Grip and slip of L1-CAM on adhesive substrates direct growth cone haptotaxis

Abe, Kouki; Katsuno, Hiroko; Toriyama, Minoru; Baba, Kenichiro; Mori, Tomoyuki; Hakoshima, Toshio; Kanemura, Yonehiro; Watanabe, Rikiya; Inagaki, Naoyuki

doi:10.1073/pnas.1711667115

Cited by 31 publications

(87 citation statements)

References 41 publications

(75 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…To assess shootin1a-mediated clutch coupling on laminin, we measured F-actin retrograde flow in growth cones on laminin. Consistent with previously reported data ( Abe et al, 2018 ), the F-actin retrograde flow rate in control growth cones on laminin was 2.3 ± 0.3 μm/min ( Figure 7—figure supplement 4D ). As in the case of growth cones on L1-CAM ( Figure 6A and B ), overexpression of shootin1a (1-125) increased significantly the retrograde flow rate under these conditions ( Figure 7—figure supplement 4D ), indicating that inhibition of the shootin1a–L1-CAM interaction also disrupts F-actin-adhesion coupling in growth cones on laminin.…”

Section: Resultssupporting

confidence: 92%

“…Laminins are widely used substrates for axon guidance assays ( Turney and Bridgman, 2005 ; Nichol et al, 2016 ); L1-CAM on growth cones interacts directly with laminin presented on the substrate ( Hall et al, 1997 ; Abe et al, 2018 ). To examine whether the shootin1a–L1-CAM interaction mediates netrin-1–induced axon guidance generally, we performed an axon guidance assay on an alternative substrate, laminin.…”

Section: Resultsmentioning

confidence: 99%

See 1 more Smart Citation

Gradient-reading and mechano-effector machinery for netrin-1-induced axon guidance

Baba

Yoshida

Toriyama

et al. 2018

eLife

Self Cite

View full text Add to dashboard Cite

Growth cones navigate axonal projection in response to guidance cues. However, it is unclear how they can decide the migratory direction by transducing the local spatial cues into protrusive forces. Here we show that knockout mice of Shootin1 display abnormal projection of the forebrain commissural axons, a phenotype similar to that of the axon guidance molecule netrin-1. Shallow gradients of netrin-1 elicited highly polarized Pak1-mediated phosphorylation of shootin1 within growth cones. We demonstrate that netrin-1–elicited shootin1 phosphorylation increases shootin1 interaction with the cell adhesion molecule L1-CAM; this, in turn, promotes F-actin–adhesion coupling and concomitant generation of forces for growth cone migration. Moreover, the spatially regulated shootin1 phosphorylation within growth cones is required for axon turning induced by netrin-1 gradients. Our study defines a mechano-effector for netrin-1 signaling and demonstrates that shootin1 phosphorylation is a critical readout for netrin-1 gradients that results in a directional mechanoresponse for axon guidance.

show abstract

Section: Resultssupporting

confidence: 92%

Section: Resultsmentioning

confidence: 99%

Gradient-reading and mechano-effector machinery for netrin-1-induced axon guidance

Baba

Yoshida

Toriyama

et al. 2018

eLife

Self Cite

View full text Add to dashboard Cite

show abstract

“…The tip of an extending axon also bears a growth cone ( Lowery and Van Vactor, 2009 ), and axonal growth cones produce traction forces for axon outgrowth and guidance ( Chan and Odde, 2008 ; Koch et al, 2012 ; Abe et al, 2018 ; Baba et al, 2018 ). Decades of analyses of axonal growth cones have revealed a key machinery to generate traction forces for growth cone migration.…”

Section: Forces For Leading Process Extensionmentioning

confidence: 99%

“…Shootin1a interacts with F-actin retrograde flow through its association with the F-actin-interacting protein cortactin ( Kubo et al, 2015 ). Shootin1a also interacts with the cell adhesion molecule L1-CAM ( Baba et al, 2018 ), which binds to the ECM protein laminin ( Abe et al, 2018 ) as well as to L1-CAM expressed on neighboring cells ( Lemmon et al, 1989 ), thereby mechanically coupling the F-actin retrograde flow with the adhesive substrates. The shootin1a-mediated actin–adhesion coupling generates traction forces for axon outgrowth ( Kubo et al, 2015 ) and axon guidance induced by diffusible and substrate-bound chemical cues ( Abe et al, 2018 ; Baba et al, 2018 ).…”

Section: Forces For Leading Process Extensionmentioning

confidence: 99%

“…Shootin1a also interacts with the cell adhesion molecule L1-CAM ( Baba et al, 2018 ), which binds to the ECM protein laminin ( Abe et al, 2018 ) as well as to L1-CAM expressed on neighboring cells ( Lemmon et al, 1989 ), thereby mechanically coupling the F-actin retrograde flow with the adhesive substrates. The shootin1a-mediated actin–adhesion coupling generates traction forces for axon outgrowth ( Kubo et al, 2015 ) and axon guidance induced by diffusible and substrate-bound chemical cues ( Abe et al, 2018 ; Baba et al, 2018 ). N-cadherin–catenin complexes were also reported to mediate actin–adhesion coupling at the axonal growth cone ( Bard et al, 2008 ; Garcia et al, 2015 ).…”

Section: Forces For Leading Process Extensionmentioning

confidence: 99%

See 1 more Smart Citation

Forces to Drive Neuronal Migration Steps

Minegishi

Inagaki

2020

Front. Cell Dev. Biol.

Self Cite

View full text Add to dashboard Cite

To establish and maintain proper brain architecture and elaborate neural networks, neurons undergo massive migration. As a unique feature of their migration, neurons move in a saltatory manner by repeating two distinct steps: extension of the leading process and translocation of the cell body. Neurons must therefore generate forces to extend the leading process as well as to translocate the cell body. In addition, neurons need to switch these forces alternately in order to orchestrate their saltatory movement. Recent studies with mechanobiological analyses, including traction force microscopy, cell detachment analyses, live-cell imaging, and loss-of-function analyses, have begun to reveal the forces required for these steps and the molecular mechanics underlying them. Spatiotemporally organized forces produced between cells and their extracellular environment, as well as forces produced within cells, play pivotal roles to drive these neuronal migration steps. Traction force produced by the leading process growth cone extends the leading processes. On the other hand, mechanical tension of the leading process, together with reduction in the adhesion force at the rear and the forces to drive nucleokinesis, translocates the cell body. Traction forces are generated by mechanical coupling between actin filament retrograde flow and the extracellular environment through clutch and adhesion molecules. Forces generated by actomyosin and dynein contribute to the nucleokinesis. In addition to the forces generated in cell-intrinsic manners, external forces provided by neighboring migratory cells coordinate cell movement during collective migration. Here, we review our current understanding of the forces that drive neuronal migration steps and describe the molecular machineries that generate these forces for neuronal migration.

show abstract