Fig 1.
Functional cycle of single- and double-headed myosin.
(A) Sequence of events of the mechanochemical cycle of the single-headed myosin. ATP bound (red) head (i) binds to the actin filament followed by the hydrolysis of ATP. The arm (black line on head) of this actin bound head (ii) in ADP + Pi state (pink) has a pre-powerstroke conformation. Phosphate (Pi) release induces the powerstroke conformational change to the lever arm (iii). Next, ADP (blue) is released from the bound head while keeping the post-powerstroke lever arm conformation (iv). Finally, the empty head (gray) detaches from the actin followed by an ATP intake. The ATP dependent unbound head experiences a repriming event to its stable pre-powerstroke lever arm conformation (v). Note that, state (v) is exactly same as state (i) with an additional stepping towards left and also the nucleotide dependent actin binding affinity information in the middle. (B) The sequence of events of the functional cycle of the double-headed myosin. In state (i), head 1 is in an ATP bound state and head 2 is bound to actin in an ADP state. ATP hydrolysis and subsequent binding to actin by head 1 provide a two-head bound myosin (ii). Head 1 releases phosphate (Pi) to transform into state (iii). In contrary to a single-head myosin, here, after Pi release, head 1 cannot perform powerstroke while head 2 is still bound. The green line shows the expected lever arm conformation of head 1. It is important to note here that the two-head-bound state iii could adopt an alternative conformation with the converters of both heads in a post-powerstroke conformation while the lever arm of the leading/trailing head bends backward/forward. Next, ADP releases from head 2 (iv) and subsequently ATP binds to the empty head. Head 2 now detaches from the actin and head 1 now performs its postponed powerstroke step. Finally, head 2 also perform its spontaneous repriming event to form state (v). Note that, state (v) is exactly same as state (i) with an additional stepping towards the left.
Fig 2.
Two important conformational states of the mechanical cycle of myosin.
(A) Pre- (PDB 2V26 [34]) and post-powerstroke (PDB 2BHK [36]) states of the myosin motor showing the motor head (MH) and the converter domains. Note the change in the conformation of the converter domain with respect to the MH in the two conformations. The competing interactions (contacts) between the MH and the converter domains, responsible for stabilizing these two states, are shown by lines. (B) Residue-residue contact map for both the conformations. The two dotted green lines are drawn to separate the contact maps of the MH and the converter domains. In the upper triangle, the post-powerstroke contact map (red) is overlaid upon the pre-powerstroke contact map (blue) to identify the exclusive converter-MH contacts in the pre-powerstroke state (shown by lines in Fig 2A). In contrast, the same data have been overlaid in opposite order (blue upon red) in the lower triangle to extract the exclusive converter-MH contacts in the post-powerstroke state (those interactions are shown by lines in Fig 2A).
Fig 3.
Structural adaptation of the trailing head signals faster ADP release.
(A) Myosin MH domain structure showing the big (red) and small (green) subunits. (B) Nucleotide binding region of the MH domain is shown in terms of P-loop (blue), switch I (red) and switch II (green). (C) RMSD distribution (P(RMSD)) of the small subunit of the MH domain after least square fitting of the big subunit from the leading and trailing head simulations. The RMSD is calculated with respect to the pre-powerstroke MH conformation. Note the larger RMSD for the trailing head indicating substantial structural changes. (D) Distribution of distances between P-loop and switch I (P(dSWI-Ploop)) for the leading and trailing head simulations. (E) Distribution of distances between P-loop and switch II (P(dSWII-Ploop)) for the leading and trailing head simulations. (F) Distribution of distances between switch I and switch II (P(dSWI-SWII)) for the leading and trailing head simulations. A larger distance between switch I and switch II for the trailing head simulation compared to leading head signals faster ADP release.
Fig 4.
Strain regulates the ADP release kinetics of the trailing head.
(A) A schematic representation of myosin dimer showing how Pi release can create strain on the trailing head. This strain arises due to the postponed-powerstroke waiting state of the leading head (left head). (B) Probability distribution of distances between small and big subunits of the MH domain at different level of strain on the trailing head. This distribution shifts towards the larger distances as strain increases, which leads to an increase in ADP release rate with increasing strain.
Fig 5.
Powerstroke of the myosin motors.
(A) Powerstroke step with the release of Pi. The residues involved in the Pi mediated interactions in terms of p-loop (blue), switch I (red) and switch II (green) are shown. (B) RMSD (with respect to pre-powerstroke crystal structure) distribution for the simulation with Pi mediated interaction. The population of the pre-powerstroke ensemble is higher. (C) RMSD (with respect to pre-powerstroke crystal structure) distribution for the simulation without Pi mediated interactions. Note the inversion of the distribution with phosphate release making post-powerstroke ensemble as the dominant one.