• Korean Journal of Food Science and Technology
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• v.26 no.2
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• pp.110-116
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• 1994

In order to study the effects of enzyme modification on the physico-chemical and functional properties of myofibrillar protein prepared from the frozen sardine, Sardinops melanostica, the protein was hydrolyzed with pepsin under the enzyme-substrate ratio 1:100 at $37^{\circ}C$ and pH 1.65 for 1, 4, 8, 12, and 24 hr, respectively. The properties of pepsin-modified sardine myofibriliar protein were determined. The extents of proteolysis with pepsin as a fuction of time was showed a typical enzyme hydorlysis curve with an initial region of 4 hour period followed by plateau region. The SDS-acrylamide slab gel electrophoresis patterns of pepsin-modified proteins showed mainly disappearances of minor protein bands, but no changes of main protein bands. The gel filtration patterns through Sephadex G-75 of sardine myofibrillar protein showed two big peaks and three small peaks. All the small peaks were disappearanced by proteolysis with pepsin in one hour. and during the period of proteolysis the fast big peak became gradually smaller and the late big peak eluted more slowly. By proteolysis, the emulsifying activity and emulsifying capacity of sardine myofibrillar protein were all decreased. The effects of pepsin-modification on emulsifying capacity were greater than those on emulsifying activity of protein. The aeration capacity of the protein was increased about 1.9 folds and the foam stability decreased to 0.6 folds of control by pepsin-modification. The pepsin-modified sardine myofibrillar proteins showed about 0.6 folds of heat coagulation and 1.4 folds of viscosity of control. The pH dependence of solubilities of sardine myofibrillar protein showed two isoelectric areas of pH 5 and 9. The pepsin-modified protein showed more clear pH dependences at the early stage but not at the late stage of proteolysis.

• Korean Journal of Food Science and Technology
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• v.25 no.1
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• pp.39-45
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• 1993

The effects of enzymatic modification with pepsin and actinidin was studied on molecular weight distributions and functional properties of hydrolysates from soy protein isolate (SPI) differing in degree of hydrolysis. The hydrolyzed SPI by pepsin showed 41.5% degree of hydrolysis after 5 min, and maximum hydrolysis was obtained after 2 hours. Actinidin hydrolyzed SPI 26.71% degree after 1 hour. On SDS-PAGE, native SPI showed 9 distinguishable bands on SDS-PAGE gel. Pepsin treated SPI showed one broad band in the lower part of gel. This band was shifted further to the bottom of the gel and became faint as hydrolysis time increased. While actinidin treated SPI showed different SDS-PAGE pattern from pepsin. However PAGE patterns were similar with pepsin and actinidin treated groups. With pepsin treatment, solubility of SPI distinctively increased around isoelectric point(pI). Emulsifying activity (EA) and emulsifying stability (ES) showed marked increase over pH range of $3.0{\sim}8.0$. 5 min modified group had most excellent foam expansion (FE). Foam stability (FS) was increased as pepsin treatment time increased at pI. With actinidin treatment, solubility was increased. 60 min modified SPI had the most effective EA at pH 4.5. However ES was not effected by actinidin treatment. 5 min modified group was most effect in FE. FS was higher at alkaline pH.

• Applied Biological Chemistry
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• v.30 no.3
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• pp.234-241
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• 1987

Conditions necessary for optimal plastein productivity from sardine protein hydrolysate using papain and pepsin were established. Sardine protein concentrate was hydrolyzed with pepsin yielding an approximate degree of hydrolysis of 77.2%. Enzyme induced plastein was optimized at: pH 6 for papain and pH 4 for pepsin; substrate concentrate, 50%(w/v) for papain and 40%(w/v) for pepsin; time of incubation, 24hr; enzyme/substrate ratio, 1 : 100(w/w). Plastein yields of 49.5% and 45.3% were found for papain and pepsin, respectively, when 10% trichloroacetic acid (TCA) was used as the precipitating agent. However, when plastein was precipitated by 50% ethanol, the yield was found to be 43.6% and 41.0% for papain and pepsin, respectively. Ethanol-precipitated plastein did not contain lipid and contained approximately 1.3% ash and 91.0% protein. In comparison, the TCA-precipitated plastein contained 74.2% protein, 0.5% lipid and 15.3% ash.

• Journal of the Korean Society of Food Science and Nutrition
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• v.21 no.6
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• pp.706-711
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• 1992

Silkworm larvae protein concentrate was partially hydrolyzed at $50^{\circ}C$ by papain at pH 2.0 and pepsin at pH 7.0 for 10min and 60min and the effect of enzymatic modification on the functional properties of silkworm larvae protein concentrate was examined. The degrees of hydrolysis measured by TCA-soluble nitrogen content were 10.2% and 19.2% when hydrolyzed by pepsin for 10min and 60min. The nitrogen solubility in water and 0.03M $CaCl_2$ was increased with increasing the degree of hydrolysis, and bulk density, water and oil absorption were also enhanced by enzymatic hydrolysis when compared with the control.

• Korean Journal of Food Science and Technology
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• v.27 no.5
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• pp.708-715
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• 1995

Effect of enzymatic modification with pepsin, papain and trypsin was studied on functional properties of isolated sesame meal protein hydrolysates. Solubility of protein hydrolysates distinctively increased from 2% to $53{\sim}94%$ at pH 4. Emulsifying properties showed marked increase 6 fold and 4.5 fold at degree of 10%, 20% hydrolysis by trypsin and degree of 10% hydrolysis by papain. The emulsion stability of the protein was unstable by heat treatment for 30 min. at $80^{\circ}C$. Foaming properties were also enhanced by enzymatic hydrolysis except at degree of 30% hydrolysis. Bulk density and water absorption of protein with trypsin and papain decreased about 0.1 g/ml and $0.3{\sim}0.7\;ml/g$, but oil absorption was increased about 1 ml/g.