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PHOTOSYNTHESIS

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Steps of Calvin Cycle starting material-ribulose bisphosphate ... algae & certain bacteria use light energy to convert CO2 + water glucose all life on Earth, ... – PowerPoint PPT presentation

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Title: PHOTOSYNTHESIS


1
PHOTOSYNTHESIS
2
Photosynthesis
  • process by which green plants some organisms
  • seaweed, algae certain bacteria
  • use light energy to convert CO2 water ?glucose
  • all life on Earth, directly or indirectly,
    depends on photosynthesis as source of food,
    energy O2

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Autotrophs
  • self feeders
  • organisms that make their own organic matter from
    inorganic matter
  • producers
  • use inorganic molecules such as CO2, H2O
    minerals to make organic molecules

5
Heterotrophs
  • consumers
  • other feeders
  • depend on glucose as energy source
  • cannot produce it
  • obtained by eating plants or animals that have
    eaten plants

6
Carbon and Energy Flow
Heat energy
CO2 H2O
Light energy
Photosynthesis
Carbs Proteins Lipids O2
Cellular (Aerobic) Respiration (ATP Produced)
7
Food Chain
  • byproduct of photosynthesis is O2
  • humans other animals breathe in oxygen
  • used in cellular respiration

8
Other Benefits of Photosynthesis
  • humans also dependent on ancient products of
    photosynthesis
  • fossil fuels
  • natural gas, coal petroleum
  • needed for modern industrial energy
  • complex mix of hydrocarbons
  • represent remains of organisms that relied on
    photosynthesis millions of years ago

9
Photosynthesis
  • plants produce more glucose than can use
  • stored as starch other carbohydrates in roots,
    stems leaves
  • can draw on these reserves for extra energy or
    building materials as needed

10
Sites of Photosynthesis
  • leaves green stems
  • in cell organelles
  • chloroplasts
  • concentrated in green tissue in interior of leaf
  • mesophyll
  • green due to presence of green pigment chlorophyll

11
Chloroplasts
  • each cell has 40-50 chloroplasts
  • oval-shaped structures with double membrane
  • inner membrane encloses compartment filled with
    stroma
  • suspended in stroma are disk-shaped
    compartments-thylakoids
  • arranged vertically like stack of plates
  • one stack-granum (plural, grana)
  • embedded in membranes of thylakoids are hundreds
    of chlorophyll molecules

12
Chlorophyll
  • light-trapping pigment
  • other light-trapping pigments, enzymes other
    molecules needed for photosynthesis are also
    found in thylakoid membranes

13
How Photosynthesis Works
  • Requires
  • CO2
  • Water
  • Sunlight
  • Makes
  • O2
  • Glucose

14
How Photosynthesis Works
  • CO2 enters plant via pores- stomata in leaves
  • water-absorbed by roots from soil
  • membranes in chloroplasts provide sites for
    reactions of photosynthesis
  • chlorophyll molecules in thylakoids capture
    energy from sunlight
  • chloroplasts rearrange atoms of inorganic
    molecules into sugars other organic molecules

15
Photosynthesis
  • redox reaction
  • 6CO2 12H2O?C6H12O6 6O2 6H2O in presence of
    light
  • must be an oxidation a reduction
  • water is oxidized
  • loses electrons hydrogen ions
  • carbon dioxide is reduced
  • gains electrons hydrogens

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Photosynthesis
  • 2 stages
  • light-dependent reactions
  • chloroplasts trap light energy
  • convert it to chemical energy
  • contained in nicotinamide adenine dinucleotide
    phosphate-(NADPH) ATP
  • used in second stage
  • light-independent reactions
  • Calvin cycle
  • formerly called dark reactions
  • NADPH (electron carrier) provides hydrogens to
    form glucose
  • ATP provides energy

18
Light Energy for Photosynthesis
  • sun energy is radiation
  • electromagnetic energy
  • travels as waves
  • distance between 2 waves- wavelength
  • light contains many colors
  • each has defined range of wavelengths measured in
    nanometers
  • range of wavelengths is electromagnetic spectrum
  • part can be seen by humans
  • visible light

19
Pigments
  • light absorbing molecules
  • built into thylakoid membranes
  • absorb some wavelengths reflect others
  • plants appear green because chlorophyll-does not
    absorb green light
  • reflected back.
  • as light is absorbed?energy is absorbed
  • chloroplasts contain several kinds of pigments
  • different pigments absorb different wavelengths
    of light
  • red blue wavelengths are most effective in
    photosynthesis
  • other pigments are accessory pigments
  • absorb different wavelengths
  • enhance light-absorbing capacity of a leaf by
    capturing a broader spectrum of blue red
    wavelengths along with yellow and orange
    wavelengths

20
Pigment Color Maximum Absoption
  • Violet   400 - 420 nm
  • Indigo   420 - 440 nm
  • Blue   440 - 490 nm
  • Green   490 - 570 nm
  • Yellow   570 - 585 nm
  • Orange   585 - 620 nm
  • Red   620 - 780 nm

21
Chlorophylls
  • Chlorophyll A
  • absorbs blue-violet red light
  • reflects green
  • participates in light reactions
  • Chlorophyll B
  • absorbs blue orange light
  • reflects yellow-green
  • does not directly participate in light reactions
  • broadens range of light plant can use by sending
    its absorbed energy to chlorophyll A

22
Carotenoids
  • yellow-orange pigments
  • absorb blue-green wavelengths
  • reflect yellow-orange
  • pass absorbed energy to chlorophyll A
  • have protective function
  • absorb dissipate excessive light energy that
    would damage chlorophylls

23
Photosynthesis
  • Pigments
  • Absorb light
  • Excites electrons
  • Energy passed to sites in cell
  • Energy used to make glucose

24
Photosystems
  • chlorophyll other pigments clustered next to
    one another in a photosystem
  • when photon strikes one pigment molecule
  • energy jumps from pigment to pigment until
    arrives at reaction center

25
Reaction Center
  • electron acceptor traps a light excited electron
    from reaction center chlorophyll
  • passes it to electron transport chain which uses
    energy to make ATP NADPH

26
Photosystems
  • two photosystems participate in light reactions
  • photosystems II I

27
Light Reactions
  • make ATP NADPH
  • electrons are removed from molecules of water
  • oxygen escapes to air
  • electrons are passed from photosystem II to
    photosystem I to NADP
  • light drives electrons from H2O to NADP which is
    oxidized? NADPH which is reduced

28
Photosystem II
  • water is split
  • oxygen atom combines with oxygen from another
    split water forming molecular oxygen-O2
  • each excited electron passes from photosystem II
    to photosystem I via electron transport chain

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Photosystem I
  • electron acceptor captures an excited electron
  • excited electrons are passed through a short
    electron transport chain to NADP reducing it to
    NADPH
  • NADP -final electron acceptor
  • electrons are stored in high state of potential
    energy in NADPH molecule
  • NADPH, ATP and O2 are products of light
    reactions

31
ATP Formation-Chemiosmosis
  • uses potential energy of hydrogen ion
    concentration gradient across membrane
  • gradient forms when electron transport chain
    pumps hydrogen ions across thylakoid membrane as
    it passes electrons down chain that connects two
    photosystems

32
ATP Formation-Chemiosmosis
  • ATP synthase (enzyme) uses energy stored by H
    gradient to make ATP
  • ATP is produced from ADP Pi when hydrogen ions
    pass out of thylakoid through ATP synthase
  • photophosphorylation

33
Calvin Cycle/Dark Reactions
  • light independent reactions
  • depend on light indirectly for inputs-ATP NADPH
  • occurs-stroma of chloroplast
  • each step controlled by different enzyme
  • cycle of reactions
  • makes sugar from CO2 energy
  • ATP provides chemical energy
  • NADPH provides high energy electrons for
    reduction of CO2 to sugar

34
Steps of Calvin Cycle
  • starting material-ribulose bisphosphate (RuBP)
  • first step-carbon fixation
  • rubisco (an enzyme) attaches CO2 to RuBP
  • Next-reduction reaction takes place
  • to do this cycle uses carbons from 3 CO2
    molecules
  • to complete cycle must regenerate beginning
    component-RuBP
  • for every 3 molecules of CO2 fixed, one G3P
    molecule leaves cycle as product of cycle
  • remaining 5 G3P molecules are rearranged using
    ATP to make 3 RuBP molecules

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Calvin Cycle
  • regenerated RuBP is used to start Calvin cycle
    again
  • process occurs repeatedly in each chloroplast as
    long as CO2, ATP NADPH are available
  • thousands of glucose molecules are produced
  • used by plants to produce energy in aerobic
    respiration
  • used as structural materials
  • stored
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