RU2366170C1 - Method of cattle selection by meat productivity - Google Patents

Abstract

FIELD: agriculture.

SUBSTANCE: method involves blood research for 20-days old animals to detect the presence of erythrocytic marker antigens of two types: high growth energy antigens B₂, G₂, I', O', Q', V, H", and low growth energy antigens Q, T₁, S₁. Animals with high growth energy markers present in genotype or prevailing over low growth energy markers are selected.

EFFECT: improved posterity meat productivity by 5,8-9,4%.

Description

The invention relates to the field of agriculture and, in particular, to the selection and genetics of cattle.

The increase in livestock production should be carried out through intensification, the basis of which is breeding and breeding. Improving existing and creating new breeds, types and lines of dairy and beef cattle with high meat productivity is one of the most important selection tasks at the present stage.

In order to accelerate selection, along with its traditional methods, it is necessary to use new genetic methods that can significantly increase the level of effectiveness of the breeding work. The proposed method is based on the use of red blood cell antigens. Antigens are passed from parents to descendants as hereditary units. The synthesis of each antigen is determined by the action of one gene (I. Matoushek, 1964; V.N. Tikhonov, 1967; O.A. Ivanova, 1967, 1974; E.K. Merkuryeva, Z.A. Abramova, A.V. Bakay, I.I. Kochish, 1991).

In this regard, erythrocyte antigens and their certain complexes represent elements of the genotype that determine the characteristics of the organism, including those associated with its productive qualities. Analysis of red blood cell antigens allows us to judge the degree of participation of the heredity of the father, mother and more distant ancestors in the formation of the offspring genotype. Based on this, we investigated their breeding importance as markers of the genotype in the study of the inheritance of economically useful qualities, assessing the genotype of individual animals and identifying the effectiveness of genetic combinations.

The main object of experimental research was the purebred Simmental flock of the OPKh pedigree plant of the Kursk Research Institute of Agricultural Production, numbering 350 cows (about 80% of the animals belong to the elite record class). Its annual productivity over the past 10 years in full-age cows has reached 4040 kg of milk with 3.9% fat.

The research material was documents of zootechnical and pedigree accounting. In addition, immunological cards were used for genetic certification of breeding animals compiled on the basis of a blood test in the immunogenetics laboratories of the Kharkov Institute of Livestock, Ukrainian Academy of Agricultural Sciences and the All-Russian State Research Institute of Livestock.

Studies were conducted on heifers of Simmental breed. To identify the genotype of heifers, differing in live weight by 18 months of age, the animals were divided into two groups. The first group included heifers with a live weight of 350 kg and above by random age (72 heads with an average live weight of 373 kg). The second group included heifers with a live weight of less than 350 kg by this age (84 heads with an average live weight of 319 kg). As a result of our studies, we revealed differences in the frequency of occurrence of antigens in these groups of heifers (Table 1). So, if the frequency of occurrence of antigens B ₂ , G ₂ , P ₂ , I ', O', P ', Q', B '', V, H '', U in the first group of heifers was increased by 0.024-0.225, or 1.32-2.26 times more often, then the antigens I ₁ , I ₂ , Q, T ₁ , B ', D', J ₂ ', X ₁ , S ₁ , U', U '' are reduced by 0.020- 0.134 or 1.35-2.46 times less often. For the remaining 26 antigens, the incidence rates in these groups were approximately the same.

In zootechnology, the question of the reliability (materiality) of differences plays an important role. The significance of the difference means that the difference between the sample indicators entails differences between the corresponding general indicators. If it turned out that the difference is unreliable, it only means that conclusions about the difference in sample indicators cannot be transferred to general indicators, because they can either differ or coincide. An assessment of the reliability of differences in sample means by the method of Strygina S.O., Dementieva S.N. and Alifanova V.V. (2008) showed that the significance of differences in the frequency of occurrence of detected antigens is reliable only for seven antigens - B ₂ , G ₂ , I ', O', Q ', V, H'', which are more common in the group of heifers intensively growing, and for three antigens - Q, T ₁ , S ₁ in the genotype of heifers with reduced growth energy.

Table 1
The frequency of occurrence of antigens in heifers with different live weight at the age of 18 months Increased frequency of antigens in group I Reduced frequency of antigens in group I antigens frequency difference I-II antigens frequency difference I-II B ₂ 0.389 0.115 ** I ₁ 0.097 -0.034 G ₂ 0.347 0.085 * I ₂ 0.069 -0.074 P ₂ 0.181 0.050 Q 0.097 -0.141 *** I ' 0.486 0.129 *** T ₁ 0.167 -0.095 * O ' 0.292 0.090 * B ' 0.069 -0.050 P ' 0.097 0.049 D ' 0.069 -0.050 Q ' 0.667 0.167 *** J ₂ ' 0.055 -0.028 B '' 0.125 0.054 X ₁ 0.042 -0.053 V 0.403 0.225 **** S ₁ 0.152 -0.134 *** H '' 0.222 0.103 ** U ' 0.028 -0.020 U 0.083 0.024 U '' - -0.024 Note: reliability * at P> 0.90; ** at P> 0.95; *** at P> 0.99; **** at P> 0.999.

Thus, the performed mathematical analysis gives grounds to consider the antigens B ₂ , G ₂ , I ', O', Q ', V, H''markers of increased growth energy, and the antigens Q, T ₁ , S ₁ - markers of reduced growth energy. The previously identified differences in antigens P ₂ , P ', B'', U and I ₁ , I ₂ , B', D ', J ₂ ', X ₁ , U ', U''are not significant due to their low the frequency of occurrence in the animal genotype (0.020-0.181) and there are no good reasons to consider them as markers of growth energy.

Subsequently, we analyzed the live weight of heifers by 18 months of age, depending on the presence and ratio of antigenic markers in their genotype (Table 2).

table 2
The live weight of heifers of different genotypes at the age of 18 months, depending on the presence and ratio of antigenic markers in their genotype Groups The presence and ratio in the genotype of heifers of antigen markers,% Goals Live weight increased growth energy low growth energy average kg including heifers with a live weight of 350 kg or more,% one one hundred 0 thirty 361.2 70.0 2 0 one hundred 16 330.2 6.2 3 73.1 26.9 56 349.5 55.3 four 50,0 50,0 19 337.6 26.3 5 34.0 66.0 26 329.3 30.8

The first group included heifers (30 animals), in the genotype of which there were only markers of increased growth energy (100%), the second group included animals, in the genotype of which there were only markers of reduced growth energy, and groups 3-5 included animals with different the ratio in the genotype of antigen markers of increased and decreased growth energy.

The data in table 2 indicate that the highest live weight - 361.2 kg by 18 months of age was in heifers whose genotype contained only antigens-markers of increased growth energy (group 1). The heifers, in the genotype of which there were only markers of reduced growth energy (group 2) or markers of reduced growth energy, prevailed over markers of increased growth energy (group 5), had the smallest live weight, respectively - 329.3 and 330.2 kg. They are inferior in live weight to heifers of the 1st group by 31.0-31.9 kg (the difference is significant at P> 0.999). The heifers of the third group, in the genotype of which the markers of increased growth energy 2.7 times prevailed over the markers of reduced growth energy, were 11.7 kg inferior to the animals of group I in terms of live weight, but exceeded the heifers of groups 2 and 5 by 19.3-20.2 kg (the difference is significant at P> 0.99).

With an equal ratio in the genotype of animal markers of increased and decreased growth energy (4th group of animals), the live weight of heifers was only 7.4-8.2 kg higher than the 2nd and 5th groups of heifers.

Analyzing the live weight of heifers of various genotypes, it should also be noted that in the 1st group, 70% of the heifers had a live weight of 350 kg or more by the age of 18 months, in the second group of such animals there were only 6.2%, that is, 11.3 times less. Among heifers with different ratios in the genotype of growth energy markers, the largest number of heifers with a live weight of 350 kg and more by the age of 18 months was in the third group (55.3%), which is 24.5% more than in the fifth and 29.0% more than in the fourth group.

As a result of further studies, it was revealed that the growth energy in heifers depends on the number of markers in their genotype. The heifers, in the genotype of which there were two antigen markers of increased growth energy, had a live weight of 342 kg by the age of 18 months, three - 356 kg, four or more - 375 kg. In this case, the correlation coefficient between the number of marker antigens in heifers genotype and their live weight was 0.319 ± 0.164 (P> 0.90).

An example of the method

The sampling procedure for determining erythrocyte antigens in cattle is as follows. From the jugular vein of an animal, starting from 20 days of age, 10-15 ml of blood is taken into a test tube and, to prevent blood clotting, 3 ml of preservative is added. The preservative is prepared as follows: 5 g of glucose, 15 g of sodium citrate and 1 g of streptomycin are dissolved in 500 ml of distilled water.

The collected blood samples are stored for no more than a day in the refrigerator, and then transported to the laboratory in a thermos, at the bottom of which there are pieces of ice.

The determination of erythrocyte antigens is carried out according to the generally accepted method of P.F.

Modern methods of immunogenetics make it possible to determine the specificity of each erythrocyte antigen. The method for their determination is based on serological reactions that occur between red blood cells of the tested blood samples of a particular animal and monospecific antiserum obtained from the blood serum of immunized recipient animals.

For the implementation of this development does not require additional material costs. It is necessary to use the available test results of bulls belonging to regional pedigree production associations, where each farm buys bull sperm.

In order to improve meat productivity in descendants, it is necessary to use sperm from bulls whose genotype contains antigens-markers of increased growth energy that we identified - B ₂ , G ₂ , I ', O', Q ', V, Н''. The use of manufacturing bulls with hereditary inclinations of increased growth energy on farms will increase the meat productivity of offspring by 5.8–9.4%.

Literature

1. Ivanova, O.A., Genetics / O.A. Ivanova // - M .: Kolos - 1974. - S.354-384.

2. Ivanova, O.A. Genetics / O.A. Ivanova, N.A. Kravchenko // - M .: Kolos - 1967. - S.328-354.

3. Matoushek, I. Blood type of cattle / I. Matoushek // - Kiev .: Publishing house "Harvest". - 1964 .-- 147 p.

4. Merkuryev, EK Genetics. / E.K. Merkuryeva, Z.V. Abramova, A.V.Bakai, I.I. Kochish // - M .: Agropromizdat. - 1991. - S.308-318.

5. Strygina S.O. Methods of probability theory, mathematical statistics and their application in animal husbandry / S.O. Strygina, S.I. Dementiev, V.V. Alifanov // Voronezh FGOU VPO VGAU, 2008. - P. 91-97.

6. Tikhonov, V.N. The use of blood groups in the selection of animals / V.N. Tikhonov // - M .: Kolos - 1967. - 391 p.

Claims (1)

A method of selecting cattle for meat productivity, characterized in that at the age of 20 days, the presence of erythrocyte antigens-markers of two types in the blood is detected: antigens of increased growth energy - B ₂ , G ₂ , I ', O', Q ', V , H ”and antigens of reduced growth energy Q, T ₁ , S ₁ , and if there are markers of increased growth energy in the genotype of animals or their prevalence over antigens of reduced growth energy, animals are selected.