mitochondria and chloroplasts 2 Flashcards
Function of chloroplasts
Harvest energy from sunlight, convert it to chemical energy to fix carbon from the atmosphere (CO2) into sugars
Features of phosphorylation
Electrons passed along ETC are from water, but unlike NADH, H2O is a poor donor of electrons, so requires energy input from light to extract electrons
How does light raise energy of electrons
Sunlight absorbed by chorophyll and electrons interact with photons, raising them to higher energy level
What does chlorophyll look like
Haem, except metal ion at the centre is Mg not Fe
in depth explanation of electron transfer from panopto
When chlorophylls in antenna complex absorb light they channel it into electrons in special pair of chlorophylls- get excited to higher energy level, can be donated to electron acceptor
If electrons are low energy can’t be passed onto electron acceptor (See diagram)
Mobile electrons carriers: Plastoquinone
resembles ubiquinone of mitochondria
Plastocyanin
small copper containing protein
Ferredoxin
Small protein containing a Fe-S centre
How is ATP generated
BY proton gradient across thylakoid membrane, same as in mitochondria
What are high energy electrons passed onto form at the end of the ETC
high energy NADPH, strong reducing agent
What are high energy electrons passed onto form at the end of the ETC
high energy NADPH, strong reducing agent
What are the NADPH and ATP generated by light dependent PS used for?
Energy sources to fix carbon from CO2 into sugars (by calvin cycle)
RUBISCO
Ribulose biphosphate carboxylase
Function RUBISCO
Catalyses initial reaction in carbon fixation
Very slow enzyme, so a lot is required to fix a lot of carbon
Catalyses addition of one carbon (CO2) onto a 5C (ribulose biphosphate) molecule to make a 6C intermediate, then cleaved to produce 2 3C molecules
Calvin cycle overview (add to from panopto)
For every three carbons that are fixed a 3C molecule can be removed from the cycle
glyceraldehyde 3-phosphate
