Kinetic Tuning of Myosin via a Flexible Loop Adjacent to the Nucleotide Binding Pocket (original) (raw)
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Functional Role of Loop 2 in Myosin V †
Biochemistry, 2004
Myosin V is molecular motor that is capable of moving processively along actin filaments. The kinetics of monomeric myosin V containing a single IQ domain (MV 1IQ) differ from nonprocessive myosin II in that actin affinity is higher, phosphate release is extremely rapid, and ADP release is ratelimiting. We generated two mutants of myosin V by altering loop 2, a surface loop in the actin-binding region thought to alter actin affinity and phosphate release in myosin II, to determine the role that this loop plays in the kinetic tuning of myosin V. The loop 2 mutants altered the apparent affinity for actin (K ATPase) without altering the maximum ATPase rate (V MAX). Transient kinetic analysis determined that the rate of binding to actin, as well as the affinity for actin, was dependent on the net positive charge of loop 2, while other steps in the ATPase cycle were unchanged. The maximum rate of phosphate release was unchanged, but the affinity for actin in the M‚ADP‚Pi-state was dramatically altered by the mutations in loop 2. Thus, loop 2 is important for allowing myosin V to bind to actin with a relatively high affinity in the weak binding states but does not play a direct role in the product release steps. The ability to maintain a high affinity for actin in the weak binding states may prevent diffusion away from the actin filament and increase the degree of processive motion of myosin V.
The role of surface loops (residues 204-216 and 627-646) in the motor function of the myosin head
Proceedings of the National Academy of Sciences of the United States of America, 1996
A characteristic feature of all myosins is the presence of two sequences which despite considerable variations in length and composition can be aligned with loops 1 (residues 204-216) and 2 (residues 627-646) in the chicken myosin-head heavy chain sequence. Recently, an intriguing hypothesis has been put forth suggesting that diverse performances of myosin motors are achieved through variations in the sequences of loops 1 and 2 [Spudich, J. (1994) Nature (London) 372, 515-518]. Here, we report on the study of the effects of tryptic digestion of these loops on the motor and enzymatic functions of myosin. Tryptic digestions of myosin, which produced heavy meromyosin (HMM) with different percentages of molecules cleaved at both loop 1 and loop 2, resulted in the consistent decrease in the sliding velocity of actin filaments over HMM in the in vitro motility assays, did not affect the Vmax, and increased the Km values for actin-activated ATPase of HMM. Selective cleavage of loop 2 on HM...
A structural state of the myosin V motor without bound nucleotide
Nature, 2003
The myosin superfamily of molecular motors use ATP hydrolysis and actin-activated product release to produce directed movement and force 1 . Although this is generally thought to involve movement of a mechanical lever arm attached to a motor core 1,2 , the structural details of the rearrangement in myosin that drive the lever arm motion on actin attachment are unknown. Motivated by kinetic evidence that the processive unconventional myosin, myosin V, populates a unique state in the absence of nucleotide and actin, we obtained a 2.0 Å structure of a myosin V fragment. Here we reveal a conformation of myosin without bound nucleotide. The nucleotide-binding site has adopted new conformations of the nucleotide-binding elements that reduce the affinity for the nucleotide. The major cleft in the molecule has closed, and the lever arm has assumed a position consistent with that in an actomyosin rigor complex. These changes have been accomplished by relative movements of the subdomains of the molecule, and reveal elements of the structural communication between the actin-binding interface and nucleotide-binding site of myosin that underlie the mechanism of chemo-mechanical transduction.
Mechanism of action of myosin X, a membrane-associated molecular motor
We have performed a detailed biochemical kinetic and spectroscopic study on a recombinant myosin X head construct to establish a quantitative model of the enzymatic mechanism of this membrane-bound myosin. Our model shows that during steady-state ATP hydrolysis, myosin X exhibits a duty ratio (i.e. the fraction of the cycle time spent strongly bound to actin) of around 16%, but most of the remaining myosin heads are also actin-attached even at moderate actin concentrations in the so-called "weak" actin-binding states. Contrary to the high duty ratio motors myosin V and VI, the ADP release rate constant from actomyosin X is around five times greater than the maximal steadystate ATPase activity, and the kinetic partitioning between different weak actin-binding states is a major contributor to the rate limitation of the enzymatic cycle. Two different ADP states of myosin X are populated in the absence of actin, one of which shows very similar kinetic properties to actomyosin⅐ADP. The nucleotide-free complex of myosin X with actin shows unique spectral and biochemical characteristics, indicating a special mode of actomyosin interaction.
Besides driving contraction of various types of muscle tissue, conventional (class II) myosins serve essential cellular functions and are ubiquitously expressed in eukaryotic cells. Three different isoforms in the human myosin complement have been identified as non-muscle class II myosins. Here we report the kinetic characterization of a human non-muscle myosin IIB subfragment-1 construct produced in the baculovirus expression system. Transient kinetic data show that most steps of the actomyosin ATPase cycle are slowed down compared with other class II myosins. The ADP affinity of subfragment-1 is unusually high even in the presence of actin filaments, and the rate of ADP release is close to the steady-state ATPase rate. Thus, non-muscle myosin IIB subfragment-1 spends a significantly higher proportion of its kinetic cycle strongly attached to actin than do the muscle myosins. This feature is even more pronounced at slightly elevated ADP levels, and it may be important in carrying out the cellular functions of this isoform working in small filamentous assemblies.
Kinetic Characterization of the Function of Myosin Loop 4 in the Actin−Myosin Interaction †
Biochemistry, 2008
Myosin interacts with actin during its enzymatic cycle, and actin stimulates myosin's ATPase activity. There are extensive interaction surfaces on both actin and myosin. Several surface loops of myosin play different roles in actomyosin interaction. However, the functional role of loop 4 in actin binding is still ambiguous. We explored the role of loop 4 by either mutating its conserved acidic group, Glu-365, to Gln (E365Q), or by replacing the entire loop with three glycines (∆AL) in a Dictyostelium discoideum myosin II motor domain (MD) containing a single tryptophan residue. This native tryptophan (Trp-501) is located in the relay loop and is sensitive to nucleotide binding and lever-arm movement. Fluorescence and fast kinetic measurements showed that the mutations in loop 4 do not alter the enzymatic steps of the ATPase cycle in the absence of actin. By contrast, actin binding was significantly weakened in the absence and presence of ADP and ATP in both mutants. Because the strength of actin-myosin interaction increases in the order of rigor, ADP, and ATP complex, we conclude that loop 4 is a functional actin-binding region that stabilizes actomyosin complex, particularly in weak actin-binding states. domain; M, myosin; A, actin; F-actin, filamentous actin; PyA, pyrene labeled F-actin; SEM, standard error of the mean. FIGURE 1: Simulated structure of the actomyosin interaction surface. A part of the actin-myosin interface in the model complex obtained by fitting chicken myosin II MD into cryo-EM electron density map of actomyosin complex (13). Actin monomers are shown in purple, light blue and light green, myosin MD is yellow and loop 4 is black. The basic amino acids (Lys-326, Lys-328 and Arg-147) of actin form a salt bridge cluster with Glu-373 (Glu-365 in Dictyostelium myosin II) of loop 4. Phe-366 (Phe-359 in Dictyostelium myosin II) stabilizes the cardiomyopathy loop (CM-loop), loop 4 and the N-terminal of the long Val 419 -Gln 448 (Asn 410 -Cys 442 Dictyostelium myosin II) R-helix which spans along the 50 kDa myosin subdomain. Phe-366, Lys-326, Lys-328 and Arg-147 are shown in spheres and colored as follows: carbon atoms are gray, oxygen atoms are red and nitrogen atoms are blue.
Biochimica et Biophysica Acta (BBA) - Enzymology, 1978
The binding of myosin to nylon fiber gives immobilized myosin with a considerable ATPase activity. Treatment of immobilized enzyme with papain results in the entire ATPase activity (known to be concentrated in myosin heads, (fragment HMM S-l)} being replaced from the fiber into the solution; this means that myosin is chemically bound to the fiber via its rod part (fragment LMM + HMM S-2). When nylon fiber is mechanically stretched, the ATPase activity of myosin attached to it sharply decreases; after relaxation of the fiber the enzymatic activity returns to the initial level. The detailed study of this phenomenon has shown that reversible inactivation of myosin upon fiber stretching is not the result of an altered microenvironment of the enzyme. The discovered regulatory effect is ascribed to deformation of myosin molecules induced by support stretching. Thus deformation of the myosin tail (not indispensable for ATPase since its cleaving-off does not alter the enzymatic activity) leads to decrease in the ATPase activity of the enzyme. The possible role of the above phenomenon in the mechanism of muscle contraction is discussed.