Ch. 40 - Water and Electrolyte Balance in Animals

Freeman - Biological Science 8th Edition

Freeman8th EditionBiological ScienceISBN: 9780138276263Not the one you use?Change textbook

Freeman 8th Edition

Ch. 40 - Water and Electrolyte Balance in Animals

Problem 10

Chapter 40, Problem 10

To test the hypothesis that mussels are osmoconformers, researchers exposed mussels to water of varying osmolarities and then drew hemolymph samples from the mussels. Graph the data provided here. Put the independent variable on the x-axis and the dependent variable on the y-axis.
Is the researchers' hypothesis supported by the data? Explain.

Verified step by step guidance

Identify the independent and dependent variables from the data table. The independent variable is the water osmolarity (milliosmol/L), and the dependent variable is the hemolymph osmolarity (milliosmol/L).

Create a graph with the x-axis representing the independent variable (water osmolarity) and the y-axis representing the dependent variable (hemolymph osmolarity).

Plot the data points on the graph using the values from the table: (250, 261), (500, 503), (750, 746), and (1000, 992).

Draw a line or curve that best fits the plotted data points to visualize the relationship between water osmolarity and hemolymph osmolarity.

Analyze the graph to determine if the hemolymph osmolarity closely follows the water osmolarity, indicating that mussels are osmoconformers. If the hemolymph osmolarity changes in direct proportion to the water osmolarity, the hypothesis is supported.

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Key Concepts

Here are the essential concepts you must grasp in order to answer the question correctly.

Osmoconformers

Osmoconformers are organisms that maintain an internal osmotic environment that is isotonic to their external environment. This means that their body fluids have the same osmolarity as the surrounding water, allowing them to avoid the energetic costs associated with osmoregulation. In the case of mussels, if they are osmoconformers, their hemolymph osmolarity should closely match the osmolarity of the surrounding water.

Osmolarity

Osmolarity is a measure of the concentration of solute particles in a solution, expressed in milliosmoles per liter (mOsm/L). It is crucial for understanding how organisms interact with their environment, particularly in terms of water movement across cell membranes. In this experiment, the osmolarity of both the water and the hemolymph is measured to determine if the mussels can conform to the osmotic conditions of their surroundings.

Graphing Data

Graphing data is a fundamental skill in biology that allows researchers to visualize relationships between variables. In this case, the independent variable (water osmolarity) is plotted on the x-axis, while the dependent variable (hemolymph osmolarity) is on the y-axis. Analyzing the resulting graph helps determine if the mussels' hemolymph osmolarity changes in response to varying water osmolarity, thus supporting or refuting the hypothesis.

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Textbook Question

Explain why mammals would not be able to produce concentrated urine if their nephrons lacked loops of Henle.

Textbook Question

Scientists have noted that marine invertebrates tend to be osmoconformers, while freshwater invertebrates tend to be osmoregulators. Suggest an explanation for this phenomenon.

Textbook Question

Biologists have been able to produce mice that lack functioning genes for aquaporins. How would the urine of these mice compare to that of mice with normal aquaporins?

a. Lower volume and lower osmolarity

b. Lower volume and higher osmolarity

c. Higher volume and lower osmolarity

d. Higher volume and higher osmolarity

Textbook Question

Fish and other aquatic organisms are exposed to many types of water pollutants, including metals such as aluminum. Although a low level of aluminum is found in unpolluted water, many lakes and streams have an increased level because of mining, sewage treatment, and accidental spills of toxic materials. Aluminum pollution can result in mass fish die-offs such as the one pictured here. How does this occur? Which of the following is an osmoregulatory challenge that freshwater fishes need to overcome?

a. Diffusion of sodium ions out of the body

b. Diffusion of water out of the body

c. Active transport of sodium ions out of the body

d. Active transport of water out of the body

Textbook Question

Fish and other aquatic organisms are exposed to many types of water pollutants, including metals such as aluminum. Although a low level of aluminum is found in unpolluted water, many lakes and streams have an increased level because of mining, sewage treatment, and accidental spills of toxic materials. Aluminum pollution can result in mass fish die-offs. In a laboratory, scientists exposed freshwater bony fish (Prochilodus lineatus) to water with a high level of aluminum and compared their blood osmolarity to that of fish exposed to water with a normal aluminum level (control). The results of the experiment are shown here (asterisks indicate P<0.05 between control and treated groups at a given time).

Do the data support the hypothesis that aluminum interferes with osmoregulation in freshwater fishes? Explain.

Textbook Question

Why did the scientists do this experiment in a laboratory instead of simply collecting fish from a river with a high aluminum level and documenting their osmoregulatory ability?