When a diffusible axon guidance cue stops diffusing: roles for netrins in adhesion and morphogenesis

Netrins are a small family of secreted proteins that are best known for their role as secreted long-range chemotropic guidance cues. Extracellular gradients of netrin protein, established by diffusion, are thought to direct cell and axon migration during neural development. In addition to this long-range role, recent findings provide increasing support for short-range functions, in which secreted netrin protein remains closely associated with its cellular source. Emerging evidence for short-range actions of netrins suggests that they contribute to tissue morphogenesis by regulating cell-cell and cell-matrix adhesion.     

The netrin protein family

The name netrin is derived from the Sanskrit Netr, meaning ''guide''. Netrins are a family of extracellular proteins that direct cell and axon migration during embryogenesis. Three secreted netrins (netrins 1, 3 and 4), and two glycosylphosphatidylinositol (GPI)-anchored membrane proteins, netrins G1 and G2, have been identified in mammals. The secreted netrins are bifunctional, acting as attractants for some cell types and repellents for others. Receptors for the secreted netrins include the Deleted in Colorectal Cancer (DCC) family, the Down''s syndrome cell adhesion molecule (DSCAM), and the UNC-5 homolog family: Unc5A, B, C and D in mammals. Netrin Gs do not appear to interact with these receptors, but regulate synaptic interactions between neurons by binding to the transmembrane netrin G ligands NGL1 and 2. The chemotropic function of secreted netrins has been best characterized with regard to axon guidance during the development of the nervous system. Extending axons are tipped by a flattened, membranous structure called the growth cone. Multiple extracellular guidance cues direct axonal growth cones to their ultimate targets where synapses form. Such cues can be locally derived (short-range), or can be secreted diffusible cues that allow target cells to signal axons from a distance (long-range). The secreted netrins function as short-range and long-range guidance cues in different circumstances. In addition to directing cell migration, functional roles for netrins have been identified in the regulation of cell adhesion, the maturation of cell morphology, cell survival and tumorigenesis.     

Netrins: versatile extracellular cues with diverse functions

Netrins are secreted proteins that were first identified as guidance cues, directing cell and axon migration during neural development. Subsequent findings have demonstrated that netrins can influence the formation of multiple tissues, including the vasculature, lung, pancreas, muscle and mammary gland, by mediating cell migration, cell-cell interactions and cell-extracellular matrix adhesion. Recent evidence also implicates the ongoing expression of netrins and netrin receptors in the maintenance of cell-cell organisation in mature tissues. Here, we review the mechanisms involved in netrin signalling in vertebrate and invertebrate systems and discuss the functions of netrin signalling during the development of neural and non-neural tissues.     

Netrin induces down-regulation of its receptor, Deleted in Colorectal Cancer, through the ubiquitin-proteasome pathway in the embryonic cortical neuron

The proper regulation of temporal and spatial expression of the axon guidance cues and their receptors is critical for the normal wiring of nervous system during development. Netrins, a family of secreted guidance cues, are involved in the midline crossing of spinal commissural axons and in the guidance of cortical efferents. Axons normally lose the responsiveness to their attractants when they arrive at their targets, where the attractant is produced. However the molecular mechanism is still unknown. We investigated the molecular mechanism of down-regulation of netrin-1 signaling in the embryonic cortical neurons. Netrin-1 induced the ubiquitination and proteolytic cleavage of Deleted in Colorectal Cancer (DCC), a transmembrane receptor for netrin, in dissociated cortical neurons. A dramatic decrease of DCC level particularly on the cell surface was also observed after netrin-1 stimulation. Specific ubiquitin-proteasome inhibitors prevented the netrin-induced DCC cleavage and decrease of cell surface DCC. We suggest that the ligand-mediated down-regulation of DCC might participate in the loss of netrin-responsiveness in the developing nervous system.     

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。     

Planarian homologs of netrin and netrin receptor are required for proper regeneration of the central nervous system and the maintenance of nervous system architecture

Conserved axon guidance mechanisms are essential for proper wiring of the nervous system during embryogenesis; however, the functions of these cues in adults and during regeneration remain poorly understood. Because freshwater planarians can regenerate a functional central nervous system (CNS) from almost any portion of their body, they are useful models in which to study the roles of guidance cues during neural regeneration. Here, we characterize two netrin homologs and one netrin receptor family member from Schmidtea mediterranea. RNAi analyses indicate that Smed-netR (netrin receptor) and Smed-netrin2 are required for proper CNS regeneration and that Smed-netR may mediate the response to Smed-netrin2. Remarkably, Smed-netR and Smed-netrin2 are also required in intact planarians to maintain the proper patterning of the CNS. These results suggest a crucial role for guidance cues, not only in CNS regeneration but also in maintenance of neural architecture.     

Rho inhibition recruits DCC to the neuronal plasma membrane and enhances axon chemoattraction to netrin 1

Molecular cues, such as netrin 1, guide axons by influencing growth cone motility. Rho GTPases are a family of intracellular proteins that regulate the cytoskeleton, substrate adhesion and vesicle trafficking. Activation of the RhoA subfamily of Rho GTPases is essential for chemorepellent axon guidance; however, their role during axonal chemoattraction is unclear. Here, we show that netrin 1, through its receptor DCC, inhibits RhoA in embryonic spinal commissural neurons. To determine whether netrin 1-mediated chemoattraction requires Rho function, we inhibited Rho signaling and assayed axon outgrowth and turning towards netrin 1. Additionally, we examined two important mechanisms that influence the guidance of axons to netrin 1: substrate adhesion and transport of the netrin receptor DCC to the plasma membrane. We found that inhibiting Rho signaling increased plasma membrane DCC and adhesion to substrate-bound netrin 1, and also enhanced netrin 1-mediated axon outgrowth and chemoattractive axon turning. Conversely, overexpression of RhoA or constitutively active RhoA inhibited axonal responses to netrin 1. These findings provide evidence that Rho signaling reduces axonal chemoattraction to netrin 1 by limiting the amount of plasma membrane DCC at the growth cone, and suggest that netrin 1-mediated inhibition of RhoA activates a positive-feedback mechanism that facilitates chemoattraction to netrin 1. Notably, these findings also have relevance for CNS regeneration research. Inhibiting RhoA promotes axon regeneration by disrupting inhibitory responses to myelin and the glial scar. By contrast, we demonstrate that axon chemoattraction to netrin 1 is not only maintained but enhanced, suggesting that this might facilitate directing regenerating axons to appropriate targets.     

Complementary expression and neurite outgrowth activity of netrin-G subfamily members.

Classical members of the UNC6/netrin family are secreted proteins which play a role as long-range cues for directing growth cones. We here identified in mice a novel member netrin-G2 which constitute a subfamily with netrin-G1 among the UNC6/netrin family. Both of these netrin-Gs are characterized by glycosyl phosphatidyl-inositol linkage onto cells, molecular variants presumably generated by alternative splicing and lack of any appreciable affinity to receptors for classical netrins. These genes are preferentially expressed in the central nervous system with complementary distribution in most brain areas, that is netrin-G1 in the dorsal thalamus, olfactory bulb and inferior colliculus, and netrin-G2 in the cerebral cortex, habenular nucleus and superior colliculus. Consistently, immunohistochemical analysis revealed that netrin-G1 molecules are present on thalamocortical but not corticothalamic axons. Thalamic and neocortical neurons extended long neurites on immobilized recombinant netrin-G1 or netrin-G2 in vitro. Immobilized anti-netrin-G1 antibodies altered shapes of cultured thalamic neurons. We propose that netrin-Gs provide short-range cues for axonal and/or dendritic behavior through bi-directional signaling.     

Proteolysis and membrane capture of F-spondin generates combinatorial guidance cues from a single molecule

The formation of neuronal networks is governed by a limited number of guidance molecules, yet it is immensely complex. The complexity of guidance cues is augmented by posttranslational modification of guidance molecules and their receptors. We report here that cleavage of the floor plate guidance molecule F-spondin generates two functionally opposing fragments: a short-range repellent protein deposited in the membrane of floor plate cells and an adhesive protein that accumulates at the basement membrane. Their coordinated activity, acting respectively as a short-range repellant and a permissive short-range attractant, constricts commissural axons to the basement membrane beneath the floor plate cells. We further demonstrate that the repulsive activity of the inhibitory fragment of F-spondin requires its presentation by the lipoprotein receptor-related protein (LRP) receptors apolipoprotein E receptor 2, LRP2/megalin, and LRP4, which are expressed in the floor plate. Thus, proteolysis and membrane interaction coordinate combinatorial guidance signaling originating from a single guidance cue.     

Selecting a longitudinal pathway: Robo receptors specify the lateral position of axons in the Drosophila CNS

On each side of the midline of the Drosophila CNS, axons are organized into a series of parallel pathways. Here we show that the midline repellent Slit, previously identified as a short-range signal that regulates midline crossing, also functions at long range to pattern these longitudinal pathways. In this long-range function, Slit signals through the receptors Robo2 and Robo3. Axons expressing neither, one, or both of these receptors project in one of three discrete lateral zones, each successively further from the midline. Loss of robo2 or robo3 function repositions axons closer to the midline, while gain of robo2 or robo3 function shifts axons further from the midline. Local cues further refine the lateral position. Together, these long- and short-range guidance cues allow growth cones to select with precision a specific longitudinal pathway.     

Netrins: beyond the brain

Named after the Sanskrit word netr, which means 'one who guides', the netrin family of secreted proteins provides migrational cues in the developing central nervous system. Recently, netrins have also been shown to regulate diverse processes (such as cell adhesion, motility, proliferation, differentiation and, ultimately, cell survival) in a number of non-neuronal tissues. In some cases, netrins affect these functions through non-classic netrin receptors, prompting a renewed interest in these factors in and beyond the nervous system.     

The lifetime of photosensory signals in Halobacterium halobium and its dependence on protein methylation

Halobacteria spontaneously reverse their swimming direction about every 10 s. This behavioral pattern is transiently disturbed upon stimulation through sensory photosystems of different spectral sensitivity. As a result of stimulation, a single swimming interval is either prolonged (attractant response) or shortened (repellent response). Thereafter the cell returns to its autonomous reversal rhythm, i.e., it quickly adapts. Method are presented to determine the lifetime of repellent as well as of attractant cellular signals at the site of signal integration, using particular stimulation programs. Independent of the photosystem through which the signals were generated, the total lifetime of a repellent signal was 1.3 s. The decay of the signal was rapid during the first 100 ms and slow thereafter. The lifetime of an attractant signal was about 4 s and likewise did not depend on the photosystems. The degree of methylation of membrane proteins was increased by attractant stimuli and decreased by repellent stimuli. Inhibition of protein methylation by homocysteine was accompanied by a slowdown of the decay of both the repellent and attractant signal. A mutant strain with an increased demethylation also gave increased signal lifetimes. A lowered Ca2+ concentration, which activates methylation in vivo, led to shortened signal lifetimes. Methylation is proposed to be the mechanism which limits the signal lifetime and thereby allows the cells to adapt.     

Repellent response functions of the Trg and Tap chemoreceptors of Escherichia coli.

The chemoreceptors responsible for the repellent response of Escherichia coli to phenol were investigated. In the absence of all four known methyl-accepting chemoreceptors (Tar, Tsr, Trg, and Tap), cells showed no response to phenol. However, when Trg, which mediates the attractant response to ribose and galactose, was introduced via a plasmid, the cells acquired a repellent response to phenol. About 1 mM phenol induced a clear repellent response; this response was suppressed by 1 mM ribose. Thus, Trg mediates the repellent response to phenol. Mutant Trg proteins with altered sensing for ribose and galactose showed a normal response to phenol, indicating that the interaction site for phenol differs from that for the ribose- and galactose-binding proteins. Tap, which mediates the attractant response to dipeptides, mediated a weaker repellent response to phenol. Tsr, which mediates the attractant response to serine, mediated an even weaker response to phenol. Trg and Tap were also found to function as intracellular pH sensors. Upon a pH decrease, Trg mediated an attractant response, whereas Tap mediated a repellent response. These results indicate that all the receptors in E. coli have dual functions, mediating both attractant and repellent responses.     

Temporal regulation of cerebellar EGL migration through a switch in cellular responsiveness to the meninges

We have studied the temporal and spatial control of cell migration from the external germinal layer (EGL) in the mammalian cerebellum as a model for cortical migration. Our results have demonstrated that embryonic EGL cells do not migrate into internal layers because they respond to a diffusible attractant in the meninges, the nonneural tissues covering the nervous system, and to a repellent in the neuroepithelium. Two developmental changes are important for postnatal EGL migration: the disappearance of the repellent in the inner layers and a switch in cellular responsiveness of EGL cells so that the postnatal EGL cells respond to the repellent, but not the attractant in the meninges. Besides revealing the signaling role of meninges in cortical development, our study suggests that an active mechanism is required to prevent cell migration, and that mechanisms of cell migration should be studied even in the absence of apparent changes in cell positions. We propose a model for the developmental control of neuronal migration in the cerebellar cortex.     

Role of the response oscillator in inverse responses of Halobacterium halobium to weak light stimuli.

Under certain conditions Halobacterium halobium organisms respond to a weak attractant light stimulus with a repellent response and to a weak repellent stimulus with an attractant response. The appearance of inverse responses depends on the stimulus strength, on the interval length between spontaneous reversals, and on the moment of stimulation during the interval. Although the cells are absolutely refractory to repellent stimuli for 500 ms after a reversal, repellent responses can be evoked even during that period if they are inverse responses to weak attractant stimuli. Simultaneous attractant and repellent stimuli cancel each other even when one of them leads to an inverse response, indicating that normal cellular signals occur at the site of signal integration. We postulate that the inverse responses are caused by certain properties of a cellular oscillator for which we previously postulated a role in response regulation and sensory control in halobacteria (A. Schimz and E. Hildebrand, Nature [London] 317:641-643, 1985).     

Emerging roles for neogenin and its ligands in CNS development

It is now well established that the netrin guidance cues and their receptors comprise a major molecular guidance system driving axon pathfinding during nervous system development. One netrin receptor, neogenin, is now emerging as a key regulator of many developmental processes throughout the embryo. Unexpectedly, a new family of neogenin ligands, the repulsive guidance molecule (RGM) family, has recently been identified. The functional outcome of neogenin activation is dictated by both the nature of the ligand as well as the developmental context. Netrin-1–neogenin interactions mediate chemoattractive axon guidance, while RGMa–neogenin interactions repel axons. Neogenin is required for the establishment of the pseudostratified epithelium of the neural tube, probably by promoting cell adhesion. In addition, a role for RGMa and neogenin in neuronal differentiation has been demonstrated. While neogenin signaling cascades are poorly understood, the opposing responses of neogenin to RGMa and netrin-1 in the context of axon guidance indicates that neogenin signaling is complex and subject to tight spatiotemporal regulation. In summary, neogenin is a multifunctional receptor regulating diverse developmental processes. Thus, its contribution to neural development is proving to be considerably more extensive than originally predicted.     

Semaphorin-1a acts in concert with the cell adhesion molecules fasciclin II and connectin to regulate axon fasciculation in Drosophila

Semaphorins comprise a large family of phylogenetically conserved secreted and transmembrane glycoproteins, many of which have been implicated in repulsive axon guidance events. The transmembrane semaphorin Sema-1a in Drosophila is expressed on motor axons and is required for the generation of neuromuscular connectivity. Sema-1a can function as an axonal repellent and mediates motor axon defasciculation. Here, by manipulating the levels of Sema-1a and the cell adhesion molecules fasciclin II (Fas II) and connectin (Conn) on motor axons, we provide further evidence that Sema-1a mediates axonal defasciculation events by acting as an axonally localized repellent and that correct motor axon guidance results from a balance between attractive and repulsive guidance cues expressed on motor neurons.     

SRC-1, a non-receptor type of protein tyrosine kinase, controls the direction of cell and growth cone migration in C. elegans

Src family tyrosine kinase (SFK) has been implicated in the regulation of cell adhesion and migration during animal development. We show that SRC-1, an ortholog of SFK, plays an essential role in directing cell migration in Caenorhabditis elegans. The mutation in the src-1 gene results in defective distal tip cell (DTC)-directed gonad morphogenesis in an activity-dependent and DTC cell-autonomous manners. In the src-1 mutants, DTCs fail to turn and continue their centrifugal migration along the ventral muscles. The effect of the src-1 mutation is suppressed by mutations in genes that function in the CED/Rac pathway, suggesting that SRC-1 in DTCs is an upstream regulator of a Rac pathway that controls cytoskeletal remodeling. In the src-1 mutant, the expression of unc-5/netrin receptor is normally regulated, and neither the precocious expression of UNC-5 nor the mutation in the unc-5 gene significantly affects the DTC migration defect. These data suggest that SRC-1 acts in the netrin signaling in DTCs. The src-1 mutant also exhibits cell-autonomous defects in the migration and growth cone path-finding of Q neuroblast descendants AVM and PVM. However, these roles of SRC-1 do not appear to involve the CED/Rac pathway. These findings show that SRC-1 functions in responding to various extracellular guidance cues that direct the cell migration via disparate signaling pathways in different cell types.     

Anchoring of Protein Kinase A by ERM (Ezrin-Radixin-Moesin) Proteins Is Required for Proper Netrin Signaling through DCC (Deleted in Colorectal Cancer)

Netrin-1, acting through its principal receptor DCC (deleted in colorectal cancer), serves as an axon guidance cue during neural development and also contributes to vascular morphogenesis, epithelial migration, and the pathogenesis of some tumors. Several lines of evidence suggest that netrin-DCC signaling can regulate and be regulated by the cAMP-dependent protein kinase, PKA, although the molecular details of this relationship are poorly understood. Specificity in PKA signaling is often achieved through differential subcellular localization of the enzyme by interaction with protein kinase A anchoring proteins (AKAPs). Here, we show that AKAP function is required for DCC-mediated activation of PKA and phosphorylation of cytoskeletal regulatory proteins of the Mena/VASP (vasodilator-stimulated phosphoprotein) family. Moreover, we show that DCC and PKA physically interact and that this association is mediated by the ezrin-radixin-moesin (ERM) family of plasma membrane-actin cytoskeleton cross-linking proteins. Silencing of ERM protein expression inhibits DCC-PKA interaction, DCC-mediated PKA activation, and phosphorylation of Mena/VASP proteins as well as growth cone morphology and neurite outgrowth. Finally, although expression of wild-type radixin partially rescued growth cone morphology and tropism toward netrin in ERM-knockdown cells, expression of an AKAP-deficient mutant of radixin did not fully rescue growth cone morphology and switched netrin tropism from attraction to repulsion. These data support a model in which ERM-mediated anchoring of PKA activity to DCC is required for proper netrin/DCC-mediated signaling.     

Activation of ADF/cofilin mediates attractive growth cone turning toward nerve growth factor and netrin‐1

Proper neural circuitry requires that growth cones, motile tips of extending axons, respond to molecular guidance cues expressed in the developing organism. However, it is unclear how guidance cues modify the cytoskeleton to guide growth cone pathfinding. Here, we show acute treatment with two attractive guidance cues, nerve growth factor (NGF) and netrin‐1, for embryonic dorsal root ganglion and temporal retinal neurons, respectively, results in increased growth cone membrane protrusion, actin polymerization, and filamentous actin (F‐actin). ADF/cofilin (AC) family proteins facilitate F‐actin dynamics, and we found the inactive phosphorylated form of AC is decreased in NGF‐ or netrin‐1‐treated growth cones. Directly increasing AC activity mimics addition of NGF or netrin‐1 to increase growth cone protrusion and F‐actin levels. Extracellular gradients of NGF, netrin‐1, and a cell‐permeable AC elicit attractive growth cone turning and increased F‐actin barbed ends, F‐actin accumulation, and active AC in growth cone regions proximal to the gradient source. Reducing AC activity blunts turning responses to NGF and netrin. Our results suggest that gradients of NGF and netrin‐1 locally activate AC to promote actin polymerization and subsequent growth cone turning toward the side containing higher AC activity. © 2010 Wiley Periodicals, Inc. Develop Neurobiol 70: 565–588, 2010