缢蛏蛋白肽制备工艺优化及其清除羟自由基作用

以缢蛏为试验材料,采用羟自由基清除率为评价指标,从胰蛋白酶、胃蛋白酶、木瓜蛋白酶、碱性蛋白酶和中性蛋白酶5种蛋白酶中筛选最适水解用酶,在单因素试验基础上使用响应面法优化酶解工艺条件,考察缢蛏蛋白肽的羟自由基清除能力并通过Sephadex G-15凝胶层析测定其分子质量分布。结果表明,碱性蛋白酶酶解制备的缢蛏蛋白肽清除羟自由基能力明显强于其他蛋白酶,优化后的碱性蛋白酶水解缢蛏蛋白工艺条件为底物浓度6mg/ml、加酶量3%、pH8.0、温度55℃、酶解时间4h,蛋白肽的羟自由基清除率为76.60%,IC50值为1.89mg/ml,蛋白肽中80%以上是分子质量小于1500Da的小分子肽。     

Optimization of the preparation of bioactive peptides from Sinonovacula constricta and its hydroxyl free radical scavenging activity

以缢蛏为试验材料,采用羟自由基清除率为评价指标,从胰蛋白酶、胃蛋白酶、木瓜蛋白酶、碱性蛋白酶和中性蛋白酶5种蛋白酶中筛选最适水解用酶,在单因素试验基础上使用响应面法优化酶解工艺条件,考察缢蛏蛋白肽的羟自由基清除能力并通过SephadexG-15凝胶层析测定其分子质量分布.结果表明,碱性蛋白酶酶解制备的缢蛏蛋白肽清除羟自由基能力明显强于其他蛋白酶,优化后的碱性蛋白酶水解缢蛏蛋白工艺条件为底物浓度6 mg/ml、加酶量3％、pH8.0、温度55℃、酶解时间4h,蛋白肽的羟自由基清除率为76.60％,IC50值为1.89 mg/ml,蛋白肽中80％以上是分子质量小于1500 Da的小分子肽.     

鲢酶解物对羟自由基的清除作用

通过测定酶解物对Fenton体系产生的羟自由基的清除效果，从胰蛋白酶、木瓜蛋白酶、胃蛋白酶、枯草杆菌蛋白酶和复合蛋白酶5种酶中，筛选出木瓜蛋白酶和胰蛋白酶作为酶解鲢制备具有较高清除羟自由基活性酶解物的理想水解酶；用正交试验L9(3^4)对两种酶的水解条件进行了优化，并对最佳酶解条件下得到的酶解物进行Sephadex G-25凝胶柱分离，洗脱液分别在波长280nm处比色，测定酶解物中主要抗氧化活性肽的分子量分布。结果表明，木瓜蛋白酶在温度50℃、酶解时间15min、pH=6．5、酶质量分数1．50％、底物：水=1：2的水解条件下，酶解物对羟自由基清除效果较好，清除率为88．2％；胰蛋白酶在温度55℃、酶解时间60min、pH=8．0、酶质量分数0．25％、底物：水=1：2的水解条件下，酶解物对羟自由基清除效果较好，清除率为84．2％。木瓜蛋白酶酶解物在最大洗脱峰时有最大羟自由基清除率峰，清除率为95．1％，在最大峰处酶解物中活性肽的分子量为2．2kDa；胰蛋白酶酶解物在最大洗脱峰时也有最大羟自由基清除率峰，其清除率为89．6％，该峰处活性肽的分子量为14．2kDa。     

复合酶提取牡蛎抗氧化肽的工艺研究

以牡蛎为原料,首先从木瓜蛋白酶、中性蛋白酶、碱性蛋白酶、胃蛋白酶、胰蛋白酶中筛选出胰蛋白酶为内切酶,以水解度为指标,得到最佳的酶解工艺条件:时间4h,温度50℃,pH8.0,料水比1∶2,加酶量3％(7 500 U/g),水解度为49.50％;同时以水解度为指标,得到外切酶风味蛋白酶的最佳酶解工艺:时间5h,温度50℃,pH8.0,料水比1∶2,加酶量3％ (450 U/g),实际水解度50.95％.最后,以清除羟自由基能力和水解度为指标,探讨内切酶(胰蛋白酶)和外切酶(风味蛋白酶)不同复合酶解方式的抗氧化能力.最终确定,复合酶解制备牡蛎抗氧化肽效果最好,其酶解条件为胰蛋白酶为3％(7 500 U/g)、风味蛋白酶加酶量为3％ (450 U/g),pH8.0,时间5h,料水比1∶2,温度50℃时,水解度高达53.94％,体外清除·OH的EC50为0.56 mg/mL.     

响应面法优化末水坛紫菜蛋白酶解工艺及其酶解液抗氧化活性研究

为实现末水坛紫菜(Porphyra haitanensis)的高值化利用,研究了末水坛紫菜的蛋白酶解工艺及其酶解液的抗氧化活性。以酶解产物水解度和还原力为指标,分别采用单因素和响应面优化实验筛选出最适蛋白酶和最佳酶解工艺参数;通过测定酶解液还原力对1,1-二苯基-三硝基苯肼(DPPH)自由基、羟自由基(·OH)和超氧阴离子自由基(O_2~-·)的清除作用,研究了最高水解度下的酶解液的抗氧化性活性。结果表明,中性蛋白酶是6种蛋白酶中的最适用酶;最佳酶解条件为:底物质量浓度35 g·L~(-1)、加酶量31 200 U·g~(-1)、温度45℃、pH 7.6、酶解时间5 h,在此条件下坛紫菜水解度达31.37%;酶解液还原力为2.2,对DPPH、·OH和O_2~-·自由基清除率分别为56.26%、85.84%和72.73%。结果表明,中性蛋白酶可以有效水解末水坛紫菜,水解后的酶解产物具有较好的抗氧化能力和应用前景。     

壳聚糖固定化胰蛋白酶制备牡蛎肽的研究

以壳聚糖为载体固定化胰蛋白酶,制备牡蛎肽,然后以肽得率为指标,分别研究了pH值,酶加量,酶解时间和温度等单因子对固定化胰蛋白酶酶解牡蛎蛋白质的影响。实验结果表明,酶解牡蛎蛋白的最佳工艺条件是:底物浓度为200μg/mL,加固定化胰蛋白酶量7mg/3mL,酶解时间3h,pH 8.0,温度40℃。在此条件下水解牡蛎蛋白,肽得率可达到20.39%。     

鳕碎肉酶解物清除羟自由基作用研究

通过测定鳕碎肉酶解物对Fenton体系产生的羟自由基的清除效果,从海洋蛋白酶YS-894、海洋蛋白酶YS-80、胃蛋白酶和木瓜蛋白酶中,筛选出海洋蛋白酶YS-894作为酶解鳕碎肉制备具有较高清除羟自由基活性酶解物的水解酶;用正交试验L9(34)对该酶的水解条件进行优化,并确定了水解的最佳肉水比。最终工艺条件为40℃、酶解45 m in、pH 9.0、酶解质量分数0.25%、底物∶水=1∶3的条件下进行水解,水解物对羟自由基的清除效果较好,清除率为68.88%。     

紫菜降血压肽酶法制备工艺的优化

摘要：降血压肽又称为血管紧张素转化酶抑制肽，是具有降血压活性的生物活性肽，对高血压患者有显著疗效。为探讨从紫菜中制备降血压肽的酶法工艺，本实验选用AS．1398中性蛋白酶、胰蛋白酶、复合酶、木瓜蛋白酶、碱性蛋白酶、风味蛋白酶等6种蛋白酶分别对紫菜进行酶解，通过对其酶解液的ACE抑制活性和水解度的比较，发现采用AS．1398中性蛋白酶酶解的产物ACE抑制活性最高。对AS．1398中性蛋白酶的酶解工艺进一步优化，确定其最佳酶解工艺为：温度50℃、pH值7．5、加酶量E／S10000U·g^-1。在此条件下，酶解4h和10h的酶解产物抑制活性最高均达70％以上，并发现紫菜酶解液的ACE抑制率与水解度的增长不成显著的线性关系。     

基于Box Behnken响应面设计优化制备鸢乌贼抗氧化肽的研究#br#

以印度洋鸢乌贼(Symplectoteuthis oualaniensis)胴体分离蛋白为原料,基于分子量分布和营养价值分析,优化制备抗氧化肽的酶解工艺参数。碱溶酸沉法从鸢乌贼胴体提取分离蛋白;以底物浓度、酶底比、酶解时间等3个因素为单因素实验;Box-Behnken中心法则设计响应面实验;DPPH自由基清除率结合水解度为响应指标。鸢乌贼胴体分离蛋白相对分子量分布在30~240 kDa;必需氨基酸占总氨基酸42.56%;最佳酶解工艺参数是底物浓度4%、酶底比9 U·mg^-1、酶解时间4 h。5 mg·mL^-1的鸢乌贼胴体分离蛋白酶解物的DPPH自由基清除率为55.60%,羟自由基清除率为53.21%,ABTS自由基清除率为40.12%。鸢乌贼胴体分离蛋白符合FAO/WHO世界卫生组织提出的理想蛋白营养价值模式,鸢乌贼胴体能制备出营养价值高和抗氧化活性强的海洋功能蛋白肽。     

牡蛎酶解液的抗氧化活性

检测了牡蛎(Crassotera gigas)木瓜蛋白酶和中性蛋白酶酶解液的抗氧化活性。由Sephadex G-15葡聚糖凝胶柱层析分析牡蛎酶解液,得到具抗氧化活性组分的分子量分布。分子量为1191 D和826 D左右的木瓜蛋白酶酶解活性肽组分的自由羟基清除活性最强,当其质量浓度分别为0.184 mg/mL和0.673 mg/mL时,体外自由羟基清除活性分别为53.6%和66.5%;分子量分别为1074 D和735 D左右的中性蛋白酶酶解活性肽的自由羟基清除活性最强,当其质量浓度分别为0.166 mg/mL和0.830 mg/mL时,体外自由羟基清除活性分别57.6%和70.5%。HPLC分析结果表明,木瓜蛋白酶与中性蛋白酶酶解的活性肽组分分别由几种抗氧化肽组成。抗氧化活性最强的木瓜蛋白酶与中性蛋白酶酶解的肽组分在质量浓度为2.5 mg/mL时,活性分别可达83.6%和80.8%。用牡蛎原浆与各酶解液灌胃昆明小白鼠。研究结果表明,用木瓜蛋白酶与中性蛋白酶酶解原液及经超滤纯化的酶解液对小白鼠实施灌胃,其肝脏组织的SOD活力都显著提高(P<0.05);灌胃经超滤纯化的木瓜蛋白酶和中性蛋白酶酶解液,小白鼠肝脏组织GSH-PX活力、GSH含量显著提高(P<0.05),MDA含量显著降低(P<0.05)。     

鲣鳔蛋白抗氧化酶解物制备工艺

为有效提高鲣鳔蛋白的附加值,研究以DPPH自由基清除率为抗氧化活性评价指标,采用蛋白酶酶解制备活性多肽的工艺,选用菠萝蛋白酶、复合蛋白酶、碱性蛋白酶、木瓜蛋白酶、胃蛋白酶、胰蛋白酶、中性蛋白酶7种酶在各自最适的条件下酶解,筛选出复合蛋白酶为最适用酶,通过单因素实验分别研究加酶量、溶液初始p H、酶解温度和时间对酶解物抗氧化活性的影响,在此基础上,根据响应面法优化鲣鳔抗氧化酶解物的制备工艺。结果显示,最佳酶解工艺条件为加酶量8.53 U/mg,p H 5.54,温度50.03°C,时间5.07 h。此外,利用超滤法对最佳条件下制备的酶解物进行初步分级,得到分子质量分别为大于10 000 u、3000~10 000 u和小于3000 u的3段组分,且这3段组分对DPPH自由基的半抑制浓度IC50值分别为0.64、0.52和0.37 mg/m L。研究表明,最优条件下制备的酶解物的DPPH清除率达72.00%,与模型预测值71.60%接近,且其中小于3000 u的组分具有较强的DPPH自由基清除活性。     

大鲵肉酶解产物的制备及其抗氧化性的研究

以大鲵肉为原料,利用Aspergillus sp.酸性蛋白酶进行酶解,研究其最佳的酶解条件以及酶解产物的抗氧化作用。结果表明,大鲵肉酶解的最佳工艺条件为Aspergillus sp.酸性蛋白酶加酶量为0.4%(质量比)及底物浓度为0.1g/mL时,酶解时间5.5h,pH 2.0,温度45℃。时间飞行质谱表明酶解产物的分子量小于2 000,苯酚硫酸法测定糖含量为2%,Folin-酚试剂法测蛋白含量为93%。大鲵酶解产物清除羟基自由基(.OH)和DPPH自由基的能力随浓度升高而增强。     

Preparation and Characterization of Protein Hydrolysates From Little Loligo Squid (Uroteuthis chinensis)

Research on the little loligo squid (Uroteuthis chinensis) protein hydrolyzed by papain and Flavourzyme and characterization of hydrolysates was carried out in this article. The optimum hydrolysis conditions of papain were obtained by orthogonal experiments, and the influence factors on the degree of hydrolysis such as enzyme/substrate ratio, hydrolysis time, pH, and temperature were investigated. The effect of Flavourzyme on the degree of hydrolysis was also studied. The characteristics of freeze-dried hydrolysates such as yield, moisture, nitrogen recovery, molecular mass distribution, and amino acid composition were determined. The results showed that papain and Flavourzyme could hydrolyze the little loligo squid protein efficiently, and the degree of hydrolysis was up to 25.82% under the optimum hydrolysis conditions. The average molecular mass of hydrolysates obtained with papain and Flavourzyme was 1,246 Da, and the low molecular mass peptides were the main fraction of hydrolysates. The yield, moisture, and nitrogen recovery of freeze-dried hydrolysates was 19.8, 4.4, and 74.2%, respectively. Compared with suggested patterns of amino acid requirements by the Food and Agriculture Organization of the United Nations/World Health Organization (FAO/WHO), the hydrolysates of the little loligo squid had high nutritional value, and was a potential nutritious supplement used in various food products.     

Antioxidant Activity of Hydrolysates and Peptide Fractions of Nemipterus japonicus and Exocoetus volitans Muscle

The focus of the study was to investigate the antioxidant activity of hydrolyzed muscle protein of Nemipterus japonicus and Exocoetus volitans. The trypsin protein hydrolysates of both fish showed maximum free radical scavenging potential and lipid peroxidation inhibition. Furthermore, it was purified by chromatographic methods followed by the lipid peroxidation inhibition; free radical scavenging assay was performed before and after purification. The purified peptide fractions of N. japonicus and E. volitans exhibited higher activity against polyunsaturated fatty acids (PUFA) peroxidation which was similar to natural antioxidants like α-tocopherol. Free radical scavenging potencies were measured by electron spin resonance technique (ESR). The purified peptide of E. volitans quenched free radicals (DPPH, hydroxyl, and superoxide) slightly more than N. japonicus. The amino acid composition of both fish protein hydrolysates showed variations in their ratio. The purified peptides were tested for cell cytotoxicity for Vero (kidney epithelial cells of the African Green Monkey) and Hep G₂ (human hepatocellular liver carcinoma) cell lines. It was found that peptides did not show any cytotoxic effect for Vero cell lines and exerted a significant antiproliferative effect on Hep G₂ cell lines.     

酶法提取鱿鱼皮胶原蛋白工艺条件的研究

研究了酶法提取鱿鱼皮胶原蛋白的工艺条件。根据5种蛋白酶水解液中羟脯氨酸（HYP）的含量,确定了胰蛋白酶和木瓜蛋白酶这2种提取率高的酶为水解用酶,采用L16（4^5）正交试验确定了这2种酶水解鱿鱼皮以制备胶原蛋白的最佳酶解条件。结果表明,胰蛋白酶和木瓜蛋白酶水解鱿鱼皮以制备胶原蛋白的最佳温度、加酶量、底物浓度、pH、时间分别为55℃、1200U·g^-1、1：20、pH8.0、4h和50℃、3200U·g^-1、1：20、pH6.0、6h。2种蛋白酶提取的胶原蛋白含量分别为11.08%和11.36%,提取率分别为95.16%和97.56%。     

Antioxidant and Angiotensin-Converting Enzyme Inhibitory Activities of Protein Hydrolysates Prepared from Threadfin Bream (Nemipterus spp.) Surimi By-products

Solid wastes from threadfin bream (Nemipterus spp.) surimi production composed of head and frame were hydrolyzed by various commercial proteases (Alcalase, Flavourzyme, Neutrase, Protamex, papain, and pepsin) to produce protein hydrolysates with bioactive properties. An Alcalase-hydrolyzed sample at 24.4% degree of hydrolysis (DH) displayed the highest antioxidant activity based on 1,1-diphenyl-2-picrylhydrazyl (DPPH) radical scavenging, ferric reducing antioxidant power (FRAP) assay, and potassium ferricyanide method. In addition, it showed an inhibitory activity toward angiotensin-converting enzyme (ACE) of 25.5%. Antioxidant activity of threadfin bream by-product hydrolysates increased with hydrolysis time and reached the highest DPPH activity after 6 h, while that hydrolyzed for 3 h showed the highest reducing power based on FRAP and potassium ferricyanide assays. In addition, ACE inhibitory activity was found to be at an optimum after 3 h of hydrolysis. The hydrolysates (1 mg/mL) also retarded oxidation of a linoleic acid emulsion system to a similar extent as 0.1 mg/mL 3-tert-butyl-4-hydroxy anisole (BHA), indicating a potential use in the food system. Protein hydrolysates from threadfin bream surimi by-products could be tailor-made to possess both antioxidant and ACE inhibitory activity through controlling DH of Alcalase-catalyzed reactions.     

条斑紫菜蛋白酶解液脱色脱腥技术研究

以条斑紫菜为原料采用木瓜蛋白酶制备紫菜蛋白酶解液,以活性回收率和脱色率为评价指标,研究酶解液的脱色脱腥技术。试验结果表明,紫菜盐酸提取液色素最大吸收峰为550nm;在单因素试验基础上,通过正交试验优化后的脱色工艺条件为活性炭用量10g/L、脱色温度60℃、脱色时间40min、pH 6.5,脱色后的酶解液呈浅黄色,活性回收率逾90%。     

Optimization of Hydrolysis Conditions for Production of Angiotensin-Converting Enzyme Inhibitory Peptides from Basa Fish Skin Using Response Surface Methodology

ABSTRACT

Basa fish skin free from fat and noncollagenous proteins was hydrolyzed by different proteinases to produce angiotensin-converting enzyme (ACE) inhibitory peptides. Protamex hydrolysates were found to have the highest ACE inhibitory activity. Response surface methodology (RSM) was applied to optimize the hydrolysis conditions of Protamex—including enzyme-to-substrate ratio, hydrolysis time, and solid (fish skin)-to-liquid (water for hydrolysis)—at a temperature of 50°C and a pH of 7.0. The mathematical model demonstrated a good fit with the experimental data. An enzyme-to-substrate ratio of 6,108 U/g, a hydrolysis time of 1.24 h, and a solid-to-liquid ratio of 1:8.05 g/mL were found to be the optimal conditions to achieve the highest value of ACE inhibitory activity. The IC₅₀ of the hydrolysates for ACE inhibitory activity was 1.417 mg/mL under these conditions.     

Autolysis of Anchovy (Engraulis japonicus) Protein: Evaluation of Antioxidant Properties and Nutritional Quality of Resulting Hydrolysates

Protein hydrolysis of underutilized marine organisms is a method to improve added value. In the present article, anchovy protein was autolyzed at pH 8.5 and 50°C. After autolysis processing for 24 h, total nitrogen recovery reached 92.1%. The protein hydrolysates had antioxidant properties on reducing power, 1, 1-diphenyl-2-picryhydrazyl radical, and hydroxyl radical scavenging activity. More than 79% of the peptides in the hydrolysates had a molecular weight of lower than 3 kDa. Protein hydrolysates had balanced amino acid compositions, and total content of essential amino acids had no significant difference after hydrolysis. Protein hydrolysates from anchovy autolysis have potential in nutritional and functional foods.