Purification and characterization of chymosin and pepsin from kid

The objective of this work was to study the characteristics of the gastric aspartic proteinases chymosin and pepsin which are constituents of the kid rennet. The two enzymes were extracted from abomasal tissue of one kid from a local indigenous breed, separated from each other by DEAE-cellulose chromatography and then were purified by gel filtration and anion-exchange chromatography. The molecular weights of the purified kid chymosin and pepsin as determined by gel filtration were 36 kDa and 40 kDa respectively. The isoelectric point of kid chymosin was as multiple forms of 3-6 zones at pH 4.6-5.1, while that of kid pepsin was at pH < or =3.0. Kid pepsin contained 0.37 molecules phosphorous per molecule and was totally inhibited by 5 muM pepstatin A, being more sensitive than kid chymosin. Both enzymes were almost equally as proteolytic as calf chymosin on total casein at pH 5.6. Kid pepsin activity was more pH and temperature dependent than kid chymosin activity. In comparison with the calf chymosin temperature sensitivity, the order of increased sensitivity was: calf chymosin 相似文献   

Purification and characterisation of milk‐clotting and caseinolytic activities of pepsin isolated from adult sheep abomasa

Ovine pepsin was isolated and assessed for its milk‐clotting properties and caseinolytic activity in comparison with commercial chymosin. Ovine pepsin showed similar responses to variations in pH, temperature and CaCl₂ concentration of milk compared with chymosin, although its pH sensitivity was higher. SDS‐PAGE electrophoretic analysis of the casein fractions treated with ovine pepsin showed that alpha‐casein was more susceptible to proteolysis than beta‐casein, in contrast to chymosin. Curd‐firming properties of skim milk gels obtained with ovine pepsin and chymosin were evaluated by Gelograph under the same conditions. Curd produced using ovine pepsin was less firm than that made with chymosin.     

Effects of age and suckling on chymosin and pepsin activities in abomasums of goat kids

The effects of age and suckling on the chymosin and pepsin activities in abomasums of goat kids were studied using column chromatography. The results showed that the chymosin activity in abomasums of suckling kids at 5 days of age was significantly greater than other age groups (P < 0.01); chymosin activity of random suckling kids decreased with increasing age (P < 0.01); chymosin activity of weaned kids gradually decreased from 10 to 20 days (P < 0.01), and then remained unchanged (P < 0.05); pepsin activity showed a trend of increasing with the advance of age. For kids of the same age, the chymosin activity in the suckling group ranked the highest, the random suckling group the second, and the weaned group the last, but the pepsin activity was in reverse order.     

Tuna pepsin: characteristics and its use for collagen extraction from the skin of threadfin bream (Nemipterus spp.)

ABSTRACT:  Pepsin from the stomach of albacore tuna, skipjack tuna, and tongol tuna was characterized. Pepsin from all tuna species showed maximal activity at pH 2.0 and 50 °C when hemoglobin was used as a substrate. Among the stomach extract of all species tested, that of albacore tuna showed the highest activity (40.55 units/g tissue) ( P < 0.05). Substrate-Native-PAGE revealed that pepsin from albacore tuna and tongol tuna consisted of 2 isoforms, whereas pepsin from skipjack tuna had only 1 form. The activity was completely inhibited by pepstatin A, while EDTA (ethylenediaminetetraacetic acid), SBTI (soybean trypsin inhibitor), and E-64 (1-( L -trans-epoxysuccinyl-leucylamino)-4-guanidinobutane) exhibited negligible effect. The activity was strongly inhibited by SDS (sodium dodecyl sulfate) (0.05% to 0.1%, w/v). Cysteine (5 to 50 mM) also showed an inhibitory effect in a concentration dependent manner. ATP, molybdate, NaCl, MgCl₂, and CaCl₂ had no impact on the activity. When tuna pepsin (10 units/g defatted skin) was used for collagen extraction from the skin of threadfin bream for 12 h, the yield of collagen increased by 1.84- to 2.32-fold and albacore pepsin showed the comparable extraction efficacy to porcine pepsin. The yield generally increased with increasing extraction time ( P < 0.05). All collagen obtained with the aid of tuna pepsin showed similar protein patterns compared with those found in acid-solubilized collagen. Nevertheless, pepsin from skipjack tuna caused the degradation of α and β components. All collagens were classified as type I with large portion of β-chain. However, proteins with molecular weight (MW) greater than 200 kDa were abundant in acid-solubilized collagen.     

Natural heterogeneity of chymosin and pepsin in extracts of bovine stomachs

The two main components, chymosin and pepsin, in calf and adult bovine rennet show heterogeneity with respect to their charge and activity. A large number of single stomachs have been extracted and their isoenzymes have been analysed by HPLC. The results showed three genetic forms of chymosin A, B and C and these are present in individual stomachs in the following combinations: AA, BB, CC, AB, AC and BC. The C variant, which can be distinguished from the degradation product of chymosin A, has never been characterised before. All three chymosins have been purified and partially characterised. Also bovine pepsins show a natural variability: the ratio between the main pepsin fractions varies according to the age of the animal and it therefore provides a criterion to distinguish between pepsin from calf and adult bovine animals.     

Immobilization of pepsin on chitosan beads

In this study, chitosan beads were prepared by using a cross-linking agent and the resulting beads were employed in immobilization process. Studies on free and immobilized pepsin systems for determination of optimum temperature, optimum pH, thermal stability, pH stability, operational stability, storage stability and kinetic parameters were carried out. The optimum temperature interval for free pepsin and immobilized pepsin were 30–40 and 40–50 °C, respectively. Free and immobilized pepsin showed higher activity at pH 2.0–4.0. Apparent K_m = 12.0 g L⁻¹ haemoglobin (1.56 mM tyrosine) and V_max = 5220 μmol (mg protein min)⁻¹ values were obtained for free pepsin, while apparent K_m = 20.0 g L⁻¹ haemoglobin (2.16 mM tyrosine) and V_max = 2780 μmol (mg protein min)⁻¹ values were obtained for immobilized pepsin. Thermal stability and storage stability of immobilized pepsin were higher than that of free pepsin. Milk clotting activity was used for evaluation of the applicability of pepsin immobilization to industrial process. Optimum milk clotting temperature was found as 40 °C for free pepsin and 50 °C for immobilized pepsin.     

Estimation of Residual Pepsin and Chymosin Activity in Curd,

Pasteurized milk (225 g) adjusted to pH 6.2 was set with 3.5 milk clotting units of chymosin (EC 3.4.23.4). The same amount of milk at pH 5.8 was set with 3.5 milk clotting units of porcine pepsin (EC 3.4.23.1). Fifteen minutes after clotting, the curd was broken, and curd and whey were separated by centrifugation at 3500 × g for 20 min. The curd (30 g) was extracted at pH 6.8 in 450 ml water or at pH 6.2 (chymosin) or 5.8 (pepsin) in 450 ml 1 M sodium chloride.Chymosin was completely released from the curd and accounted for by both methods of extraction. Pepsin was completely released and accounted for after extraction in 1 M sodium chloride at pH 5.8 but was partly inactivated during extraction at pH 6.8.Assay of curd extracts and whey by a linear agar diffusion test accounted for 102 ± 6% of the pepsin activity added to milk when the curd was extracted in 1 M sodium chloride. Extraction at pH 6.8 allowed recovery of only 63% of the activity. Chymosin recovery was 100 ± 5% by both methods of curd extraction.     

Type I collagen from the skin of ornate threadfin bream (Nemipterus hexodon): Characteristics and effect of pepsin hydrolysis

Type I collagen from the skin of ornate threadfin bream (Nemipterus hexodon) was purified and characterised. Purified type I collagen contained [α1(I)]₂α2(I) as the dominant component with the co-presence of α1(I)α2(I)α3(I). It was rich in glycine and alanine with high content of imino acids (188 residues/1000 residues). The maximum transition temperature (T_m) and the total denaturation enthalpy (ΔH) of purified type I collagen was 33.35 °C and 0.819 J/g, respectively. The isoelectric point (pI) of purified type I collagen was estimated to be 6.40. After hydrolysis of purified type I collagen using pepsin, the band intensity ratios of α1/α2-chains were increased (P < 0.05). The cross-linked components were effectively hydrolysed by pepsin 1 and 2 from skipjack tuna stomach and porcine pepsin at 4 °C without the cleavage of β- and α-chains. At 50 °C, they were more susceptible to porcine pepsin hydrolysis, followed by pepsin 2 and 1, respectively.     

Gel diffusion--a simple and sensitive technique for the assay of proteinase inhibitors and its use for the determination of the ratio of proteinases in mixtures.

In casein-containing agarose gels, pepsin and chymosin form radial diffusion zones; the diameters of these zones show rectilinear correlations with the logarithm of the enzyme concentration at constant time. The sensitivity for both enzymes is below 1 microgram. Addition of the inhibitor pepstatin A to these enzymes causes a reduction of the diameters of the diffusion zones, with large differences for both the enzymes. With this procedure, the pepsin/chymosin ratio in rennet preparations was assayed with an accuracy of +/- 5%. Identification of the inhibitors allows the determination of amounts in the namomole range. This method is a simple technique for the evaluation of proteinases and their inhibitors in screening systems.     

Primary proteolysis studied in a cast cheese made from microfiltered milk

Primary proteolysis was studied in a starter-free cheese model made from microfiltered (MF) milk (19.0% casein,<0.2% whey proteins). Specificity of plasmin and chymosin activity was investigated in the pH range 5.0–6.0, by analysis of peptide composition using high-performance liquid chromatography and liquid chromatography–mass spectrometry. Hydrolysis experiments with purified caseins were performed to aid identification of peptides released by specific activities. Plasmin had no activity in cheese below pH 5.4, while its activity increased from pH 5.4 to 6.0. Chymosin activity on the Phe₂₃–Phe₂₄ bond of α_S1-casein had an optimum pH around 5.3, while release of the bitter peptide β-casein (f193–209), effected by chymosin, was highest at pH 6.0. At pH <5.3, the specificity of chymosin on α_S1-casein changed, and the peptide bond Leu₂₀–Leu₂₁ was cleaved at an increasing rate with decreasing pH. Demineralisation of the MF retentate generally increased proteolytic activity.     

STABILITY OF PEPSIN (EC 3.4.23.1) DURING IN VITRO PROTEIN DIGESTIBILITY ASSAY1,2

To maximize the efficiency of utilization of pepsin and estimate the contamination of pepsin for in vitro protein digestibility assays, the specific activity decay and peptide bond hydrolysis of pepsin incubated at different pH and concentration were studied with the bovine hemoglobin method and the o‐phthaldialdehyde method, respectively. It was found that increase of pH and concentration of pepsin increased pepsin's half‐life for both specific activity decay and peptide bond hydrolysis. The half‐life for specific activity decay was not extended by the presence of a substrate protein. The results indicated the time needed to maximize pepsin utilization depended on pH and the concentration of pepsin. At the time when all specific activity of pepsin was lost, the average size of pepsin autolysates was between 6.9 and 12.1 amino acid residues, suggesting most peptic protein would be fractionated as digestible protein.     

Thermal inactivation of chymosin during cheese manufacture

The aspartic proteinase, chymosin (EC 3.4.23.4) is the principal milk clotting enzyme used in cheese production and is one of the principal proteolytic agents involved in cheese ripening. Varietal differences in chymosin activity, due to factors such as cheese cooking temperature, fundamentally influence cheese characteristics. Furthermore, much chymosin is lost in whey, and further processing of this by-product may require efficient inactivation of this enzyme, with minimal effects on whey proteins. In the first part of this study, the thermal inactivation kinetics of Maxiren 15 (a recombinant chymosin preparation) were studied in skim milk ultrafiltration permeate, whole milk whey and skim milk whey. Inactivation of chymosin in these systems (at pH 6.64) followed first order kinetics with a D45.5 value of 100 +/- 21 min and a z-value of 5.9 +/- 0.3 degrees C. D-Values increased linearly with decreasing pH from 6.64 to 6.2, while z-values decreased as pH decreased from 6.64 to 6.4, but were similar at pH 6.4 and 6.2. Subsequent determination of chymosin activity during manufacture of Cheddar and Swiss-type cheese showed good correlations between predicted and experimental values for thermal inactivation of chymosin in whey. However, both types of cheese curd exhibited relatively constant residual chymosin activity throughout manufacture, despite the higher cooking temperature applied in the manufacture of Swiss cheese. Electrophoretic analysis of slurries made from Cheddar and Swiss cheese indicated decreased proteolysis due to chymosin activity during storage of the Swiss cheese slurry, but hydrolysis of sodium caseinate by coagulant extracted from both cheese types indicated similar levels of residual chymosin activity. This may suggest that some form of conformational change other than irreversible thermal denaturation of chymisin takes place in cheese curd during cooking, or that some other physico-chemical difference between Swiss and Cheddar cheese controls the activity of chymosin during ripening.     

Proteolytic activity of proteinases on macropeptide isolated from kappa-casein.

Proteolytic activities of chymosin, bovine pepsin, Mucor miehei rennet, Cryphonectria parasitica (formerly Endothia parasitica) rennet, trypsin, and chymotrypsin on kappa-casein macropeptide were measured. Macropeptide solutions (10 mg/ml of .05 M, pH 6.6 phosphate buffer) were incubated with the enzymes at 37 degrees C for various times, and their reactions were stopped by adding .025 ml of pepstatin (1 mg/ml of methanol). Peptides released from kappa-casein macropeptide were then fractionated using reverse-phase HPLC. At the pH of milk (pH 6.6), kappa-casein macropeptide was resistant to enzymic action by chymosin, bovine pepsin, and M. miehei and C. parasitica rennets. Bovine pepsin hydrolyzed kappa-casein macropeptide at pH 3. kappa-Casein macropeptide was readily hydrolyzed at pH 6.6 by trypsin and chymotrypsin. Possible physiological functions of the kappa-casein macropeptide are discussed in light of these findings.     

Inhibition of rennets by blood serum

Incubation of calf chymosin with the serum from blood of various mammalian species before addition to milk reduced its milk‐clotting activity at 30°C; the inhibitory potency of the sera was in the order horse > goat > cattle > donkey = human. For all species, inhibition of calf chymosin increased on increasing both the incubation time and the level of blood serum. Horse blood serum inhibited other milk coagulants in the order porcine pepsin > Cryphonectria parasitica proteinase = calf chymosin > Rhizomucor miehei proteinase = bovine pepsin. Methylamine‐treated blood serum did not inhibit calf chymosin, suggesting that α₂‐macroglobulin may be the principal inhibitor of rennet in blood serum.     

Optimization and Scale‐Up Preparation of Egg White Hydrolysate with Angiotensin I Converting Enzyme Inhibitory Activity

Angiotensin I converting enzyme (ACE) plays an important role in regulation of blood pressure as it converts angiotensin I into angiotensin II (a potent vasoconstrictor). Food protein‐derived ACE inhibitory peptides have been considered as a safer alternative to antihypertensive drugs. In our previous study, three ACE inhibitory peptides were characterized from egg white ovotransferrin and their antihypertensive activity has been validated in spontaneously hypertensive rats. However, it is too costly to prepare these peptides from purified egg white ovotransferrin. The aims of the study were to determine the feasibility of preparing these peptides using egg white and then to optimize the conditions of preparing egg white hydrolysate. Taguchi's method was used to design experiments for optimization, which was established as follows: substrate %, pH of thermoase, time of thermoase digestion, ratio of pepsin to substrate, pH of pepsin, temperature of pepsin, and time of pepsin digestion were 7.5%, pH 8, 90 min, 1%, pH 2.5, 55 °C, and 180 min, respectively. The ACE inhibitory activity (IC₅₀ value) and peptide yield obtained under optimal condition were 30 ± 2 μg/mL and 77.5% ± 0.3%, respectively, which were comparable to the predicted values. Hydrolysate prepared at 150 L reactor showed comparable activity but low peptide yield. Results of this study demonstrated the feasibility of using egg white protein as the starting material to prepare a functional ingredient with potent ACE inhibitory activity.     

Influence of pH on retention of camel chymosin in curd

Retained coagulant in cheese initiates casein breakdown and influences cheese structure and flavour formation. This study investigated the influence of milk pH on retention of camel chymosin in curd and compared it with bovine chymosin. Milk at five different pH levels was coagulated with same coagulant activity of each chymosin and centrifuged. Chymosin activity in whey was determined using the synthetic peptide Pro-Thr-Glu-Phe-(NO₂-Phe)-Arg-Leu as substrate and HPLC analysis of the resulting product. Camel chymosin had 2.7 times lower activity in milk than bovine chymosin at the same coagulation activity. The retention of camel chymosin in curd was rather constant at ∼20% between pH 6.65 and 6.00, while it increased almost linear from 2 to 21% for bovine chymosin. The lower pH dependence for retention of camel chymosin than of bovine chymosin may be explained by a lower negative charge of the camel chymosin molecule.     

Biochemical properties of pepsinogen and pepsin from the stomach of albacore tuna (Thunnus alalunga)

Pepsinogen (PG) from the stomach of albacore tuna (Thunnus alalunga) was purified to homogeneity by using a series of chromatographies involving Sephacryl S-200HR, Sephadex G-50 and DEAE-cellulose with a 658-fold increase in purity. Based on the native-PAGE and zymography, PG showed a single band with pepsin activity. Molecular weights (MW) of PG and active pepsin were estimated to be 39.9 and 32.7 kDa as determined by SDS–PAGE, respectively. PG was converted to the corresponding pepsin through an intermediate form (MW ≈ 36.8 kDa) and the complete activation was observed after 30–60 min. The N-terminal amino acid sequence of the first 15 amino acids of activation segment of pepsinogen was FHKLPLIKGKTAREE. The optimal pH and temperature for pepsin activity were 2.0 and 50 °C, respectively. The activity was stable in the pH range of 2–5. Residual activity more than 85% was found after heating at temperatures up to 50 °C for 30 min. Pepsin activity was strongly inhibited by pepstatin A, whilst E-64, ethylenediaminetetraacetic acid (EDTA) and soybean trypsin inhibitor exhibited the negligible effect. SDS and cysteine also showed inhibitory effects, whilst ATP, molybdate, NaCl and CaCl₂ had no impact on pepsin activity.     

Regulation of lactate production in Streptococcus bovis: A spiraling effect that contributes to rumen acidosis

When Streptococcus bovis was grown in batch culture with 6 g/L glucose at pH 6.7, maximum specific growth rate was 1.47 h(-1), and lactate was the primary fermentation product. In continuous culture at pH 6.7 and growth rate equal to .10 h(-1), little lactate was formed, and formate, acetate, and ethanol accounted for most of the product. When extra-cellular pH decreased to 4.7, intra-cellular pH declined to 5.4, and organisms switched back to lactate production. Intracellular concentration of fructose 1,6-diphosphate of batch culture cells was greater than 12 mM, a concentration that allowed maximal lactate dehydrogenase activity. When Streptococcus bovis was grown in continuous culture at pH 6.7, intracellular fructose-l,6-diphosphate declined to .4 mM, a concentration which gave little lactate dehydrogenase activity at pH 6.5 or greater. Decreasing pH of continuous culture to 4.7 increased intracellular fructose-1,6-diphosphate concentration to .8 mM. This concentration was still limiting if lactate dehydrogenase was assayed at pH 6.5, but nearly maximal activity was obtained when enzyme was assayed at pH 5.5. The small increase in fructose-l,6-diphosphate and decreased requirement of lactate dehydrogenase for fructose-l,6-diphosphate under acidic assay conditions, accounted for increased lactate production during low pH (4.7) continuous culture. These and other aspects of lactate regulation by Streptococcus bovis are discussed as factors leading to rumen acidosis. This pattern of regulation also helps to explain why rumen acidosis is difficult to reverse.     

混料设计优化牦牛“曲拉”凝乳酶干酪素的工艺及产品的性质分析

为提高牦牛产业的附加值,以牦牛乳提取酥油后进行凝固沉淀,再经自然发酵、风干而成的蛋白质含量丰富的产品“曲拉”为原料,采用胃蛋白酶、木瓜凝乳酶和酵母凝乳酶复配成混合凝乳酶,通过单因素实验和混料设计对凝乳干酪素的制备工艺进行研究,并对干酪素的理化性质、红外光谱特性、热力学性质进行分析。结果表明,混合酶质量分数1%(其中胃蛋白酶∶木瓜凝乳酶∶酵母凝乳酶的质量比为0.60∶0.18∶0.22),在pH 6.3、45℃、添加质量分数CaCl 21%条件下,凝乳30 min,出品率为80.35%。混合酶法制备干酪素的理化性质、红外光谱特性和热力学性质与小牛皱胃酶干酪素差异不显著,而且符合GB31638—2016要求。     

茶多酚对胃蛋白酶的回收以及特性的影响研究

研究从绿茶中提取的茶多酚对胃蛋白酶特性的影响,以及胃蛋白酶与茶多酚络合后进行沉淀回收,茶多酚对胃蛋白酶有起混作用,以及胃蛋白酶和胃蛋白酶与茶多酚形成的络合物在不同茶多酚浓度、温度、pH和底物浓度下的活性变化,结果表明,胃蛋白酶对茶多酚无抑制作用,沉淀回收率较低,只有10.4％,络合后的胃蛋白酶的最适反应温度以及最适pH变化稍微变窄,然而热稳定性以及对底物的亲和力增加。