Cell behaviors associated with somite segmentation and rotation in <i>Xenopus laevis</i>

Afonin, Bonnie; Ho, Minh; Gustin, Jean K.; Meloty-Kapella, Caroline V.; Domingo, Carmen

doi:10.1002/dvdy.20979

Cited by 42 publications

(56 citation statements)

References 28 publications

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“…In Xenopus, a recent very detailed 3D confocal analysis of embryos confirms earlier explant observations (Wilson et al, 1989) that the expansion of short discrete fissures (Fig. 3B) acts to gently bisect the PSM to form a stable somite border (Afonin et al, 2006). Similarly, in zebrafish, cell rearrangements within a forming somite are minimal and a somite border forms when cells appear to gently detach from neighbors along a medio-to-lateral direction (Fig.…”

Section: Variations In Somite Border Formationsupporting

confidence: 82%

“…Interestingly, although Xenopus somites undergo a 90-degree rotation but do not epithelialize, time-lapse analyses showed that individual cells bend in a precise spatiotemporal manner that propagates in a dorsal-to-ventral direction (Afonin et al, 2006). In a similar manner, in analysis of histological sections from the chick PSM (Duband et al, 1987;Sato et al, 2002;Nakaya et al, 2004), the presumptive posterior border, including the dorsal, ventral, medial, and lateral sleeves of the new somite, appear epithelialized.…”

Section: Targeting Somite Epithelializationmentioning

confidence: 94%

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From segment to somite: Segmentation to epithelialization analyzed within quantitative frameworks

Kulesa

Schnell

Rudloff

et al. 2007

Developmental Dynamics

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One of the most visually striking patterns in the early developing embryo is somite segmentation. Somites form as repeated, periodic structures in pairs along nearly the entire caudal vertebrate axis. The morphological process involves short-and long-range signals that drive cell rearrangements and cell shaping to create discrete, epithelialized segments. Key to developing novel strategies to prevent somite birth defects that involve axial bone and skeletal muscle development is understanding how the molecular choreography is coordinated across multiple spatial scales and in a repeating temporal manner. Mathematical models have emerged as useful tools to integrate spatiotemporal data and simulate model mechanisms to provide unique insights into somite pattern formation. In this short review, we present two quantitative frameworks that address the morphogenesis from segment to somite and discuss recent data of segmentation and epithelialization.

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Section: Variations In Somite Border Formationsupporting

confidence: 82%

Section: Targeting Somite Epithelializationmentioning

confidence: 94%

From segment to somite: Segmentation to epithelialization analyzed within quantitative frameworks

Kulesa

Schnell

Rudloff

et al. 2007

Developmental Dynamics

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“…Here, we show that the protein is detected from the onset of somitogenesis and is enriched at intersomitic junctions and at the notochord/somite boundaries. Somitogenesis requires the mediolateral elongation of presomitic cells, the formation of filopodia protrusions at the onset of rotation, the break of adhesive interactions with the ECM at the notochord/somite boundary, the bending of cells around the dorsoventral axis and finally the elongation and alignment of cells parallel to the notochord (Afonin et al, 2006). Dg is present during these events suggesting that Dg/ECM interactions might govern adhesive properties of cells during somitogenesis and muscle formation.…”

Section: Discussionmentioning

confidence: 99%

“…During gastrulation, presomitic cells of the paraxial mesoderm intercalate radially and mediolaterally, separate from the rest of the mesoderm, establish the notochord/somite boundary and finally form blocks of 7-9 cells width (Danker et al, 1992). In those blocks, cells change shape, lengthen along their mediolateral axis and narrow along their anteroposterior axis (Wilson et al, 1989;Afonin et al, 2006). At the onset of somitogenesis, the presomitic cells bend anteriorly and undergo a 90°rotation relative to the anteroposterior axis of the embryo to form mono-nucleate muscle cells that are aligned parallel to the notochord (Keller, 2000).…”

Section: Introductionmentioning

confidence: 99%

In vivo analyzes of dystroglycan function during somitogenesis in Xenopus laevis

Hidalgo

Sirour

Bello

et al. 2008

Developmental Dynamics

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Dystroglycan (Dg) is a cell adhesion receptor for laminin that has been reported to play a role in skeletal muscle cell stability, cytoskeletal organization, cell polarity, and signaling. Here we show that Dg is expressed at both the notochord/somite and the intersomitic boundaries, where laminin and fibronectin are accumulated during somitogenesis. Inhibition of Dg function with morpholino antisense oligonucleotides or a dominant negative mutant results in the normal segmentation of the presomitic mesoderm but affects the number, the size, and the integrity of somites. Depletion of Dg disrupts proliferation and alignment of myoblasts without affecting XMyoD and XMRF4 expression. It also leads to defects in laminin deposition at the intersomitic junctions, whereas expression of integrin ␤1 subunits and fibronectin assembly occur normally. Our results show that Dg is critical for both proliferation and elongation of somitic cells and that the Dg-cytoplasmic domain is required for the laminin assembly at the intersomitic boundaries.

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“…In Xenopus embryos, two short, discrete fissures start from both the medial and lateral edges of the PSM and expand gradually towards the middle of the PSM to form a stable somite-PSM border (Afonin et al, 2006). In zebrafish embryos, cell rearrangements within forming somites are minimal and the forming-somite-PSM border develops when cells in the forming somite gently detach from their PSM neighbors, forming a medial notch which spreads laterally (Wood and Thorogood, 1994;Henry et al, 2000;Jiang et al, 2000).…”

Section: Introductionmentioning

confidence: 99%

Coordinated Action of N-CAM, N-cadherin, EphA4, and ephrinB2 Translates Genetic Prepatterns into Structure during Somitogenesis in Chick

Glazier¹,

Zhang²,

Swat³

et al. 2008

Current Topics in Developmental Biology

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During gastrulation in vertebrates, mesenchymal cells at the anterior end of the pre-somitic mesoderm (PSM) periodically compact, transiently epithelialize and detach from the posterior PSM to form somites. In the prevailing clock-and-wavefront model of somitogenesis, periodic gene expression, particularly of Notch and Wnt, interacts with an FGF8-based thresholding mechanism to determine cell fates. However, this model does not explain how cell determination and subsequent differentiation translates into somite morphology. In this paper, we use computer simulations of chick somitogenesis to show that experimentally-observed temporal and spatial patterns of adhesive N-CAM and N-cadherin and repulsive EphA4-ephrinB2 pairs suffice to reproduce the complex dynamic morphological changes of somitogenesis in wild-type and N-cadherin (−/−) chick, including intersomitic separation, boundary-shape evolution and sorting of misdifferentiated cells across compartment boundaries. Since different models of determination yield the same, experimentallyobserved, distribution of adhesion and repulsion molecules, the patterning is independent of the details of this mechanism.

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Cell behaviors associated with somite segmentation and rotation in Xenopus laevis

Cited by 42 publications

References 28 publications

From segment to somite: Segmentation to epithelialization analyzed within quantitative frameworks

From segment to somite: Segmentation to epithelialization analyzed within quantitative frameworks

In vivo analyzes of dystroglycan function during somitogenesis in Xenopus laevis

Coordinated Action of N-CAM, N-cadherin, EphA4, and ephrinB2 Translates Genetic Prepatterns into Structure during Somitogenesis in Chick

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