Fumio Nakamura

Plexin-Neuropilin-1 Complexes Form Functional Semaphorin-3A Receptors

Class 1 and 3 semaphorins repulse axons but bind to different cell surface proteins. We find that the two known semaphorin-binding proteins, plexin 1 (Plex 1) and neuropilin-1 (NP-1), form a stable complex. Plex 1 alone does not bind semaphorin-3A (Sema3A), but the NP-1/Plex 1 complex has a higher affinity for Sema3A than does NP-1 alone. While Sema3A binding to NP-1 does not alter nonneuronal cell morphology, Sema3A interaction with NP-1/Plex 1 complexes induces adherent cells to round up. Expression of a dominant-negative Plex 1 in sensory neurons blocks Sema3A-induced growth cone collapse. Sema3A treatment leads to the redistribution of growth cone NP-1 and plexin into clusters. Thus, physiologic Sema3A receptors consist of NP-1/plexin complexes.

Neuropilin-1 Extracellular Domains Mediate Semaphorin D/III-Induced Growth Cone Collapse

Somatosensory axon outgrowth is repulsed when soluble semaphorin D (semD) binds to growth cone neuropilin-1 (Npn-1). Here, semD ligand binding studies of Npn-1 mutants demonstrate that the sema domain binds to the amino-terminal quarter, or complement-binding (CUB) domain, of Npn-1. By herpes simplex virus- (HSV-) mediated expression of Npn-1 mutants in chick retinal ganglion cells, we show that semD-induced growth cone collapse requires two segments of the ectodomain of Npn-1, the CUB domain and the juxtamembrane portion, or MAM (meprin, A5, mu) domain. In contrast, the transmembrane segment and cytoplasmic tail of Npn-1 are not required for biologic activity. These data imply that the CUB and MAM ectodomains of Npn-1 interact with another transmembrane growth cone protein that in turn transduces a semD signal into axon repulsion.

Semaphorins A and E act as antagonists of neuropilin-1 and agonists of neuropilin-2 receptors.

Neuropilin-1 (NP-1) has been identified as a necessary component of a semaphorin D (SemD) receptor that repulses dorsal root ganglion (DRG) axons during development. SemA and SemE are related to SemD and bind to NP-1, but do not repulse DRG axons. By expressing NP-1 in retinal neurons and NP-2 in DRG neurons, we demonstrate that neuropilins are sufficient to determine the functional specificity of semaphorin responsiveness. SemA and SemE block SemD binding to NP-1 and abolish SemD repulsion in axons expressing NP-1. SemA and SemE seem to have a newly discovered protein antagonist capacity at NP-1 receptors, whereas they act as agonists at receptors containing NP-2.

Growth cone neuropilin‐1 mediates collapsin‐1/sema III facilitation of antero‐ and retrograde axoplasmic transport

Collapsin-1/Sema III, a member of the semaphorin family, has been implicated in axonal pathfinding as a repulsive guidance cue. Cellular and molecular mechanisms by which collapsin-1 exerts its action are not fully understood. Collapsin-1 induces growth cone collapse via a pathway which may include neuropilin-1, a cellsurface collapsin-1 binding protein, as well as intracellular CRMP-62 and heterotrimeric G proteins. We previously identified a second action of collapsin-1, the facilitation of antero- and retrograde axoplasmic transport. This response occurs via a mechanism distinct from that causing growth cone collapse. To investigate the possible involvement of neuropilin-1 in the action of collapsin-1 on axoplasmic transport, we produced a soluble neuropilin-1 (sNP-1) lacking the transmembrane and intracellular region. sNP-1 progressively displaced the dose-response curve for collapsin-1 to induce growth cone collapse to higher concentrations. sNP-1 also inhibited collapsin-1-induced augmentation of both antero- and retrograde axoplasmic transport. Furthermore, an anti-neuropilin-1 antibody blocked the collapsin-induced axoplasmic transport. These results together indicate that neuropilin-1 mediates collapsin-1 action on axoplasmic transport. To visualize collapsin-1 binding to endogenous neuropilin-1, we used a truncated collapsin-1-alkaline phosphatase fusion protein (CAP-4). CAP-4 stains the growth cone, neurite, and cell body. However, local application of collapsin-1 to growth cone but to neither neurite nor cell body promotes axoplasmic transport. Thus, growth cone NP-1 mediates the facilitatory action of collapsin-1 on antero- and retrograde axoplasmic transport.

GAP-43 augmentation of G protein-mediated signal transduction is regulated by both phosphorylation and palmitoylation.

Abstract: The neuronal protein GAP‐43 is concentrated at the growth cone membrane, where it is thought to amplify the signal transduction process. As a model for its neuronal effects, GAP‐43 protein injection into Xenopus laevis oocytes strongly augments the calcium‐sensitive chloride current evoked by the G protein‐coupled receptor stimulation. We have now examined a series of GAP‐43 mutants in this system and determined those regions of GAP‐43 required for this increase in current flux. As expected, palmitoylation inhibits signal amplification in oocytes by blocking G protein activation. Unexpectedly, a second domain of GAP‐43 (residues 35–50) containing a protein kinase C phosphorylation site at residue 41 is also necessary for augmentation of G protein‐coupled signals in oocytes. This region is not required for activation of isolated Go but is necessary for GAP‐43 binding to isolated calmodulin and to isolated protein kinase C. Substitution of Asp for Ser41 inactivates GAP‐43 as a signal facilitator in oocytes. This mutation blocks GAP‐43 binding to both protein kinase C and calmodulin. Thus, GAP‐43 regulates an oocyte signaling cascade via coordinated, simultaneous G protein activation and interaction with either calmodulin or protein kinase C.

Protein tyrosine phosphatase δ mediates the sema3a-induced cortical basal dendritic arborization through the activation of fyn tyrosine kinase

Leukocyte common antigen-related (LAR) class protein tyrosine phosphatases (PTPs) are critical for axonal guidance; however, their relation to specific guidance cues is poorly defined. We here show that PTP-3, a LAR homolog in Caenorhabditis elegans, is involved in axon guidance regulated by Semaphorin-2A-signaling. PTPδ, one of the vertebrate LAR class PTPs, participates in the Semaphorin-3A (Sema3A)-induced growth cone collapse response of primary cultured dorsal root ganglion neurons from Mus musculus embryos. In vivo, however, the contribution of PTPδ in Sema3A-regualted axon guidance was minimal. Instead, PTPδ played a major role in Sema3A-dependent cortical dendritic growth. Ptpδ−/− and Sema3a−/− mutant mice exhibited poor arborization of basal dendrites of cortical layer V neurons. This phenotype was observed in both male and female mutants. The double-heterozygous mutants, Ptpδ+/−; Sema3a+/−, also showed a similar phenotype, indicating the genetic interaction. In Ptpδ−/− brains, Fyn and Src kinases were hyperphosphorylated at their C-terminal Tyr527 residues. Sema3A-stimulation induced dephosphorylation of Tyr527 in the dendrites of wild-type cortical neurons but not of Ptpδ−/−. Arborization of cortical basal dendrites was reduced in Fyn−/− as well as in Ptpδ+/−; Fyn+/− double-heterozygous mutants. Collectively, PTPδ mediates Sema3A-signaling through the activation of Fyn by C-terminal dephosphorylation. SIGNIFICANCE STATEMENT The relation of leukocyte common antigen-related (LAR) class protein tyrosine phosphatases (PTPs) and specific axon guidance cues is poorly defined. We show that PTP-3, a LAR homolog in Caenorhabditis elegans, participates in Sema2A-regulated axon guidance. PTPδ, a member of vertebrate LAR class PTPs, is involved in Sema3A-regulated cortical dendritic growth. In Sema3A signaling, PTPδ activates Fyn and Src kinases by dephosphorylating their C-terminal Tyr residues. This is the first evidence showing that LAR class PTPs participate in Semaphorin signaling in vivo.