Rotary F1-ATPase. Is the C-terminus of subunit gamma fixed or mobile?

F-ATP synthase synthesizes ATP at the expense of ion motive force by a rotary coupling mechanism. A central shaft, subunit gamma, functionally connects the ion-driven rotary motor, F(O), with the rotary chemical reactor, F(1). Using polarized spectrophotometry we have demonstrated previously the functional rotation of the C-terminal alpha-helical portion of gamma in the supposed 'hydrophobic bearing' formed by the (alpha beta)(3) hexagon.

Rotation of the c subunit oligomer in EF(0)EF(1) mutant cD61N.

ATP synthases (F(0)F(1)-ATPases) mechanically couple ion flow through the membrane-intrinsic portion, F(0), to ATP synthesis within the peripheral portion, F(1). The coupling most probably occurs through the rotation of a central rotor (subunits c(10)epsilon gamma) relative to the stator (subunits ab(2)delta(alpha beta)(3)). The translocation of protons is conceived to involve the rotation of the ring of c subunits (the c oligomer) containing the essential acidic residue cD61 against subunits ab(2).

F-ATPase: forced full rotation of the rotor despite covalent cross-link with the stator.

In ATP synthase (F(O)F(1)-ATPase) ion flow through the membrane-intrinsic portion, F(O), drives the central "rotor", subunits c(10)epsilongamma, relative to the "stator" ab(2)delta(alphabeta)(3). This converts ADP and P(i) into ATP. Vice versa, ATP hydrolysis drives the rotation backwards.

Inter-subunit rotation and elastic power transmission in F0F1-ATPase.

ATP synthase (F-ATPase) produces ATP at the expense of ion-motive force or vice versa. It is composed from two motor/generators, the ATPase (F1) and the ion translocator (F0), which both are rotary steppers. They are mechanically coupled by 360 degrees rotary motion of subunits against each other.

Viscoelastic dynamics of actin filaments coupled to rotary F-ATPase: angular torque profile of the enzyme.

ATP synthase (F(O)F(1)) operates as two rotary motor/generators coupled by a common shaft. Both portions, F(1) and F(O), are rotary steppers. Their symmetries are mismatched (C(3) versus C(10-14)).

F-ATPase: specific observation of the rotating c subunit oligomer of EF(o)EF(1).

The rotary motion in response to ATP hydrolysis of the ring of c subunits of the membrane portion, F(o), of ATP synthase, F(o)F(1), is still under contention. It was studied with EF(o)EF(1) (Escherichia coli) using microvideography with a fluorescent actin filament. To overcome the limited specificity of actin attachment through a Cys-maleimide couple which might have hampered the interpretation of previous work, we engineered a 'strep-tag' sequence into the C-terminal end of subunit c.