Familial hypertrophic cardiomyopathy mutations in the regulatory light chains of myosin affect their structure, Ca2+ binding, and phosphorylation.

The effect of the familial hypertrophic cardiomyopathy mutations, A13T, F18L, E22K, R58Q, and P95A, found in the regulatory light chains of human cardiac myosin has been investigated. The results demonstrate that E22K and R58Q, located in the immediate extension of the helices flanking the regulatory light chain Ca(2+) binding site, had dramatically altered Ca(2+) binding properties. The K(Ca) value for E22K was decreased by approximately 17-fold compared with the wild-type light chain, and the R58Q mutant did not bind Ca(2+). Interestingly, Ca(2+) binding to the R58Q mutant was restored upon phosphorylation, whereas the E22K mutant could not be phosphorylated. In addition, the alpha-helical content of phosphorylated R58Q greatly increased with Ca(2+) binding. The A13T mutation, located near the phosphorylation site (Ser-15) of the human cardiac regulatory light chain, had 3-fold lower K(Ca) than wild-type light chain, whereas phosphorylation of this mutant increased the Ca(2+) affinity 6-fold. Whereas phosphorylation of wild-type light chain decreased its Ca(2+) affinity, the opposite was true for A13T. The alpha-helical content of the A13T mutant returned to the level of wild-type light chain upon phosphorylation. The phosphorylation and Ca(2+) binding properties of the regulatory light chain of human cardiac myosin are important for physiological function, and alteration any of these could contribute to the development of hypertrophic cardiomyopathy.

Abnormal contractile function in transgenic mice expressing a familial hypertrophic cardiomyopathy-linked troponin T (I79N) mutation.

This study characterizes a transgenic animal model for the troponin T (TnT) mutation (I79N) associated with familial hypertrophic cardiomyopathy. To study the functional consequences of this mutation, we examined a wild type and two I79N-transgenic mouse lines of human cardiac TnT driven by a murine alpha-myosin heavy chain promoter. Extensive characterization of the transgenic I79N lines compared with wild type and/or nontransgenic mice demonstrated: 1) normal survival and no cardiac hypertrophy even with chronic exercise; 2) large increases in Ca(2+) sensitivity of ATPase activity and force in skinned fibers; 3) a substantial increase in the rate of force activation and an increase in the rate of force relaxation; 4) lower maximal force/cross-sectional area and ATPase activity; 5) loss of sensitivity to pH-induced shifts in the Ca(2+) dependence of force; and 6) computer simulations that reproduced experimental observations and suggested that the I79N mutation decreases the apparent off rate of Ca(2+) from troponin C and increases cross-bridge detachment rate g. Simulations for intact living fibers predict a higher basal contractility, a faster rate of force development, slower relaxation, and increased resting tension in transgenic I79N myocardium compared with transgenic wild type. These mechanisms may contribute to mortality in humans, especially in stimulated contractile states.

Altered regulation of cardiac muscle contraction by troponin T mutations that cause familial hypertrophic cardiomyopathy.

To study the effect of troponin (Tn) T mutations that cause familial hypertrophic cardiomyopathy (FHC) on cardiac muscle contraction, wild-type, and the following recombinant human cardiac TnT mutants were cloned and expressed: I79N, R92Q, F110I, E163K, R278C, and intron 16(G(1) --> A) (In16). These TnT FHC mutants were reconstituted into skinned cardiac muscle preparations and characterized for their effect on maximal steady state force activation, inhibition, and the Ca(2+) sensitivity of force development. Troponin complexes containing these mutants were tested for their ability to regulate actin-tropomyosin(Tm)-activated myosin-ATPase activity. TnT(R278C) and TnT(F110I) reconstituted preparations demonstrated dramatically increased Ca(2+) sensitivity of force development, while those with TnT(R92Q) and TnT(I79N) showed a moderate increase. The deletion mutant, TnT(In16), significantly decreased both the activation and the inhibition of force, and substantially decreased the activation and the inhibition of actin-Tm-activated myosin-ATPase activity. ATPase activation was also impaired by TnT(F110I), while its inhibition was reduced by TnT(R278C). The TnT(E163K) mutation had the smallest effect on the Ca(2+) sensitivity of force; however, it produced an elevated activation of the ATPase activity in reconstituted thin filaments. These observed changes in the Ca(2+) regulation of force development caused by these mutations would likely cause altered contractility and contribute to the development of FHC.

The role of the NH(2)- and COOH-terminal domains of the inhibitory region of troponin I in the regulation of skeletal muscle contraction.

The role of the inhibitory region of troponin (Tn) I in the regulation of skeletal muscle contraction was studied with three deletion mutants of its inhibitory region: 1) complete (TnI-(Delta96-116)), 2) the COOH-terminal domain (TnI-(Delta105-115)), and 3) the NH(2)-terminal domain (TnI-(Delta95-106)). Measurements of Ca(2+)-regulated force and relaxation were performed in skinned skeletal muscle fibers whose endogenous TnI (along with TnT and TnC) was displaced with high concentrations of added troponin T. Reconstitution of the Tn-displaced fibers with a TnI.TnC complex restored the Ca(2+) sensitivity of force; however, the levels of relaxation and force development varied. Relaxation of the fibers (pCa 8) was drastically impaired with two of the inhibitory region deletion mutants, TnI-(Delta96-116).TnC and TnI-(Delta105-115).TnC. The TnI-(Delta95-106).TnC mutant retained approximately 55% relaxation when reconstituted in the Tn-displaced fibers. Activation in skinned skeletal muscle fibers was enhanced with all TnI mutants compared with wild-type TnI. Interestingly, all three mutants of TnI increased the Ca(2+) sensitivity of contraction. None of the TnI deletion mutants, when reconstituted into Tn, could inhibit actin-tropomyosin-activated myosin ATPase in the absence of Ca(2+), and two of them (TnI-(Delta96-116) and TnI-(Delta105-115)) gave significant activation in the absence of Ca(2+). These results suggest that the COOH terminus of the inhibitory region of TnI (residues 105-115) is much more critical for the biological activity of TnI than the NH(2)-terminal region, consisting of residues 95-106. Presumably, the COOH-terminal domain of the inhibitory region of TnI is a part of the Ca(2+)-sensitive molecular switch during muscle contraction.

The effect of pH on the Ca2+ affinity of the Ca2+ regulatory sites of skeletal and cardiac troponin C in skinned muscle fibres.

It is known that intracellular pH drops rapidly after the onset of ischemia in cardiac muscle and may play some role in the rapid drop in force that ensues. It is also known that alpha 1-adrenoceptor agonists alkalinize intracellular pH by stimulating Na+/H+ exchange and may represent a mechanism which facilitates recovery of intracellular pH from acidosis. Lowering or raising pH shifts the Ca2+ dependence of force development in muscle fibres to higher or lower free Ca2+ concentrations, respectively, yet the precise mechanism is unknown. To investigate this phenomenon we have used skinned skeletal or cardiac muscle fibres whose endogenous troponin C (TnC) has been replaced with chicken skeletal TnC labelled with DANZ (STnCDANZ) or recombinant cardiac TnC labelled with IAANS (CTnC3(C84)[AANS), respectively. The fluorescence of the STnCDANZ or CTnC3(C84)IAANS was enhanced by Ca2+ binding to the Ca(2+)-specific (regulatory) site(s) of STnC or CTnC when incorporated into skinned fibres, and was measured simultaneously with force. When the pH was changed from 7.0 to 6.5 or 7.5 the shift in the Ca2+ dependence of force paralleled the shift in fluorescence. Since the force and fluorescence shift in parallel as the pH is lowered or raised, it can be concluded that these changes in Ca2+ sensitivity are caused by a decrease or increase, respectively, in the Ca2+ affinity of the Ca(2+)-specific site(s) of TnC. Since lowering or raising the pH also resulted in lower or higher, respectively, maximal Ca2+ activated force while maximal fluorescence remained unchanged, it is possible that H+ may act indirectly, as well, by reducing or increasing, respectively, the number or type of crossbridges attached to actin and thereby alter the crossbridge induced depression or elevation, respectively of the observed TnC Ca2+ affinity. Experiments with 2,3-butanedione monoxime, however, where force-generating crossbridges were greatly reduced, indicated that the pH effect may be primarily related to a direct change in the Ca2+ affinity to the regulatory sites of TnC.

The role of the four Ca2+ binding sites of troponin C in the regulation of skeletal muscle contraction.

In order to study the role of the Ca2+-specific sites (I and II) and the high affinity Ca2+-Mg2+ sites (III and IV) of TnC in the regulation of muscle contraction, we have constructed four mutants and the wild type (WTnC) of chicken skeletal TnC, with inactivated Ca2+ binding sites I and II (TnC1,2-), site III (TnC3-), site IV (TnC4-), and sites III and IV (TnC3,4C-). All Ca2+ binding site mutations were generated by replacing the Asp at the X-coordinating position of the Ca2+ binding loop with Ala. The binding of these mutated proteins to TnC-depleted skinned skeletal muscle fibers was investigated as well as the rate of their dissociation from these fibers. The proteins were also tested for their ability to restore steady state force to TnC-depleted fibers. We found that although the NH2-terminal mutant of TnC (TnC1,2-) bound to the TnC-depleted fibers (with a lower affinity than wild type TnC (WTnC)), it was unable to reactivate Ca2+-dependent force. This supports earlier findings that the low affinity Ca2+ binding sites (I and II) in TnC are responsible for the Ca2+-dependent activation of skeletal muscle contraction. All three COOH-terminal mutants of TnC bound to the TnC-depleted fibers, had different rates of dissociation, and could restore steady state force to the level of unextracted fibers. Although both high affinity Ca2+ binding sites (III and IV) are important for binding to the fibers, site III appears to be the primary determinant for maintaining the structural stability of TnC in the thin filament. Moreover, our results suggest an interaction between the NH2- and COOH-terminal domains of TnC, since alteration of sites I and II lowers the binding affinity of TnC to the fibers, and mutations in sites III and IV affect the Ca2+ sensitivity of force development.

The regulatory light chains of myosin modulate cross-bridge cycling in skeletal muscle.

We investigated the kinetics of Ca2+ activation of skeletal muscle contraction elicited by the photolysis of caged Ca2+. Previously we showed that partial extraction of the 18-kDa regulatory light chains (RLCs) of myosin decreased the rate of force development and was subsequently increased by approximately 20% following reconstitution with RLCs (Potter, J. D., Zhao, J. and Pan, B. S. (1992) FASEB J. 6, A1240). We extend here the RLC-extraction study to the complete removal of the RLCs. The complete removal of RLCs was achieved by a combination of 5,5'-dithiobis-(2-nitrobenzoic acid) and EDTA treatment followed by reduction of oxidized sulfydryl groups by dithiothreitol. Under these conditions the complete extraction of RLCs was accompanied by the extraction of endogenous troponin C, resulting in the loss of isometric tension. Steady state force was restored to 65-75% following troponin C reconstitution and increased to 75-85% as a result of RLC reincorporation into the fibers. The rates of force transients generated by UV-flash photolysis of 1-(2-nitro-4,5-dimethoxyphenyl)-N,N,N',N' -tetrakis[(oxycarbonyl)methyl]-1,2-ethanediamine) or nitrophenyl-EGTA, photoliberating bound Ca2+, decreased 2-fold after RLC extraction and troponin C reconstitution and then increased to the values of intact fibers after RLC reconstitution. These results support our earlier findings that the regulatory light chains of myosin play an important role in the kinetics of cross-bridge cycling.

The functional role of the domains of troponin-C investigated with thrombin fragments of troponin-C reconstituted into skinned muscle fibers.

Proteolysis of rabbit fast skeletal troponin-C (RSTnC) with thrombin produces four separate fragments containing the following Ca2+-binding site(s): TH1 (residues 1-120) sites I-III; TH2 (121-159) site IV; TH3 (1-100) sites I and II; and TH4 (101-120) site III. We studied the ability of these fragments to restore the steady state isometric force in TnC-depleted skinned skeletal muscle fibers. Interestingly, we found that all investigated fragments of RSTnC possessed some of the properties of native RSTnC, but none of them could fully regulate contraction in the fibers like intact RSTnC. TH1 was the most effective in the force restoration (65%) whereas the smaller fragments developed about 50% (TH3 and TH4) or 20% (TH2) of the initial force of unextracted fibers. Additionally, much higher concentrations of TH2, TH3, and TH4 compared to RSTnC OR TH1 were necessary for force development suggesting a decreased affinity of these fragments to their binding site(s) in the fibers. Like intact RSTnC, TH1 was able to interact with the fibers in a Ca(2+)-independent (Mg(2+)-dependent) manner, indicating that at a minimum, Ca(2+)-binding site III is required for this type of binding. The initial binding of the other fragments to the TnC-depleted fibers occurred only in the presence of Ca2+. TH2 and TH4 appeared to bind to two different binding sites in the fibers. The binding to one of the sites caused partial force restoration. This binding of TH2 and TH4 was abolished when Ca2+ was removed. TH2 and TH4 binding to the second site required Ca2+ initially but was maintained in the presence of Mg2+. This interaction of TH2 and TH4 partially blocked the rebinding of RSTnC to the fibers. The latter results suggest that site III and IV in these small fragments, when removed from the constraints of the parent protein, may assume conformations that allow them to function, to a certain extent, like both the regulatory sites (I and II) and the Ca(2+)-Mg2+ sites(III and IV) of TnC.

The tropomyosin domain is flexible and disordered in reconstituted thin filaments.

We have used EPR spectroscopy to study the rotational motion and orientation of tropomyosin labeled with maleimide spin-label, in skeletal muscle fibers. Fibers depleted of intrinsic myosin, troponin, and tropomyosin were reconstituted with labeled tropomyosin. The 3-7 ns mobility of the labeled domains was only slightly (2-fold) inhibited by reconstitution into fibers. No motional changes were observed on addition of troponin, irrespective of the presence of Ca2+; however, the binding of extrinsic myosin heads increased the rate of domain motion to that observed in solution. Orientational studies demonstrate a broad angular distribution of the labeled domain of tropomyosin, with respect to the fiber axis. Troponin reduces the orientational disorder, while the binding of Ca2+ to troponin partially reverses this ordering effect. Myosin S1 has no effect on the orientational distribution of tropomyosin. Overall, the observed changes are very small, implying a loose association of the probed domain of tropomyosin with the thin filament.

Significance of the N-terminal fragment of myosin regulatory light chain for myosin-actin interaction.

The influence of myosin regulatory light chains (LC2s) lacking the 2kD N-terminal portions of these chains, on internal organization of myosin heads and on actin-myosin interaction was studied with limited proteolysis and polarized fluorescence methods. For these studies heavy meromyosin (HMM) preparations were used: HMM containing intact LC2s (phosphorylated or dephosphorylated) and HMM containing LC2s lacking the 2kD N-terminal portions (including serine which can be phosphorylated). It was found that the susceptibility of the heavy chain cleavage site to trypsin and the alkali light chain (LC1) site to papain of myosin containing shortened regulatory LC2s, is not dependent on saturation of LC2s with Ca2+ or Mg2+ ions. This is in contrast to the myosin containing intact LC2s where Ca2+ or Mg2+ ion saturation does demonstrate a dependence. Similarly, in spectroscopic experiments, dephosphorylated HMM containing intact LC2s causes decrease or increase of actin filament flexibility depending on whether Mg2+ or Ca2+ are bound to LC2s. Correspondingly, HMM with shortened LC2s induces only increase of actin flexibility despite cations being bound. We conclude that the N-terminal fragment of LC2 is important for ensuring a proper Ca2+ dependent conformation of myosin head in the course of its actin-activated ATP hydrolysis.

Myosin S1 changes the orientation of caldesmon on actin.

Changes in the orientation of caldesmon bound to actin in skeletal ghost myofibrils caused by the binding of myosin subfragment 1 (S1) were measured by fluorescence-detected linear dichroism using fluorescence microscopy. Gizzard caldesmon, labeled with acrylodan at its two Cys residues (CaD*), bound to actin with a probe angle that was unaffected by actin-bound tropomyosin. Irrigation of fibrils with myosin S1 dissociated most of the bound CaD*, but reintroduction of CaD* resulted in its rebinding to actin, without dissociation of S1, with a 7 degrees difference in probe angle. A similar change in probe angle was also observed when a 27-kDa actin-binding C-terminal fragment of caldesmon, labeled with acrylodan at its single Cys 580 (CaD-27*), was used. Introducing MgADP, which bound to S1 in the CaD*-actin-S1 ternary complex in the fibril, reversed the bound CaD* dichroism. These results indicate that (i) myosin heads and caldesmon compete for a common actin binding site; (ii) a ternary complex of CaD*-actin-S1 can be formed with an orientation of CaD* different from that in the CaD*-actin binary complex, and (iii) MgADP, which binds to and reorients myosin S1, affects the orientation of CaD* in the ternary complex. These results are consistent with a two-state binding model of caldesmon for actin in which state 1 involves a site that is competitive with S1 binding and state 2 involves a site that is formed in the presence of bound S1.

The binding of fluorescent phallotoxins to actin in myofibrils.

Fluorescence microscope observation of myofibrils incubated with rhodamine-phalloidin and coumarine-phallacidin showed an initial appearance of fluorescence bands at the Z-lines and near the middle of the sarcomeres indicating preferential binding of dye to actin subunits located at both actin filament ends. After long incubation times (1-3 h) however, a final pattern is reached which consists of fluorescent Z-lines in the center of uniformly labelled actin bands, with greater fluorescence in the Z-lines than in the uniform region outside the Z-lines. Increasing the temperature or the ionic strength increased the rate of change to the final pattern. These data indicate: (1) that the ends of the actin filament are kinetically more accessible to phallotoxins; (2) at long times when equilibrium binding presumably occurs, the concentration of actin subunits in the Z-band is greater than in the rest of the sarcomere.

Linear dichroism of acrylodan-labeled tropomyosin and myosin subfragment 1 bound to actin in myofibrils.

Muscle contraction can be activated by the binding of myosin heads to the thin filament, which appears to result in thin filament structural changes. In vitro studies of reconstituted muscle thin filaments have shown changes in tropomyosin-actin geometry associated with the binding of myosin subfragment 1 to actin. Further information about these structural changes was obtained with fluorescence-detected linear dichroism of tropomyosin, which was labeled at Cys 190 with acrylodan and incorporated into oriented ghost myofibrils. The fluorescence from three sarcomeres of the fibril was collected with the high numerical aperture objective of a microscope and the dichroic ratio, R (0/90 degrees), for excitation parallel/perpendicular to the fibril, was obtained, which gave the average probe dipole polar angle, Theta. For both acrylodan-labeled tropomyosin bound to actin in fibrils and in Mg2+ paracrystals, Theta congruent to 52 degrees +/- 1.0 degrees, allowing for a small degree of orientational disorder. Binding of myosin subfragment 1 to actin in fibrils did not change Theta; i.e., the orientation of the rigidly bound probe on tropomyosin did not change relative to the actin axis. These data indicate that myosin subfragment 1 binding to actin does not appreciably perturb the structure of tropomyosin near the probe and suggest that the geometry changes are such as to maintain the parallel orientation of the tropomyosin and actin axes, a finding consistent with models of muscle regulation. Data are also presented for effects of MgADP on the orientation of labeled myosin subfragment 1 bound to actin in myofibrils.

[The disappearance of the dependence of actin-myosin interaction on the phosphorylation of myosin light chains in the "freezing" of the structure of heavy meromyosin by a bifunctional reagent]. / Ischeznovenie zavisimosti aktin-miozinovogo vzaimodeistviia ot fosforilirovaniia legkikh tsepei miozina pri "zamorazhivaniia" struktury tiazhelogo meromiozina bifunktsional'nym reagentom.

Using glycerinated muscle fibers, free of myosin, tropomyosin and troponin, a study was made of the structural state of F-actin modified by N-(iodoacetyl)-N'-(1-naphthyl-5-sulfo)-ethylendiamine (1.5-IAEDANS) and by rhodaminyl--phalloin at decoration of thin filaments with a proteolytic fragment of myosin--heavy meromyosin containing phosphorylated and dephosphorylated myosin light chains. The heavy meromyosin used has three SH-groups of heavy chain SH1, SH2 and SH chi modified by bifunctional reagent N,N'-n-phenylmaleimide (SH1-SH2, SH2-SH chi). At decoration of thin filaments with heavy meromyosin, some changes in polarized fluorescence of rhodaminyl--phalloin and 1.5-IAEDANS independent of phosphorylation of myosin light chains were found. Fluorescence anisotropy of the fiber was found to depend primarily on the character of heavy chain of SH-group modification. The ability of heavy chains to change their conformations is supposed to play an important role in the mechanism of myosin system modulation of muscle contraction.

[The effect of phosphorylation of myosin light chains on the structural state of tropomyosin in thin filaments, decorated with heavy meromyosin]. / Vliianie fosforilirovaniia legkikh tsepei miozina na strukturnoe sostoianie tropomiozina v tonkikh nitiakh,, dekorirovannykh tiazhelym meromiozinom.

The structural state of tropomyosin (TM) modified by 5-(iodoacetamidoethyl)-aminonaphthalene-1-sulfonate (1.5-IAEDANS) upon F-actin decoration with myosin subfragment 1 (S1) and heavy meromyosin (HMM) in glycerinated myosin- and troponin-free muscle fibers was studied. HMM preparations contained native phosphorylated myosin light chains, while S1 preparations did not. The changes in the polarized fluorescence of 1.5-IAEDANS-TM during the F-actin interaction with S1 were independent of light chains phosphorylation and Ca2+ concentration, but were dependent on these factors during the F-actin interaction with HMM. The binding of myosin heads to F-actin is supposed to initiate conformational changes in TM which are accompanied by changes in the flexibility and molecular arrangement of TM. In the presence of light chains, the structural changes in TM depend on light chains phosphorylation and Ca2+ concentration. The conformational changes in TM seem to be responsible for the mechanisms of coupling of the myosin and tropomyosin modulation system during the actin-myosin interaction in skeletal muscles.

Interaction of tropomyosin with F-actin-heavy meromyosin complex.

The effect of phosphorylated and dephosphorylated heavy meromyosins (HMMs) saturated with Ca2+ or Mg2+ on the binding of tropomyosin to F-actin and on the conformational changes of tropomyosin on actin was investigated. The experimental data were analysed on the basis of th emodel of cooperative binding of tropomyosin to F-actin with overlapping binding sites. In general, attachment of both HMMs to F-actin increased around 100-fold the tropomyosin-binding affinity but concomittantly reduced the cooperatively of binding. In the presence of Ca2+ and in the absence of ATP the binding of tropomyosin to F-actin in a "doubly contiguous" manner was three-fold stronger for F-actin saturated with dephosphorylated HMM as compared to phosphorylated HMM. Under the same rigor conditions but in the absence of Ca2+ the reverse was true but the difference was about 1.5-fold. The binding stoichiometry of tropomyosin to actin was 7:1 in the presence of dephosphorylated HMM saturated with Ca2+ or phosphorylated-saturated with Mg2+ and tended to be about 6:1 for both after the exchange of the cation bound to myosin heads. Bound HMM was also found to influence the fluorescence polarization of 1,5-IAEDANS-labelled tropomyosin complexed with F-actin in muscle ghost fibres. In the presence of Ca2+, the amount of randomly arranged tropomyosin fluorophores decreased when dephosphorylated HMM was bound to ghost fibres, in contrast to an observed increase in the case of bound phosphorylated HMM. Thus HMM induced conformational changes of tropomyosin in the actin-tropomyosin complex that was reflected in an alteration of the geometrical arrangement between tropomyosin and actin.(ABSTRACT TRUNCATED AT 250 WORDS)

Conformational changes of F-actin in myosin-free ghost single fibre induced by either phosphorylated or dephosphorylated heavy meromyosin.

The changes in F-actin conformation of myosin-free single ghost fibre induced by binding of phosphorylated or dephosphorylated heavy meromyosin have been studied by measuring polarized fluorescence of F-actin intrinsic tryptophan and of phalloidin-rhodamine bound to F-actin. The changes of polarization of both fluorescences were found to be dependent on low or high Ca2+ concentration and on the phosphorylated or dephosphorylated form of heavy meromyosin. Computer analysis of polarized fluorescence has shown that binding of phosphorylated heavy meromyosin with divalent ion binding sites saturated with Mg2 (in the presence of 1 mM MgCl2 and 1 mM EGTA) and dephosphorylated heavy meromyosin with divalent ion binding sites saturated with Ca2+ (in the presence of 1 mM MgCl2 and 0.1 mM Ca2+) decreases the angles of emission and absorption dipoles and the angle between the F-actin axis and the fibre axis, thus suggesting that F-actin in ghost fibre becomes more flexible. On the other hand, the above-mentioned angles increase when phosphorylated heavy meromyosin at high and dephosphorylated heavy meromyosin at low Ca2+ concentration were bound to thin filaments, thus showing the decrease of F-actin flexibility under these conditions.

Effect of phosphorylation of myosin light chains on interaction of heavy meromyosin with regulated F-actin in ghost fibers.

The binding of phosphorylated heavy meromyosin to regulated F-actin in ghost fibers at high Ca2+ concentration increases, and at low Ca2+ concentration decreases, the anisotropy of intrinsic tryptophan fluorescence of F-actin. The effect is opposite to the effect of the binding of dephosphorylated heavy meromyosin.

Binding of phosphorylated and dephosphorylated heavy meromyosin to F-actin.

The effect of myosin light chain phosphorylation in skeletal muscle was investigated with respect to the binding affinity of phosphorylated and dephosphorylated heavy meromyosin (HMM) for F-actin in the absence of ATP. For phosphorylated HMM the affinity was 2.5-times weaker in the presence of Ca2+ as in its absence (HMM divalent binding sites saturated only with Mg). For dephosphorylated HMM the reverse was true, the binding being 2.4-times higher in the presence of Ca2+.