1 / 13

Other Types of Photosynthesis C 4 Photosynthesis and CAM Photosynthesis

Other Types of Photosynthesis C 4 Photosynthesis and CAM Photosynthesis. Calvin Cycle Reactions: Carbon Dioxide Fixation. CO 2 is attached to 5-carbon RuBP molecule Result in a 6-carbon molecule This splits into two 3-carbon molecules (3PG)

paley
Télécharger la présentation

Other Types of Photosynthesis C 4 Photosynthesis and CAM Photosynthesis

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Other Types of Photosynthesis C4 Photosynthesis and CAM Photosynthesis

  2. Calvin Cycle Reactions:Carbon Dioxide Fixation • CO2 is attached to 5-carbon RuBP molecule • Result in a 6-carbon molecule • This splits into two 3-carbon molecules (3PG) • Reaction accelerated by RuBP Carboxylase (Rubisco) • CO2 now “fixed” because it is part of a carbohydrate

  3. Calvin Cycle Reactions:Carbon Dioxide Reduction • 3PG reduced to BPG • BPG then reduced to G3P • Utilizes NADPH and some ATP produced in light reactions

  4. Calvin Cycle Reactions:Regeneration of RuBP • RuBP used in CO2 fixation must be replaced • Every three turns of Calvin Cycle, • Five G3P (a 3-carbon molecule) used To remake three RuBP (a 5-carbon molecule)

  5. The Calvin Cycle: Fixation of CO2

  6. Importance of Calvin Cycle • G3P (glyceraldehyde-3-phosphate) can be converted to many other molecules • The hydrocarbon skeleton of G3P can form • Fatty acids and glycerol to make plant oils • Glucose phosphate (simple sugar) • Fructose (which with glucose = sucrose) • Starch and cellulose • Amino acids

  7. Other Types of Photosynthesis C4 Photosynthesis and CAM Photosynthesis

  8. Most plants are C3 plants • In C3 plants, the Calvin cycle fixes CO2 directly; the first molecule following CO2 fixation is 3PG. • In hot weather, stomata close to save water; CO2 concentration decreases in leaves; O2 increases. • O2 combines with RuBP instead of CO2 • This is called photorespiration since oxygen is taken up and CO2 is produced; this produces less 3PG.

  9. C4 Photosynthesis • In a C3 plant, mesophyll cells contain well‑formed chloroplasts, arranged in parallel layers. • In C4 plants, bundle sheath cells as well as the mesophyll cells contain chloroplasts. • In C4 leaf, mesophyll cells are arranged concentrically around the bundle sheath cells.

  10. C4 Photosynthesis • Remember C3 plants use RuBP carboxylase to fix CO2 to RuBP in mesophyll; the first detected molecule is 3PG. • C4 plants use the enzyme PEP carboxylase (PEPCase) to fix CO2 to PEP (phosphoenolpyruvate, a C3 molecule); the end product is oxaloacetate (a C4 molecule). • In C4 plants, CO2 is taken up in mesophyll cells and malate, a reduced form of oxaloacetate, is pumped into the bundle‑sheath cells; here CO2 enters Calvin cycle. • In hot, dry climates, net photosynthetic rate of C4 plants (e.g., corn) is 2–3 times that of C3 plants. • Photorespiration does not occur in C4 leaves because PEP does not combine with O2; even when stomata are closed, CO2 is delivered to the Calvin cycle in bundle sheath cells. • C4 plants have advantage over C3 plants in hot and dry weather because photorespiration does not occur; e.g., bluegrass (C3) dominates lawns in early summer, whereas crabgrass (C4) takes over in the hot midsummer.

  11. CAM Photosynthesis • CAM(crassulacean‑acid metabolism) plants form a C4 molecule at night when stomata can open without loss of water; found in many succulent desert plants including the family Crassulaceae. • At night, CAM plants use PEPCase to fix CO2 by forming C4 molecule stored in large vacuoles in mesophyll. • C4 formed at night is broken down to CO2 during the day and enters the Calvin cycle which now has NADPH and ATP available to it from the light‑dependent reactions. • CAM plants open stomata only at night, allowing CO2 to enter photosynthesizing tissues; during the day, stomata are closed to conserve water but now CO2 cannot enter photosynthesizing tissues. • Photosynthesis in a CAM plant is minimal, due to limited amount of CO2 fixed at night; but this does allow CAM plants to live under stressful conditions.

More Related