Metabolism Mark Shepard Flashcards
What 2 molecules feed the ETC with electrons? Where are these produced?
NADH and FADH2
Produced during glycolysis and via the krebs cycle`
Movement of electrons along the respiratory complexes produces ATP by what mechanism?
Oxidative phosphorylation
Give some types of electron carrier molecules, what they use to carry electrons and their names in different oxidative states?
1) Flavoproteins: Use flavo nucleotides
oxidised: FAD
reduced: FADH2
2) Ubipuinones: use a benzoquinone
Q = ubiquinone
QH
QH2 = ubiquinol
3) Cytochromes: use iron containing heme group
Fe2+ = ferrous
Fe3+ = ferric
4) Iron-sulfur proteins: iron complexed with sulfur
5) Copper: uses copper complexed to cysteine or heme
What are the structures of the 3 classes of cytochromes? (type a,b and c)
A) 2 Histadine amino acids and a isoprenoid chain
B) 1 Histadine AA
C) 1 Histadine AA and 2 Cysteine AA’s
Each class in distinguished by its absorption. What wavelengths does each absorb at?
A = 600nm B = 560 nm C = 550 nm
What are the 5 main structures involved in the ETC?
1) Complex I or NADH dehydrogenase
2) Complex II or Succinate dehydrogenase
3) Complex III or Cytochrome bc1 complex or cytochrome c oxireductase
4) Complex IV or cytochrome C oxidase
5) Coenzyme Q or Ubiquinone
Describe what occurs at complex I in the ETC
1) Complex I catalyses transfer of a hydride ion (2e-) from NADH to flavinmononucleotide (FMN) (NADH + H+ —> NAD+)
2) 2 electrons from FMN pass through a series of Fe-S (iron) centres to the Fe-S protein N-2
3) 2 electrons transfer from N-2 in the matrix arm of the complex to coenzyme Q to produce ubiquinol (QH2)
4) Process drives translocation of 4 protons from matrix into intermembrane space
Describe what occurs at complex II in the ETC
1) Succinate (from krebs cycle) is converted to fumarate and passes electrons through flavin (FAD) and several Fe-S centres in complex II on the way to coenzyme Q
2) Donation of electrons through FAD by glycerol-3-phosphate catalysed by G3P dehydrogenase
3) Acyl-CoA dehydrogenase also provides enzymes via electron transferring proteins (ETFs)
What are the 3 subunits of complex III?
Rieske Fe-S proteins (2Fe-2S) Cytochrome C1 - Interacts with cytochrome c for final step of electron transfer to complex IV Cytochrome b - ubiquinone binding site
What is the name for the process that occurs at complex III in the ETC and what are the steps?
Q cycle model - 2 molecules of QH2 are oxidised to Q - Each QH2 donates: > 1 electron to cytochrome c > 1 electron to a molecule of Q (1st step) or Q- (2nd step) regenerating 1 QH2 between them i.e 2 QH2 goes in, 1 QH2 comes out
What is the net reaction of QH2 oxidation within complex III?
- transfers 2 electrons to 2 different cytochrome c molecules
- 2H+ consumed in the matrix
- 4H+ translocated into intermembrane space
How are protons translocated at complex III? What is this called?
- Protons on QH2 are released into intermembrane space by cytochrome bc1
- Known as vectorial proton translocation
What are the 3 subunits of the functional core of complex IV?
1) 2 heme groups (a & a3) and CuB
Fe of a3 and CuB form a Fe-Cu centre
2) 2 Cu ions (CuA) that resembles a 2Fe-2S centre
3) Poor understanding
What occurs at complex IV in the ETC?
Cytochrome c (carrying e-) travels from complex III to complex IV Electron transfer from cytochrome c to CuA, to heme a, to heme a3-CuB centre and finally onto O2 to produce H20
What is the net production of 4 cytochrome c molecules passing 4 electrons through complex IV?
4 H+ used from the matrix to make 2H2O and 4 H+ pumped into the intermembrane space
How is energy provided to translocate protons across the inner mitochrondrial membrane?
ETC provides energy via thermodynamically favourable electron transfer reactions
What is produced by the movement of protons?
An electrochemical gradient
Electro - charge separation
Chemical - difference in pH
What is the electrochemical gradient of protons in the mitochrondria often referred to as?
The proton motive force
What is the chemiosmotic model?
That the proton motive force drives ATP synthesis
Give some similarities between ATP synthesis by photophosphorylation (PP) and oxidative phosphorylation (OP)
1) Reaction centres, electron carriers and ATP forming enzymes are located in an intact membrane that is impermeable to H+ (unless transported)
2) Can be uncoupled from electron transport mechanisms by reagents that promote H+ passage through the membrane
3) ATP synthesis is catalysed by ATP synthases that both have FoF1 sub-structures
4) Both inhibited by venturicidin
What type of ATPase is ATP synthase?
F-type
What are the main 2 structures of ATP synthase and where is each found?
Fo portion found in the inner mitochondrial membrane
F1 portion found in the matrix
What subunits does F1 contain?
3 alpha 3 beta 1 gamma 1 lower case delta 1 epsilon
What subunits does Fo contain?
a,b and c in proportions ab2c10-12
What reaction does ATP synthase catalyse and how does it achieve the energy for this?
ADP + Pi —> ATP + H2O
Uses energy via flow of H+ from P side (intermembrane) to N side (matrix)
What are the 3 conformations of the alpha-beta pairs in the F1 portion of ATP synthase?
ADP bound, ATP bound and empty
What is the energy from the proton gradient used for?
Used to release bound ATP
Formation of ATP uses very little energy (reversible reaction)
Describe the relationship between Fo and F1 and what occurs when protons flow through the membrane
- b2 and delta of Fo associates with an alpha-beta pair in F1, holding them in a fixed position relative to the membrane
- The Fo cyclinder of c subunits is attached to the F1 gamma and epsilon
- As the H+ flows through the membrane, the cyclinder and shaft rotate and the beta subunits of F1 change conformation as the interactions with the gamma subunit changes
How was the rotation of Fo shown experimentally?
F1 was bound to a microscope slide
C subunit was biotinylated (covalent binding of biotin)
Avidin was bound to biotin
Fluorescent actin was attached to avidin
ATP provided as substrate, rotation of actin observed
What occurs upon each 120 degree turn of the gamma subunit?
1) Converts beta-ATP to beta-empty and the ATP dissociates
2) This promotes the condensation of ADP + Pi to form ATP
3) beta-empty site becomes beta-ADP and loosely binds ADP + Pi
How many protons does ATP synthase use to make one ATP?
3
What is the net amount of protons that move per ATP produced and where do the rest come from?
4
1 proton is transferred by the phosphate translocase (symporter) along with dihydrogen phosphate (H2PO4-) (phosphate needed for ATP synthesis)
What is the P/O ratio?
Phosphate/Oxygen ratio
Amount of ATP produced from the movement of two electrons through a defined electron transport chain
What was the equation originally assumed in order to determine the amount of ATP produced from oxidative phosphorylation?
xADP + xPi + 1/2O2 + H+ + NADH —> xATP + H20 + NAD+
where x equals P/O ratio as an integer
What were the assumed P/O ratios of NADH and Succinate?
NADH - 3
Succinate - 2
Why is it difficult to measure P/O ratios experimentally?
1) Mitochondria consume ATP in many other reactions in the matrix
2) Mitochondria consume oxygen for purposes other than oxidative phosphorylation
What must be considered to gain the true P/O ratio?
1) How many protons are pumped out during oxidation of NADH
2) How many protons leak back across the membrane
3) How many protons must pass through ATP synthase to synthesise ATP
What are the true P/O values for NADH and succinate and how are they determined?
- Each NADH will pump 10H+ into the mitochondiral intermembrane space
- Each succinate (via FADH2) will pump 6H+
- 4H+ are used to fully synthesise 1 ATP
10/4 = 2.5 for NADH
6/4 = 1.5 for succinate
Why must NADH rely of alternative pathways to deliver electrons to the ETC?
Because it cannot freely diffuse from the cytosol to the matrix
What are the names of the 2 pathways NADH uses to move to the matrix?
1) Malate-Aspartate shuttle
2) Glycerol-3-phosphate shuttle
Describe how the malate-aspartate shuttle allows cytosolic NADH to pass its electrons to the ETC
1) Reducing equivalents (can be lone electron or hydrogen atom) from cytosolic NADH are transferred to oxaloacetate to yield malate, catalysed by malate dehydrogenase (NADH converted to NAD+) in intermembrane space
2) Malate passes through inner membrane via malate alpha-ketoglutarate transporter
3) Reducing equivalents passed to NAD+ by matrix malate dehydrogenase to form matrix NADH (malate converted back to oxaloacetate)
4) NADH passes electrons to respiratory chain
5) Oxaloacetate converted to aspartate in matrix and transported into intermembrane space by glutamate-aspartate transporter
6) Aspartate converted to oxaloacetate, ready to be converted to malate
Where in the body is the Malate-Aspartate shuttle mostly used?
Liver, kidney and heart mitochondria
How does the glycerol-3-phosphate shuttle differ from the malate-aspartate shuttle?
1) Produces FADH2 from FAD on the inner membrane instead of NADH from NAD+ in the matrix
2) Delivers electrons to coenzyme Q (ubiquinone) and thus into complex III instead of complex I
Where in the body is the Glycerol-3-phosphate shuttle mostly used?
Skeletal muscle and brain mitochondria
What effect do ADP + Pi and NADH have on mitochondrial energy metabolism control?
ADP + Pi: accelerate the citric acid cycle and oxidative phosphorylation NADH inhibits: - pyruvate kinase - pyruvate dehydrogenase - citrate synthase - isocitrate dehydrogenase - alpha-ketoglutarate dehydrogenase (ATP also inhibits many of these)
Why are mitochondria susceptible to their own set of diseases?
Because they have their own genome
What is Leber’s hereditary optic neuropathy (LHON) and what is it caused by?
- Affects CNS and causes vision loss in adulthood
- Single ND4 base change causes Arg –> His mutation in complex 1
- Mitochondrial defect in electron transfer from NADH to complex 1
- Also seen with single base change in cytochrome b gene
What is Myoclonic Epilepsy & Ragged-Red Fibre Disease (MERRF) and what is it caused by??
- Causes uncontrolled muscle jerks
- Mutation of mitochondrial gene that encodes tRNA specific for lysine
- Defective production of several proteins
- Skeletal muscle fibres have abnormally shaped mitochondria
What 2 factors cause mitochondrial heterogeneity among daughter cells?
1) Not all mitochondria in a cell will encode the disease causing mutation
2) Unequal separation of mitochondria during cell division
How are mitochondria diseases inherited?
Maternally inherited
- Males carry their mothers mtDNA but only females pass it on to their offspring
What are the 4 main disease results of inherited metabolic diseases?
1) Accumulation of substrate
2) Accumulation of a normally minor metabolite
3) Deficiency of product
4) Secondary metabolic phenomena
Give an example of a metabolic disease that is due to accumulation of substrate
Phenylketonuria
What is phenylketonuria and what is it caused by?
- Mutation in human phenylalanine hydroxylase (PAH) gene
- Body cannot break down phenylalanine so it accumulates in blood, brain and urine
Give an example of a disease caused by the accumulation of a normally minor metabolite
Cataracts in patients with galactosemia results from accumulation of the sugar alcohol galacticol
What are the 4 main modes of inheritance of metabolic disorders?
1) Autosomal recessive
2) Autosomal dominant
3) X linked
4) Mitochondrial inheritance
Give some examples of autosomal recessive metabolic disorders
- Tay Sachs disease
- Phenylketonuria
What is the name of disorders that have variable symptom severity?
Variable penetrance
Give an example of autosomal dominant disorder that shows variable penetrance
Variegate Porphyria
Give an example of an x linked metabolic disorder
Hunters Disease
Give some examples of important molecules that amino acids are precursors of
Hormones Coenzymes Alkaloids Cell wall polymers Antibiotics Pigments Neurotransmitters
Give some specific examples of where amino acids are involved in synthesis of important molecules
1) Glycine used to create haem
2) Arginine, glycine and methionine are required for synthesis of phosphocreatine
3) Phenylalanine and Tyrosine are used to synthesise alkaloids: found in cayenne pepper, vanilla, cloves
4) Nitric oxide (bacteriocidal) made from Arginine
What are the 3 examples (that we need to know) of AA that produce neurotransmitters? Which neurotransmitter do they produce?
1) Tryptophan —> Serotonin (Depression)
2) Glutamate —> GABA (gamma-aminobutyrate)
3) Histidine —> Histamine (Allergies)
What type of neurotrasmitter is GABA and what is underproduction associated with?
- Inhibitory neurotransmitter
- Underproduction associated with epileptic seizures
What type of drug is used to treat epilepsy and give an example
GABA analogues
Diazepam (Valium) - binds to GABA receptor, but at a site distinct from endogenous GABA
What enzyme converts glutamate to GABA?
Glutamate decarboxylase
What enzyme converts histidine to histamine?
Histidine decarboxylase
How is aspartame synthesised?
Dipeptide of phenylalanine and aspartate
What is phenylketonuria?
Rare congenital disease in which phenylalanine cannot be metabolised due to a deficiency in the enzyme phenylalanine hydroxylase (PAH)
Phenylalanine and phenylpyruvate builds up in blood and brain
What is the consequence of an accumulation of phenylalanine?
Prevents transport of amino acids across the blood brain barrier, inhibiting synthesis of key neurotransmitters and disrupting protein synthesis in the brain Can lead to: Learning difficulties Behavioral problems Epilepsy and seizures
