Differential Growth Biology at Timothy Mears blog

Differential Growth Biology. morphogenesis by differential growth. After their initiation, the various organs and regions of an organism may increase in. by changing only the planar differential growth rates in silico, we successfully predict overgrowth clone and wingless mutant morphologies in vivo. when x and y are body and organ sizes at different developmental stages, the allometric coefficient captures the. differential growth between cells in initiating organ primordia and the surrounding boundary cells leads to the emergence (i.e., evagination) of a rounded primordium. Show that different growth dynamics determine the shape of plant aerial organs, leaf and floral primordia, which. Phyllotaxis) that is dictated by the plant species and organ type. by means of computational simulations and quantitative analyses of the growth strains in live plant organs, we. With our computational analysis, we propose a mechanism whereby planar differential growth rates define epithelial fold initiation positions. Organ primordia emerge from the meristem in a stereotypic pattern (a.k.a.

by means of computational simulations and quantitative analyses of the growth strains in live plant organs, we. Organ primordia emerge from the meristem in a stereotypic pattern (a.k.a. when x and y are body and organ sizes at different developmental stages, the allometric coefficient captures the. differential growth between cells in initiating organ primordia and the surrounding boundary cells leads to the emergence (i.e., evagination) of a rounded primordium. With our computational analysis, we propose a mechanism whereby planar differential growth rates define epithelial fold initiation positions. Phyllotaxis) that is dictated by the plant species and organ type. by changing only the planar differential growth rates in silico, we successfully predict overgrowth clone and wingless mutant morphologies in vivo. morphogenesis by differential growth. After their initiation, the various organs and regions of an organism may increase in. Show that different growth dynamics determine the shape of plant aerial organs, leaf and floral primordia, which.

Differential cell growth at the embryo RSI produces anisotropic

Differential Growth Biology by means of computational simulations and quantitative analyses of the growth strains in live plant organs, we. Organ primordia emerge from the meristem in a stereotypic pattern (a.k.a. differential growth between cells in initiating organ primordia and the surrounding boundary cells leads to the emergence (i.e., evagination) of a rounded primordium. by means of computational simulations and quantitative analyses of the growth strains in live plant organs, we. morphogenesis by differential growth. by changing only the planar differential growth rates in silico, we successfully predict overgrowth clone and wingless mutant morphologies in vivo. when x and y are body and organ sizes at different developmental stages, the allometric coefficient captures the. Phyllotaxis) that is dictated by the plant species and organ type. After their initiation, the various organs and regions of an organism may increase in. With our computational analysis, we propose a mechanism whereby planar differential growth rates define epithelial fold initiation positions. Show that different growth dynamics determine the shape of plant aerial organs, leaf and floral primordia, which.