Oxidative Phosphorylation - Chapter 19 PDF

Summary

This document is a lecture/notes from a biochemistry course, specifically focusing on oxidative phosphorylation. The notes detail processes like chemiosmotic theory, the role of mitochondria, and the components of the electron transport chain.

Full Transcript

Oxidative phosphorylation
Marc A. Ilies, Ph. D.

Lehninger - Chapter 19 [email protected]; lab 517, office 517A (Tu, Fr 3-5)
For questions, comments please use the discussion tool in Canvas ©MAIlies 2024 1
 Energy from reduced fuels is used to synthesize ATP
via cellular respiration

Carbohydrates, lipids, and
amino acids are the main
reduced fuels for the cell.
Electrons from reduced fuels are
transferred to reduced cofactors
NADH or FADH2.
In oxidative phosphorylation,
energy from NADH and FADH2
is used to make ATP.
 Chemiosmotic Theory
 ADP + Pi  ATP is highly thermodynamically unfavorable.
 Energy needed to phosphorylate ADP is provided by the flow of
protons down the electrochemical gradient.
G is directly related to ΔE = Eo (e- acceptor) – Eo (e- donor)

 The energy released by electron transport (redox processes) is used to
transport protons against the electrochemical gradient (chemiosmotic
theory, Peter Mitchell, 1961)
 Chemiosmotic energy coupling
requires membranes
The proton gradient needed for ATP
synthesis can be stably established across a
membrane that is impermeable to ions.
– plasma membrane in bacteria
– inner membrane in mitochondria
– thylakoid membrane in chloroplasts
The membrane must contain proteins that
couple the “downhill” flow of electrons in
the electron-transfer chain with the “uphill”
flow of protons across the membrane.
The membrane must also contain a protein
that couples the “downhill” flow of protons
to the phosphorylation of ADP.
 Structure of a Mitochondrion
Double membrane leads to four distinct compartments:
1. Outer membrane:
– relatively porous membrane; allows passage of
metabolites
2. Intermembrane space (IMS):
– similar environment to cytosol
– higher proton concentration (lower pH)
3. Inner membrane
– relatively impermeable, with proton gradient
across it
– location of electron transport chain complexes
– convolutions called cristae serve to increase
the surface area.
4. Matrix
– location of the citric acid cycle and parts of
lipid and amino acid metabolism
– lower proton concentration (higher pH)
 Electron-Transport Chain Complexes Contain
a Series of Electron Carriers
Each complex contains multiple redox centers consisting of:
– flavin mononucleotide (FMN) or flavin adenine dinucleotide (FAD)
– cytochromes a, b, or c
– iron-sulfur clusters
Order of transfer of electrons is dependent on reduction potential:

Tendency to accept
e- increases
 NAD(P)+/NAD(P)H, FMN/FMNH2 FAD/FADH2
electron carriers
Coenzymes associated with dehydrogenases

- transfers hydride ions: H- (one
proton plus two electrons H+ + 2.e-)
- deficiency: Pellagra

- transfers hydrogen atoms.H (one
proton plus one electron H+ +.e-)
- deficiency: Ariboflavinosis
 Coenzyme Q or Ubiquinone

Ubiquinone is a lipid-soluble quinone
isoprenoid compound that readily
accepts electrons from different redox-
active compounds
Upon accepting two electrons, it picks
up two protons to give an alcohol,
ubiquinol.
Ubiquinol can freely diffuse in the
membrane, carrying electrons with
protons from one side of the membrane
to another side.
Coenzyme Q is a mobile electron
carrier transporting electrons from
Complexes I and II to Complex III.
O OH

+ 2 e - + 2 H+

O OH
1,4-benzoquinone hydroquinone
 Cytochromes
One-electron carriers based on Fe3+/Fe2+ redox system
Fe3+/Fe2+ coordinating porphyrin ring (heme) derivatives
a, b, or c differ by ring additions; substitution modulates redox properties:
 Iron-Sulfur Proteins
One-electron carriers based on Fe3+/Fe2+ redox system
Iron ions coordinated by cysteines in the protein or assembled in iron-sulfur
clusters that are coordinated by Cys residues in the protein
Iron-sulfur clusters contain an equal number of iron and sulfur atoms
 Chemiosmotic Model for ATP Synthesis
Electron transport through complexes I→IV sets up a proton-motive force
(flow of electrons creates a concentration gradient of protons)
Energy of proton-motive force drives synthesis of ATP.

TABLE 19-3 The Protein Components of the Mitochondrial Respiratory Chain
Enzyme complex/protein Mass (kDa) Number of subunitsa Prosthetic group(s)
I NADH dehydrogenase 850 45 (14) FMN, Fe-S
II Succinate dehydrogenase 140 4 FAD, Fe-S
III Ubiquinone: cytochrome c oxidoreductaseb 250 11 Hemes, Fe-S
Cytochrome cc 13 1 Heme
IV Cytochrome oxidaseb 204 13 (3–4) Hemes; CuA, CuB
a
Number of subunits in the bacterial complexes in parentheses.
b
Mass and subunit data are for the monomeric form.
c
Cytochrome c is not part of an enzyme complex; it moves between Complexes III and IV as a freely soluble protein.
 Flow of electrons in mitochondria
Transport of a pair of electrons from NADH to O 2
is achieved through successive redox reactions, in
Complexes I to IV
The energetic difference in redox potential is
gradually harvested to create a proton concentration
gradient
Transport of a pair of electrons from NADH to O2
produces 220 kJ; It takes ~ 30kJ to produce one ATP.
This is more than enough energy to make 3 ATP. The
rest of energy is lost as heat

The sequence can be determined using inhibitors of
electron transfer

Uncouplers can bypass the H+ flow through ATPase
 NADH:Ubiquinone Oxidoreductase, a.k.a. Complex I
One of the largest macro-molecular
assemblies in the mammalian cell
Over 40 different polypeptide chains,
encoded by both nuclear and mitochondrial
genes
NADH binding site in the matrix side
Non-covalently bound flavin
mononucleotide (FMN) accepts two
electrons from NADH.
Several iron-sulfur centers pass one electron
at a time toward the ubiquinone binding site.
Transfer of two electrons from NADH to
ubiquinone is accompanied by a transfer of
protons from the matrix (N) to the
intermembrane space (P); about four protons
are transported per one NADH.

NADH + Q + 5H+N = NAD+ + QH
 Succinate Dehydrogenase, a.k.a. Complex II

FAD accepts two electrons from
succinate.
Electrons are passed, one at a time, via
iron-sulfur centers to ubiquinone,
which becomes reduced QH2.
Does not transport protons

FADH2 + Q FAD + QH2
Succinate dehydrogenase is a single enzyme with dual role:
convert succinate to fumarate in the citric acid cycle
capture and donate electrons in the electron transport chain
 Ubiquinone:Cytochrome c Oxidoreductase,
a.k.a. Complex III

Uses two electrons from QH2
to reduce two molecules of
cytochrome c
Additionally contains iron-
sulfur clusters, cytochrome b,
and cytochrome c
Clearance of electrons from the
reduced quinones via the Q-
cycle results in translocation of
four additional protons to the
intermembrane space:
 Cytochrome c
The second mobile electron carrier
– Ubiquinone moves through the
membrane.
– Cytochrome c moves through the
intermembrane space.
A soluble heme-containing protein in the
intermembrane space
Heme iron can be either ferrous (Fe3+,
oxidized) or ferric (Fe2+, reduced).
Cytochrome c carries a single electron from
the cytochrome bc1 complex to cytochrome
oxidase.
absorbs blue light and gives cytochrome c
an intense red color; named by the position
of their longest-wavelength (α) peak.
 Cytochrome Oxidase, a.k.a. Complex IV

Mammalian cytochrome oxidase is a
membrane protein with 13 subunits.
Contains two heme groups: a and a3
Contains copper ions
– CuA: two ions that accept electrons
from cyt c
– CuB: bonded to heme a3, forming a
binuclear center that transfers four
electrons to oxygen
Four electrons are used to reduce one oxygen
molecule into two water molecules.
Four protons are picked up from the matrix in
this process.
Four additional protons are passed from the
matrix to the intermembrane space:
4 cyt c (reduced) + 8H+N + O2 → 4 cyt c (oxidized) + 4H+P + 2 H2O
Summary of the Electron Flow in the Respiratory Chain

Complex I  Complex III  Complex IV
NADH + 11H+(N) + ½O2 ——> NAD+ + 10H+(P) + H2O
Complex II  Complex III  Complex IV
FADH2 + 6H+(N) + ½O2 ——> FAD + 6H+(P) + H2O

Difference in H+ transported will reflect difference in ATP synthesized (3 for NADH, 2 for FADH2)
 Mitochondria can generate reactive oxygen species ROS
- when the rate of electron entry into the respiratory chain and the rate of electron
transfer through the chain are mismatched, superoxide radical ( O2-) and ROS
production increases via e- transfer from ubiquinone:

(SOD)

- cell can correct free-radical production via superoxide dismutase (SOD) and
glutathione peroxidase, with the use of Glutathione (GSH)
- RBCs do not have mitochondria!
 Proton-Motive Force

The proteins in the electron-
transport chain created the
electrochemical proton gradient by
one of three means:

– actively transporting protons
across the membrane
Complex I and Complex
IV
– chemically removing protons
from the matrix
reduction of Q and
reduction of oxygen
– releasing protons into the
intermembrane space
oxidation of QH2
 Proton-motive force drives ATP synthesis
- the electrochemical energy stored in the H+ concentration gradient and the
separation of charge across the inner mitochondrial membrane (the proton
motive force) drives ATP synthesis via ATP synthase:
 Mitochondrial ATP Synthase Complex
Contains two functional units:
F
0
integral membrane complex
transports protons from IMS to matrix,
dissipating the proton gradient
energy transferred to F to catalyze
1
phosphorylation of ADP
F1
soluble complex in the matrix
individually catalyzes the hydrolysis of ATP
Structure: Hexamer arranged in three αβ
dimers
Dimers can exist in three different
conformations:
open: empty
loose: binding ADP and Pi
tight: catalyzes ATP formation and
binds product
 Synthesis of ATP in ATP synthase
Translocation of three protons fuels synthesis of one ATP:

https://www.youtube.com/watch?v=b_cp8MsnZFA
Chemiosmotic Model for ATP Synthesis
 Electron transport and ATP synthesis are coupled
As described, ATP synthesis requires electron transport
However, electron transport also requires ATP synthesis

- Addition of both ADP + P and succinate is needed for mitochondrial respiration; ATP is
synthesized.
- Addition of cyanide (CN-), which blocks electron transfer between cytochrome oxidase
(Complex IV) and O2, inhibits both respiration and ATP synthesis.
- Vice-versa, mitochondria provided with succinate respire and synthesize ATP only when
ADP and Pi are added. Subsequent addition of venturicidin or oligomycin, inhibitors of ATP
synthase, blocks both ATP synthesis and respiration.
- Dinitrophenol (DNP) is an uncoupler, allowing respiration to continue without ATP
synthesis.
 Uncouplers
Transport of protons across mitochondrial membrane by
2,4-dinitrophenol (DNP):

Valinomycin is a K+ Ionophore
- Ionophores will disrupt ion gradients across
membranes and thus uncouple electron
transport.
- Experimentally an artificially imposed
electrochemical gradient can be produced by
the addition of a + charge from K+, this can
drive ATP synthesis in the absence of an
oxidizable substrate as electron donor
- This provides evidence of the role of a
proton gradient in ATP synthesis.

Valinomycin
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 Uncouplers
Thermogenin in Brown Fat
- Uncoupling protein in the mitochondria of brown adipose tissue
- Provides heat via H+ flow through it
- Provides heat for babies (have high surface area/volume ratio), also in
hibernating animals

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 *
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*
*
*

*

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 Transport of different species in/out of matrix
- Translocation of a fourth proton per ATP is required to facilitate cotransport of
substrates into and products out of the mitochondria:
 Malate-Aspartate Shuttle
- this shuttle transports reducing equivalents (NADH) from cytosol into the
mitochondrial matrix (liver, kidneys, heart):
 Glycerol-3-Phosphate Shuttle
- This alternative means of moving reducing equivalents from the cytosol to the
mitochondrial matrix operates in skeletal muscle and the brain:

- Note that from NADH we get FADH2, so we are losing energy (1 ATP) – see next
slide!
 Glucose
2H++ 2e-
1/2 O 2
Pyruvate ADP
2H++ 2e- ADP ADP

2H++ 2e- NADH FMN CoQ b c1 c a
isocitrate
Acetyl CoA ATP ATP ATP
-ketoglutarate
citrate 2H++ 2e-

oxaloacetate succinyl CoA

malate succinate
2H++ 2e- FADH2
fumarate
2H++ 2e-
Glycolysis 2 substrate level phosphoryations-2ATP = 2 ATP
Oxidation of 2 NADH from glycolysis 2 x 3(Malate Shuttle) = 6 ATP
Pyruvate acetyl-CoA 2 xNADH = 6 ATP
6 x NADH = 18 ATP
Krebs 2 x FADH 2 = 4 ATP
2 substrate level phosphorylations = 2 ATP
38 ATP produced using Malate Shuttle !! Total = 38 ATP

36 ATP produced using Glycerol PO4 Shuttle !! 27
 Regulation of Oxidative Phosphorylation

Primarily regulated by substrate availability
– NADH and ADP/Pi
The rate of O2 consumption and thus ATP synthesis is
regulated by the amount of ADP ( i.e. the Pi acceptor).
The intracellular concentration of ADP is a measure of
the energy status of the cell.
Another measure is the Mass-Action Ratio: [ATP] /
([ADP] [Pi]) Normally this ratio is high. When energy is
required the ratio falls so [ADP] increases, respiration
increases and more ATP is produced. The ratio is fairly
stable so that ATP is formed only as fast as needed.
High ATP has inhibitory effects at multiple levels
Inhibition of OxPhos leads to accumulation of NADH.
– causes feedback inhibition cascade up to PFK-1 in
glycolysis
 Mitochondria can play an initiating role in apoptosis
- loss of mitochondrial membrane
integrity releases cytochrome c in the
cytosol, where it acts as a trigger for
apoptosis (programmed cell death)
by stimulating the activation of a
family of proteases called caspases
 Mitochondria genetics is very important
Mitochondrial DNA is circular and well conserved.
The mitochondrial genome has 37 genes and encodes
rRNA, tRNA, and enzymes in central metabolism,
including the citric acid cycle and oxidative
phosphorylation.
– Mitochondria have their own ribosomes to allow
synthesis of proteins within the organelle.
– However, the vast majority of mitochondrial
proteins are encoded on nuclear DNA, synthesized
in the cytosol, and imported into the mitochondria.
Mitochondrial DNA is maternally inherited.
Mutations can cause many diseases:
Mitochondrial Mutations Result in a Rare form of
Diabetes

Defects in oxidative
phosphorylation result in
low [ATP] in the cell.
– Insulin cannot be
released from the cell.
 Goals and Objectives
Upon completion of this lecture at minimum you should be able to answer the
following:
►What is the role of cellular respiration in catabolism and ATP synthesis?
►What are the implications of the chemiosmotic theory in terms of energetics,
mitochondria design? What processes take place in mitochondria and where?
►Which are the main redox intermediates (electron carriers) in oxdative
phosphorylation, what are their details and what role they play in oxPhos?
►What complexes involve the electron flow in mitochondrial, what is their role and
what are their particularities?
►How the proton motive force is created (sources) and how it is used to produce
ATP? What enzymes are involved, what is their role and particularities?
►Which are the inhibitors of electron flow, of ATP synthesis, at what steps they act,
how is the electron flow coupled with ATP production, how can it be uncoupled ?
What particularities have different uncouplers?
►What are the particularities of material (compounds, intermediates) transfer in/out
of mitochondria?
►How is oxidative phosphorylation regulated?
►What is the role of mitochondria in ROS production and apoptosis, what are the
details of mitochondria genetics and what diseases can be observed as a result of
mutations of different mitochondrial enzymes?
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