Mechanisms of convergence and extension by cell intercalation

Keller, Ray; Davidson, Lance A.; Edlund, Anna; Elul, Tamira; Ezin, Max; Shook, David; Skoglund, Paul

doi:10.1098/rstb.2000.0626

Cited by 461 publications

(402 citation statements)

References 97 publications

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“…The localization of XF protein to the developing notochord-somite boundaries suggests that XF functions in the process of axial convergence and extension driven by cell intercalation, because these boundaries have been implicated in regulating convergence and extension at several levels (Keller et al, 2000). These matrix-containing structures appear and elongate as straight lines of separation of presumptive notochordal and somitic cells at stage 11-11.5, the midgastrula (Shih and Keller, 1992b), and the pattern of boundary formation is reflected in the pattern of induction of cell motile behaviors that drive intercalation and thus dorsal, axial morphogenesis.…”

Section: Possible Functions For Xf In Convergence and Extensionmentioning

confidence: 99%

“…The bulk of this morphogenesis occurs at gastrulation and is largely driven by convergence and extension of the involuting axial and paraxial mesoderm that gives rise to notochord and somites. This convergence and extension is driven by a patterned cell motility in this tissue termed mediolateral intercalation behavior (MIB) (Keller et al, 2000). This tissue exhibits an anisotropic increase in stiffness and generates directed force to drive normal, asymmetric blastopore closure and archenteron elongation at gastrulation (Moore et al, 1995).…”

Section: Introductionmentioning

confidence: 99%

“…This boundary regulates both cell motility, by inducing presumptive notochordal cells that contact the boundary to transit from a bipolar to a monopolar protrusive state, and the expression of cell fate in the presumptive notochord (Domingo and Keller, 1995). However, the molecular basis underlying regulation of this patterned cell motility, the change in stiffness and force production exhibited by this tissue, and the role of the ECM at the developing notochord-somite boundary, remains unclear (Keller et al, 2000).…”

Section: Introductionmentioning

confidence: 99%

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Xenopus fibrillin is expressed in the organizer and is the earliest component of matrix at the developing notochord‐somite boundary

Skoglund

Dzamba

Coffman

et al. 2006

Developmental Dynamics

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We identify a Xenopus fibrillin homolog (XF), and show that its earliest developmental expression is in presumptive dorsal mesoderm at gastrulation, and that XF expression is regulated by mesoderm-inducing factors in animal cap assays. XF protein is also first detected in presumptive mesoderm, but is concentrated specifically into extracellular-matrix structures that begin to develop de novo by mid-gastrulation at both of the bilateral presumptive notochord-somite boundaries. Later in embryogenesis, XF protein is localized to the extracellular matrix at tissue boundaries, where it is found surrounding the notochord, the somites, and the neural tube, as well as under the epidermis. This pattern of protein deposition combines to give the appearance of an "embryonic skeleton," suggesting that one role for XF is to serve as a mechanical element in the embryo prior to bone deposition.

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Section: Possible Functions For Xf In Convergence and Extensionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Xenopus fibrillin is expressed in the organizer and is the earliest component of matrix at the developing notochord‐somite boundary

Skoglund

Dzamba

Coffman

et al. 2006

Developmental Dynamics

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“…Adhesive forces Detailed modeling of cell adhesion is a major effort in itself, and as a simplification the PO model splits the adhesional force into two components, one tangential to the cell membrane and one normal to the membrane. This is motivated by the idea that cell adhesion may be less resistant to tangential forces and more resistant to normal forces (Keller et al, 2000).…”

Section: Article In Pressmentioning

confidence: 99%

How cellular movement determines the collective force generated by the Dictyostelium discoideum slug

Dallon

Othmer

2004

Journal of Theoretical Biology

106

132

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How the collective motion of cells in a biological tissue originates in the behavior of a collection of individuals, each of which responds to the chemical and mechanical signals it receives from neighbors, is still poorly understood. Here we study this question for a particular system, the slug stage of the cellular slime mold Dictyostelium discoideum (Dd). We investigate how cells in the interior of a migrating slug can effectively transmit stress to the substrate and thereby contribute to the overall motive force. Theoretical analysis suggests necessary conditions on the behavior of individual cells, and computational results shed light on experimental results concerning the total force exerted by a migrating slug. The model predicts that only cells in contact with the substrate contribute to the translational motion of the slug. Since the model is not based specifically on the mechanical properties of Dd cells, the results suggest that this behavior will be found in many developing systems. r

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“…Near the end of epiboly, lateral mesodermal cells form tightly packed aggregates that converge using dorsalward translocation of cell groups and extend (Jessen et al, 2002). In Xenopus laevis and in the notochord of the zebrafish, convergence and extension of the mesoderm are driven by the mediolateral intercalation of cells (Keller et al, 2000;Glickman et al, 2003). Ectodermal cells manage a similar morphogenesis while in the apparent configuration of a cellular sheet (Concha and Adams, 1998).…”

Section: Introductionmentioning

confidence: 99%

Initiation of convergence and extension movements of lateral mesoderm during zebrafish gastrulation

Sepich

Calmelet

Kiskowski

et al. 2005

Developmental Dynamics

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Embryonic morphogenesis is accomplished by cellular movements, rearrangements, and cell fate inductions. Vertebrate gastrulation entails morphogenetic processes that generate three germ layers, endoderm, mesoderm, and ectoderm, shaped into head, trunk, and tail. To understand how cell migration mechanistically contributes to tissue shaping during gastrulation, we examined migration of lateral mesoderm in the zebrafish. Our results illustrate that cell behaviors, different from mediolaterally oriented cell intercalation, also promote convergence and extension (C&E). During early gastrulation, upon internalization, individually migrating mesendodermal cells contribute to the elongation of the mesoderm by moving animally, without dorsal movement. Convergence toward dorsal starts later, by 70% epiboly (7.7 hpf). Depending on location along the Animal-Vegetal axis, an animal or vegetal bias is added to the dorsalward movement, so that paths fan out and the lateral mesoderm both converges and extends. Onset of convergence is independent of noncanonical Wnt signaling but is delayed when Stat3 signaling is compromised. To understand which aspects of motility are controlled by guidance cues, we measured turning behavior of lateral mesodermal cells. We show that cells exhibit directional preference, directionally-regulated speed, and turn toward dorsal when off-course. We estimate that ectoderm could supply from a fraction to all the dorsalward displacement seen in mesoderm cells. Using mathematical modeling, we demonstrate that directional preference is sufficient to account for mesoderm convergence and extension, and that, at minimum, two sources of guidance cues could orient cell paths realistically if located in the dorsal midline. Developmental Dynamics 234:279 -292, 2005.

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Mechanisms of convergence and extension by cell intercalation

Cited by 461 publications

References 97 publications

Xenopus fibrillin is expressed in the organizer and is the earliest component of matrix at the developing notochord‐somite boundary

Xenopus fibrillin is expressed in the organizer and is the earliest component of matrix at the developing notochord‐somite boundary

How cellular movement determines the collective force generated by the Dictyostelium discoideum slug

Initiation of convergence and extension movements of lateral mesoderm during zebrafish gastrulation

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