神经细胞粘附分子的研究进展

神经系统的正常发育依赖于细胞与局部环境间复杂的相互作用,这种相互作用受几种细胞粘附分子的介导,神经系统表达多种粘附分子,它们在神经管形成,神经元迁移,迁移后分化,以及成熟神经元结构维持中具有相当重要的作用。另外,细胞粘附分子还促进接触依赖性细胞间连接的形成。     

多聚唾液酸(PSA)及其修饰的神经粘附分子(PSA-NCAM)对肿瘤及细胞信号通路的影响

神经粘附分子(Neural cell adhesion molecule, NCAM)是免疫球蛋白家族中的一员,在细胞粘附和细胞通信,尤其是神经系统的生长和塑型中起重要作用。而多聚唾液酸(Polysialic acid, PSA)则是控制NCAM粘附能力形成与神经系统分化的重要因素。研究发现,多种肿瘤细胞中存在PSA以及多聚唾液酸化的神经粘附分子(PSA-NCAM)再表达的现象,预示PSA及PSA-NCAM与多种肿瘤细胞的粘附性、迁移性和侵袭性等特性密切相关,影响肿瘤细胞的生长与转移,并通过介导多种细胞信号通路影响癌症的发生与发展。文章综述了NCAM以及PSA对癌症的发生与发展、预后的作用及其功能对细胞下游信号传导的影响。     

神经细胞粘附分子与硫酸化氨基聚糖在神经发育、轴突生长、突触可塑性及学习和记忆中的作用

神经细胞粘附分子（neural cell adhesion molecule,NCAM)是一种主要表达于神经系统的糖蛋白,通过亲同性及亲异性结合介导细胞与细胞与细胞外基质间的相互作用,参与细胞的识别,迁移,轴突生长,细胞信号转导,学习和记忆等过程。硫酸化氨基聚糖可调节脑发育中的细胞分化,轴突生长及中枢神经系统中神经元的再生,可能参与了与学习和记忆相关的神经结构功能的调节。这些作用可能与神经细胞粘附分子的亲异性结合有关。     

神经富亮氨酸重复家族成员LRRN3的研究进展

神经富亮氨酸重复家族成员LRRN3(leucine-rich repeat neuronal protein 3)是一种在进化上高度保守,功能多样,由多个连续的LRR结构域、纤维连接蛋白3型结构域(FNⅢ)及IgC2样结构构成的跨膜蛋白,通过介导细胞间粘附作用对神经系统发育起调节作用.已有证据表明,LRRN3除了在神经系统的发生、分化、损伤修复等过程中起作用,还与孤独症等精神障碍的发生密切相关,是神经系统发育过程中重要的蛋白,但目前人们对其生理功能、作用机制及临床意义知之甚少.LRRN3的结构、功能及其与人类疾病间的关系将被重点阐述.     

白细胞与内皮细胞的粘附

白细胞与内皮细胞相互作用由粘附分子介导.整合素、免疫球蛋白及选择素家族的粘附分子在这两种细胞的粘附中起关键作用.粘附的起始阶段由选择素介导,随后由CD11/CD18复合物与ICAM-1形成更为紧密的结合.多种细胞因子及炎症反应可诱导粘附.抗粘附分子单抗、药物等可抑制粘附.     

gp150蛋白在盘基网柄菌发育中的作用及粘附分子间关系的分析

饥饿的盘基网柄菌进入多细胞发育期 ,在发育早期 ,AK12 7细胞 (gp150突变细胞 )能表达DdCAD 1和 gp80两种粘附分子 ,但它们不足以促进细胞继续发育 ,发育停留在细胞疏松结合阶段。粘附分子 gp150调节的细胞与细胞间的粘着影响了细胞丘“突出”的形成 ,由此影响了盘基网柄菌多细胞发育的形态发生。TL93细胞 (DdCAD 1和gp80突变细胞 )能完成发育。主要原因是在细胞流发育阶段就表达了gp150分子 ,在细胞粘着的功能上有替代DdCAD 1和 gp80的作用。因此 gp150蛋白对盘基网柄菌多细胞发育有着不可或缺的作用     

L1CAM胞内区相互作用蛋白的筛选与鉴定

L1细胞粘附分子(L1cell adhesion molecular,L1CAM)属于神经细胞粘附分子,是属于免疫球蛋白超家族的Ⅰ型跨膜糖蛋白.L1主要在神经系统中表达,参与神经系统发育,学习记忆等重要过程作用.L1的胞内区可能参与信号转导,对于L1的功能非常重要,为探讨L1胞内区信号转导的分子机制,以L1胞内区为诱饵运用酵母双杂交技术在人脑cDNA文库中筛选其结合蛋白,挑选阳性克隆,进行DNA序列分析和同源检索,阳性克隆编码几个不同的蛋白质,其中一个候选蛋白为PAX6转录因子.为进一步验证L1胞内区和PAX6的相互作用,克隆其基因到表达质粒共转染COS-7细胞,免疫共沉淀证实了L1胞内区和PAX6的相互作用,提示L1胞内区可能参与转录调节,为深入探讨其功能提供了重要线索.     

FGF8在脊椎动物早期胚胎发育中的调控作用

成纤维细胞生长因子8 (fibroblast growth factor 8,FGF8)是成纤维细胞生长因子家族的成员之一,是一种组织发育过程中的重要分泌性调控信号分子,参与脊椎动物的多种组织器官的发生与发育.早期胚胎细胞通过表达FGF8在组织和器官发育、血管发生、血细胞生成、附肢发生和伤口愈合等方面发挥着重要作用.FGF8不但可以在细胞外通过胞内信号通路,而且也可以进入细胞内部发挥生物学功能.本文就FGF8在脊椎动物神经系统、内脏器官、肢体发育及不对称发育等组织、器官发育中的调控作用予以阐述.     

隧道纳米管：神经系统中的新型细胞间交流结构

隧道纳米管(tunneling nanotubes,TNTs)是基于细胞骨架尤其是纤维状肌动蛋白形成的细胞间管道样结构,其功能主要是介导广泛的细胞间物质交换,包括各种信号分子、RNA、蛋白质、细胞器甚至病原体,在生理和病理过程中都发挥重要作用.各种细胞类型中均发现有TNTs的形成,尤其在神经元细胞和神经胶质细胞中得到广泛关注.神经元细胞间或神经元细胞与星形胶质细胞间形成的TNTs,能够介导电耦合,还参与神经退行性疾病相关致病蛋白质的转移和/或传播,进而在神经系统发育和疾病进展中发挥作用.本文简要总结了在神经系统细胞间形成TNTs的研究进展,包括调节其形成的分子机制、功能和在神经系统疾病治疗中的潜在优势.     

神经细胞粘附分子结构特征和生理功能

神经细胞粘附分子是一类调节细胞与细胞、细胞与细胞外基质间粘附作用的膜表面糖蛋白,主要有NCAM-180、NCAM-140、NCAM-120三种形式,多与PSA结合在一起。在神经系统中,NCAM的表达具有时间和空间特异性,最主要的作用为调节神经系统的可塑性,这种作用可能是通过PSA-NCAM对AMPA的调节作用,主要是通过调节蛋白激酶的表达和细胞内Ca^2 浓度来实现的。     

Misguided axonal projections,neural cell adhesion molecule 180 mRNA upregulation,and altered behavior in mice deficient for the close homolog of L1

Cell recognition molecules are involved in nervous system development and participate in synaptic plasticity in the adult brain. The close homolog of L1 (CHL1), a recently identified member of the L1 family of cell adhesion molecules, is expressed by neurons and glia in the central nervous system and by Schwann cells in the peripheral nervous system in a pattern overlapping, but distinct from, the other members of the L1 family. In humans, CHL1 (also referred to as CALL) is a candidate gene for 3p- syndrome-associated mental impairment. In the present study, we generated and analyzed CHL1-deficient mice. At the morphological level, these mice showed alterations of hippocampal mossy fiber organization and of olfactory axon projections. Expression of the mRNA of the synapse-specific neural cell adhesion molecule 180 isoform was upregulated in adult CHL1-deficient mice, but the mRNA levels of several other recognition molecules were not changed. The behavior of CHL1-deficient mice in the open field, the elevated plus maze, and the Morris water maze indicated that the mutant animals reacted differently to their environment. Our data show that the permanent absence of CHL1 results in misguided axonal projections and aberrant axonal connectivity and alters the exploratory behavior in novel environments, suggesting deficits in information processing in CHL1-deficient mice.     

Stress downregulates hippocampal expression of the adhesion molecules NCAM and CHL1 in mice by mechanisms independent of DNA methylation of their promoters

Stress is an important physiological regulator of brain function in young and adult mammals. The mechanisms underlying regulation of the consequences of stress, and in particular severe chronic stress, are thus important to investigate. These consequences most likely involve changes in synaptic function of brain areas being part of neural networks that regulate responses to stress. Cell adhesion molecules have been shown to regulate synaptic function in the adult and we were thus interested to investigate a regulatory mechanism that could influence expression of three adhesion molecules of the immunoglobulin superfamily (NCAM, L1 and CHL1) after exposure of early postnatal and adult mice to repeated stress. We hypothesized that reduction of adhesion molecule expression after chronic stress, as observed previously in vivo, could be due to gene silencing of the three molecules by DNA methylation. Although adhesion molecule expression was reduced after exposure of C57BL/6 mice to stress, thus validating our stress paradigm as imposing changes in adhesion molecule expression, we did not observe differences in methylation of CpG islands in the promoter regions of NCAM, L1 and CHL1, nor in the promoter region of the glucocorticoid receptor in the hippocampus, the expression of which at the protein level was also reduced after stress. We must therefore infer that severe stress in mice of the C57BL/6 strain downregulates adhesion molecule levels by mechanisms that do not relate to DNA methylation.     

CHL1 is involved in human breast tumorigenesis and progression

Neural cell adhesion molecules (CAM) play important roles in the development and regeneration of the nervous system. The L1 family of CAMs is comprised of L1, Close Homolog of L1 (CHL1, L1CAM2), NrCAM, and Neurofascin, which are structurally related trans-membrane proteins in vertebrates. Although the L1CAM has been demonstrated play important role in carcinogenesis and progression, the function of CHL1 in human breast cancer is limited. Here, we found that CHL1 is down-regulated in human breast cancer and related to lower grade. Furthermore, overexpression of CHL1 suppresses proliferation and invasion in MDA-MB-231 cells and knockdown of CHL1 expression results in increased proliferation and invasion in MCF7 cells in vitro. Finally, CHL1 deficiency promotes tumor formation in vivo. Our results may provide a strategy for blocking breast carcinogenesis and progression.     

Close homolog of L1 is an enhancer of integrin-mediated cell migration

Close homolog of L1 (CHL1) is a member of the L1 family of cell adhesion molecules expressed by subpopulations of neurons and glia in the central and peripheral nervous system. It promotes neurite outgrowth and neuronal survival in vitro. This study describes a novel function for CHL1 in potentiating integrin-dependent cell migration toward extracellular matrix proteins. Expression of CHL1 in HEK293 cells stimulated their haptotactic migration toward collagen I, fibronectin, laminin, and vitronectin substrates in Transwell assays. CHL1-potentiated cell migration to collagen I was dependent on alpha1beta1 and alpha2beta1 integrins, as shown with function blocking antibodies. Potentiated migration relied on the early integrin signaling intermediates c-Src, phosphatidylinositol 3-kinase, and mitogen-activated protein kinase. Enhancement of migration was disrupted by mutation of a potential integrin interaction motif Asp-Gly-Glu-Ala (DGEA) in the sixth immunoglobulin domain of CHL1, suggesting that CHL1 functionally interacts with beta1 integrins through this domain. CHL1 was shown to associate with beta1 integrins on the cell surface by antibody-induced co-capping. Through a cytoplasmic domain sequence containing a conserved tyrosine residue (Phe-Ile-Gly-Ala-Tyr), CHL1 recruited the actin cytoskeletal adapter protein ankyrin to the plasma membrane, and this sequence was necessary for promoting integrin-dependent migration to extracellular matrix proteins. These results support a role for CHL1 in integrin-dependent cell migration that may be physiologically important in regulating cell migration in nerve regeneration and cortical development.     

Stress downregulates hippocampal expression of the adhesion molecules NCAM and CHL1 in mice by mechanisms independent of DNA methylation of their promoters

Stress is an important physiological regulator of brain function in young and adult mammals. The mechanisms underlying regulation of the consequences of stress, and in particular severe chronic stress, are thus important to investigate. These consequences most likely involve changes in synaptic function of brain areas being part of neural networks that regulate responses to stress. Cell adhesion molecules have been shown to regulate synaptic function in the adult and we were thus interested to investigate a regulatory mechanism that could influence expression of three adhesion molecules of the immunoglobulin superfamily (NCAM, L1 and CHL1) after exposure of early postnatal and adult mice to repeated stress. We hypothesized that reduction of adhesion molecule expression after chronic stress, as observed previously in vivo, could be due to gene silencing of the three molecules by DNA methylation. Although adhesion molecule expression was reduced after exposure of C57BL/6 mice to stress, thus validating our stress paradigm as imposing changes in adhesion molecule expression, we did not observe differences in methylation of CpG islands in the promoter regions of NCAM, L1 and CHL1, nor in the promoter region of the glucocorticoid receptor in the hippocampus, the expression of which at the protein level was also reduced after stress. We must therefore infer that severe stress in mice of the C57BL/6 strain downregulates adhesion molecule levels by mechanisms that do not relate to DNA methylation.Key words: stress, immunoglobulin superfamily, adhesion molecules, promoter, DNA methylation, hippocampus, glucocorticoid receptor     

The adhesion molecule CHL1 regulates uncoating of clathrin-coated synaptic vesicles

In searching for binding partners of the intracellular domain of the immunoglobulin superfamily adhesion molecule CHL1, we identified the clathrin-uncoating ATPase Hsc70. CHL1 gene ablation resulted in reduced targeting of Hsc70 to the synaptic plasma membrane and synaptic vesicles, suggesting CHL1 as a synapse-targeting cue for Hsc70. CHL1 accumulates in presynaptic membranes and, in response to synapse activation, is targeted to synaptic vesicles by endocytosis. CHL1 deficiency or disruption of the CHL1/Hsc70 complex results in accumulation of abnormally high levels of clathrin-coated synaptic vesicles with a reduced ability to release clathrin. Generation of new clathrin-coated synaptic vesicles in an activity-dependent manner is inhibited when the CHL1/Hsc70 complex is disrupted, resulting in impaired uptake and release of FM dyes in synaptic boutons. Abnormalities in clathrin-dependent synaptic vesicle recycling may thus underlie brain malfunctions in humans and mice that carry mutations in the CHL1 gene.     

CHL1 Is a Selective Organizer of the Presynaptic Machinery Chaperoning the SNARE Complex

Proteins constituting the presynaptic machinery of vesicle release undergo substantial conformational changes during the process of exocytosis. While changes in the conformation make proteins vulnerable to aggregation and degradation, little is known about synaptic chaperones which counteract these processes. We show that the cell adhesion molecule CHL1 directly interacts with and regulates the activity of the synaptic chaperones Hsc70, CSP and αSGT. CHL1, Hsc70, CSP and αSGT form predominantly CHL1/Hsc70/αSGT and CHL1/CSP complexes in synapses. Among the various complexes formed by CHL1, Hsc70, CSP and αSGT, SNAP25 and VAMP2 induce chaperone activity only in CHL1/Hsc70/αSGT and CHL1/CSP complexes, respectively, indicating a remarkable selectivity of a presynaptic chaperone activity for proteins of the exocytotic machinery. In mice with genetic ablation of CHL1, chaperone activity in synapses is reduced and the machinery for synaptic vesicle exocytosis and, in particular, the SNARE complex is unable to sustain prolonged synaptic activity. Thus, we reveal a novel role for a cell adhesion molecule in selective activation of the presynaptic chaperone machinery.     

CHL1 promotes Sema3A-induced growth cone collapse and neurite elaboration through a motif required for recruitment of ERM proteins to the plasma membrane

Close homolog of L1 (CHL1) is a transmembrane cell adhesion molecule with unique developmental functions in cortical neuronal positioning and dendritic projection within the L1 family, as well as shared functions in promotion of integrin-dependent neurite outgrowth and semaphorin3A (Sema3A)-mediated axon repulsion. The molecular mechanisms by which CHL1 mediates these diverse functions are obscure. Here it is demonstrated using a cytofluorescence assay that CHL1 is able to recruit ezrin, a member of the ezrin-radixin-moesin (ERM) family of filamentous actin binding proteins to the plasma membrane, and that this requires a membrane-proximal motif (RGGKYSV) in the CHL1 cytoplasmic domain. This sequence in CHL1 is shown to have novel functions necessary for Sema3A-induced growth cone collapse and CHL1-dependent neurite outgrowth and branching in cortical embryonic neurons. In addition, stimulation of haptotactic cell migration and cellular adhesion to fibronectin by CHL1 depends on the CHL1/ERM recruitment motif. These findings suggest that a direct or indirect interaction between CHL1 and ERM proteins mediates Sema3A-induced growth cone collapse as well as neurite outgrowth and branching, which are essential determinants of axon guidance and connectivity in cortical development.     

L1 and NCAM adhesion molecules as signaling coreceptors in neuronal migration and process outgrowth

Neural cell adhesion molecules (CAMs) of the immunoglobulin superfamily engage in multiple neuronal interactions that influence cell migration, axonal and dendritic projection, and synaptic targeting. Their downstream signal transduction events specify whether a cell moves or projects axons and dendrites to targets in the brain. Many of the diverse functions of CAMs are brought about through homophilic and heterophilic interactions with other cell surface receptors. An emerging concept is that CAMs act as coreceptors to assist in intracellular signal transduction, and to provide cytoskeletal linkage necessary for cell and growth cone motility. Here we will focus on new discoveries that have revealed novel coreceptor functions for the best-understood CAMs--L1, CHL1, and NCAM--important for neuronal migration and axon guidance. We will also discuss how dysregulation of CAMs may also bear on neuropsychiatric disease and cancer.     

Structure and interactions of NCAM Ig1-2-3 suggest a novel zipper mechanism for homophilic adhesion

The neural cell adhesion molecule, NCAM, mediates Ca(2+)-independent cell-cell and cell-substratum adhesion via homophilic (NCAM-NCAM) and heterophilic (NCAM-non-NCAM molecules) binding. NCAM plays a key role in neural development, regeneration, and synaptic plasticity, including learning and memory consolidation. The crystal structure of a fragment comprising the three N-terminal Ig modules of rat NCAM has been determined to 2.0 A resolution. Based on crystallographic data and biological experiments we present a novel model for NCAM homophilic binding. The Ig1 and Ig2 modules mediate dimerization of NCAM molecules situated on the same cell surface (cis interactions), whereas the Ig3 module mediates interactions between NCAM molecules expressed on the surface of opposing cells (trans interactions) through simultaneous binding to the Ig1 and Ig2 modules. This arrangement results in two perpendicular zippers forming a double zipper-like NCAM adhesion complex.