1. PHOTOSYNTHESIS AND PLANT HORMONES

2. Plant Structure ●Obtaining raw materials o sunlight  leaves = solar collectors o CO 2  stomates = gas exchange ●Found under leaves o H 2 O  uptake from roots o Nutrients  N, P, K, S, Mg, Fe…  uptake from roots

3. Plant Structure ●Chloroplasts o double membrane o stroma o thylakoid sacs o grana stacks ●Chlorophyll & ETC in thylakoid membrane ●H + gradient built up within thylakoid sac

4. Pigments ●chlorophyll & accessory pigments ●“photosystem” o embedded in thylakoid membrane ●structure function

5. Light: Absorption Spectrum ●Photosynthesis gets energy by absorbing wavelengths of light o chlorophyll a (dominant pigment)  absorbs best in red & blue wavelengths & least in green o other pigments with different structures absorb light of different wavelengths

6. Photosynthesis ●Light reactions (light-dependent reactions) o energy production reactions o convert solar energy to chemical energy o ATP & NADPH ●Calvin cycle (light-independent reactions) o sugar production reactions o uses chemical energy (ATP & NADPH) to reduce CO 2 & synthesize C 6 H 12 O 6

7. Light Reactions ●Electron Transport Chain (like cell respiration!) o membrane-bound proteins in organelle o electron acceptor  NADPH o proton (H + )  gradient across  inner membrane o ATP synthase  enzyme

8. Photosystems ●act as light-gathering “antenna complex” ●Photosystem II o chlorophyll a o P 680 = absorbs 680nm o wavelength red light ●Photosystem I o chlorophyll b o P 700 = absorbs 700nm o wavelength red light

9. ETC of Photosynthesis ●ETC produces from light energy o ATP & NADPH  NADPH (stored energy) goes to Calvin cycle o PS II absorbs light  excited electron passes from chlorophyll to “primary electron acceptor” at the REACTION CENTER. ●splits H 2 O (Photolysis!!) ●O 2 released to atmosphere ●ATP is produced for later use

10. Noncyclic Photophosphorylation ●Light reactions elevate electrons in 2 steps (PS II & PS I) o PS II generates energy as ATP o PS I generates reducing power as NADPH

11. Cyclic Photophosphorylation ●If PS I can’t pass electron to NADP, it cycles back to PS II & makes more ATP, but no NADPH o coordinates light reactions to Calvin cycle o Calvin cycle uses more ATP than NADPH

13. Light Reactions to Calvin Cycle ●Calvin cycle o Chloroplast stroma o Need products of light reactions to drive synthesis reactions  ATP  NADPH

14. Calvin Cycle

15. Factors that Affect Photosynthesis ●Enzymes are responsible for several photosynthetic processes, therefore, temperature and pH can affect the rate of photosynthesis. ●The amount and type of light can affect the rate. ● A shortage of any of the reactants,CO 2 and/or H 2 O, can affect the rate.

16. Alternative Mechanisms ●Photorespiration ●žMetabolic pathway which:  Uses O 2 & produces CO 2  Uses ATP  No sugar production (rubisco binds O 2 à breakdown of RuBP)  žOccurs on hot, dry bright days when stomata close (conserve H 2 O)  žWhy? Early atmosphere: low O 2, high CO 2 ?

17. Evolutionary Adaptations ●Problem with C 3 Plants: o CO 2 fixed to 3-C compound in Calvin cycle o Ex. Rice, wheat, soybeans o Hot, dry days: partially close stomata, ↓CO 2 o –Photorespiration o ↓ photosynthetic output (no sugars made)

18. Evolutionary Adaptations ●C 4 Plants: o CO 2 fixed to 4-C compound o Ex. corn, sugarcane, grass o Hot, dry days à stomata close o –2 cell types = mesophyll & bundle sheath cells  –mesophyll : PEP carboxylase fixes CO 2 (4-C), pump CO 2 to bundle sheath  –bundle sheath: CO 2 used in Calvin cycle o ↓photorespiration, ↑sugar production o WHY? Advantage in hot, sunny areas

19. Evolutionary Adaptations ●CAM Plants: o Crassulacean acid metabolism (CAM)  NIGHT: stomata open à CO 2 enters à converts to organic acid, stored in mesophyll cells  DAY: stomata closed à light reactions supply ATP, NADPH; CO 2 released from organic acids for Calvin cycle o Ex. cacti, pineapples, succulent (H 2 O-storing) plants o WHY? Advantage in arid conditions

21. Supporting a Biosphere ●On global scale, photosynthesis is the most important processfor the continuation of life on Earth o each year photosynthesis synthesizes 160 billion tons of carbohydrate o heterotrophs are dependent on plants as food source for fuel & raw materials

22. Plant Hormones

23. ●Auxin – stimulate cell elongation à phototropism & gravitropism (high concentrations = herbicide) ●Cytokinins – cell division (cytokinesis) & differentiation ●Gibberellins – stem elongation, leaf growth, germination, flowering, fruit development ●Abscisic Acid – slows growth; closes stomata during H 2 O stress; promote dormancy ●Ethylene – promote fruit ripening (positive feedback!); involved in apoptosis (shed leaves, death of annuals)

24. Effects of Gibberellins on Length

25. Ethylene Gas on Ripening

26. Plant Movement ●Tropisms: growth responses à SLOW o –Phototropism – light (auxin) ●–Gravitropism – gravity (auxin) ●–Thigmotropism – touch ●Turgor movement: allow plant to make relatively rapid & reversible responses o –Venus fly trap, mimosa leaves, “sleep” movement

27. Positive Gravitropism

28. Thigmotropism

29. Responses to Light ●—Plants can detect direction, intensity, & wavelenth of light ●—Phytochromes: light receptors, absorbs mostly red light o Regulate seed germination, shade avoidance

30. Biological Clocks ●Circadian rhythm: biological clocks o Persist w/o environmental cues o Frequency = 24 hours ●Phytochrome system + Biological clock = plant can determine time of year based on amount of light/darkness

31. Photoperiodism ●Short-day plants: flower when nights are long (mums, poinsettia) ●Long-day plant: flower when nights are short (spinach, iris, veggies) ●Day-neutral plant: unaffected by photoperiod (tomatoes, rice, dandelions)

32. Response to Stress ●Drought (H 2 O deficit): o close stoma o release abscisic acid to keep stoma closed o Inhibit growth o roll leaves à reduce SA & transpiration o deeper roots ●Flooding (O 2 deprivation): ●release ethylene à root cell death à air tubes formed to provide O 2 to submerged roots

33. Response to Stress ●Excess Salt: o cell membrane – impede salt uptake o produce solutes to ↓ ψ - retain H 2 O ●Heat: o evap. cooling via transpiration o heat shock proteins – prevent denaturation ●Cold: o alter lipid composition of membrane (↑unsat. fatty acids, ↑fluidity) o increase cytoplasmic solutes o antifreeze proteins

34. Response to Stress ●Herbivores: o physical (thorns) o chemicals (garlic, mint) o recruit predatory animals (parasitoid wasps) ●Pathogens: o 1st line of defense = epidermis o 2nd line = pathogen recognition, host- specific