Plant Adaptations: C3 and C4 plants. Leaf anatomy.
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Transcript of Plant Adaptations: C3 and C4 plants. Leaf anatomy.
![Page 1: Plant Adaptations: C3 and C4 plants. Leaf anatomy.](https://reader036.fdocuments.in/reader036/viewer/2022081506/56649db55503460f94aa6e1e/html5/thumbnails/1.jpg)
Plant Adaptations: C3 and C4 plants
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Leaf anatomy
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Remember The Needs of Plants!
Plants need to take in:water (from soil)nutrients (from soil)CO2 (from atmosphere)
Plants need to release:water vapor (through leaves)O2 (through leaves)
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Controlling water loss from leaves• Hot or dry days
– stomates close to conserve water– guard cells
• gain H2O = stomates open
• lose H2O = stomates close
– adaptation to living on land, but…
– creates PROBLEMS!
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When stomates close… • Closed stomates lead to…
– O2 build up → from light reactions
– CO2 is depleted → in Calvin cycle• causes problems in Calvin Cycle
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Inefficiency of RuBisCo: CO2 vs O2
• RuBisCo in Calvin cycle– carbon fixation enzyme
• normally bonds C to RuBP• CO2 is the optimal substrate• reduction of RuBP• building sugars
– when O2 concentration is high• RuBisCo bonds O to RuBP• O2 is a competitive substrate• oxidation of RuBP• breakdown sugars
photosynthesis
photorespiration
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6Cunstable
intermediate
1C CO2
Calvin cycle when CO2 is abundant
5CRuBP
3CPGA
ADP
ATP
3CNADP
NADPH
ADP
ATP
G3Pto make glucose
3CG3P
5C
RuBisCo
C3 plants
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Calvin cycle when O2 is high
5CRuBP
3C2C
to mitochondria
–––––––lost as CO2 without
making ATP
photorespiration
O2
Hey Dude,are you highon oxygen!
RuBisCo
It’s so sad to see a
good enzyme,go BAD!
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Photorespiration• In most plants initial fixation of CO2 occurs via rubisco
and results in a three-carbon compound, 3-phosphoglycerate.
• When their stomata are closed on a hot, dry day, CO2 levels drop as CO2 is consumed in the Calvin cycle.
• At the same time, O2 levels rise as the light reaction converts light to chemical energy.
• While rubisco normally accepts CO2, when the O2/CO2 ratio increases (on a hot, dry day with closed stomata), rubisco can add O2 to RuBP.
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• When rubisco adds O2 to RuBP, RuBP splits into a three-carbon piece and a two-carbon piece in a process called photorespiration.– The two-carbon fragment is exported from the chloroplast
and degraded to CO2 by mitochondria and peroxisomes.– Unlike normal respiration, this process produces no ATP, nor
additional organic molecules.• Photorespiration decreases photosynthetic output by
taking organic material from the Calvin cycle. • Photorespiration can drain away as much as 50% of the
carbon fixed by the Calvin cycle on a hot, dry day.• Certain plant species have evolved alternate modes of
carbon fixation to minimize photorespiration.
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Impact of Photorespiration • Oxidation of RuBP
– short circuit of Calvin cycle – loss of carbons to CO2
• can lose 50% of carbons fixed by Calvin cycle
– reduces production of photosynthesis• no ATP (energy) produced• no C6H12O6 (food) produced
– if photorespiration could be reduced, plant would become 50% more efficient• strong selection pressure to evolve alternative carbon
fixation systems
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Reducing photorespiration • Separate carbon fixation from Calvin cycle
– C4 plants • PHYSICALLY separate carbon fixation from Calvin cycle
– different cells fix carbon vs. where Calvin cycle occurs (different leaf structure)
– PEP carboxylase
– CAM plants• TEMPORALLY separate carbon fixation from Calvin cycle• fix carbon during night, Calvin cycle during day
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Working of the C4
• After entering through stomata, CO2 diffuses into a mesophyll cell.
• Instead the CO2 is inserted into a 3-carbon compound (C3) called phosphoenolpyruvic acid (PEP) forming the 4-carbon compound oxaloacetic acid (C4).
• Oxaloacetic acid is converted into malic acid or aspartic acid (both have 4 carbons), which is transported (by plasmodesmata) into a bundle sheath cell. – Bundle sheath cells are deep in the leaf so
atmospheric oxygen cannot diffuse easily to them;
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• These features keep oxygen levels low.• Here the 4-carbon compound is broken down into
carbon dioxide, which enters the Calvin cycle to form sugars and starch.
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AP Biology
Comparative anatomy
C3 C4
Location,location,location!
PHYSICALLY separate C fixation from Calvin cycle
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C4 Leaf Biochemistry
Up Close:
Photosynthesis across 2
different cells.
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CAM (Crassulacean Acid Metabolism) plants
Adaptation to hot, dry climates separate carbon fixation from Calvin cycle by TIME
close stomates during day open stomates during night
at night: open stomates & fix carbonin 4C “storage” compounds
in day: release CO2 from 4C acids
to Calvin cycle increases concentration of CO2 in cells
succulents, some cacti, pineapple
It’s all inthe timing!
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CAM plants
succulents
cacti
pineapple
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CAM Plant Biochemistry:Photosynthesis at 2 times of day
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C4 vs CAM Summary
C4 plants
separate 2 steps of C fixation anatomically in 2 different cells
CAM plants
separate 2 steps of C fixation temporally =2 different times
night vs. day
solves CO2 / O2 gas exchange vs. H2O loss challenge
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Why the C3 problem?• Possibly evolutionary baggage
– Rubisco evolved in high CO2 atmosphere• there wasn’t strong selection against active site of
Rubisco accepting both CO2 & O2
• Today it makes a difference
– 21% O2 vs. 0.03% CO2
– photorespiration can drain away 50% of carbon fixed by Calvin cycle on a hot, dry day
– strong selection pressure to evolve better way to fix carbon & minimize photorespiration
We’ve all gotbaggage!
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Supporting a biosphere• On global scale,
photosynthesis is the most important process for the continuation of life on Earth– each year photosynthesis…
• captures 121 billion tons of CO2
• synthesizes 160 billion tons of carbohydrate
– heterotrophs are dependent on plants as food source for fuel & raw materials