Photosynthesis

1. Photosynthesis Campbell and Reece Chapter 10

2. Autotrophs • “self-feeders” • sustain themselves w/out eating anything derived from other living things • are the biosphere’s producers • photoautotrophs: plants, algae, some protists, & some prokaryotes

3. Heterotrophs • live on cpds produced by other organisms • are the biosphere’s consumers • Includes: carnivores, omnivores, decomposers

4. Origin of Photosynthesis • Photosynthesis most likely originated in prokaryotes that had infolded regions of plasma membrane containing clusters of that included photosystems and photosynthetic enzymes

5. Chloroplasts • All green parts of plants have chloroplasts but leaves are major sites of photosynthesis in most plants • 1 mm² of top of a leaf contains .5 million chloroplasts!

6. Parts of a Leaf

7. Parts of a Leaf • Mesophyll:leaf cells specialized for photosynthesis • Stomata:microscopic pore surrounded by guard cells in epidermis of leaf & stems, allows gas exchange • Veins: vascular bundle in a leaf

8. Chloroplast Structure • ~2-4 μm by 4-7 μm • dbl membrane surrounding dense fluid called the stroma • membrane w/in stroma made of sacs called thylakoids • inside thylakoid: thylakoid space • Chlorophyll & photosystems reside in thylakoid membrane

9. Chloroplast Structure

10. Photosynthesis Equation • equation worked out in 19th century • use glucose as product to simplify relationship with respiration but what actually happens….

11. Photosynthesis Equation • direct product is 3-C sugar that can be used to make glucose • light • CO2 + H2O  [CH2O] + O2

12. Photosynthesis Equation • [CH2O] brackets mean what is inside is not actual sugar but represents general formula for carbohydrate (building a carbohydrate 1 carbon at a time)

13. Photosynthesis Equation • originally, it was thought the O2 released came from CO2 • assumption challenged in 1930’s (van Niel, Stanford University) • Studied bacteria that use CO2 to make carbohydrates but do not release O2 • Concluded that at least in the bacteria he studied CO2 was not split

14. Photosynthesis Equation • Another group bacteria use H2S (hydrogen sulfide) instead of water releasing S: • CO2 + 2H2S  [CH2O] + H2O + 2S • vanNiel concluded the H2S split & H was used with C to build sugars & inferred water must split in photosynthesis with H to sugars & O released

15. Photosynthesis Equation • Van Niel’s hypothesis confirmed in 1950’s when O-18 used in water and traced thru photosynthesis

16. Photosynthesis as Redox Reactions • photosynthesis equation: C becomes reduced & O oxidized

17. Summary of Photosynthesis

18. Photosynthesis Vocabulary • Photophosphorylation: process of generating ATP from ADP + P by means of chemiosmosis using a proton-motive force generated across the thylakoid membrane • Carbon Fixation: incorporation of C from CO2 into an organic cpd by an autotroph

20. Light Reactions

21. Light • Form of electromagnetic energy or radiation • 380 nm – 750 nm = visible light • Photon: discrete particle of energy • Amt nrg inversely proportional to wavelength

22. Electromagnetic Spectrum

23. Photosynthesis Pigments • pigment substance that absorbs light • different pigments absorb different wavelengths • we see color that is reflected (not absorbed) • Chlorophyll absorbs violet-blue & red

24. Spectrophotometer • Measures the proportion of light of different wavelengths absorbed & transmitted by a pigment solution

25. Absorption Spectrum • graph plotting a pigment’s light absorption versus wavelength

26. Chlorophyll’s Absorption Spectrum • gives clues to relative effectiveness of different wavelengths for driving photosynthesis (light can perform work in chloroplasts only if it is absorbed)

27. Pigments in Photosynthesis • chlorophyll a • Violet-blue & red light works best • appear blue green • chlorophyll b • violet blue • appear olive green • carotenoids • violet & blue-green • appear various shades yellow & orange

28. Chlorophyll a/b

29. Rate of Photosynthesis vs. Wavelength of Light

30. Carotenoids • absorb wavelengths that chlorophylls do not • more importantly they function as photoprotection: they absorb & dissipate light nrg that would otherwise damage chlorophyll or would interact with O2 yielding reactive oxidative products that would damage cell (act as antioxidants)

31. Phytochemicals • carotenoids in health food products • promoted as antioxidants

32. What Happens When Chlorophyll Absorbs Light ? • colors from corresponding wavelengths that are absorbed disappear from the spectrum of transmitted & reflected light • butnrg cannot disappear

33. What Happens When Chlorophyll Absorbs Light? • nrg from photon absorbed by e- in pigment (more nrg .. e- moves to orbital further out from nucleus where it has more PE & less stability) • ground state: when e- in normal orbital • excited state: e- in orbital of higher nrg

34. Which Photons are Absorbed? • only those photons whose wavelength’s nrg is exactly = to the nrg difference between the ground & excited states • explains why each pigment has unique absorption spectrum

35. Electrons in the Excited State • unstable when excited • if isolated: chlorophyll molecules absorb photons the e- immediately drop back to ground state releasing nrg as heat or light (fluorescence) & heat

36. Excitation of Isolated Chlorophyll Molecule

37. Photosystems • chlorophyll molecules in native state found in thylakoid membrane organized into complexes called photosystems

38. Photosystem • composed of: • Reaction-Center Complex surrounded by: • Light-Harvesting Complex • consists of various pigments bound to proteins: • chlorophyll a • chlorophyll b • carotenoids

39. Photosystems • Light-Harvesting Complex acts like “antennae” for the Reaction-Center Complex

40. Reaction-Center Complex • contains molecule (the primary e- acceptor) capable of accepting e- & becoming reduced

41. 1st Step of Light Reactions • solar-powered transfer of e- from reaction-center chlorophyll a  primary e- acceptor • redox reaction

42. 2 Types of Photosystems • PS II • It’s reaction-center complex known as P680 • 680 wavelength in red part of spectrum • PS I • It’s reaction-center complex known as P700 • 700 wavelength far red part of spectrum

43. P680 & P700 both Chlorophyll a

44. Linear Electron Flow

45. Linear e- Flow Figure 10.14 • 1. photon strikes PS II chlorophyll a & 1 e- jumps to higher nrg level -> this e- falls back to its ground state transferring its nrg to nearby chlorophyll molecule so 1 of its e- jump to excited state …..continues like this until it reaches P680 pair of chlorophyll a molecules in reaction-center & a pair of e- jumps to excited state

46. Linear Electron Flow: Figure 10.14

47. Linear Electron Flow:Figure 10.14 Step 2: e- transferred from excited P680  primary e- acceptor making P680  P680+

48. Linear Electron Flow: Figure 10.14

49. Linear Electron Flow:Figure 10.14 Step 3: enzyme splits 2water  4 e- + 4 H+ + O2 2 e- replace those that left P680 so P680+ returns to P680 one of strongest biological oxidizing agents H+ released into thylakoid space O2 diffuses out of chloroplast  out of cell

50. Linear Electron Flow: Figure 10.14