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Finding responses within fat account inside COVID-19 individuals.
The neural tube in amniotic embryos forms as a result of two consecutive events along the anteroposterior axis, referred to as primary and secondary neurulation (PN and SN). While PN involves the invagination of a sheet of epithelial cells, SN shapes the caudal neural tube through the mesenchymal-to-epithelial transition (MET) of neuromesodermal progenitors, followed by cavitation of the medullary cord. The technical difficulties in studying SN mainly involve the challenge of labeling and manipulating SN cells in vivo. Here we describe a new method to follow MET during SN in the chick embryo, combining early in ovo chick electroporation with in vivo time-lapse imaging. This procedure allows the cells undergoing SN to be manipulated in order to investigate the MET process, permitting their cell dynamics to be followed in vivo.Avian (chick) embryos are an established and accessible model organism making them ideal for studying developmental processes. Chick embryos can be harvested from the egg and cultured allowing real-time observations and imaging. Here, we describe ex vivo culture and preparation of somite tissue followed by time-lapse multi-photon microscopy, image capture and processing. We applied this approach to perform live imaging of somites, the paired segments in vertebrate embryos that form in a regular sequence on either side of the neural tube, posteriorly from presomitic mesoderm (psm). #link# Somites give rise to cell lineages of the musculoskeletal system in the trunk such as skeletal muscle, cartilage and tendon, as well as endothelial cells. Until recently it was not possible to observe the cellular dynamics underlying morphological transitions in live tissue, including in somites which undergo epithelial-to-mesenchymal transitions (EMT) during their differentiation. In addition to the experimental setup, we describe the analytical tools used for image processing.Metastasis underlies the majority of cancer-related deaths. Until recently, research on this complex multi-step process has been hindered by a lack of genetically tractable experimental models amenable to high-throughput analyses. This was recently overcome with the development of a model of metastatic colorectal cancer (CRC) in adult flies, which relies on the activation of a partial-epithelial-to-mesenchymal transition (EMT) in intestinal tumors. In this model, tumor cells are labeled with both GFP and luciferase reporters, enabling high-throughput analyses. We report here the detailed protocol for generating the model, and assaying for primary tumor burden and distinct stages of metastasis, including the number of circulating tumor cells and secondary metastases.The epithelial-to-mesenchymal transition is a highly dynamic cell process and tools such as fluorescence recovery after photobleaching (FRAP), which allow the study of rapid protein dynamics, enable the following of this process in vivo. This technique uses a short intense pulse of photons to disrupt the fluorescence of a tagged protein in a region of a sample. The fluorescent signal intensity after this bleaching is then recorded and the signal recovery used to provide an indicator of the dynamics of the protein of interest. This technique can be applied to any fluorescently tagged protein, but membrane-bound proteins present an interesting challenge as they are spatially confined and subject to specialized cellular trafficking. Several methods of analysis can be applied which can disentangle these various processes and enable the extraction of information from the recovery curves. Here we describe this technique when applied to the quantification of the plasma membrane-bound E-cadherin protein in vivo using the epidermis of the late embryo of Drosophila melanogaster (Drosophila) as an example of this technique.Epithelial-mesenchymal transition (EMT) is often studied in pathological contexts, such as cancer or fibrosis. This chapter focuses on physiological EMT that allows the separation of germ layers during mouse embryo gastrulation. In order to record individual cells behavior with high spatial and temporal resolution live imaging as they undergo EMT, it is very helpful to label the cells of interest in a mosaic fashion so as to facilitate cell segmentation and quantitative image analysis. This protocol describes the isolation, culture, and live imaging of E6.5-E7.5 mouse embryos mosaically labeled in the epiblast, the epithelium from which mesoderm and endoderm layers arise through EMT at gastrulation.In the early stages of Drosophila melanogaster (Drosophila) metamorphosis, a partial epithelial-mesenchymal transition (pEMT) takes place in the peripodial epithelium of wing imaginal discs. Blocking this pEMT results in adults with internalized wings and missing thoracic tissue. Using peripodial GAL4 drivers, GAL80ts temporal control, and UAS RNAi transgenes, one can use these phenotypes to screen for genes involved in the pEMT. Dominant modifier tests can then be employed to identify genetic enhancers and suppressors. To analyze ML210 in the pEMT, one can then visualize peripodial cells in vivo at the time of eversion within the pupal case using live markers, and by dissecting, fixing, and immunostaining the prepupae. Alternatively, one can analyze the pEMT ex vivo by dissecting out wing discs and culturing them in the presence of ecdysone to induce eversion. This can provide a clearer view of the cellular processes involved and permit drug treatments to be easily applied.Live embryo imaging may provide a wealth of information on intact cell and tissue dynamics, but can be technically challenging to sustain embryo orientation and health for long periods under a microscope. In this protocol, we describe an in vivo method to mount and image cell movements during the epithelial-to-mesenchymal transition (EMT) of neural crest cells within the chick dorsal neural tube. We focus on describing the collection of images and data preparation for image analysis throughout the developmental stages HH15-21 in the chick trunk. Trunk neural crest cell EMT is crucial to development of the peripheral nervous system and pigment cell patterning. The methods we describe may also be applied to other cell and tissue phenomena at various chick developmental stages with some modifications.
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