Post mortemRelease of Fish White Muscle α-Actinin as a Marker of Disorganisation

α-Actinin release and its degradation from myofibrils Z-line were studied in post mortem white dorsal muscle from bass and sea trout stored at 4°C and 10°C. Using α-actinin specific antibodies, we show that this protein is rapidly released within the first 24 h for the two species, and reaches a plateau within 4 days. Proteolysis take place very rapidly in bass muscle yielding 80 and 40 kDa fragments from α-actinin as major bands of proteolysis. Sea trout muscle is more resistant, and muscle stored at 4°C is not significantly α-actinin degraded even 10 days after death. In the case of sea trout muscle stored at 10°C, an increasing quantity of 80 and 40 kDa fragment can be observed after the third day. These results show that release and proteolysis of α-actinin are time- and temperature-dependent processes that take place at the early stages of fish storage. Furthermore, we observed that proteolysis of α-actinin seems to be dependent on fish species. In both species studied, the early release of α-actinin comes before the degradation of released molecules, and appears as a biphasic process throughout the disorganisation of post mortem muscle in fish cold-stored above 0°C.     

Desmin Degradation in Postmortem Fish Muscle

The degradation of desmin was studied in postmortem white dorsal muscle from sea bass, brown trout, turbot and sardine, stored at 0–4°C. Based on desmin specific antibody tests, results showed that the extent and rate of desmin degradation in postmortem fish muscle varied considerably among species. There was no degradation of desmin during the first 4 days postmortem storage of sea bass and brown trout, whereas 10 to 20% of muscle desmin was degraded during the first 4 days of postmortem storage of turbot. Sardine muscle presented a very complex pattern of desmin degradation products and aggregated desmin fragments detected within the first 24h. Most polypeptides were larger than the nondenatured desmin. Desmin degradation would not be a suitable marker for evaluation of postmortem changes of stored fish.     

Post-mortem Changes in Breast Muscles of Mule Duck

Post-mortem changes in myofibril fragmentation index and degradation of myofibrillar proteins of duck breast muscles at 5°C was investigated. Muscle samples were collected immediately after killing and from the stored carcasses at 5°C for 1, 3, 7, and 14 days post mortem . The results showed that the MFI of the breast muscles increased with time post mortem . SDS-PAGE of myofibrils indicated that the disappearance of troponin-T accompanied concurrently with the appearance of 32–30 kDa components. After 7 days of storage, α-actinin was degraded, and a 98 kDa component appeared. Titin 1 and nebulin also disappeared after post-mortem storage for 3 days.     

Effect of temperature and pH on the post-mortem degradation of myofibrillar proteins

Incubation of bovine muscle at 37°C promoted a more drastic proteolytic change in myofibrillar proteins, as determined from sodium dodecyl sulphate polyacrylamide gels of isolated myofibrils, than incubation at 4°C. Degradation of myosin and troponin-T were the most noticeable changes at 37°C. Loss of α-actinin was observed in the 4°C incubated muscle. Ground bovine muscle incubated at pH 5·4 and 7 revealed that alterations in myosin and troponin-T were the most noticeable changes at ph 5·4 while troponin-T and α-actinin were altered at pH7. More troponin-T degradation occurred at pH 5·4 and 37°C than at pH7 and 4°C (similar to the degradation of myosin), indicating that troponin-T degradation in post-mortem muscle may be an indicator of overall myofibrillar proteolysis and not responsible for post-mortem tenderisation per se. Myosin degradation in the ground samples incubated at pH 5·4 and in whole samples incubated at 37°C was compared with the digestion of myofibrillar myosin by papain. Both pyrophosphate and Guba-Straub extracts of the 37°C and pH 5·4 treated samples confirmed that myosin degradation did occur to a much greater extent at this temperature and pH than at 4°C and pH7, and, in addition, at pH 5·4 frequent cleavage occurred near the papain sensitive site of myosin.     

Conditioning of bovine muscle. III. The α-actinin of bovine muscle

The protein α-actinin has been prepared, pure, from 1-day-old beef and from beef conditioned up to 21 days at +4 °C. The total amount of α-actinin isolated frommyofibrils remained the same, 1.4% of the myofibril, regardless of the period of conditioning. A small reduction was found in the amount of α-actinin, from conditioned muscle, which could be bound to F-actin when compared with α-actinin from fresh muscle, but the difference did not seem sufficient to explain all the changes in the properties of myofibrils occurring during conditioning.     

Degradation of structural proteins and their relationship with the quality of Mandarin fish (Siniperca chuatsi) during post-mortem storage and cooking

This study was carried out to investigate the changes in the microstructure and structural proteins (titin, nebulin, desmin and tropomyosin (TPM)) of mandarin fish muscle as well as the relationship between the structural proteins and the quality characteristics of fish muscle during post-mortem storage and after cooking. During post-mortem storage, titin was degraded initially, accompanied with an increase of the I-band length. Subsequently, the degradation of desmin induced a gradual breakage of the myofibrils. The following degradation of nebulin accelerated the destruction of N₂-lines, which occurred with a slightly fuzzy Z-disc. Finally, TPM began to degrade, and the remaining desmin was also degraded further. Principal component analysis (PCA) and correlation analysis indicated that the changes in the quality characteristics of fish muscle were intimately related to the degradation of structural proteins. Hence, these structural proteins could be the biomarkers to monitor the quality characteristics of fish muscle.     

An immunological method to assess protein degradation in post-mortem muscle

A method for determining proteolysis of any specific protein in muscle is demonstrated. The protocol involves the preparation of a specific antibody which is used in immunoblotting total protein extracts from post-mortem muscle. In the present study an antibody to bovine myosin heavy chain was prepared that reacts with intact myosin heavy chain as well as proteolytic fragments that are generated by proteases. We show that little, if any, myosin heavy chain fragments are generated during prolonged aging of muscle at 4°C. In contrast, storage of muscle at 37°C results in the rapid breakdwon of myosin heavy chain to immunologically detectable peptides. Using a monoclonal antibody to titin, we demonstrate that this protein is degraded at 4°C during the aging period, and that, between 2 and 3 weeks following slaughter, no undergraded titin is detectable. This method is suitable for the analysis of any protein that can be separated by SDS polyacrylamide gel electrophoresis (SDS-PAGE).     

MOLECULAR PROPERTIES OF POST-MORTEM MUSCLE. 9. Effect of Temperature and pH on Tropomyosin-Troponin and Purified α-Actinin from Rabbit Muscle

SUMMARY– A study was done on the effects of in vitro storage of purified α-actinin, troponin, tropomyosin, and the tropomyosin-troponin complex on the activity of these protein fractions in the ATPase and superprecipitation assays. Storage was done at various combinations of temperatures between 0 and 40°C and pH values between 5.7 and 7.0. Even after 40 hr of storage, activities of purified tropomyosin and the tropomyosin-troponin complex were not affected by any combination of temperature and pH included in this study, but activities of purified α-actinin and troponin were almost completely lost after 16 hr at 40°C and pH 5.7. Storage for 40 hr at low pH (5.7) and low temperatures (0°C) did not affect the activity of either α-actinin or troponin, but 40 hr of storage at high temperatures (40°C) and neutral pH caused some loss in activity for both these proteins. This loss of activity caused by 40°C, pH 7.0 storage was much more noticeable in the case of troponin than in the case of α-actinin. Storage periods of 40 hr or longer were required before any loss of α-actinin activity could be detected at pH 7.0 and 40°C. Since most meat animal carcasses are chilled soon after exsanguination and attain muscle temperatures of 25°C or lower before the pH falls below 6.2, it is probable that α-actinin and tropomyosin-troponin activity remain almost unchanged in meat handled through normal market channels. However, myofibrillar tissue in those porcine animals whose musculature undergoes a very rapid post-mortem decline in pH so that values of 5.7 or less are reached while muscle temperatures are still 37°C or higher may lose much of its α-actinin and tropomyosin-troponin activity during the first 24 hr post-mortem.     

Post mortem changes in porcine longissimus muscle incubated with 0.1 M calcium lactate

The effects of calcium lactate incubation at 5 °C on post mortem changes in porcine longissimus muscle were studied. Myofibrils were purified from control (CON) and calcium lactate‐incubated (CL) muscles. Samples were taken at 0, 1, 3, 7 and 14 days post mortem. SDS‐PAGE results showed that the disappearance of titin, nebulin, tropomyosin and troponin‐T and the appearance of a ～30 kDa component were more pronounced in CL samples than in CON samples. Western blots labelled with a monoclonal antibody to desmin also demonstrated that desmin degraded more quickly in CL samples. Our data suggested that calcium lactate incubation might accelerate the post mortem changes in porcine longissimus muscle via activation of calpains. © 2001 Society of Chemical Industry     

Degradation of myofibrils from rabbit, chicken and beef by cathepsin l and lysosomal lysates

The degradation of rabbit, chicken and beef myofibrils by cathepsin L or lysosomal lysates was studied by SDS-polyacrylamide-gel electrophoresis and electron microscopy (EM). Similar degradation patterns were observed for each myofibrillar preparation incubated with cathepsin L, except that myosin heavy chain and tropomyosin of beef were more susceptible than those of rabbit and chicken. Otherwise, troponin T, troponin in I and C-protein were rapidly degraded with slower degradation of titin, nebulin, myosin heavy chain, α-actinin, α-tropomyosin, actin and myosin light chains, LC1 and LC2. However, the component of 30 000 Mr was found to be further degraded to smaller peptides. Degradation at pH 5·5 (approximate post-mortem limit value) was faster than at pH 6·0 but slower than at pH 5·0. A number of new protein bands were identified (130 000, 120 000, 90 000, 85 000, 80 000, 31 000 and 30 000 Mr). The degradation patterns of rabbit myofibrils by rabbit muscle lysosomal lysates were similar to that of myofibrils incubated with purified cathepsin L except for the retention of the 30 000 Mr component and reduced degradation of actin, due presumably to the reduced amount or stability of cathepsin L in the crude enzyme preparations. Electron micrographs revealed that myofibrillar degradation by cathepsin L occurred preferentially at the Z-lines leading to removal of the Z-line proteins and fracturing of the myofibrils at these sites. Catheptic damage was seen to be most rapid in chicken myofibrils and least rapid in beef myofibrils consistent with the more rapid conditioning process in chicken.     

Changes in Muscovy duck breast muscle marinated with ginger extract

The effects of ginger extract (GE) marination on the changes in Muscovy duck breast muscle were evaluated. Pectoralis muscles were excised from the carcasses of male Muscovy ducks and marinated for 14 days in GE at 5 °C. Samples were taken at the end of 0, 1, 3, 7 and 14 days of the marination. The results showed that the pH was higher (p < 0.05) in the GE-marinated samples than in control samples and that TBARS values were lower (p < 0.05) in the GE-marinated samples. The SDS–PAGE and western blot results indicated that titin, myosin heavy chain, desmin and α-actinin degraded more rapidly in the GE-marinated samples than in the control samples and that 32- and 30-kDa troponin-T degradation components were also generated in the GE-marinated samples. Our results suggest that GE marination could not only retard lipid oxidation, but also enhance the proteolysis of Muscovy duck breast muscle.     

Effect of muscle type on the rate of post-mortem proteolysis in pigs

Post-mortem proteolysis was examined in muscle homogenates from porcine m. longissimus dorsi (LD), m. semitendinosus (ST), m. semimembranosus (SM), m. vastus intermedius (VI), and m. soleus (S). During post-mortem storage, desmin and troponin-T degraded faster in LD and SM than in ST, VI and S. ST exhibited the same rate of degradation as VI and S. These differences could not be explained solely by differences in fibre type distribution, indicating that other muscle-specific traits independent of fibre type determine myofibrillar degradation post-mortem. Thus, the rate of post-mortem proteolysis seems to depend more on muscle-to-muscle variations than on fibre type composition.     

Myofibril-Bound Serine Proteinase (MBP) and its Degradation of Myofibrillar Proteins

Proteolysis of a myofibril-bound serine proteinase (MBP) from carp Cyprinus carpio on myofibrillar proteins and their gel formation ability were investigated. MBP readily decomposed myosin heavy chain as indicated by SDS-PAGE. In the preparation of kamaboko, the gel formation ability was diminished by addition of MBP. The optimum degradation temperatures of MBP to myosin heavy chain in myofibril and kamaboko gel were 55°C and 60°C, respectively. The degradation effects of MBP on actin, α-actinin and tropomyosin were studied by the immunoblotting method. Because of its myofibril-bound and myofibrillar protein degradation characteristics, MBP was regarded as the proteinase most probably involved in the modori effect.     

The effect of active caspase-3 on degradation of chicken myofibrillar proteins and structure of myofibrils

The objective of this study was to investigate the potential contribution of caspase-3 to meat postmortem tenderisation by examining the role of caspase-3 in the degradation of myofibrillar proteins and disruption of myofibril structure in vitro. Myofibrillar protein prepared from chicken muscle was incubated with EDTA or EDTA plus caspase-3 at 25 °C for 16 h and used for detecting muscle protein degradation and ultrastructure of myofibril. Results revealed that caspase-3 reproduced the degradation patterns of titin, nebulin and α-actinin during postmortem storage of meat, but caused little proteolysis of desmin and no appearance of 28–30 kDa peptides. Meanwhile, caspase-3 also induced the weakening in the I band adjacent to Z-lines, which occurred during meat postmortem ageing. Therefore, caspase-3 could account only for a part of the myofibrillar protein degradation observed in naturally aged meat and is likely involved in postmortem tenderisation of meat together with other endogenous proteases.     

In vitro proteolysis of myofibrillar and sarcoplasmic proteins of European sea bass (Dicentrarchus Labrax L) by an endogenous m‐calpain

The effects of m‐calpain isolated from the skeletal muscle of sea bass on sarcoplasmic and myofibrillar proteins isolated from the same tissue were examined in vitro. Incubation of sarcoplasmic proteins with m‐calpain resulted in only a slight decrease (0.7 kDa) in the molecular weight (MW) of a 26.5 kDa protein. Degradation of myofibrils, monitored by quantification of TCA‐soluble peptides generated, resulted in the maximum amount of peptides being generated after 1 h of incubation at 25 °C. Noticeable modifications in the SDS‐PAGE profile of digested myofibrils were observed, including partial denaturation of myosin heavy chain and the release of tropomyosin, ～69 and ～27 kDa doublet bands and a few polypeptides of MW lower than 20 kDa in the soluble fraction. Examination of the degradation patterns of myofibrillar proteins using Western blotting showed that α‐actinin was partially degraded, with release of native α‐actinin and its fragments from myofibrils, whereas desmin was highly degraded after 2 h of digestion. © 2002 Society of Chemical Industry     

Stability of Spray-Dried Encapsulated Carrot Carotenes

Encapsulation with various dextrose equivalent (DE) hydrolyzed starches affected stability of α- and β-carotene in spray-dried carrot powders. Degradation of α- and β-carotene during storage of the powders at temperatures ranging from 37 to 65°C followed first-order kinetics and both degraded at the same rate. Hydrolyzed starch of 36.5DE was superior to 4, 15, and 25DE in improving retention of the carotenes. Carotenes encapsulated with 36.5DE hydrolyzed starch had a predicted half-life of 450 days at 21°C compared to 2 days for carrot juice spray dried alone. Increasing the proportion of carrier decreased the carotene degradation rate and similarly decreased surface carotene. Air was critical in carotene stability, but exposure of encapsulated carrot powders to light did not accelerate degradation.     

Cleavage of desmin by cysteine proteases: Calpains and cathepsin B

The intermediate filament protein, desmin, was purified from pork longissimus dorsi and incubated with either μ-calpain, m-calpain or cathepsin B. Proteolysis of desmin was followed using SDS-PAGE and Western blotting. After incubation of desmin with the proteases, cleavage sites on the desmin molecule were identified by N-terminal sequencing of the different proteolytic fragments. Desmin incubated with either m-calpain or μ-calpain was primarily cleaved in the head and tail region leaving the rod domain relatively intact even after prolonged incubation. Incubation with cathepsin B produces a sequential C-terminal degradation pattern characteristic of this dipeptylpeptidase. The substrate primary structure was not found to be essential for regulation of the proteolytic activity of the cysteine peptidases studied. However, the degradation patterns obtained imply that calpains are involved in degradation of desmin early post-mortem, targeting the non-helical region of the desmin molecule and resulting in depolymerisation and initial disorganisation of the intermediate filament structures of the muscle cell.     

极限pH对羊肉宰后成熟过程中肌原纤维蛋白特型的影响

为了研究羊肉宰后成熟过程中极限pH对肌原纤维蛋白特型即肌联蛋白、伴肌动蛋白、肌间线蛋白和肌钙蛋白-T降解及肌原纤维小片化指数的影响。本文选取50只羊的右侧背最长肌,贮存于4 ℃条件下,在宰后时间点分别为1 h、1、2、3、5 d和7 d时,测定其pH。按照宰后2 d的pH将肉样分成三组:高极限pH组(5.72±0.03),中极限pH组(5.54±0.01)和低极限pH组(5.40±0.02)。在每个宰后时间点,测定肌联蛋白、伴肌动蛋白、肌间线蛋白、肌钙蛋白-T降解程度和肌原纤维小片化指数(MFI)。结果表明:肌联蛋白在高极限pH组中宰后1 d开始降解;在宰后1 d时,高极限pH组肌间线蛋白相对灰度值显著低于中极限pH组和低极限pH组(p<0.05);肌钙蛋白-T在高极限pH组中,宰后1 d已出现降解条带。而伴肌动蛋白在中极限pH组中降解较快,在宰后1 d开始降解。另外在宰后1、2、3、5、7 d时,高极限pH组和中极限pH组的肌原纤维小片化指数显著高于低极限pH组的肌原纤维小片化指数(p<0.05)。极限pH通过影响这些肌原纤维蛋白降解来促进宰后肌肉成熟过程并且肌联蛋白、肌间线蛋白和肌钙蛋白-T的降解,加快了宰后前期嫩化过程。这为揭示宰后肉嫩度形成机理提供理论基础。     

Proteolytic degradation of myofibrillar components by carp cathepsin L

Carp cathepsin L, which is the best candidate to produce textural change in the arai-treated carp fillet, exhibited maximum hydrolytic activity for Z-Phe-Arg-MCA and soluble casein at pH 5·0–5·5. The proteolytic action of the enzyme was evaluated by complete degradation of various carp myofibrils at pH 5·0 over 30 min and by potent degradation of the same proteins at pH 5·5–6·0 over 20 h. All myofibrillar components were partially degraded by the enzyme at pH 6·5–7·0, but varying amounts of them remained undegraded after 20 h. These findings indicate that carp cathepsin L degrades not only carp myofibrillar components but also their resultant products between pH 5·0 and 7·0 and that it markedly acts on myosin heavy chain, α-actinin and troponin-T and -I. Carp cathepsin L likely contributes to postmortem muscle tenderisation of carp fillet over an extensive pH range during storage. © 1998 SCI.     

The Effect of µ/m‐Calpain on Protein Degradation of Chicken Breast Meat

This study was designed to determine the effects of µ/m‐calpain on the degradation of cytoskeletal proteins in pectoralis major. Four chickens were slaughtered and the breasts were removed and stored for 12 hr at 4 °C. Each sample was divided into three groups and respectively immersed in control reagent, calpain inhibitor, and caspase inhibitor at 4 °C. The samples were used to evaluate troponin‐T and desmin degradation, calpain activity, and myofibril ultrastructure at 12 hr, day 1, day 3, and day 7. Casein zymography revealed that µ‐calpain could not be detected in all samples after 12 hr postmortem. The calpain inhibitor inhibited µ/m‐calpain activity and reduced troponin‐T and desmin degradation during 7 day postmortem. The caspase inhibitor inhibited µ/m‐calpain activity and, troponin‐T and desmin degradation before day 3 postmortem. The findings suggest that, µ/m‐calpain had an effect on cytoskeletal protein degradation after 12 hr postmortem.