Kunihiko Konno

Enzymatic hydrolysis of recovered protein from frozen small croaker and functional properties of its hydrolysates.

Fish protein isolate were recovered from frozen small croaker using pH shift. The partial enzymatic hydrolysates were fractionated as soluble and insoluble parts. They were dried using the drum dryer and their functional properties were examined. The total nitrogen content of the enzymatic hydrolysates ranged from 12.9% to 13.7%. The degree of hydrolysis of precipitates was 18.2% and 12.2% for croaker hydrolysates treated with Protamex 1.5 MG (Bacilllus protease complex) and Flavourzyme 500 MG (endoproteases and exoproteases, Aspergillus oryzae), respectively. The TCA supernatant, after centrifugation of hydrolysates, contained numerous peptides ranging from 100 to 4000 daltons. The solubility of the supernatants was higher than that of the precipitates at 0% to 3% NaCl and pH 2 to 10. The precipitate of Flavourzyme- and Protamex-treated hydrolysates showed a high emulsion activity index value compared to egg white and bovine plasma protein. In addition, the highest emulsion stability was observed for Protamex-treated precipitate hydrolysates. Emulsion stability of Protamex-treated precipitate hydrolysates was comparable to those of protein additives (egg white, bovine plasma protein, and soy protein concentrate). Water and fat binding capacity of precipitates were higher than those of supernatant. The results indicate that precipitate hydrolysate from undersized croaker can be used in processed muscle foods as a functional and nutritional ingredient.

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.

Proteolysis of noncollagenous proteins in sea cucumber, Stichopus japonicus, body wall: characterisation and the effects of cysteine protease inhibitors.

Proteolysis of noncollagenous proteins in sea cucumber, Stichopus Japonicus, body wall (sjBW) was investigated. The proteins removed from sjBW by SDS and urea extraction were mainly noncollagenous proteins with molecular weights about 200kDa (Band I) and 44kDa (Band II), respectively. Band I and Band II were identified as major yolk protein (MYP) and actin, respectively, from holothurian species by liquid chromatography-mass spectrometry (LC-MS/MS) with significant scores. Based on TCA-soluble oligopeptide assay, the optimum proteolysis condition of noncollagenous proteins was at 46.3°C and pH 6.1, by response surface methodology. The proteolysis of MYP, and actin, was partially inhibited by cysteine protease inhibitors, including Trans-epoxysuccinyl-l-leucyl-amido (4-guanidino) butane (E-64), iodoacetic acid, antipain and whey protein concentrate. These results suggest that cysteine proteases are partially involved in the proteolysis of noncollagenous proteins in body wall of sea cucumber, S. japonicus.

Thick filaments of fish myosin and its actin-activated Mg-ATPase activity☆

1. Tilapia (Tilapia nilotica) myosin forms short, mini-filaments, and are easily disassembled upon addition of ATP showing no saturated activation in its actin-activated Mg-ATPase activity. 2. The presence of 5-10 mM MgCl2 allows tilapia myosin to form native thick-filaments and are resistant to ATP. 3. The rod portion of Tilapia myosin molecule is responsible for its characteristic filament forming ability. 4. The similar filament forming ability as Tilapia myosin was suggested for other fish myosins.

Structural stability of fish myosin subfragment-1

1. Tryptic cleavage of fish myosin subfragment-1 (S-1) revealed its similar substructure of heavy chain to that of rabbit S-1. 2. The structural stability of fish S-1 was studied by thermal denaturation method, and a rapid polymerization of inactivated fish S-1, detected by turbidity increase, was characteristic. 3. The light-chain release and tryptic susceptibility increase upon heating were significant with fish S-1.

Comparative study on thermal denaturation modes of myosin in walleye pollack and carp myofibrils as affected by salt concentration

The effect of salt concentration on the thermal denaturation profile of myosin in walleye pollack and carp myofibrils was compared by studying the subfragment-1 (S-1) and rod denaturation rates upon heating. Species-specific denaturation mode observed at 0.1 M KCl was no longer detected when samples were heated above 0.5 M KCl, where S-1 and rod denaturation rates were identical to each other. As the heating of the chymotryptic digest of myofibril formed practically no rod aggregates, S-1 de naturation in a form of myosin was the rate limiting step for rod aggregate formation. As the aggregate formation by rod was remarkably suppressed by lowering the temperature, the free movement of myosin tail upon heating was suggested to play an important role in the rod aggregate formation in a high salt medium.

Preparation of heavy meromyosin from the autolyzed squid mantle muscle homogenate

Incubation of squid mantle muscle homogenate caused a selective cleavage of myosin into heavy meromyosin (HMM) and light meromyosin (LMM). HMM was isolated from the incubated homogenate by using ammonium sulfate fractionation. The purified HMM retained two types of light chain components. Its Mg2+-ATPase activity with or without F-actin showed a Ca=-sensitivity. HMM was cleaved into subfragment-1 and subfragment-2 upon chymotryptic digestion with or without Ca2+, possessing different light chain composition. Two types of light chain component were kept intact when digested in the presence of Ca2+, Ca2+ stabilized HMM especially in a bound form to F-actin.

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.

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).

Comparative aspect of thermal stability of squid myofibrils

Abstract 1. 1. Thermal stability of myofibrils (Mf) prepared from eight species of squid were compared by measuring a loss of Ca-ATPase activity. The most stable and unstable Mf tested were from cuttlefish and shortfin squid, respectively. 2. 2. Addition of Ca 2+ stabilized all Mf tested about 100-fold, and raising KC1 concentration from 0.1 M to 0.7 M increased Mf inactivation more than 100-fold.