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Transcript
The Calvin Cycle •Anabolic reaction (builds sugar) •Requires ATP and NADPH (reducing power) •Requires 9 ATP and 6 NADPH (which are regenerated by light reactions) •Carbon enters in the form of CO2 and exits as a glucose molecule •For every three molecules of CO2, one G3P(sugar) is produced (net gain) Phases of The Calvin Cycle • Phase I: Carbon Fixation – CO2 attaches to a five-carbon sugar ribulose biophosphate (RuBP) – Enzyme (RuBP carboxylase aka rubisco most abundant protein) catalyzes this reaction – Produces a six carbon molecule but is unstable and split to form a three carbon molecule • 3-phosphoglycerate **For each CO2 molecule • Phase II: Reduction – Each 3-phosphoglycerate receives an additional phosphate group – Enzyme transfers phosphate from ATP to the molecule – A pair of electrons donated from NADPH reduces the molecule to G3P (potential energy) • Phase III: Regeneration of CO2 acceptor RuBP – five molecules of G3P are arranged into three molecules of RuBP • uses 3 ATP molecules to do this – RuBP is now prepared again to receive CO2 and the cycle continues What would happen if you closed the stomata on a leaf? • Build up of oxygen • No water would be released • No carbon dioxide would enter • Why would a plant close its stomata? – Hot dry environments (prevent dehydration) – But this limits photosynthesis production Alternate Methods of Carbon Fixation • Photorespiration: – C3 plants (most plants) – Produce G3P by fixating carbon using rubisco. Examples:Rice, wheat, soybean • Stomata close therefore CO2 decreases and O2 increases • Rubisco adds O2 to the Calvin Cycle which forms two carbon molecule broken down by mitochondria/peroxisomes into CO2 • Process is called photorespiration – No ATP is generated – No food is generated – Seems wasteful Modern Plants have Evolved • C4 Plants – Produces a four carbon molecule – Examples: sugarcane, corn, grass – Contain two types of photosynthetic cells • Bundle sheath cells • Mesophyll cells – CO2 is added to PEP (phosphoenopyruvate) – Enzyme PEP carboxylase combines the two due to enzymes high affinity for CO2 – After C4 plants fixes CO2 then the mesophyll cells exports the four carbon into bundle sheath cells – Enhances sugar production (b/c CO2 is available) • CAM Plants (Crassulacean Acid Metabolism) – Cacti, pineapples • CAM Plants (Crassulacean Acid Metabolism) – Cacti, pineapples – open stomata at night – CO2 gained at night forms organic acid – Mesophyll cells of CAM plants store the organic acid – During daylight CO2 (from organic acid) is released into the bundle sheath and made into sugar ** CAM, C3 and C4 plants all eventually use the Calvin Cycle to make sugar from CO2
