科研人员研究发现Netrin引起轴突生长和导向的新机制

在神经系统发育过程中,新生神经元的轴突要经历漫长的历程才能到达预定的脑区,然后与靶区神经元建立突触联系进而形成神经系统复杂的网络系统。因此,发育中轴突的生长和导向是形成正常神经系统功能的前提和保证;相反,轴突发育的异常会导致多种神经系统疾病,包括智力障碍和癫痫发作等。     

Bmal1对小鼠胚胎期皮层神经元放射状迁移和轴突投射的影响

大脑皮层的发育是脑结构形成与功能建立的重要基础,在此过程中,皮层神经元放射状迁移及胼胝体区的轴突投射是必不可少的关键环节,该环节受基因转录的调控,但相关的分子机制目前仍不明确。转录因子BMAL1 (brain and muscle Arnt-like protein1)是体内重要的生物钟节律因子之一,最新研究发现其还参与调节海马神经祖细胞增殖,提示其与神经发育存在潜在的相关性。为明确Bmal1基因在大脑皮层发育中的具体作用,本研究首先通过RT-PCR和Real-timePCR检测Bmal1基因在神经系统中的表达情况。结果表明,Bmal1基因在神经系统中表达丰富,并且在发育期的大脑内呈现特定的表达规律:在胚胎后期和出生后早期脑内表达水平相对较高,以出生后第3 d为高峰。进一步通过联合使用小鼠子宫内胚胎电转和RNAi干扰方法敲减脑内神经元中Bmal1的表达水平,结果发现胚胎期皮层神经元的放射状迁移发生了延迟,延迟程度与RNAi的敲减效率呈正相关,存在一定的基因剂量-效应关系。进一步观察发现,在胚胎期脑内神经元中降低Bmal1表达水平以后,胼胝体轴突向对侧大脑半球的投射也出现了明显的缺陷。上述研究结果表明,BMAL1是大脑皮层神经元的放射状迁移以及轴突投射发育过程中的一个重要的调控分子,为从转录因子角度深入理解大脑皮层发育的分子调节机制和寻找调控靶点提供了新的线索。     

Schwann细胞在髓鞘形成过程中的极性调控

周围神经系统髓鞘形成依赖Schwann细胞和神经元之间复杂的相互作用。细胞极性分子蛋白Par-3在Schwann细胞与轴突接触面密集分布,为BDNF/p75NTR介导的启动成髓提供分子支架。然而,Par-3在该界面聚集并呈不对称性分布的机制仍是一个谜。不少研究发现,JAM和nectin等细胞粘附分子与Par-3不对称性分布有关。另外,通过改变轴突信号如神经营养因子和神经素的水平,也能影响Schwann髓鞘的形成。本文综述和阐释在髓鞘形成过程中,Schwann细胞极性是如何被调控的。     

中枢神经系统少突胶质细胞前体细胞产生的研究进展

少突胶质细胞(oligodendrocytes,OLs)在脊椎动物中枢神经系统(central nervous system,CNS)中负责形成包裹神经元轴突的髓鞘,保证神经冲动沿轴突的快速传导,并为其提供营养支持。OLs发育异常及损伤会导致严重的神经系统疾病,比如脑白质营养不良(leukodystrophy)、多发性硬化症(multiple sclerosis,MS)等。少突胶质细胞前体细胞(oligodendrocyte progenitor cells,OPCs)在胚胎期由神经前体细胞(neural progenitor cells,NPCs)产生,该过程受到一系列细胞内外因素的调控,对这一问题的研究也是神经系统研究的重要内容。现主要基于遗传学结果,简述关于OPCs产生的调控机制的最新研究进展。     

神经元轴突信号调节髓鞘发育的研究进展

神经元轴突外包裹的髓鞘结构对于提高神经元传导速率,维持神经系统稳定性有重要作用。在中枢神经系统中,髓鞘主要由少突胶质细胞形成。成髓鞘过程在内源性和外源性因素的共同调节下进行,神经元轴突信号在这个过程中扮演重要角色。髓鞘发育过程依赖于轴突的促进信号和抑制信号的相互平衡:促进信号包括层粘连蛋白和神经调节素等,神经元电信号能启动并促进髓鞘再生;抑制信号包括细胞黏附分子以及Notch信号。本文综述了一些因子尤其是神经元信号在髓鞘发育中的作用,也讨论了脱髓鞘疾病中神经元如何参与髓鞘再生。这些总结有助于理解髓鞘发育的机制,也有助于脱髓鞘疾病的研究和治疗。     

大脑皮层神经元放射状迁移的分子调控机制

神经元放射状迁移是一个复杂而又精确的过程,对大脑皮层的正常发育和功能发挥起着不可忽视的作用。近几年来的研究表明,许多重要的小分子分别从不同方面参与对这一过程的调控。对这些分子的调控机制进行深入研究,将有助于我们对神经系统发育机理和相关疾病发病机制的认识。下面就目前已发现的调控神经元放射状迁移的一些关键分子机制进行综述。     

神经迁移因子在血管系统中的表达与功能

神经迁移因子是近10年来在发育神经生物学中的研究热点,主要由ephrin、neuropilin、Slit和netrin四大家族成员构成,其主要功能是吸引或排斥神经元轴突的迁移,在神经系统中发挥着重要作用。现在,越来越多的实验证据表明：神经迁移因子的作用不仅仅局限在神经系统发育过程中,在血管发生或新生血管形成中同样具有不可替代的功能。     

5-羟甲基胞嘧啶在脑发育和神经系统疾病中的作用

大脑的发育和神经系统疾病的发生发展是极其复杂的过程,涉及多种因素. 大量研究证实,表观遗传调控系统,如组蛋白甲基化、组蛋白乙酰化和DNA甲基化,是其中一类重要的调控因素. 近年来研究发现,DNA去甲基化中间产物5-羟甲基胞嘧啶(5hmC)是一种新的表观遗传标记形式,且在神经元内呈现非常高的水平. 这暗示5hmC可能在脑的生长发育以及中枢神经系统疾病的发生发展过程中有着重要的调控作用. 本文综述了近年来该领域的重要研究进展,并且提出一些今后的研究展望.     

5-羟甲基胞嘧啶及其TET氧合酶在神经系统发育和相关疾病中的研究进展

神经系统的正常发育是多种因素相互协调作用的结果,一旦特定因素失衡将引起相关疾病的发生。近年来不断有研究发现,DNA去甲基化过程的一类中间产物5-羟甲基胞嘧啶(5-hydroxymethylcytosine, 5hmC)作为一种新的表观遗传标记,在神经系统中高水平分布,并参与认知、记忆等重要的神经功能。5hmC的形成由氧合酶家族分子(ten-eleven translocation protein, TET)催化,在多种神经系统相关疾病中,5hmC水平和TETs分子的表达都发生改变,提示TET-5hmC表观遗传机制在复杂的神经系统发生发展过程中发挥了重要的调控作用。此外,作为基因表达调控的DNA标记物,5hmC的基因定位与基因表达水平的关系也是重要的研究方向。本文就近年来5hmC和TET家族蛋白分子在神经系统发育和相关疾病方面的重要研究发现进行了综述总结,希望为相关领域研究人员深入开展研究提供重要的思路,并为相关疾病设计治疗策略提供理论支持。     

Axon Guidance at the Midline: From Mutants to Mechanisms

How axons in the developing nervous system successfully navigate to their correct targets is a fundamental problem in neurobiology. Understanding the mechanisms that mediate axon guidance will give important insight into how the nervous system is correctly wired during development and may have implications for therapeutic approaches to developmental brain disorders and nerve regeneration. Achieving this understanding will require unraveling the molecular logic that ensures the proper expression and localization of axon guidance cues and receptors, and elucidating the signaling events that regulate the growth cone cytoskeleton in response to guidance receptor activation. Studies of axon guidance at the midline of many experimental systems, from the ventral midline of Drosophila to the vertebrate spinal cord, have led to important mechanistic insights into the complex problem of wiring the nervous system. Here we review recent advances in understanding the regulation of midline axon guidance, with a particular emphasis on the contributions made from molecular genetic studies of invertebrate model systems.     

Reciprocal interactions between olfactory receptor axons and olfactory nerve glia cultured from the developing moth Manduca sexta

In olfactory systems, neuron-glia interactions have been implicated in the growth and guidance of olfactory receptor axons. In the moth Manduca sexta, developing olfactory receptor axons encounter several types of glia as they grow into the brain. Antennal nerve glia are born in the periphery and enwrap bundles of olfactory receptor axons in the antennal nerve. Although their peripheral origin and relationship with axon bundles suggest that they share features with mammalian olfactory ensheathing cells, the developmental roles of antennal nerve glia remain elusive. When cocultured with antennal nerve glial cells, olfactory receptor growth cones readily advance along glial processes without displaying prolonged changes in morphology. In turn, olfactory receptor axons induce antennal nerve glial cells to form multicellular arrays through proliferation and process extension. In contrast to antennal nerve glia, centrally derived glial cells from the axon sorting zone and antennal lobe never form arrays in vitro, and growth-cone glial-cell encounters with these cells halt axon elongation and cause permanent elaborations in growth cone morphology. We propose that antennal nerve glia play roles similar to olfactory ensheathing cells in supporting axon elongation, yet differ in their capacity to influence axon guidance, sorting, and targeting, roles that could be played by central olfactory glia in Manduca.     

The development of a long,coiled, optic nerve in the stalk-eyed fly <Emphasis Type="Italic">Cyrtodiopsis whitei</Emphasis>

In the stalk-eyed fly Cyrtodiopsis whitei (Diopsidae; Diptera), the relatively long optic nerve develops within the tight lumen of a very short eyestalk. Axonal growth is generally considered in terms of path finding, selective fasciculation, and towing. Physical forces that are necessary for axon lengthening are generated either by the growth cone or by the growth of surrounding tissues. Therefore, it is surprising to encounter a loosely coiled nerve apparently lacking any attachments that could allow for pull, or towing, of the nerve. In this study, we used histological sections and whole-mount preparations to confirm that the optic nerve of the stalk-eyed fly indeed elongates without the external application of tension to the nerve. Secondly, we examined the distribution of cytoskeletal elements and selected proteins that may be involved in axon extension. Staining against the vesicle fusion proteins SNAP-24 and SNAP-25 consistently results in stronger staining in the rapidly extending optic nerve than in a control nerve, suggesting a possible role of these proteins in the extension process. On a gross morphological level, SNAP-24/25 as well as the cytoskeletal elements actin and tubulin are uniformly distributed throughout the lengths of the growing nerve, suggesting that nerve elongation is distributed rather than localized. Finally, we identified glia as a possible source for tension within the nerve bundle. Glia proliferate rapidly in the optic nerve but not in the control nerve. Much work continues to focus on the growth of axons in culture, but this study is one of the few that considers the dynamics of nerve bundle extension as a whole.This research is supported by the National Science Foundation (IBN-9974512 and IBN-211770).     

Patched regulation of axon guidance is by specifying neural identity in the<Emphasis Type="Italic"> Drosophila</Emphasis> nerve cord

Within an axon bundle, one or two are pioneering axons and the rest are follower axons. Pioneering axons are projected first and the follower axons are projected later but follow a pioneering axon(s) pathway. It is not clear whether the pioneering axons have a guidance role for follower axons. In this paper, we have investigated the role of Patched (Ptc) in regulating the guidance of medial tract, one of the longitudinal tracts in the nerve cord. In patched mutants the medial longitudinal tract fails to fasciculate on its own side along the nerve cord, instead it abnormally crosses the midline and fasciculates with the contralateral tract. Interestingly, the medial tracts cross the midline ignoring the axon-repellant Slit on the midline and Roundabout on growth cones. The medial tract is pioneered by neurons pCC and vMP2. Our results show that guidance defects of this tract are due to loss and mis-specification of vMP2, which results in the projection from pCC to either stall or project outward near the location of vMP2. Thus, both pioneering neurons are necessary for the proper guidance of pioneering and follower axons. We also show that the loss of Ptc activity in the neuroectoderm prior to the formation of S1 and S2 neuroblasts causes the majority of axon guidance defects. These results provide insight into how mis-specification and loss of neurons can non-autonomously contribute to defects in axon pathfinding.     

Genes required for axon pathfinding and extension in the C. elegans nerve ring.

Over half of the neurons in Caenorhabditis elegans send axons to the nerve ring, a large neuropil in the head of the animal. Genetic screens in animals that express the green fluorescent protein in a subset of sensory neurons identified eight new sax genes that affect the morphology of nerve ring axons. sax-3/robo mutations disrupt axon guidance in the nerve ring, while sax-5, sax-9 and unc-44 disrupt both axon guidance and axon extension. Axon extension and guidance proceed normally in sax-1, sax-2, sax-6, sax-7 and sax-8 mutants, but these animals exhibit later defects in the maintenance of nerve ring structure. The functions of existing guidance genes in nerve ring development were also examined, revealing that SAX-3/Robo acts in parallel to the VAB-1/Eph receptor and the UNC-6/netrin, UNC-40/DCC guidance systems for ventral guidance of axons in the amphid commissure, a major route of axon entry into the nerve ring. In addition, SAX-3/Robo and the VAB-1/Eph receptor both function to prevent aberrant axon crossing at the ventral midline. Together, these genes define pathways required for axon growth, guidance and maintenance during nervous system development.     

Feedback-controlled dynamics of neuronal cells on directional surfaces

The formation of neuronal networks is a complex phenomenon of fundamental importance for understanding the development of the nervous system. The basic process underlying the network formation is axonal growth, a process involving the extension of axons from the cell body and axonal navigation toward target neurons. Axonal growth is guided by the interactions between the tip of the axon (growth cone) and its extracellular environmental cues, which include intercellular interactions, the biochemical landscape around the neuron, and the mechanical and geometrical features of the growth substrate. Here, we present a comprehensive experimental and theoretical analysis of axonal growth for neurons cultured on micropatterned polydimethylsiloxane (PDMS) surfaces. We demonstrate that closed-loop feedback is an essential component of axonal dynamics on these surfaces: the growth cone continuously measures environmental cues and adjusts its motion in response to external geometrical features. We show that this model captures all the characteristics of axonal dynamics on PDMS surfaces for both untreated and chemically modified neurons. We combine experimental data with theoretical analysis to measure key parameters that describe axonal dynamics: diffusion (cell motility) coefficients, speed and angular distributions, and cell-substrate interactions. The experiments performed on neurons treated with Taxol (inhibitor of microtubule dynamics) and Y-27632 (disruptor of actin filaments) indicate that the internal dynamics of microtubules and actin filaments plays a critical role for the proper function of the feedback mechanism. Our results demonstrate that axons follow geometrical patterns through a contact-guidance mechanism, in which high-curvature geometrical features impart high traction forces to the growth cone. These results have important implications for our fundamental understanding of axonal growth as well as for bioengineering novel substrate to guide neuronal growth and promote nerve repair.     

Diffuse serotoninergic neurohemal systems associated with cerebral and suboesophageal nerves in the head of the Colorado potato beetle Leptinotarsa decemlineata

We analyzed the anatomy of two diffuse neurohemal systems for serotonin in the head of the Colorado potato beetle Leptinotarsa decemlineata by means of immunohistochemistry. One system is formed by axons from two bilateral pairs of neurons in the frontal margin of the suboesophageal ganglion that enter the ipsilateral mandibular nerve, emerge from this nerve at some distance from the suboesophageal ganglion, and cover all branches of the mandibular nerve with a dense plexus of immunoreactive axon swellings. The other system is formed by axons from two large neurons in the frontal ganglion that enter the ipsilateral frontal connectives, emerge from these connectives, and form a network of axon swellings on the labroforntal, pharyngeal, and antennal nerves and on the surface of the frontal ganglion. Immunohistochemical electron microscopy demonstrated that the axon swellings are located outside the neural sheaths of the nerves and hence in close contact with the hemolymph. We therefore suggest that these plexuses represent extensive neurohemal systems for serotonin. Most immunoreactive terminals are in direct contact with the hemolymph, and other terminals are closely associated with the muscles of the mandibles, labrum, and anterior pharynx, as well as with the salivary glands, indicating that these organs are under serotoninergic control.     

Electron Microscopy of Peripheral Nerves and Neuromuscular Junctions in the Wasp Leg

The peripheral nerve branch innervating the femoral muscles of the common yellow jacket (Vespula carolina) has been found to possess a thick lemnoblast basement membrane and a complex mesaxon. The term "tunicated nerve" is proposed to designate the type of peripheral nerve in which one or several axons are loosely mantled by meandering, cytoplasm-enclosing membranes of the lemnoblast. The peripheral axon courses longitudinally in a groove in the muscle fiber between the plasma membrane of the muscle fiber and a cap formed by lemnoblast and tracheoblast. The junction is characterized by apposition of plasma membranes of axon and muscle fiber, abundant mitochondria, and synaptic vesicles in the axon, and aggregates of "aposynaptic granules" plus mitochondria and endoplasmic reticulum on the muscle side of the synapse. Unlike the vertebrate striated muscle fiber, no complex infolding of the synapsing plasma membrane of the muscle fiber occurs. The "connecting tissue" of the insect is formed by tracheoblasts, their basement membranes, and the basement membranes of other cells. Further mechanical support is given by the ramifying tracheoles. The physiologic roles of the specialized structures are considered.     

C. elegans dystroglycan coordinates responsiveness of follower axons to dorsal/ventral and anterior/posterior guidance cues

Neural development in metazoans is characterized by the establishment of initial process tracts by pioneer axons and the subsequent extension of follower axons along these pioneer processes. Mechanisms governing the fidelity of follower extension along pioneered routes are largely unknown. In C. elegans, formation of the right angle‐shaped lumbar commissure connecting the lumbar and preanal ganglia is an example of pioneer/follower dynamics. We find that the dystroglycan ortholog DGN‐1 mediates the fidelity of follower lumbar commissure axon extension along the pioneer axon route. In dgn‐1 mutants, the axon of the pioneer PVQ neuron faithfully establishes the lumbar commissure, but axons of follower lumbar neurons, such as PVC, frequently bypass the lumbar commissure and extend along an oblique trajectory directly toward the preanal ganglion. In contrast, disruption of the UNC‐6/netrin guidance pathway principally perturbs PVQ ventral guidance to pioneer the lumbar commissure. Loss of DGN‐1 in unc‐6 mutants has a quantitatively similar effect on follower axon guidance regardless of PVQ axon route, indicating that DGN‐1 does not mediate follower/pioneer adhesion. Instead, DGN‐1 appears to block premature responsiveness of follower axons to a preanal ganglion‐directed guidance cue, which mediates ventral‐to‐anterior reorientation of lumbar commissure axons. Deletion analysis shows that only the most N‐terminal DGN‐1 domain is required for these activities. These studies suggest that dystroglycan modulation of growth cone responsiveness to conflicting guidance cues is important for restricting follower axon extension to the tracts laid down by pioneers. © 2011 Wiley Periodicals, Inc. Develop Neurobiol, 2012