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Coral larvae are produced in a variety of different sizes and symbiont densities, and their survival is dependent on the specific environment they’re in. | Coral larvae are produced in a variety of different sizes and symbiont densities, and their survival is dependent on the specific environment they’re in. | ||
Coral larvae with high symbiont densities were 5x less likely to resist heat stress compared to those of low densities. | Coral larvae with high symbiont densities were 5x less likely to resist heat stress compared to those of low densities. | ||
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Kim Stone is a curator of fish and invertebrates at the GA Aquarium, which is less than a 20 minute walk from GSU. We had an incredible talk with her, and she walked us through some of the basics of coral husbandry. We may even partner with the GA aquarium in the future when we’re ready to test our modified algae in a closed coral reef system. | Kim Stone is a curator of fish and invertebrates at the GA Aquarium, which is less than a 20 minute walk from GSU. We had an incredible talk with her, and she walked us through some of the basics of coral husbandry. We may even partner with the GA aquarium in the future when we’re ready to test our modified algae in a closed coral reef system. | ||
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Algae uptake | Algae uptake | ||
Once our algae have been successfully engineered to resist the stressors that cause bleaching, we will need the coral to uptake them. We thought of several ways of doing this. One way involved dumping a large concentration of our algae into a sea region where a large but stressed coral reef is found. Another possibility was to inject the algae into the coral with a syringe-like tool. After speaking with Kim Stone at the GA Aquarium, we came up with a much more practical solution. We may partner with the GA Aquarium in the future when they can provide us with tank systems that can be regulated with respect to temperature, light intensity, and water flow. We plan on setting up two tanks of seawater. We’ll begin by placing a Caulastraea coral into the first tank. After inducing bleaching by gradually bringing the temperature up 2°F every other day until about 86 °F is reached, we will transfer the organism into a fresh tank. To prevent the coral from going into shock, this fresh tank will start at 86 °F, and its temperature will eventually be brought down to about 72 °F. We will then introduce our algae of varying concentrations and monitor the coral for uptake. If the coral uptakes, we will later observe its offspring and note if the modified symbionts were passed down from the mother. | Once our algae have been successfully engineered to resist the stressors that cause bleaching, we will need the coral to uptake them. We thought of several ways of doing this. One way involved dumping a large concentration of our algae into a sea region where a large but stressed coral reef is found. Another possibility was to inject the algae into the coral with a syringe-like tool. After speaking with Kim Stone at the GA Aquarium, we came up with a much more practical solution. We may partner with the GA Aquarium in the future when they can provide us with tank systems that can be regulated with respect to temperature, light intensity, and water flow. We plan on setting up two tanks of seawater. We’ll begin by placing a Caulastraea coral into the first tank. After inducing bleaching by gradually bringing the temperature up 2°F every other day until about 86 °F is reached, we will transfer the organism into a fresh tank. To prevent the coral from going into shock, this fresh tank will start at 86 °F, and its temperature will eventually be brought down to about 72 °F. We will then introduce our algae of varying concentrations and monitor the coral for uptake. If the coral uptakes, we will later observe its offspring and note if the modified symbionts were passed down from the mother. | ||
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Dr. Joyner is a marine biology professor at our school, GA State University. After learning about the general mechanisms of bleaching from Alanna, we asked Dr. Joyner more specific questions about our project. For example, what factors contribute to the uptake of algae? Additionally, what model organisms would work best for testing the uptake of our modified algae by the coral? | Dr. Joyner is a marine biology professor at our school, GA State University. After learning about the general mechanisms of bleaching from Alanna, we asked Dr. Joyner more specific questions about our project. For example, what factors contribute to the uptake of algae? Additionally, what model organisms would work best for testing the uptake of our modified algae by the coral? | ||
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Aptasia is a good model organism for uptaking algae because both the larval and adult forms of this organism are easy to culture in the lab. | Aptasia is a good model organism for uptaking algae because both the larval and adult forms of this organism are easy to culture in the lab. | ||
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Revision as of 04:48, 20 October 2019
Our Experts
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Alanna Waldman
Marine Biologist
Kim Stone
Curator
Dr. Jessica Joyner
Professor
Alanna Waldman
Coral Reef Restoration, Assessment & Monitoring Lab,
Nova Southeastern University
Why we approached her: Alanna is a marine biologist at Nova Southeastern University. Because Alanna is currently working in the field as a research assistant in a Coral Reef Restoration Assessment and Monitoring Lab, we thought she’d be a great person to teach us the basics of coral bleaching
What we asked her about: Why and how coral bleaching occurs, mechanisms of recovery, and the symbiotic relationship between corals and algae.
What we learned: We now understand that the potential causes of coral bleaching remain a mystery, but some likely factors include: extreme temp., high irradiance, prolonged darkness, heavy metal pollution, and pathogenic microorganisms. When the bleaching-inducing stressors disappear, recovery is still not guaranteed. Coral bleaching minimizes the number of fish in the surrounding area. Without fish that consume macroalgae, the already strained corals can be overpowered. On top of this, the gaps between bleaching events are about half as long as they used to be. This isn’t enough time for the corals to fully recover. Alanna also informed us that certain proteins produced by the algal symbionts have been associated with an increased resistance to bleaching. These include: fluorescent proteins, heat shock proteins, and antioxidant enzymes. After learning from Alanna that bleaching is less likely in corals with high algae diversity, we decided to make several different modifications to our symbiodinium rather than just one. We plan on introducing genes that encode fluorescent and heat shock proteins in one alga and antioxidant genes into another. Additionally, we will transform other algae to express a combination of these proteins at varying levels.
Kim Stone
Curator of Fish and Invertebrates, Georgia Aquarium
Why we approached her: Kim Stone studies corals at the GA Aquarium, which is only a 20 minute walk from GSU. She’s an expert on coral husbandry and conducts her own sustainability research on these organisms.
What we asked her about: We wanted to learn more about how to care for corals in a lab setting along with how to introduce our modified symbiodinium into them.
What we learned: We had an incredible talk with Kim Stone that ended with a potential partnership in the future. We didn’t realize before this talk that getting the coral to uptake the algae would be a grand project by itself. We thought that we would either dump our modified symbiodinium into a region of coral reef or directly inject the algae into the corals using a syringe-like tool. Stone proposed a much more practical and efficient method. She offered us a system of tanks that can be temperature and light-intensity regulated. We now plan on using these tanks to test a variety of approaches to prompt the coral uptake of our modified algae. We’ll have to start by deliberately bleaching the corals of their existing algae then transfer them to a new tank filled with our transformed symbiodinium. Kim Stone also recommended that we move away from the Aptasia model and shift instead towards a large and stony coral such as Caulastraea furcata. Compared to small soft corals, large stony ones are easier to culture, and early signs of bleaching are not as difficult to detect. Although Aptasia offers these benefits, Caulastraea furcata will be a much better representation of coral species as a whole due to its phylogeny.
Dr. Jessica Joyner
Professor of Biology,
Georgia State University
Why we approached her: Dr. Joyner is a marine biology professor at our university. We also noticed that she’s an author of a couple publications regarding Agrobacterium Tumefaciens, a bacteria utilized in our project.
What we asked her about: We met with Dr. Joyner expecting to talk about A. Tumefaciens, but she ended up being very knowledgeable about corals themselves.
What we learned: Dr. Joyner introduced the sea anenome Aptasia to us. She suggested we use Aptasia as a model organism to study coral uptake of algae because it is relatively easy to culture and uptakes in a similar way to that of corals. We were initially going to test our modified algae on one of the most common corals in the Carribean: Elkhorn coral, but this organism is much harder to culture and isn’t as easy to obtain because of its position on the critically endangered list. We also learned of the importance of bacterial symbionts that produce mucus layers on the corals to protect from microbial predators.