5 research outputs found
Exposure to Ultraviolet Radiation Causes Proteomic Changes in Embryos of the Purple Sea Urchin, \u3cem\u3eStrongylocentrotus purpuratus\u3c/em\u3e
We performed experiments to determine how environmentally relevant ultraviolet radiation (UVR) affects protein expression during early development in the sea urchin, Strongylocentrotus purpuratus. To model the protein-mediated cell cycle response to UV-irradiation, six batches of embryos were exposed to UVR, monitored for both delays in the first mitotic division and changes in the proteome at two specific developmental time points. Embryos were exposed to or protected from artificial UVR (11.5 W/m2) for 25 or 60 min. These levels of UVR are within the range we have measured in coastal waters between 0.5 and 2 m. Embryos treated with UVR for 60 min cleaved an average of 23.2 min (±1.92 s.e.m.) after UV-protected embryos. Differential protein spot migration between UV-protected and UV-treated embryos was examined at 30 and 90 min post-fertilization using two-dimensional SDS-PAGE (2D GE). A total of 1306 protein spots were detected in all gels, including differences in 171 protein spots (13% of the detected proteome) in UV-treated embryos at 30 min post-fertilization and 187 spots (14%) at 90 min post-fertilization (2-way ANOVA, P=0.03, n =6). The majority of the proteins affected by UVR were subsequently identified using matrix assisted laser desorption ionization tandem time-of-flight mass spectrometry (MALDI-TOF–TOF MS). Our results indicate UVR affects proteins from multiple cellular pathways and indicate that the mechanisms involved in UV-stress and UV-induced developmental delay in sea urchin embryos are integrated among multiple pathways for cellular stress, protein turnover and translation, signal transduction, cytoskeletal dynamics, and general metabolism
Recommended from our members
Coordination of protrusion dynamics within and between collectively migrating border cells by myosin II.
Collective cell migration is emerging as a major driver of embryonic development, organogenesis, tissue homeostasis, and tumor dissemination. In contrast to individually migrating cells, collectively migrating cells maintain cell-cell adhesions and coordinate direction-sensing as they move. While nonmuscle myosin II has been studied extensively in the context of cells migrating individually in vitro, its roles in cells migrating collectively in three-dimensional, native environments are not fully understood. Here we use genetics, Airyscan microscopy, live imaging, optogenetics, and Förster resonance energy transfer to probe the localization, dynamics, and functions of myosin II in migrating border cells of the Drosophila ovary. We find that myosin accumulates transiently at the base of protrusions, where it functions to retract them. E-cadherin and myosin colocalize at border cell-border cell contacts and cooperate to transmit directional information. A phosphomimetic form of myosin is sufficient to convert border cells to a round morphology and blebbing migration mode. Together these studies demonstrate that distinct and dynamic pools of myosin II regulate protrusion dynamics within and between collectively migrating cells and suggest a new model for the role of protrusions in collective direction sensing in vivo
Recommended from our members
Transport in technicolor: mapping ATP-binding cassette transporters in sea urchin embryos.
One quarter of eukaryotic genes encode membrane proteins. These include nearly 1,000 transporters that translocate nutrients, signaling molecules, and xenobiotics across membranes. While it is well appreciated that membrane transport is critical for development, the specific roles of many transporters have remained cryptic, in part because of their abundance and the diversity of their substrates. Multidrug resistance ATP-binding cassette (ABC) efflux transporters are one example of cryptic membrane proteins. Although most organisms utilize these ABC transporters during embryonic development, many of these transporters have broad substrate specificity, and their developmental functions remain incompletely understood. Here, we review advances in our understanding of ABC transporters in sea urchin embryos, and methods developed to spatially and temporally map these proteins. These studies reveal that multifunctional transporters are required for signaling, homeostasis, and protection of the embryo, and shed light on how they are integrated into ancestral developmental pathways recapitulated in disease