Bio 111 Study Guide Chapter 8 Photosynthesis BEFORE CLASS: Reading: Read the whole chapter from pp. 161-179. Figure 8.16 puts all of the light reactions together for you. Study it and understand it well! Figure 8.19 displays a great overview of photosynthesis. Figure 8.20 is an incredible figure that shows how concepts from chapters 3-8 would be at work together in a living plant cell. Definitions: photosynthesis chlorophyll NADP + photophosphorylation carbon fixation electromagnetic spectrum visible light absorption spectrum chlorophyll a chlorophyll b action spectrum carotenoids photosystem reaction-center complex light-harvesting complex primary electron acceptor photosystem II (PSII)
photosystem I (PSI) G3P (glyceraldehyde 3-phosphate) RuBP (ribulose bisphosphate) rubisco (RuBP carboxylase oxygenase) C3 plants photorespiration C4 plants CAM plants Questions/Problems: 1. Describe the relationship between the molecules involved in photosynthesis and cellular respiration. Also, what role does the sun play? 2. Label the following parts and molecules in the diagram below: chloroplast, thylakoids, stroma, light, H2O, CO2, O2, sugar, NADP +, ADP, Pi, ATP, NADPH, Light Reactions, and Calvin cycle.
DURING CLASS: Significance of Photosynthesis Plant Structures Leaf: Chlorophyll: Characteristics of Light Electromagnetic spectrum Pigment Molecules Absorption spectrum Action spectrum
Photosynthesis Purpose Summary equation Two Stages: Photosystems: Redox Reactions: Coenzymes:
Light Reactions Purpose Steps: Mechanism of ATP Synthesis: Photophosphorylation Chemiosmosis
Calvin Cycle Purpose Steps: Review of Photosynthesis Animation Photosynthesis
Adaptations to Photorespiration C3 plants Photorespiration C4 plants CAM plants Putting it All Together (Ch. 3-8) **Take Away Concept** Photosynthesis provides the foundation for both energy and nutrients that support almost all living organisms in the world.
AFTER CLASS: Questions/Problems: 1. What color(s) of light drive photosynthesis in green plants most efficiently? What color of light is least effective in driving photosynthesis? Explain how you know both answers. 2. Which of the following statements describes the results of photosynthesis? 6CO2 + 6H2O + light energy C6H12O6 + 6O2 a. CO2 is reduced and H2O is oxidized. b. C6H12O6 is oxidized and O2 is reduced. c. O2 is oxidized and H2O is reduced. d. CO2 is oxidized and C6H12O6 is reduced e. O2 is reduced and CO2 is oxidized. 3. This is a figure of the Light Reactions. Use the following words to label the figure below: ADP, ATP, ATP synthase, chlorophyll, ETC, small ETC, H +, H2O, NADP +, NADP + reductase, NADPH, O2, photosystem I, photosystem II, Pi, and primary electron acceptor (some are used more than once). Draw in where light energy plays a role and where the electrons get excited and are passed along. Also draw the many H + ions involved in the chemiosmosis part of photophosphorylation. Label the parts of the chloroplast shown (stroma, thylakoid, and thylakoid space), and indicate in the gray box on the right where the ATP and NADPH are headed next.
4. To depict the Calvin Cycle, draw a circle below with an arrow going in the top and one coming out the bottom. Then add and label the molecules ADP, ATP, CO2, G3P, H +, NADP +, NADPH, Pi, RuBP, and rubisco. Then label the three main steps of the Calvin Cycle: Carbon Fixation, Reduction, and Regeneration. Location: 5. The Calvin Cycle requires ATP and NADPH, products of the light reactions. If a classmate asserted that the light reactions don t depend on the Calvin cycle and, with continual light, could just keep on producing ATP and NADPH, how would you respond? 6. Why are C4 plants able to photosynthesize with no apparent photorespiration? 7. Why is a CAM plant better adapted to a very dry climate than a C3 plant?
Putting it All Together (Ch. 3-8) Pictured below is an active plant cell (Figure 8.20 from the textbook). It shows many of the cellular parts and processes that we ve been learning about for the last few chapters. Label every organelle and molecule that you can (at least once). Then, write a sentence or two describing what is happening for each of the numbers. 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11.