BMS208%20Human%20Nutrition - PowerPoint PPT Presentation
Title: BMS208%20Human%20Nutrition
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BMS208 Human Nutrition
- Topic 4 Photosynthesis
- Chris Blanchard
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Learning Objectives
- Outline the basic processes involved in
photosynthesis - conversion of energy into food
- Distinguish the two-part process
- light reactions (ATP and NADPH)
- dark reactions (Calvin cycle)
- Distinguish between C3 and C4 plants in terms of
- biochemistry metabolic modifications
- botany leaf structure
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The importance of photosynthesis
- Primary source of organic food and food energy
(ATP) for all forms of life, either directly or
indirectly. - Helps to maintain balance of oxygen and carbon
dioxide in the ecosystem. - Oxygenic photosynthesis was responsible for
converting the totally anaerobic condition on
earth into the aerobic atmosphere present now. - The fossil fuels (e.g. natural gas, coal,
petroleum (oil), etc.) are all energy-rich
materials of an organic origin. The energy stored
in all these fuels is basically solar energy
which was trapped and stored during
photosynthesis in the geological past
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The location of photosynthesis
- The leaf is the primary site of photosynthesis in
plants - Carried out in organelles called chloroplasts
- Efficiency of energy conversion is about 90
compared to 30 in a solar panel
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Chloroplasts
- Photosynthesis takes place in chloroplasts
- Structurally, they are similar to mitochondria
- Embedded in the thylakoid membranes are the
photosynthetic pigments and the enzyme complexes
which carry out the light reactions - Chlorophylls harvest and concentrate the energy
from sunlight
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Nelson and Cox Fig 19.38
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The Photosynthesis process
- Energy from the Sun (light photo) used in the
synthesis of energy rich compounds (eg glucose) - The process is summarised in the equation
Light
6 CO2 6 H2O ? C6H12O6 6 O2
Chlorophyll
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Light and dark reactions
- Light reactions
- photophosphorylation
- absorption of light gt ATP, NADPH O2
- Dark reactions
- NADPH and ATP are used to make carbohydrates
- Calvin cycle
- Carbon dioxide fixation
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Light reactions
- Chlorophylls (chlorophyll a and b)
- harvest and concentrate the energy from
sunlight - Membrane-bound protein-chlorophyll complexes form
photosystems. - In photosystem I P700 absorbs at l lt 700nm
- In photosystem II P680 absorbs at l lt 680nm
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Light reactions
- Photosystem I
- generates reducing power in the form of NADPH
- Photosystem II
- H2O split to produce H and O2
- Synthesis of ATP
- Electron flow within/between each photosystem
- Similar to oxidative phosphorylation
- Summary reactions
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Dark reactions (C3 plants)
- Calvin cycle
- Reduction of CO2 in presence of ATP NADPH
- Ribulose-1,5-bisphosphate CO2
- Yields 2 mols of 3-phosphoglycerate (3-PG)
- In summary
- C5 ? C6 ? C3 C3
- CO2 H2O
- Hexose sugar formation
- 3-PG gt C6H12O6 via gluconeogenesis
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Dark reactions (C3 plants)
- Calvin Cycle or C3 cycle
Source Mathews, van Holde Ahern, 2000,
Biochemistry 3rd ed
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C3 vs C4 Plants
- The C6 carbohydrate synthesised in plants can be
achieved by two processes - Calvin Cycle (C3 synthesis)
- Hatch-Slack Pathway (C4 synthesis)
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C3 Plants and Photorespiration
- Most plants fix CO2 by the C3 pathway
- Temperate climate conditions
- CO2 fixation hampered by photorespiration
- O2 reacts with ribulose-1,5-bisphosphate in the
place of CO2 - Reaction makes photosynthesis 30-50 less
efficient - Photorespiration is stimulated by
- Light
- Heat
- Unfavourable for plants growing in hot climate
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C4 Plants
- Alternative pathway for plants in hot (tropical)
regions known as the C4 pathway (or Hatch-Slack
pathway) - Utilise high light intensity even when CO2 is low
- Plants grow rapidly
- Higher yield per unit area than C3 plants.
- eg sugar cane and maize
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Hatch-Slack Pathway
- Photorespiration countered by CO2 reaction with
PEP gt store of fixed CO2 not normally available
Source Stryer, 2002, Biochemistry, 5th ed
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C3 vs C4 Plant Leaf Structure
- Mesophyll and bundle sheath cell linked in C4
plants
Source Mathews, van Holde Ahern, 2000,
Biochemistry 3rd ed
