Biology Commonwealth of Virginia



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Procedure


Safety Note: You must wear protective eyewear!

1. Number the containers 1 through 4, and fill each about 4/5 full with aquarium water.

2. Add enough of the bromthymol blue indicator solution (2 to 3 mL) to each bottle to obtain a green color

3. Add the following items to the containers, and then seal them tightly:

#1. Sprig of Elodea

#2. Snail

#3. Sprig of Elodea and Snail

#4. Nothing (the control)

4. Place containers near a light source.

5. Predict the color the water in the containers will turn in a few hours. Explain your predictions.



6. Fill in the Experimental Design table on the next page.
Photosynthesis and Respiration

Experimental Design Table


Question(s)




Hypothesis




Independent variable (IV)




Levels of the IV tested, and control

#1

Water + Elodea

#2

Water + snail

#3

Water + snail + Elodea

#4

Water only (control)

Number of repeated trials

One

One

One

One

Dependent variable(s) (DV)

and prediction













Constants






Observations and Conclusions


Within a few hours, the water in the containers should be different colors. Explain your observations.

Energy and ATP


Organizing Topic Life Functions and Processes

Overview Students learn how ATP is synthesized and how it stores the energy needed for metabolism, the sum total of all the chemical reactions in the cell of an organism. Also, students demonstrate that carbohydrates, such as glucose or common table sugar, contain energy that can be released in the form of heat. They simulate the breaking of the high energy bonds of ATP to release that energy.

Related Standards of Learning BIO.1d; BIO.3d

Objectives


The students will summarize the processes of cells, including the following:

  • Eukaryotic cells (plant and animals) burn organic molecules with oxygen to produce energy, carbon dioxide, and water.

  • Cells release the chemical energy stored in the products of photosynthesis. This energy is transported in molecules of ATP.

  • When cells need energy to do work, certain enzymes release the energy stored in the chemical bonds in ATP.

M
Activity 2

  • Protective eyewear

  • Scissors

  • Tape measure

  • Four blocks of wood, one twice the size of the other three

  • Three identical rubber bands
aterials needed


Activity 1

  • Lab coats, protective eyewear

  • Sugar cube (sucrose, a disaccharide)

  • Heat resistant watch glass or dish

  • Thermometer (°C)

  • Lighter

  • Test tube with 10 mL of water

  • Ring stand and clamps

Instructional activity

Content/Teacher Notes


In the interdependent processes of photosynthesis and respiration shown in this graphic, one of the products of cellular respiration is “useful chemical bond energy.”

Energy is the ability to do work. Potential energy is energy of position or stored energy, and it can be converted into kinetic energy. Kinetic energy is energy of motion. Chemical bond energy, a type of potential energy, is the energy stored in the bonds of molecular substances.

Imagine that you are standing on the second floor of a building. You have potential energy due to your position. You can convert it to kinetic energy all at once by jumping to the floor below, or you can release it a little at a time by walking down the stairs.

The problem is that the release of the chemical bond energy of carbohydrates in a cell must be done in a manner that does not destroy the cell during the process. In cellular respiration, the energy in glucose is released in small amounts instead of all at once.

Cellular Respiration: In cells, potential energy in the chemical bonds of food is transferred to the bonds of a substance called “adenosine triphosphate” (ATP). The potential energy of ATP is readily converted into kinetic energy to do work, such as electrical work (nerve impulse), transport work (heart, active pumps), chemical work, or mechanical work (muscle contraction).


C6H12O6










muscle contraction
building polymers
membrane transport
nerve impulses

+
6O2


↑↓




ADP




Energy Transfer

+

Energy Release



Phosphate group







↑↓







ATP




6CO2 + 6H20










This transfer of energy involves an ordered, step-by-step procedure that starts with glucose and ends with the formation of carbon dioxide, water, and energy stored in adenosine triphosphate (ATP). It is called “cellular respiration” and is defined as the process by which cells release the energy in glucose. A simplified equation for cellular respiration is the following:

C6H12O6 + 6O2  6CO2 + 6H20 + 38 ATP

A better representation of cellular respiration is shown below. The process involves dozens of intermediate steps requiring enzymes and the addition of two ATP molecules to start the reaction. To accomplish this, the cell uses special proteins called “enzymes.” Enzymes are organic catalysts (proteins) that lower the energy of activation for reactions.











enzymes
















C6H12O6

+

6O2




6CO2

+

6H20

+

38 ATP










+2 ATP
















Adenosine Triphosphate (ATP): Adenosine triphosphate is not the only energy-storing molecule in cells (creatine phosphate is found in muscle cells), but it is the most common. ATP is constructed from the RNA nucleotide adenine: Adenine + Ribose Sugar = A-P~P~P. The structure of ATP compared to those of ADP and AMP is as follows:

  • Adenosine triphosphate (ATP) has three phosphate groups attached to it: A-P~P~P.

  • Adenosine diphosphate (ADP) has two phosphate groups attached to it: A-P~P.

  • Adenosine monophosphate (AMP) has a single phosphate group: A-P.

Note the high energy bonds between the second and third phosphate groups.

Before starting these activities, review the processes of photosynthesis and cellular respiration. Then introduce cellular energy and ATP (adenosine triphosphate [tri = three]) by showing some rechargeable batteries. Ask students what rechargeable batteries do and how they work. Use an analogy between ATP and the batteries. As the batteries are used, they give up their potential energy until all of it has been converted into kinetic energy and heat/unusable energy. Spent rechargeable batteries can be used again only after the input of additional energy. ATP is the higher energy form (like the recharged battery), while ADP (adenosine diphosphate [di = two]) is the lower energy form (like the used-up battery). When the terminal (third) phosphate is cut loose, ATP becomes ADP, and the stored energy is released for use in some biological process. The input of additional energy (plus a phosphate group) “recharges” ADP into ATP.



Introduction


1. Ask students where ATP comes from. Show an overview of photosynthesis with an animated tutorial. Possible Web sites for tutorials include the following:

  • http://www.fw.vt.edu/dendro/forestbiology/photosynthesis.swf

  • http://www.johnkyrk.com/photosynthesisdark.html

2. Remind students that carbohydrates are named for the number of carbon atoms they contain and that their names usually end in the letters ose.

Procedure


Activity 1. Relative Amount of Energy in Carbohydrates

Safety Note: Students must wear lab coats and protective eyewear! They must perform the experiment in an approved fume hood.

1. Put on safety glasses.

2. Place a test tube with 10 mL of room-temperature water in a clamp, and attach it to a ring stand.

3. Measure and record the temperature of the water.

4. Place a sugar cube on a heat-resistant dish under the test tube.

5. Light the sugar cube with the lighter, and let it burn as completely as possible.



6. Measure and record the increase in heat of the water.
Activity 2. Relative Amount of Energy in the Bonds of ATP

Safety Note: Students must wear lab coats and protective eyewear! They must complete this experiment in an open area: outside is best.

1. Put on safety glasses.

2. Label the large wooden block with an A (adenosine).

3. Label each of the other three with a P (phosphate group).

4. Use three rubber bands to represent the chemical bonds holding the phosphates to the adenosine molecule. The first rubber band goes around the adenosine block and one phosphate group. The second goes around the adenosine and two phosphate groups. The third goes around the adenosine and all three phosphate groups.

5. Cut the rubber bands with scissors to simulate the breaking of the bonds. Start with the band encircling all three phosphate groups.

6. Measure the distances the rubber bands traveled, which represent the amounts of energy in the molecule.

Safety Note: The trajectory of a rubber band can be totally unpredictable. Be prepared! Keep safety glasses on at all times.



Observations and Conclusions


1. Have the students view an animated tutorial on glycolysis, such as that at http://www.johnkyrk.com/glycolysis.html. Discuss reactions to the tutorial.

2. Have students state how much the temperature of the water rose in Activity 1. Based on the fact that a calorie is equal to the amount of energy needed to heat 1 mL of water 1°C, have students calculate how many calories were in the sugar cube.

3. Have students state which rubber band traveled the farthest in Activity 2. Have them explain why in terms of potential and kinetic energy.

4. Ask: “Is there more or less energy in ADP (two phosphate groups) than in ATP? Which would you want to have the most of if you were going to run a race?”

5. Ask: “Is phosphate important in a diet? Why, or why not?” Have students research foods that are high in phosphate.


Directory: testing -> sol -> scope sequence
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