Myosin heavy chain isoforms influence myofibrillar ATPase activity under simulated postmortem pH, calcium, and temperature conditions

The pH and Ca(2+) sensitivity of myofibrillar ATPase activity plays an integral role in regulating postmortem muscle ATP utilization and likely paces postmortem glycolysis. The objective of this study was to determine the influence of pH and Ca(2+) concentration on the ATPase activity of myofibrils from red semitendinosus (RST) and white semitendinosus (WST) porcine muscles. Myofibrillar ATPase was measured at 39 °C over a pH range 5-7.5 and a [Ca(2+)] range pCa 4-9 (10(-4)-10(-9)M). At maximum Ca(2+)-dependent activation (pCa 4), RST myofibrils had lower (p<0.0001) ATPase activity than WST myofibrils. This maximum activity of myofibrils from both muscle regions was not influenced from pH 7.5 to 6.5, declined between pH 6.5 and 5.75 (Hill coefficient, n(H)=2.7-3.4; pH at half maximum activity, pH(50)=5.97) and was near zero at pH 5.5. At pH 7, pCa-activity relationships showed that RST required less Ca(2+) for half-maximum activation (higher pCa(50); 6.50) than WST myofibrils (pCa(50)=6.35) but had no difference in n(H). At pH 7, both RST and WST myofibrils had maximum Ca(2+)-dependent, actin-activated ATPase activity at pCa ?6 and Ca(2+)-independent myosin ATPase activity at pCa ?6.75. pCa-activity relationships at different pH levels indicated that pCa(50) decreased with pH from pH 6.5 to 6.125 in both RST and WST myofibrils. At pH <5.75, [Ca(2+)] did not influence ATPase activity in RST or WST myofibrils. These data show that myofibrils with predominantly fast MyHC (WST) have a higher actin-activated myosin ATPase activity than myofibrils with primarily slow MyHC isoforms (RST) at Ca(2+) concentrations and pH values characteristic of postmortem muscle.     

Method of isolation, rate of postmortem metabolism, and myosin heavy chain isoform composition influence ATPase activity of isolated porcine myofibrils

The objective of this study was to determine the influence of myofibril isolation procedures and myosin heavy chain (MyHC) isoform composition on myofibrillar ATPase activity as related to postmortem muscle metabolism. Myofibrils from the red (RST) and white (WST) portions of semitendinosus muscles were isolated using two different methods (A and B) at 3 min and 24 h postmortem in control (NS) and electrically stimulated (ES) pork carcasses. Comparison of the relative MyHC isoform profiles between the two different myofibril isolation methods and myosin extracts from the RST and WST at 3 min showed that method B myofibrils were more similar to the myosin extract than method A. Myofibrillar ATPase activity remained constant or increased (P<0.01) from 3 min to 24 h postmortem in NS carcasses and decreased (P<0.0001) in ES carcasses. From the RST, method A myofibrils had higher (P<0.0001) ATPase activity compared to method B across sampling time and carcass treatment. In the WST, method A myofibrils had lower (P<0.01) activity at 3 min, were not different at 24 h in NS carcasses, but had higher (P<0.05) activity at 24 h in ES carcasses versus method B myofibrils. Compared to method B, isolation method A biased the isoform profile of myofibril samples more towards faster MyHC (2A and 2X) in the RST and towards MyHC 2X in the WST. Results suggest that the ATPase activity and MyHC isoform profile of isolated myofibril samples are influenced by method of myofibril isolation, postmortem sampling time, and the rate of postmortem metabolism. Thus, differences in MyHC isoform profile and method of myofibril isolation must be taken into account to determine accurately the relationship between myofibrillar ATPase activity and rate of postmortem metabolism.     

The effect of proteasome on myofibrillar structures in bovine skeletal muscle

When bovine myofibrils are incubated with the 20S proteasome their structure is rapidly damaged with loss of material, particularly from the Z discs and I bands. After 24 hr of incubation the myofibrils rupture and debris appears. Certain myofibrillar proteins, including nebulin, myosin, actin and tropomyosin, are hydrolysed during the incubation; others are solubilised (α-actinin). The 20S proteasome completely and rapidly hydrolyses purified myofibrillar proteins in an energy-independent manner. This shows that the 20S proteasome probably plays a role in the postmortem transformation of muscle and more generally in the hydrolysis of cellular proteins.(1).     

Effect of frozen storage on the structure and enzymatic activities of myofibrillar proteins of rabbit skeletal muscle

The effect of frozen storage on the biochemical properties of myofibrils, and of their major constituents, actin and myosin, was investigated. Extractability of myofibrillar proteins increased slightly for 3 weeks during frozen storage of muscle, decreasing thereafter. The change in myofibrillar ATPase activity during frozen storage was consistent with that of a reconstituted acto-heavy meromyosin (HMM) complex prepared from frozen stored muscle at the same weight ratio of actin to myosin as in situ. However, myosin ATPase activity showed a different pattern of change when compared with myofibrillar ATPase activity. The maximum velocity of acto-HMM ATPase activity and the apparent dissociation constant of the acto-HMM complex decreased for 1 week during frozen storage, increasing thereafter, indicating that the affinity of actin for myosin was greatest in muscle which had been frozen for 1 week.     

Influence of myosin heavy chain isoform expression and postmortem metabolism on the ATPase activity of muscle fibers

The objective of this study was to determine the effects of postmortem muscle pH and temperature declines on the actomyosin ATPase activity of muscle fibers expressing different MyHC isoforms. Using a quantitative histochemical procedure to determine ATPase activity, the maximum actomyosin ATPase activity was determined on individual fibers classified by MyHC expression. Samples were collected from the red (RST) and white (WST) semitendinosus muscles at 3 min and 24 h postmortem from electrically stimulated (ES) and control (NS) pork carcasses. In samples taken at 3 min postmortem, type I fibers had the lowest ATPase activity staining and type 2X and 2B had the highest activity staining, with type 2A fibers intermediate. Postmortem time and carcass treatment did not influence the ATPase activity staining of type I muscle fibers. ATPase activity staining of 2A fibers was lower (p<0.001) in 24 h samples than in 3 min samples from ES carcasses. In 3 min and NS-24 h samples, RST type 2A fibers had lower (p<0.05) activities than type 2A fibers from the WST. In type 2X fibers, ATPase activity staining decreased (p<0.01) from 3 min to 24 h postmortem in ES carcasses. This decrease was more severe in WST 2X fibers compared to RST 2X fibers. ATPase activity staining in type 2B fibers did not decrease from 3 min to 24 h postmortem in NS carcasses. In ES carcasses, activity staining of 2B fibers decreased (p<0.0001) with time postmortem. The results of the experiment indicate that fibers expressing fast MyHC isoforms have a higher ATPase activity early postmortem than slow muscle fibers but are more prone to inactivation by a rapid pH decline.     

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.     

Comparative action of cathepsins D, B, H, L and of a new lysosomal cysteine proteinase on rabbit myofibrils

Specific action of cathespins D, B, H, L, and of a new high Mr (molecular weight relative to hydrogen) cysteine proteinase, on rabbit muscle myofibrils was studied at pH 5·7 by following changes affecting their ATPase activities, their calcium sensitivity, their effect on the ultrastructure, as well as the electrophoretic pattern of the contractile proteins in the presence of SDS. With regard to the MgCa-enhanced ATPase activity, all these proteinases had a very similar effect. A decrease in this activity was thus noted concomitantly with a shift of the straight-line graph obtained when plotting the present acto-myosin ATPase activity versus KCl concentrations. Cathepsins D, B, L and the high Mr cysteine proteinase induced a decrease in both the calcium ATPase activity of myosin and the calcium sensitivity of myofibrils. On the contrary, the Mg-EGTA-dependent ATpase activity was increased. Except for cathepsin H, extensive hydrolysis of proteins occurred in myofibrils treated with each of the lysosomal proteinases tested. However, different specificities could be distinguished. On the one hand, cathepsins D and B affected mainly myofibrillar protein running above and below actin, respectively, on SDS-polyacrylamide gel electrophoresis; on the other hand, the high Mr cysteine proteinase exhibited broader specificity since most of the proteins were hydrolyzed irrespective of their Mr. Myofibrils incubated with cathepsins B and the high Mr cysteine proteinase showed ultrastructural modifications at the level of Z-line, M-bands and A-bands. Myofibrils treated with cathepsin D and cathepsin H appeared almost unaltered. On the basis of these characteristics, cathepsin H hardly affected myofibrils. These results provide evidence for the involvement of the lysosomal proteinases in the meat ageing process and are discussed in regard to the changes occurring at the myofibrillar level during conversion of muscle into meat.     

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.     

Structural studies of rigor bovine myofibrils using fluorescence microscopy. II. Influence of sarcomere length on the binding of myosin subfragment-1, alpha-actinin and G-actin to rigor myofibrils

Sarcomere length influences the textural quality of meat, yet the molecular basis for the mechanism of post-mortem shortening and the toughness associated with shortened muscle remain obscure. Bovine and rabbit myofibrillar structure was investigated over a range of sarcomere lengths (SL), using the high affinity of the myosin head for actin and of alpha-actinin for the Z-line. Myofibrils were incubated with fluorescent conjugates of myosin subfragment-1 (S1), alpha-actinin and actin. When S1 and alpha-actinin were added together, S1 bound in the I-band and A-band but not at the Z-line, while alpha-actinin bound at the Z-line. The pattern of S1 binding was highly influenced by SL, and could be explained using a model with the ratio of myofibrillar actin to myosin heads in the overlap region of 2:1 and thin filament penetration into opposing half sarcomeres. Double staining with S1 and actin demonstrated that, once the tip of the thin filament reached the bare zone, few intrinsic myosin heads were available for fluorescent actin. The patterns observed for both S1 and actin staining suggest that myofibrillar rigor bonds form even at very short SL. These observations lead to the hypothesis that the toughness associated with short sarcomeres is due to thick-filament interactions and not to the density of rigor bonds in the myofibril. Regulation of S1 binding was investigated by incubating myofibrils with low levels of fluorescent S1 in the presence and absence of calcium; S1 binding was in the overlap region when calcium was absent, but in the I-band when it was present. These results suggest that the thin filament can be activated for muscle shortening by the binding of myosin heads, a mechanism that may contribute to post-mortem muscle shortening.     

Effect of Cathepsin D on Bovine Myofibrils under Different Conditions of pH and Temperature

Purified cathepsin D was incubated with bovine skeletal muscle myofibrils under in virro conditions resembling those found in postmortem muscle. SDS-PAGE analysis of myofibrils treated at pH 5.5 and 37°C and the sedimented, showed degradation of myosin heavy chains and titin. A small amount of actin, tropomyosin, troponins T and I, and myosin light chains also were degraded. The cathepsin D treated myofibrils were not fragmented to any greater extend than untreated myofibrils. Raising the pH and/or lowering the temperature greatly reduced the effectiveness of cathepsin D suggesting that the enzyme does not play a principal role in the tenderization process occurring in muscle postmortem.     

Some observations on protein changes in washed myofibrils of bovine muscle

It was found that the protein and water contents of washed myofibrils obtained from bovine longissimus dorsi muscles vary with the rate of pH change during the first hour post mortem. Neither myosin nor actin is responsible for the variation, which is due to changes in the other myofibrillar components. The amount of remaining myofibrillar proteins (RMP), obtained after the sum of myosin and actin is deducted from the total myofibrillar protein (TMP), shows a minimum at a rate of pH change corresponding to a 1-h pH value of 6·7. Apart from this pH-dependent decrease, a further substantial reduction of the RMP fraction was observed, particularly in myofibrils extracted from electrically stimulated muscles. It is considered that the observed changes result from partial proteolysis taking place in muscle during the early hours post mortem. A possible involvement of connectin as a primary substrate for the action of calcium-activated neutral protease is discussed. On the basis of the observed correlation between Warner-Bratzler peak shear force and TMP, a significant influence of pre-rigor muscle status on meat tenderness is suggested.     

Temperature induced denaturation of myosin: Evidence of structural alterations of myosin subfragment-1

Denaturation of myofibrillar proteins in porcine longissimus thoracis et lumborum muscle was investigated after pre-rigor temperature incubation at 20, 30 and 40 °C. At 24 h myofibrils were isolated and myosin was further cleaved by chymotrypsin. High temperature pre-rigor induced release of myosin S1 (subfragment-1), less (P < 0.05) Ca²⁺-ATPase activity and structural alterations of the region of the myosin molecule that harbors S1. Surface hydrophobicity of myofibrils from the 40 °C group increased (P < 0.001), suggesting a temperature-induced structural rearrangement exposing hydrophobic groups on the surface of myofibrils which in turn may explain the reduced water-holding of PSE meat.     

Identification of myofibrillar substrates for μ-calpain

To identify myofibrillar substrates of μ-calpain under post-mortem conditions, a combination of SDS–PAGE, two-dimensional gel electrophoresis (2DE) and matrix-assisted laser desorption/ionisation time-of-flight mass spectrometry (MALDI-TOF MS) was used. Purified myofibrils were incubated with μ-calpain under post-mortem-simulated conditions for two or four days at 4 °C. The resulting protein changes were analyzed by SDS–PAGE and 2DE. The μ-calpain-mediated protein changes were identified by peptide-mass mapping using MALDI-TOF MS and revealed that desmin, actin, myosin heavy chain, myosin light chain I, troponin T, tropomyosin 1, tropomyosin 4, thioredoxin and CapZ are all degraded in vitro by μ-calpain. The findings that actin and myosin heavy chain are substrates of μ-calpain were rather surprising, as it has previously been reported that these proteins are resistant to μ-calpain degradation. However, both actin and myosin heavy chain are poor substrates compared with desmin.     

IDENTIFICATION OF A MYOFIBRIL-BOUND SERINE PROTEINASE IN THE SKELETAL MUSCLE OF SILVER CARP

Myofibril‐bound serine proteinase (MBSP) in the skeletal muscle of silver carp was characterized. Myosin heavy chain (MHC) degraded markedly when silver carp myofibril was incubated at 55–60C as shown by SDS‐PAGE. Prolonged incubation of myofibrils also caused the degradation of other myofibrillar proteins such as α‐actinin, actin and tropomyosin to some degree. The results suggest the existence of an endogenous myofibril associated proteinase. Serine proteinase inhibitors (Pefabloc SC and Lima bean trypsin inhibitor) greatly suppressed the degradation of myosin heavy chain, while inhibitors for cysteine, metallo, and aspartic proteinases did not show any effect, indicating that the endogeneous proteinase is a myofibril‐bound serine proteinase.     

Muscle protein changes post mortem in relation to pork quality traits

The relationship between post-mortem traits of muscle proteins and water loss traits was investigated using 84 pork loins representing the four quality traits of PSE, RSE (reddishpink, soft, exudative), RFN (reddish-pink, firm, non-exudative) and DFD. Protein solubility measurements (sarcoplasmic, myofibrillar and total) were lower and myosin denaturation (quantified by myofibrillar ATPase activity) was higher for PSE samples compared with samples from the other quality classes. RSE samples were similar to RFN samples in protein solubility and myosin denaturation, although RSE had lower values then DFD samples for protein solubility measurements. RFN samples had lower drip, thaw, cook and total water loss than RSE samples and all water loss traits were lowest for DFD samples and highest for PSE samples. Insoluble phosphorylase was the only characteristic that differentiated among PSE, RSE and RFN samples. SDS-PAGE and Western blots indicated that in PSE and RSE samples, the myofibrillar protein titin was less degraded and nebulin was more degraded compared with RFN and DFD samples. SDS-PAGE of extracted and unextracted myofibrils showed that the reduced myofibrillar solubility of PSE samples was caused by decreased extractability of the myosin heavy chain in these samples. In conclusion, although RSE samples have unacceptably high water loss, muscle protein denaturation was minimal and did not explain the low water-holding capacity.     

EFFECT OF POSTMORTEM CONDITIONS ON CERTAIN CHEMICAL, MORPHOLOGICAL AND ORGANOLEPTIC PROPERTIES OF BOVINE MUSCLE

Paired sides from U.S. Choice grade beef were aged immediately after slaughter at 2 and 16°C. Samples were removed from longissimus and semitendinosus at slaughter and at 1, 3 and 7 days postmortem for ATPase assay, phase microscopy, shear and organoleptic evaluation. Rib steaks from sides aged at 16°C for 1-day postmortem were as tender as steaks from sides aged at 2°C for 7 days postmortem. Flavor development of rib steaks also was more rapid at 16°C than at 2°C. Tenderness of semitendinosus steaks was improved by aging sides at 16°C; the difference in improvement of tenderness of semitendinosus, however, was not as great between 2°nd 16° as it was for rib steaks. Ca⁺⁺, Mg⁺⁺ and EGTA-modified ATPase activity of myofibrils from both muscles increased with postmortem time, with myofibrils from muscles held at 16°C having slightly higher ATPase activity than myofibrils from muscles held at 2° Increased EGTA-modified ATPase activity was indicative of loss of calcium sensitivity of the myofibril. Sarcomeres of myofibrils from longissimus were longer at 1-day postmortem than those from at-death longissimus and they remained essentially unchanged during the remainder of postmortem aging; however, tenderness improved at 16°C for 1 day and at 2°C for 3 days. Also greater fragmentation of myofibrils from longissimus postmortem aged at 16°C for 1 day and at 2°C for 3 days was observed, suggesting that the rate of myofibril fragmentation is an important factor in tenderization.     

Effect of frozen storage on protein denaturation in bovine muscle 1. Myofibrillar ATPase activity and differential scanning calorimetric studies

The effect of frozen storage on myofibrillar ATPase activity and thermal transitions in bovine muscle was investigated. Myofibrillar ATPase activity and total enthalpy of denaturation (ΔH) decreased with time of storage. The rate of decrease was lower at −20°C than at −5°C or −10°C. Differences in behaviour during storage of muscle after fast or slow freezing could be attributed to differences in ice recrystallization. The observed decreases in area of the first peak seen in the thermograms and Ca²⁺-myo-fibrillar ATPase activity show that the myosin head denaturated progressively during storage. The myosin tail also denaturated during storage but the thin filament remained unaltered. Kinetic analysis suggested that the denaturation of the myofibrillar proteins took place through two consecutive first order reactions; an initial rapid reaction followed by a slower one.     

Lysosomal Enzyme Effects on the Postmortem Changes in Tilapia (Tilapia nilotica X T. aurea) Muscle Myofibrils

To investigate the effects of lysosomal proteases on myofibril fragmentation, tilapia (Tilapia nilotica X T. aurea) muscle myofibrils were incubated with isolated lysosomal fraction containing 12 units of cathepsin D/mL (G-II) and pure cathepsin D (12 units/mL G-III) at pH 5.5, 6.0, and 6.5 for 3 days at 4°C. Among samples incubated at pH 5.5, the degree of myofibril fragmentation (DMF) of G-III was highest, while, at pH 6.0 and 6.5, that of G-II was highest. At pH 6.5, the higher DMF of G-III than that of G-I suggested that cathepsin D still had proteolytic activity on myofibrils. Difference in the decrease of protein content between G-III and G-I, and between G-II and G-I indicated that proteolysis caused by cathepsin D was highest at pH 5.5, while that caused by lysosomal enzymes was highest at pH 6.5. This suggested the participation of lysosomal enzymes in the fragmentation of myofibrils.     

Comparative effects of post-mortem storage and low-calcium-requiring neutral proteinase on bovine and rabbit myofibrillar proteins

The effects of post-mortem storage and of a low-calcium-requiring neutral proteinase on the myofibrils of beef Longissimus dorsi and Rectus abdominis muscles and rabbit Longissimus dorsi muscle were studied by measuring the Mg-Ca-enhanced myofibrillar ATPase activity and the changes in banding patterns on electrophoresis in sodium dodecyl sulphate. During ageing, the changes in the ATPase activity and myofibrillar proteins were qualitatively different between rabbit and bovine muscles, whilst differences in intensity were only observed between the two bovine muscles. The most prevalent component appearing upon conditioning had a mol. wt of 27 000 in rabbit muscle and of 30 000 in bovine muscles. In both species, the incubation of myofibrils with the low-calcium-requiring neutral proteinase mimicked the post-mortem changes. This would suggest that this enzyme has a qualitatively different effect on rabbit and bovine myofibrils.     

Thermally Induced Interactions and Gelation of Combined Myofibrillar Protein from White and Red Broiler Muscles

The gelling properties of broiler myofibrillar protein were studied by determining protein-protein interactions during heating. Breast and leg salt-soluble protein (SSP) showed 1–3 transitions in protein-protein interactions within pH 5.5–6.5. The maximum transition temperatures of leg SSP decreased when leg SSP was mixed with breast SSP. The combined breast/leg myofibrils formed stronger gels than leg myofibrils alone at pH ≥ 6.0, and stronger gels than breast myofibrils alone at pH < 6.0. The results suggest that interactions existed between breast and leg myofibrillar proteins, and the transitions in these interactions were useful for predicting gel strength of the combined breast/ leg myofibrils.