During embryogenesis, Drosophila embryos undergo epithelial folding and unfolding, which leads to a hole in the dorsal epidermis, transiently covered by an extraembryonic tissue called the amnioserosa. Dorsal Closure (DC) consists of the migration of lateral epidermis towards the midline, covering the amnioserosa. It has been extensively studied since numerous physical mechanisms and signaling pathways present in DC are conserved in other morphogenetic events and wound healing in many other species (including vertebrates). We present here a simple mathematical model for DC that involves a reduced number of parameters directly linked to the intensity of the forces in presence and which is applicable to a wide range of geometries of the Leading Edge (LE). This model is a natural generalization of the very interesting model proposed in Hutson et Al., Science, 2003. Being based on an Ordinary Differential Equation (ODE) approach, the previous model had the advantage of being even simpler, but this restricted significantly the variety of geometries that could be considered and thus the number of modified dorsal closures that could be studied. Making the transition to a Partial Differential Equation (PDE) approach, as we do here, allows considering much more general situations that show up in genetically or physically perturbed embryos and whose study will be essential for a proper understanding of the different components of the DC process. Even for native embryos, our model has the advantage of being applicable since the early stages of DC when there is no antero-posterior symmetry (approximately verified only in the late phases of DC). We validate our model in a native setting and also test it further by obtaining variations of the force coefficients that are consistent with what was previously described for embryos where the zipping force is perturbed through the expression of Spastin (a microtubule severing protein). We obtain variations of the force coefficients that are consistent with what was previously described for this setting.
A Mathematical Model for Dorsal Closure
BAGNERINI, PATRIZIA;
2011-01-01
Abstract
During embryogenesis, Drosophila embryos undergo epithelial folding and unfolding, which leads to a hole in the dorsal epidermis, transiently covered by an extraembryonic tissue called the amnioserosa. Dorsal Closure (DC) consists of the migration of lateral epidermis towards the midline, covering the amnioserosa. It has been extensively studied since numerous physical mechanisms and signaling pathways present in DC are conserved in other morphogenetic events and wound healing in many other species (including vertebrates). We present here a simple mathematical model for DC that involves a reduced number of parameters directly linked to the intensity of the forces in presence and which is applicable to a wide range of geometries of the Leading Edge (LE). This model is a natural generalization of the very interesting model proposed in Hutson et Al., Science, 2003. Being based on an Ordinary Differential Equation (ODE) approach, the previous model had the advantage of being even simpler, but this restricted significantly the variety of geometries that could be considered and thus the number of modified dorsal closures that could be studied. Making the transition to a Partial Differential Equation (PDE) approach, as we do here, allows considering much more general situations that show up in genetically or physically perturbed embryos and whose study will be essential for a proper understanding of the different components of the DC process. Even for native embryos, our model has the advantage of being applicable since the early stages of DC when there is no antero-posterior symmetry (approximately verified only in the late phases of DC). We validate our model in a native setting and also test it further by obtaining variations of the force coefficients that are consistent with what was previously described for embryos where the zipping force is perturbed through the expression of Spastin (a microtubule severing protein). We obtain variations of the force coefficients that are consistent with what was previously described for this setting.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.