Effect of the C-terminal actin-binding sites of caldesmon on the interaction of actin with myosin

TRITC-phalloidin or FITC-labeled F-actin of ghost muscle fibers was bound to tropomyosin and C-terminal recombinant fragments of caldesmon CaDH1 (residues 506-793) or CaDH2 (residues 683-767). After that the fibers were decorated with myosin subfragment 1. In the absence of caldesmon fragments, subfragment 1 interaction with F-actin caused changes in parameters of polarized fluorescence, that were typical of "strong" binding of myosin heads to F-actin and of the "switched on" conformational state of actin. CaDH1 inhibited, whereas CaDH2 activated the effect of subfragment 1. It is suggested that C-terminal part of caldesmon may modulate the transition of F-actin subunits from the "switched on" to the "switched off" state.     

Incubation of myosin with exogenous small components (g1, g2, or g3) in KSCN or LiCl and properties of g-exchanged myosins.

Myosin was incubated with a large excess of exogenous g1, g2 or g3 in 0.6 M KSCN (or in 4 M LiCl) for 1-2 h at 0-2 degrees C. KSCN (or LiCl) was then removed by dialysis. The composition of g-chains in the resulting myosin was analyzed by SDS-gel electrophoresis. When myosin was incubated with g1, the amount of g1 in myosin increased and the increment was nearly counterbalanced by a decrease in g3, whereas an opposite change was observed on incubation with g3. The amount of g2 was not changed by these treatments. The same ATPase activity as that of control myosin was observed in the presence of Ca2+ or EDTA with the myosins incubated with g1, g2, or g3, but the activity in the presence of Mg2+ was about one-half of the control. The Ca2+ sensitivity of actomyosin containing the treated myosins was slightly higher than that of actomyosin containing the control myosin. Spin-labeled g1 or spin-labeled g3 was incorporated into myosin, but the ESR spectra of two spin labels were not distinguishable. No information could be obtained from the ESR spectra by the addition of Ca2+, Mg2+, nucleotides or actin. Inhibition of ATPase activity was observed when SH groups g1 or g3 in myosin were chemically modified.     

Effects of alkali ions on myosin conformation

We have used two probes to study the effects of alkali ions on the conformation of myosin. One was paramagnetic, the “spin label” N-(1-oxyl-2,2,6,6-tetramethyl-4-piperidinyl)-maleimide, which binds primarily to SH groups; and the other was fluorescent, l-anilino-8-naphthalenesulfonate, which binds to an apolar niche. The bonding of the spin label to myosin was carried out in 0.6M LiCl, 0.6M NaCl, or 0.6M KCl, and the resulting labeled myosin was studied in the same medium in which the myosin was labeled as well as in other alkali chlorides. The electron paramagnetic resonance spectra of the spin label showed that the structure of myosin in the vicinity of the labeled groups differed in the various salts. The protein surface in the region of the labeled groups restricted the rotational freedom of the spin label more in KCl than in any of the other salts. Although ions are known to influence the properties of myosin, our results show that these ions also effect the molecular structure. The fluorescence of l-anilino-8-naphthalenesulfonate, noncovalently attached to myosin in the presence of alkali chlorides, decreased progressively with increasing size of the cations, again showing the protein structure near the probe attachment to be a function of the cation, in the solvent. Ca²⁺ quenched the fluorescence of the bound probe, indicating an interaction between Ca²⁺ and the myosin molecule. The effect of Ca²⁺ on the fluorescence was greatest in KCl.     

The effects of ionic conditions, temperature, and chemical modification on the fluorescence of myosin during the steady state of ATP hydrolysis. A comparison of the fluorescnece and electron spin resonance spectra of the spin-labeled enzyme.

The ATP-induced enhancement of the intrinsic fluorescence of myosin and heavy meromyosin (HMM) that persists during the steady state of hydrolysis has been investigated. To compare the substrate-induced changes in fluorescence with those in the electron spin resonance spectrum of the spin-labeled enzyme, we studied the influence of temperature, pH, and ionic strength, as well as the effect of chemical modification (spin labeling) of the SH-1 sulfhydryl groups. Changing the pH between 6 and 9 does not affect the enhancement of fluorescence of myosin or HMM; changing the ionic strength, which could be studied only with HMM, also has no effect; and decreasing the temperature from 20 to 5 degrees slightly diminishes the enhancement with both myosin and HMM. Chemical modification with N-(1-oxyl-2,2,6,6-tetramethyl-4-piperidinyl) iodoacetamide, which blocks the SH-1 thiol groups, reduces the enhancement of fluorescence, induces a strong dependence on ionic strength and pH, and substantially increases the dependence on temperature. The enhancement with labeled myosin or labeled HMM increases with increasing pH, ionic strength, and temperature, closely paralleling the effects of these parameters on the electron spin resonance spectrum of spin-labeled myosin (SEIDEL, J.C. and GERGELY, J. (1973) Arch. Biochem. Biophys. 158, 853), suggesting that the same molecular change, induced by ATP and associated with formation of the MADP-P1 complex, underlies both the change in fluorescence and the change in ESR spectrum. Those analogues of ATP that produce the maximal enhancement of fluorescence (WERBER, M., SZENT-GYORGYL, A.G., and FASMAN, G. (1972) Biochemistry 11, 2872) also produce the maximal change in the ESR spectra. Both an amino group at position 6 of the substrate and an unmodified triphosphate chain are required for maximal change in either fluorescence or ESR spectra. The smaller enhancement of fluorescence produced by spin labeling the SH-1 groups persists after the nitroxide has been chemically changed to a diamagnetic species. Thus the small enhancement cannot be attributed to paramagnetic quenching of tryptophan fluorescence by the spin label. An initial burst of phosphate liberation accompanies the hydrolysis of ATP, cytidine 5'-triphosphate, uridine 5'-triphosphate, guanosine 5'-tryphosphate, iosine 5'-triphosphate, 2'-deoxyadenosine 5'-tryphosphate, adenosine 5'-tetraphosphate, and tripolyphosphate. The presence or absence of the burst does not correlate with the extent of the spectral change.     

Spectral fluctuation of a single fluorophore conjugated to a protein molecule

We have measured the fluorescence spectra of a single fluorophore attached to a single protein molecule in aqueous solution using a total internal reflection fluorescence microscope. The most reactive cysteine residue of myosin subfragment-1 (S1) was labeled with tetramethylrhodamine. The spectral shift induced by a change in solvent from aqueous buffer to methanol in both single-molecule and bulk measurements were similar, indicating that, even at the single molecule level, the fluorescence spectrum is sensitive to microenvironmental changes of fluorophores. The time dependence of the fluorescence spectra of fluorophores attached to S1 molecules solely showed a fluctuation with time over a time scale of seconds. Because the fluorescence spectra of the same fluorophores directly conjugated to a glass surface remained constant, the spectral fluctuation observed for the fluorophores attached to S1 is most likely due to slow spontaneous conformational changes in the S1 molecule. Thus, single-molecule fluorescence spectroscopy appears to be a powerful tool to study the dynamic behavior of single biomolecules.     

Spectroscopic characterization of the ATPase of the thermophilic bacterium PS3 and its isolated subunits

The ATPase of the thermophilic bacterium PS3, TF0F1, and its subunits has been isolated and their absorption and fluorescence spectra have been measured. The following results were obtained: The tryptophan content of the subunits was determined spectroscopically. Although tryptophan (Trp) and tyrosine (Tyr) are found in TF1, the fluorescence spectrum of native TF1 and its subunits is dominated by Tyr fluorescence; this is in contrast to other proteins. Among (native) TF1 and its subunits only TF1 and the alpha-subunit show a weak fluorescence of Trp, which is blue-shifted, indicating a location in a strongly hydrophobic environment. TF0 fluorescence is dominated by the strong Trp fluorescence. TF0F1 fluorescence is also dominated by the Trp residues. Additionally, its fluorescence is higher than the sum of the isolated TF0 and TF1, indicating marked changes in the microenvironment of the fluorescing aminoacids upon binding of TF1 to TF0.     

Spectroscopic characterization of textilotoxin, a presynaptic neurotoxin from the venom of the Australian eastern brown snake (Pseudonaja t. textilis)

Spectroscopic behavior of textilotoxin, from the venom of Pseudonaja t. textilis, and its subunits were investigated using fluorescence, circular dichroism and Fourier transform infrared spectroscopy. Circular dichroism spectra of the B, C and D subunits indicate considerable similarity in their alpha-helix and beta-sheet contents. By contrast, the A subunit displays significantly more beta-sheet and 'remainder' structure. FTIR spectra confirm conclusions drawn from CD spectra. Fluorescence spectra indicate that, in general, tryptophan residues in the A, B and D subunits are relatively exposed to the solvent. The C subunit exhibits no fluorescence, suggesting a lack of tryptophan. Comparisons of individual subunit spectra with those of the intact toxin suggest that significant changes in secondary structure may occur when the toxin dissociates.     

Fluorescence properties and contraction characteristics of ANM (N-(1-anilinonaphthyl-4)maleimide)-labeled rabbit psoas muscle fibers

Fluorescence spectra of ANM-labeled, glycerinated rabbit psoas muscle fibers were recorded in relaxed, contracted, and rigor states. SDS polyacrylamide gel electrophoresis of the ANM-labeled muscle fibers indicated that proteins labeled with ANM were myosin heavy chain, C protein, and actin. In a relaxed state in the presence of ATP, myosin heavy chain was mainly labeled. During the transition from rigor to the relaxed or contracted state, there was a blue shift (about 5 nm) of the ANM emission spectrum. Similar experiments with FAM (N-(3-fluoranthyl)-maleimide)-labeled muscle fibers showed that these fluorescence changes were not artifacts due to the movement of muscle fibers. The fibers labeled in the ATP relaxing solution showed a marked decrease in both isometric force and unloaded shortening velocity (Vo), while in the fibers labeled in the rigor solution isometric tension was not markedly suppressed, though Vo decreased to the same extent as in the fibers labeled in the ATP relaxing solution. Fluorescence spectra of ANM-labeled HMM in different states were also measured. A fluorescence enhancement and a blue shift (about 5 nm) of the emission maximum were observed in HMM + MgATP or HMM + MgATP + F-actin in comparison with HMM + F-actin. These results suggest that the fluorescence spectra of the ANM-labeled muscle fibers reflect their conformational changes between the rigor state (in the absence of MgATP) and the relaxed or contracted state (in the presence of MgATP).     

Changes in rabbit skeletal myosin and its subfragments under high hydrostatic pressure

The pressure-induced denaturation of rabbit skeletal myosin and its subfragments under hydrostatic pressure were investigated. Four nanometer of red shift of the intrinsic fluorescence spectrum was observed in myosin under a pressure of 400 MPa. The ANS fluorescence of myosin increased with elevating pressure. Changes in the intrinsic fluorescence spectra of myosin and its subfragments were quantified and expressed as the center of spectral mass. The center of spectral mass of myosin and its subfragments linearly decreased with elevating pressure, and increased with lowering pressure. The fluorescence intensity of the ANS-labeled rod did not change during pressure treatment. The present results indicate that the most pressure-sensitive portion of myosin molecule is the head. Hysteresis of the center of spectral mass of S1 appeared under pressures above 300 MPa. Changes in the center of spectral mass of S1 above 350 MPa showed stronger hysteresis. The center of spectral mass did not decrease above 350 MPa during the compression process, indicating that S1 was stable in a partially denatured state at 350 MPa under pressure. The changes in the relative intensities of ANS fluorescence of S1 were measured under pressures up to 400 MPa, and the ANS fluorescence intensity increased with elevating pressure but it did not change after pressure release. The ANS fluorescence intensity increased under constant pressure suggesting that the pressure-induced denaturation of myosin was accelerated during pressurization.     

Fluorescence probe studies of the state of tropomyosin in reconstituted muscle thin filaments

The monomer fluorescence of N-(1-pyrenyl)maleimide-labeled tropomyosin bound to F-actin (PTm-actin) increases when myosin subfragment 1 (S1) binds to actin and is half complete when only approximately 1 S1 is bound to 7 actin subunits [Ishii, Y., & Lehrer, S. S. (1985) Biochemistry 24, 6631-6638]. Similar studies of the binding of S1 and S1-ADP to fully reconstituted thin filaments [PTm-actin-troponin (Tn)] are now reported. The pyrene monomer fluorescence change was half complete when approximately 0.5 S1/7 actin subunits and approximately 1.5 S1/7 actin subunits were bound in the presence and absence of Ca2+, respectively. In the presence of Mg2+-ADP, when S1 binding is weakened, the S1 binding profiles and fluorescence changes were sigmoidal, with the cooperative transitions occurring at lower [S1] in the presence of Ca2+ as first shown by Greene and Eisenberg for S1 binding [Greene, L., & Eisenberg, E. (1980) Proc. Natl. Acad. Sci. U.S.A. 77, 2616-2620]. It was possible to fit both the binding and fluorescence data with the same parameters of a two-state (weak and strong S1 binding) cooperative binding model [Hill, T., Eisenberg, E., & Greene, L. (1980) Proc. Natl. Acad. Sci. U.S.A. 77, 3186-3190] for each Ca2+ situation if the fluorescence change is interpreted as the fraction of tropomyosin (Tm) units in the strong S1 binding state. These data indicate that the fluorescence change is a direct measure of the S1-induced change of state of Tm in the fully reconstituted thin filament.(ABSTRACT TRUNCATED AT 250 WORDS)     

Combining EPR with Fluorescence Spectroscopy to Monitor Conformational Changes at the Myosin Nucleotide Pocket

We used spin-labeled nucleotide analogs and fluorescence spectroscopy to monitor conformational changes at the nucleotide-binding site of wild-type Dictyostelium discoideum (WT) myosin and a construct containing a single tryptophan at position F239 near the switch 1 loop. Electron paramagnetic resonance (EPR) spectroscopy and tryptophan fluorescence have been used previously to investigate changes at the myosin nucleotide site. A limitation of fluorescence spectroscopy is that it must be done on mutated myosins containing only a single tryptophan. A limitation of EPR spectroscopy is that one infers protein conformational changes from alterations in the mobility of an attached probe. These limitations have led to controversies regarding conclusions reached by the two approaches. For the first time, the data presented here allow direct correlations to be made between the results from the two spectroscopic approaches on the same proteins and extend our previous EPR studies to a nonmuscle myosin. EPR probe mobility indicates that the conformation of the nucleotide pocket of the WT⋅SLADP (spin-labeled ADP) complex is similar to that of skeletal myosin. The pocket is closed in the absence of actin for both diphosphate and triphosphate nucleotide states. In the actin⋅myosin⋅diphosphate state, the pocket is in equilibrium between closed and open conformations, with the open conformation slightly more favorable than that seen for fast skeletal actomyosin. The EPR spectra for the mutant show similar conformations to skeletal myosin, with one exception: in the absence of actin, the nucleotide pocket of the mutant displays an open component that was approximately 4-5 kJ/mol more favorable than in skeletal or WT myosin. These observations resolve the controversies between the two techniques. The data from both techniques confirm that binding of myosin to actin alters the conformation of the myosin nucleotide pocket with similar but not identical energetics in both muscle and nonmuscle myosins.     

tRNA binding modifies the properties of the small ribosomal subunit of rat liver

The binding of a specific tRNA (acylated or not) to the 40S subunits in the presence of the proper codon was shown to produce two striking effects on the subunits. First, the subunits were no longer able to dimerize at low ionic strength. Second, they became fully resistant to 1.25 M LiCl treatment: bound tRNA prevented subunit inactivation as measured by polyphenylalanine synthesis; it also prevented large sedimentation changes of subunits and ribosomal protein release induced by LiCl. The number of protected proteins far exceeded that of the proteins crosslinked with tRNA after irradiation at 254 nm (A.M. REBOUD, S. DUBOST and J.P. REBOUD (1983) FEBS Lett. 158, 285-288). These results strongly suggest that tRNA binding induces modifications of rRNA-protein interactions in large domains of the subunits. A weak interaction of tRNA with the 40S subunit was demonstrated in the absence of the codon.     

Analysis of log-normal components of fluorescence spectra of prodan and acrylodan bound to proteins

Steady-state fluorescence spectra of prodan and acrylodan covalently bound to cystein residue of Lys-Cys-Phe tripeptide in solvents of different polarity were analyzed. It was shown that the shape of spectral bands is well described by a log-normal function. Linear relations between three shape-determining parameters of the log-normal function (namely, the positions of spectral maximum and two half-maximum amplitudes) were revealed and evaluated for both fluorophores. This finding enabled us to present the shape of spectral bands of these fluorophores in any environment as analytical log-normal functions depending on only two parameters, the maximum position and the peak amplitude. The empirical uniparametric log-normal curve was used for the analysis of composite fluorescence spectra of prodan bound to bovine serum albumin and acrylodan covalently attached to actin or subfragment 1 of myosin.     

Human cardiac myosin ATPase and light subunits. A comparative study.

Myosin was extracted from normal human hearts (autopsy material) and compared to that of pig heart and rabbit white skeletal muscle. Myosin light subunits were isolated by a preparative urea gel electrophoresis. These subunits were shown by urea and sodium dodecylsulfate gel electrophoresis to be only slightly affected by the time lapse between death and the beginning of myosin extraction. This was also true for myosin ATPases. The Ca-2+-activated ATPases of pig and human heart myosins have the same apparent Km and V, whereas white skeletal muscle myosin ATPase has the same Km with a higher V. Human myosin light subunits, when compared to those of pig heart possess: (i) different molecular weights: 27 999 and 18 000 datlons for pig heart, and 25 000 and 19 000 daltons for human heart. (ii) for both the light chains, different ultraviolet spectra and a higher helical content for the subunit molecular weight 25 000. (iii) a different composition for several amino acids (Tyr, Pro, Lys). A third light subunit (molecular weight 15 000) was occasionally seen in human as well as pig heart myosin. It concentration varied inversely with that of the subunit molecular weight 27 000-25 000, and so was probably a degradation product of the heaviest subunit.     

Twitchin can regulate the ATPase cycle of actomyosin in a phosphorylation-dependent manner in skinned mammalian skeletal muscle fibres

The effect of twitchin, a thick filament protein of molluscan muscles, on the actin-myosin interaction at several mimicked sequential steps of the ATPase cycle was investigated using the polarized fluorescence of 1.5-IAEDANS bound to myosin heads, FITC-phalloidin attached to actin and acrylodan bound to twitchin in the glycerol-skinned skeletal muscle fibres of mammalian. The phosphorylation-dependent multi-step changes in mobility and spatial arrangement of myosin SH1 helix, actin subunit and twitchin during the ATPase cycle have been revealed. It was shown that nonphosphorylated twitchin inhibited the movements of SH1 helix of the myosin heads and actin subunits and decreased the affinity of myosin to actin by freezing the position and mobility of twitchin in the muscle fibres. The phosphorylation of twitchin reverses this effect by changing the spatial arrangement and mobility of the actin-binding portions of twitchin. In this case, enhanced movements of SH1 helix of the myosin heads and actin subunits are observed. The data imply a novel property of twitchin incorporated into organized contractile system: its ability to regulate the ATPase cycle in a phosphorylation-dependent fashion by changing the affinity and spatial arrangement of the actin-binding portions of twitchin.     

Changes in the structural state of myosin filaments in glycerol-treated fibers of rabbit skeletal muscles induced by phosphorylation of myosin light chains

Using the polarization microfluorimetry method, it was demonstrated that the increase in the degree of phosphorylation of myosin light chains (LC2) in extended single glycerinated fibers from rabbit psoas muscle changes the anisotropy of polarized fluorescence both tryptophan residue in the rod parts of the myosin molecule and the fluorescent label-N (iodoacetyl-aminoethyl)-5-naphthylamine-1-sulfonate (1,5-IAEDANS) bound to the SH1-group in myosin molecule heads. The changes in fluorescence anisotropy during LC2 phosphorylation were observed, when the measurements were performed only in the presence of 5 mM MgCl2. It was suggested that in the presence of MgCl2 the phosphorylation of LC2 associated with myosin heads changes their orientation and causes conformational shifts in the myosin filament core.     

Spectral effects of denaturation of B- and C-phycoerythrins]

B-phycoerythrin (B-PhE) from red alga Porphyridium cruentum and C-phycoerythrin (C-PhE) from blue-green alga Nostoc punctiforma were isolated. Their absorption and fluorescence spectra were measured at room and liquid nitrogen temperature. The drastic change of fluorescence and absorption maxima under dissociation of the proteins into subunits was observed. Dissociation of the C-PhE into two subunits (molecular weight 16 000 and 12 000) was revealed by SDS-acrylamide gel electrophoresis in 0.01% SDS solution at pH 7.0. The absorption spectra of subunits of both B-PhE and C-PhE were similar. The fluorescence quenching by oxidants and destructive photooxidation were negligible and increased after denaturation.     

Association of iron-protoporphyrin-IX (hemin) with myosins

Addition of myosins isolated from guinea pig heart and rabbit skeletal muscle to hemin solutions resulted in the appearance of new absorption spectra indicating association of hemin and the myosins. Binding stoichiometry based on absorption changes was found to be two hemin sites per myosin molecule. The binding constants calculated from quenching of the intrinsic fluorescence of the myosins by hemin are Ka = 7 (+/- 2) 10(6) M-1 for skeletal muscle myosin, and Ka = 3 (+/- 1) x 10(7) M-1 for heart muscle myosin. Based on these findings, myosins are suggested as potential transporters of free hemin between cell organelles.     

Movement of smooth muscle tropomyosin by myosin heads.

It has been proposed that during the activation of muscle contraction the initial binding of myosin heads to the actin thin filament contributes to switching on the thin filament and that this might involve the movement of actin-bound tropomyosin. The movement of smooth muscle tropomyosin on actin was investigated in this work by measuring the change in distance between specific residues on tropomyosin and actin by fluorescence resonance energy transfer (FRET) as a function of myosin head binding to actin. An energy transfer acceptor was attached to Cys374 of actin and a donor to the tropomyosin heterodimer at either Cys36 of the beta-chain or Cys190 of the alpha-chain. FRET changed for the donor at both positions of tropomyosin upon addition of skeletal or smooth muscle myosin heads, indicating a movement of the whole tropomyosin molecule. The changes in FRET were hyperbolic and saturated at about one head per seven actin subunits, indicating that each head cooperatively affects several tropomyosin molecules, presumably via tropomyosin's end-to-end interaction. ATP, which dissociates myosin from actin, completely reversed the changes in FRET induced by heads, whereas in the presence of ADP the effect of heads was the same as in its absence. The results indicate that myosin with and without ADP, intermediates in the myosin ATPase hydrolytic pathway, are effective regulators of tropomyosin position, which might play a role in the regulation of smooth muscle contraction.     

Correlation of intrinsic fluorescence and conformation of smooth muscle myosin

The addition of ATP to turkey gizzard myosin causes an enhancement of the intrinsic tryptophan fluorescence. The level of fluorescence enhancement is determined by the myosin conformation. The transition of myosin from the folded (10 S) state to the extended (6 S) state is accompanied by a decrease in the fluorescence level. Phosphorylation-dephosphorylation of myosin does not directly influence fluorescence and will induce changes only if the myosin conformation is altered. Under the appropriate conditions, phosphorylation of myosin favors the transition of 10 S to 6 S. The phosphorylation dependence of the associated fluorescence decrease is not linear, and it is proposed that the phosphorylation of both light chains is required for the full transition. The tryptophan residues involved respond to the binding of ATP at the hydrolytic sites. Since the fluorescence properties of gizzard myosin are influenced by the myosin conformation, it is reasonable to assume that the active sites are also modified by the shape of the myosin molecule.