biological oxidation (electron transport chain)
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Balance of electric (electrostatic) charge in molecule mostly
determined by electron (e–).
Electron is a particle with elementary negative charge.
In some processes in organic molecules charge balance is
determined by the proton (H+). [Proton is charged positively].
Oxidation is defined as the loss of electrons –e– and reduction
as a gain of electrons +e–.
Biological oxidation – also named as respiration – it is an
ATP-generating process in which an inorganic compound
serves as the ultimate electron (e–) acceptor (i.g. O2 [i.e. during
biological oxidation O2 reduced to H2O]). The electron donor
can be either an organic compound or inorganic one.
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Mitochondria
Mitochondria are
oval-shaped cell
organelles, contain
the respiratory
assembly – that is the
enzymes of the citric
acid cycle, and the
enzymes of fatty acid
oxidation.
Mitochondria are
typically about 2μm
in length and 0.5μm
in diameter
Distribution of protons H+ – between matrix and
intermembrane space [inner crista space] forms electrostatic
potential on inner mitochondria membrane.
Four complexes of mitochondria electron transporting
chain and (fifth) ATP-synthesis complex.
[NADH and Succinate-Fumarate entrances into ETC]
Cellular respiration and biological oxidation based on
NADH and FADH2 (which are gained from: glycolysis, pyruvate
processing, citric acid cycle, amino acid oxidation, and β-oxidation
Two main possible ways of sugar oxidation[energy gradient during biological oxidation and direct burn of sugar]
Complex I in Electron Transport Chain 1
NADH ubiquinone
oxidoreductase (Complex I)
[usually have ‘L’ shape
consists of 46 polypeptides]
NADH – is an oxidized
molecule
Ubiquinone – is reduced
Complex I acts as proton pomp
Complex I in Electron Transport Chain
[this complex is pumping H+ into intermembrane
space: each NADH+H+ – give two protons 2H+]
Source of NADH+H+ for complex I :
-Glycolysis
-TCAcycle
-Amino Acid oxidation
-β-oxidation
All of these reactions increas concentration of
NADH+H+, which is transporting into mitochondrial
matrix, where it is oxidated by enzyme oxidoreductase
NADH+H+ → NAD+
in the same time FMN is reducing:
FMN(oxidated form) → FMNH2 (reduced form)
Hydrogen stereospecifically trasferred by NADH
(reduced form) dehydrogenases
[NAD+ is an oxidised form]
reduced form
Reduction of dimethylisoalloxazine (flavin)
in Flavin mono nucleotide (FMN)
reduced form
oxidized form
Complex I with the help of FMN and Iron-Sulfur
centers [clusters] (Fe–S) do transfer electron
to Ubiquinone (reducting it into Ubiquinol)
FMNred → FMNox
Fe+3–S(ox) → Fe+2–S(red)Ferric (+3) oxidized form → Ferros (+2) reduced form
Fe+2–S(red) → Fe+3–S(ox)
…
Fe+3–S(ox) → Fe+2–S(red)
Fe+2–S(red) → Fe+3–S(ox)
…
Coenzyme Qn (Ubiquinone(ox))→ Coenzyme QnH2 (Ubiquinol(red))
this all increasing ubiquinol pool
Molecular models of iron-sulfur complex: (A) cluster
containing one Fe; (B) containing [2Fe-2S] cluster;
(C) [4Fe-4S] cluster. Iron atoms are shown in red, cistein sulfur
atoms shown in yellow; inorganic sulfur atoms in green.
Coezyme Q10 – oxidized and reduced forms
(with intermediate semiquinone form)
[to be reduced receives 2 electrons (from Complex I
or Complex II) and 2 protons (from matrix)]
Complex II (Succinate dehydrogenese) of ETC
Complex II do not transfer
protons (H+) into intermembrane
space
but reduces FAD to FADH2 and
through Fe-S clusters reduce
coenzyme Q10 (to ubiquinol)
Succinate dehydrogenese
(it is the same enzyme as in TCA cycle)
Succinate (alkane) oxidized to (alkine) Fumarate
Adenin mono
phosphat
(AMP)
Flavin Adenin
Dinucleotide (FAD)
[dimethylisoalloxazine]
Flavin
([ribo]flavin – Vitamin B2)
Flavin part of
Flavin adenin
dinucleotide
(FAD) is active
part of molecule
– oxidized
(consists of
flavin
mononucleotid
(FMN) unit
[green] and
adenin mono
phosphate
(AMP) [red]
Iron Sulfur center (Fe–S) in Complex II in ETC
Succinate → FumarateFAD(ox) → FADH2(red)
Ferric (+3) oxidized form → Ferros (+2) reduced form
Fe+3–S(ox) → Fe+2–S(red)
Fe+2–S(red) → Fe+3–S(ox)
…
Fe+3–S(ox) → Fe+2–S(red)
Fe+2–S(red) → Fe+3–S(ox)
…
Coenzyme Qn (Ubiquinone(ox))→ Coenzyme QnH2(Ubiquinol(red))
this all increasing ubiquinol pool
Complex III in Electron Transport Chain
Cytochrome c Ubiquinol
oxidoreductase [Q cycle]
12 polypeptide chains
Complex III do transfer
protons (2H+) into
intermembrane space
Cytochrome c Ubiquinol oxidoreductase [Q cycle]
Complex III
QH2 →–→ e → 2Fe–2S
2Fe–2S→Heme c→Cytochrome c(red)→complex IV
e– → Heme blowpotencial → Heme bhighpotencial
Semiquinol intermediate radical
[Q` ubiquinol with one electron]
Heme (AmE) or haem (BrE) is a cofactor has an Fe2+ (ferrous) ion in the
middle of a large heterocyclic organic ring called a porphyrin, made up
of 4 pyrrolic groups joined together by methine bridges(5,10,15,20).
Not all porphyrins contain iron, but a
substantial fraction of porphyrin-
containing metalloproteins have heme
as their prosthetic group; these are
known as hemoproteins. Hemes are
most commonly recognized as
components of hemoglobin, the red
pigment in blood, but are also found in
a number of other biologically
important hemoproteins such as
myoglobin, cytochrome, catalase, and
endothelial nitric oxide synthase.
Complex IV in Electron Transport Chain
Cytochrome c oxidaze
Complex IV do transfer
protons (2H+) into
intermembrane space
Three-dimensional structure of reduced cytochrome c.The heme group (red), methionine 80 (green), histidine 18 (blue), and the
α-carbon atoms are shown. [from tuna]
ATP synthase and arrangment
of gens encoding the subunits
of ATP synthase in E.coli. This
cluster of genes is called
uncoupled operon (unc)
ATP synthase – the three catalytic sites cyclr through
three conformational states: O [open], L[loose
binding], T [tight binding]. Proton flux through the
syntase drives this interconversion of states. The
essence of this proposed mechanism is that proton flux
lead to the release of tightly bound ATP.
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