Thermal behavior of myofibrillar proteins from the adductor muscles of scallops: a differential scanning calorimetric study (DSC)

Paredi, M.E.; Tomas, M.C.; Crupkin, M.

doi:10.1590/S0104-66322003000200009

Abstract

Muscles and different proteins obtained from scallops (Chlamys tehuelchus and Zygochlamys patagonica) were analyzed. In both species of scallop, the thermograms of striated and smooth muscles showed two endothermic transitions. The Tmax values corresponding to striated and smooth muscles from C. tehuelchus were 53.2, 79.0ºC and 52.7, 78.0 ºC, respectively. The Tmax corresponding to striated and smooth muscles of Z. patagonica were 55.0, 79.2ºC and 54.7, 78.7ºC, respectively. No significant differences were observed between the thermal transitions of myofibrils and actomyosin of both types of muscles from both species of scallop. Irrespective of the species, the thermal stability decreased when the pH of the muscles was increased. The increase in ionic strength greatly affected Tmax, the deltaH total and the deltaH of the first transition. A significant decrease in deltaH total and deltaH corresponding to both transitions was observed, particularly in the striated muscles of Zygochlamys patagonica. These results indicate a major sensitivity of the adductor muscles of Zygochlamys to changes in the chemical environment.

thermal stability; chemical environment; scallop

Thermal behavior of myofibrillar proteins from the adductor muscles of scallops. A differential scanning calorimetric study (DSC)

M.E.Paredia, I, II, ^* * To whom correspondence should be addressed ; M.C.Tomas^{b, III}; M.Crupkin^{a, I}

^aCentro Regional Sur CEMSUR-CITEP, Email: paredi@mdp.edu.ar

Marcelo T. de Alvear 1168- 7600 Mar del Plata-Argentina

^bCentro de Investigaciones y Desarrollo en Criotecnología de Alimentos - CIDCA - (Fac. Cs Exactas-CONICET) - 47 y 116 - 1900 La Plata-Argentina

^IFCAB. Universidad Nacional de Mar del Plata

^IIComisión de Investigaciones Científicas de la Pcia de Buenos Aires(CIC)

^IIIConsejo Nacional de Investigaciones Científicas y Técnicas (CONICET)

ABSTRACT

Muscles and different proteins obtained from scallops (Chlamys tehuelchus and Zygochlamys patagonica) were analyzed. In both species of scallop, the thermograms of striated and smooth muscles showed two endothermic transitions. The T_max values corresponding to striated and smooth muscles from C. tehuelchus were 53.2, 79.0ºC and 52.7, 78.0 ºC, respectively. The T_max corresponding to striated and smooth muscles of Z. patagonica were 55.0, 79.2ºC and 54.7, 78.7ºC, respectively. No significant differences were observed between the thermal transitions of myofibrils and actomyosin of both types of muscles from both species of scallop. Irrespective of the species, the thermal stability decreased when the pH of the muscles was increased. The increase in ionic strength greatly affected T_max, the DH total and the DH of the first transition. A significant decrease in DH total and DH corresponding to both transitions was observed, particularly in the striated muscles of Zygochlamys patagonica. These results indicate a major sensitivity of the adductor muscles of Zygochlamys to changes in the chemical environment.

Keywords: thermal stability, chemical environment, scallop.

INTRODUCTION

The study of the thermal behavior of myofibrillar proteins is of technological importance for determining and predicting the final quality of meat products because the functional and textural characteristics of meat depend mainly on their myofibrillar proteins. Differential scanning calorimetry (DSC) offers a direct method of studying the thermal transitions of muscle proteins in situ (Wright et al., 1977).

Invertebrate proteins have different thermal characteristics because they have an inherent myofibrillar protein called paramyosin (Paredi et al., 1994). Paramyosin constitutes the core of thick filaments in invertebrate muscles, where which is covered by a cortical layer of myosin (Cohen et al., 1971; Elfvin et al., 1976). Paramyosin considerably alters the characteristic texture of marine meat gel products

(Noguchi, 1979; Sano et al., 1986). Scallops have two kinds of adductors, the larger one which contains striated muscle and the a smaller one which contains smooth muscles. (Kondo and Morita, 1981). The smooth muscle of the Tehuelche scallop (Chlamys tehuelchus) contains more paramyosin than the striated muscle (Paredi, 1994). In addition, smooth muscles of the patagonian scallop contain more paramyosin than those of the tehuelche scallop (Paredi and Crupkin, 2000). Previous work suggested that different paramyosin-paramyosin or myosin-paramyosin interactions influence the thermal stability of myofibrillar proteins in marine invertebrates (Paredi et al., 1998). The purpose of this work was to use DSC to study the thermal behavior of myofibrillar proteins in striated and smooth muscles from two species of scallop in different chemical environments.

MATERIALS AND METHODS

Specimens of the tehuelche scallop (Chlamys tehuelchus) were collected at the Gulf of San Jose, Chubut, Argentina. Mature specimens with a length of 70mm, were selected. Patagonian scallops (Zygochlamys patagónica) were caught on the Argentine Continental Shelf in the Reclutas bed (39° 24' S; 55° 56' W). Mature specimens with a shell height of 55-65mm, were selected. Muscles were dissected and carefully freed of adhering pancreatic and liver tissues. All the procedures were carried out at 2-4°C.

Preparation of Myofibrillar Proteins

The procedure followed to obtain partially purified actomyosin was described by Paredi et al. (1990). Myofibrils was obtained according to Chantler and Szent-Gyorgyi (1980) .

The purity of proteins was assessed by SDS-PAGE 10% gels as reported by Laemmli (1970). The protein concentration was determined according to the Lowry method (Lowry et al., 1951).

Differential Scanning Calorimetry

DSC studies were performed in a Polymer Lab (PL-DSC, Reometric Scientific) according to previous work (Paredi et al., 1994). Temperature calibrations were made according to ASTM Norm E 474/80 using indium thermograms. The samples (20mg wet weight) were placed in the DSC hermetic pans, assuring good contact between the sample and the capsule bottom. Triplicate samples were analyzed. A hermetic pan with 18µl of distilled water was used as reference. After DSC analysis, capsules were punctured and the dry matter was determined by drying at 105°C overnight. All the samples were scanned at 10°C/min over the range of 10 to 100°C at a sensitivity of 0.5mV/cm. Total and partial denaturation enthalpies were estimated by measuring the area under the DSC transition curve.

pH and Ionic Strength Adjustment

Small pieces of muscle were dissected with a scalpel, treated with a 0.05M phosphate buffer solution, and stirred for 30 min at 0-4° C. The pH was adjusted to the desired value with 0.1N NaOH or 0.1N HCl. The ionic strengths were adjusted by the addition of NaCl at values between I=0.05 and 0.5.

Statistical Analysis

Analysis of variance was used and Duncan's New Multiple Range Test was applied to the data using a SYSTAT statistical analysis package (SYSTAT, 1994).

RESULTS AND DISCUSSION

DSC thermograms of striated whole muscle from patagonian scallops showed two endothermic transitions with T_max of 55.0 and 79.2° C (Figure 1a). In the thermograms of smooth whole muscle a similar profile was obtained and two endothermic transitions with T_max 54.7 and 78.7°C were observed (Data not shown). Similar DSC thermograms were obtained for striated and smooth muscles from the tehuelche scallop with T_max of 53.2, 79.0°C and 52.7, 78.0°C, respectively. To study the contribution of myofibrillar proteins to DSC transition of whole muscle, muscle depleted of sarcoplasmic protein fraction, myofibrils and actomyosin from smooth and striated muscles were also analyzed. Figure 1 shows that the endothermic transitions form muscle depleted of sarcoplasmic protein, myofibrils and actomyosin from striated muscle of Zygochlamys patagonica. Isolated and purified myofibrils and actomyosin from both types of muscle of both species of scallop showed thermograms similar to those of the respective whole muscles, with a slight displacement towards lower temperature. These results indicate that myosin and paramyosin contributed to the first transition and acting to the second transition. Similar results were reported for other invertebrates species (Paredi et al., 1994, 1996).

The characteristics associated with the chemical environment, such as pH and ionic strength, could modify both the thermal stability and the conformational structure of the proteins (Wright and Wilding, 1984). As shown in Figure 1(b and c), when pH increased to 8.0 a displacement of the thermal transition to lower temperatures occurred. A significant decrease (p<0.05) in the T_max values for both transitions was found in striated muscle of the patagonian scallop at pH 8.0. Smooth muscle was affected in a similar manner by pH (data no shown). Striated muscles were more affected by the increase in pH than smooth ones. The DSC thermograms of two types of adductor muscle from the tehuelche scallop were similar to those of the patagonian scallop, but the smooth muscles were more affected by pH (data not shown). A significant decrease (p<0.05) in DH total and DHpeak I when the pH increased to 8.0 was observed in both types of muscles from the patagonian scallop (Table 1a). A significant decrease (p<0.01) was found at pH 8.0 in the DHpeak II of striated muscles from the patagonian scallop. These results agree with those obtained for other species of fish (Beas et al., 1990; Howell et al., 1991).

Thumbnail

The denaturation entalphies (DH total and DHpeak I) from smooth muscles of the tehuelche scallop showed a significant decrease (p <0.05) at pH 8.0 (Table 1b). A significant modification in the myosin-paramyosin zone of the thermograms with a decrease in the T_max values and endothermal areas was observed when the ionic strength was increased to 0.5 in both types of muscles from the patagonian scallop (Fig. 2c).

Thumbnail

These results were similar for both species despite the fact that the striated muscles of the patagonian scallop were affected more than the smooth muscles. It has been postulated that at low ionic strength, molecules of myosin aggregate to form filaments which are stable than individual molecules present at high ionic strength (Samejima et al., 1983). Merrick and Johnson (1977) reported that solubility of paramyosin also increased at high ionic strength.

With respect to the second transition, actin was significantly affected by the increase in ionic strength and a displacement of the T_max value was observed with the increases in ionic strength in the patagonian scallop (Fig.2). A similar behavior was found for the tehuelche scallop. It had already been reported that KCl destabilizes the actin of bovine and fish striated muscles in this way (Stabursvik and Martens, 1980; Beas et al., 1990; Paredi et al., 1994).

As can be seen in Table 2 (a, ^b ) irrespective of species of scallop a significant decrease (p<0.05) in the denaturation entalpies was observed in both types of muscle when the ionic strength increased to 0.5.

Thumbnail

CONCLUSIONS

The paramyosin content was not directly responsible for thermal stability in either species of scallop. In both smooth and striated muscle the zone corresponding to the first transition was affected more by the increase in pH and ionic strength. Modifications in the chemical environment affected the striated muscle of the patagonian scallop more than they affected the smooth muscle. Conversely, the smooth muscle was affected more than the striated muscle in the tehuelche scallop. Zygochlamys patagonica showed a major sensitivity to changes in the chemical environment.

ACKNOWLEDGEMENT

This work was supported by grants from FONCYT. PICT 03794/98. We thank to Eng. M.E. Almandos for his assistance with the statistical analysis.

Received: March 5, 2002

Accepted: February 11, 2003

Beas, V.E. Wagner, J.R., Crupkin, M. and Añon, M.C. (1990). Thermal denaturation of hake (Merluccius hubbsi) myofibrillar proteins. A differential scanning calorimetric and electrophoretic study. J. Food Sci., 55, 683.
Chantler, P.D. and Szent-Gyorgyi, A.G. (1980). Regulatory light chains and scallop myosin: Full dissociation, reversibility and cooperative effects. J. Mol. Biol.,138, 473.
Cohen., C., Szent-Gyorgyi, A.G. and Kendrick-Jones, J. (1971). Paramyosin and the filaments of molluscan "catch" muscles. I. Paramyosin structure and assembly. J. Mol. Biol., 56, 223.
Elfvin., M., Levine, R.J.C. and Dewey, M.M. (1976). Paramyosin in invertebrates muscles. I. Identification and localization. J. Cell. Biol., 71, 261.
Howell, B.K., Matthews, A.D. and Donnelly, A. P. (1991). Thermal stability of fish myofibrils a differential scanning calorimetric study. Int. J. of Food Sci and Tech., 26, 283.
Kondo, S and Morita, F. (1981) Smooth muscle of scallop adductor contains at least two kinds of myosin. J. Biochem. 90, 673.
Laemmli, U.K. (1970). Cleavage of structural proteins during the assembly of the head of bacteriophage T4 . Nature, 227, 680.
Lowry, O.H., Rosembrough, N.J., Farr., A.L. and Randall, R.J. (1951). Protein measurement with the folin phenol reagent. J. Biol. Chem., 193, 265.
Merrick, J.P. and Johnson, W.H. (1977). Solubility properties of a -reduced paramyosin. Biochemistry, 16, 2260.
Noguchi, S. (1979). Reito surimi no kagaku- .I.Gyoniku Neriseihin Gijutsu Kenkyu Kaishi., 5, 356
Paredi, M.E., De Vido de Mattio, N. and Crupkin, M. (1990). Biochemical properties of actomyosin of cold stored striated adductor muscle of Aulacomya ater (Molina). J.Food Sci., 55, 1567.
Paredi, M.E., Tomas, M.C., Crupkin, M. and Añon, M.C. (1994). Thermal denaturation of Aulacomya ater (Molina) myofibrillar proteins. A differential scanning calorimetric study. J. Agric. Food Chem., 42, 873.
Paredi, M.E. (1994). Ph.D.diss., Fac. Cs Exactas y Naturales. Universidad Nacional de Mar del Plata.
Paredi, M.E., Tomas, M.C., Crupkin, M and Añon, M.C. (1996). Thermal denaturation of muscle proteins from male and female squid (Illex argentinus) at different sexual maturation stages. A differential calorimetric study. J Agric. Food Chem., 44, 3812.
Paredi, M.E., Tomas, M.C., Añon, M.C. and Crupkin, M. (1998).Thermal stability of myofibrillar proteins from smooth and striated muscles of scallop (C. tehuelchus) A differential scanning calorimetric study. J. Agric. Food Chem., 46, 3971.
Paredi, M.E. and Crupkin, M. (2000). Propiedades bioquímicas y funcionales de la actomiosina de músculo aductor de vieira (Zygochlamys patagónica). Almacenamiento a 2-4 ºC. IV Jornadas Nacionales de Ciencias del Mar. Puerto Madryn, Chubut, Argentina.
Samejima, K., Ishioroshi, M. and Yasui, T. (1983) Scanning calorimetric studies on thermal denaturation of myosin and its subfragments. Agric. Biol. Chem., 47, 2373.
Sano, T., Noguchi, S. F., Tsuchiya.,T. and Matsumoto, J. J. (1986). Contribution of paramyosin to marine meat gel characteristics. J. Food Sci., 51, 946.
Stabursvik, E. and Martens, H. (1980). Thermal transitions of the proteins in post rigor muscle tissues as studied by differential scanning calorimetry. J. Sci. Food Agric., 31, 1034.
Wright, D.J. and Wilding, P. (1984) Differential scanning calorimetric study of muscle and its proteins: myosin and its subfragments. J.Sci.Food Agric., 35, 357.
Wright, D.J., Leach, L.B. and Wilding, P. (1977). Differential scanning calorimetric studies of muscle ant its constituent proteins. J.Sci.Food Agric., 28, 557.

*

To whom correspondence should be addressed

Publication Dates

Publication in this collection
26 June 2003
Date of issue
June 2003

History

Accepted
11 Feb 2003
Received
05 Mar 2002

This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.

[1] Beas, V.E. Wagner, J.R., Crupkin, M. and Añon, M.C. (1990). Thermal denaturation of hake (Merluccius hubbsi) myofibrillar proteins. A differential scanning calorimetric and electrophoretic study. J. Food Sci., 55, 683.

[2] Chantler, P.D. and Szent-Gyorgyi, A.G. (1980). Regulatory light chains and scallop myosin: Full dissociation, reversibility and cooperative effects. J. Mol. Biol.,138, 473.

[3] Cohen., C., Szent-Gyorgyi, A.G. and Kendrick-Jones, J. (1971). Paramyosin and the filaments of molluscan "catch" muscles. I. Paramyosin structure and assembly. J. Mol. Biol., 56, 223.

[4] Elfvin., M., Levine, R.J.C. and Dewey, M.M. (1976). Paramyosin in invertebrates muscles. I. Identification and localization. J. Cell. Biol., 71, 261.

[5] Howell, B.K., Matthews, A.D. and Donnelly, A. P. (1991). Thermal stability of fish myofibrils a differential scanning calorimetric study. Int. J. of Food Sci and Tech., 26, 283.

[6] Kondo, S and Morita, F. (1981) Smooth muscle of scallop adductor contains at least two kinds of myosin. J. Biochem. 90, 673.

[7] Laemmli, U.K. (1970). Cleavage of structural proteins during the assembly of the head of bacteriophage T4 . Nature, 227, 680.

[8] Lowry, O.H., Rosembrough, N.J., Farr., A.L. and Randall, R.J. (1951). Protein measurement with the folin phenol reagent. J. Biol. Chem., 193, 265.

[9] Merrick, J.P. and Johnson, W.H. (1977). Solubility properties of a -reduced paramyosin. Biochemistry, 16, 2260.

[10] Noguchi, S. (1979). Reito surimi no kagaku- .I.Gyoniku Neriseihin Gijutsu Kenkyu Kaishi., 5, 356

[11] Paredi, M.E., De Vido de Mattio, N. and Crupkin, M. (1990). Biochemical properties of actomyosin of cold stored striated adductor muscle of Aulacomya ater (Molina). J.Food Sci., 55, 1567.

[12] Paredi, M.E., Tomas, M.C., Crupkin, M. and Añon, M.C. (1994). Thermal denaturation of Aulacomya ater (Molina) myofibrillar proteins. A differential scanning calorimetric study. J. Agric. Food Chem., 42, 873.

[13] Paredi, M.E. (1994). Ph.D.diss., Fac. Cs Exactas y Naturales. Universidad Nacional de Mar del Plata.

[14] Paredi, M.E., Tomas, M.C., Crupkin, M and Añon, M.C. (1996). Thermal denaturation of muscle proteins from male and female squid (Illex argentinus) at different sexual maturation stages. A differential calorimetric study. J Agric. Food Chem., 44, 3812.

[15] Paredi, M.E., Tomas, M.C., Añon, M.C. and Crupkin, M. (1998).Thermal stability of myofibrillar proteins from smooth and striated muscles of scallop (C. tehuelchus) A differential scanning calorimetric study. J. Agric. Food Chem., 46, 3971.

[16] Paredi, M.E. and Crupkin, M. (2000). Propiedades bioquímicas y funcionales de la actomiosina de músculo aductor de vieira (Zygochlamys patagónica). Almacenamiento a 2-4 ºC. IV Jornadas Nacionales de Ciencias del Mar. Puerto Madryn, Chubut, Argentina.

[17] Samejima, K., Ishioroshi, M. and Yasui, T. (1983) Scanning calorimetric studies on thermal denaturation of myosin and its subfragments. Agric. Biol. Chem., 47, 2373.

[18] Sano, T., Noguchi, S. F., Tsuchiya.,T. and Matsumoto, J. J. (1986). Contribution of paramyosin to marine meat gel characteristics. J. Food Sci., 51, 946.

[19] Stabursvik, E. and Martens, H. (1980). Thermal transitions of the proteins in post rigor muscle tissues as studied by differential scanning calorimetry. J. Sci. Food Agric., 31, 1034.

[20] Wright, D.J. and Wilding, P. (1984) Differential scanning calorimetric study of muscle and its proteins: myosin and its subfragments. J.Sci.Food Agric., 35, 357.

[21] Wright, D.J., Leach, L.B. and Wilding, P. (1977). Differential scanning calorimetric studies of muscle ant its constituent proteins. J.Sci.Food Agric., 28, 557.

Brasil

Brasil

Thermal behavior of myofibrillar proteins from the adductor muscles of scallops: a differential scanning calorimetric study (DSC)

Abstract

Publication Dates

History