding. This review presents the roles identified for members of three prominent morphogen families--the Hedgehog, Wnt and TGFbeta/BMP families--in axon guidance, and discusses potential implications for the molecular mechanisms underlying their guidance functions.     

Morphogens in motion: growth control of the neural tube

The entire vertebrate nervous system develops from a simple epithelial sheet, the neural plate which, along development, acquires the large number and wide variety of neuronal cell types required for the construction of a functional mature nervous system. These include processes of growth and pattern formation of the neural tube that are achieved through complicated and tightly regulated genetic interactions. Pattern formation, particularly in the vertebrate central nervous system, is one of the best examples of a morphogen-type of function. Cell cycle progression, however, is generally accepted to be dependent on cell-intrinsic factors. Recent studies have demonstrated that proliferation of neural precursors is also somehow controlled by secreted signaling molecules, well-known by their role as morphogens, such as fibroblast growth factor (FGF), vertebrate orthologs of the Drosophila wingless (Wnt), hedgehog (Hh), and transforming growth factor beta (TGF-beta) families, that in turn regulate the activity of factors controlling cell cycle progression. In this review we will summarize the experimental data that support the idea that classical morphogens can be reused to regulate proliferation of neural precursors.     

Neuropeptide Y and peptide YY neuronal and endocrine systems

An extensive system of neuropeptide Y (NPY) containing neurons has recently been identified in the central and peripheral nervous system. In addition, NPY and a structurally related peptide, peptide YY (PYY), containing endocrine cells have been identified in the periphery. The NPY system is of particular interest as the peptide coexists with catecholamines in the central and sympathetic nervous system and adrenal medulla. Evidence has been presented which indicates that NPY may play important roles in regulating autonomic function.     

Principles of glutamatergic synapse formation: seeing the forest for the trees

General principles regarding glutamatergic synapse formation in the central nervous system are beginning to emerge. These principles concern the specific roles that dendrites and axons play in the induction of synaptic differentiation, the modes of presynaptic and postsynaptic assembly, the time course of synapse formation and maturation, and the roles of synaptic activity in these processes.     

Ontogenetic expression of CART-peptides in the central nervous system and the periphery: a possible neurotrophic role?

Little attention has been devoted to the expression of CART during development. However, a few studies in the central nervous system and periphery provide a clear indication that these peptides may play significant roles during histogenesis, and may have trophic actions.     

Developing a complete pharmacology for AMPA receptors: A perspective on subtype-selective ligands

AMPA receptors are a family of ligand-gated ion channels that play central roles in rapid neural signaling and in regulation of synaptic strength. Additionally, these receptors are implicated in a number of major psychiatric and neurological diseases. A comprehensive understanding of the roles that AMPA receptors play in the mammalian nervous system has been hampered by the dearth of ligands available to select between individual AMPA receptors subtypes. Here we provide a perspective on opportunities for developing a complete pharmacology for AMPA receptors.     

Longitudinal axon guidance

Our knowledge about molecular mechanisms underlying axon guidance along the antero-posterior axis in contrast to the dorso-ventral axis of the developing nervous system is very limited. During the past two years in vitro and in vivo studies have indicated that morphogens have a role in longitudinal axon guidance. Morphogens are secreted proteins that act in a concentration-dependent manner on susceptible groups of precursor cells and induce their differentiation to a specific cell fate. Thus, gradients of morphogens are responsible for the appropriate patterning of the nervous system during early phases of neural development. Therefore, it was surprising to find that gradients of two of these morphogens, Wnt4 and Shh, can be re-used for longitudinal axon guidance during later stages of nervous system development.     

Obesity-induced Hypertension: Role of Sympathetic Nervous System,Leptin, and Melanocortins

Excess weight gain contributes to increased blood pressure in most patients with essential hypertension. Although the mechanisms of obesity hypertension are not fully understood, increased renal sodium reabsorption and impaired pressure natriuresis play key roles. Several mechanisms contribute to altered kidney function and hypertension in obesity, including activation of the sympathetic nervous system, which appears to be mediated in part by increased levels of the adipocyte-derived hormone leptin, stimulation of pro-opiomelanocortin neurons, and subsequent activation of central nervous system melanocortin 4 receptors.     

Toll信号通路在中枢神经系统损伤中的作用

Toll样受体(Toll-like receptors,TLR)是先天性免疫反应识别病原体的一个重要分子,在免疫系统中发挥关键作用.其家族各种成员的主要功能是识别入侵病原体表面的各种不同分子模式,随后启动免疫反应,达到保护机体作用.在大脑中,小胶质细胞可以作为抗原提呈细胞,参与脑内免疫反应,也可以通过分泌各种促炎症因子启动或促进免疫反应,而TLR家族在中枢神经免疫系统的作用仍存在争议,它既可以通过促进神经免疫反应枢纽因子的表达来增强免疫,也可因免疫过度而损伤神经细胞.总之,Toll信号通路对中枢神经系统疾病有一定的调控作用.     

Patterns of sequence conservation in presynaptic neural genes

Background  

The neuronal synapse is a fundamental functional unit in the central nervous system of animals. Because synaptic function is evolutionarily conserved, we reasoned that functional sequences of genes and related genomic elements known to play important roles in neurotransmitter release would also be conserved.     

Functional roles of microglia in the central nervous system

Microglia, a type of perineuronal glial cells in the central nervous system, have been suggested to play various important roles in normal and pathologic brains. In this article, first, we described the association or roles of activated microglia in injury and various brain diseases, and subsequently, summarized microglia-derived physiologically active molecules which will affect the neuronal survival and neuronal growth, and glial function, and finally, discussed the molecular mechanism of microglial activation.     

长链非编码RNA在神经系统中的研究进展

长链非编码RNA (long noncoding RNA, lncRNA)是多种复杂有机体转录组中最主要的一类转录本. lncRNA在各种生物之间序列保守性差、表达量普遍比较低.与编码基因相比,lncRNA有相似的启动子区域以及剪切位点,具有较好的细胞和组织特异性分布,尤其在神经系统中具有较为丰富的表达,提示它们在神经系统中具有不可忽视的作用.本文围绕近几年lncRNA在神经系统方面的最新研究成果,总结了lncRNA对中枢和外周神经系统发育以及对神经系统功能等方面的调控作用及机制.同时展望了有关lncRNA研究的新理念和新技术及对未来神经科学研究的推动作用.     

cDNA cloning, characterization, and brain region-specific expression of a neuromedin-B-preferring bombesin receptor.

Recent binding studies in the central nervous system and other tissues provide evidence that the mammalian bombesin-like peptides, gastrin-releasing peptide (GRP) and neuromedin-B (NMB), exert their numerous physiological effects through at least two different receptors. We describe the structure and expression of a cloned NMB-preferring bombesin receptor (NMB-R) with properties distinct from a GRP-preferring bombesin receptor (GRP-R) reported previously. In particular, the NMB-R shows higher affinity binding to NMB than to GRP in BALB 3T3 fibroblasts expressing the cloned NMB-R. The distinct regional distribution of NMB-R and GRP-R mRNA in the brain suggests that both bombesin receptor subtypes play independent roles in mediating many of the dramatic effects of bombesin-like peptides in the central nervous system.