Photosynthesis Intro Chapter 9 & 10

What you need to know! How chemiosmosis generates ATP in the light reactions How photosystems convert solar energy into chemical energy

Physics of Light Light, like all radiation, has energy Radiation can be sorted into an electromagnetic wave spectrum according to its wavelength Visible light can be broken up into: red, orange, yellow, green, blue, indigo, violet

Colored Solid Objects The color of solid objects is a result of absorbing and reflecting parts of the visible light spectrum Example: Green object Reflects green Absorbs: red, orange, yellow, blue, purple Absorbance spectrum of plants Reflected light is useless to plants. Plants cannot grow under green light It has the same affect as total darkness

Structure of a Chloroplast Chloroplasts have a double membrane (endosymbiotic theory) Inner membrane builds thylakoids: hollow membrane compartments that form stacks called grana.

Thylakoid Membrane Molecules embedded in the phospholipid bilayer of the thylakoid membrane: ATPase Thylakoid space is used for H+ gradient and ATP synthase in the membrane Pigments Chlorophyll a, b, carotenoids, and xantophylls are the main pigments serving photosynthesis are embedded in the membrane Electron transport chain molecules: Ubiquinones, and cytochromes are embedded in the membrane

Structure of Cholorophyll

Structure of Chlorophyll Magnesium Porphyrine Ring Chlorophyll is a molecule that contains nitrogen (present in fertilizer, decaying compost, and proteins) or has to bound out of the air’s N2 (by nitrobacteria) Expensive molecule: is recycled in fall in temperate climates Chlorophyll has a hydrocarbon tail to make it lipophilic for membrane attachment

Structure of Cholorophyll Chlorophyll exists in two different versions: chlorophyll a and b. Absorbance spectrums for both pigments maximize absorbance in the red and blue range

Leaf Structure and Photosynthesis Photosynthesis takes place in the mesophyll of a plant’s leaf. Gas exchange will take place through the stomata, during photosynthesis, stomata need to be open. Plants inevitably transpire through open stomata, which also helps to keep plants cool, but: Only turgid stomata cells are open; if they become flaccid, they close, and photosynthesis stops.

Leaf Structure and Photosynthesis Cuticle Mesophyll Vein Stomata

Paper Chromatography Technique for separating and identifying pigments from cell extracts. The solvent moves up chromatography paper by capillary action Pigments (solutes) are dissolved in the solvent and are carried up the paper

Paper Chromatography Differing pigments have different properties: Solubility, size/shape, polarity Different bands form as the solutes separate while they migrate up the paper

Rf Values of Pigments Rf is a ratio of the migration of the pigment (B) over the migration of the solvent (F) Rf = B/F B = distance (mm) from the bottom of the pigment origin to the bottom of the pigment migration If more than one pigment molecule is tested the highest band is B1, the next band is B2, etc. F = distance from the bottom of the pigment origin to the bottom of the solvent front

Rf Values of Pigments Solvent Front B4 Band # Distance migrated Rf value Identification of substance 1 2 B4 Rf values of substances are specific to the chromatography system used. If paper or solvent is changed, Rf values change Rf values do not change with migration length in a system Rf values are always between 0 & 1 B3 B2 B1 Pigment Origin