[Proteases for obtaining of food protein hydrolysates from proteinaceous by-products].

Due to the increasing shortage of food protein in the world, the most effective and complete use of proteinaceous substrates is an urgent task. The most promising way to utilize secondary protein-containing raw materials is to increase its nutritional value through enzymatic hydrolysis. The use of protein hydrolysates obtained from protein-containing by-products has great potential in various areas of the food industry, as well as in the production of foods for medical and special dietary uses. The aim of the research was to propose optimal methods for processing protein substrates to obtain hydrolysates with desired properties, taking into account the characteristics of the main types of proteinaceous by-products and the specificity of proteases used. Material and methods. We used the data contained in PubMed, WoS, Scopus, and eLIBRARY.RU databases, which meet the requirements of scientific reliability and completeness. Results. Collagen-containing wastes from the meat, poultry and fish processing industries, whey, soy protein and gluten are the main types of protein-containing by-products successfully used to produce food and functional hydrolysates. The molecular structure, basic biological and physico-chemical properties of collagen, whey proteins, various protein fractions of wheat gluten and soy protein are described. The expediency of enzymatic treatment of protein-containing by-products using proteases is shown to reduce antigenicity and eliminate anti-nutritional properties, improve nutritional, functional, organoleptic and bioactive properties for subsequent use in food production, including those for medical and special dietary uses. Information is presented on the classification of proteolytic enzymes, their main properties, and the effectiveness of their use in the processing of various types of proteinaceous by-products. Conclusion. Based on the literature data analysis, the most promising methods for obtaining food protein hydrolysates from secondary protein-containing raw materials are proposed, including pretreatment of substrates and the selection of proteolytic enzymes with a certain specificity.

[Efficiency of an enzyme preparation obtained from a new mutant Bacillus subtilis-96 strain in the hydrolysis of whey and egg white proteins].

Whey and hen egg white proteins are characterized by high nutritional value, but possess antigenic properties, which limit their use in the production of dietary products. Enzymatic hydrolysis decreases significantly the allergenicity of proteins. The efficiency of hydrolysis depends on the specificity of the proteases used. The aim of this work was to determine the effectiveness of EP-96 enzyme preparation obtained from Bacillus subtilis-96 culture liquid in the hydrolysis of whey and egg white proteins in comparison with commercial bacterial proteases preparations - Alcalase, Neutrase, and Protosubtilin. Material and methods. Whey and egg white protein concentrates were used as substrates. Commercial enzyme preparations Alcalase, Neutrase, and Protosubtilin, and an experimental sample of EP-96 preparation obtained from Bacillus subtilis-96 culture liquid were used for hydrolysis. Hydrolysis was carried out at a substrate concentration of 100 g/L for 3 h at 55 °C or for 24 h at 50 °C. After hydrolysis, the reaction mixture was incubated at 90 °C for 15 min to inactivate the enzymes. The content of peptides with a molecular weight of less than 10 kDa was determined in the obtained hydrolysates. The hydrolysis of the main allergenic proteins was assessed by the disappearance of the corresponding protein bands on the hydrolysate supernatants electrophoregrams. Results and discussion. All the studied preparations showed high efficiency in the hydrolysis of whey proteins and provided the yield of low molecular weight peptides at the level of 18.8-22.8% after 3 h of hydrolysis and 39.4-41.6% after 24 h. Sodium dodecyl sulfate polyacrylamide gel electrophoresis showed a residual amount of protein with a molecular weight of about 14 kDa, corresponding to α-lactoalbumin, after 3 h of hydrolysis when using Neutrase. The preparations containing serine protease, including EP-96, provided more intensive hydrolysis of whey proteins. In the hydrolysis of egg white protein, Neutrase showed the greatest efficiency. The efficiency of EP-96 was comparable to Neutrase both in the yield of low molecular weight peptides and in the intensity of cleavage of the main allergenic proteins. The effectiveness of preparations with predominant content of serine proteases - Alcalase and Protosubtilin was significantly lower. Conclusion. The optimal ratio of neutral and serine proteases in the EP-96, obtained on the basis of the B. subtilis-96 strain, provided the high efficiency and its versatility in the hydrolysis of the main allergenic proteins of whey and egg white. The parameters of the hydrolysis technology using EP-96 are recommended, which provide intensive conversion of the main immunogenic proteins of whey and egg white to soluble and low molecular weight fractions (duration 3 h at a temperature of 55 °C and the proteolytic activity of the preparation is not less than 2 units per g of substrate) and an increase of subsequent ultrafiltration efficiency in the production of protein hydrolysates for foods for special dietary uses.

Creation of Chitinase Producer and Disruption of Micromycete Cell Wall with the Obtained Enzyme Preparation.

A recombinant strain producing a complex of extracellular enzymes including chitinase from Myceliophtora thermophila was created based on the fungus Penicillium verruculosum. The activity of the enzyme preparations obtained from the cultural fluid of the producer strain was 0.55, 0.53, and 0.66 U/mg protein with chitin and chitosans with the molecular weight of 200 and 1000 kDa, respectively. The temperature optimum for the recombinant chitinase was 52-65°C; the pH optimum was 4.5-6.2, which corresponded to the published data for this class of the enzymes. The content of heterologous chitinase in the obtained enzyme preparations was 47% of total protein content in the cultural fluid. Enzyme preparations produced by the recombinant P. verruculosum XT403 strain and containing heterologous chitinase were able to degrade the mycelium of micromycetes, including phytopathogenic ones, and were very efficient in the bioconversion of microbiological industry waste.

A New Bacillus licheniformis Mutant Strain Producing Serine Protease Efficient for Hvdrolvqis of Sov Meal Proteins.

Induced mutagenesis with y-irradiation of the industrial strain Bacillus licheniformis-60 VKM B-2366,D was used to obtain a new highly active producer of an extracellular serine protease, Bacillus licheni- formis7 145. Samples of dry.concentrated preparations of serine protease produced by the original and mutant strains were obtained, and identity of their protein composition was'established. Alkaline serine protease sub- tilisin DY was the main component of the preparations. The biochemical and physicochemical properties of the Protolkheterm-145 enzyme preparation obtained from the mutant strain were studied. It exhibited pro- teolytic activity (1.5 times higher than the preparation from the initial strain) within broad ranges of pH (5- 11) and temperature (30-70'C).-Efficient hydrolysis of extruded soy meal protein at high concentrations (2 to 50%) in-the reaction mixture was.the main advantage of the Protolikheterm 145 preparation. Compared to,. the preparation obtained using the initial strain, the new preparation with increased proteolytic-activity pro- vided for more complete hydrolysis of the main non-nutritious soy,proteins.(glycinin and 0-conglycinin) with the yield of soluble protein increased by 19-28%, which decreased the cost of bioconversion of the protein- aceous material and indicated promise of the new preparation in resource-saving technologies for processing soy meals and cakes.

[A New Enzyme Preparation with High Penicillopepsin Activity Based on the Producer Strain Penicillium canescens].

The producer of fungal penicillopepsin, an aspartate protease, has been created by genetic engineering. The biochemical and physicochemical properties of the penicillopepsin enzyme preparation obtained from the culture liquid of the producer were studied. Properties of the new enzyme preparation and the commercially available aspergillopepsin were compared. Their proteolytic activities were found to be 670-680 U/g of the preparation. The soluble protein yield upon the wheat flour hydrolysis with penicillopepsin was 2.7 times higher than with aspergillopepsin. It is probably caused by the presence of the xylanase activity in the penicillopepsin preparation.

[Creation of a heterologous gene expression system on the basis of Aspergillus awamori recombinant strain].

A heterologous gene expression system was created in a domestic Aspergillus awamori Co-6804 strain, which is a producer of the glucoamylase gene. Vector pGa was prepared using promoter and terminator areas of the glucoamylase gene, and A. niger phytase, Trichoderma reesei endoglucanase, and Penicillium canescens xylanase genes were then cloned into pGa vector. Separation of enzyme samples using FPLC showed the amount of the recombinant proteins to be within the 0.6-14% range of total protein.

[Increase in glucoamylase productivity of Aspergillus awamori strain by combination of radiating mutagenesis and plasmid transformation methods].

Increase in the level of amylolytic genes activator protein encoded by amyR gene was shown to result in enhancement of glucoamylase productivity of A. awamori strain by 30%. However, the same effect equal to 30% increase can be achieved by introduction of extra copies of gla gene encoding glucoamylase. These two effects were not additive, which gave the possibility to suggest an additional limitation in the egulation mechanism of glucoamylase gene expression in Aspergillus family strains while introducing an additional copies of amyR and gla genes.