Denaturation mode of carp myofibrils when affected by temperature and salt concentration

ABSTRACT: Heating temperatures of 30–40°C and KCl concentrations of 0.1–0.5 M altered the denaturation mode of carp myofibrils. In 0.1 M KCl medium, heating temperature affected the denaturation of rod more significantly than of subfragment-1 (S-1), and a slow decrease in solubility at 30°C was accompanied by a slow denaturation of rod. KCl concentration at heating altered the denaturation mode differently at 30°C and 40°C. Increased KCl concentrations for heating reduced the rod denaturation rate at 40°C, but it was increased at 30°C. At concentrations above 0.3*Τ*M KCl, the denaturation rate for rod became identical to that for S-1 at both temperatures. Upon heating of chymotryptic digest of myofibrils, S-1 denaturation was similarly detected as in intact myofibrils, whereas practically no rod denaturation was detected. Thus, it was concluded that myosin structure connecting S-1 and rod has an important role in the denaturation process.     

Stabilization of myosin by ionic compounds as affected by F-actin

ABSTRACT:   Suppressive effects of non-ionic (sorbitol, maltose, and trehalose) and ionic (Na-glutamate, Na-acetate, Na-sulfate, and ammonium sulfate) compounds on the thermal inactivation of myosin subframgent-1 (S-1) and myofibril Ca²⁺-ATPase were compared. All compounds suppressed S-1 denaturation. When myofibrils were used (at 0.1 M KCl), sugars and sugar alcohol (non-ionic compounds) suppressed denaturation similar to S-1, while Na-glutamate, Na-acetate, and Na-sulfate weakly suppressed them. Ammonium sulfate accelerated denaturation, but suppressed denaturation when heated in 2 M KCl, at which myosin lost protection by F-actin. It was thus concluded that ionic compounds affected the denaturation of myofibrils in two ways; suppression as established with S-1, and acceleration as a result of loss of protection by F-actin caused by increase in ionic strength.     

Species-specific thermal denaturation pattern of fish myosin when heated as myofibrils as studied by myosin subfragment-1 and rod denaturation rates

Thermal denaturation of myofibrils from various species of fish was investigated by measuring ATPase inactivation, myosin aggregation, myosin subfragment-1 (S-1) and rod denaturation rates as studied by chymotryptic digestion. Decrease in monomeric myosin (myosin aggregation) was always faster than the ATPase inactivation for all myofibrils tested. The relative denaturation rate of rod to that of S-1 differed from species to species. Preceded denaturation of rod was observed with some species, and the opposite was true with other species. The denaturation pattern was explained by the different magnitude of S-1 stabilization by F-actin in myofibrils at low salt medium. Myofibrils which receive a great stabilization by F-actin as studied by ATPase inactivation showed the preceded rod denaturation pattern, and vice versa. S-1 portion, not F-actin, determined the different stabilization of S-1 by F-actin in myofibrils.     

Effect of calcium ion on the thermal denaturation of subfragment-1 and rod regions of squid myosin upon the heating of myofibrils

Thermal inactivation of Ca²⁺ ATPase of squid myofibrils was significantly suppressed in the presence of Ca²⁺. Monomeric myosin content decreased much faster than Ca²⁺ ATPase inactivation in Ca medium, which was well explained by fast rod denaturation. In contrast, rod denaturation was slower than S-1 in EDTA medium. The decrease in monomeric myosin content was explained by faster S-1 denaturation. Comparing the S-1 and rod denaturation rates at a fixed temperature, it was concluded that S-1 denaturation was suppressed by Ca²⁺ whereas the rod denaturation was not. An unfolding experiment with isolated myosin rod confirmed that there was no stabilizing effect of Ca²⁺ on myosin rod. It was concluded that significant stabilization of the S-1 portion by Ca²⁺ generated the apparently different myosin denaturation patterns in the two media.     

Myosin denaturation in heated myofibrils of scallop adductor muscle

The thermal inactivation of Ca²⁺ ATPase of scallop myofibrils (0.1 M KCl, pH 7.5) was found to be unaffected by the presence of Ca²⁺. Monomeric myosin content and salt solubility decreased much faster than Ca²⁺ ATPase inactivation in both Ca and EDTA media, which was well explained by faster denaturation of the rod portion than subfragment-1 of myosin. In contrast, when the myofibrils were heated at 0.5 M KCl, a slow decrease in salt solubility was observed, which was also explained by slow denaturation of the rod portion of myosin. Myofibrils from scallop smooth muscle showed the same denaturation pattern as those from adductor muscle. These results show that mollusk myosin is not always stabilized by Ca²⁺.     

Thermal denaturation profiles of catfish and tilapia myofibrils as affected by pH for heating

Thermal denaturation profiles of catfish myosin when heated as myofibrils (Mf) were compared with those of tilapia. The Ca²⁺-ATPase inactivation rate of catfish myofibrils was the same as that of tilapia myofibrils. The conclusion was the same with isolated myosin. Catfish Mf was clearly distinguished from tilapia Mf in terms of subfragment-1 (S-1) and rod denaturation. Quick denaturation of rod relative to S-1 was characteristic of catfish Mf, while slower denaturation of rod relative to S-1 was the pattern for tilapia Mf. These patterns were greatly affected by the pH for heating. Rod denaturation was accelerated with increasing pH for heating and oppositely suppressed by lowering the pH, for both Mf. Tilapia Mf showed a S-1 and rod denaturation pattern similar to that for catfish Mf, but at 1 pH unit higher; for example, the pattern of catfish Mf at pH 7.5 was similar to that for tilapia Mf at pH 8.5. Less rigid filament structure of catfish Mf than tilapia Mf was demonstrated by studying chymotryptic digestion at various pH values. Accordingly, the difference in the S-1/rod denaturation patterns between the two fish species can be explained by the different rigidity of their myosin filaments.     

Suppressing effect of neocarrabiose 4-O-sulfate on thermal and freeze denaturation of myosin subfragment-1 and myofibrils

Suppressive effects of neocarrabiose 4-O-sulfate on the thermal and freeze denaturation of myosin subfragment-1 (S-1) and on myofibrils were investigated. The compound strongly suppressed the thermal denaturation of S-1. Its suppressive effect was greater than that of sorbitol and similar to that of maltose. However, it tended to accelerate the denaturation of myofibrils, suggesting a loss of protection by F-actin upon its addition. The compound suppressed the freeze denaturation of myofibrils and S-1. The effect was similar to that of sorbitol or maltose, and completely different from that of Na-sulfate. The compound solubilized myofibrils at concentrations similar to KCl. Therefore, it was concluded that neocarrabiose 4-O-sulfate behaved as an ionic salt in the thermal treatment process, whereas it behaved as a sugar in the frozen storage process.     

Myosin denaturation in “Burnt” Bluefin tuna meat

A quantitative conversion of tuna meat into muscle homogenate made it possible to study myosin denaturation in Bluefin tuna meat. Myosin denaturation was accessed by measuring Ca²⁺-ATPase activity, salt-solubility with and without Mg-ATP, monomeric myosin content, and amount of subfragment-1 (S-1) and rod produced by chymotryptic digestion. Commercially available tuna used in this study showed a pH around 5.4–5.7. Myosin in the meat lost the salt-solubility measured in the absence of Mg-ATP; however, such myosin showed full salt-solubility when released from actin in the presence of Mg-ATP. Incubation of tuna meat at 30 °C for up to 90 min caused obvious myosin denaturation. However, the tuna meat dialyzed against neutral pH buffer showed practically no myosin denaturation by the same heating. It was suggested that exposure to lowered pH to around 5.5 and increased temperature of 30 °C led myosin denaturation. Myosin denaturation in the “Burnt” Bluefin tuna sample was analyzed. A significant myosin denaturation was observed with the part showing the “Burning” symptom, the inner part of the tuna meat near the spine. Myosin in that part showed almost no Ca²⁺-ATPase activity, no salt-solubility even with Mg-ATP, no recovery of monomeric myosin, and almost no production of S-1 by chymotryptic digestion. However, myosin denaturation was not detectable for the meat taken from outer parts of the same tuna near the skin with normal appearance. It was demonstrated that “Burning” of tuna meat occurring in the deep part of the body is accompanied by myosin denaturation. The above results suggested that insufficient cooling of the deep part of body would be the reason for “Burning” of tuna meat.     

Different effects of ionic and non-ionic compounds on the freeze denaturation of myofibrils and myosin subfragment-1

The effects of non-ionic (sorbitol, maltose, trehalose) and ionic compounds (Na-glutamate, Na-acetate, Na-sulfate, ammonium sulfate) on freeze denaturation of myosin subfragment-1 (S-1) and of myofibrils were compared. Sugars, Na-glutamate and Na-acetate well suppressed the freeze denaturation of myofibrils as well as S-1 in a concentration dependent manner. Although sulfate suppressed freeze denaturation of S-1 irregularly, it accelerated myofibril denaturation. It was concluded that sulfate salts were useless as cryoprotectant for myofibrils. Stabilization extent by F-actin in frozen storage was much less than that in heating.     

Thermal denaturation and autolysis profiles of myofibrillar proteins of mantle muscle of jumbo squid Docidicus gigas

ABSTRACT:    Jumbo squid was very similar to Japanese common squid in terms of myofibrillar Ca²⁺-, Mg²⁺- and K⁺(EDTA)-ATPase activities. Myofibrils of jumbo squid were significantly stabilized upon addition of Ca²⁺ and destabilized by increasing KCl concentration for heating. Incubation of muscle homogenate of jumbo squid induced a selective cleavage of myosin into two major fragments and the cleavage was inhibited by EDTA. Autolysis was prominent at and above 0.3 M NaCl where myosin filaments dissolve. The enzyme involved in the autolysis was proved to be unstable showing maximal autolysis rate at 25°C. Washing the homogenate partially reduced the autolysis activity.     

Stabilizing effect of Ca<Superscript>2+</Superscript> on myosin and myofibrils of squid mantle muscle as affected by heating conditions

The suppressive effects of Ca²⁺ on the thermal denaturation of myosin and myofibrils of squid mantle muscle were compared. The stabilization effect on myosin was smaller than that on myofibrils and was not affected by KCl concentration. The stabilizing effect of Ca²⁺ on myosin decreased as the heating temperature dropped, showing no stabilization at 20°C, while the effect on myofibrils was the same at all temperatures tested. The stabilizing effect of Ca²⁺ on myosin disappeared even at 30°C in the presence of sorbitol, where a small inactivation rate was found, while the effect of Ca²⁺ on myofibrils was equally detected irrespective of the reduction in inactivation rate in the presence of sorbitol. Stabilization of myosin by Ca²⁺ again appeared even in the presence of sorbitol when the heating temperature was raised to 38°C. It was suggested that Ca²⁺ confers stabilization on myosin only when myosin is under unstable conditions. The stabilization effect of Ca²⁺ on myosin was enhanced upon F-actin binding: Ca²⁺-bound myosin was more significantly stabilized by F-actin binding, and the effect was no longer affected by the conditions for heating.     

Water solubilization of glycated carp and scallop myosin rods,and their soluble state under physiological conditions

ABSTRACT:   Myosin rod regions prepared from carp Cyprinus carpio dorsal muscle and scallop Pecten yessoensis striated adductor muscle were non-enzymatically reacted with glucose (glycation), and the changes in the filament-forming ability and the size distribution of the rod filaments during glycation were examined to discuss the molecular mechanism of the water solubilization of myosin molecules under physiological conditions. Both myosin rods became solubilized in 0.1 M NaCl (pH 7.5), and their filament-forming ability was weakened with the progress of glycation. The size of the insoluble filaments of the myosin rods was diminished with an increase in the solubility under physiological conditions, and glycated myosin rods finally existed as monomers in 0.1 M NaCl (pH 7.5). These results supported the hypothesis that the water solubilization of myosin by glycation was caused by the loss of the filament-forming ability of myosin molecules. Water solubilization seemed to occur through the same molecular mechanism regardless of the species, whereas the scallop myosin rods required a much larger number of lysine residues reacted with glucose to collapse the insoluble filaments, in contrast to the carp myosin rods.     

Characterization of fast skeletal myosin from white croaker in comparison with that from walleye pollack

ABSTRACT:   Enzymatic and structural properties of white croaker fast skeletal muscle myosin were determined and compared with those of walleye pollack counterpart. Ca²⁺-ATPase activity of white croaker myosin was decreased to approximately 70% of the original activity during 1 day of storage at 0°C and pH 7.0 in 0.5 M KCl and 0.1 mM dithiothreitol, whereas that of walleye pollack was decreased to approximately 20% under the same condition. The activation energy ( E _a) for inactivation of white croaker myosin calculated by the Arrhenius plot for inactivation rate constant (K_D) was 1.2-fold higher than that of walleye pollack. While Ca²⁺-ATPase showed a similar KCl-dependency for the two species, the maximal activity was observed at pH 6.2 and 6.3 for white croaker and walleye pollack, respectively. Actin-activated myosin Mg²⁺-ATPase activity of white croaker was approximately half that of walleye pollack at 0.05 M KCl and pH 7.0, although the two myosins showed a similar affinity to F-actin with K _m of 1.7 and 1.4, respectively. Limited proteolysis with α-chymotrypsin cleaved heat-denatured white croaker myosin mainly at heavy meromyosin/light meromyosin (HMM/LMM) junction, whereas walleye pollack myosin was cleaved at several sites in LMM as well as at the HMM/LMM junction.     

Myosin and actin denaturation in frozen stored kuruma prawn Marsupenaeus japonicus myofibrils

Myosin and actin denaturation in kuruma prawn myofibrils stored frozen (0.1 M NaCl, pH 7.5) at ?20 °C was investigated. The inactivation profile of Ca²⁺-ATPase in the myofibrils was identical to that for myosin, indicating that myosin in myofibrils was not protected by actin. The presence of myosin detached from actin in the soluble fraction was proven by ammonium sulfate fractionation in the absence and presence of Mg-ATP. Actin denaturation in myofibrils was further confirmed by its increased susceptibility to chymotryptic degradation. In the frozen myofibrils, actin denatured more rapidly quicker than myosin: actin had completely denatured by storage day 1, followed by a gradual denaturation of myosin. Both myosin and actin in the frozen stored myofibrils retained their high salt-solubility, which decreased slowly during the frozen storage period. The presence of aggregated inactivated myosin in the salt-soluble fraction was proven by precipitation at 40 % saturation of ammonium sulfate in the presence of Mg-ATP, leaving active monomeric myosin in the soluble fraction. Almost no actin denaturation was observed with heated myofibrils.     

Heat-induced structural changes and aggregation of walleye pollack myosin in the light meromyosin region

Heat-induced structural changes and aggregation properties of walleye pollack myosin, light meromyosin (LMM) and heavy meromyosin (HMM) were investigated. According to the circular dichroism (CD) measurement, the α-helix content of the pollack myosin and LMM were estimated to be 72% and 90% at 5°C but decreased to 22% and 21% by increasing the temperature to 60°C with two transitions at 35°C and 50°C, respectively. In contrast, that of HMM decreased gradually from 37% to 33% by increasing the temperature from 5°C to 40°C, and decreased steeply to 20% above 50°C. These results indicate that the decrease in the α-helix content in the myosin molecule upon heating was attributable mainly to the decrease in the α-helix content in the LMM region. In contrast, 1-anilinonaphthalene-8-sulfonate (ANS) fluorescence and light scattering intensity of both myosin and HMM were remarkably increased above 25°C and 35°C, respectively, while those of LMM showed only a slight change even above 60°C. Although LMM alone formed no aggregates detectable by the light scattering measurement, it formed coprecipitates with myosin but not with HMM upon heating at 40°C for 10 min. These facts suggest that LMM bind to the LMM region of the myosin. Further, it was found that myosin gel formed in a test tube by the same heating conditions was significantly weakened by coexistence of LMM. These results suggest that the association of the LMM region of myosin molecules is essential for the heat-induced gelation of myosin.     

Determination of primary structure of amberjack myosin heavy chain and its relationship with structural stability of various fish myosin rods

The structural stability of fish myosin depends upon species and temperatures of water in which fish live. Primary, secondary, and quaternary structures of myosin heavy chain (MyHC) from three species of fish living at different temperature ranges have been compared with those of rabbit MyHC in order to investigate the differences in stability. Primary structure of MyHC, although being accessible for warm-water and cold-water fish (carp and walleye pollack), was not available in previous for tropical-water fish literature; so in this study primary structure of MyHC of the tropical-water fish amberjack has been determined by cloning and sequencing its cDNA. The MyHC has 1938 amino acid residues (AA), which are almost as much as as those of carp and walleye pollack. The amberjack MyHC is 91–95% homologous with other fish and rabbit MyHCs. There is a discernible difference between animal species with stable myosin rod (amberjack, carp, and rabbit) and walleye pollack with unstable rod. Stable rod species have a high probability of forming coiled-coil around the COOH-terminal end of the rod, while the pollack has a low coiled-coil formation probability. In addition, the average scores of the coiled-coil for myosin rod were rabbit (1.738) > amberjack (1.691) > carp (1.680) > walleye pollack (1.674) which correlated exactly with the observed stability. The results suggest that coiled-coil forming ability, particularly around the COOH-terminal end, directs structural stability of fish myosin rod.     

Gelation of low salt soluble proteins from scallop adductor muscle in relation to its freshness

ABSTRACT: The low salt extract from scallop striated adductor muscle contained extra proteins in addition to sarcoplasmic proteins and was turned into a gel upon standing or immediately by the addition of Ca²⁺. The amount of extra protein, which was composed of a large amount of actin and a small amount of myosin, decreased with a decrease in adenosine triphosphate (ATP) content in the muscle during storage at 5°C. Actin was easily extracted from scallop myofibrils in low salt solution with ATP at 1 mM or above. Furthermore, ATP was required to induce the gelation of the low salt extract. A visual observation of the gelation of low salt extract is therefore a simple and easy method to inspect prerigor state of scallop adductor muscle.     

Rheological properties and structural changes in steamed and boiled abalone meat

ABSTRACT: Changes in tissue structures, rheological properties, and water content of abalone meat were studied in relation to boiling and steaming time. The adductor muscle of abalone Haliotis discus, which was removed directly from the shell, was boiled or steamed for 1 h, 2 h, and 3 h. When observed under a light microscope and by scanning electron microscopy, structural changes in the myofibrils were greatest in the boiled abalone meat compared with the steamed meat. When heating time was increased from 1 h to 3 h, the instantaneous modulus E ₀ of boiled abalone meat decreased gradually with increased heating time, whereas the E ₀ of steamed abalone meat was reduced when heated for 2 h. When heated for 1 h, the relaxation time of steamed abalone meat was much longer than that of boiled meat. There were no significant changes in the relaxation time of abalone meat among the different boiling times, but the relaxation time of steamed abalone meat was reduced gradually with increasing heating times. The study's results confirmed that the difference in rheological properties between the boiled and steamed meats was due mainly to the denaturation level of myofibrils when heated for 1 h, as well as due to the changes in water and solid content and the manner in which the inner water was exchanged after heating time was increased from 1 h to 3 h.     

Changes in physical properties of heat-induced gel on addition of gluconate associated with suppression of myosin denaturation in walleye pollack salt-ground <Emphasis Type="Italic">surimi</Emphasis> during preheating

Changes in physical properties of two-step heated gels on addition of gluconate were investigated in terms of relationships between breaking strength and gel stiffness. Regression lines between the breaking strength and the gel stiffness were extended to the x-axis (gel stiffness), and the intercept was defined as S_BSO. The S_BSO of the two-step heated gels increased with gluconate contents in salt-ground surimis, suggesting that the harder but less elastic gels formed on addition of gluconate were dose-dependent. Conversely, the denaturation rate constants of myosin in salt-ground surimis during preheating estimated by means of Ca-ATPase inactivation, loss of salt solubility, and decrease of denaturant solubility were considerably reduced by gluconate. Thus, the progress of myosin denaturation was strongly suppressed. Increments of S_BSO (δS_BSO) of the two-step heated gels on addition of gluconate were inversely correlated with the denaturation rate constants of myosin in salt-ground surimis for every index. Thus, the changes in physical parameters of two-step heated gel caused by gluconate may be associated with the sluggish progress of myosin denaturation in salt-ground surimi during preheating.     

Development of myofibrillar ATPase assay system on pH stat

The ATPase assay system on pH stat apparatus was developed. For the ATPase activity measurement, hydrogen ion (H⁺) concentration delivered from inorganic phosphate (Pi) as a hydrolysis production of ATP was estimated by titrating with 20 mM NaOH solution instead of colorimetric measurement of Pi. Inclusion of 0.5 M KCl in the ATP stock solution and 2 mM Tris-maleate (pH 7.0) buffer in the reaction medium reduced the extent of pH change upon addition of ATP to initiate the ATPase reaction. The amount of H⁺ liberated from Pi was strongly affected by the set pH for the ATPase assay with a promotion at alkaline pH. Thus, it was required to estimate the coefficient to convert H⁺ to a Pi concentration at a specific pH. The specified coefficient at pH 7.0 was 1.248. ATPase assay on pH stat allowed us to follow the ATP hydrolysis by myofibrils continuously showing a curvature profile at low salt medium (≤0.2 M KCl) or a linear profile at high salt (≥0.3 M KCl).