RU2583305C1 - Method of determining and predicting productive qualities of young cattle of meat breeds on meat productivity - Google Patents

Abstract

FIELD: agriculture.

SUBSTANCE: method of determining and predicting productive qualities of young cattle of meet breeds on meat productivity comprises the use of methods of intra-breed and intra-herd selection. At that it is characterized by an index of relative body weight (IRBW) to 102%, indicating low, and more than 105% - the high weight qualities of young animals of meat productivity, which is represented by the formula:

where: P₁ and P₂ are the actual average body weight of animals-offspring of the servicing bull under study at 15 and 18 months, respectively; N₁ and N₂ are the actual average body weight of calves (heifers) in a herd of 15 and 18 months, respectively; S₁ and S₂ is the normalized bodyweight of elite-record class of 15 and 18 months, respectively, depending on the genotype and sex; R is a coefficient of heritability of body weight in a herd as corrected from the level of 100%.

EFFECT: use of the method provides a simplified assessment of the breed, reproduction of new group genotypes of animals with high body weight, contributes to increase in meat productivity.

1 dwg, 10 tbl

Description

The invention relates to the breeding and selection of cattle in the meat direction of productivity and can be used in pedigree and commercial meat cattle breeding.

A method for selecting cattle by meat productivity includes detecting the presence of erythrocyte marker antigens of two types at the age of 20 days: antigens of increased growth energy and antigens of reduced growth energy. The method allows to increase the meat productivity of the offspring by 5.8-9.4% [1].

A significant disadvantage of this method, firstly, is that it has low accuracy of prediction. It has been established that it is rather difficult to conclude the value of carriage of individual antigens as markers of breeding and productive qualities of animals [2]. Secondly, sophisticated equipment and expensive reagents are used to identify individual antigens, and analyzes must be carried out by highly qualified specialists.

The main direction of improving specialized beef cattle is selection by live weight - the most objective indicator by which to determine how much beef (and what quality) can be obtained in each case. The value of live weight, in turn, is determined by the intensity of changes in body weight, limited to a certain age.

In the practice of breeding work with cattle of meat breeds, index estimates for predicting animal productivity are used to improve breeding qualities and increase the production of high-quality beef. The tribal value when testing gobies (heifers) in terms of their own productivity, and production bulls - in terms of offspring quality, is established by indicators: live weight of 15 months, average daily increase from 8 to 15 months, feed consumption per 1 kg of growth, meat assessment forms, body type rating [3].

From the point of view of mathematical statistics, this model is not in doubt and provides for the maximum approximation of the results of a comprehensive assessment of the animal to its true genetic value.

However, in the practical use of this model, a number of difficulties arise.

The ultimate breeding value of meat producers is practically determined from the standpoint of individual care. With high probability, it can be assumed that the highly productive descendants of the best bulls, evaluated in such comfortable conditions for the manifestation of their potential capabilities, will require the same conditions, and in their absence they will not meet expectations. In order for the best bulls to fulfill their purpose, their test, in our opinion, must be brought closer to the conditions of production.

Some other provisions of the current recommendations are doubtful. In connection with the peculiarities of breeding and breeding work in pedigree beef cattle breeding, the indicators of young animals of 15 months of age are traditionally taken into account. Given the current trend towards an increase in longevity and live weight of animals of the desired type, the period of control rearing of young animals during the test, apparently, should be differentiated, for domestic meat breeds and types - up to 18 months [4]. With limited opportunities for a sharp increase in the number of livestock, structural changes in the use of livestock breeds (types) will also increase the overall potential for the production of meat from meat breeds through cultivation to high weight conditions [5].

At the annual scoring of bull-calves and heifers of the meat direction of productivity for the purpose of their further use, an individual comprehensive assessment is carried out according to all main characteristics: live weight, exterior and physique, assessment according to own productivity, genotype. They belong to one of the following classes: record elite, elite, class I, class II, extracurricular [6].

The main drawback in this method of determining the breeding, productive value and purpose of the animal is an assessment by grade. Often, the level of productivity is not revealed strictly enough. The selection of animals of the desired types is not always accurate. In the rules for appraising young beef cattle, bulls and heifers with live weight that meet the requirements of both the elite record and the elite are allowed to be classified as the highest complex class elite record.

An important reserve for intensifying breeding work with the most numerous and widespread meat breeds of our country - Kalmyk, Aberdeen Angus, Hereford and Kazakh white-headed - should be considered an increase in their live weight and growth. The combination of these requirements and the biological characteristics of the best animals according to these properties allows you to use and develop them in the selection improvement and acquisition of meat herds. The task of increasing live weight to 500-550 kg at the age of 15-18 months. relevant for domestic and widely bred British meat breeds [7].

Improving the efficiency of breeding and breeding in determining the quality of breeding animals is important for breeding and is the object of constant interest of practitioners and scientists.

Attention is increasing to the quality of meat products in accordance with customer requests and technological requirements related to the standardization of meat productivity of young cattle from live weight, development of muscle tissue and fat deposition (Table 1).

The data obtained during slaughter show that the level of meat productivity and quality of young meat directly depends on its live weight [8].

In specialized beef cattle, live weight reliably correlates with carcass weight and is an objective lifetime indicator of animal meatiness [9, 10].

The improvement of meat productivity, as well as the manifestation of the competitiveness of meat animals, raises the need for breeds (type of cattle) that respond to full-fledged feeding by increasing the live weight of young animals, depending on the bulls used in the reproduction. The difference and the effect of each of them on the weight characteristics of the herd can be represented by the development of the animal by body weight and the difference in difference between the average live weight of the descendants of the tested bull (P) and the average development of this selection trait in uniform-aged animals of the studied herd (N) and is characterized by the following expression (PN).

Under the average herd productivity by live weight (N), we mean the actual average productivity of all bulls (heifers) by this characteristic in the herd (on the farm) of the same age, without the average live weight of the sons (daughters) of the tested bull, which is subject to comparative breeding assessment ( R).

Suppose two bull-calves are compared in live weight, the first has a body weight of 430 kg, and the second has 480 kg, is it possible to say on the basis of only these data that the second has higher productivity? No, it’s impossible, the age of the compared bulls is not yet known. All things being equal (breed, gender, optimal feeding and keeping), the calves differ in live weight due to age. The first goby has a live weight of 430 kg at the age of 15 months. - the second - 480 kg in 18 months.

It is clear that a simple comparison of the massiveness of these gobies is impossible, it must be taken into account that these gobies are of different ages.

A relative idea of the degree of development of the animal, the studied trait at certain ages, the change in its value, the degree of growth tension gives the relative growth rate [11, 12, 13].

Based on the above messages and on the basis of the author’s research, differences between descendant groups were established by the ratio of average live weight indices at 15 and 18 months.

to the standardized elite-record class value of the studied trait of each age.

We propose to consider this value as an indicator of the severity of the weight condition of young animals over time (15 and 18 months).

To understand the nature of the functioning of the entire genotype system, it is necessary to identify the limits of hereditary and non-hereditary variability in the herd using the heritability coefficient (h ² ) for the relative live weight of 18 months.

Practical experience shows that in some cases, the increase in meat productivity is provided in the increased development of live weight with age. This phenomenon is observed more often when breeding tall types (breeds) of animals that are characterized by longevity. This allows you to count on the maximum possible size of production and is a prerequisite for improving the economy of the industry.

The increase in live weight of young animals with age does not prove the need for the introduction of differentiated standards by age. Since the biologically determined tendency to change productivity is the same for all breeds, it is impossible to objectively reflect interbreed characteristics in changes in live weight by age in normalized values. The introduction for all ages of one trait of a generalized average for relative live weight, in percent equal to the number 100, from the selection point of view simplifies the tribal assessment without compromising its objectivity and will correspond to long-term use, focusing on the selection of groups of individuals with live weight of at least the elite class - record.

In this regard, the criterion for assessing the weight conditions and the meat productivity potential of young meat breeds of cattle should be an independent indicator determined by the prevailing breeding situation within the breed, herd, type, or line. Such a criterion should be the Relative Living Mass Index (IOLM), combining the weight characteristics of the descendants of the bulls-producers of meat direction of productivity in 15 and 18 months. The value of the IOLM index is determined by the ratio of the difference between the average live weight of the descendants of the studied bull-producer and the average live weight of the same-age animals per herd to the corresponding indicator of the elite-record class requirement by a similar attribute at fixed ages. At the same time, lower or higher relative weight qualities of young animals will be indicated by their values from 100%. Thus, the vector of artificial selection is directed against animals with live weight below the level of the elite-record class.

Moreover, the difference between the average values of the breeding trait in the compared groups of animals at fixed ages (15 and 18 months) serves as a more perfect measure of assessment. It shows in numerical terms the degree of difference of each manufacturer from all others and determine the reliability of this difference. In addition, a guarantee appears to reveal the hereditary possibilities of weight growth of animal descendants of the tested genotype and use them to predict the meat productivity of the herd.

In the proposed method, the requirements for repair animals to be checked are increased, and the pedigree (normalized) requirements of the elite-record class by this attribute are adopted as the scale with which productivity is calculated according to live weight of sons (daughters) (Table 2).

With this approach, when the assessment is not adapted to the low genetic potential of meat breeds and to the unsatisfactory conditions of their feeding and keeping, the actual state and relative value of each individual herd (breed) will be revealed.

With an economic approach to organizing beef production, high-class individuals of any meat breed justify themselves when they have high meat productivity [14, 15].

The target standard - the elite-record class of new breed groups and types of livestock - is designed to fulfill not only the resolving, but also the guiding and mobilizing role for several years to come.

Of fundamental importance for our methodology (claims) was the prediction of selection and heritability of the trait (h2), that is, the approximate level of development of the selection indicator is live weight [16].

The hereditary effect of father producers on the live weight of descendant bulls is 30% of the sum of the influence of all existing factors. Heritability coefficient (h ² ) - live weight - is 0.016-0.510 units and varies in separate lines from unreliable to reliable at the lower threshold value. In this regard, individual selection will be based on the use of not only the best phenotypes, but also genotypes for descendants [17].

From the above data it follows that the heritability coefficients can characterize only a specific herd (population).

Application of the invention

The experimental part of the study was carried out in a herd of Shepherd cattle of the Balkany breeding farm in the Chelyabinsk region according to the methodological scheme of in-breed (in-house) breeding using bulls-producers of herefords of different genealogical lines, body types, and ecogenetic groups.

The feeding and keeping conditions of animals of all genotypes were the same [18].

The aim of our breeding and breeding work was to focus on achieving high live weight and identifying groups of animals with the highest potential for meat productivity. At the same time, the accumulation of new properties, the development of heredity of animals in generations, the differentiation of groups, lines according to the nature of weight growth with age, the use and obtaining of producers with stable productivity are important tasks to improve the efficiency of meat cattle breeding.

According to the principle of analog groups [19], groups of full-age (5-8 years) cows were formed, according to a set of traits not lower than class I (breed standard), which in the first experiment were seeded with verified bulls-producers of genetic groups - Dove 4168 of the factory line Maer Verna 88480, Mazaya 117 of the related group Jade 138/3 Hungarian selection, in the second experiment - Fantika 4100 domestic selection of medium-sized physique, Revolyushina 1HP823 tall physique of American selection.

In order to confirm the main characteristics of the bulls-fathers and the descendants of the corresponding genotypes in comparison with the available genotypes of the herd “Balkans”, scientific and economic experiments were carried out.

In the Balkans breeding farm, when selecting Hereford bull-calves for control rearing, in the first experiment of the first variant, their linear affiliation was taken into account, which made it possible to conduct a comparative assessment depending on their paternal origin (Table 3).

According to the actual data and from the formula for calculating the severity of weight conditions.

amounted to bull-flows of the studied bull-producer - Mazaya 117. Similar indicators of the severity of weight conditions.

и

and

were in descendants of the remaining bulls used in the reproduction of the herd (table. 4).

It should be noted here that at the second age in animals, the severity of weight condition is noticeably lower in the herd than at 15 months, as well as in comparison with another group.

The use of biometric methods for processing average quality data of the studied economically useful trait made it possible to establish certain differences in the study of livestock groups. Gobies, descendants of the manufacturer Mazay 117 and their analogues in the herd, had intergroup differences with age.

So, if at the age of 15 months. since there was no significant difference in live weight, then by the age of 18 months the difference became significant (P> 0.95). This is probably due to the growth and development processes of the descendants of the bulls Mazai, which are characterized by longevity, while other animals significantly reduce weight growth compared to the previous age.

The results were a prerequisite for further justification of the application of the proposed method. More precisely, the meat productivity potential of the bulls-descendants of the production bull Mazay 117 was determined by calculating the index of relative live weight by 18 months of age.

The improving qualities of linear offspring gobies, with a certain difference in the indices of the evaluated trait at fixed ages, indicate the need for a differentiated approach to solving the use of bulls to improve the weight conditions of young animals.

The gene pool of Hereford cattle of the Balkany breeding farm is of great value, since only animals from the first production lines and major related groups from Russian adapted breeding herds are represented here.

Of certain interest in the second variant of the first experiment are the descendants of the Hereford production bull Pigeon 4168 (Table 5). The fact is that Pigeon 4168 is a fourth-generation successor from the ancestor of the Maer-Vern factory line 88480 KS V-21, characterized by high fertilizing ability, and the young growth from it, quite good adaptability to pasture conditions.

In the second variant of the first experiment, the subject of special study, on which the breeding methods of the proposed method were practiced, was a comparative study of descendants-continuers of the plant line, and the bull-descendants of Mazay 117 were already grouped for comparison from the herd as a whole (Table 6). Given the foregoing, using formulas for determining the severity of weight conditions:

,

,

calculated indicators of the severity of weight conditions in both groups at 15 and 18 months. In the above version, they are as follows:

.

.

From a practical point of view, the difference in the ratio of live weight in favor of the descendant bulls of the Dove 4168 is due to the objective lifetime high indicator of their descendants at different ages according to the studied trait.

The use of in-breed reserves opens up a significant prospect in improving the productivity of young beef cattle breeds. The maximum deviation in live weight from the average values of the achieved level. Animals corresponding to the elite-record class in live weight characterize the degree of selection pressure and determine the level of selection progress in the herd.

At the age of 15 months, the average live weight (P ₁ ) of the mass of bulls descendants of the breeding bull Dove 450 ± 8.43 kg was 20.6 kg higher than the requirements of the elite-record class for Hereford breed (S ₁ ), but it was also 58, 8 kg higher, which peers (N ₁ ) in the herd (P> 0.95).

At a later (18 months) age, this indicator in the latter (437.8 ± 3.83 kg) was 78.2 kg lower than the requirements of the highest rating class, while among the descendants-sons of the producer, the Pigeon was 4168 (510.6 ± 8.3 kg) - at the level of elite-record class requirements.

Based on the analysis of changes in live weight at 15 and 18 months, to identify the most promising groups of linear animals, it seems necessary to derive an index of the relative live weight of the descendants of the bulls-producer bull Pigeon 4168:

.

.

Considering, on the whole, the selection factor for the first experiment in the Balkans herd and the achieved level of relative live weight of descendants of the Pigeon 4168, of all groups of animals that have undergone a comparative assessment, preference should be given to animals with a higher relative live weight, in this case, descendants Pigeon 4168 with an index of relative live weight of 109.3%.

With age, due to the increased influence of the complex of genotypic factors on the growth and development of Hereford bull descendants from manufacturing bulls of different body types, noticeable differences in body weight were observed.

From the formula for calculating the severity of weight conditions, they amounted to 1.13 at 15 months, 1.06 at 18 months for descendants of the tall bull Revolyushin 1HP823 of the American selection, and in analogous animals from this herd, originating from different bulls, these indicators were 0 , 90 and 0.85 units (tab. 7, 8).

The correspondence of the live weight of bull-calves descendants of Herefords of the studied bulls to the desired criteria (class elite-record) by breed can be illustrated in FIG. one.

The largest excess of live weight relative to the recommended values was recorded in goby descendants of the bull Revolyushin by 12.9% in 15 months. and 5.1% at 18 months, while among peers in the herd, these indicators were less than the desired level by 10.1% and 16.2%, respectively.

In our studies, the gobies descended from the Revolyushin bull, a tall physique of American selection, were particularly distinguished by 98.8 kg in live weight. At a sufficiently high (P> 0.999), the probabilities were better in bulk than the 15-month-old peers in the herd.

It also turned out that if meat productivity was predicted by the dynamics of live weight development at fixed ages, then the probability of the correct selection of the potentially best groups of animals in this breeding direction for improving beef cattle could be significantly increased. The maximum values of group indicators in 18 months. - the severity of weight conditions was equal to 1.06 units, the difference in actual live weight of 108.4 kg with a high (P> 0.999) reliability of the difference more fully reflected the economic and tribal value of young animals of this type and our assumptions when using elements of the proposed method.

In order to comprehensively assess the meat productivity potential of the bulls descendants of the manufacturing bull Revolyushin 1HP823 it is proposed to derive the index of the relative live weight of the bulls descendants of the manufacturing bull Revolyushin.

.

.

One of the fragments of the above study was the determination of the change in the live weight of the descendants of the bulls of the bull of the producer Fantika 4100 medium-sized physique of domestic selection.

With an economic approach to the organization of breeding of young beef cattle, high-class individuals of any breed up to date only prove their worth when they have high meat productivity. In this regard, it was important to find out the increase or decrease in the productive potential in terms of live weight at 15 and 18 months of descendants of Fantik and animal counterparts according to the herd of the target standard (elite-record class requirements for live weight) by the ratio of the values of the studied trait (Table 9, 10).

In the second version of the second experiment, they are as follows:

.

.

An analysis of the quality of the offspring showed a higher severity of weight condition at 15 and 18 months in bulls descending from the manufacturing bull Fantika 4100.

Knowing the biological characteristics of the growth and development of animals of different body types allows you to more reasonably approach the prediction of their weight growth and obtaining heavy carcasses.

At the age of 15 months. Fantik's sons were superior in average live weight over coeval animals of the herd by 15.3 kg with an unreliable difference in the first threshold of reliability. Control rearing up to 18 months of age showed a slight (21.6 kg) increase in the body weight advantage of offspring from a bull of medium build over peers in the herd. However, the reliability of this difference between the compared groups was not confirmed by biometric processing (P <0.95).

It should be noted here that such small differences between the descendants of Fantik 4100 and the animals of the herd in terms of average live weight are largely due to the presence among the last descendants of the Revolyushin bull, including quite massive ones.

With the growing popularity of cattle with high live weight, interest in improving the selection and prediction of the main economically useful traits is justified.

Taking into account the foregoing, we can assume the probable relative live weight of the descendants of the Fantik 4100 bull and predict their meat productivity from the proposed formula:

.

.

From this we can conclude that Fantik's bull-descendants are less in compliance with the requirements of the desired type of cattle being created. The potential for possible meat productivity among them remains low. The results can be useful for other breeding herds.

The technical essence of the invention is to increase the live weight of young beef cattle, both from individual bulls and the herd as a whole, which is implemented according to the proposed formula as the sum of the terms, the first term is the ratio of the difference in the actual average live weight of 15-month-old descendants of the studied bull and the actual average value of this trait in the herd at the same age to the normalized live weight of the elite-record class of 15 months, the second term from identical arithmetic operations is similar x feature indicators considered only 18 months of age on the heritability coefficient bw with correction of the level of 100%.

Information sources

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2. Tuzov I.N., Schukina I.V., Kuznetsov A.V. Study of the possibilities of selection by immunogenetic criteria // Modern achievements of zootechnical science and practice. - The basis for increasing the productivity of farm animals: Sat. scientific tr Part 1. SKNIIZH. Krasnodar, 2007.S. 176-178.

3. The procedure and conditions for evaluating bulls-producers of meat breeds by their own productivity and the quality of offspring / resp. for issue. X A. Amerkhanov. M., Orenburg, 2013.24 s

4. Lukash V.P., Garmash I.A. Assessment of producers of the created Ukrainian beef cattle // Zootechny. 1990. No. 1. S. 34-36.

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7. Zadnipryansky I.P. Results and prospects of using the world's best gene pool in beef cattle breeding // Problems of beef cattle breeding: collection of articles. scientific tr VNIIMS. Orenburg, 1995. Issue. 48.S. 17-25.

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9. Polinukovsky L.I. The productivity of young Hereford breed, depending on the compatibility of the genotypes of the parents // Improving the methods of breeding and increasing the productivity of beef cattle: Sat. scientific tr VNIIMS. Orenburg, 1993.S. 45-53.

10. Genetic resources of Hereford, Kazakh white-headed breeds and their interaction in breeding: scientific. ed. / X.A. Amerkhanov, F.G. Kayumov, M.P. Dubovskova, A.M. Belousov. M .: Federal State Budgetary Institution "Rosinformagroteh", 2010. S. 57-59; 269-273.

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Claims (1)

A method for determining and predicting the productive qualities of young meat breeds of cattle by meat productivity, containing methods of in-breed, intra-breeding selection, characterized by an index of relative live weight (IOLM) of up to 102% indicating low, and more than 105%, high weight qualities of young meat productivity represented by the formula:

,
where: P ₁ and P ₂ - the actual average live weight of animal descendants of the studied bull at 15 and 18 months. respectively;
N ₁ and N ₂ - the actual average live weight of gobies (heifers) in the herd at 15 and 18 months. respectively;
S ₁ and S ₂ - normalized live weight of the elite-record class at 15 and 18 months. accordingly, depending on genotype and gender;
R is the heritability coefficient of live weight in the herd, adjusted for a level of 100%;
IOZHM - an index of relative live weight on a considered group of animals.

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