The document summarizes key theories and mechanisms of oxidative phosphorylation:
1) Chemiosmotic theory proposed by Peter Mitchell describes how ATP synthesis is coupled to respiration via an electrochemical proton gradient generated by electron transport complexes pumping protons across the inner mitochondrial membrane.
2) Boyer's binding change mechanism describes how ATP synthase uses the proton gradient to drive the sequential binding and conformational changes of its beta subunits to synthesize ATP.
3) Factors that regulate oxidative phosphorylation include inhibitors that block electron transport complexes or uncouple the proton gradient from ATP synthesis.
2. Theories of oxidative phosphorylation
1.Chemiosmotic theory
2.Boyer’s binding change mechanism
3. The Chemiosmotic Theory of oxidative
phosphorylation, for which Peter Mitchell received
the Nobel prize:
Coupling of ATP synthesis to respiration is indirect, via a
H+ electrochemical gradient.
Matrix
H+
+ NADH NAD+
+2H+
2H+
+ ½ O2 H2O
2e – –
I Q III IV
+ +
4H+
4H+
2H+
Intermembrane Space
cyt c 3H+
F1
Fo
ADP + Pi ATP
4. Chemiosmotic theory proposed by Peter Mitchell
The transport of protons from matrix to intermembrane
space is accompanied by
the generation of a proton gradient across the
membrane.
5. Protons (H+) accumulate intermembrane space
creating an electrochemical potential difference,
proton gradient or electrochemical gradient.
This proton motive force (PMF) drives the synthesis
of ATP by ATP synthase complex.
8. Proton dependant ATP synthese
Uses proton gradient to make ATP
Protons pumped through channel on enzyme
From intermembrane space into matrix
~4 H+ / ATP
Called chemiosmotic theory
9. NADH
10 H+ X 1 ATP = 2.5 (3) ATP
4 H+
FADH2
6 H+ X 1 ATP = 1.5 (2) ATP
4 H+
10. Boyer ’s binding change mechanism:
ATP synthase is a protein assembly in the inner
mitochondrial membrane.
11. ATP synthase has two units
F1 - projects into matrix
-has 3 α , 3 β , gamma , delta, epsilon chains
-catalyses ATP synthesis
Peripheral catalytic sites are present on beta
subunits.
Fo - embedded in membrane
- acts as channel for transport of H+
12. ADP + Pi ATP
F1
Fo
3 H+
matrix
intermembrane
space
4
H+ H+ H+ H+H+ H+ H+ H+
13. Mechanism of ATP synthesis (Boyer’s Hypothesis)
Boyer’s binding change hypothesis
Synthesis of ATP occurs on the surface of F1.
Binding change mechanism states that 3 beta
subunits change CONFORMATIONS during
catalysis with only one beta subunit acting as
Catalytic site.
14. β subunits occur in 3 forms
„O‟ form (Open form). It has low affinity for
substrates ADP +Pi
„L‟ form (loose form). Can bind substrates ADP
and Pi but catalytically it is inactive.
„T‟ form (Tight form). Binds substrates ADP + Pi
tightly and catalyses ATP synthesis.
15. When protons pass through the disk of C subunits of
F0 unit it causes rotation of γ sub unit.
The β subunits which are fixed to the membrane
donot rotate.
ADP & Pi are taken up sequentially by the βsubunits
which undergo conformational changes and form
ATP.
16.
17. Gamma subunit is in the form of axle . It rotates
when protons flow.
ATP synthase is smallest known MOLECULAR
MOTOR in the living cells.
18. ETC - inhibitors
Complex I : site I of ATP synthesis inhibitors
Rotenone, Peircidin, Amytal, Barbiturates
ComplexII:
Carboxin,Thenoyltrifluroacetone,malonate
Complex III : site II of ATP synthesis inhibitors
Antimycin, Myxothiazol , stigmatellin
Complex IV: site III of ATP synthesis inhibitors
Cyanide, azide , carbon monoxide
19. Complex – I inhibitors (Site I inhibitors)
Rotenone, insecticide, also used as fish poison.
Binds to complex I and prevents the reduction of
Ubiquinone.
Piercidin, Amytal (sedative), Barbiturates
– inhibit by preventing the transfer of electrons from
iron sulfur center of complex – I to Ubiquinone.
20. Complex – II inhibitors
Malonate acts as a competitive inhibitor with the
substrate succinate
21. Complex – III inhibitors (Site II Inhibitors)
Antimycin inhibit electron transfer from cytb to C1.
Myxothiazol and stigmatellin, antibiotics
inhibit electron transfer from Cytb to C1.
22. Complex – IV (site III inhibitors)
Cyanide and azide bind tightly to oxidized form of
heme a3 ( of complex iv ) preventing electron flow.
Cyanide is potent and rapidly acting poison.
Cyanide prevents binding of oxygen to Cytochrome
oxidase ( aa3 ).
Mitochondrial respiration and energy production stops
cell death occurs rapidly.
23. Carbonmonoxide binds to the reduced form of
heme a3(Fe2+) competitively with oxygen and prevents
electron transfer to oxygen.
24. Uncouplers of oxidative phosphorylation :
Uncouplers will allow oxidation to proceed but
energy instead of being trapped as ATP is dissipated
as heat.
They are hydrophobic weak acids.
They are protonated in the intermembrane space
where a higher concentration of protons exists.
25. These protonated uncouplers due to their lipophilic
nature rapidly diffuse across the membrane into
matrix where they are deprotonated since matrix has
a lower concentration of protons.
Thus, the proton gradient is dissipated.
26. 2-4 dinitrophenol a classical uncoupler – electrons
from NADH to oxygen proceeds normally but ATP not
formed as proton motive force across inner
mitochondrial membrane is dissipated .
27. 2. Penta chloro phenol
3. Dinitro cresol
4.Bilirubin
5.Thyroxine-Physiological uncoupler
6.Valinomycin
7.Nigericin
Note: They are Lipophilic
29. Physiological Uncouplers
1.Excessive thyroid hormones
2. Unconjugated hyper bilirubinaemia
3. In high doses aspirin uncouple oxidative
phospharylation which explains fever that
accompanies toxic over dosage of these drugs.
30.
31. Uncoupling proteins
UCPs occur in the inner mitochondrial membrane of
mammals, including humans.
UCPs create a “proton leak”, that is they allow
protons to re-enter the mitochondrial matrix without
energy being captured as ATP.
Energy is released as heat, and the process is called
nonshivering thermogenesis.
32. UCP1, also called thermogenin, is responsible for the
activation of fatty acid oxidation and heat production
in the brown adipocytes of mammals.
Brown fat , unlike the more abundant white fat, uses
almost 90% of its respiratory energy for
thermogenesis in response to cold, at birth,etc.
33. Inhibitors of Oxidative phosphorylation :
Oligomycin – acts through one of the proteins
present in F0 - F1 stalk .
Oligomycin blocks the synthesis of ATP by
preventing the movement of protons through ATP
synthase.
34. The regulation of the rate of oxidative
phosphorylation by ADP level is called respiratory
control.
The ADP level increases when ATP is consumed and
so oxidation is coupled to the utilization of ATP.
Under physiological conditions, electron transport is
tightly coupled to oxidative phosphorylation.
35. Electrons do not usually flow through the electron
transport chain to O2 unless ADP is simultaneously
phosphorylated to ATP.
In the presence of excess substrate and Oxygen,
respiration continues until all ADP is converted to
ATP.
After that the respiration rate or utilization of oxygen
decreases
In the presence of adequate oxygen and substrate, ADP
becomes rate limiting; it exerts a control over the
entire oxidative phosphorylation process
36. The rate of respiration of mitochondria (Oxidative
phosphorylation) can be controlled by ADP.
Oxidation cannot proceed via ETC without
simultaneous phosphorylation of ADP.
Chance & Williams defined 5 conditions that can
control rate of respiration.
37.
38.
39. Generally most cells in the resting state are in state
4 , and respiration is controlled by the availability
of ADP.
The availability of inorganic phosphate could also
influence the respiration.
As respiration increases (Exercise) cell approaches
state 3 ( ETC working to its full capacity ) or state 5
( Availability of O2 is a limiting factor ).
ADP / ATP transporter may also be a rate limiting
factor
40. P:O ratio (ADP : O ratio)
P:O ratio is defined as number of phosphates
incorporated into ATP to 1 atom of oxygen utilized
during the transfer of 2 electrons through ETC.
For NADH P:O ratio is 3 i.e 3 ATPs are produced
(2.5)
For FADH2 P:O ratio is 2 i.e 2 ATPs are
produced(1.5)