RU2022013C1 - Method for producing pectinesterase - Google Patents

Abstract

FIELD: biotechnology. SUBSTANCE: method involves treating the solution of complex pectolytic ferment preparation in cathode space of diaphragm electrolyzer at a current density of 0,05-30,00 mА/cm² to pH 10.5-11.5, holding out, separation of sediment, bringing pH to 4.5-5.5 and extracting the target product. Solution of complex pectolytic ferment preparation is treated with aqueous solution of sodium salt of inorganic acid in a concentration of 0.3-2.0% . In above-mentioned pH interval the pectinesterase is stable and its yield is 56-67%. EFFECT: method ensures removal of alkali-labial proteins including polygalacturonasa with maximum preservation of pectinesterase in solution. 3 tbl

Description

 The invention relates to biotechnology, namely the production of a purified enzyme pectin esterase (PE), used in the confectionery industry in the production of low-calorie products.

 The purpose of the invention is to increase the yield of PE.

The method consists in processing a solution of a complex pectolytic enzyme preparation in the cathode space of a diaphragm electrolyzer at a current density of 0.05-30.00 mA / cm ² until reaching a pH of 10.5-11.5, aging, separating the precipitate, adjusting the pH to 4 5-5.5 and the selection of the target product, moreover, against the solution of the complex pectolytic enzyme preparation, an aqueous solution of the sodium salt of an inorganic acid in a concentration of 0.3-2.0% is used.

 Processing a complex pectolytic enzyme preparation by changing the pH to 10.5-11.5 is carried out to inactivate and precipitate the polygalacturonase (PG) present in the preparation. The application of a constant electric current ensures a uniform pH shift of the enzyme solution throughout the entire volume, a change in the charge of the proteins, their aggregation and precipitation, which ensures the removal of alkaline labile proteins, including PG, with maximum PE storage in solution.

 In the indicated range, the pH of PE is stable, and its yield is 56-67%.

 At a pH below 10.5, the level of GHG activity does not meet the requirements of the consumer for the enzyme preparation PE, since the GHG content significantly exceeds the value of 0.5%.

 At a pH above 11.5, the degree of inactivation of PE in solution increases compared to pH 10.5–11.5, and thus the yield of PE in the final preparation decreases.

The choice of current density from 0.05 to 30 m A / cm ^{2 is} necessary so that the PE in the solution is preserved in the active state. Thus no change of structure of the protein molecule, the process goes uniformly, and the enzyme solution temperature does not exceed ^{35 °} C, e.g. lies in the zone of thermal stability of PE.

A decrease in current density of less than 0.05 m A / cm ² leads to a slowdown or termination of electrolysis, and either the desired pH value cannot be achieved at all, or is achieved due to a significant increase in the duration of the process by several times, which entails a drop in PE activity in processing process and becomes economically impractical.

An increase in current density above 30 m A / cm ² leads to a too rapid change in pH. In addition to ballast proteins, PE precipitates, and the enzyme yield decreases. In addition, due to the high current strength, the enzyme solution overheats, which leads to additional inactivation of PE.

 To carry out the process of electrochemical processing of an enzyme solution with a pH shift of 10.5–11.5, it is necessary to conduct the process so that electrolysis is carried out against a solution of inorganic acid salts at a concentration of 0.3–2.0%. When the salt concentration is below 0.3%, the processes of electrolytic changes in the pH of the enzyme solution either sharply slow down or do not go at all. With an increase in salt concentration above 2.0%, the consumption of reagents unreasonably increases, and an increased amount of gases is released into the atmosphere.

 A solution containing a complex of pectolytic enzymes from which PE is isolated is prepared by extraction of a surface culture containing pectolytic enzymes, or by dissolving the finished enzyme preparations obtained by surface or deep cultivation, or directly using the culture fluid obtained after separation of the biomass.

The initial enzyme solution is placed in the cathode chamber of the diaphragm electrolyzer. A solution of an inorganic acid salt with a mass concentration of 0.3-2.0% is poured into the anode chamber, which provides a shift in the pH of the enzyme solution to the alkaline zone and the flow of current with a density of 0.05-30.00 mA / cm ² . During electrolytic processing of the enzyme solution, the pH of the enzyme solution is shifted to the alkaline zone, and the process of electric processing is stopped when the pH reaches 10.5-11.5. The treated enzyme solution is kept at a temperature of ^about 4-35 / C (optimum 25-30 ^{° C)} for 0.5-4.0 hours (optimally 1.5-2.5 h), and the formed precipitate is removed by centrifugation or filtration. The filtrate, practically free of PG, is acidified with hydrochloric acid to a pH of 4.5-5.5 and PE is isolated from the solution in a known manner.

Example 1. In the cathode chamber of a diaphragm electrolyzer, an aqueous extract of a surface culture of Aspergillus foetidus M-45 is poured, a 0.3% aqueous NaCl solution is poured into the anode chamber, and a constant electric current of 1.5 mA / cm ^{2 is} supplied . After 4 minutes the pH of the enzyme solution reaches 10.5, and electrolytic processing is stopped, the enzyme solution is drained from the chamber, maintained at 35 ^{° C} for 0.5 hours, the resulting precipitate was removed by centrifugation and the supernatant pH adjusted to 5.5 with a solution of Hcl. After processing the content
PE = 5.3 u / ml
PG = 620 units / ml.

PE yield = 67.2%,
GH = 0.32%,
residual GHG = 28%.

 The value of residual GHG characterizes a change in the relative viscosity of a 1% pectin solution under the influence of possible traces of the GHG complex and should vary in high-quality PE preparations in the range from 0 to 40%.

PRI me R 2. Into the cathode chamber of a diaphragm electrolyzer pour water extract of the surface culture of A. foetidus M-45, and the anode chamber is filled with a 2.0% aqueous solution of NaCl and direct current with a density of 0.5 mA / cm ² . After 60 minutes, the pH of the enzyme solution reaches 11.5, and the solution is drained. Then it was allowed to stand at ⁴ ° C for 4 hours and the formed precipitate was separated by filtration, the filtrate was adjusted pH 4.5 with HCl. After processing the content
PE = 4.6 u / ml
PG = 490 u / ml.

PE yield = 57.1%,
GH = 0.06%,
residual GHG = 10%
The resulting preparation is of high quality.

PRI me R 3. For electrolytic treatment using an aqueous extract of the surface culture of A. foetidus and process it similarly to the method described in example 1, but as anolyte using a 1% solution of NaCl. The electrolytic treatment process is carried out with a current density of 10.0 mA / cm ² and stop it when the pH reaches 11.0. Before separating the precipitate solution was kept at ²⁵ ° C for 1.5 h and the pH was adjusted with HCl to pH 4.8.

After processing the content
PE = 5.5 u / ml
GH = 480 units / ml.

PE yield = 62.7%,
GH = 0.01%
residual GHG = 6%.

 The resulting preparation is of high quality.

 In the table. 1 shows data where, as a solution of a complex pectolytic enzyme preparation, a solution of Pectofoetidin P10x isolated from a surface culture of A.foetidus fungus is used.

 In the table. Figure 2 presents data where, as a solution of a complex enzyme preparation, the culture fluid obtained by deep cultivation of A. Joetidus, a producer of pectolytic enzymes, is used.

 Table 3 presents data where a solution of Pectofoetidin Gxx is used as a complex pectolytic enzyme preparation.

 As can be seen from the data described in the examples and given in tables 1-3, the proposed method for producing PE with trace amounts of GHG can be used for all types of complex enzyme solutions.

 Using the method allows to increase the yield of PE to 56-67%, to stabilize the output of the enzyme from the solution of the complex pectolytic enzyme preparation and thus provide a more uniform composition of the final preparation; reduce the cost of the process by reducing the consumption of alkali, using an economically cheaper and more environmentally friendly process of electrolytic treatment, which in turn leads to a reduction in industrial effluents and a reduction in the cost of their treatment; the use of the enzyme preparation PE in the confectionery industry provides a significant reduction in the cost of production; processing highly methoxylated citrus pectin used in the preparation of marmalade, PE allows you to get pectin, which gels products to the desired consistency in the presence of less sugar. Reducing the consumption of the latter in marmalades reaches 50%, and, accordingly, provides significant savings in sugar, cheaper marmalade. Low-calorie, less sweet confectionery products are intended for a wide range of consumers in accordance with the recommendations of the Institute of Nutrition. This is an additional prevention against obesity; in addition, the production of PE according to the proposed method can be made closed, waste-free, environmentally friendly, if an electroactivated salt solution having a pH of 1.1-1.5 is used to treat difficult-hydrolyzable raw materials, which are usually carried out in the preparation of culture media for the cultivation of microorganisms on the same microbiological industries.

Claims (1)

METHOD FOR PRODUCING PECTINESTERASE, which involves treating a solution of a complex pectolytic enzyme preparation to an alkaline pH, keeping it, separating the precipitate, adjusting the pH of the solution to 4.5-5.5 and isolating the target product, characterized in that, in order to increase the yield of the target product, processing complex pectolytic enzyme preparation is carried out in the cathode compartment of a diaphragm electrolytic cell at a current density of 0.05 - 30.00 mA / cm ² versus the aqueous solution of the sodium salt of an inorganic acid in conc ntratsii 0.3 - 2.0%.

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