Muscle specification in theXenopus laevis gastrula-stage embryo

Temporal and spatial patterning of axial myotome fibers in Xenopus laevis

Somites give rise to the vertebral column and segmented musculature of adult vertebrates. The cell movements that position cells within somites along the anteroposterior and dorsoventral axes are not well understood. Using a fate mapping approach, we show that at the onset of Xenopus laevis gastrulation, mesoderm cells undergo distinct cell movements to form myotome fibers positioned in discrete locations within somites and along the anteroposterior axis. We show that the distribution of presomitic cells along the anteroposterior axis is influenced by convergent and extension movements of the notochord. Heterochronic and heterotopic transplantations between presomitic gastrula and early tail bud stages show that these cells are interchangeable and can form myotome fibers in locations determined by the host embryo. However, additional transplantation experiments revealed differences in the competency of presomitic cells to form myotome fibers, suggesting that maturation within the tail bud presomitic mesoderm is required for myotome fiber differentiation.

Embryonic cells depleted of beta-catenin remain competent to differentiate into dorsal mesodermal derivatives

Disruption of axis specification leads to defects in dorsal tissue patterning and cell movements. Here, we examine how beta-catenin coordinately affects gastrulation movements and dorsal mesoderm differentiation. The reduction of beta-catenin protein levels by morpholino oligonucleotides complementary to beta-catenin mRNA causes a disruption in gastrulation movements. Time-lapse imaging of beta-catenin morphants during gastrulation reveals that involution occurs simultaneously around the blastopore in the absence of convergent extension cell movements. Transplantation experiments show that morphant cells grafted from the marginal zone into wild-type hosts differentiate into notochord and muscle. However, wild-type mesoderm cells grafted to the marginal zone of beta-catenin morphants do not form dorsal tissues. These data argue that beta-catenin is not required for the initial establishment of dorsal mesoderm cell competency, but it is required for the maintenance of that competency. We propose that tissue interactions that occur during convergent extension movements are necessary for maintaining dorsal tissue competency.