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Chapter 10: Problem 5

In the animal kingdom today, poikilotherms outnumber homeotherms by a great margin. Why is poikilothermy a successful way of life even though poikilotherms sometimes must compete successfully with homeotherms to survive?

Short Answer

Expert verified
Poikilothermy is a successful lifestyle because these organisms conserve energy by not having to maintain a constant internal body temperature. This energy conservation allows them to survive in diverse harsh environments and makes them less dependent on a constant food supply. Sometimes they out-compete homeotherms by utilizing energy more efficiently and adapting to environmental changes more effectively, which could explain their greater numbers in the animal kingdom.

Step by step solution

01

Define and Distinguish

Understand the definitions of poikilotherms and homeotherms. Poikilotherms are organisms whose body temperature varies with the ambient temperature whereas homeotherms are organisms that maintain a constant body temperature regardless of surroundings.
02

Advantages of Poikilothermy

Examine the reasons why poikilothermy is a successful lifestyle. Poikilotherms conserve more energy because they don't need to metabolize as much to preserve a constant body temperature. This conservation of energy allows them to survive in harsh and variable environments and makes them less dependent on a constant food supply.
03

Competition with Homeotherms

Consider the competition scenario between poikilotherms and homeotherms. In some habitats, both types of organisms exist. Poikilotherms can sometimes out-compete homeotherms by utilizing energy more efficiently and capitalizing on environmental changes more effectively, as they can survive and even thrive in conditions that would be too extreme for homeotherms.
04

Explain the Ratio

Using the information gathered from steps 2 and 3, explain why poikilotherms outnumber homeotherms. In a broader range of environments and conditions, they're simply more adept at survival, likely contributing to their greater numbers in the animal kingdom.

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Key Concepts

These are the key concepts you need to understand to accurately answer the question.

Homeothermy
Homeothermy refers to the ability of certain animals to maintain a stable internal body temperature, regardless of the external environmental conditions. This capability is crucial for the survival and proper functioning of these organisms, as many physiological processes are temperature dependent. For instance:
  • Cellular metabolism operates optimally at certain temperatures.
  • Enzymatic activities fluctuate with changes in body heat.
Homeotherms use physiological mechanisms, such as shivering, sweating, and alterations in blood flow to regulate their temperature. These processes require a significant amount of energy, which is often derived from a steady diet. Thus, while homeothermy provides an advantage in terms of stability of physiological functions, it demands continuous energy intake, making these animals more vulnerable to fluctuations in food availability.
Energy Conservation
Energy conservation is a vital strategy utilized by poikilotherms that allows them to thrive in a variety of environments. Unlike homeotherms, poikilotherms do not need to invest energy in maintaining a constant body temperature. Instead, their body temperature fluctuates with the environment, drastically reducing their metabolic rate when temperatures dip. This energy-saving approach means:
  • Lower caloric requirements, reducing the need for frequent feeding.
  • Enhanced resilience to food scarcity.
By not having to expend energy on temperature regulation, poikilotherms can survive in regions where food resources are unpredictable or sparse. This energy conservation strategy is pivotal in the success and adaptability of poikilotherms in diverse habitats.
Environmental Adaptation
Adaptation to environmental conditions is a hallmark of poikilotherms. These animals have evolved to leverage their immediate surroundings to stabilize their body temperature. They bask in the sun to warm up or retreat to shaded areas or burrows to cool down. This behavioral adaptation allows them to:
  • Capitalize on favorable environmental changes.
  • Thrive in habitats ranging from deserts to rainforests.
Poikilotherms demonstrate a high degree of flexibility and survival capability. Their ability to efficiently use environmental features to their physiological advantage helps them outcompete homeotherms in certain ecosystems, especially those characterized by harsh climate variations.
Animal Physiology
Animal physiology varies significantly between poikilotherms and homeotherms, reflecting their different survival strategies. Poikilotherms have a physiology that enables them to endure wider temperature ranges, while homeotherms invest more in complex physiological processes to maintain a constant internal environment.
  • Homeotherms: Develop features such as fur or feathers for insulation.
  • Poikilotherms: Possess efficient mechanisms to utilize immediate thermal resources.
These physiological differences play a crucial role in how these animals interact with their environment and dictate their energy requirements and behavioral strategies. The robustness of poikilotherms' physiology to adapt to wide-ranging conditions is a key factor that explains their prevalence in the animal kingdom.

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Most popular questions from this chapter

There is currently a worldwide movement to create protected marine parks. If the parks have an Achilles heel, it is that they have fixed geographical positions, just in the way that Yellowstone National Park is at a fixed geographical location. Suppose that a certain endangered species of fish exists only in a marine park. If the ocean temperature rises in the park because of global warming, explain what physiological problems the species of fish might confront. How might the species face a brighter future if parks could have moveable boundaries rather than fixed ones?

Suppose you travel to a tropical place such as the Bahamas and watch the coastal poikilotherms, such as fish, crabs, and starfish, swim and crawl about in the warm waters. Suppose then that you travel to northern Maine and watch the related species of poikilotherms in the cold waters there. In the abstract, it would not be unreasonable to expect to see the animals in Maine moving about in slow motion compared with those in the Bahamas. In fact, however, rates of locomotion are likely to look to your eye to be more similar than different in the two places. Design experiments to assess whether the Maine animals are especially able to be active in cold waters. If you find that they are, how might their high ability for activity in cold waters be explained? For each hypothesis you present, design an experiment to test the hypothesis.

As discussed in Chapter 1 (see page 13), Claude Bernard, a nineteenth-century French physiologist often considered the father of modern animal physiology, is still remembered today for his famous dictum: "Constancy of the internal environment is the condition for free life." Does the study of thermal relations lend support to his dictum? Explain.

During winter, when people are in a well-insulated house, they usually feel comfortable if the air temperature is near \(22^{\circ} \mathrm{C}\left(72^{\circ} \mathrm{F}\right)\). If you have ever spent a night in a poorly insulated cabin in winter, however, you will recognize that paradoxically, when people are in poorly insulated buildings, they often feel chilly even when the air inside is heated to \(22^{\circ} \mathrm{C}\) or higher. One important reason for the difference in how warm people feel in the two sorts of buildings is that even if a well-insulated and poorly insulated building are identical in the air temperature inside, they differ in thermalradiation heat transfer. Specifically, a person standing in the two types of buildings experiences different heat exchange by thermal radiation in the two. Explain how thermal-radiation heat transfer accounts for the sense of chill in the poorly insulated building. (Hint: Think of the outer walls of the two types of buildings, and think specifically of the temperatures of the interior surfaces of those walls.)

In the rete mirabile serving the red swimming muscles of tunas, some key enzymes of catabolism show gradients of concentration: They are more concentrated at the cold end of the rete, and less concentrated at the warm end. These variations parallel variations that are often seen in the thermal acclimation of poikilotherms, when enzyme concentrations rise during acclimation to cold and fall during acclimation to heat. What do you think could be some of the reasons for these spatial and temporal variations in enzyme concentration? Why not have the highest observed enzyme concentrations everywhere at all times?
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