18 × vmax [12] From NET it is known that such a maximum is produ

18 × vmax [12]. From NET it is known that such a maximum is produced by uncoupling.

To create such a maximal efficiency, uncoupling terms have to be incorporated into JStr. Variable, load dependent λ values (λ(AStrLd) instead of constant λ’s) are defined, to preserve the hyperbolic nature of the function. In this way, uncoupling becomes operative only when AStrLd exceeds a certain value (Figure 1A). Both flux equations are given by: (11a) (11b) These latter equations (for Inhibitors,research,lifescience,medical a complete description, especially of conductances, see (A15)) appear in simulations. λ values are given as functions of AStrLd, e.g., (12) (see below for a mechanistic interpretation of uncoupling and λ values). Conversion to mechanical units can then be done

in the same way as shown above. In Figure 1 the effects of uncoupling are shown. At a load of about −3.0×104 J/mol, deviations from the hyperbolic (coupled) curve begin to arise. From the plots it can be seen that uncoupling leads to a shift of the intersection with the abscissa to less negative values Inhibitors,research,lifescience,medical of AStrLd, whereas – (JStrP) is still maintained, even at AStrLd = – (AStrP), where the coupled flux must be zero and only uncoupled fluxes Inhibitors,research,lifescience,medical are possible. In the following, an attempt has been made to interpret the above results, which were gained from a phenomenological approach, mechanistically by relating coupled and uncoupled fluxes to possible cross-bridge actions. At AStrLd = – (AStrP), coupled reactions with associated actin filament movement come to a halt, because the driving force has vanished. As already mentioned above, now only uncoupled fluxes can occur. Such a situation may also be realised with isometric contraction, which is Inhibitors,research,lifescience,medical known to be associated with ATP splitting and heat production, but without power output. That is, a mechanism has to be found which explains the identity of the isometric force F0 with FP, which was merely formally derived from the input affinity AStrP by a conversion factor. This

is achieved by defining the uncoupling Inhibitors,research,lifescience,medical mechanism by a shortening of the stroke length lStr of the power stroke. Total uncoupling is reached when lStr = 0. This may be realised under isometric conditions. Free energy corresponding to AStrP ≈ AATP is delivered Brefeldin_A to actin filaments as mechanical work, i. e., F0 × lStr × NA = AStrP. Shortening may be brought about through splitting of actomyosin bonds before the whole stroke length is transferred to an actin filament. When AStrLd = – AStrP, as is realised under isometric conditions, actomyosin splitting already occurs at zero stroke length, so that no energy can be delivered to the actin filaments. Only force development by cross-bridges during the time interval between bond formation and bond splitting is possible under these conditions. This may be achieved by the torque every myosin head exerts on an actin filament after bond formation and release of H2PO4− and MgADP−.

Leave a Reply

Your email address will not be published. Required fields are marked *

*

You may use these HTML tags and attributes: <a href="" title=""> <abbr title=""> <acronym title=""> <b> <blockquote cite=""> <cite> <code> <del datetime=""> <em> <i> <q cite=""> <strike> <strong>