RU2735230C1 - Method for increasing cicatric digestion in ruminant cattle animals - Google Patents

Abstract

FIELD: agriculture.

SUBSTANCE: present invention relates to agriculture, namely to a method for increasing cicatric digestion in ruminants of cattle, characterized by that in their diet is introduced a composition of plant origin molecules in dosage 4.2 mg/kg of dry substance of ration, where the plant composition of vegetal origin consists of antiarol - 20 wt. %, propyl resorcin - 15.5 wt. %, vanillin - 5.9 wt. %, coniferyl alcohol - 50 wt. %, coumarin - 5.3 wt. %, scopoletin - 3.3 wt. %.

EFFECT: present invention increases intensity of cellulolytic and amylolytic activity processes, increased number of microorganisms participating in fodder digestibility that allows to recommend them as a fodder additive for cattle.

1 cl, 3 tbl

Description

The invention relates to the field of agriculture and can be used in the animal husbandry industry.

In view of the development of new views on the use of the same antibiotic drugs, both in medicine and in animal husbandry, and the subsequent negative impact through food of animal origin on the human body, it forces a new attitude towards their uncontrolled use.

Understanding the current situation prompts the world's leading manufacturers to create an alternative to antibiotics in animal feeding [1]. One of the promising areas of such a search is the development of new solutions for managing the sense of quorum in bacteria [2]. At the same time, the expected advantages of new solutions are the minimization of the effect on the normal flora of the rumen of cattle, as well as the low probability of developing resistance to them in pathogenic microorganisms.

Quorum inhibitory (QSI) compounds have been identified from a wide range of natural resources, in particular medicinal plants, edible herbs, fruits and vegetables [3], and spices [4]. Such antipathogenic compounds, in contrast to antimicrobial agents, are neither bactericidal nor bacteriostatic and do not reduce the risk of developing resistance [5].

Bacterial populations of the ruminant cattle rumen coordinate community behavior through a signaling process mediated by molecules of a diffusing signal [6]. This process controls the expression of genes responsible for a variety of physiological functions, including virulence, antibiotic production, and biofilm formation [7].

Over the past few years, the problem of finding solutions for QS inhibition has been widely developed in studies on eukaryotes [8]. This made it possible to isolate several groups of substances specifically inhibiting QS in reporter strains, including ajoene from garlic, the result was described in patent WO 2012076016, Process for the manufacture of ajoene derivatives, however, the best result was achieved when administered together with antibiotics.

Quercus cortex extract is widely used in animal husbandry, including for partial replacement of antibiotics, it suppresses intestinal microflora, these effects are due to the high anti-QS effects of the extract [9].

In pig breeding, the use of oregano, cinnamon, Mexican pepper, thyme is recommended to suppress pathogenic microflora in the intestine [10] sangrovite, garlic extract containing allicin can increase body weight gain [11] thyme, cloves, eugenol and carvacrol can improve the productivity of pigs [12] ... A known method of improving fermentation in the rumen and suppressing opportunistic microorganisms when introducing a composition based on bitter orange extract into the diet [13]. The disadvantage of this method is the obstacle to the use of the extract - an unstable chemical composition, depending on the conditions of the environment, growth, area. Therefore, we used small molecules of plant origin, isolated from the extract and synthesized artificially. In the experiment, when small molecules of plant origin were included in the diet when growing broiler chickens, the experimental groups did not have pathogenic and opportunistic microflora, and the live weight increased by 20.3% [16].

The use of molecules of plant origin, namely gamma-octalactone, has shown an inhibitory effect on the quorum sensing system of bacteria [14].

The use of coumarin and scopoletin in experiments leads to the suppression of the quorum-dependent formation of LuxI / LuxR type biofilms in bacteria [15].

Analyzing the above, we can say that small molecules of natural origin affect the sense of quorum of microorganisms, therefore they can be used in feeding cattle, to correct cicatricial digestion, thereby contributing to the optimal digestion of nutrients in diets.

In this regard, the task is to use small molecules of plant origin to increase cicatricial digestion by regulating the microbiological composition.

The studies were carried out on the basis of the department of feeding farm animals and feed technology named after V.I. Professor S.G. Leushin Federal State Scientific Institution "Federal Scientific Center for Biological Systems and Agrotechnologies of the Russian Academy of Sciences" (FSC BST RAS).

To solve the set tasks, a series of studies was carried out in several stages. For laboratory research, the following bases were used: Testing Center, laboratory "Agroecology of technogenic nanomaterials" and the Center for Collective Use of the FSC BST RAS. Scientific and economic experiments were carried out at the production site "Pokrovsky Agricultural College-Branch" of the Federal State Budgetary Educational Institution of Higher Education "Orenburg State Agrarian University".

In experimental studies, as anti-quorum substances, a composition of small molecules of plant origin in the form of a white powder was used, consisting of: antiarol - 20%, propylresorcinol - 15.5%, vanillin - 5.9%, coniferyl alcohol - 50%, coumarin - 5.3%, scopoletin - 3.3% [16, 17].

Preparation of the preparation: exact weighed portions of MM RP were dispersed in an isotonic solution by ultrasonic treatment for 15 minutes at a frequency of 35 kHz (f-35 kHz, N-300 W, A-10 μA) in 1 ml of distilled water.

To study the effect of small molecules of plant origin on digestive processes, 2 groups of bulls (n = 3) at the age of 13 months were formed, group I received the main diet, II - the main diet + a composition of small molecules of plant origin at a dose of 4.2 mg / dry matter diet, the preparatory period of 10 days, then were transferred to the conditions of the main accounting period (8 days). At the time of the study, the content was tethered, individual feeding [18]. The collection of scar fluid was performed through a chronic scar fistula 3 and 6 hours after feeding by the in situ method.

Determination of amylolytic activity occurs by means of starch cleavage by the enzyme of bacteria and determination of density on a photoelectrocolorimeter (KFK-2). The analysis was carried out in two stages. The first one before incubation: rumen fluid, starch and phosphate buffer, temperature 40 ° C, were shaken, HCI was added to stop the enzyme reaction. Stained with potassium iodide. The second stage of determination after an hour of incubation, the same manipulations were performed, but under the condition of incubation at a temperature of 40 ± 2 ° C.

Samples were examined on a photocolorimeter against distilled water in 5.0 mm cuvettes, wavelength 590 nm. The amount of starch is found on a calibration graph. Amylolytic activity was found by the formula

X = (A-B) ⋅20,

where X is the amount of starch, split by 1 ml of the contents of the rumen for 1 hour, mg;

A - the amount of starch in the solution before incubation, mg;

B - the amount of starch after incubation, mg;

20 - conversion factor per 1 ml of the contents of the rumen.

Cellulolytic activity was determined according to V.I. Georgievsky (1976). Cicatricial fluid (RF) filtered through gauze in an amount of 250 ml, temperature 40 ± 2 ° C. We select in test tubes with cellophane strips, dried to constant weight - 30 ml of RJ. The tubes were placed in a thermostated water bath at a temperature of 39 ° C for 24 hours; at the end of the time, the strips are rinsed and dried.

Cellelulosolytic activity was determined by the formula

X = A-B / A⋅100,

where X - Cellelulosolytic activity;

A - Weight of the cellophane strip before incubation;

B - Weight of the cellophane strip after incubation.

The taxonomic diversity of microorganisms was determined at the Center for Collective Use "Persistence of Microorganisms" of the Institute of Cellular and Intracellular Symbiosis, Ural Branch of the Russian Academy of Sciences (Orenburg, Russia). For this, 300 ml of scar fluid was taken 3 hours after feeding. The samples were filtered through 4 layers of gauze, the samples of the contents of the rumen were placed in sterile tubes, removed into a cryochamber of the ARKTIKO type t = -80 ° C, followed by isolation of purified DNA preparations.

Isolation of protozoan DNA. After defrosting, 400 μL of the suspension was taken, a mixture of glass beads d = 0.1 and 0.5 mm was added in a volume equal to about 1/3 of the volume of liquid in the test tube. The mixture was homogenized using a Tissue Lyser homogenizer for 3 min at maximum speed. The suspension was incubated at 95 ° C for 10 min, vortexed, and centrifuged for 10 min at 14500 rpm. The supernatant was transferred to a new tube and 200 μl of Binding Matrix solution was added to clean 2.0 ml conical tubes. Transfer the SPIN Filter column to a clean 1.9 ml Catch tube. Added 50 μl of TES. The mixture was stirred to resuspend the matrix, the samples were centrifuged at 14000 rpm for 2 minutes to elute the purified DNA into a clean Catch tube. The taxonomic composition of the rumen content was determined by NGS sequencing on a MiSeq device (Illumina, USA), the classification of microorganisms was determined using sequences using VAMPS and the SILVA reference database (Huse 2014).

The results were processed using the Microsoft Office software package using the Excel software (Microsoft, USA) and Statistica 10.0 software (Stat Soft Inc., USA). The results were considered significant at P≤0.05.

When MM RP is introduced into the diet, the enzymatic activity increases in comparison with the control group.

Cellulolytic activity increased in group II by 8.03% (P≤0.001) after 3 hours of feeding and by 8.23% (P≤0.001) after 6 hours of feeding relative to control (Table 1).

Amylolytic activity in experimental group II was higher than in group I by 7.1% (P≤0.001) after 3 hours and by 6.8% (P≤0.01) 6 hours after feeding in relation to the control (table. 2).

The introduction of MM RP into the diet of animals shifted the established balance of microorganisms towards those responsible for better digestibility of feed, in particular, an increase in the number of Proteobacteria and Firmicutes.

MM RPs contribute to a decrease in the number of opportunistic microorganisms, so in the experimental groups the number of Streptococcaceae decreases relative to the control, which indicates the inhibitory effect of the experimental additive. In experimental group II, pathogenic microorganisms are absent, and in the control group, the level of pathogenic microorganisms does not exceed 0.1% of the total number of bacteria. Rumen microorganisms play an important role in meeting the energy needs of an animal by transforming organic compounds in the feed to obtain useful energy (Table 3).

Thus, the introduction of the drug into the diet in the form of small molecules of plant origin is accompanied by an increase in the intensity of the processes of cellulolytic and amylolytic activity, an increase in the number of microorganisms involved in the digestibility of feed, which makes it possible to recommend them as a feed additive for ruminants of cattle.

Literature

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Claims (1)

A method for increasing cicatricial digestion in ruminants of cattle, characterized by the fact that a composition of plant molecules is introduced into their diet at a dosage of 4.2 mg / kg of dry matter of the diet, where the composition of plant molecules consists of antiarol - 20 wt%, propylresorcinol - 15.5 wt.%, Vanillin - 5.9 wt.%, Coniferyl alcohol - 50 wt.%, Coumarin - 5.3 wt.%, Scopoletin - 3.3 wt.%.