Syndecan regulates cell migration and axon guidance in<i>C. elegans</i>

Rhiner, Christa; Gysi, Stephan; Fröhli, Erika; Hengartner, Michael O.; Hajnal, Alex

doi:10.1242/dev.02042

Cited by 112 publications

(193 citation statements)

References 46 publications

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“…In C. elegans, PVPR pioneer axon navigation defects observed in fmi-1-deficient animals are also reported for several other genes, e.g. the basement membrane components UNC-6/NETRIN and NID-1/NIDOGEN, the IgCAMs WRK-1 and SAX-3/ROBO, the Fatlike cadherin CDH-4, and the SYNDECAN ortholog SDN-1 (Boulin et al, 2006;Hutter, 2003;Rhiner et al, 2005;Schmitz et al, 2008;Schwarz et al, 2009). fmi-1-deficient animals, as well as lin-17/frizzled, cdh-4 and nid-1 mutants, show highly penetrant PVPR defects, suggesting that in this complex network of guidance cues, these molecules might play a central role for correct axon navigation and midline avoidance of the PVPR pioneer axon.…”

Section: Fmi-1 Mediates Axon Track Formation In the Vncmentioning

confidence: 60%

The Flamingo ortholog FMI-1 controls pioneer-dependent navigation of follower axons inC. elegans

et al. 2010

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SUMMARYDevelopment of a functional neuronal network during embryogenesis begins with pioneer axons creating a scaffold along which later-outgrowing axons extend. The molecular mechanism used by these follower axons to navigate along pre-existing axons remains poorly understood. We isolated loss-of-function alleles of fmi-1, which caused strong axon navigation defects of pioneer and follower axons in the ventral nerve cord (VNC) of C. elegans. Notably follower axons, which exclusively depend on pioneer axons for correct navigation, frequently separated from the pioneer. fmi-1 is the sole C. elegans ortholog of Drosophila flamingo and vertebrate Celsr genes, and this phenotype defines a new role for this important molecule in follower axon navigation. FMI-1 has a unique and strikingly conserved structure with cadherin and C-terminal G-protein coupled receptor domains and could mediate cell-cell adhesion and signaling functions. We found that follower axon navigation depended on the extracellular but not on the intracellular domain, suggesting that FMI-1 mediates primarily adhesion between pioneer and follower axons. By contrast, pioneer axon navigation required the intracellular domain, suggesting that FMI-1 acts as receptor transducing a signal in this case. Our findings indicate that FMI-1 is a cell-type dependent axon guidance factor with different domain requirements for its different functions in pioneers and followers.

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Section: Fmi-1 Mediates Axon Track Formation In the Vncmentioning

confidence: 60%

The Flamingo ortholog FMI-1 controls pioneer-dependent navigation of follower axons inC. elegans

et al. 2010

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“…For example, in both Drosophila and C. elegans, syndecan regulates slit-Robo-mediated midline guidance events (Hu 2001;Johnson et al 2004;Steigemann et al 2004;Rhiner et al 2005), and in Drosophila, dally-like can compensate for the loss of syndecan (Johnson et al 2004). In contrast, during visual system assembly and synaptic development, there is only limited rescue of syndecan mutant defects with dallylike transgenes and vice versa; this suggests that dallylike and syndecan can serve distinct functions .…”

Section: Discussionmentioning

confidence: 99%

The extracellular matrix proteoglycan perlecan facilitates transmembrane semaphorin-mediated repulsive guidance

et al. 2012

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The Drosophila transmembrane semaphorin-1a (Sema-1a) is a repulsive guidance cue that uses the Plexin A (PlexA) receptor during neural development. Sema-1a is required in axons to facilitate motor axon defasciculation at guidance choice points. We found that mutations in the trol gene strongly suppress Sema-1a-mediated repulsive axon guidance. trol encodes the phylogenetically conserved secreted heparan sulfate proteoglycan (HSPG) perlecan, a component of the extracellular matrix. Motor axon guidance defects in perlecan mutants resemble those observed in Sema-1a-and PlexA-null mutant embryos, and perlecan mutants genetically interact with PlexA and Sema-1a. Perlecan protein is found in both the CNS and the periphery, with higher expression levels in close proximity to motor axon trajectories and pathway choice points. Restoring perlecan to mutant motor neurons rescues perlecan axon guidance defects. Perlecan augments the reduction in phospho-focal adhesion kinase (phospho-FAK) levels that result from treating insect cells in vitro with Sema-1a, and genetic interactions among integrin, Sema-1a, and FAK in vivo support an antagonistic relationship between Sema-1a and integrin signaling. Therefore, perlecan is required for Sema-1a-PlexA-mediated repulsive guidance, revealing roles for extracellular matrix proteoglycans in modulating transmembrane guidance cue signaling during neural development.

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“…The native HSPGs involved in this process are not known and require further investigation, however, several HSPGs are expressed in Xenopus embryos in tissue specific patterns during gastrulation including Syndecans-1 and -2 [expressed in the ectoderm (44)] and Syndecan-4, Glypican-4, and Biglycan [expressed in the ectoderm and mesoderm (44)(45)(46)(47)]. Although the role(s) of these HSPGs in mesendoderm migration have not been investigated, they are involved in a wide range of processes that involve cell rearrangements including embryonic development, wound healing, angiogenesis, neuronal cell migration and cancer cell invasion through their interactions with ECM molecules, growth factors, cytokines, and chemokines (38,(48)(49)(50)(51). For example, as discussed above, knock-down of either Syndecan-1 or -2 disrupts the blastocoel roof ECM and results in gaps in fibril deposition (38).…”

Section: Discussionmentioning

confidence: 99%

PDGF-A interactions with fibronectin reveal a critical role for heparan sulfate in directed cell migration during Xenopus gastrulation

Smith

Mitsi

Nugent

et al. 2009

Proc. Natl. Acad. Sci. U.S.A.

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Platelet-derived growth factor (PDGF) signaling is essential for processes involving cell motility and differentiation during embryonic development in a wide variety of organisms including the mouse, frog, zebrafish, and sea urchin. In early Xenopus laevis embryos, PDGF-AA provides guidance cues for the migration of anterior mesendoderm cells as they move across a fibronectin-rich extracellular matrix. The long form of PDGF-A includes a positively charged carboxyl-terminal retention motif that can interact with the extracellular matrix and heparan sulfate proteoglycans (HSPGs). In this study we demonstrate that PDGF-AA binds directly to fibronectin and that this association is greatly enhanced by heparin. The PDGF-AA-fibronectin binding occurs across a broad range of pHs (5.5-9), which is significant because the PDGF-guided migration of Xenopus mesendoderm cells occurs under basic extracellular conditions (pH 8.4). We further demonstrate that endogenous HSPG's are required for the PDGF-AA-guided mesendoderm movement, suggesting an in vivo role for HSPGs in mediating the interaction between PDGF-AA and fibronectin.embryo ͉ embryonic development ͉ mesendoderm ͉ mesoderm

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Syndecan regulates cell migration and axon guidance inC. elegans

Cited by 112 publications

References 46 publications

The Flamingo ortholog FMI-1 controls pioneer-dependent navigation of follower axons inC. elegans

The Flamingo ortholog FMI-1 controls pioneer-dependent navigation of follower axons inC. elegans

The extracellular matrix proteoglycan perlecan facilitates transmembrane semaphorin-mediated repulsive guidance

PDGF-A interactions with fibronectin reveal a critical role for heparan sulfate in directed cell migration during Xenopus gastrulation

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