Succinate oxidation Much is known about the
succinate oxidation mechanism, which involves the transfer of a proton and a hydride. A combination of mutagenesis and structural analysis identifies Arg-286 of the SDHA subunit (
E. coli numbering) as the proton shuttle.
Crystal structures of the enzymes from multiple organisms shows that this is well poised for the proton transfer step. Thereafter, there are two possible elimination mechanisms: E2 or E1cb. In the E2 elimination, the mechanism is concerted. The basic
residue or
cofactor deprotonates the
alpha carbon, and FAD accepts the
hydride from the
beta carbon,
oxidizing the bound
succinate to
fumarate—refer to image 6. In E1cb, an
enolate intermediate is formed, shown in image 7, before
FAD accepts the
hydride. Further research is required to determine which elimination mechanism succinate undergoes in Succinate Dehydrogenase.
Oxidized fumarate, now loosely bound to the
active site, is free to exit the
protein.
Electron tunneling After the
electrons are derived from
succinate oxidation via
FAD, they tunnel along the [Fe-S] relay until they reach the [3Fe-4S] cluster. These
electrons are subsequently transferred to an awaiting
ubiquinone molecule within the
active site. The
Iron-
Sulfur electron tunneling system is shown in image 9.
Ubiquinone reduction The O1
carbonyl oxygen of
ubiquinone is oriented at the active site (image 4) by
hydrogen bond interactions with Tyr83 of subunit D. The presence of
electrons in the [3Fe-4S] iron sulphur cluster induces the movement of
ubiquinone into a second orientation. This facilitates a second
hydrogen bond interaction between the O4
carbonyl group of
ubiquinone and Ser27 of subunit C. Following the first single
electron reduction step, a
semiquinone radical species is formed. The second
electron arrives from the [3Fe-4S] cluster to provide full reduction of the
ubiquinone to
ubiquinol. This mechanism of the
ubiquinone reduction is shown in image 8.
Heme prosthetic group Although the functionality of the
heme in succinate dehydrogenase is still being researched, some studies have asserted that the first
electron delivered to
ubiquinone via [3Fe-4S] may tunnel back and forth between the
heme and the
ubiquinone intermediate. In this way, the
heme cofactor acts as an
electron sink. Its role is to prevent the interaction of the intermediate with
molecular oxygen to produce
reactive oxygen species (ROS). The
heme group, relative to
ubiquinone, is shown in image 4. It has also been proposed that a gating
mechanism may be in place to prevent the
electrons from tunneling directly to the
heme from the [3Fe-4S] cluster. A potential candidate is
residue His207, which lies directly between the cluster and the
heme. His207 of subunit B is in direct proximity to the [3Fe-4S] cluster, the bound
ubiquinone, and the
heme; and could modulate
electron flow between these redox centers.
Proton transfer To fully reduce the
quinone in SQR, two
electrons as well as two
protons are needed. It has been argued that a
water molecule (HOH39) arrives at the
active site and is coordinated by His207 of subunit B, Arg31 of subunit C, and Asp82 of subunit D. The
semiquinone species is
protonated by
protons delivered from HOH39, completing the
ubiquinone reduction to
ubiquinol. His207 and Asp82 most likely facilitate this process. Other studies claim that Tyr83 of subunit D is coordinated to a nearby
histidine as well as the O1
carbonyl oxygen of
ubiquinone. The
histidine residue decreases the
pKa of
tyrosine, making it more suitable to donate its
proton to the reduced
ubiquinone intermediate. == Inhibitors ==