A novel running wheel apparatus to monitor locomotor rhythms in land crabs |
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Authors: | M. Zachary Darnell Matthew B. Ogburn Humberto Diaz |
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Affiliation: | 1. Duke University Marine Laboratory, Nicholas School of the Environment , Beaufort, NC, USA mzd2@duke.edu;3. Duke University Marine Laboratory, Nicholas School of the Environment , Beaufort, NC, USA |
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Abstract: | The spatial distribution of cephalopods is influenced by salinity and temperature. In marine osmoconformers, one reason for different spatial distributions maybe the putative distinct capacity to regulate tissue hydration. Adult Octopus vulgaris (n?=?6) and O. insularis (n?=?6) were obtained by divers from sites along the southern and northeastern Brazilian coasts, respectively. In the laboratory, octopuses were acclimated to full-strength seawater (salinity 34), for 5–10 days. They were then anesthetized (10 min in 4 °C seawater), a portion of the second right arm was removed, and cut into three portions. Tissues were placed in control isosmotic saline (osmolality 1072 mOsm/kg H2O). Fragments were weighed and transferred to either isosmotic, hyposmotic (50%), or hyperosmotic (150%) salines, and their weight was observed for 120 min. Tissue from both species maintained their hydration/weight following the hyposmotic shock, but differed in their response to the hyperosmotic challenge, where hydration remained unchanged in O. insularis, but was significantly reduced in O. vulgaris. This result could partially explain why O. insularis is more abundant than O. vulgaris throughout the shallow reefs and tide pools in the warmer and salty tropical waters of the northeastern Brazilian coast. |
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Keywords: | Octopus Octopus vulgaris Octopus insularis salinity tissue hydration in vitro distribution |
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