RU2595428C1 - Method of selecting prepotent (terminal) boars for hybridisation of pigs - Google Patents

Abstract

FIELD: agriculture.

SUBSTANCE: invention relates to animal science and may be used when growing, selecting and hybridising pigs. Method of selecting prepotent (terminal) boars for hybridisation of pigs Sys scrofa includes blood sampling in boars and pigs with live weight of 100 kg, detecting presence of complete set of erythrocyte antigens when testing pigs on blood groups and detecting swine genotype on all loci and determining genetic similarity of boars and pigs on tests of blood groups. In boars and pigs based on blood group tests, genetic similarity is calculated, selecting a pair of pigs and boars with high genetic similarity, estimating at phenotype class elite, upon reaching breeding age (8-9 months) performing registered mating of boars and sows with high genetic similarity (from 0.8 to 0.9) to produce high-homozygous (propotent) offspring. For local systems of hybridisation in order to obtain a high heterosis effect, boars with homozygosity of 0.8 are selected.

EFFECT: present method enables to obtain prepotent boars, which increase productivity of offspring during hybridisation.

1 cl, 5 tbl, 1 ex

Description

The invention relates to agriculture, in particular to livestock, can be used in growing, breeding pigs and hybridization.

There is a method of identifying high productivity of the offspring of pig producers, assigned to the group of prepotent "similar"; having a high similarity of the reproductive and somatic systems with offspring [4]. The method consists in laboratory histological studies of somatic cells of fathers, assigned to the group of "similar". The disadvantage of this method is its low efficiency due to the complexity of its implementation. The method is more theoretical than practical.

Closest to the technological essence of the proposed method is a method for predicting the prepotency of boars determined by their genotypes of blood groups of all known loci [3], including taking blood from boars at 3 months of age, determining in it the presence of a complete set of red blood cell antigens when testing pigs according to blood groups and identification of the genotype of pigs at all loci. Then, according to the tests of blood groups, the level of homozygosity of the boars is calculated according to the formula:

, где

where

I _g - level of homozygosity;

To _g is the number of homozygous genes;

N is the total number of genes.

Upon reaching a live weight of 100 kg, according to the "Procedure and conditions for the scoring of pedigree pigs", repair grunts are evaluated according to their own productivity. Calculate the age of reaching a live weight of 100 kg, the thickness of the fat over 6-7 thoracic vertebrae and the length of the body, determine the rating class.

Based on the analysis of the genetic status of the boars and the rating class for their own productivity, they make a prediction of the breeding value of the boars by the level of homozygosity. Boars with a homozygosity of 0.8 and an elite class of 100 kg in their own productivity will steadily transmit their productive qualities to offspring.

The disadvantage of this method is the lack of technology for producing highly homozygous boars (descendants) by the selection method.

The purpose of the invention is to improve the accuracy of evaluation of the prepotency of boars and increase the effect of heterosis in hybridization.

This goal is achieved by obtaining by the method of selection (custom mating) boars with high homozygosity (prepotent).

The essence of the method consists in obtaining prepotent boars and their evaluation on prepotency and increasing the effect of heterosis during hybridization.

The proposed method allows to obtain prepotent boars by the selection method, which will increase the productivity of their offspring during hybridization.

The method is as follows: in pigs and boars with a live weight of 100 kg, evaluated by in vivo assessment by the elite class, blood is taken, the presence of a complete set of erythrocyte antigens is determined in it when testing pigs by blood groups according to the method [1], and the pig genotype is detected at all loci . Then, the genotypes of blood groups of boars and pigs are compared for each studied locus and the coefficient of genetic similarity is calculated by the formula [2]:

where P ₁ , P ₂ - the frequency of alleles in the compared groups of animals;

r _E is the coefficient of genetic similarity.

In the first pair of ten studied loci in four (E, G, K, L), differences in the genotypes of blood groups between the grist and the pig are observed. We calculate the frequency of occurrence of alleles at boars (P ₁₎ and pig (P ₂₎ according to claims define the correlation coefficient in one locus. The similarity index between a pig and a pig for several genetic systems is calculated by multiplying the correlation coefficients for each individual blood group system:

Calculation is also carried out for other pairs (table. 1).

Then, pairs (future parents) of boars (X _gc ) and pigs (C _gc ) with high genetic similarity (0.8-0.9) are selected and, when they reach a random age (8-9 months), they are mated, in which offspring are obtained - prepotent boars with homozygosity 0.8 (table. 2).

To assess the genetic status of boars at 3 months of age, blood is taken and blood groups are determined. The blood groups of boars are determined according to generally accepted methods for setting the reaction of direct agglutination and hemolysis according to 10 main systems of blood groups: A, B, D, E, F, G, H, K, L, M. According to blood group tests, the level of homozygosity of boars is calculated (table . 2).

, где

where

_G - the level of homozygosity;

To _g is the number of homozygous genes;

N is the total number of genotypes.

Calculation example for the pig Parnas 3471:

Y _r = 8/10 = 0.8;

For the boar Perseus 5597:

Y _r = 3/10 = 0.3.

The age of reaching 100 kg is calculated, the thickness of the fat over 6–7 thoracic vertebrae and the length of the body are measured, and the valuation class is determined (Table 3).

Based on the analysis of the genetic status of the boars and the rating class for their own productivity, they make a prediction of the breeding value of the boars. According to the results of the evaluation of the boars (Table 3), the Parnas 3471 boar with a homozygosity of 0.8 and an elite class of 100 kg in its own productivity will persistently transmit its heredity, which allows us to recommend a selection method for obtaining prepotent (terminal) boars to increase the effect of heterosis (I _d >) during hybridization.

The invention is illustrated by the following example.

Example 1

When developing a local hybridization system at ABSOLUT-AGRO LLC, Kirov Region, in order to grow highly productive prepotent (terminal) boars of Duroc breeds to obtain high heterosis at the final stage in the hybridization system for 100 heads of pigs and 20 heads of boars per 100 kg, evaluated on their own productivity class elite according to the "Procedure and conditions for the scoring of breeding pigs" (2009), blood was taken. According to tests of blood groups in pigs and pigs, the genetic similarity between pigs and boars was calculated by a known method. Then pairs of boars and pigs (future parents) with high genetic similarity (from 0.8 to 0.9) were selected and, upon reaching a random age (8-9 months), they ordered mating. Grubs obtained from custom mating were tested at 3 months of age by blood group. Upon reaching a live weight of 100 kg in accordance with the "Procedure and conditions for the scoring of breeding pigs" (2009), an assessment was made of repair grunts.

Then, according to the results of testing blood groups and evaluating the boars by their own productivity, the boars with high, medium, low homozygosity (0.8; 0.6; 0.3) and the elite class according to intravital assessment were selected. After reaching a boar of a random age (8–9 months), they were observed with sows of the maternal form F1 - (JL) (Table 4).

The analysis of the given factual data as a result of the experiment (Table 4) showed that, as the homozygosity of the second paternal boars (D) decreases when they are crossed with the two-linear maternal form (JL), fattening and meat qualities decrease in comparison with the maternal form.

The highest actual data (the age at which live weight of 100 kg is reached is 12 days higher (P <0.001), feed consumption per 1 kg of growth is less than 0.21 kg (P <0.001), the fat thickness is less by 3.5 mm (P < 0.001), eye muscle area over 10cm ² (P <0.001)) observed in combination bilinear mother form (YhL) with vysokogomozigotnym boar (0.8) Duroc breeds (D).

The effect of heterosis (I _g ) of fattening and meat qualities of young trilinear cross-country (JL) xD in relation to the parent maternal form (JL) was also the highest in combination (JL) xD with boar homozygosity (D) - 0.8 (Table. 5).

Thus, the boar (D) with a homozygosity of 0.8 is prepotent (terminal), it steadily transfers its heredity in feeding and meat qualities, increasing the effect of heterosis (I _g >) during hybridization.

Based on the results obtained, it is proposed to use prepotent (terminal) boars with high homozygosity - 0.8 in the local hybridization system of ABSOLUT-AGRO LLC, Kirov Region, to increase the heterosis effect in feeding and meat qualities.

Information sources

1. Bezenko S.P. Guidelines for determining the origin of pigs based on the analysis of the study of antigens of red blood cells. - 1974

2. Rozhkov Yu.I., Pronyaev A.V., Ohapkin S.K. The formula for genetic similarity between different groups of animals. - 1992

3. Suslina E.N., Beltyukova A.Yu. Guidelines for predicting prepotency of boars-producers at an early age. - 2011 - p. 6-7.

4. Chamukha M. D., Goncharenko G. M., Kabantsev A. I. The use of immunobiological indicators in predicting the prepotency of producers / Problems of stabilization and development of agriculture in Kazakhstan, Siberia and Mongolia. - Novosibirsk. - 2000 .-- S. 146-147.

Claims (2)

1. A method of breeding prepotent (terminal) boars for hybridization of Sys scrofa pigs, including taking blood from boars and pigs with a live weight of 100 kg, determining the presence of a complete set of red blood cells antigens when testing pigs by blood groups and identifying the genotype of pigs at all loci, determination of the genetic similarity of boars and pigs according to blood group tests, characterized in that for boars and pigs (future parents), genetic similarities are calculated from blood group tests, pairs of pigs and boars with high genetic In order to achieve random age (8–9 months), mating of boars and sows with high genetic similarity (from 0.8 to 0.9) is obtained by highly similar resemblance, assessed by phenotype as an elite class, and highly homozygous (prepotent) offspring are obtained for local systems hybridization in order to obtain an increased effect of heterosis selected boars with homozygosity of 0.8. 2. The method according to p. 1, characterized in that highly homozygous boars (prepotent), which increase the effect of heterosis when crossed, are obtained by the selective method of mating of boars and sows with high genetic similarity (from 0.8 to 0.9)
I _g > = C _gcx × X _gcx = Px _go , where
I _g > = increased effect of heterosis in hybridization;
C _gh × X _gh - the parent pair of sows × boars with high genetic similarities from 0.8 to 0.9;
Px _go - offspring - prepotent pig with homozygosity 0.8.