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This dataset describes phenotypic plasticity in sand dollars in response to predators at the Friday Harbor Laboratories, WA, USA and in sea urchins from Southern Maine, USA from 2018 to 2019.
This dataset represents data from Danielle Barnes’ honors thesis on phenotypic plasticity in juvenile sea urchins in response to predators. Larvae were cultured at the Friday Harbor Laboratories in Washington, USA under standard conditions for metamorphosis when they were measured using standard light microscopy.
For the first experiment, we studied the juvenile phenotypes of S. droebachiensis after they were exposed as larvae to waterborne cues from the European green crab (Carcinus maenas). Green crabs were selected as a cue source because they are a known predator of juvenile sea urchins (Fagerli et al., 2014). Two trials were conducted in the laboratory in Williamsburg, Virginia in the spring of 2018 and 2019 using two separate male-female pairs to account for differences in genotype and laboratory conditions.
Adult S. droebachiensis and green crabs were shipped overnight from the Marine Biological Laboratory at Woods Hole, MA in March of 2018 (Trial 1) and 2019 (Trial 2). Adult urchins were spawned using standard methods by injecting 1 milliliter (mL) of 0.5M KCl into the coelomic cavity (Strathmann, 1987). To collect eggs, female urchins were inverted over glass beakers filled with artificial seawater (ASW; Instant Ocean, Spectrum Brands, Blacksburg, VA) at a temperature of 12 degrees C and salinity of 32. Eggs collected from a single female were rinsed in ASW and immediately fertilized with dilute sperm collected from a single male. Each trial consisted of offspring from one male-female pair. Eggs were checked to ensure high (>90%) fertilization and then transferred into 1 L glass bowls filled with ASW, kept in aquaria at 12 degrees C, and manually stirred multiple times per day.
The S. droebachiensis embryos developed in these conditions until three days post fertilization when they had reached the gastrula stage. Swimming gastrulae were separated into ten, 250 mL glass beakers filled with 200 mL of ASW at a salinity of 32 and a density of 100 embryos per beaker. Beakers were kept in a 12 degrees C water bath and stirred by paddles connected to a 10-rpm motor in order to suspend the larvae and microalgal food (Strathmann, 1987). Beaker locations were rotated every other day in order to minimize potential effects of position in the water bath. Three times per week until settlement, 100 mL of culture water in each beaker was reverse filtered through a 35 micrometer (µm) mesh and replenished with 100 mL of ASW at a salinity of 32. After each water change, larvae were fed a mixed algal diet consisting of Dunaliella tertiolecta, Isochrysis galbana, and Rhodomonas lens at concentrations of 2,500 cells/mL for each species.
Each trial consisted of two treatments: 1) water borne cues from a benthic predator and 2) control with no cue. There were five replicate beakers per treatment (10 beakers total). Adult green crabs were used to generate the benthic predator cue. Upon arrival, crabs were separated into aerated individual 20 L tanks containing ASW at a salinity of 32 in a cold room maintained at 15ºC. Carapace lengths of the crabs ranged from 51 mm to 59 mm (Trial 1) and 46 mm to 59 mm (Trial 2), and the wet weight of the crabs was estimated to range from 30.3 g to 46.3 g (Trial 1) and 22.4 g to 46.3 g (Trial 2; estimated using the following conversion: wet weight (g) = 0.26 (carapace width (cm))2.92 R2= 0.99 from Menge, 1983). Crabs were fed a diet of frozen shrimp every two days except for the window where they were used to create predator cue water. Every two days, one of the crabs was randomly chosen to generate the predator cue water. To generate water with water born cues, an individual crab was housed in an aerated tank filled with 6 L of ASW for 24 hours. The cue water was then filtered through a 5 µm bag filter in order to remove any particulate waste and larger microorganisms. The water for the control treatment was collected from a replicate tank with 6 L of ASW without crabs. The pH, dissolved oxygen, temperature, and salinity of the predator cue and control water were monitored using a YSI Pro 1030 conductivity, pH, and temperature probe (Yellow Springs Instrument, Yellow Springs, OH).
The predator cue water was introduced to each of the beakers beginning when the development of spines as part of the juvenile rudiment were first observed using polarized light under a compound microscope. During water changes, after 100 mL of the original culture water was filtered out, 100 mL of the predator cue water was added in place of the ASW. Predator cues were added to the beakers in the same manner for each subsequent water change (i.e. every other day) until all urchins had settled. Larval settlement was induced by adding a blue mussel shell (Mytilus edulis) to each beaker beginning at 28 days post fertilization (Pearce and Scheibling, 1990).
Upon metamorphosis, urchin juveniles were removed from each beaker and morphological measurements were taken at 100x magnification using a compound microscope fitted with an ocular micrometer. Mean spine length was calculated by averaging the length of each juvenile’s three longest spines. The total number of spines was also counted. Disk area was determined by measuring the length of the body at the longest axis and then the width of the body at its widest point perpendicular to the length. These two measures were then used to calculate the area of an ellipse as a proxy for sea urchin disk area.
Pacific Sand Dollars
For the second experiment, we studied the juvenile phenotypes of Pacific sand dollars (Dendraster excentricus) after they were exposed as larvae to waterborne cues from the red rock crab (Cancer productus). C. productus are commonly used in experiments as predators of larval D. excentricus (Rumrill et al., 1985; Pennington et al., 1986; Allen, 2008), in addition to being frequently associated with sand dollar beds and being observed feeding on adult sand dollars in the field (Merrill and Hobson, 1970). Two trials were conducted at the University of Washington's Friday Harbor Laboratories (FHL) on San Juan Island, Washington in the summer of 2019. For each trial a unique male-female pair was used to account for differences in genotypes and laboratory conditions.
Adult Dendraster excentricus were collected from a large sand dollar bed in East Sound, Orcas Island, WA (48o 41' 40'' N 122o 53’ 45" W) in June, 2019. Sand dollars were transported to FHL where they were housed in tanks connected to a flow-through sea water system. The sand dollars were spawned using standard methods (Strathmann, 1987) by injecting 1 milliliter (mL) of 0.53M KCl into the coelomic cavity. To collect the eggs, female sand dollars were inverted over 50 mL glass beakers filled with 1-micron filtered sea water (FSW) at a salinity of 32. Eggs collected from a single female were rinsed in FSW and immediately fertilized with dilute sperm collected from a single male. Eggs were checked to ensure high (> 90%) fertilization and then transferred into 1 liter (L) glass bowls filled with FSW and kept in a flow-through sea water table at ambient temperature (range approximately 12ºC – 14ºC), and manually stirred multiple times per day.
Two days post fertilization, when embryos had developed into the prism larval stage, larvae were sorted into twenty replicate 250 milliliter (mL) glass beakers containing 200 milliliter (mL) of FSW at a salinity of 33 with 100 larvae per beaker. Beakers were kept in a flow-through sea table at ambient temperature (range 12ºC – 14ºC). The beakers were stirred by paddles connected to a 10-rpm motor in order to suspend the larvae and microalgal food (Strathmann, 1987). Beaker locations were rotated every other day in order to minimize potential effects of position in the water bath. Every other day until settlement, 100 milliliter (mL) of culture water in each beaker was reverse filtered through a 35 µm mesh and replenished with 100 mL of FSW. After water changes, larvae were fed a mixed algal diet consisting of Dunaliella tertiolecta, Isochrysis galbana, and Rhodomonas lens at concentrations of 2,500 cells/mL for each species.
The first trial consisted of two treatments: benthic predator cue, and a control without cue. There were 10 replicate beakers per treatment (20 beakers total). Adult red rock crabs (C. productus) were used to create the benthic predator cue. Red rock crabs were collected intertidally from the intertidal shoreline in front of Friday Harbor Laboratories in July of 2019 and housed in flow-through sea water tanks at ambient salinity and temperature. The crabs’ carapace lengths ranged from 53 mm to 61 mm and their masses ranged from 16.8 grams to 23.6 grams. To generate water with a predator cue, a single crab was housed in a closed jar filled with 3 L of FSW for 24 hours. The crab was then removed and the water was filtered through a 5 µm bag filter, re-oxygenated by vigorously shaking for one minute, and diluted with an additional 3 L of FSW. Every other day, a different crab was used to produce the predator cue. The control water came from a jar in the same conditions without a crab. The pH, dissolved oxygen, temperature, and salinity of the predator cue and control water were monitored as done for the green urchin experiment.
The second trial consisted of three treatments: benthic predator cue, planktonic predator cue, and a control. There were 20 total beakers, with seven replicate beakers in the benthic predator cue treatment, seven in the planktonic predator cue treatment, and six in the control. The same population of red rock crabs used in the first trial were used to create the benthic predator cue. To create the planktonic predator cue, Cancer productus megalopae were collected from the waters off the dock at Friday Harbor Laboratories. The average mass of an individual megalopa was determined to be 0.019 g, which was used to calculate the number of megalopae needed for a given cue batch, such that the total mass of all megalopae combined was equivalent to the mass of the adult crab used in the corresponding benthic predator cue batch (~150-200 megalopae per 1 L of FSW). The control water came from a jar in the same conditions.
Benthic predator cue water, planktonic predator cue water, or control water was added to the beakers at 14 days post fertilization, when the sand dollar larvae had developed spines on the juvenile rudiment that could be observed with polarized light. 100 mL of predator cue water or control water was added after the culture water was filtered. Predator cues were added to the culture beakers in each subsequent water change until all larvae had settled. Settlement was induced starting at 18 days post fertilization by adding into each beaker approximately 0.2 g of sand from the flow-through sand dollar tanks at Friday Harbor Laboratories that had been conditioned by adult sand dollars for over a year (Highsmith, 1982).
On the day each juvenile metamorphosed, they were removed from the beaker and morphological measurements were taken at 100x magnification using a compound microscope. Mean spine length was calculated by averaging each juvenile’s three longest spines. The total number of spines was also counted. Disk area was determined by measuring the length of the body at the longest axis and then the width of the body at its widest point perpendicular to the length under a compound microscope at 100x magnification. These two measures were then used to calculate the area of an ellipse as a proxy for sand dollar disk area.
Barnes, D., Allen, J. (2022) Phenotypic plasticity in sand dollars in response to predators at the Friday Harbor Laboratories, WA, USA and in sea urchins from Southern Maine, USA from 2018 to 2019. Biological and Chemical Oceanography Data Management Office (BCO-DMO). (Version 1) Version Date 2022-12-02 [if applicable, indicate subset used]. doi:10.26008/1912/bco-dmo.877780.1 [access date]
Terms of Use
This dataset is licensed under Creative Commons Attribution 4.0.
If you wish to use this dataset, it is highly recommended that you contact the original principal investigators (PI). Should the relevant PI be unavailable, please contact BCO-DMO (info@bco-dmo.org) for additional guidance. For general guidance please see the BCO-DMO Terms of Use document.