@article{8966, abstract = {During development, a single cell is transformed into a highly complex organism through progressive cell division, specification and rearrangement. An important prerequisite for the emergence of patterns within the developing organism is to establish asymmetries at various scales, ranging from individual cells to the entire embryo, eventually giving rise to the different body structures. This becomes especially apparent during gastrulation, when the earliest major lineage restriction events lead to the formation of the different germ layers. Traditionally, the unfolding of the developmental program from symmetry breaking to germ layer formation has been studied by dissecting the contributions of different signaling pathways and cellular rearrangements in the in vivo context of intact embryos. Recent efforts, using the intrinsic capacity of embryonic stem cells to self-assemble and generate embryo-like structures de novo, have opened new avenues for understanding the many ways by which an embryo can be built and the influence of extrinsic factors therein. Here, we discuss and compare divergent and conserved strategies leading to germ layer formation in embryos as compared to in vitro systems, their upstream molecular cascades and the role of extrinsic factors in this process.}, author = {Schauer, Alexandra and Heisenberg, Carl-Philipp J}, issn = {0012-1606}, journal = {Developmental Biology}, keywords = {Developmental Biology, Cell Biology, Molecular Biology}, pages = {71--81}, publisher = {Elsevier}, title = {{Reassembling gastrulation}}, doi = {10.1016/j.ydbio.2020.12.014}, volume = {474}, year = {2021}, } @article{7545, abstract = {Neuronal activity often leads to alterations in gene expression and cellular architecture. The nematode Caenorhabditis elegans, owing to its compact translucent nervous system, is a powerful system in which to study conserved aspects of the development and plasticity of neuronal morphology. Here we focus on one pair of sensory neurons, termed URX, which the worm uses to sense and avoid high levels of environmental oxygen. Previous studies have reported that the URX neuron pair has variable branched endings at its dendritic sensory tip. By controlling oxygen levels and analyzing mutants, we found that these microtubule-rich branched endings grow over time as a consequence of neuronal activity in adulthood. We also find that the growth of these branches correlates with an increase in cellular sensitivity to particular ranges of oxygen that is observable in the behavior of older worms. Given the strengths of C. elegans as a model organism, URX may serve as a potent system for uncovering genes and mechanisms involved in activity-dependent morphological changes in neurons and possible adaptive changes in the aging nervous system.}, author = {Cohn, Jesse A. and Cebul, Elizabeth R. and Valperga, Giulio and Brose, Lotti and de Bono, Mario and Heiman, Maxwell G. and Pierce, Jonathan T.}, issn = {0012-1606}, journal = {Developmental Biology}, number = {1}, pages = {66--74}, publisher = {Elsevier}, title = {{Long-term activity drives dendritic branch elaboration of a C. elegans sensory neuron}}, doi = {10.1016/j.ydbio.2020.01.005}, volume = {461}, year = {2020}, }