44

2.4  Cell Processes

electrochemical “redox reactions.” Each full redox reaction is the sum of two separate half

reactions involving reduction and oxidation, each of which has an associated reduction

potential (E0), which is the measure of the equivalent electrode voltage potential if that spe­

cific chemical half reaction was electrically coupled to a standard hydrogen electrode (the

term standard means that all components are at concentrations of 1 M, but confusingly the

biochemical standard state electrode potential is the same as the standard state electrode

potential apart from the pH being 7; the pH is defined as −log10[H^+​ concentration] and thus

indicates a concentration of H^+​ of 10⁻⁷ M for the biochemical standard state).

The reduction half reaction for the electron acceptor NAD^+​ is

(2.1)

NAD

H

e

NADH

V

+

+

−

+

+

= −

2

0 315

0



E

.

An example of a reduction half reaction at one point in the TCA cycle (see Figure 2.8) involves

an electron acceptor called of “oxaloacetate⁻,” which is reduced to malate⁻:

(2.2)

Oxaloacetate

H

e

Malate

V

−

+

−

+

+

= −

2

2

0 166

0



E

.

These two reversible half reactions can be combined by taking one away from the other, so

malate⁻ then acts as an electron donor and in the process is oxidized back to oxaloacetate⁻,

which is exactly what occurs at one point in the TCA cycle (two other similar steps occur

coupled to the reduction of NAD+​, and another coupled to FAD^+​ reduction, Figure 2.8). The

concentrations of oxaloacetate and malate are kept relatively low in the cell at 50 nM and

0.2 mM, respectively, and these low concentrations compared to the high concentration of

acetyl-​CoA result in a large excess of NAD^+​.

A general reduction half reaction can be written as a chemical state O being reduced to a

chemical state R:

(2.3)

O +​ nH^+​ + ​ne^-​ ⇌ R

where the free energy change per mole associated with this process can be calculated from

the electrical and chemical potential components:

(2.4)

∆

∆

G

G

RT

R

O H

nFE

n

=

+

[ ]

[ ][

]

= −

+

0

ln

where F is Faraday’s constant, 9.6 × 10⁴ C mol⁻¹, equivalent to the magnitude of the electron

charge q multiplied by Avogadro’s number NA, n electrons in total being transferred in the

process. This also allows the molar equilibrium constant K to be calculated:

(2.5)

K

nFE

RT

nqE

k T

=



^



^=



^



^

exp

exp

B

0

0

where R is the molar gas constant, equal to kBNA, with absolute temperature T. Equation 2.4

can be rewritten by dividing through by −nF:

(2.6)

E

E

k T

nq

R

O H

B

n

=

−

[ ]

[ ][

]

+

0

ln

Equation 2.6 is called the “Nernst equation.”

The free energy of oxidation of NADH and FADH is coupled to molecular machines,

which pump protons across either the mitochondrial inner membrane (eukaryotes) or cyto­

plasmic membrane (prokaryotes) from the inside to the outside, to generate a proton motive

force (pmf), Vpmf, of typical value −200 mV relative to the inside. The free energy required to

pump a single proton against this pmf can be calculated from Equation 2.4 equating Vpmf to