Examples of C4 plants include corn, sorghum, sugarcane, millet, and switchgrass. By contrast, with their adaptations, C4 plants are not as limited by carbon dioxide, and under elevated carbon dioxide levels, the growth of C4 plants did not increase as much as C3 plants.
A C4 plant is a plant that cycles carbon dioxide into four-carbon sugar compounds to enter into the Calvin cycle. These plants are very efficient in hot, dry climates and make a lot of energy. Many foods we eat are C4 plants, like corn, pineapple, and sugar cane.
C3 plants are plants in which the initial product of the assimilation of carbon dioxide through photosynthesis is 3-phosphoglycerate, which contains 3 carbon atoms.
C4 plants include corn, sugar cane, and many other tropical grasses. CAM ("crassulacean acid metabolism") plants also initially attach CO 2 to PEP and form OAA. CAM plants are more common than C4 plants and include cacti and a wide variety of other succulent plants.
C4 cycle occurs in both monocot plants and dicot plants. However, it is more common in monocots than dicots. Furthemore, a misconception exists that the c4 cycle is absent in monocots due to the absence of bundle sheath cells. However, this notion is false.
C3 plants include the cereals barley, oats, rice, and wheat, alfalfa (lucerne), cotton, Eucalyptus, sunflower, soybeans, sugar beets, potatoes, tobacco, Chlorella, and others.
C3 vs C4 Plants
| C3 Plants | C4 Plants |
|---|
| Examples include rice, wheat, oats, barley, cotton, peanuts, tobacco, sugar beets, soybeans and spinach | Examples include Maize, Sugarcane, pearl millet, sorghum. |
| Leaves of these plants DO NOT show Kranz anatomy. | Leaves of these plants show Kranz anatomy. |
Both C4 and C3 plants use Rubisco to catalyze carbon fixation. A key difference is that C4 plants sequester the Rubisco enzyme to keep it away from oxygen. In C3 plants, the enzyme Rubisco is found in the mesophyll cells. In C4 plants Rubisco is relocated to the bundle sheath cells well inside the leaf.
C3 and C4 cycle are two parts of the overall photosynthesis process. More preciously, these are two sections of the biosynthesis process. This process is also known as the Hatch and Slack pathway. The first stable product of this process is a four-carbon compound (oxaloacetate acid), hence the name.
C3 photosynthesis produces a three-carbon compound via the Calvin cycle while C4 photosynthesis makes an intermediate four-carbon compound that splits into a three-carbon compound for the Calvin cycle. Plants that use CAM photosynthesis gather sunlight during the day and fix carbon dioxide molecules at night.
Most plants are C3 plants and some examples include: evergreen trees, deciduous trees and weedy plants like lambs quarters and bindweed. Important crop plants like rice, barley and soybean are also C3. Many plants that live in the tropics and subtropics, where precipitation is not sparse, are C3 plants.
C4 plants are commonly found in warm- to high-temperature environments, such as tropical grasslands, where photorespiratory rates would be high in C3 plants.
The main difference between C3 C4 and CAM photosynthesis is that C3 photosynthesis produces a three-carbon compound via the Calvin cycle, and C4 photosynthesis produces an intermediate four-carbon compound, which split into a three-carbon compound for the Calvin cycle, whereas CAM photosynthesis gathers sunlight during
Aquatic grasses have aerial and submersed leaves with C4 or C3-C4 photosynthesis and Kranz anatomy, but some lack Kranz anatomy in the submersed leaves.
