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Chapter 8 - Photosynthesis

Photosynthesis Overview

Slide 1: Introduction to Photosynthesis

  • Definition: Photosynthesis is the process that uses solar energy to convert carbon dioxide (CO2) and water (H2O) into sugar and oxygen (O2).

    • General Formula: 6CO2 + 6H2O -> C6H12O6 + 6O2

Slide 2: Energy Transformations

  • Light Reactions: Convert solar energy into short-term chemical energy.(proton Gradient)

    • Products: ATP and NADPH.

  • Calvin Cycle: Converts short-term chemical energy (ATP, NADH) into long-term chemical energy (sugar).

    • Calvin cycle = Biochemical reactions

Slide 3: Chlorophyll

  • Function: A pigment that absorbs light, specifically red and blue wavelengths, and transmits and reflects green light.

    • A pigment is a chemical that absorbs light

Slide 4: Light Reactions

  • Reactions that directly require light

  • Location: Occurs in the thylakoids, in the grana chloroplasts.

  • Thylakoid:Green photosynthetic membrane, contains chlorophyll and other pigments

  • Purpose: Convert solar energy into short term chemical energy (ATP and NADPH).

    • Solar energy

    • Electron transport/Redox reactions

    • Proton Gradient

    • ATP?NADH

      • Reactants(IN): H2O, ADP + P, NADP+

      • Products(OUT): O2, ATP, NADPH

Slide 5: Calvin Cycle (Biochemical Reactions)

  • Definition: Light-independent reactions; they do not directly us light.

    • May occur in light or dark, but usually during the day

  • Location: Stroma(Liquid) of chloroplasts.

  • Purpose: Fix CO2 into sugar.

    • Uses ATP + NADPH to make sugar from CO2 + H2O

      • Carbon Fixation: Convert inorganic C to organic C compounds

        • Convert short term chemical energy (ATP, NADPH) to long term chemical energy (Sugar) (Store it as starch and ship it to other cells)

          • Reactants(IN): CO2 + C5 = RuBP, ATP, NADPH

          • Products(OUT): C6 = Glucose, ADP + P, NADP+

Slide 6: Photosynthetic Pigments

  • Types: Chlorophyll a, Chlorophyll b, Carotenoids.

  • Chlorophyll a: essential pigment, part of the reaction center of PSI and PSII

  • Accessory Pigments: absorbs wavelengths of light chlorophyll a can’t, so can use broader range of light for photosynthesis

    • Chlorophyll b, carotenoids, xanthophylls

      • Role: Accessory pigments absorb light wavelengths that chlorophyll a cannot, broadening the range of light used for photosynthesis.

  • Leaves are green due to chlorophyll and accessory pigments, absorbs mainly red and blue wavelengths

    • Other wavelengths (green) are reflected or transmitted

  • Action spectrum: Rate of Photosynthesis vs. Wavelength

    • Photosynthesis uses most wavelengths of light (except green) because of the absorbance of the accessory pigments and chlorophyll a

Slide 7: Light Harvesting Complex

  • Structure: Composed of antenna complexes that absorb light and transfer energy to the reaction center of photosystems.

  • Antenna Complex = Light harvesting complex

    • Chlorophyll a molecules are in the reaction center of the photosystem

    • Accessory pigments are in the antenna complex or light harvesting complex of the photosystem

    • Light is absorbed by accessory pigments in the antenna complex and transferred to the reaction center of the photosystem

      • 2 Types of Reaction Center:

        • PSI : P700

        • PSII: P680

          • PSI = Photosystem I

          • PSII = photosystem II

Slide 8: Electron Transport Chain

  • Process: Involves the transfer of electrons from PSII to PSI, generating a proton gradient used for ATP synthesis and split H2O → O2.

  • Electron transport from PSI to ferredoxin to the sysntesis of NADPH

  • Light reactions: Electrons transport from PSII to PSI

    • Antenna complex absorbs a photon of light and transfers it to the reaction center of photosystem II

  • Absorption of light by PSII; the excited electron of chlorophyll a in p680 is easily donated to another molecule

  • Electron Transport from PSII to PSI

    • After PSII absorbs a photon of light the excited electron is passed down chain until it reaches PSI

      • PSII → plastoquinon (PQ or QB ) → cytochrome complex → plastocyanin (PC) → PSI

        • During Electron Transport H+s are pumped across membrane

    • Electrons from H2O go to PSII H+s from H2O are part of H+ gradient

  • Purpose: Generate a proton Gradient!

    • H+s moved from stroma to thylakoid lumen during elecron transport (cytochrome complex)

  • Water Splitting: Produces O2 and contributes to the proton gradient.

    • 2H2O → O2 + 4H+ + 4e-

      • PSII has lost an electron and can’t absorb another photon of light until the electron is replaced

      • Electrons from water go to fill “hole” in PSII

      • 4H+ contribute to H+ gradient

      • O2 is made as a by product

    • Location: Oxygen evolving complex (OEC), part of PSII

  • Purpose: releases H+s into thylakoid lumen

    • Thylakoid lumen: pH 7 → pH 4

    • Stroma: pH 7 → pH 8

  • H+ gradient will be used by ATP synthase to make ATP

  • Light Reactions: Electron Transport from PSI

    • Antenna Complex absorbs a photon of light and transfers it to the reaction center of photosystem I

  • Absorption of Light by PSI

    • The excited electron of chlorophyll a in P700 is easily donated to another molecule

  • Electron Transport from PSI:

    • After PSi absorbs a photon of light the excited electron is passed down chain until it raches ferredoxin

    • PSI → ferredoxin (Final e- acceptor)

    • Ferredoxin reacts with an enzyme to make NADPH (Redox reaction)

    • Enzyme: Ferredoxin NADP Reductase (FNR)

  • PSII: H2O split to make O2 and H+ Electron transport from PSII to PSI synthesis of NADPH and ATP

Slide 9: ATP Synthesis

  • Electron Transport generates a proton gradient

    • Energy in proton gradient used to make ATP by enzyme ATP Synthase

  • Chemiosomosis: Oxidative Phosphorylation

Slide 10: Calvin Cycle Phases

  • Phase 1: Carbon fixation (CO2 + RuBP(C5) -> 2 PGA(C3)).

    • Enzyme: Rubisco = Ribulose bisphosphate carboxylase oxygenase

      • Carboxylase = add CO2. Oxygenase = Add O2

    • Location: Stroma of chloroplast

  • Carboxylase Activity: Carbon Fixation

    • CO2 + Ribulose bisphosphate (C5) → 2 Phosphoglyceric acid (C3)(Goes to calvin cycle to make sugar)

    • Oxygenase Activity: Photorespiration (BAD!!!)

      • O2 + Ribulose bisphosphate (C5) → Phosphoglyceric acid (C3)(Goes to calvin cycle to make sugar) + Phosphoglycolate (C2) (Cell spends ATP to salvage)

  • Reactants: CO2 , RuBP (C5)

  • Products: 2 PGA (C3)

  • Enzyme: Rubisco = protein = enzyme

  • Phase 2: Sugars are Rearranged and Reduced

    • PGA (C3) → → → G3P (C3)

    • Uses the ATP and NADPH made in the light reacions

  • Phase 3: Regeneration of Ribulose Bisphosphate (RuBP).

Slide 11: Types of Photosynthesis

  • C3 Photosynthesis: Most common, efficient under moderate conditions but prone to photorespiration.

    • Most plants

  • 1st stable compound made: C3 sugar

  • 1st Reaction: CO2 + RuBP C5 → 2 PGA C3

    • 2PGA = Phosphoglycotic acid

  • Enzyme: Rybisco

  • Example: Soybean, Most plants

  • Advantage: Most efficient type of photosynthesis

  • Disadvantage: Photorespiration (BAD! WASTEFUL)

  • C3 Leaf

    • Mesophyll = photosynthetic tissu palisade and spongy mesophyll

  • C4 Photosynthesis: Adapted to hot, dry environments, minimizes photorespiration.

    • Corn, Sugar cane

  • 1st stable compound : C4 OAA (Ocaloacetate)

  • 1st Reaction: CO2 + PEP (C3) → OAA (C4)

  • Enzyme : PEP carboxylase (Adds CO2)

    • PEP: Phosphoenol Pyruvate

    • OAA: Oxaloacetate

  • Advatage: No Photorespiration

  • Disadvantage: Uses more energy to make sugar

    • Need to mkae special structures = the bundle sheath

    • In Mesophyll:

      • CO2 + PEP C3 → OAA C4

      • Enzyme: PEP carboxylase no photorespiration because PEP carboxylase can’t react with O2

      • OAA C4 → Malate C4,Malate shipped to Bundle sheath cells

    • In Bundle sheath

      • Malate C4 → CO2 + Pyruvate C3

      • Calvin Cylce: CO2 + RuBP C5 → 2 PGA C3

        • Enzyme: Rubisco

      • No photorespiration because high CO2 (20-100x) in bundle sheath cells! No photorespiration = no waste!

    • Bundle Sheath Cells: Contain Rubisco, make sugar in the calvin cycle (high CO2 so no photorespiration)

  • CAM Photosynthesis: Opens stomates at night to store CO2 as malate, preventing dehydration and photorespiration.

    • Carries out Calvin Cycle during Day

      • Desert plants, cacti, sedum, “Living stones” (slow growing desert plants)

  • Not all plants are C4 plants due to optimal conditions C3 plants can compete C4 plants (high CO2, wet environment, moderate temperature)

    • C4 plants need an extra 2 ATP to fix C into a C6 sugar

    • C4 plants must expend energy to produce extra enzymes and build bundle sheath cells

  • CAM Photosynthesis: Night

    • Stomates open, CO2 eneters leaf

    • CO2 + PEP C3 → OAA C4

    • Enzyme: PEP carboxylase

    • OAA C4 → Malate C4

    • Malate shipped out of chloroplast stored in central vacuole

  • CAM photosynthesis: Day

    • Stomates close to prevent dehydration

    • Malate shipped from vacuole back to chloroplast

    • Malate C4 → CO2 + pyruvate C3

    • CO2 used in calvin cycle to make sugar

  • CAM Photosynthesis: Results

    • CAM plants carry out photosynthesis during Day with stomates closed

    • No Photorespiration: High CO2 because CO2 was stored as malate overnight

    • No dehydration: Plant keep stomates closed during day to prevent excess water loss

  • C4 vs CAM Photosynthesis

    • Same reactions, different locations or time

    • Initial CO2 fixation: CO2 + PEP (C3) = OAA (C4)

    • Enzyme: PEP Carboxylase

    • CO2 is stored as a C4 sugar. Later C4 broken down to release CO2, to be used in calvin cycle to make glucose

  • Photorespiration:

    • why does it occur? Rubisco reacts with O2 instead of with CO2 in C3 plants

      • Rubisco can use oxygen as a substrate when CO2 levels are low and oxygen levels are high

    • When is it a problem? When hot + Dry

      • When relatively high O2/CO2 ratio

      • When stomates close: high temperature low water (CO2 goes down)

      • When stomates close no new gases enter leaf, use up CO2 make more O2 ( O2 goes up)

    • Advantages: NONE

    • Disadvantages: Breaks down sugar and wastes energy, fixed CO2

    • Oxygenase Activity of Rubisco: O2 + RuBP (C5) → PGA (C3) + Phosphoglycolate (C2) ( Salavage reaction spend energy)

  • Compensation Point:

    • Plants carry out 2 metabolic processes;

      • Photosynthesis: Uses CO2 + H2O to produce O2 + sugar

      • Respiration: Uses O2 + Sugar to produce CO2 + H2O

    • Compensation Point: When amount of O2 made by photosynthesis exactly matchs amount of O2 used by respiration

  • C3 vs C4 Photosynthesis

    • C3 plants out compete C4 plants:

      • Cool/ moderate temeprature, high humidity, low to average light intensity

      • C4 photosynthesis costs more energy to make sugar and other structures

    • C4 plants out compete C3 plants:

      • Hot dry conditions, high light intensity

      • No photorespiration in C4 plants

Slide 12: Environmental Factors

  • Temperature: High rate as temperature increase, up to a point

    • Cool temperature → lower rate

  • Light Intensity: Lower rate at low light intensity (shade) and Higher rate at high light intensity, up to a point

  • Humidity/Water Availability: Rate increases with high humidity/water

Page 13: Summary of Photosynthesis

  • Connection: Photosynthesis and respiration are interconnected processes that utilize and produce gases (O2 and CO2) in plants.

  • Importance: Understanding photosynthesis is crucial for comprehending plant biology, ecology, and the global carbon cycle.

Chapter 8 - Photosynthesis

Photosynthesis Overview

Slide 1: Introduction to Photosynthesis

  • Definition: Photosynthesis is the process that uses solar energy to convert carbon dioxide (CO2) and water (H2O) into sugar and oxygen (O2).

    • General Formula: 6CO2 + 6H2O -> C6H12O6 + 6O2

Slide 2: Energy Transformations

  • Light Reactions: Convert solar energy into short-term chemical energy.(proton Gradient)

    • Products: ATP and NADPH.

  • Calvin Cycle: Converts short-term chemical energy (ATP, NADH) into long-term chemical energy (sugar).

    • Calvin cycle = Biochemical reactions

Slide 3: Chlorophyll

  • Function: A pigment that absorbs light, specifically red and blue wavelengths, and transmits and reflects green light.

    • A pigment is a chemical that absorbs light

Slide 4: Light Reactions

  • Reactions that directly require light

  • Location: Occurs in the thylakoids, in the grana chloroplasts.

  • Thylakoid:Green photosynthetic membrane, contains chlorophyll and other pigments

  • Purpose: Convert solar energy into short term chemical energy (ATP and NADPH).

    • Solar energy

    • Electron transport/Redox reactions

    • Proton Gradient

    • ATP?NADH

      • Reactants(IN): H2O, ADP + P, NADP+

      • Products(OUT): O2, ATP, NADPH

Slide 5: Calvin Cycle (Biochemical Reactions)

  • Definition: Light-independent reactions; they do not directly us light.

    • May occur in light or dark, but usually during the day

  • Location: Stroma(Liquid) of chloroplasts.

  • Purpose: Fix CO2 into sugar.

    • Uses ATP + NADPH to make sugar from CO2 + H2O

      • Carbon Fixation: Convert inorganic C to organic C compounds

        • Convert short term chemical energy (ATP, NADPH) to long term chemical energy (Sugar) (Store it as starch and ship it to other cells)

          • Reactants(IN): CO2 + C5 = RuBP, ATP, NADPH

          • Products(OUT): C6 = Glucose, ADP + P, NADP+

Slide 6: Photosynthetic Pigments

  • Types: Chlorophyll a, Chlorophyll b, Carotenoids.

  • Chlorophyll a: essential pigment, part of the reaction center of PSI and PSII

  • Accessory Pigments: absorbs wavelengths of light chlorophyll a can’t, so can use broader range of light for photosynthesis

    • Chlorophyll b, carotenoids, xanthophylls

      • Role: Accessory pigments absorb light wavelengths that chlorophyll a cannot, broadening the range of light used for photosynthesis.

  • Leaves are green due to chlorophyll and accessory pigments, absorbs mainly red and blue wavelengths

    • Other wavelengths (green) are reflected or transmitted

  • Action spectrum: Rate of Photosynthesis vs. Wavelength

    • Photosynthesis uses most wavelengths of light (except green) because of the absorbance of the accessory pigments and chlorophyll a

Slide 7: Light Harvesting Complex

  • Structure: Composed of antenna complexes that absorb light and transfer energy to the reaction center of photosystems.

  • Antenna Complex = Light harvesting complex

    • Chlorophyll a molecules are in the reaction center of the photosystem

    • Accessory pigments are in the antenna complex or light harvesting complex of the photosystem

    • Light is absorbed by accessory pigments in the antenna complex and transferred to the reaction center of the photosystem

      • 2 Types of Reaction Center:

        • PSI : P700

        • PSII: P680

          • PSI = Photosystem I

          • PSII = photosystem II

Slide 8: Electron Transport Chain

  • Process: Involves the transfer of electrons from PSII to PSI, generating a proton gradient used for ATP synthesis and split H2O → O2.

  • Electron transport from PSI to ferredoxin to the sysntesis of NADPH

  • Light reactions: Electrons transport from PSII to PSI

    • Antenna complex absorbs a photon of light and transfers it to the reaction center of photosystem II

  • Absorption of light by PSII; the excited electron of chlorophyll a in p680 is easily donated to another molecule

  • Electron Transport from PSII to PSI

    • After PSII absorbs a photon of light the excited electron is passed down chain until it reaches PSI

      • PSII → plastoquinon (PQ or QB ) → cytochrome complex → plastocyanin (PC) → PSI

        • During Electron Transport H+s are pumped across membrane

    • Electrons from H2O go to PSII H+s from H2O are part of H+ gradient

  • Purpose: Generate a proton Gradient!

    • H+s moved from stroma to thylakoid lumen during elecron transport (cytochrome complex)

  • Water Splitting: Produces O2 and contributes to the proton gradient.

    • 2H2O → O2 + 4H+ + 4e-

      • PSII has lost an electron and can’t absorb another photon of light until the electron is replaced

      • Electrons from water go to fill “hole” in PSII

      • 4H+ contribute to H+ gradient

      • O2 is made as a by product

    • Location: Oxygen evolving complex (OEC), part of PSII

  • Purpose: releases H+s into thylakoid lumen

    • Thylakoid lumen: pH 7 → pH 4

    • Stroma: pH 7 → pH 8

  • H+ gradient will be used by ATP synthase to make ATP

  • Light Reactions: Electron Transport from PSI

    • Antenna Complex absorbs a photon of light and transfers it to the reaction center of photosystem I

  • Absorption of Light by PSI

    • The excited electron of chlorophyll a in P700 is easily donated to another molecule

  • Electron Transport from PSI:

    • After PSi absorbs a photon of light the excited electron is passed down chain until it raches ferredoxin

    • PSI → ferredoxin (Final e- acceptor)

    • Ferredoxin reacts with an enzyme to make NADPH (Redox reaction)

    • Enzyme: Ferredoxin NADP Reductase (FNR)

  • PSII: H2O split to make O2 and H+ Electron transport from PSII to PSI synthesis of NADPH and ATP

Slide 9: ATP Synthesis

  • Electron Transport generates a proton gradient

    • Energy in proton gradient used to make ATP by enzyme ATP Synthase

  • Chemiosomosis: Oxidative Phosphorylation

Slide 10: Calvin Cycle Phases

  • Phase 1: Carbon fixation (CO2 + RuBP(C5) -> 2 PGA(C3)).

    • Enzyme: Rubisco = Ribulose bisphosphate carboxylase oxygenase

      • Carboxylase = add CO2. Oxygenase = Add O2

    • Location: Stroma of chloroplast

  • Carboxylase Activity: Carbon Fixation

    • CO2 + Ribulose bisphosphate (C5) → 2 Phosphoglyceric acid (C3)(Goes to calvin cycle to make sugar)

    • Oxygenase Activity: Photorespiration (BAD!!!)

      • O2 + Ribulose bisphosphate (C5) → Phosphoglyceric acid (C3)(Goes to calvin cycle to make sugar) + Phosphoglycolate (C2) (Cell spends ATP to salvage)

  • Reactants: CO2 , RuBP (C5)

  • Products: 2 PGA (C3)

  • Enzyme: Rubisco = protein = enzyme

  • Phase 2: Sugars are Rearranged and Reduced

    • PGA (C3) → → → G3P (C3)

    • Uses the ATP and NADPH made in the light reacions

  • Phase 3: Regeneration of Ribulose Bisphosphate (RuBP).

Slide 11: Types of Photosynthesis

  • C3 Photosynthesis: Most common, efficient under moderate conditions but prone to photorespiration.

    • Most plants

  • 1st stable compound made: C3 sugar

  • 1st Reaction: CO2 + RuBP C5 → 2 PGA C3

    • 2PGA = Phosphoglycotic acid

  • Enzyme: Rybisco

  • Example: Soybean, Most plants

  • Advantage: Most efficient type of photosynthesis

  • Disadvantage: Photorespiration (BAD! WASTEFUL)

  • C3 Leaf

    • Mesophyll = photosynthetic tissu palisade and spongy mesophyll

  • C4 Photosynthesis: Adapted to hot, dry environments, minimizes photorespiration.

    • Corn, Sugar cane

  • 1st stable compound : C4 OAA (Ocaloacetate)

  • 1st Reaction: CO2 + PEP (C3) → OAA (C4)

  • Enzyme : PEP carboxylase (Adds CO2)

    • PEP: Phosphoenol Pyruvate

    • OAA: Oxaloacetate

  • Advatage: No Photorespiration

  • Disadvantage: Uses more energy to make sugar

    • Need to mkae special structures = the bundle sheath

    • In Mesophyll:

      • CO2 + PEP C3 → OAA C4

      • Enzyme: PEP carboxylase no photorespiration because PEP carboxylase can’t react with O2

      • OAA C4 → Malate C4,Malate shipped to Bundle sheath cells

    • In Bundle sheath

      • Malate C4 → CO2 + Pyruvate C3

      • Calvin Cylce: CO2 + RuBP C5 → 2 PGA C3

        • Enzyme: Rubisco

      • No photorespiration because high CO2 (20-100x) in bundle sheath cells! No photorespiration = no waste!

    • Bundle Sheath Cells: Contain Rubisco, make sugar in the calvin cycle (high CO2 so no photorespiration)

  • CAM Photosynthesis: Opens stomates at night to store CO2 as malate, preventing dehydration and photorespiration.

    • Carries out Calvin Cycle during Day

      • Desert plants, cacti, sedum, “Living stones” (slow growing desert plants)

  • Not all plants are C4 plants due to optimal conditions C3 plants can compete C4 plants (high CO2, wet environment, moderate temperature)

    • C4 plants need an extra 2 ATP to fix C into a C6 sugar

    • C4 plants must expend energy to produce extra enzymes and build bundle sheath cells

  • CAM Photosynthesis: Night

    • Stomates open, CO2 eneters leaf

    • CO2 + PEP C3 → OAA C4

    • Enzyme: PEP carboxylase

    • OAA C4 → Malate C4

    • Malate shipped out of chloroplast stored in central vacuole

  • CAM photosynthesis: Day

    • Stomates close to prevent dehydration

    • Malate shipped from vacuole back to chloroplast

    • Malate C4 → CO2 + pyruvate C3

    • CO2 used in calvin cycle to make sugar

  • CAM Photosynthesis: Results

    • CAM plants carry out photosynthesis during Day with stomates closed

    • No Photorespiration: High CO2 because CO2 was stored as malate overnight

    • No dehydration: Plant keep stomates closed during day to prevent excess water loss

  • C4 vs CAM Photosynthesis

    • Same reactions, different locations or time

    • Initial CO2 fixation: CO2 + PEP (C3) = OAA (C4)

    • Enzyme: PEP Carboxylase

    • CO2 is stored as a C4 sugar. Later C4 broken down to release CO2, to be used in calvin cycle to make glucose

  • Photorespiration:

    • why does it occur? Rubisco reacts with O2 instead of with CO2 in C3 plants

      • Rubisco can use oxygen as a substrate when CO2 levels are low and oxygen levels are high

    • When is it a problem? When hot + Dry

      • When relatively high O2/CO2 ratio

      • When stomates close: high temperature low water (CO2 goes down)

      • When stomates close no new gases enter leaf, use up CO2 make more O2 ( O2 goes up)

    • Advantages: NONE

    • Disadvantages: Breaks down sugar and wastes energy, fixed CO2

    • Oxygenase Activity of Rubisco: O2 + RuBP (C5) → PGA (C3) + Phosphoglycolate (C2) ( Salavage reaction spend energy)

  • Compensation Point:

    • Plants carry out 2 metabolic processes;

      • Photosynthesis: Uses CO2 + H2O to produce O2 + sugar

      • Respiration: Uses O2 + Sugar to produce CO2 + H2O

    • Compensation Point: When amount of O2 made by photosynthesis exactly matchs amount of O2 used by respiration

  • C3 vs C4 Photosynthesis

    • C3 plants out compete C4 plants:

      • Cool/ moderate temeprature, high humidity, low to average light intensity

      • C4 photosynthesis costs more energy to make sugar and other structures

    • C4 plants out compete C3 plants:

      • Hot dry conditions, high light intensity

      • No photorespiration in C4 plants

Slide 12: Environmental Factors

  • Temperature: High rate as temperature increase, up to a point

    • Cool temperature → lower rate

  • Light Intensity: Lower rate at low light intensity (shade) and Higher rate at high light intensity, up to a point

  • Humidity/Water Availability: Rate increases with high humidity/water

Page 13: Summary of Photosynthesis

  • Connection: Photosynthesis and respiration are interconnected processes that utilize and produce gases (O2 and CO2) in plants.

  • Importance: Understanding photosynthesis is crucial for comprehending plant biology, ecology, and the global carbon cycle.

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