Madeleine J. Headlam

Placental cytochrome P450scc (CYP11A1): comparison of catalytic properties between conditions of limiting and saturating adrenodoxin reductase

The mitochondrial side-chain cleavage of cholesterol, catalysed by cytochrome P450scc, is rate-limiting in the synthesis of progesterone by the human placenta. Cytochrome P450scc activity is in turn limited by the concentration of adrenodoxin reductase (AR) in placental mitochondria. In order to better understand which components of the cholesterol side-chain cleavage system are important in the regulation of placental progesterone synthesis, we have examined their effects on P450scc activity with both saturating and limiting concentrations of AR. The present study reveals that decreasing the AR concentration causes a decrease in the K(m) of cytochrome P450scc for cholesterol, facilitating saturation of the enzyme with its substrate. Decreasing AR resulted in P450scc activity becoming less sensitive to changes in P450scc concentration. The adrenodoxin (Adx) concentration in mitochondria from term placentae is near-saturating for P450scc and under these conditions, we found that decreasing AR reduces the K(m) of P450scc for adrenodoxin. Increasing either the cholesterol or P450scc concentration increased the amount of AR required for P450scc to work at half its maximum velocity. A relatively small increase in AR can support considerably higher rates of side-chain cleavage activity when there is a coordinate increase in AR and P450scc concentrations. We conclude from this study that cholesterol is near-saturating for cytochrome P450scc activity in placental mitochondria due to the P450scc displaying a low K(m) for cholesterol resulting from the low and rate-limiting concentration of AR present. This study reveals that it is unlikely that cholesterol or adrenodoxin concentrations are important regulators of placental progesterone synthesis but AR or coordinate changes in AR and P450scc concentrations are likely to be important in its regulation.

The effect of glycerol on cytochrome P450scc (CYP11A1) spin state, activity, and hydration

We examined the effects of glycerol, a stabilizing agent commonly used in cytochrome P450scc purification and analysis, on the spin state, catalytic activity, and molecular volume of the cytochrome. Glycerol induced a sigmoidal low-spin response. The binding of hydroxycholesterol reaction intermediates, but not cholesterol, increased the concentration of glycerol required for the spin transition to be 50% complete (K(1/2)). Glycerol weakened adrenodoxin binding to P450scc but had no effect on CO or 20alpha,22R-dihydroxycholesterol binding. Cytochrome P450scc activity was inhibited by glycerol with the K(1/2) for inhibition being substrate-dependent. The osmotic stress exerted by glycerol on P450scc resulted in decreases in P450scc molecular volume for both the transition to low spin state and the inhibition of activity. From this we determined that two dissociative water molecules are involved in the inhibition of activity with cholesterol as substrate and five or six dissociative waters are involved in the low-spin transition. The dehydration of P450scc by osmotic stress provides an explanation for the effects of glycerol on P450scc spin transition and activity.