碱性蛋白酶水解大豆分离蛋白制备大豆多肽的工艺条件优化

以大豆分离蛋白为原料,地衣芽胞杆菌产碱性蛋白酶水解大豆分离蛋白,分别从酶浓度、pH值、反应温度和水解时间等因素来研究水解效果,在50℃,pH 10,酶浓度100 U/mL,水解2 h时水解效果最好,水解度达到31.45%。     

响应面法优化蚕豆蛋白酶解工艺条件的研究

考察了碱性蛋白酶、胰蛋白酶和中性蛋白酶对蚕豆蛋白的酶解效果,探讨了水解度（DH）与酶解产物抗氧化活性间的关系。通过单因素试验和响应面分析法,得到碱性蛋白酶酶解工艺的最佳条件。结果表明,温度50℃、pH8.0、酶底比8%、底物浓度3%条件下酶解3h,水解度0~22%内,碱性蛋白酶较胰蛋白酶和中性蛋白酶水解蚕豆蛋白效果好;DH与还原能力（R2=0.68~0.81）及ABTS清除能力（R2=0.98~0.99）具有较好的相关性,碱性蛋白酶酶解液较其他2个酶解液有较好的还原能力和ABTS清除能力;优化后的最佳酶解工艺参数为：酶底比8%,温度50℃、pH 7.6,对蚕豆蛋白还原能力的影响顺序为酶底比＞pH＞温度;在此条件下,蚕豆蛋白酶解液的还原能力理论值为0.174,验证试验测得还原能力为0.173,与理论值接近。     

高压酶解卵清蛋白的工艺优化及其在BHK-21细胞培养中的初步应用

采用高压技术水解卵清蛋白,以水解度为指标,对6种酶的水解效果进行比较,筛选出最佳水解用酶;在单因素实验的基础上,采用正交实验的方法对高压酶解卵清蛋白的工艺进行优化,并对酶解产物在BHK-21细胞培养中的应用进行了初步探讨。结果表明:6种酶中胰酶的水解效果最好,水解最佳工艺为:压力120 MPa、温度50℃、p H值7.0和酶/底物(E/S)=1∶2.5(质量比),水解度达到45.13%;用酶解产物培养BHK-21细胞,细胞生长形态良好,在培养168 h后,试验组细胞最大密度达到6.69×105cells/m L,是对照组的1.56倍,细胞数量增大了33.45倍,说明卵清蛋白酶解产物有明显的促细胞生长效果,为其在细胞培养中的应用提供了理论依据。     

牦牛骨蛋白的酶解条件研究

以蛋白质水解度为评价指标,辅以固形物溶出率,比较了中性蛋白酶、菠萝蛋白酶和木瓜蛋白酶对牦牛骨蛋白的水解效果,研究了酶用量、料液比(底物浓度)、酶解时间对水解度的影响,采用正交试验对酶解条件进行了优化。结果显示,木瓜蛋白酶是牦牛骨蛋白水解的适宜催化剂。在一定条件下,样品水解度随酶用量和酶解时间的增加而增大,底物浓度过低或过高均不利于原料中蛋白质的酶解。木瓜蛋白酶水解牦牛骨蛋白最佳条件为:酶解温度60℃,酶解时间8 h,酶用量3500 U/g蛋白质,料液比1:25(g:m l)。     

Alcalase碱性蛋白酶对中华稻蝗蛋白水解条件的研究

本试验采用Alcalase碱性蛋白酶对中华稻蝗蛋白进行水解,研究其蛋白酶解条件和酶解物的抗氧化性(用抑制邻苯三酚自氧化率来表示).结果表明,实验室最佳酶解条件为:底物浓度1%,pH值8.0,温度55℃,水解时间4 h,加酶量(V/V,%)为10%.在此条件下其酶解物具有明显的抗氧化活性,对邻苯三酚自氧化的抑制率可达40%,水解度为51%.     

牡蛎黄酒的研制及其功能性成分和抗氧化活性的研究

本研究采用酶解和发酵的方法,将牡蛎酶解液有机添加到北方黄酒的传统生产工艺中,研制出具有更强营养保健功能的牡蛎黄酒。首先对牡蛎酶解条件进行优化,料液比为5:1,加酶量为1%,酶解温度40℃,酶解时间为8 h时,水解度达到最高的31.21%,牛磺酸含量最高达到626.96μg/mL。进而比较了添加和不添加牡蛎酶解液的两种黄酒(牡蛎黄酒和北方黄酒)的营养价值和抗氧化活性。分析比较发现牡蛎黄酒比北方黄酒游离氨基酸增加了74.98%,牛磺酸含量增加了400%。新研制的牡蛎黄酒功能性成分显著增加,抗氧化性能增强。     

'过山香'香蕉胚性悬浮细胞原生质体分离的方法研究

目的:研究不同的方法对‘过山香'胚性悬浮细胞原生质体分离的影响,筛选最适合用于‘过山香'香蕉胚性悬浮细胞原生质体分离的方案.方法:用不同浓度、不同组合的酶液对‘过山香'原生质体进行分离,并对酶液的甘露醇含量、pH值进行调节.结果:3.0%纤维素酶R-10+0.2%果胶酶Y-23的是最佳酶组合;酶解8 h、酶液中含0.41 M甘露醇、酶液pH值为5.3时,获得原生质体产量最高.结论:合适的酶组合、酶解时间、酶液的渗透压和pH值对‘过山香'香蕉胚性悬浮细胞原生质体的分离有明显的促进作用.     

响应曲面法制备蛹虫草子实体酶解液的研究

为了将蛹虫草开发成为便于人们食用的产品形式,本实验以不同的酶对蛹虫草进行水解得到蛹虫草酶解液.以水解度和酶解液中腺苷含量为目标,确定选用木瓜蛋白酶.以水解度为响应指标,应用响应曲面法对蛹虫草酶解条件进行优化,根据Box-Behnken中心组合实验设计原理,选取酶解温度、酶解时间、加酶量三因素三水平进行中心组合实验,响应曲面分析结果表明水解最佳条件为:酶解温度60.92℃,酶解时间11.85 h,加酶量1.02％,此条件下蛹虫草的水解度达到最大.水解度验证值61.27％与预测值60.76％接近,说明建立模型正确.     

不同来源家蝇幼虫蛋白粉的水解与抗氧化性

本研究比较不同来源、不同酶解物浓度的家蝇幼虫蛋白及其抗氧化活性。以来自猪粪源和鸡粪源家蝇幼虫为原料制备蛋白粉,用胰蛋白酶水解蛋白粉制备水解产物,以·OH和O_2~-·清除率为指标评价两种蛋白酶解物的抗氧化活性。结果显示,家蝇幼虫蛋白水解物在4 h达水解度最高值,其水解物的·OH清除率在5 h达到最大为59.02%,其水解物的O_2~-·清除率在4 h达到最大为73.24%;随着两种水解物浓度增加,其抗氧化效果越强,当猪粪源和鸡粪源家蝇幼虫酶解物浓度为10 mg/mL时,两者O_2~-·清除率达到最大分别为70%和80%;·OH清除率分别为45%和52%。由此可见,家蝇幼虫酶水解物对超氧阴离子、羟自由基均有清除能力,鸡粪源家蝇幼虫酶解物优于猪粪源。     

贡蕉胚性悬浮细胞原生质体分离的研究

目的:研究不同方法对贡蕉胚性悬浮细胞原生质体分离的影响,筛选适合用于贡蕉胚性悬浮细胞原生质体分离的方案.方法:用不同的酶浓 度、酶组合及不同的酶解时间对贡蕉胚性悬浮细胞进行原生质体分离,并对不同继代时间的胚性悬浮细胞的原生质体产量和活力进行研究.结果:贡蕉胚性悬浮细胞 在酶组合为3.5%纤维素酶R-10、1%离析酶R-10和0.15%果胶酶Y-23的酶溶液中,酶解8h可获 得高产量的原生质体,采用继代7d的贡蕉胚性悬浮细胞进行原生质体分离时获得的原生质体产量最高,达到1.2×107个/mL PCV ECS,原生质体活力达到85%以上.结论: 合适的酶组合、酶浓度和酶解时间有利于贡蕉胚性悬浮细胞的原生质体分离,继代7d 后的贡蕉胚性悬浮细胞最适合用于原生质体分离.     

Protein hydrolysates from Bluefin Tuna (Thunnus thynnus) heads as influenced by the extent of enzymatic hydrolysis

Functional properties and antioxidant activities of protein hydrolysates from tuna (Thunnus thynnus) heads (THPHs), with different degrees of hydrolysis, obtained by treatment with Bacillus mojavensis A21 alkaline proteases and Alcalase, were investigated. Protein content of all freeze-dried THPHs ranged from 73.74 ± 0.5 to 78.56 ± 1.2%. The THPHs had excellent solubility, compared to untreated tuna head proteins and possessed interfacial properties, which were governed by their concentrations. Similarly, at a degree of hydrolysis (DH) of 12 and 15%, > 90% nitrogen solubility was observed at all experimental pH values tested. The emulsifying activity index (EAI) and emulsion stability index (ESI) of both hydrolysates at different DHs decreased (p < 0.05) with increasing DH. At low DH (5%), hydrolysates exhibited strong emulsifying properties. All THPHs produced by the A21 proteases generally showed higher antioxidative activity than that of the Alcalase protein hydrolysates. The highest DPPH radical-scavenging activity (78 ± 2.1% at 3 mg/mL) was obtained with a DH of 15%. The IC₅₀ value for the β-carotene bleaching assay was 0.5 ± 0.03 mg/mL. Alcalase (DH = 12%) and A21 (DH = 15%) protein hydrolysates contained glutamic acid/glutamine and arginine as the major amino acids, followed by lysine, aspartic acid/ asparagine, histidine, valine, phenylalanine, and leucine. In addition, the THPHs had a high percentage of essential amino acids, which made up 50.52 and 50.47%, of the protein hydrolysates obtained by the Alcalase and A21 proteases, respectively. Therefore, THPHs can be used as a promising source of functional peptides with antioxidant properties.     

Evaluation of iron-binding capacity,amino acid composition,functional properties of Acetes japonicus proteolysate and identification of iron-binding peptides

Recovery of functional iron-binding protein hydrolysate from Acetes japonicus employing enzymatic hydrolysis and iron-chelating peptide identification were conducted in this study. The result showed that under the optimal hydrolysis condition including Flavourzyme, pH 5, 50 °C, E:S ratio of 27.4 U/g protein and hydrolysis time of 4.8 h, the obtained proteolysate displayed the maximal iron-binding capacity (IBC) of 177.7 μgFe²⁺/g protein and comprehended 38,77 % of essential amino acids. Functional features of the Acetes proteolysate encompassing solubility, heat stability, foaming and emulsifying property, oil and water holding capacity were also noteworthy. Peptide fractionation was performed using ultrafiltration and the 1−3 kDa fraction expressed the highest IBC of 120.43 ± 0.15 μgFe²⁺/g protein, 13.7 times lower than that of disodium ethylenediaminetetraacetate (Na₂EDTA). From this fraction, two iron-binding peptides of DSVNFPVHGL (1083.53 Da) and FKVGQENTPILK (1372.77 Da) were identified utilizing nano-UHPLC-MS/MS as well as their de novo spatial structures and interaction with ferrous ion were simulated by PEP-FOLD 3. As a whole, the proteolysate/peptides could be filled as an iron chelator which could shield human body from iron deficient-related disorders or as a functional proteolysate preparation to upgrade food properties.     

Enzymatic hydrolysis of the Eisenia andrei earthworm: Characterization and evaluation of its properties

Some studies have carried out in order to retrieve proteins from the by-product of animal-processing industries. Earthworms are rich in protein and usually are used in animal feed. Thus, this study aimed to optimize the hydrolysis process of Eisenia andrei earthworms by employing Alcalase enzyme. Using the response surface methodology, we evaluated the following conditions: temperature, hydrolysis time, stirring speed, and enzyme/substrate ratio. The optimal conditions for the experimental design were determined through the analysis of the foaming and emulsifying properties, in vitro starch digestibility, and antioxidant activity. The results demonstrate that the highest degree of hydrolysis (i.e., 92%) was obtained under the following conditions: pH, 9.5; temperature, 25?°C; hydrolysis time, 2.25?h; stirring speed, 200?rpm; and enzyme/substrate ratio, 1.77%, using Alcalase enzyme. Evaluation of the amino acid composition under these conditions revealed higher concentrations of aspartic acid, glutamic acid, and leucine. The in vitro protein digestibility of the hydrolysate was approximately 73%. There were no significant improvements in either foam stability or emulsification after enzymatic hydrolysis. Additional studies on the antioxidant activity are required. This bioproduct could potentially serve as a promising supplementary food product.     

Hydrolysis of rapeseed protein isolates: Kinetics,characterization and functional properties of hydrolysates

Two rapeseed protein isolates corresponding to albumins and globulins, respectively, were produced from an industrial defatted rapeseed meal. A pilot-scale process of protein extraction has been developed to remove major anti-nutritional compounds, easy to scale-up and using recyclable solvents. The kinetics of the hydrolyses of these two protein substrates using Alcalase 2.4L^® were compared by the measurement of the degree of hydrolysis (DH) when varying the initial proteins and enzyme concentrations. The globulins isolate was hydrolysed more efficiently than the albumins isolate mainly due to the compact and globular conformation of albumin (napin). Kinetic parameters have been determined for both substrates and a log-linear relation has been established between the DH values at a definite time and the initial enzyme/substrate ratio. Such relationships allow an effective monitoring of hydrolysis process since the hydrolysates analysis using reverse-phase chromatography coupled with mass spectrometry revealed that peptide maps corresponding to peptides of molecular weight inferior to 1 kDa are similar at a specific DH, independently of the reaction temperature and initial concentrations of substrate and enzyme. Thus, it is demonstrated that the DH is the sole parameter needed to control the physico-chemical properties and consequently the functionalities (solubility, foaming and emulsifying properties) which depend on the nature of peptides present in the hydrolysates.     

猪血蛋白的酶水解及氨基酸含量

以AS1.398中性蛋白酶、胰蛋白酶、木瓜蛋白酶和菠萝蛋白酶对猪血蛋白进行水解,AS1.398中性蛋白酶对猪血蛋白的水解能力最强。采用活性炭对酶水解液进行脱色。脱色后的酶水解液中含有18种氨基酸,必需氨基酸占总氨基酸的39.18%。     

Enzymatic modification of yeast protein isolates

Yeast protein isolate with 85% of pure protein and 1.2% of nucleic acids in dry matter was isolated from Saccharomyces cerevisiae by a procedure of two pre-treatment steps, acidic extraction and isoelectric precipitation. The application of this yeast protein isolate was limited by its functionality resulting from the partially extreme isolating conditions. An enzymatic partial hydrolysis with Thermitase to a degree of hydrolysis of 5% not only improved the solubility and foaming properties, but also the water binding capacity and the emulsifying properties. The hydrolysate was free of bitter taste and could be applied either in two fractions of different solubility after centrifugation or as a whole product in food systems to improve the physiological and functional quality. The yeast protein hydrolysate had the same or even better properties than conventional protein products.     

木瓜蛋白酶水解马鹿茸血制备免疫活性肽的研究

选用木瓜蛋白酶对天山马鹿茸血进行水解制备免疫活性肽,确定了最佳水解工艺条件,并测定了三种不同水解度水解物的抗氧化活性和免疫活性。水解度(DH)为6.65%时的水解物具有最高DPPH.清除率,DH12.2%时的水解物具有最高OH.清除率。免疫活性体外检测实验显示,DH12.2%时的水解物促进细胞增值率随着浓度的增大而增大,呈现出良好的线性关系(P<0.05)。结果还显示,OH.清除率与免疫活性之间存在相关性,r=0.87(P<0.05).     

Lipase-catalyzed hydrolysis of fish oil in an optimum emulsion system

In this study, fish oil was hydrolyzed by lipase in a fish oil-in-water emulsion system in an effort to improve the functional properties of fish oil. Lipase activity was found to depend on the quality of the water/fish oil interface area. We selected several suitable emulsifiers, and their emulsifying activities were evaluated under a variety of conditions, including concentration, water-oil ratios, pH values, and temperature. Among the selected emulsifiers, the emulsifying activity of gelatin was higher than those of carboxymethyl chitin (CM-chitin), bovine serum albumin, and Tween-20, all of which are commercial emulsificers Moreover, the emulsifying activity of the gelatin solution was the highest at 0.5%, and was reduced with increasing concentrations of above 1%. The optimal water-oil ratio, pH, and temperature conditions were 40% (w/v), pH 8.0 and 40°C, respectively. Under these conditions, the emulsifying activity of gelatin solution was 86%. The emulsion structure of the gelatin solution was characterized by high density and small particle size. The degree of sardine oil hydrolysis in the emulsion system was 50% higher than that of the non-emulsion system. The lipid species of the lipase-prepared sardine oil hydrolysates were identified as triacylglycerol, 1,3- and 1,2-diacylglycerol, monoacylglycerol, and fatty acid.     

High T cell epitope sharing between two HLA-B27 subtypes (B*2705 and B*2709) differentially associated to ankylosing spondylitis.

HLA-B*2705 is strongly associated with ankylosing spondylitis (AS) and reactive arthritis. In contrast, B*2709 has been reported to be more weakly or not associated to AS. These two molecules differ by a single amino acid change: aspartic acid in B*2705 or histidine in B*2709 at position 116. In this study, we analyzed the degree of T cell epitope sharing between the two subtypes. Ten allospecific T cell clones raised against B*2705, 10 clones raised against B*2703 but cross-reactive with B*2705, and 10 clones raised against B*2709 were examined for their capacity to lyse B*2705 and B*2709 target cells. The anti-B*2705 and anti-B*2703 CTL were peptide dependent as demonstrated by their failure to lyse TAP-deficient B*2705-T2 transfectant cells. Eight of the anti-B*2705 and five of the anti-B*2703 CTL clones lysed B*2709 targets. The degree of cross-reaction between B*2705 and B*2709 was donor dependent. In addition, the effect of the B*2709 mutation (D116H) on allorecognition was smaller than the effect of the other naturally occurring subtype change at this position, D116Y. These results demonstrate that B*2705 and B*2709 are the antigenically closest HLA-B27 subtypes. Because allospecific T cell recognition is peptide dependent, our results imply that the B*2705- and B*2709-bound peptide repertoires are largely overlapping. Thus, to the extent to which linkage of HLA-B27 with AS is related to the peptide-presenting properties of this molecule, our results would imply that peptides within a relatively small fraction of the HLA-B27-bound peptide repertoire influence susceptibility to this disease.     

Changes in the enzymatic hydrolysis rate of Avicel cellulose with conversion

The slow down in enzymatic hydrolysis of cellulose with conversion has often been attributed to declining reactivity of the substrate as the more easily reacted material is thought to be consumed preferentially. To better understand the cause of this phenomenon, the enzymatic reaction of the nearly pure cellulose in Avicel was interrupted over the course of nearly complete hydrolysis. Then, the solids were treated with proteinase to degrade the cellulase enzymes remaining on the solid surface, followed by proteinase inhibitors to inactive the proteinase and successive washing with water, 1.0 M NaCl solution, and water. Next, fresh cellulase and buffer were added to the solids to restart hydrolysis. The rate of cellulose hydrolysis, expressed as a percent of substrate remaining at that time, was approximately constant over a wide range of conversions for restart experiments but declined continually with conversion for uninterrupted hydrolysis. Furthermore, the cellulose hydrolysis rate per adsorbed enzyme was approximately constant for the restart procedure but declined with conversion when enzymes were left to react. Thus, the drop off in reaction rate for uninterrupted cellulose digestion by enzymes could not be attributed to changes in substrate reactivity, suggesting that other effects such as enzymes getting "stuck" or otherwise slowing down may be responsible.