Agrin‐independent activation of the agrin signal transduction pathway

The neural factor agrin induces the aggregation of acetylcholine receptors (AChRs) and other synaptic molecules on cultured myotubes. This aggregating activity can be mimicked by experimental manipulations that include treatment with neuraminidase or elevated calcium. We report evidence that neuraminidase and calcium act through the agrin signal transduction pathway. The effects of neuraminidase and calcium on AChR clustering are additive with that of agrin at low concentrations and cosaturating at high concentrations. In addition, like agrin, both neuraminidase and calcium cause rapid tyrosine phosphorylation of the muscle‐specific kinase (MuSK) and the AChR‐β subunit. Our results argue that all three agents act directly on components of the same signal transduction complex. We suggest that sialic acids on components of the complex inhibit interactions necessary for signal transduction and that disinhibition can result in activation. In such a model, agrin could activate signal transduction by disinhibition or by circumventing the inhibition. © 1999 John Wiley & Sons, Inc. J Neurobiol 40: 356–365, 1999     

Sialic acid inhibits agrin signaling in C2 myotubes

Acetylcholine receptor (AChR) clustering is an early event in neuromuscular synapse formation that is commonly studied using muscle cell culture. Motor neuron-derived agrin induces the postsynaptic tyrosine phosphorylation of both a muscle-specific kinase (MuSK) and the AChR beta-subunit. These phosphorylation events are required for AChR clustering, suggesting an agrin-driven signaling pathway. Both the phosphorylation events and AChR clustering can also be induced by neuraminidase, an enzyme that cleaves sialic acid from glycoconjugates, suggesting that neuraminidase is able to activate the agrin signaling pathway. A postulated signal for postsynaptic differentiation at sites of nerve-muscle contact during vertebrate development is the enzymatic removal of basal lamina components. We show here that bath-applied sialic acid has an effect directly opposite that of agrin or neuraminidase. Sialic acid not only decreases AChR clustering but also diminishes the tyrosine phosphorylation of MuSK and the AChR beta-subunit signal-transduction events normally driven by agrin. However, sialic acid does not prevent agrin-binding molecules from colocalizing with the decreased number of AChR clusters that do form, suggesting that sialic acid is acting to inhibit the agrin signaling pathway downstream of agrin binding to the muscle cell membrane. We propose a regulatory role for sialic acid in the signal transduction events of neuromuscular synapse formation, in which agrin or neuraminidase can overcome this sialic acid repression, resulting in the clustering of AChRs and other postsynaptic molecules.     

A role for acetylcholine receptors in their own aggregation on muscle cells

Both neurotrophic factors and activity regulate synaptogenesis. At neuromuscular synapses, the neural factor agrin released from motor neuron terminals stimulates postsynaptic specialization by way of the muscle specific kinase MuSK. In addition, activity through acetylcholine receptors (AChRs) has been implicated in the stabilization of pre- and postsynaptic contacts on muscle at various stages of development. We show here that activation of AChRs with specific concentrations of nicotine is sufficient to induce AChR aggregation and that this induction requires the function of L-type calcium channels (L-CaChs). Furthermore, AChR function is required for agrin induced AChR aggregation in C2 muscle cells. The same concentrations of nicotine did not induce observable tyrosine phosphorylation on either MuSK or the AChR beta subunit, suggesting significant differences between the mechanisms of agrin and activity induced aggregation. The AChR/L-CaCh pathway provides a mechanism by which neuromuscular signal transmission can act in concert with the agrin-MuSK signaling cascade to regulate NMJ formation.     

Agrin signaling in cortical neurons is mediated by a tyrosine kinase-dependent increase in intracellular Ca2+ that engages both CaMKII and MAPK signal pathways

Agrin has been implicated in multiple aspects of central nervous system (CNS) neuron differentiation and function including neurite formation, synaptogenesis, and synaptic transmission. However, little is known about the signaling mechanisms whereby agrin exerts its effects. We have recently identified a neuronal receptor for agrin, whose activation induces expression of c-fos, and provided evidence that agrin binding to this receptor is associated with a rise in intracellular Ca2+, a ubiquitous second messenger capable of mediating a wide range of effects. To gain further insight into agrin's role in brain, we used Ca2+ imaging to explore agrin signal transduction in cultured cortical neurons. Bath application of either z+ or z-agrin isoforms resulted in marked changes in intracellular Ca2+ concentration specifically in neurons. Propagation of the Ca2+ response was a two-step process characterized by an initial increase in intracellular Ca2+ mediated by ryanodine receptor (RyR) release from intracellular stores, supplemented by influx through voltage-gated calcium channels (VGCCs). Agrin-induced increases in intracellular Ca2+ were blocked by genistein and herbimycin, suggesting that the agrin receptor is a tyrosine kinase. Ca2+ release from intracellular stores activates both calcium/calmodulin-dependent kinase II (CaMKII) and mitogen activated protein kinase (MAPK). Activation of CaMKII is required for propagation of the Ca2+ wave itself, whereas both MAPK and CaMKII play a role in mediating long latency responses such as induction of c-fos. These results suggest that an agrin-dependent tyrosine kinase could play a critical role in modulating levels of intracellular Ca2+ and activity of MAPK and CaMKII in CNS neurons.     

Distinct domains of MuSK mediate its abilities to induce and to associate with postsynaptic specializations.

Agrin released from motor nerve terminals activates a muscle-specific receptor tyrosine kinase (MuSK) in muscle cells to trigger formation of the skeletal neuromuscular junction. A key step in synaptogenesis is the aggregation of acetylcholine receptors (AChRs) in the postsynaptic membrane, a process that requires the AChR-associated protein, rapsyn. Here, we mapped domains on MuSK necessary for its interactions with agrin and rapsyn. Myotubes from MuSK(-/)- mutant mice form no AChR clusters in response to agrin, but agrin-responsiveness is restored by the introduction of rat MuSK or a Torpedo orthologue. Thus, MuSK(-/)- myotubes provide an assay system for the structure-function analysis of MuSK. Using this system, we found that sequences in or near the first of four extracellular immunoglobulin-like domains in MuSK are required for agrin responsiveness, whereas sequences in or near the fourth immunoglobulin-like domain are required for interaction with rapsyn. Analysis of the cytoplasmic domain revealed that a recognition site for the phosphotyrosine binding domain-containing proteins is essential for MuSK activity, whereas consensus binding sites for the PSD-95/Dlg/ZO-1-like domain-containing proteins and phosphatidylinositol-3-kinase are dispensable. Together, our results indicate that the ectodomain of MuSK mediates both agrin- dependent activation of a complex signal transduction pathway and agrin-independent association of the kinase with other postsynaptic components. These interactions allow MuSK not only to induce a multimolecular AChR-containing complex, but also to localize that complex to a primary scaffold in the postsynaptic membrane.     

The mAKAP signaling complex: integration of cAMP, calcium, and MAP kinase signaling pathways

Following its production by adenylyl cyclases, the second messenger cAMP is in involved in pleiotrophic signal transduction. The effectors of cAMP include the cAMP-dependent protein kinase (PKA), the guanine nucleotide exchange factor Epac (exchange protein activated by cAMP), and cAMP-dependent ion channels. In turn, cAMP signaling is attenuated by phosphodiesterase-catalyzed degradation. The association of cAMP effectors and the enzymes that regulate cAMP concentration into signaling complexes helps to explain the differential signaling initiated by members of the G(s)-protein coupled receptor family. The signal transduction complex formed by the scaffold protein mAKAP (muscle A kinase-anchoring protein) at the nuclear envelope of both striated myocytes and neurons contains three cAMP-binding proteins, PKA, Epac1, and the phosphodiesterase PDE4D3. In addition, the mAKAP complex also contains components of the ERK5 MAP kinase signaling pathway, the calcium release channel ryanodine receptor and the phosphatases PP2A as well as calcineurin. Analysis of the mAKAP complex illustrates how a macromolecular complex can serve as a node in the intracellular signaling network of cardiac myocytes to integrate multiple cAMP signals with those of calcium and MAP kinases to regulate the hypertrophic actions of several hormones.     

Synaptic localization and axonal targeting of agrin secreted by ventral spinal cord neurons in culture

Agrin secreted by motor neurons is a critical signal for postsynaptic differentiation at the developing neuromuscular junction. We used cultures of chick ventral spinal cord neurons with rat myotubes and immunofluorescence with species-specific antibodies to determine the distribution of agrin secreted by neurons and compare it to the distribution of agrin secreted by myotubes. In addition, we determined the distribution of agrin secreted by isolated chick ventral spinal cord neurons and rat motor neurons grown on a substrate that binds agrin. In cocultures, neuronal agrin was concentrated along axons at sites of axon-induced acetylcholine receptor (AChR) aggregation and was found at every such synaptic site, consistent with its role in synaptogenesis. Smaller amounts of agrin were found on dendrites and cell bodies and rarely were associated with AChR aggregation. Muscle agrin, recognized by an antibody against rat agrin, was found at nonsynaptic sites of AChR aggregation but was not detected at synaptic sites, in contrast to neuronal agrin. In cultures of isolated chick neurons or rat motor neurons, agrin was deposited relatively uniformly around axons and dendrites during the first 2-3 days in culture. In older cultures, agrin immunoreactivity was markedly more intense around axons than dendrites, indicating that motor neurons possess an intrinsic, developmentally regulated program to target agrin secretion to axons.     

The putative agrin receptor binds ligand in a calcium-dependent manner and aggregates during agrin-induced acetylcholine receptor clustering.

Agrin derived from Torpedo electric organ induces the clustering of acetylcholine receptors (AChRs) on cultured myotubes. As a first step toward characterizing the plasma membrane receptor for agrin, we have examined agrin binding to cultured myotubes. Agrin binding is saturable as measured by radioimmunoassay and, like agrin-induced AChR clustering, requires extracellular calcium. Immunofluorescence shows that on myotubes incubated with agrin at 4 degrees C, agrin binds in a uniform, finely punctate pattern that correlates poorly with the distribution of AChRs. Myotubes stimulated with agrin at 37 degrees C for greater than or equal to 2 hr show a coclustering of agrin binding sites and AChRs. By contrast, if anti-AChR antibodies are used either to cluster or to internalize AChRs, the distribution and number of agrin binding sites remain unchanged. The aggregation and calcium dependence of the putative agrin receptor may represent important control points in postsynaptic differentiation.     

C. elegans G protein regulator RGS-3 controls sensitivity to sensory stimuli

Signal transduction through heterotrimeric G proteins is critical for sensory response across species. Regulator of G protein signaling (RGS) proteins are negative regulators of signal transduction. Herein we describe a role for C. elegans RGS-3 in the regulation of sensory behaviors. rgs-3 mutant animals fail to respond to intense sensory stimuli but respond normally to low concentrations of specific odorants. We find that loss of RGS-3 leads to aberrantly increased G protein-coupled calcium signaling but decreased synaptic output, ultimately leading to behavioral defects. Thus, rgs-3 responses are restored by decreasing G protein-coupled signal transduction, either genetically or by exogenous dopamine, by expressing a calcium-binding protein to buffer calcium levels in sensory neurons or by enhancing glutamatergic synaptic transmission from sensory neurons. Therefore, while RGS proteins generally act to downregulate signaling, loss of a specific RGS protein in sensory neurons can lead to defective responses to external stimuli.     

The ordered visual transduction complex of the squid photoreceptor membrane

The study of visual transduction has given invaluable insight into the mechanisms of signal transduction by heptahelical receptors that act via guanine nucleotide binding proteins (G-proteins). However, the cyclic-GMP second messenger system seen in vertebrate photoreceptor cells is not widely used in other cell types. In contrast, the retina of higher invertebrates, such as squid, offers an equally accessible transduction system, which uses the widespread second messenger chemistry of an increase in cytosolic calcium caused by the production of inositol-(1,4,5)-trisphosphate (InsP3) by the enzyme phospholipase C, and which may be a model for store-operated calcium influx. In this article, we highlight some key aspects of invertebrate visual transduction as elucidated from the combination of biochemical techniques applied to cephalopods, genetic techniques applied to flies, and electrophysiology applied to the horseshoe crab. We discuss the importance and applicability of ideas drawn from these model systems to the understanding of some general processes in signal transduction, such as the integration of the cytoskeleton into the signal transduction process and the possible modes of regulation of store-operated calcium influx.     

Calcium plays a critical role in determining the acetylcholine receptor-clustering activities of alternatively spliced isoforms of Agrin

Neural agrin, an extracellular matrix protein secreted by motor neurons, plays a key role in clustering of nicotinic acetylcholine receptors (AChR) on postsynaptic membranes of the neuromuscular junction. The action of agrin is critically dependent on an eight-amino acid insert (z8 insert) in the third of three consecutive laminin-like globular (G3) domains near the C terminus of neural agrin. Alternatively spliced agrin isoforms in non-neural tissue including muscle lack the z8 insert and are biologically inactive. Extracellular calcium has been shown to be imperative for the AChR-clustering activity of neural agrin. It is unclear, however, whether calcium preferentially interacts with the neural isoform or whether it acts solely as an intracellular messenger that mediates agrin signaling. Here, we report the G3 domain of rat neural agrin (AgG3z8) expressed in Pichia pastoris promoted AChR clustering on surface of C2C12 myotubes in a calcium-dependent manner. Direct binding of calcium to AgG3z8 was demonstrated by trypsin digestion and thermal denaturation experiments. Moreover, calcium induced a significant change in the conformation of AgG3z8, and the effect was correlated with an enhanced binding affinity of the protein to muscle receptor. Mutation of calcium-binding residues in the G3 domain diminished the conformational change of neural agrin, reduced its binding affinity to muscle membrane, and inhibited AChR-clustering activity. Conversely, the G3 domain of muscle agrin (AgG3z0) displayed little structural change in the presence of calcium, bound poorly to muscle surface, and was inactive in AChR-clustering assays. We conclude that distinct interactions of the G3 domain with calcium determine the biological activities of alternatively spliced agrin isoforms during synapse formation.     

LRP4 serves as a coreceptor of agrin

Neuromuscular junction (NMJ) formation requires agrin, a factor released from motoneurons, and MuSK, a transmembrane tyrosine kinase that is activated by agrin. However, how signal is transduced from agrin to MuSK remains unclear. We report that LRP4, a low-density lipoprotein receptor (LDLR)-related protein, is expressed specifically in myotubes and binds to neuronal agrin. Its expression enables agrin binding and MuSK signaling in cells that otherwise do not respond to agrin. Suppression of LRP4 expression in muscle cells attenuates agrin binding, agrin-induced MuSK tyrosine phosphorylation, and AChR clustering. LRP4 also forms a complex with MuSK in a manner that is stimulated by agrin. Finally, we showed that LRP4 becomes tyrosine-phosphorylated in agrin-stimulated muscle cells. These observations indicate that LRP4 is a coreceptor of agrin that is necessary for MuSK signaling and AChR clustering and identify a potential target protein whose mutation and/or autoimmunization may cause muscular dystrophies.     

Crosstalk between jasmonic acid, ethylene and Nod factor signaling allows integration of diverse inputs for regulation of nodulation

Plant hormones interact at many different levels to form a network of signaling pathways connected by antagonistic and synergistic interactions. Ethylene and jasmonic acid both act to regulate the plant's responsiveness to a common set of biotic stimuli. In addition ethylene has been shown to negatively regulate the plant's response to the rhizobial bacterial signal, Nod factor. This regulation occurs at an early step in the Nod factor signal transduction pathway, at or above Nod factor-induced calcium spiking. Here we show that jasmonic acid also inhibits the plant's responses to rhizobial bacteria, with direct effects on Nod factor-induced calcium spiking. However, unlike ethylene, jasmonic acid not only inhibits spiking but also suppresses the frequency of calcium oscillations when applied at lower concentrations. This effect of jasmonic acid is amplified in the ethylene-insensitive mutant skl, indicating an antagonistic interaction between these two hormones for regulation of Nod factor signaling. The rapidity of the effects of ethylene and jasmonic acid on Nod factor signaling suggests direct crosstalk between these three signal transduction pathways. This work provides a model by which crosstalk between signaling pathways can rapidly integrate environmental, developmental and biotic stimuli to coordinate diverse plant responses.     

Scube2 mediates Hedgehog signalling in the zebrafish embryo

The Hedgehog family of secreted morphogens specifies the fate of a large number of different cell types within invertebrate and vertebrate embryos, including the muscle cell precursors of the embryonic myotome of zebrafish. Formation of Hedgehog-sensitive muscle fates is disrupted within homozygous zebrafish mutants of the "you"-type class, the majority of which disrupt components of the Hedgehog (HH) signal transduction pathway. We have undertaken a phenotypic and molecular characterisation of one of these mutants, you, which we show results from mutations within the zebrafish orthologue of the mammalian gene scube2. This gene encodes a member of the Scube family of proteins, which is characterised by several protein motifs including EGF and CUB domains. Epistatic and molecular analyses position Scube2 function upstream of Smoothened (Smoh), the signalling component of the HH receptor complex, suggesting that Scube2 may act during HH signal transduction prior to, or during, receipt of the HH signal at the plasma membrane. In support of this model we show that scube2 has homology to cubilin, which encodes an endocytic receptor involved in protein trafficking suggesting a possible mode of function for Scube2 during HH signal transduction.     

Lanthanide ions are agonists of transient gene expression in rice protoplasts and act in synergy with ABA to increase Em gene expression

Previous work has shown that in rice suspension cells, NaCl at 0.4 M can induce Em gene expression and act synergistically with ABA, possibly by potentiating the ABA response pathway through a rate-limiting intermediate (R.M. Bostock and R.S. Quatrano (1992) Plant Physiol., 98, 1356–1363). Since calcium is an intermediate in ABA regulation of stomatal closure, we tested the effect of calcium changes on ABA-inducible Em gene expression in transiently transformed rice protoplasts. We show that calcium is required for ABA-inducible Em-GUS expression and can act in synergy with ABA. The trivalent ions lanthanum, gadolinium, and aluminum, which are known to interact with calcium- and other signaling pathways, can act at sub-millimolar concentrations to increase GUS reporter gene expression driven by several promoters in transiently transformed rice protoplasts. This effect is not specific for the ABA-inducible Em promoter, but is synergistic with ABA. The lanthanum synergy with ABA does not require calcium. In rice suspension cells, lanthanum alone does not induce Em gene expression, in contrast to transiently transformed protoplasts, yet can act synergistically with ABA to effectively increase the sensitivity to ABA greater than tenfold. Trivalent ions may be a useful tool to study the regulation of gene expression. The possible effects of trivalent ions on ABA signal transduction and gene expression are discussed.     

Phytochrome and UV signal transduction pathways

The phytochromes are the best studied plant photoreceptors, controlling a wide variety of responses at both whole plant and single cell levels. Three signal transduction pathways, dependent on cGMP and/or calcium, have been found to be utilized by phytochrome to control the expression of genes required for chloroplast development (e.g., CAB and FNR) and anthocyanin biosynthesis (e.g., CHS). In particular, cGMP is a second messenger positively regulating CHS gene expression whilst calcium and calmodulin act as negative regulators. In addition to phytochrome regulation of CHS we have begun to examine the signal transduction pathways utilized by UV photoreceptors. In contrast to phytochrome-mediated responses, results indicate a role for calcium and calmodulin as positive regulators of CHS gene expression in UV light.     

Calcium/calmodulin transduces thrombin-stimulated secretion: studies in intact and minimally permeabilized human umbilical vein endothelial cells

Thrombin stimulates cultured endothelial cells (EC) to secrete stored von Willebrand factor (vWF), but the signal transduction pathways are poorly defined. Thrombin is known to elevate the concentration of intracellular calcium ([Ca2+]i) and to activate protein kinase C (PKC) in EC. Since both calcium ionophores and phorbol esters release vWF, both second messenger pathways have been postulated to participate in vWF secretion in response to naturally occurring agonists. We find that in intact human EC, vWF secretion stimulated by either thrombin or by a thrombin receptor activating peptide, TR(42-55), can be correlated with agonist-induced elevations of [Ca2+]i. Further evidence implicating calcium in the signal transduction pathway is suggested by the finding that MAPTAM, a cell-permeant calcium chelator, in combination with the extracellular calcium chelator EGTA, can inhibit thrombin-stimulated secretion. In contrast, the observation that staurosporine (a pharmacological inhibitor of PKC) blocks phorbol ester- but not thrombin-stimulated secretion provides evidence against PKC-mediated signal transduction. To examine further the signal transduction pathway initiated by thrombin, we developed novel conditions for minimal permeabilization of EC with saponin (4-8 micrograms/ml for 5-15 min at 37 degrees C) which allow the introduction of small extracellular molecules without the loss of large intracellular proteins and which retain thrombin-stimulated secretion. These minimally permeabilized cells secrete vWF in response to exogenous calcium, and EGTA blocks thrombin-induced secretion. Moreover, in these cells, thrombin- stimulated secretion is blocked by a calmodulin-binding inhibitory peptide but not by a PKC inhibitory peptide. Taken together, these findings demonstrate that thrombin-stimulated vWF secretion is transduced by a rise in [Ca2+]i and provide the first evidence for the role of calmodulin in this process.     

The NFP locus of Medicago truncatula controls an early step of Nod factor signal transduction upstream of a rapid calcium flux and root hair deformation

Establishment of the Rhizobium-legume symbiosis depends on a molecular dialogue, in which rhizobial nodulation (Nod) factors act as symbiotic signals, playing a key role in the control of specificity of infection and nodule formation. Using nodulation-defective (Nod-) mutants of Medicago truncatula to study the mechanisms controlling Nod factor perception and signalling, we have previously identified five genes that control components of a Nod factor-activated signal transduction pathway. Characterisation of a new M. truncatula Nod- mutant led to the identification of the Nod Factor Perception (NFP) locus. The nfp mutant has a novel phenotype among Nod- mutants of M. truncatula, as it does not respond to Nod factors by any of the responses tested. The nfp mutant thus shows no rapid calcium flux, the earliest detectable Nod factor response of wild-type plants, and no root hair deformation. The nfp mutant is also deficient in Nod factor-induced calcium spiking and early nodulin gene expression. While certain genes controlling Nod factor signal transduction also control the establishment of an arbuscular mycorrhizal symbiosis, the nfp mutant shows a wild-type mycorrhizal phenotype. These data indicate that the NFP locus controls an early step of Nod factor signal transduction, upstream of previously identified genes and specific to nodulation.     

Dystroglycan overexpression in vivo alters acetylcholine receptor aggregation at the neuromuscular junction

Dystroglycan is a member of the transmembrane dystrophin glycoprotein complex in muscle that binds to the synapse-organizing molecule agrin. Dystroglycan binding and AChR aggregation are mediated by two separate domains of agrin. To test whether dystroglycan plays a role in receptor aggregation at the neuromuscular junction, we overexpressed it by injecting rabbit dystroglycan RNA into one- or two-celled Xenopus embryos. We measured AChR aggregation in myotomes by labeling them with rhodamine-alpha-bungarotoxin followed by confocal microscopy and image analysis. Dystroglycan overexpression decreased AChR aggregation at the neuromuscular junction. This result is consistent with dystroglycan competition for agrin without signaling AChR aggregation. It also supports the hypothesis that dystroglycan is not the myotube-associated specificity component, (MASC) a putative coreceptor needed for agrin to activate muscle-specific kinase (MuSK) and signal AChR aggregation. Dystroglycan was distributed along the surface of muscle membranes, but was concentrated at the ends of myotomes, where AChRs normally aggregate at synapses. Overexpressed dystroglycan altered AChR aggregation in a rostral-caudal gradient, consistent with the sequential development of neuromuscular synapses along the embryo. Increasing concentrations of dystroglycan RNA did not further decrease AChR aggregation, but decreased embryo survival. Development often stopped during gastrulation, suggesting an essential, nonsynaptic role of dystroglycan during this early period of development.