Other than being green, what do all these fruits and vegetables have in common?
They are full of energy. Energy in the form of glucose. The energy from sunlight is briefly held in NADPH and ATP, which is needed to drive the formation of sugars such as glucose. And this all happens in the Calvin cycle.
The Calvin Cycle
Making Food “From Thin Air”
You’ve learned that the first, light-dependent stage of photosynthesis uses two of the three reactants, water and light, and produces one of the products, oxygen gas (a waste product of this process). All three necessary conditions are required – chlorophyll pigments, the chloroplast “theater,” and enzyme catalysts. The first stage transforms light energy into chemical energy, stored to this point in molecules of ATP and NADPH. Look again at the overall equation below. What is left?
Waiting in the wings is one more reactant, carbon dioxide, and yet to come is the star product, which is food for all life – glucose. These key players perform in the second act of the photosynthesis drama, in which food is “made from thin air!”
The second stage of photosynthesis can proceed without light, so its steps are sometimes called “light-independent” or “dark” reactions (though the term "dark" reactions can be misleading). Many biologists honor the scientist, Melvin Calvin, who won a 1961 Nobel Prize for working out this complex set of chemical reactions, naming it the Calvin cycle .
The Calvin cycle has two parts. First carbon dioxide is "fixed." Then ATP and NADPH from the light reactions provide energy to combine the fixed carbons to make sugar.
The Calvin cycle is discussed at http://www.youtube.com/watch?v=slm6D2VEXYs (13:28).
Carbon Dioxide is “Fixed”
Why does carbon dioxide need to be fixed? Was it ever broken?
Life on Earth is carbon-based. Organisms need not only energy but also carbon atoms for building bodies. For nearly all life, the ultimate source of carbon is carbon dioxide (CO 2 ), an inorganic molecule. CO 2 makes up less than 1% of the Earth’s atmosphere.
Animals and most other heterotrophs cannot take in CO 2 directly. They must eat other organisms or absorb organic molecules to get carbon. Only autotrophs can build low-energy inorganic CO 2 into high-energy organic molecules like glucose. This process is carbon fixation .
Stomata on the underside of leaves take in CO 2 and release water and O 2 . Guard cells close the stomata when water is scarce. Leaf cross-section (above) and stoma (below).
Plants have evolved three pathways for carbon fixation.
The most common pathway combines one molecule of CO 2 with a 5-carbon sugar called ribulose biphosphate (RuBP). The enzyme which catalyzes this reaction (nicknamed RuBisCo ) is the most abundant enzyme on earth! The resulting 6-carbon molecule is unstable, so it immediately splits into two 3-carbon molecules. The 3 carbons in the first stable molecule of this pathway give this largest group of plants the name “C 3 .”
Dry air, hot temperatures, and bright sunlight slow the C 3 pathway for carbon fixation. This is because stomata , tiny openings under the leaf which normally allow CO 2 to enter and O 2 to leave, must close to prevent loss of water vapor ( Figure above ). Closed stomata lead to a shortage of CO 2 . Two alternative pathways for carbon fixation demonstrate biochemical adaptations to differing environments.
Plants such as corn solve the problem by using a separate compartment to fix CO 2 . Here CO 2 combines with a 3-carbon molecule, resulting in a 4-carbon molecule. Because the first stable organic molecule has four carbons, this adaptation has the name C 4 . Shuttled away from the initial fixation site, the 4-carbon molecule is actually broken back down into CO 2 , and when enough accumulates, RuBisCo fixes it a second time! Compartmentalization allows efficient use of low concentrations of carbon dioxide in these specialized plants.
See http://www.youtube.com/watch?v=7ynX_F-SwNY (16:58) for further information.
Cacti and succulents such as the jade plant avoid water loss by fixing CO 2 only at night. These plants close their stomata during the day and open them only in the cooler and more humid nighttime hours. Leaf structure differs slightly from that of C 4 plants, but the fixation pathways are similar. The family of plants in which this pathway was discovered gives the pathway its name, Crassulacean Acid Metabolism, or CAM ( Figure below ). All three carbon fixation pathways lead to the Calvin cycle to build sugar.
See http://www.youtube.com/watch?v=xp6Zj24h8uA (8:37) for further information.
Even chemical reactions adapt to specific environments! Carbon fixation pathways vary among three groups. Temperate species (maple tree, left) use the C 3 pathway. C 4 species (corn, center) concentrate CO 2 in a separate compartment to lessen water loss in hot bright climates. Desert plants (jade plant, right) fix CO 2 only at night, closing stomata in the daytime to conserve water.
How Does the Calvin Cycle Store Energy in Sugar?
As Melvin Calvin discovered, carbon fixation is the first step of a cycle. Like an electron transport chain, the Calvin cycle, shown in Figure below , transfers energy in small, controlled steps. Each step pushes molecules uphill in terms of energy content. Recall that in the electron transfer chain, excited electrons lose energy to NADPH and ATP. In the Calvin cycle, NADPH and ATP formed in the light reactions lose their stored chemical energy to build glucose.
Use the Figure below to identify the major aspects of the process:
- the general cycle pattern
- the major reactants
- the products
Overview of the Calvin Cycle Pathway.
First, notice where carbon is fixed by the enzyme nicknamed RuBisCo. In C 3 , C 4 , and CAM plants, CO 2 enters the cycle by joining with 5-carbon ribulose bisphosphate to form a 6-carbon intermediate, which splits (so quickly that it isn’t even shown!) into two 3-carbon molecules.
Now look for the points at which ATP and NADPH (made in the light reactions) add chemical energy (“Reduction” in the diagram) to the 3-carbon molecules. The resulting “half-sugars” can enter several different metabolic pathways. One recreates the original 5-carbon precursor, completing the cycle. A second combines two of the 3-carbon molecules to form glucose, universal fuel for life.
The cycle begins and ends with the same molecule, but the process combines carbon and energy to build carbohydrates – food for life.
So, how does photosynthesis store energy in sugar? Six “turns” of the Calvin cycle use chemical energy from ATP to combine six carbon atoms from six CO 2 molecules with 12 “hot hydrogens” from NADPH. The result is one molecule of glucose, C 6 H 12 O 6 .
- The reactions of the Calvin cycle add carbon (from carbon dioxide in the atmosphere) to a simple five-carbon molecule called RuBP.
- These reactions use chemical energy from NADPH and ATP that were produced in the light reactions.
- The final product of the Calvin cycle is glucose.
Use these resources to answer the questions that follow.
- http://www.hippocampus.org/Biology Biology for AP* Search: The Calvin-Benson Cycle: Overview
- What are carbon assimilation and carbon fixation?
- Why are most plants called C 3 plants?
- Describe RuBisCo.
- What is a C 4 plant?
- http://www.hippocampus.org/Biology Biology for AP* Search: The Conversion of Carbon Dioxide to Sugar
- How does CO 2 enter the leaf?
- What is Ribulose-1,5-bisphosphate?
- What happens to some of the Glyceraldehyde-3-phosphate?
- What happens to RuBisCo at night?
- http://www.hippocampus.org/Biology Biology for AP* Search: The Calvin-Benson Cycle: Summary
- What eventually happens to the carbon that enters plants as part of CO 2 ?
- What happens to the ATP and NADPH made during the light reactions?
- What happens to energy during photorespiration?
- What is a main advantage of C 4 plants?
- Photosynthesis at http://johnkyrk.com/photosynthesisdark.html .
- What happens during the carbon fixation step of the Calvin cycle?
- What is special about RuBisCo?
- What are stomata?
- Explain what might happen if the third step of the Calvin cycle did not occur. Why?
- What is the main final product of the Calvin cycle? How many turns of the Calvin cycle are needed to produce this product?