Photosynthesis Reactions Lecture 17 PDF

Summary

Lecture 17 on Photosynthesis Reactions, Spring 2024, covers the components of the light-dependent and light-independent reactions in plants. It explains the roles of pigments, photosystems, and chemiosmosis within photosynthesis.

Full Transcript

Photosynthesis Reactions
Lecture 17
Spring 2024
Light
Pigments absorb light - visible
Violet/Blue - shorter wavelengths - higher energy
Red - longer wavelengths - lower energy
Plants - Chlorophyll a, Chlorophyll b, Carotenoids
Absorb wide range of wavelengths
Convert light energy into chemical energy
 Pigments

The plant pigments are found in chloroplasts on the membranes of the thylakoids.
Chlorophyll a: Absorbs blue-violet (reflects blue-green). Main photosynthetic pigment.
Chlorophyll b: Absorbs red-blue (reflects yellow-green). Accessory Pigment.
Carotene: Absorbs blue-purple (reflects orange). Accessory Pigment.
Xanthophyll: Absorbs blue-purple (reflects yellow). Accessory Pigment.
Accessory pigments: absorb other colors of light that chlorophyll a can't absorb. They
help boost energy absorption.
Accessory Pigments
 Structure

The molecule chlorophyll a has a specific shape. This shape causes wavelengths of light that we see as a
dark bluish green to be reflected back.
Change the shape of that molecule by adding only two atoms, making it chlorophyll b, and the light that
is reflected back is now less blue and more yellow.
Chlorophyll
Photosystems - pigment molecules (chlorophyll) & proteins
Membranes of thylakoids - absorb photons
Excites e- in chlorophyll - chlorophyll donates e-
H2O is split to replace 2 e-
Chlorophyll regenerated
O2 to environment, H+ to thylakoid space
Process

Sugar
Steps (Light)
Light-Dependent
Light-Dependent
Light-dependent reactions require sunlight.
In the light-dependent reactions, energy from sunlight is absorbed by
chlorophyll and converted into stored chemical energy, in the form of
the electron carrier molecule NADPH (nicotinamide adenine
dinucleotide phosphate) and the energy currency molecule ATP
(adenosine triphosphate).
The light-dependent reactions take place in the thylakoid membranes
in the granum (stack of thylakoids), within the chloroplast.
Photosystem
Energy - Reaction Center (chlorophyll a)
Transfer Energy - Primary Electron Acceptor
Antenna Pigments
chlorophyll b
carotenoids
xanthophyll
Electron Transport
Reaction Center
Photosystem I: P700
Photosystem II: P680
Electrons passed along electron acceptors
Final = NADP+ è NADPH
Our old friend ATP Synthase
e-
PSII - transfers e- to proteins in membrane - ETC
e- energy moves H+ from stroma to thylakoid space
After energy is used e- accepted by pigment molecule in PSI
Electrochemical gradient - H+ create charge
H+ - move down gradient through ATP Synthase
 Summary

To replace the electron in the reaction center, a molecule of water is split. This splitting
releases an electron and results in the formation of oxygen (O2) and hydrogen ions (H+) in
the thylakoid space.
Technically, each breaking of a water molecule releases a pair of electrons, and therefore
can replace two donated electrons.
The replacing of the electron enables the reaction center to respond to another photon.
The oxygen molecules produced as byproducts find their way to the surrounding
environment.
The hydrogen ions play critical roles in the remainder of the light-dependent reactions.
Thylakoid Membrane
Steps (Calvin)

OF LIGHT-DEPENDENT REACTIONS (ATP, NADPH)
Calvin Cycle
Calvin Cycle - Light-Independent - Dark Rxn
CO2 enters through stomata
diffuses into stroma
Uses energy from light reactions
ATP & NADPH
 Light-Independent
In the light-independent reactions or Calvin cycle, the energized electrons
from the light-dependent reactions provide the energy to form
carbohydrates from carbon dioxide molecules.
Although the light-independent reactions do not use light as a reactant
(and as a result can take place at day or night), they require the products
of the light-dependent reactions to function.
The light-independent molecules depend on the energy carrier molecules,
ATP and NADPH, to drive the construction of new carbohydrate molecules.
After the energy is transferred, the energy carrier molecules return to the
light-dependent reactions to obtain more energized electrons.
Light-Independent
Calvin Cycle
Fixation, reduction, regeneration
Enzyme - RuBisCO
Molecule - ribulose bisphosphate (RuBP)
 Photosystems
Two types of photosystems are embedded in the thylakoid membrane: photosystem II
( PSII) and photosystem I (PSI).
Each photosystem plays a key role in capturing the energy from sunlight by exciting
electrons.
Photosystems consist of a light-harvesting complex and a reaction center.
Pigments in the light-harvesting complex pass light energy to two special
chlorophyll a molecules in the reaction center.
The light excites an electron from the chlorophyll a pair, which passes to the primary
electron acceptor. The excited electron must then be replaced.
In photosystem II, the electron comes from the splitting of water, which releases
oxygen as a waste product.
In photosystem I, the electron comes from the chloroplast electron transport chain.
Photosystems
Concept Check
Describe light, pigments, chlorophyll (properties, function)
Compare the components of the light-dependent and light-
independent reactions
Describe a photosystem and the role it plays in photosynthesis
Explain the role of chemiosmosis in photosynthesis
Describe inputs and outputs of the light-dependent vs light-
independent reactions.