Neural recognition molecules CHL1 and NB-3 regulate apical dendrite orientation in the neocortex via PTP alpha

Apical dendrites of pyramidal neurons in the neocortex have a stereotypic orientation that is important for neuronal function. Neural recognition molecule Close Homolog of L1 (CHL1) has been shown to regulate oriented growth of apical dendrites in the mouse caudal cortex. Here we show that CHL1 directly associates with NB-3, a member of the F3/contactin family of neural recognition molecules, and enhances its cell surface expression. Similar to CHL1, NB-3 exhibits high-caudal to low-rostral expression in the deep layer neurons of the neocortex. NB-3-deficient mice show abnormal apical dendrite projections of deep layer pyramidal neurons in the visual cortex. Both CHL1 and NB-3 interact with protein tyrosine phosphatase alpha (PTPalpha) and regulate its activity. Moreover, deep layer pyramidal neurons of PTPalpha-deficient mice develop misoriented, even inverted, apical dendrites. We propose a signaling complex in which PTPalpha mediates CHL1 and NB-3-regulated apical dendrite projection in the developing caudal cortex.     

F3/contactin,a neuronal cell adhesion molecule implicated in axogenesis and myelination

A general feature of the cell adhesion molecules belonging to the immunoglobulin family (Ig-CAMs) is to display a modular structure that provides a framework for multiple binding sites for other recognition molecules. Among this family, F3/contactin is a glycan phosphatidyl-inositol (GPI)-anchored molecule expressed by neurons that displays the distinctiveness to exert heterophilic but no homophilic binding activities. The Ig domains of F3/contactin were shown to interact with the L1 family of Ig-CAMs, including L1, NrCAM, and neurofascin. Binding between F3/contactin and NrCAM is known to modulate axonal elongation of the cerebellar granule cells and to control sensory axon guidance. F3/contactin mediates neuron-glial contacts through its association with extracellular matrix components (tenascin-R, tenascin-C) and RPTPbeta/phosphacan, influencing axonal growth and fasciculation. Another major role of F3/contactin is to organize axonal subdomains at the node of Ranvier of myelinated fibers in interplay with other Ig-CAMs, through its binding with caspr/paranodin at paranodes and the voltage-gated sodium channels in the nodal region. The F3/contactin deficient mice display a severe ataxia correlated with defects in axonal and dendritic projections in the cerebellum. These mice also display defects in nerve influx conduction due to the disruption of the axo-glial contacts at paranodes. Finally, the recent identification of a Drosophila homologue of F3/contactin indicated that this family of GPI-anchored CAMs plays a conserved function in axonal insulation.     

Heterophilic binding of L1 on unmyelinated sensory axons mediates Schwann cell adhesion and is required for axonal survival.

This study investigated the function of the adhesion molecule L1 in unmyelinated fibers of the peripheral nervous system (PNS) by analysis of L1- deficient mice. We demonstrate that L1 is present on axons and Schwann cells of sensory unmyelinated fibers, but only on Schwann cells of sympathetic unmyelinated fibers. In L1-deficient sensory nerves, Schwann cells formed but failed to retain normal axonal ensheathment. L1-deficient mice had reduced sensory function and loss of unmyelinated axons, while sympathetic unmyelinated axons appeared normal. In nerve transplant studies, loss of axonal-L1, but not Schwann cell-L1, reproduced the L1-deficient phenotype. These data establish that heterophilic axonal-L1 interactions mediate adhesion between unmyelinated sensory axons and Schwann cells, stabilize the polarization of Schwann cell surface membranes, and mediate a trophic effect that assures axonal survival.     

The neural cell adhesion molecules L1 and CHL1 are cleaved by BACE1 protease in vivo

The β-site amyloid precursor protein-cleaving enzyme BACE1 is a prime drug target for Alzheimer disease. However, the function and the physiological substrates of BACE1 remain largely unknown. In this work, we took a quantitative proteomic approach to analyze the secretome of primary neurons after acute BACE1 inhibition, and we identified several novel substrate candidates for BACE1. Many of these molecules are involved in neuronal network formation in the developing nervous system. We selected the adhesion molecules L1 and CHL1, which are crucial for axonal guidance and maintenance of neural circuits, for further validation as BACE1 substrates. Using both genetic BACE1 knock-out and acute pharmacological BACE1 inhibition in mice and cell cultures, we show that L1 and CHL1 are cleaved by BACE1 under physiological conditions. The BACE1 cleavage sites at the membrane-proximal regions of L1 (between Tyr(1086) and Glu(1087)) and CHL1 (between Gln(1061) and Asp(1062)) were determined by mass spectrometry. This work provides molecular insights into the function and the pathways in which BACE1 is involved, and it will help to predict or interpret possible side effects of BACE1 inhibitor drugs in current clinical trials.     

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.     

神经粘附分子CHL1在神经系统中的研究进展

粘附分子通过介导细胞间相互作用发挥其在发育、再生和突触修饰等方面的重要作用.神经细胞粘附分子CHL1(close homologue of L1)是近年发现的粘附分子,属于粘附分子免疫球蛋白超家族,集中表达于神经系统,通过亲异性作用(heterophilic interaction)介导细胞与细胞、细胞与胞外基质的相互作用,进而参与神经系统的发育、轴突的生长、迁移及导向等过程.     

Dtrk, a Drosophila gene related to the trk family of neurotrophin receptors, encodes a novel class of neural cell adhesion molecule.

We report the identification and molecular characterization of Dtrk, a Drosophila gene encoding a receptor tyrosine kinase highly related to the trk family of mammalian neurotrophin receptors. The product of the Dtrk gene, gp160Dtrk, is dynamically expressed during Drosophila embryogenesis in several areas of the developing nervous system, including neurons and fasciculating axons. gp160Dtrk has structural homology with neural cell adhesion molecules of the immunoglobulin superfamily and promotes cell adhesion in a homophilic, Ca2+ independent manner. More importantly, this adhesion process specifically activates its tyrosine protein kinase activity. These findings suggest that gp160Dtrk represents a new class of neural cell adhesion molecules that may regulate neuronal recognition and axonal guidance during the development of the Drosophila nervous system.     

Ectodomain shedding of the neural recognition molecule CHL1 by the metalloprotease-disintegrin ADAM8 promotes neurite outgrowth and suppresses neuronal cell death

The neural cell adhesion molecule "close homologue of L1," termed CHL1, has functional importance in the nervous system. CHL1 is expressed as a transmembrane protein of 185 kDa, and ectodomain shedding releases soluble fragments relevant for its physiological function. Here we describe that ADAM8, a member of the family of metalloprotease disintegrins cleaves a CHL1-Fc fusion protein in vitro at two sites corresponding to release of the extracellular domain of CHL1 in fibronectin (FN) domains II (125 kDa) and V (165 kDa), inhibited by batimastat (BB-94). Cleavage of CHL1-Fc in the 125-kDa fragment was not detectable under non-reducing conditions arguing that cleavage resulting in the 165-kDa fragment is more relevant in releasing soluble CHL1 in vivo. In cells transfected with full-length ADAM8, membrane proximal cleavage of CHL1 was similar and not stimulated by phorbol ester 12-O-tetradecanoylphorbol-13-acetate and pervanadate. No cleavage of CHL1 was observed in cells expressing either inactive ADAM8 with a Glu330 to Gln exchange (EQ-A8), or active ADAM10 and ADAM17. Consequently, processing of CHL1 was hardly detectable in brain extracts of ADAM8-deficient mice but enhanced in a neurodegenerative mouse mutant. CHL1 processed by ADAM8 in supernatants of COS-7 cells and in co-culture with cerebellar granule neurons was very potent in stimulating neurite outgrowth and suppressing neuronal cell death, not observed in cells co-transfected with CHL1/EQ-A8, CHL1/ADAM10, or CHL1/ADAM17. Taken together, we propose that ADAM8 plays an important role in physiological and pathological cell interactions by a specific release of functional CHL1 from the cell surface.     

In silico-initiated cloning and molecular characterization of a novel human member of the L1 gene family of neural cell adhesion molecules

To discover genes contributing to mental retardation in 3p^- syndrome patients we have used in silico searches for neural genes in NCBI databases (dbEST and UniGene). An EST with strong homology to the rat CAM L1 gene subsequently mapped to 3p26 was used to isolate a full-length cDNA. Molecular analysis of this cDNA, referred to as CALL (cell adhesion L1-like), showed that it is encoded by a chromosome 3p26 locus and is a novel member of the L1 gene family of neural cell adhesion molecules. Multiple lines of evidence suggest CALL is likely the human ortholog of the murine gene CHL1: it is 84% identical on the protein level, has the same domain structure, same membrane topology, and a similar expression pattern. The orthology of CALL and CHL1 was confirmed by phylogenetic analysis. By in situ hybridization, CALL is shown to be expressed regionally in a timely fashion in the central nervous system, spinal cord, and peripheral nervous system during rat development. Northern analysis and EST representation reveal that it is expressed in the brain and also outside the nervous system in some adult human tissues and tumor cell lines. The cytoplasmic domain of CALL is conserved among other members of the L1 subfamily and features sequence motifs that may involve CALL in signal transduction pathways. Received: 14 April 1998 / Accepted: 18 June 1998     

Neuronal cell adhesion molecule deletion induces a cognitive and behavioral phenotype reflective of impulsivity

Cell adhesion molecules, such as neuronal cell adhesion molecule (Nr-CAM), mediate cell–cell interactions in both the developing and mature nervous system. Neuronal cell adhesion molecule is believed to play a critical role in cell adhesion and migration, axonal growth, guidance, target recognition and synapse formation. Here, wild-type, heterozygous and Nr-CAM null mice were assessed on a battery of five learning tasks (Lashley maze, odor discrimination, passive avoidance, spatial water maze and fear conditioning) previously developed to characterize the general learning abilities of laboratory mice. Additionally, all animals were tested on 10 measures of sensory/motor function, emotionality and stress reactivity. We report that the Nr-CAM deletion had no impact on four of the learning tasks (fear conditioning, spatial water maze, Lashley maze and odor discrimination). However, Nr-CAM null mice exhibited impaired performance on a task that required animals to suppress movement (passive avoidance). Although Nr-CAM mutants expressed normal levels of general activity and body weights, they did exhibit an increased propensity to enter stressful areas of novel environments (the center of an open field and the lighted side of a dark/light box), exhibited higher sensitivity to pain (hot plate) and were more sensitive to the aversive effects of foot shock (shock-induced freezing). This behavioral phenotype suggests that Nr-CAM does not play a central role in the regulation of general cognitive abilities but may have a critical function in regulating impulsivity and possibly an animal's susceptibility to drug abuse and addiction.     

Function-Triggering Antibodies to the Adhesion Molecule L1 Enhance Recovery after Injury of the Adult Mouse Femoral Nerve

L1 is among the few adhesion molecules that favors repair after trauma in the adult central nervous system of vertebrates by promoting neuritogenesis and neuronal survival, among other beneficial features. In the peripheral nervous system, L1 is up-regulated in Schwann cells and regrowing axons after nerve damage, but the functional consequences of this expression remain unclear. Our previous study of L1-deficient mice in a femoral nerve injury model showed an unexpected improved functional recovery, attenuated motoneuronal cell death, and enhanced Schwann cell proliferation, being attributed to the persistent synthesis of neurotrophic factors. On the other hand, transgenic mice over-expressing L1 in neurons led to improved remyelination, but not improved functional recovery. The present study was undertaken to investigate whether the monoclonal L1 antibody 557 that triggers beneficial L1 functions in vitro would trigger these also in femoral nerve repair. We analyzed femoral nerve regeneration in C57BL/6J mice that received this antibody in a hydrogel filled conduit connecting the cut and sutured nerve before its bifurcation, leading to short-term release of antibody by diffusion. Video-based quantitative analysis of motor functions showed improved recovery when compared to mice treated with conduits containing PBS in the hydrogel scaffold, as a vehicle control. This improved recovery was associated with attenuated motoneuron loss, remyelination and improved precision of preferential motor reinnervation. We suggest that function-triggering L1 antibodies applied to the lesion site at the time of injury over a limited time period will not only be beneficial in peripheral, but also central nervous system regeneration.     

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.     

Temporal and spatial patterns of expression of p35, a regulatory subunit of cyclin-dependent kinase 5, in the nervous system of the mouse

The protein p35 is a regulatory subunit of cyclin-dependent kinase 5. It has no recognized homology to cyclins but binds to and activates cyclin-dependent kinase 5 directly in the absence of other protein molecules. Cyclin-dependent kinase 5 was initially isolated by homology to the key cell cycle regulator cdc2 kinase and later identified as a neuronal kinase that phosphorylates histone H1, tau or neurofilaments. This kinase is localized in axons of the developing and mature nervous system. To understand the role of p35 as a regulator of cyclin-dependent kinase 5 activity in the CNS, we examined the pattern of expression of p35 mRNA in the nervous system of embryonic, early postnatal and adult mice. In separate experiments, we also examined the spatial distribution of cyclin-dependent kinase 5 mRNA and the activity of cyclin-dependent kinase 5/p35 kinase complex. Postmitotic cells express p35 mRNA immediately after they leave the zones of cell proliferation. It is also expressed in developing axonal tracts in the brain. Cyclin-dependent kinase 5 mRNA is present in postmitotic and in proliferative cells throughout the embryonic central nervous system. During early postnatal period signal for p35 mRNA declines while that for cyclin-dependent kinase 5 mRNA increases throughout the brain. In the adult brain although both p35 and cyclin-dependent kinase 5 mRNAs are expressed at relatively high levels in certain structures associated with the limbic system, considerable differences exist in the patterns of their distribution in other parts of the brain. These data suggest that the p35/cyclin-dependent kinase 5 complex may be associated with early events of neuronal development such as neuronal migration and axonal growth while in the limbic system of the mature brain it may be associated with the maintenance of neuronal plasticity.     

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.     

Ankyrins and cellular targeting of diverse membrane proteins to physiological sites

Ankyrins are spectrin-binding proteins that associate via ANK repeats with a variety of ion channels/pumps, calcium release channels and cell adhesion molecules. Recent studies in mice indicate that ankyrins have a physiological role in restricting voltage-gated sodium channels and members of the L1 CAM family of cell adhesion molecules to excitable membranes in the central nervous system and in targeting calcium-release channels to the calcium homeostasis compartment of striated muscle.     

急性低氧对小鼠黏附分子CHL1组织水平表达的影响

目的:观察急性低氧条件下小鼠脑组织及心、肺、肾中黏附分子CHL1的表达变化,为探讨黏附分子CHL1在低氧损伤中的调节作用提供依据.方法:利用本室已建立的小鼠急性低氧模型,将雄性成年C57BL/6小鼠随机分为低氧处理组和常氧对照组(n=10).低氧8h后提取组织蛋白,通过Westem blot检测急性低氧处理后CBL1在...     

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     

Aberrant neuronal connectivity in CHL1-deficient mice is associated with altered information processing-related immediate early gene expression

In humans, loss or alteration of the CHL1/CALL gene may contribute to mental impairment associated with the 3p-syndrome, caused by distal deletions of the short (p) arm of chromosome 3, and schizophrenia. Mice deficient for the Close Homologue of L1 (CHL1) show aberrant connectivity of hippocampal mossy fibers and olfactory sensory axons, suggesting participation of CHL1 in the establishment of neuronal networks. Furthermore, behavioral studies showed that CHL1-deficient mice react differently towards novel experimental environments. These data raise the hypothesis that processing of information, possibly novel versus familiar, may be altered in the absence of CHL1. To test this hypothesis, brain activities were investigated after presentation of a novel, familiar, or neutral gustatory stimulus using metabolic mapping with ((14)C)-2-deoxyglucose (2-DG) and analysis of mRNA expression of the immediate early genes (IEGs) c-fos and arg 3.1/arc by in situ hybridization. 2-DG labeling revealed only small differences between CHL1-deficient and wild-type littermate mice. In contrast, while the specific novelty-induced increase in c-fos expression was maintained in most of the brain areas analyzed, c-fos mRNA expression was similar after the novel and familiar taste in several brain areas of the CHL1-deficient mice. Furthermore, in these mutants, arg 3.1/arc expression was slightly reduced after the novel taste and increased after the familiar taste, leading to a similar arg 3.1/arc mRNA expression after both stimuli. Our results indicate that, in contrast to controls, CHL1-deficient mice might process novel and familiar information similarly and suggest that the altered neuronal connectivity in these mutants disturbs information processing at the molecular level.     

Ataxia and abnormal cerebellar microorganization in mice with ablated contactin gene expression

Axon guidance and target recognition depend on neuronal cell surface receptors that recognize and elicit selective growth cone responses to guidance cues in the environment. Contactin, a cell adhesion/recognition molecule of the immunoglobulin gene superfamily, regulates axon growth and fasciculation in vitro, but its role in vivo is unknown. To assess its function in the developing nervous system, we have ablated contactin gene expression in mice. Contactin-/- mutants displayed a severe ataxic phenotype consistent with defects in the cerebellum and survived only until postnatal day 18. Analysis of the contactin-/- mutant cerebellum revealed defects in granule cell axon guidance and in dendritic projections from granule and Golgi cells. These results demonstrate that contactin controls axonal and dendritic interactions of cerebellar interneurons and contributes to cerebellar microorganization.