Mitochondria and chloroplasts Flashcards
Mitochondria structure
2 membranes, outer permeable (molecules eg ATP can pass), inner not permeable and folded so its convoluted, large SA
Matrix is where enzymes of krebs reside
Choroplast
Made of 3 membrane systems- outer, inner, thylakoid
Thylakoid highly folded, have integral mem proteins important for PS eg PS I and PS II
Primary function of mitochondria and chloroplasts
ATP synthesis
ATP uses
fuel cellular processes
Anabolic reactions of cells responsible for growth and repair processes
Catabolic reactions release energy needed to drive anabolic reactions
ATP is the energy intermediate used to link energy yielding to energy requiring processes
Where is ATP synthase found
Mitochondrial inner membrane - ATP synthesised in the matrix.
Choroplast thylakoid membrane. ATP synthesised in the stroma
Inner membrane of eubacteria
Type of ATPase
Large multisubunit F-type ATPase made up of an F0 which is integral (carrier part) in the membrane and an F1 peripheral (lollipop part)
Structure of ATP synthase
Large lollipop head attached through a stalk to transmembrane carrier for protons
As protons pass through carrier (F0) stalk spins, causes conformational changes in F1 that facilitate production of ATP from ADP and PI
Direction of proton flow
mitochondria intermembrane space to matrix
in chloroplasts from lumen of thylakoid to stroma of chloroplast
What is a form of stored energy
proton gradient
2 parts of proton gradient
delta V- difference in voltage ie membrane potential
delta pH ie H+ conc gradient
How many protons needed to synthesise 1 ATP
3
How can formation of ATP be reversed
Use hydrolysis of ATP to pump protons
How is the proton gradient across the mitochondrial membrane generated?
Coupling of electron transfer to proton pumping across the membrane
HIgh energy electrons passed along ETC, transfers release/lose energy used to pump H+ across membrane creating an electrochemical proton gradient
How can protons be pumped across membranes by coupling to electron transfers?
transfer of electron from integral membrane protein A to B gives B a negative charge, which attracts a proton. Electron transferred to C, proton loses its affinity for B because no longer negative charge, so is released the other side of the membrane
3 protein pumping complexes in mitochondria
NADH hydrogenase, Cytochrome bc1 comple, cytochrome oxidase complex (in order)
What happens to protein pumping complexes
Receive electrons from oxidation of food molecules (fats and carbohydrates) in the citric acid/krebs cycle, passed onto NADH, which becomes reduced and passes electrons onto protein complexes, becoming oxidised and forming NAD+.
Formation of H20
Electrons passed onto oxygen held in the cytochrome oxidase complex, which forms water
NADH
Nicotinamide adenine dinucleotide
Mobile electron carriers- Ubiquinone
small lipid like molecule
Carries electrons from NADH hydrogenase to cytochrome bc1 complex
Mobile electron carriers- Cytochrome C
Carries electrons from cytochrome bc1 complex to cytochrome oxidase complex
Chemiosmotic coupling-
and what is it known as in mitochondria?
Linkage of electron transport, proton pumping and ATP synthesis
Known as oxidative phosphorylation in mitochondria
Electron transfer potential
Reducing agents ranked according to this NADH high (-ve value) H20 low (+ve value)
Trend in redox potential (electron affinity) across the mitochondria ETC
increases
electrons losing energy
NADH hydrogenase nature
Flavin nucleotides, FeS
