Variation in Symbiodinium ITS2 sequence assemblages among coral colonies.

Endosymbiotic dinoflagellates in the genus Symbiodinium are fundamentally important to the biology of scleractinian corals, as well as to a variety of other marine organisms. The genus Symbiodinium is genetically and functionally diverse and the taxonomic nature of the union between Symbiodinium and corals is implicated as a key trait determining the environmental tolerance of the symbiosis. Surprisingly, the question of how Symbiodinium diversity partitions within a species across spatial scales of meters to kilometers has received little attention, but is important to understanding the intrinsic biological scope of a given coral population and adaptations to the local environment. Here we address this gap by describing the Symbiodinium ITS2 sequence assemblages recovered from colonies of the reef building coral Montipora capitata sampled across Kane'ohe Bay, Hawai'i. A total of 52 corals were sampled in a nested design of Coral Colony(Site(Region)) reflecting spatial scales of meters to kilometers. A diversity of Symbiodinium ITS2 sequences was recovered with the majority of variance partitioning at the level of the Coral Colony. To confirm this result, the Symbiodinium ITS2 sequence diversity in six M. capitata colonies were analyzed in much greater depth with 35 to 55 clones per colony. The ITS2 sequences and quantitative composition recovered from these colonies varied significantly, indicating that each coral hosted a different assemblage of Symbiodinium. The diversity of Symbiodinium ITS2 sequence assemblages retrieved from individual colonies of M. capitata here highlights the problems inherent in interpreting multi-copy and intra-genomically variable molecular markers, and serves as a context for discussing the utility and biological relevance of assigning species names based on Symbiodinium ITS2 genotyping.

Gene expression changes accompanying p53 activity during estrogen treatment of osteoblasts.

Estrogen is known to be anabolic for bone and we have used estrogen treatment as a paradigm to understand how p53 may affect osteoblast differentiation. In previous studies we have shown estrogen treatment to increase p53 functional activity in osteoblasts. Estrogen has been suggested to inhibit apoptosis in osteoblasts. Since the significance of a p53 increase during estrogen treatment is not apparent, we investigated the environment within osteoblasts after treatment with estrogen. We observed two peaks of p53 activity during continuous treatment of 17-[beta]-estradiol (E2) for 72h. The gene expression profile of different cell cycle regulators and apoptosis related genes at different times during treatment with 17-[beta]-estradiol were tested using gene arrays. There was an early increase in expression of several genes involved in apoptosis. This was followed by changes in expression of several genes involved in cell survival and stress response. The second peak of activity was associated with increase in expression of cell cycle regulators. Our results suggest that p53 activity may be a result of activation of several signaling pathways involving apoptosis, cell survival and cell cycle arrest. P53 may have a role in integrating these responses, which eventually results in cell cycle arrest and expression of differentiation markers.