The Sun

1. The Sun

2. The Visible Spectrum of Light • Photosynthesis usesonly small visible portion of the electromagneticspectrum • Wavelengths of visible light most important forphotosynthesis. • The symbol for wavelength is λ

3. Fig. 8.3

4. How Electrons Capture Energy • Electrons can absorb radiant energy. • Radiant energy comes in parcels called photons • When electrons absorb energy, they hop to a higher shell. • When electrons release energy, drop back to the lower shell. • The energy released is a kind of light energy called fluorescence.

5. Absorption of Light Energy • Light energy is absorbed by electrons • The energy causes electrons to jump shells; the more energy absorbed, the further away electrons move from the nucleus • The energy may be shed as fluorescence • Or transferred in the form of an electron to another molecule

6. Leaf Pigments Absorb Light Energy • Leaf Pigments absorb light energy • Chlorophylls a and b • Carotenoids

7. Chlorophylls are Leaf Pigments • Chlorophylls collect light energy (absorbs it) in a resonant porphyrin group that hangs out like a kite on the surface of the thylakoid • Chlorophyll a initiates the light-dependent reactions • Chlorophyll b is an accessory pigment • Carotenoids are yellow and orange pigments that capture light energy and pass electrons to chlorophyll

8. The Structure of Chlorophyll • Note the double bonds and the Mg2+ ion • The positive charges on the Mg2+ ion attract electrons • The electrons bounce around the porphyrin ring

9. Photosynthesis 6CO2 + 12H2O + light energy → C6H12O6 + 6O2

10. Leaf Structure • Leaves have a layered organization • The mesophyll tissue (middle layers of cells) is the main site of photosynthesis • Sap flows through the veins

11. Internal Structure of a Leaf

12. The Chloroplast • The site of light harvesting or energy capture • The site of the start of carbohydrate synthesis

13. Photosynthesis in the Chloroplast • The light-dependent reactions (the harvesting of light) occur on thylakoid membranes • The carbon fixation reactions (formation of carbohydrate) occur in the stroma

15. 6 CO + 12H O C H O + 6O 6 12 6 2 Photosynthesis 6CO2 + 12H2O + light energy → C6H12O6 + 6O2 • Carbon dioxide is reduced to sugar • Water is converted to oxygen 2 2

16. Three Energy Carriers of Photosynthesis • NADH • NADPH: • Much like NADH except that it bears a phosphate • Phosphate is attached to the sugar group • ATP

17. Light-Dependant Reactions Cyclic photophosphorylation Non-cyclic photophosphorylation Light-Independent reactions Calvin cycle (C3) Two Major Steps in Photosynthesis

18. Understand this slide!

19. The Light Dependant Reactions • Water molecules are split apart, producing electrons and hydrogen ions, and O2 gas is released. • Electrons from the split water are passed along an electron transport chain • Energy storing ATP molecules are produced • Hydrogen from the split water is transferred from • NADP  NADPH and used in the light independent reactions

20. Capturing Light Energy • Photons are absorbed by chlorophyll • Energy (as an electron) “falls” from one chlorophyll to the next.

21. Two Different ways to Photosynthesize in the Light-Dependant Reactions 1. Cyclic photophosphorylation • e- run in a cycle • makes ATP • No carbohydrate made • Uses only P700 2. Noncyclic photophosphorylation • e- derived from splitting of water • Releases O2 • Makes lots of ATP • Makes carbohydrate • Uses P700 and P680

22. Cyclic Photophosphorylation • Photosystem I • P700 reaction center • Energized e- hops to an e- acceptor protein • e- “falls” from protein complex to protein complex, losing energy as it cascades down

23. Cyclic Photophosphorylation • Does not produce any carbohydrate • But still makes some ATP • Found in certain primitive plants • Found also in bacteria • Also seen in plants that have sufficient carbohydrate but need ATP:

24. Noncyclic Photophosphorylation • Plants that need a lot of energy must make a large quantities of carbohydrate. • They use noncyclic photophosphorylation • Both PII (P680) and PI (P700) are used. • The 680/700 designations indicate the peak wavelengths absorbed by each chlorophyll reaction center

25. Steps of Non-cyclic Photophosporylation • Photosystem II (P680) uses light energy to split a water molecule– rips it apart into electrons, protons and oxygen • e- cascades from protein complex to protein complex losing energy. • The e- gets re-energized by photosystem I (P700) and “falls” down another cascade of protein complexes. • The energy from the e- cascades is used to pump H+ from the split water molecule into the intermembrane space of the thylakoid. • The H+ from the water ultimately is used to make ATP and NADPH

26. Noncyclic Photophosphorylation

27. Non-cyclic Photophosphorylation

28. The Electron Transport Chain

29. The Chloroplast ATP Synthase • The H+ forms a proton gradient. • The H+ moves from [H]→ [L] • H+ are transported through the ATP synthase • Makes ATP by combining ADP and phosphate • The H+ that have been pumped into the stroma are used to make NADPH

31. The Light Independent Reactions • So-called because they do not directly need light (radiant energy) • They occur in the stroma of the chloroplast • They fix carbon to make carbohydrate • Named theCalvin Cycle

32. The Light Independent Reactions • CO2 is combined with RuBP to yield a 6C sugar • Enzyme RuBP carboxylase • 6C sugar is broken into TWO 3C sugars • NADPH and ATP supply the energy for the conversion • Most of the 3C sugar gets recycled into the Calvin cycle • The remainder gets converted into sucrose Takes place in the stroma of the chloroplast

33. RuBisCO • Ribulose bisphosphate carboxylase/oxygenase • Most abundant enzyme in the whole world • Carbon fixation enzyme

34. Fig. 8.13

35. The PCR (Calvin) Cycle: • CO2 uptake • Catalyzed by the enzyme RUBISCO; ribulose bisphosphate carboxylase • ATP and NADPH from the light-dependant reactions are used as energy sources to rearrange the 3-C sugars

36. Most of the 3-C sugars are sent to the cytoplasm to make glucose • The remaining 3-C sugars are recycled back into the Calvin cycle to regenerate RUBP

37. The PCRCycle is very expensive in terms of Energy • CO2 is the carbon source • For each glucose to be formed, 18 ATP and 12 NADPH are used!