Continuous capture scale down model: A comparison of a continuous and a discrete approach

In continuous pharmaceutical manufacturing, consisting of a perfused batch fermentation and integrated continuous downstream processing, the continuous capture is the linking unit operation. For the development of this unit operation, scale-down models (SDMs) are crucial, whereas discrete, noncontinuous SDMs are preferred over continuous SDM due to their simplistic nature, reduced material consumption, and shorter operation time. The results presented in this study show the suitability of a discrete SDM approach, compared to a continuous SDM for a continuous protein A purification step.

A frequently occurring mutation in the lipoprotein lipase gene (Asn291Ser) contributes to the expression of familial combined hyperlipidemia

We performed denaturing gradient gel electrophoresis (DGGE) of exons 4, 5, 6 and their exon-intron boundaries of the LPL-gene in 169 unrelated male patients suffering from familial combined hyperlipidemia (FCH). Twenty patients were found to carry a nucleotide substitution in exon 6. Sequence and PCR/digestion analysis revealed one common mutation (Asn291Ser) in all these cases. This mutation was talso present in 215 male controls, albeit at a lower frequency than in FCH patients (10/215 = 4.6% vs. 20/169 = 11.8%; p < 0.02). Analysis of lipid, lipoprotein and apolipoprotein levels demonstrated an association between the presence of this Asn291Ser substitution and decreased HDL-cholesterol (0.94 +/- 0.31 vs. 1.12 +/- 0.26 mmol/l; p < 0.04) in our controls. FCH patients carrying this mutation showed decreased HDL-cholesterol (0.75 +/- 0.16 vs. 0.95 +/- 0.36 mmol/l; p = 0.05) and increased triglyceride levels (5.96 +/- 4.12 vs. 3.48 +/- 1.78 mmol/l; p < 0.005) compared to non-carriers. The high triglyceride and low HDL-cholesterol phenotype in carriers of this substitution was most obvious when BMI exceeded 27 kg/m2. Our study of male FCH patients revealed the presence of a common mutation in the LPL-gene that is associated with lipoprotein abnormalities, indicating that defective LPL is at least one of the factors contributing to the FCH-phenotype.

Unfolding domains in smooth muscle myosin rod

Gizzard smooth muscle myosin rod, an alpha-helical coiled coil, exhibits two cooperative thermal or denaturant-induced helix unfolding transitions in solutions containing 0.6 M NaCl at neutral pH, when monitored by circular dichroism at 222 nm. The first smaller transition unfolds part of the subfragment 2 (S2) domain, and the main transition unfolds the remaining helix including the light meromyosin (LMM) domain. These unfolding domains were identified by monitoring the fluorescence of acrylodan, an environmentally sensitive fluorescence probe, and the ESR signal of a maleimide spin-label, sensitive to motion, both specifically attached to Cys 43 in the S2 region of the rod sequence. The identities of the domains were verified by studying the unfolding of the S2 and LMM coiled-coil peptides obtained by proteolytic cleavage of spin-labeled and unlabeled rod. The fluorescence of acrylodan-labeled rod indicated that although the S2 intermediate is unfolded, it is not in a random-coil conformation. The unfolded S2 region stabilized the LMM domain against unfolding, possibly by a direct interaction with the LMM region. Such an interaction may be involved in the salt- and phosphorylation-dependent 6S to 10S shift in configuration of the myosin molecule.

Effects of phosphorylation, MgATP, and ionic strength on the rates of papain degradation of heavy and light chains of smooth muscle heavy meromyosin at the S1-S2 junction

The effects of ionic strength, MgATP, and phosphorylation on the degradation rates of heavy meromyosin (HMM) by papain have been compared to their effects on the sedimentation coefficient (s20,w) to determine the relationship of the degradation rate to the equilibrium between the flexed and the extended forms (Suzuki, H., Stafford, W. F., Slayter, H. S., and Seidel, J. C. (1985) J. Biol. Chem. 260, 14810-14817). At 0.025 M NaCl, where HMM is predominantly in the flexed form, MgATP, Mg-adenylyl imidodiphosphate or MgADP reduce kH by 80-90%. MgATP exerts its optimal effect at this ionic strength, where at least 70% of HMM is flexed in the presence or absence of MgATP, suggesting that nucleotides reduce kH by decreasing the proteolytic susceptibility of the flexed form. At 0.5 M NaCl, where HMM is in the extended form, MgATP has no effect on kH. At low ionic strengths phosphorylation decreases kH but increases it in the presence of MgATP. Plots of kH against s20,w determined at various ionic strengths are linear, the data for phosphorylated and dephosphorylated HMM falling on the same line. Thus, raising the ionic strength or phosphorylating the 20-kDa light chain appears to alter kH by increasing the fraction of HMM in the extended form. The degradation rate of the 20-kDa light chain (kL) of dephosphorylated HMM responds to changes in ionic strength in essentially the same way as does kH, suggesting that the response of kL to changes in ionic strength can also be attributed to conversion of HMM to the extended form. However, kL for phosphorylated HMM measured in the presence of MgATP exhibits very little dependence on ionic strength.

Location of the sites of reaction of N-ethylmaleimide in papain and chymotryptic fragments of the gizzard myosin heavy chain

The thiol of the gizzard myosin heavy chain, which reacts most rapidly with N-ethylmaleimide (MalNEt), has been located in the subfragment 2 region of myosin rod by fragmentation of [14C]-MalNEt-labeled myosin with papain and chymotrypsin. MalNEt reacts more slowly with thiols present in the 70- and 25-kilodalton (kDa) papain fragments of subfragment 1. The reaction of MalNEt with thiols present in these regions is increased on addition of ATP by factors of 2 and 10, respectively, when myosin is modified in 0.45 M NaCl where it is present in the extended, 6S conformation. The rate of increase of Mg2+-activated adenosinetriphosphatase (ATPase) activity, which reflects the loss of ability of myosin to assume the folded, 10S conformation, and the rate of loss of K+-EDTA-activated activity produced by MalNEt are both accelerated 5- to 10-fold on addition of ATP. The rates at which ATPase activities change agree closely to the reaction rates of MalNEt with the 25-kDa region of subfragment 1; therefore, the changes in these activities can be attributed to modification of a thiol of the 25-kDa segment. An increase in actin-activated ATPase activity produced by reaction of myosin with MalNEt in 0.45 M NaCl is accelerated by ATP by a factor of at least 4. Reaction with [14C]MalNEt in the presence of MgATP and 0.2 M NaCl, where myosin is in the 10S form, inhibits the incorporation of radioactive MalNEt into the 25-kDa papain fragment of subfragment 1. It also prevents the increase in actin-activated ATPase activity and preserves the ability of myosin to assume the 10S form.

Single-headed binding of a spin-labeled-HMM-ADP complex to F-actin. Saturation transfer electron paramagnetic resonance and sedimentation studies

The interaction of actin and spin-labeled heavy meromyosin (MSL-HMM) was studied in the presence and absence of adenosine diphosphate or 5'-adenyl-yl-imidodiphosphate (AMPPNP) to determine the contributions of single and double-headed binding. The extent of single-headed binding to actin was deduced from a comparison of the fraction of immobilized heads (fi) with the fraction of bound molecules (fs) determined by saturation-transfer EPR (ST-EPR) and sedimentation, respectively. The ST-EPR measurements depend on the reduced motion of the spin label rigidly bound to the HMM heads upon the interaction of the latter with actin. During titration of acto-MSL-HMM with nucleotide, we measured changes in fi and fs brought about by dissociation of MSL-HMM from actin. On titration with ADP, fs changed very little, remaining above 0.8, while fi decreased to approximately 0.5 at 10mM ADP, a result consistent with extensive single-headed binding of MSL-HMM to actin. On titration with AMPPNP, single-headed binding was not detected; viz., fi and fs decreased in parallel. It was not necessary to postulate a nucleotide induced state of the bound heads, differing in motional properties from that of rigor heads, to account for the results.

Ca2+ dependence of the ATPase activity of phosphorylated smooth muscle myosin: effects of tropomyosin and actin

Calcium ions produce a 3-4-fold stimulation of the actin-activated ATPase activities of phosphorylated myosin from bovine pulmonary artery or chicken gizzard at 37 degrees C and at physiological ionic strengths, 0.12-0.16 M. Actins from either chicken gizzard or rabbit skeletal muscle stimulate the activity of phosphorylated myosin in a Ca2+-dependent manner, indicating that the Ca2+ sensitivity involves myosin or a protein associated with it. Partial loss of Ca2+ sensitivity upon treatment of phosphorylated gizzard myosin with low concentrations of chymotrypsin and the lack of any change on similar treatment of actin supports the above conclusion. Although both actins enhance ATPase activity, activation by gizzard actin exhibits Ca2+ dependence at higher temperatures or lower ionic strengths than does activation by skeletal muscle actin. The Ca2+ dependence of the activity of phosphorylated heavy meromyosin is about half that of myosin and is affected differently by temperature, ionic strength and Mg2+, being independent of temperature and optimal at lower concentrations of NaCl. Raising the concentration of Mg2+ above 2-3 mM inhibits the activity of heavy meromyosin but stimulates that of myosin, indicating that Mg2+ and Ca2+ activate myosin at different binding sites.

Saturation transfer electron paramagnetic resonance study of the mobility of myosin heads in myofibrils under conditions of partial dissociation

The rotational motion of rigidly spin-labeled myosin heads of glycerinated myofibrils as reflected in saturation-transfer EPR spectra behaves to a first approximation as though the heads consist of two populations with different rotational motions. An immobilized fraction has a correlation time (tau 2) of approximately 0.5 ms, comparable to that of spin-labeled subfragment-1 (S1) bound to thin filaments, while a mobile fraction has a tau 2 of 10 microseconds, comparable to that of the heads of purified myosin filaments. The effects of nonhydrolyzable ATP analogues, potassium pyrophosphate (PPi), or adenylyl imidodiphosphate, Ca2+, temperature, or ionic strength on the spectra can be analyzed in terms of the fraction of myosin heads immobilized by attachment to thin filaments, without requiring changes in the motion of either attached or detached heads.

A conformational transition in gizzard heavy meromyosin involving the head-tail junction, resulting in changes in sedimentation coefficient, ATPase activity, and orientation of heads

Gizzard heavy meromyosin (HMM) sediments in the ultracentrifuge as a single peak, whose sedimentation coefficient (S20,w) decreases from 9 to 7.5 S upon increasing the NaCl concentration from 0.02 to 0.3 M. This decrease is accompanied by a parallel increase in Mg2+-ATPase activity, suggesting that both changes have a common molecular basis. Phosphorylation decreases S20,w and increases ATPase activity, while ATP increases S20,w. Sedimentation equilibrium studies indicate that HMM undergoes no detectable aggregation at 0.02 or 0.4 M NaCl, remaining monomeric with a molecular weight of 3.4 X 10(5). In contrast, S20,w of subfragment 1 does not change with changes in ionic strength, and its ATPase activity does not decrease at low ionic strengths. Electron micrographs of samples of HMM prepared at low ionic strength show that up to half of the molecules are flexed, i.e. the heads are bent at the neck and project back toward the tail, while the remaining molecules have either one or both of the heads pointing away from the tail. In samples prepared at high ionic strength only about 10% of the molecules are flexed. There is a linear relationship between the fraction of flexed molecules and S20,w, with no significant bending or folding of the tail and no detectable change in the shape of the heads. This correlation suggests that the changes in ATPase activity and S20,w may be a result of the reorientation of the heads.

Modification of thiols of gizzard myosin alters ATPase activity, stability of myosin filaments, and the 6-10 S conformational transition

The pattern of incorporation of [14C]N-ethylmaleimide (MalNEt) into gizzard myosin indicates the presence of two classes of thiols: rapidly and slowly modified. The first class contains two thiol residues, SH-A and SH-B, located in the myosin rod and the 17-kDa light chain, respectively, while the second contains at least two thiols located in the myosin heavy chain. Changes in ATPase activities upon modification occur rapidly or slowly, paralleling reaction of either the first or second class of thiols. Rapid changes include increases in the Ca2+- and Mg2+-activated activities of myosin alone, measured at ionic strengths below 0.3 M, and an increase and a decrease in the actin-activated activity of dephosphorylated and phosphorylated myosin, respectively. Modification of SH-A and SH-B with MalNEt is accompanied by stabilization of myosin filaments, seen as an increase in light-scattering intensity, and by destabilization of the folded, 10 S conformation of the myosin monomer. In the presence of 0.175 M NaCl and 1 mM MgATP, unmodified and MalNEt-modified myosin sediment in the ultracentrifuge as single components at 10.0 S and 6.0 S, respectively. The MalNEt-induced increase in the Ca2+- or Mg2+-activated ATPase activity, measured in the absence of actin, can be attributed either to stabilization of filaments or to destabilization of the 10 S conformation, depending on the ionic strength of the assay. Modification of the second class of thiols is accompanied by a decrease in K+-EDTA-activated activity and an increase in Ca2+-activated activity measured above 0.3 M NaCl, where myosin neither forms filaments nor assumes the 10 S conformation. These slow changes are characteristic of blocking the SH-1 thiols of skeletal-muscle myosin, but in gizzard myosin are attributable to modification of a less reactive thiol, SH-C.

Comparison of the fluorescence and conformational properties of smooth and striated tropomyosin

In contrast to previous conformational studies with rabbit skeletal and cardiac tropomyosins, (i) when the cysteine side chains of chicken gizzard tropomyosin were reacted with 5,5'-dithiobis(2-nitrobenzoate), an interchain disulfide cross-link was not produced, (ii) when they were labeled with pyrenylmaleimide , excimer fluorescence was not observed, and (iii) when they were labeled with didansylcystine , a long-lived fluorescence component did not appreciably contribute to the fluorescence decay over a large temperature range including the major unfolding transition. In addition, the temperature dependence of the ellipticity at 222 nm did not reveal a pretransition prior to the main helix unfolding transition. This indicates that gizzard tropomyosin does not exhibit a localized chain-open state in the region of its cysteine residues, analogous to that seen with cardiac and skeletal tropomyosins, nor in any other region of the molecule. As a consequence, these observations suggest that gizzard tropomyosin is more rigid than striated tropomyosin.

Modulation of the actin-activated adenosinetriphosphatase activity of myosin by tropomyosin from vascular and gizzard smooth muscles

Tropomyosins from bovine aorta and pulmonary artery exhibit identical electrophoretic patterns in sodium dodecyl sulfate but differ from tropomyosins of either chicken gizzard or rabbit skeletal muscle. Each of the four tropomyosins binds readily to skeletal muscle F-actin as indicated by their sedimentation with actin and by their ability to maximally stimulate or inhibit actin-activated ATPase activity at a molar ratio of one tropomyosin per seven actin monomers. Smooth and skeletal muscle tropomyosins differ in their effects on activity of skeletal myosin or heavy meromyosin (HMM); the former can enhance activity under conditions in which the latter inhibits. Gizzard and arterial tropomyosins are usually equally effective in stimulating ATPase activity of skeletal acto-HMM, but at high concentrations of Mg2+ gizzard tropomyosin is more effective, a result that cannot be attributed to differences in the binding of the two tropomyosins to F-actin. The effects of tropomyosin also depend on the type of myosin; tropomyosin enhances activity of gizzard myosin under conditions in which it inhibits that of skeletal myosin. Increasing the pH or the Mg2+ concentration can reverse the effect of tropomyosin on actin-stimulated ATPase activity of skeletal HMM from activation to inhibition, but this reversal is not found with gizzard myosin. Activity in the absence of tropomyosin is independent of pH, and the loss of activation with increasing pH is not accompanied by loss of binding of tropomyosin to actin.

Studies of myosin and its proteolytic fragments by laser Raman spectroscopy

Two bands in the Raman spectrum of myosin, at 1,304 cm-1 and 1,270 cm-1, are attributable to alpha-helical structure. The first of these, also present in the spectrum of light meromyosin (LMM) but not in that of subfragment-1 (S-1), is assigned to the coiled-coil tail region of myosin; the second, seen in spectra of S-1 or heavy meromyosin (HMM), is largely absent from the spectrum of light meromyosin and is likely to correspond to the alpha-helical segments of the head region. When myosin or LMM aggregates, spectral bands attributable to backbone and sidechain groups sharpen suggesting a reduction in motional freedom. This sharpening is particularly apparent in the 902 cm-1 C--C stretching mode. Mg2+ broadens and shifts the peak at 1,244 cm-1 to 1,237 cm-1 and diminishes the intensity from 1,230 to 1,240 cm-1, changes which appear to be associated the S-1 region. MgPPi produces changes in the 1,300 cm-1 region attributable to alpha-helical regions in coiled-coil structures suggesting that MgPPi affects not only S-1, but also some part of the myosin rod.

Dependence on Ca2+ and tropomyosin of the actin-activated ATPase activity of phosphorylated gizzard myosin in the presence of low concentrations of Mg2+

Ca2+ and tropomyosin are required for activation of ATPase activity of phosphorylated gizzard myosin by gizzard actin at less than 1 mM Mg2+, relatively low Ca2+ concentrations (1 microM), producing half-maximal activation. At higher concentrations, Mg2+ will replace Ca2+, 4 mM Mg2+ increasing activity to the same extent as does Ca2+ and abolishing the Ca2+ dependence. Above about 1 mM Mg2+, tropomyosin is no longer required for activation by actin, activity being dependent on Ca2+ between 1 and 4 mM Mg2+, but independent of [Ca2+] above 4 mM Mg2+. Phosphorylation of the 20,000-Da light chain of gizzard myosin is required for activation of ATPase activity by actin from chicken gizzard or rabbit skeletal muscle at all concentrations of Mg2+ employed. The effect of adding or removing Ca2+ is fully reversible and cannot be attributed either to irreversible inactivation of actin or myosin or to dephosphorylation. After preincubating in the absence of Ca2+, activity is restored either by adding micromolar concentrations of this cation or by raising the concentration of Mg2+ to 8 mM. Similarly, the inhibition found in the absence of tropomyosin is fully reversed by subsequent addition of this protein. Replacing gizzard actin with skeletal actin alters the pattern of activation by Ca2+ at concentrations of Mg2+ less than 1 mM. Full activation is obtained with or without Ca2+ in the presence of tropomyosin, while in its absence Ca2+ is required but produces only partial activation. Without tropomyosin, the range of Mg2+ concentrations over which activity is Ca2+-dependent is restricted to lower values with skeletal than with gizzard actin. The activity of skeletal muscle myosin is activated by the gizzard actin-tropomyosin complex without Ca2+, although Ca2+ slightly increases activity. The Ca2+ sensitivity of reconstituted gizzard actomyosin is partially retained by hybrid actomyosin containing gizzard myosin and skeletal actin, but less Ca2+ dependence is retained in the hybrid containing skeletal myosin and gizzard actin.

Submillisecond rotational dynamics of spin-labeled myosin heads in myofibrils

The rotational motion of crossbridges, formed when myosin heads bind to actin, is an essential element of most molecular models of muscle contraction. To obtain direct information about this molecular motion, we have performed saturation transfer EPR experiments in which spin labels were selectively and rigidly attached to myosin heads in purified myosin and in glycerinated myofibrils. In synthetic myosin filaments, in the absence of actin, the spectra indicated rapid rotational motion of heads characterized by an effective correlation time of 10 microseconds. By contrast, little or no submillisecond rotational motion was observed when isolated myosin heads (subfragment-1) were attached to glass beads or to F-actin, indicating that the bond between the myosin head and actin is quite rigid on this time scale. A similar immobilization of heads was observed in spin-labeled myofibrils in rigor. Therefore, we conclude that virtually all of the myosin heads in a rigor myofibril are immobilized, apparently owing to attachment of heads to actin. Addition of ATP to myofibrils, either in the presence or absence of 0.1 mM Ca2+, produced spectra similar to those observed for myosin filaments in the absence of actin, indicating rapid submillisecond rotational motion. These results indicate that either (a) most of the myosin heads are detached at any instant in relaxed or activated myofibrils or (b) attached heads bearing the products of ATP hydrolysis rotate as rapidly as detached heads.

Enzymatic activities and ATP-induced fluorescence enhancement of myosin from fast and slow skeletal and cardiac muscles

The maximal ATP-induced enhancement of fluorescence and the dependence of this enhancement on ATP concentration were determined for myosins from fast and slow skeletal and cardiac muscle of the rabbit. With myosins from slow and cardiac muscle modifications in the preparative procedure and chromatography on DEAE-Sephadex were required to obtain preprations which were free of actin, which exhibited the maximal fluorescence enhancement and which bound two moles of ATP per mole of myosin. Since the fluorescence enhancement of cardiac and slow muscle myosins is labile at slightly alkaline pH, it was also necessary to minimize incubation at pH greater than 7 in order to attain the maximal enhancement. With fast muscle myosin the changes in preparative procedure, together with chromatography, led to a 50 to 100% increase in the steady-state rate of ATP hydrolysis and fluorescence enhancement, without changing the maximal binding of ATP. From a comparison of the rate of steady-state hydrolysis of ATP with the rate of decay of the enhanced fluorescence, it appears that for all three myosins, both ATP binding sites have the same enzymatic activity, the steady-state rate per site being slower for cardiac and slow muscle myosins than for fast muscle myosin.

Effect of Ca2+ binding on troponin C. Changes in spin label mobility, extrinsic fluorescence, and sulfhydryl reactivity

The Ca2+ binding component (TnC) of troponin has been selectively labeled with either a spin label, N-(1-oxyl-2,2,6,6-tetramethyl-4-piperidinyl) iodoacetamide, or with a fluorescent probe, S-mercuric-N-dansyl cysteine, presumably at its single cysteine residue (Cys-98) in order to probe the interactions of TnC with divalent metals and with other subunits of troponin. The modified protein has the same Ca2+ binding properties as native TnC (Potter, J. D., and Gergely, J. (1975) J. Biol. Chem. 250, 4628), viz. two Ca2+ binding sites at which Mg2+ appears to compete (Ca2+-Mg2+ sites, KCa = 2 X 10(7) M-1) and two sites at which Mg2+ does not compete (Ca2+-specific sites, KCa = 2 X 10(5) M-1). Either Ca2+ or Mg2+ alters the ESR spectrum of spin-labeled TnC in a manner that indicates a decrease in the mobility of the label, Ca2+ having a slightly greater effect. In systems containing both Ca2+ and Mg2+ the mobility of the spin label is identical with that in systems containing Ca2+ alone. The binding constants for Ca2+ and Mg2+ deduced from ESR spectral changes are 10(7) and 10(3) M-1, respectively, and the apparent affinity for Ca2+ decreases by about an order of magnitude on adding 2 mM Mg2+. Thus, the ESR spectral change is associated with binding of Ca2+ to one or both of the Ca2+-Mg2+ sites. Addition of Ca2+ to the binary complexes of spin-labeled TnC with either troponin T (TnT) or troponin I (TnI) produces greater reduction in the mobility of the spin label than in the case of spin-labeled TnC alone, and in the case of the complex with TnI the affinity for Ca2+ is increased by an order of magnitude. The fluorescence of dansyl (5-dimethylaminonaphthalene-1-sulfonyl)-labeled TnC is enhanced by Ca2+ binding to both high and low affinity sites with apparent binding constants of 2.6 X 10(7) M-1 and 2.9 X 10(5) M-1, respectively, calculated from the transition midpoints. The presence of 2 mM Mg2+, which produces no effect on dansyl fluorescence itself, in contrast to its effect on the spin label, shifts the high affinity constant to 2 X 10(6) M-1. Spectral changes produced by Ca2+ binding to the TnC-TnI complex furnish evidence that the affinity of TnC for Ca2+ is increased in the complex. The reactivity of Cys-98 to the labels and to 5,5'-dithiobis(2-nitrobenzoic acid) (Nbs2) is decreased by Ca2+ or Mg2+ both with native TnC and in 6 M urea. The reaction rate between Cys-98 and Nbs2 decreases to one-half the maximal value at a Ca2+ concentration that suggests binding to the Ca2+-Mg2+ sites. Formation of a binary complex between TnI and TnC reduces the rate of reaction, and there is a further reduction by Ca2+. The effect of Ca2+ takes place at concentrations that are 1 order of magnitude lower than in the case of TnC alone. These results suggest that the Ca2+ binding site adjacent to Cys-98 is one of the Ca2+-Mg2+ binding sites.

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.

Motion of subfragment-1 in myosin and its supramolecular complexes: saturation transfer electron paramagnetic resonance

Molecular dynamics in spin-labeled muscle proteins was studied with a recently developed electron paramagnetic resonance (EPR) technique, saturation transfer spectroscopy, which is uniquely sensitive to rotational motion in the range of 10(-7)-10(-3) sec. Rotational correlation time (tau2) were determined for a spin label analog of iodoacetamide bound to the subfragment-1 (S-1) region of myosin under a variety of conditions likely to shed light on the molecular mechanism of muscle contraction. Results show that (a) the spin labels are rigidly bound to the isolated S-1 (tau2 = 2 x 10(-7) sec) and can be used to estimate values of tau2 for the S-1 region of the myosin molecule; (b) in solutions of intact myosin, S-1 has considerable mobility relative to the rest of the myosin molecule, the value of tau2 for the S-1 segment of myosin being less than twice that for isolated S-1, while the molecular weights differ by a factor of 4 to 5; (c) in myosin filaments, tau2 increases by a factor of only about 10, suggesting motion of the S-1 regions independent of the backbone of the myosin filament, but slower than that in a single molecule; (d) addition of F-actin to solutions of myosin or S-1 increases tau2 by a factor of nearly 10(3), indicating strong immobilization of S-1 upon binding to actin. Saturation transfer spectroscopy promises to provide an extremely useful tool for the study of the motions of the crossbridges and thin filaments in reconstituted systems and in glycerinated muscle fibers.

The quantitative measurement of rotational motion of the subfragment-1 region of myosin by saturation transfer epr spectroscopy

According to current models of muscle contraction (Huxley, H. E., Science 164: 1356-1366 [1969]), motion of flexible myosin crossbridges is essential to the contractile cycle. Using a spin-label analog of iodoacetamide bound to the subfragment No. 1 (S1) region of myosin, we have obtained rotational correlation times (tau 2) for this region of the molecule with the ultimate goal of making quantitative measurements of the motion of the crossbridges under conditions comparable to those in living, contracting muscle. We used the newly developed technique of saturation transfer electron paramagnetic resonance spectroscopy (Hyde, J.S., and Thomas, D.D., Ann. N.Y. Acad Sci. 22:680-692 [1973]), which is uniquely sensitive to rotational motion in the range of 10(-7)-10(-3) sec. Our results indicate that the spin label is rigidly bound to S1 (tau 2 for isolated S1 is 2 X 10(-7) sec) and that the motion of the label reflects the motion of the S1 region of myosin. the value of tau 2 for the S1 segment of myosin is less than twice that for isolated S1, while the molecular weights differ by a factor of 4, indicating flexibility of myosin in agreement with the conclusions of Mendelson et al. (Biochemistry 12:2250-2255 [1973]). Adding F-actin increses tau 2 in either myosin or isolated S1 by a factor of mearly 103, indicating rigid immobilization of S1 by actin. Formation of myosin filaments (at an ionic strength of 0.15 or less) increses tau 2 by a factor of 10-30, depending on the ionic strength, indicating a decrease of the rotational mobility of S1 in these agregates. The remaining motion is at least a factor of 10 faster than would be expected for the filament itself, suggesting motion of the S1 region independent of the filament backbone but slower than in a single molecule. F-actin has a strong immobilizing effect on labeled S1 in myosin filaments (in 0.137 M KC1), but the immobilization is less complete than that observed when F-actin is added to labeled myosin monomers (in 0.5 M KC1). A spin-label analog of maleimide, attached to the SH-2 thiol groups of S1, is immobilized to a much lesser extent by F-actin than is the label on SH-1 groups. The maleimide label also was attached directly to F-actin and was sufficiently immobilized to suggest rigid binding to actin.