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Case Study: Loggerhead Turtles and Population Models

  • Page ID
    20357
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    Part 1: Hatchling Exodus

    Amy was very excited to be staying at a resort in Florida where loggerhead turtles lay their eggs. She had carefully read the literature that outlined the rules for her stay. Rules that were in place so that visitors would not interfere with the nesting females. Though her cabin was next to the beach, there were no exterior lights and she was warned to not use flashlights or flash photography. The beach was also to be kept clear of any toys or furniture that may block a female from a nesting site. Amy was surprised to learn that loggerhead turtles cannot back up.

    At night, Amy and her tour group were allowed to carefully walk the beach and observe a female turtle as she laid her eggs. The massive 275 pound loggerhead had a shell that was almost 3 feet long. The huge reptile used her hind flippers to dig a trench and lay over 100 eggs. The tour guide explained that the hatching success rate of an in situ nest has a success rate of 80-­100%, but a relocated nest will only have about a 60% success rate.

    "Why would anyone want to relocate the nest?" Amy asks.

    The tour guide answered, "Sometimes the nests are in high traffic areas, or areas that have been compromised. During the gulf oil spill, thousands of turtles nests were relocated."

    "What happens after the loggerhead turtles hatch?"

    The tour guide sighed as she relayed that the odds of their survival is really low. "Many of the hatchlings die before they ever reach the ocean, they fall prey to birds and crabs. Some become disoriented and go the wrong direction."

    "Where do they go if they do make it to the ocean?"

    "That's the strange thing," answered the guide, "Biologists didn't really know what happened during the decade after they were hatched. They even called that period of time 'the lost years.'"

    A member of the group raised his hand and speaking quietly so as not to disturb the female, shared additional information. "I'm from the University of Florida, and I know that they've managed to attach solar trackers to some of the juvenile turtles. It seems that the turtles enter the North Atlantic Gyre which is part of the Gulf Stream. They live in the seaweed there, using it as food and shelter."

    In the back of the group, someone whispered: "Like in Finding Nemo!"

    Amy watched as the female turtle finished laying her clutch of eggs and pushed sand over the nest to cover them. This female must have beaten all the odds to return to this beach to lay her eggs many years later.

    1. Turtle nests are found near areas where tourists visit. Many of these locations have ordinances in place to protect turtles. List a few rules that would be necessary to protect turtles in these areas.
    2. What reproductive challenges do female sea turtles face?
    3. Some conservation efforts remove eggs and raise the hatchlings in captivity to ensure their survival. Do you think money should be spent for captive breeding programs? Why or why not?
    4. The term "in situ" is used by doctors to refer to organs or structures that are studied without removing them from the body. For example, a photo my show a picture of a heart in situ. How is the term used to describe turtle nests?

    Part 2: Survivorship Curves

    When Amy returned from her vacation, she decided to look into sea turtles to find out how many of them actually survived those early years. She discovered very little data on sea turtles as teenagers, but she recalled how the guide had referred to that time period as the "lost years." One data set did include turtle hatchling numbers and then numbers of turtles who returned to the beach a decade later.

    Sea Turtle Data
    Individuals Present (or hatched) Survived Survivorship
    Time 0 (eggs laid) 1100 1100 1.0
    Day 1 1100 1000 1000/1100 = .91
    Day 2 1000 600
    Day 3 600 230
    Day 4 230 80
    Day 5 80 18
    Year 15 18 16

    5. Calculate the survivorship by dividing the number that survived by the initial population (hatched). Complete the table to show survivorship at each time frame. Always use the initial population in the calculation.

    6. Create a graph that shows the number of survivors on the Y axis, and time on the X axis. Be sure to label your axes.

    As Amy looked at the graph she found it odd that a whole species would invest so much into a clutch of eggs, and have so few survivors. She took the data to her biology instructor to see if Dr. Franklin could shed some light on this. As he looked over the data, he nodded slowly. "I think I can explain what is going on here."

    "In the animal kingdom there are different strategies for reproduction. Remember that evolution favors behaviors or traits that ensure the survival of the species. Sometimes this means that the adults have a large number of offspring where only a few are expected to survive. These type of animals are called "R-Strategists" like the loggerhead sea turtles. As long as a few of the offspring survive to reproductive age,then there is continuity within the species."

    "What does the "R" stand for?" asked Amy.

    "Well, that is a little more complicated. There is a formula for population growth, where r represents the maximum reproductive capacity. This basically means that the turtles would be at maximum if so many of them didn't die that first year of life. Imagine what would happen to the sea turtle population if there were no predators!"

    "There would be a lot of sea turtles out there. Probably too many for the environment to support."

    "Exactly." Replied the professor. "Fortunately, very few organisms reach their biotic potential."

    "What is biotic potential?" Asked Amy.

    "That's the maximum rate the population can grow given optimal conditions. It basically means the growth rate if there were no limiting factors like food, space, or water."

    Amy felt the topic was veering off track. She really wanted to understand why evolution would select for organisms that would lay hundreds of eggs but only have a few that survived the first year of life. It seemed like a waste of resources. "But what about the turtles, why lay so many eggs to just have them all die?"

    The professor thought about how to explain it and then went to a blackboard. He quickly sketched a graph. "You see, there are three types of survivorship curves. One of these looks like the graph you made of the sea turtles."

    survivorship.png

    7. The graph shows survivorship curves for organisms that have different strategies. Label the graph to show which type is likely human and which type is the loggerhead sea turtle.

    8. The three types of curves are also described as: early loss, late loss, and constant loss. Propose an organism that would have a Type 2 curve. Defend your choice by describing this animal's life pattern using he data and growth curve as a guide. (

    9. What other animals can you think of would be R strategists? There are also animals described as K-strategists. Describe this type of strategy and provide an example.

    10. In some cases, animals reach their biotic potential (if for a short period of time) and wreak havoc on the environment. What is biotic potential and why would reaching it create problems for the environment?

    Part 3: Population Models

    Amy became really interested in how populations work and how different groups of organisms evolved different strategies for reproduction. Though Dr. Franklin mentioned that the "R" was part of an equation,she decided to look up the actual equation. A simple Google search located the equation that Dr. Franklin had referred to:

    \[\dfrac{dN}{dt} = rN \left( 1 -\dfrac{N}{K} \right) \]

    Where (\(dN/dt\)) is the rate of increase of the population and \(N\) is the population size, r is the intrinsic rate of increase. K is the carrying capacity of its local environmental setting. Thus, the equation relates the rate of change of the population \(N\) to the current population size and is the theoretical maximum rate of increase of a population per individual.

    The equation was developed from the r/K selection theory which relates to organisms that trade off between quantity and quality of offspring. If "r" was the maximum growth rate and referred to animals like sea turtles, then there must be a different type of strategy that referred to animals like humans or whales that had very few offspring but invested in years of parental care.

    Another internet search revealed that animals that invest more heavily into fewer offspring are called K-strategists. Traits associated with these animals are large body size, long life expectancy, production of fewer offspring and more parental care.

    Amy sighed deeply, that equation looked like the differential equations she learned in math class. She barely remembered how to work those types of problems. Her roommate, who is a math major, looked at the equation and quickly sketched what the graph would look like. Amy took one look at the graph and realized she'd seen it before. "Oh, that's a logistic growth curve!"

    carrying capacity.png

    Her roommate looked puzzled and Amy explained further. "Logistic growth curves occur when there is a limiting factor in the environment. A population grows until it levels out, usually because the population runs out of resources. Some populations, like humans, are in exponential growth, they haven't leveled out."

    Her roommate shrugged and went back to calculus. "I guess humans will reach that point some day...."

    13. "K" refers to the carrying capacity. Based on the graph and the text, suggest a definition for "carrying capacity."

    14. What factors would affect the carrying capacity of turtles? There are two types of limiting factors: Density­dependent factors and density independent factors. Define each and indicate which would have the greater impact on turtle populations.

    The following growth curve shows a population of crab in areas where loggerheads are known to gather. Crabs are a food source for the turtles who can use their strong jaws to crack their shells.

    problem 16 graph.png

    16. Based on the graph, what is the carrying capacity for crabs in the area being studied. Propose a reason that the population dropped in 2010.

    17. What does the population curve of crabs tell you about the loggerhead turtle populations in the same area? Draw a line to show how the turtle populations and the crab populations might be related.

    18. Summarize: Using all of the information from the case study, summarize the relationship between the following terms: carrying capacity | r-­strategist | survivorship | biotic potential | logistic growth curve | limiting factors


    This page titled Case Study: Loggerhead Turtles and Population Models is shared under a CC BY-NC-SA license and was authored, remixed, and/or curated by Shannan Muskopf (Biology Corner) .

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