蓝园鲹深度水解过程中蛋白质降解研究

利用风味蛋白酶深度酶解蓝园鲹蛋白，通过比较酶解液的水解度曲线和蛋白质利用率曲线之间的差异、对TCA不溶性氮的变化趋势以及不同酶解时间的凝胶过滤图谱进行分析，探讨了深度酶解过程中蛋白质的降解。酶解6h后大部分蛋白质在酶的作用下降解为水溶性多肽，蛋白质利用率达到83。3％；6h以后蛋白质利用率增长速度降低，这可能是由于可被降解的底物含量降低。此后。风味蛋白酶以水溶性多肽为底物将其进一步降解为小分子肽和氨基酸；21h时水解度达到59．7％。21h以后水解度增长速度降低．这可能是由于亮氨酸氨肽酶难于分解氨基末端上带有甘氨酸和酸性氨基酸的肽。21h以后酶解的主要底物分子量范围在6214到10700的多肽。     

黑豆蛋白肽果汁复合饮料的研制

黑豆是种皮为黑色的大豆，其蛋白质含量高达50%，是极具开发潜力的植物蛋白资源，但黑豆蛋白质分子高度压缩折叠、不易消化，使其加工利用受到了限制。该试验采用2709碱性蛋白酶对黑豆蛋白进行有控制的水解，制备酸溶性好、易消化吸收的黑豆蛋白肽，经水解度与酸溶性蛋白肽得率测定，确定了酶解工艺条件：底物浓度为每100 mL黑豆浆含3.75 g蛋白质，酶-底物比为8 000 u/g，pH值9.0，温度50℃，酶解时间2.0 h，水解度为10%，酸溶性蛋白肽得率达85%。2709蛋白酶对黑豆蛋白具有较好的水解效果，1 kg黑豆经磨浆、酶解与离心去渣脱苦制得20 L黑豆蛋白肽混合液，将其与天然澄清苹果汁按80∶20(V/V)混合调配制备黑豆蛋白肽果汁复合饮料，产品色泽棕红清亮，具天然果汁与黑豆清香风味，蛋白质与肽类物质含量(m/V)≥1.5%，酸度(以柠檬酸计) ≥0.4 g/100 mL。     

大米肽的酶法制备工艺及其特性的研究

该文利用蛋白酶水解大米蛋白制备得到大米肽。比较碱性蛋白酶、中性蛋白酶、复合蛋白酶和风味酶水解大米蛋白的进程曲线,结果显示碱性蛋白酶的水解效果最好,其较佳作用条件为：底物浓度10%、pH值9.0、温度45℃、酶与底物比48 AU/kg、时间150 min。在此条件下,大米肽的得率为46.8%,纯度为71.3%。大米肽具有溶解性较好和黏度较低的特性,可以在食品中广泛应用。     

酶解法制备豆粕水解肽工艺优化

为制备苦味低且生物活性高的豆粕水解肽,本试验在综合考虑水解酶酶切位点后选取7种酶组合对低温豆粕进行水解,以蛋白质转化率、水解度、分子量分布及智能感官评价等作为水解肽的评价指标,比较不同酶组合的作用效果。结果表明,优化得到豆粕水解肽的最佳酶法制备工艺条件:复合酶的最佳组合为碱性蛋白酶+中性蛋白酶+脱苦蛋白酶,酶解pH值依次为8.5、7.5、7.5,反应温度保持55℃,反应时间分别为3、2、2 h,经最佳酶组合制得的水解肽水解度为16%,分子量≤1 000 Da的水解肽可达89.8%,制备的水解肽理化性质及口感更优。本研究结果为豆粕资源开发及功能性肽产品的应用奠定了理论基础。     

复合酶法制备鱿鱼皮胶原蛋白抗冻肽的工艺研究

为了获得具有较高活性的抗冻肽,提高水产加工副产物的综合利用率,本试验以水解度和过氧化氢酶低温保护活性为指标,优化鱿鱼皮胶原蛋白酶解工艺,并对水解产物进行分离纯化及结构鉴定。结果表明,最佳酶解条件为：当底物浓度为4%、加酶量为4 000 U·g^-1时,先由碱性蛋白酶于pH值8、50℃条件下酶解2 h;灭酶后由木瓜蛋白酶于pH值6、45℃条件下酶解3 h。在此条件下所得酶解产物分子量主要在1 000～5 000 Da之间,经G-25凝胶柱分离后得到具有较高抗冻活性的F₂组分,其主要成分的氨基酸序列可能为Gly-Pro-Try-Pro-Ala-Ala-Asn-Ser-Pro-Glu或Glu-Pro-Ser-Asn-Ala-Ala-Pro-Try-Pro-Gly。本研究为鱿鱼皮的精深加工和新型抗冻剂的开发提供了一定的理论依据。     

大豆蛋白限制性酶解模式与产品胶凝性的相关性

为了改善大豆蛋白的胶凝性,对大豆浓缩蛋白、大豆分离蛋白进行限制性酶解处理,并考察相应产品的蛋白酶酶解模式与胶凝性变化的相关性。该研究以蛋白质的水解度为指标,通过中性蛋白酶、胰蛋白酶的酶解作用,水解大豆浓缩蛋白、大豆分离蛋白至蛋白质水解度(DH)为1%、2%,考察酶性质、蛋白质的DH对产品胶凝性影响,并利用SDS-凝胶电泳进行确认。结果表明:大豆浓缩蛋白经中性蛋白酶、胰蛋白酶的酶解后,产品胶凝性均显著下降;大豆分离蛋白经中性蛋白酶的酶解后,产品胶凝性在DH为1%时增加,但在DH为2%时下降;大豆分离蛋白经胰蛋白酶酶解后,胶凝性显著改善。SDS-凝胶电泳确认,蛋白质的酶水解模式和水解度不同是导致产品胶凝性产生不同变化的原因。     

红娘鱼降血压肽的酶解制备工艺优化及酶解产物的抗氧化活性研究

为有效利用红娘鱼制备降血压肽,以红娘鱼鱼糜为原料提取蛋白,并对其进行酶解制备降血压肽。以血管紧张素转换酶ACE抑制率和水解度为指标,通过响应面分析法对酶解红娘鱼鱼糜蛋白制备降血压肽的工艺条件进行优化,并对最优条件下制备的酶解产物进行分子量和抗氧化活性测定。结果表明,碱性蛋白酶是制备降血压肽的最适蛋白酶,响应面法优化制备降血压肽的最佳酶解条件为pH值9、酶与底物的比值(酶底比)1.4%、温度54℃、时间2 h,此条件下酶解制得的降血压多肽ACE抑制率理论值为88%,实际值为89.3%;经高效液相色谱(HPLC)分析可得酶解产物相对分子量<2 000 Da。通过测定酶解产物样品的1,1-二苯基-2-三硝基苯肼(DPPH)自由基清除率、羟自由基(·OH)清除率及还原力判定其体外抗氧化活性,结果表明酶解产物具有较强抗氧化活性。本研究结果为红娘鱼的高值化利用提供了数据支持和理论基础。     

南瓜籽粕酶法制备血管紧张素转化酶抑制肽工艺优化

用中性蛋白酶水解南瓜籽粕,制备血管紧张素转换酶（angiotensin-converting enzyme,ACE）抑制肽,是南瓜籽粕蛋白深度开发的途径之一。为了探寻南瓜籽粕酶法制备ACE抑制肽的最佳工艺,该文以ACE抑制率为响应值,用响应面分析法研究酶浓度、底物质量浓度和水解时间等因素对酶解产物的ACE抑制活性的影响,优化制备工艺。结果表明,各因素对制备ACE抑制肽的活性具有极显著影响（P<0.001）。获得中性蛋白酶水解南瓜籽粕制备ACE抑制肽的最佳工艺条件为：酶体积分数为4.8%、底物质量浓度为4.0g/100 mL、水解时间为320 min。在此条件下,南瓜籽粕蛋白酶解产物对ACE的理论抑制率最高可达80.0％,验证值为80.56％±0.23%,预测模型可靠性高,可应用于南瓜籽粕ACE抑制肽的酶法制备。通过优化,提高了南瓜籽粕ACE抑制肽的活性。     

丝胶蛋白抗氧化肽的酶法制备及功能评价

为进一步开发利用废蚕丝,充分挖掘丝胶蛋白的可利用程度,该文研究了6种蛋白酶水解制备丝胶肽及产品的抗氧化活性。筛选出Alcalase碱性蛋白酶为制备丝胶抗氧化肽的理想蛋白酶,并以ABTS体系评价了丝胶肽的抗氧化活性。通过单因素试验研究了反应时间、底物浓度、反应温度、pH值、酶底物比对酶水解制备丝胶肽的影响;并通过回归正交旋转试验设计对水解条件进行优化,建立各因素与水解度和抗氧化活性的数学模型,确定Alcalase酶水解丝胶蛋白的最佳水解条件为:反应时间240min,底物浓度2%,反应温度55℃,pH8.5,酶底物比2.375%。最佳水解条件下水解度为33.35%,ABTS清除活性为43.19%。该研究为开发丝胶抗氧化肽功能产品提供了技术依据。     

马面鱼皮胶原抗氧化肽的分离制备及稳定性研究

为促进对马面鱼皮资源的综合利用,开发高附加值产品,本试验以DPPH自由基清除率和水解度(DH)为评价指标,探讨马面鱼皮胶原蛋白的最佳酶解工艺,并采用超滤和凝胶柱层析法分离制备抗氧化肽,通过超高效液相色谱-质谱联用(UPLC-MS)法对其进行结构解析。此外,还探讨了pH值、温度及体外模拟消化对多肽抗氧化活性的影响。结果表明,利用双酶分步酶解法可制备高活性抗氧化多肽,即在底物浓度3%,加酶量3 600 U·g^-1以及温度50℃的条件下先用Proteasea A ‘Amano’2G酶解3 h,再用酸性蛋白酶酶解2 h,清除DPPH自由基的IC₅₀值为13.03 mg·mL ^-1。经超滤及柱层析分离后,可得到抗氧化活性较高的A₁组分,其清除DPPH自由基的 IC₅₀值为1.80 mg·mL^-1。稳定性研究结果表明,所制备的胶原蛋白抗氧化肽热稳定性好,在偏酸性条件下能保持较高的活性,经体外模拟胃肠消化后仍能保持较高的抗氧化活性。根据UPLC-MS分析推测A₁的氨基酸序列可能为Gly-Glu-Gly-Ala-Cys-Asn或Asn-Glu-Gly-Ala-Cys-Gly。本研究结果为马面鱼皮的高值化利用及高活性抗氧化肽的筛选提供了一定的理论依据。     

汽爆处理对鳙鱼骨酶解特性的影响

为研究汽爆预处理对鱼骨蛋白酶解特性的影响,以鳙鱼骨为研究对象,采用Alcalase酶解鳙鱼鱼骨,研究不同保压时间、汽爆压力对鳙鱼骨的水解度、蛋白质回收率、三氯乙酸(TCA)可溶性氮得率的影响。结果表明,汽爆预处理能显著提高鳙鱼骨蛋白的溶出率。0.6 MPa、2.0 min汽爆预处理鱼骨经Alcalase酶解3.0 h后,酶解产物的水解度为8.69%,蛋白质回收率为32.69%,TCA可溶性氮得率为28.79%,均显著高于未处理组;酶解产物相对分子质量主要分布在1 000 Da以下,高达93%。本研究结果为鱼骨资源利用提供了一定的技术支持。     

Hydrophobicity,Solubility, and Emulsifying Properties of Enzyme-Modified Rice Endosperm Protein

Rice endosperm protein was modified to enhance solubility and emulsifying properties by controlled enzymatic hydrolysis. The optimum degree of hydrolysis (DH) was determined for acid, neutral, and alkaline type proteases. Solubility and emulsifying properties of the hydrolysates were compared and correlated with DH and surface hydrophobicity. DH was positively associated with solubility of resulting protein hydrolysate regardless of the hydrolyzing enzyme, but enzyme specificity and DH interactively determined the emulsifying properties of the protein hydrolysate. The optimum DH was 6–10% for good emulsifying properties of rice protein, depending on enzyme specificity. High hydrophobic and sulfhydryl disulfide (SH-SS) interactions contributed to protein insolubility even at high DH. The exposure of buried hydrophobic regions of protein that accompanied high-temperature enzyme inactivation promoted aggregation and cross-linking of partially hydrolyzed proteins, thus decreasing the solubility and emulsifying properties of the resulting hydrolysate. Due to the highly insoluble nature of rice protein, surface hydrophobicity was not a reliable indicator for predicting protein solubility and emulsifying properties. Solubility and molecular flexibility are the essential factors in achieving good emulsifying properties of rice endosperm protein isolates.     

Effect of Hydrolyzing Enzymes on Wheat Bran Cell Wall Integrity and Protein Solubility

Wheat bran contains good quality protein, but given its location inside aleurone cells, this protein has restricted digestibility. The aim of this work was to liberate and solubilize wheat bran proteins via cell wall degradation by using carbohydrate‐hydrolyzing and proteolytic enzymes without causing extensive protein hydrolysis. Bran incubated with water (without added enzymes) for 16 h increased the solubilized organic nitrogen content from 14.0 to 42.8%. Enzymes with solely carbohydrate‐hydrolyzing activity increased the water‐soluble pentosan and reducing sugar contents but did not significantly increase protein solubilization or protein release from the aleurone cells. Enzymes with proteolytic activity significantly increased the solubilization of protein to 58.2% already at 4 h. Significant protein hydrolysis was detected with a high dosage of protease. However, based on light microscopy, the enzymatic treatment mainly modified the proteins in the subaleurone layer, and it was less effective on proteins inside the aleurone cells. With optimized protease treatment (3 h, 35°C, and 550 nkat/g), effective protein solubilization (>48%) without extensive protein hydrolysis (free amino nitrogen content <45 mg/L) was achieved. In conclusion, intensive solubilization of proteins in the subaleurone layer of wheat bran is possible by using exogenous enzymes with proteolytic activities.     

琥珀酰化和蛋白酶改性对小麦面筋蛋白功能性质的影响

对小麦面筋蛋白进行琥珀酰化和蛋白酶复合改性以提高其溶解性及其他特性。对复合改性面筋蛋白与原面筋蛋白、琥珀酰化面筋蛋白、碱性蛋白酶改性面筋蛋白进行了比较。结果表明:在pH 3~11、水解度4%~12%的范围内,复合改性面筋蛋白的溶解度亦随着水解度的增大而增大,比原面筋蛋白、酰化面筋蛋白、中性蛋白酶和碱性蛋白酶的改性产物都高。起泡性和起泡稳定性则先增加后降低,在水解度4%时具有较佳值,但在各水解度下较单一改性的面筋蛋白产物都要低。添加复合改性面筋蛋白面团黏弹性和面包口感较好,内部结构均匀、细腻。     

Enzymatic hydrolysis of brewers' spent grain proteins and technofunctional properties of the resulting hydrolysates

Brewers' spent grain (BSG) is the insoluble residue of barley malt resulting from the manufacture of wort. Although it is the main byproduct of the brewing industry, it has received little attention as a marketable commodity and is mainly used as animal feed. Our work focuses on one of the main constituents of BSG, i.e., the proteins. The lack of solubility of BSG proteins is one of the limitations for their more extensive use in food processing. We therefore aimed to generate BSG protein hydrolysates with improved technofunctional properties. BSG protein concentrate (BPC) was prepared by alkaline extraction of BSG and subsequent acid precipitation. BPC was enzymatically hydrolyzed in a pH-stat setup by several commercially available proteases (Alcalase, Flavourzyme, and Pepsin) for different times and/or with different enzyme concentrations in order to obtain hydrolysates with different degrees of hydrolysis (DH). Physicochemical properties, such as molecular weight (MW) distribution and hydrophobicity, as well as technofunctional properties, such as solubility, color, and emulsifying and foaming properties, were determined. Enzymatic hydrolysis of BPC improved emulsion and/or foam-forming properties. However, for the hydrolysates prepared with Alcalase and Pepsin, an increasing DH generally decreased emulsifying and foam-forming capacities. Moreover, the type of enzyme impacted the resulting technofunctional properties. Hydrolysates prepared with Flavourzyme showed good technofunctional properties, independent of the DH. Physicochemical characterization of the hydrolysates indicated the importance of protein fragments with relatively high MW (exceeding 14.5 k) and high surface hydrophobicity for favorable technofunctional properties.     

Heat-induced destabilization of oil-in-water emulsions formed from hydrolyzed whey protein.

The emulsifying ability, heat stability, and coalescence stability of oil-in-water emulsions prepared with whey protein of varied degrees of hydrolysis (DH), and at varied protein contents, was studied. Whey protein hydrolysates (WPH) with a DH of 4% and 10% had poorer emulsifying ability than non-hydrolyzed whey protein concentrate (WPC), but were more heat stable. Increasing DH between 10 and 27% improved emulsifying ability and further improved the heat stability of the emulsion droplets. Increasing DH from 27 to 35% led to a big decrease in both emulsifying ability and heat stability. The quiescent coalescence stability of WPH emulsions was relatively good up to a DH of 27%. Above DH 27% emulsions become highly unstable. It appears that two mechanisms of instability are at work here. At low DH heat-induced denaturation and aggregation occur. In the DH range of 4-20% heat stability increases as protein globular structure is disrupted. At a DH greater than 27% we see a change from a hydrolysis-induced increase in heat-stability to coalescence instability, with a resultant large increase in emulsion breakdown during heating.     

酶解制备鱼鳞蛋白降血压肽的工艺优化

为有效利用鱼鳞制备降血压肽,以罗非鱼鱼鳞为原料,在121℃条件下进行热预处理15 min后,运用响应面分析法优化酶解制备鱼鳞蛋白ACE抑制肽的工艺条件。结果表明,以水解度和ACE抑制率为评价指标,筛选出碱性蛋白酶为最优酶。在单因素试验的基础上,根据Box-Behnken中心组合试验设计原理,最终确立最优的酶解工艺参数为:酶解时间2 h、酶解温度56.3℃、pH值8.0,酶底比1.1%,此条件下ACE抑制率理论值为87.95%,实际值为88.26%。最优条件下制得的酶解产物相对分子质量集中在300～3 000 Da之间,水解效果较好。本研究结果对酶解法制备鱼鳞蛋白降血压活性肽具有一定的实践参考价值。     

Physicochemical and flavor characteristics of flavoring agent from mungbean protein hydrolyzed by bromelain

Enzymatic bromelain mungbean meal protein hydrolysate (eb-MPH) was produced from mungbean meal protein isolate (MPI). Enzymatic bromelain, with a known protease activity of 98,652 (unit/g), was used at concentrations of 0, 2, 6, 10, 14 and 18% (w/w) and with hydrolysis times of 0.5, 3, 6, 12, and 24 h. The pH and temperature were controlled at 6.0 and 50 °C, respectively. It was found that the best treatment combination for eb-MPH production by response surface methodology (RSM) was 18% bromelain and a hydrolysis time of 3 h, resulting in the greatest degree of hydrolysis (% DH) and percent yield, with values of 61.04 and 45.63%, respectively. Results also showed that the phenylalanine, tyrosine and leucine contents of the optimally produced eb-MPH were 20.88, 14.50 and 10.93%, respectively. Twelve volatile compounds were identified using gas chromatography mass spectrometry in eb-MPH; benzaldehyde, 2-pentylfuran and furfural were the predominant odorants.     

Oxygen permeability and mechanical properties of films from hydrolyzed whey protein

The effects of whey protein hydrolysis on film oxygen permeability (OP) and mechanical properties at several glycerol-plasticizer levels were studied. Both 5.5% and 10% degree of hydrolysis (DH) whey protein isolate (WPI) had significant effect (p 0.05) occurred for film OP between unhydrolyzed WPI, 5.5% DH WPI, and 10% DH WPI films at the same glycerol content. Hydrolyzed WPI films of mechanical properties similar to those of WPI films had better oxygen barrier. Therefore, use of hydrolyzed WPI allowed achievement of desired film flexibility with less glycerol and with smaller increase in OP.