تجزیه و تحلیل ژنتیکی مواد جامد بدون چربی شیر با دو مدل تابعیت ثابت و تصادفی در گوسفند کردی شیروان

کاظمی برزل آباد, فاطمه; حسنی, سعید; صمدی, فیروز; آهنی آذری, مجتبی; ساقی, داوود علی

doi:10.22067/ijasr.v8i1.41859

تجزیه و تحلیل ژنتیکی مواد جامد بدون چربی شیر با دو مدل تابعیت ثابت و تصادفی در گوسفند کردی شیروان

نوع مقاله : علمی پژوهشی- ژنتیک و اصلاح دام و طیور

نویسندگان

¹ دانشگاه علوم کشاورزی و منابع طبیعی گرگان

² گروه ژنتیک و اصلاح نژاد دام و طیور، دانشگاه علوم کشاورزی و منابع طبیعی گرگان

³ مرکز تحقیقات کشاورزی و منابع طبیعی خراسان رضوی

10.22067/ijasr.v8i1.41859

چکیده

مواد جامد بدون چربی شیر اهمیت اقتصادی زیادی در صنعت پنیرسازی دارد. در تحقیق حاضر درصد مواد جامد بدون چربی شیر میش های کردی شیروان با مدل های تابعیت ثابت و تصادفی و نرم افزار Wombatمورد تجزیه و تحلیل ژنتیکی قرار گرفتند. داده های مورد استفاده در این پژوهش 1094 رکورد روزآزمون درصد مواد جامد بدون چربی شیر مربوط به 250 رأس میش گله ایستگاه پرورش و اصلاح نژاد گوسفند کردی شیروان بود که از اردیبهشت تا مرداد ماه سال 1391 جمع آوری شد. در هر دو مدل، اثرات ثابت تعداد بره ها در هر زایش، شکم زایش، ماه رکوردگیری، متغیر کمکی روزهای شیردهی و همچنین اثرات تصادفی ژنتیکی افزایشی و محیط دائمی گنجانده شدند. در مدل تابعیت تصادفی چند جمله ای های متعامد لژاندر با درجه برازش 2 برای اثرات محیط دائمی و ژنتیکی افزایشی برازش داده شدند. میانگین درصد مواد جامد بدون چربی شیر میش های کردی این گله 83/11 بود. میانگین وراثت پذیری این صفت با مدل تابعیت ثابت 06/0 برآورد گردید. در مدل تابعیت تصادفی وراثت پذیری بدست آمده در نیمه دوم شیردهی بالاتر از نیمه اول شیردهی بود. پایین ترین و بالاترین مقادیر وراثت پذیری به ترتیب مربوط به روزهای 14 (068/0) و 112 شیردهی (193/0) بودند. همبستگی های ژنتیکی افزایشی و محیط دائمی برای صفت درصد مواد جامد بدون چربی شیر در روزهای شیردهی مجاور بیش از روزهای دور از هم بود. به طور کلی نتایج این تحقیق نشان داد که میش های نژاد کردی شیروان پتانسیل بالایی برای تولید مواد جامد بدون چربی شیر دارند.

کلیدواژه‌ها

20.1001.1.20083106.1395.8.1.9.8

عنوان مقاله [English]

Genetic analysis of milk solid no-fat percentage by fixed and random regression models in Kurdi sheep of Shirvan

نویسندگان [English]

fatemh kazemi borzel abad ¹
Saeed Hassani ¹
Firooz Samadi ¹
Mojtaba Ahani Azari ²
Davoud Ali Saghi ³

¹ Gorgan University of Agricultural Sciences and Natural Resources

² Department of Animal and Poultry Breeding and Genetics, Gorgan University of Agricultural Sciences and Natural Resources, Gorgan, Iran

³ Khorasan Agricultural and Natural Resources Research and Training Center

چکیده [English]

Introduction Milk solid no-fat is economically very important in cheese industry. Compared to the other kinds of milk, ewe’s milk contains higher amount of milk solids no-fat. Milk solids no-fat (MSNF) contains lactose, caseins, whey proteins, and minerals.
The use of test day records in random regression method has several benefits including flexibility to account for the environmental and genetic components of the shape of lactation, reducing generation interval and cost of recording by making fewer measurements, increasing the accuracy of genetic evaluation and direct correction for fixed effects. Therefore, the objective of the present study was to estimate genetic parameters for test-day milk solid no-fat percentage in Kurdi sheep of Shirvan using fixed and random regression models.
Materials and methods In the present investigation, genetic analysis of milk solid no-fat percentage was carried out using fixed and random regression models by Wombat software. Data included 1094 test day records of milk solid no-fat percentage collected from 250 ewes in Hossien Abad Kurdi sheep breeding station. Milking was carried out by hand milking combined with lamb suckling at 14 days interval starting from May to August 2012. Then, 50 ml of milk samples were immediately analysed by Ecomilk total to determine the milk solid no-fat percentage. Fixed effects of litter size, parity, month of recording and days in milk as covariate and random effects of direct genetic and permanent environmental effects were included in the models. General linear model was used to identify effective fixed effects on the trait by SAS 9.1 software. Variance and covariance components were estimated using restricted maximum likelihood procedure. In random regression model, orthogonal Legendre polynomials of order 2 for permanent environmental and additive genetic effects was fitted.
Results and Discussion Average milk solid no-fat percentage of Kurdi ewes was 11.83. Average heritability, repeatability, additive genetic variance, permanent environmental variance, phenotypic variance and residual variance of milk solid no-fat percentage were estimated as 0.06, 0.26, 0.029, 0.094, 0.0471, and 0.0348, respectively in fixed regression model. In a study on northern Thailand dairy cows, heritability, additive genetic variance and residual variance estimates were 0.133, 0.36, and 0.238, respectively. In random regression model, heritability of milk solid no-fat percentage was higher in second than first part of lactation period. The highest and the lowest heritability were estimated at 14 (0.068) and 112 (0.193) days, respectively. Repeatability of milk solid no-fat percentage was higher in second than first part of lactation period. The highest and the lowest repeatability were estimated at 14 (0.279) and 126 (0.732) days, respectively. In a study on milk solid no-fat percentage in Holstein cow in Korea, the range of heritabilities were from 0.305 to 0.489 and higher estimates of heritability for milk solid non fat percentage occurred in second half of lactation. Additive genetic variance in early lactation was lower than that of the end of lactation. The highest and the lowest additive genetic variance were estimated at 5 (0.013) and 126 (0.143) days, respectively. Permanent environmental variance was estimated higher in second than first part of lactation period and the highest and the lowest permanent environmental variances were estimated at 21 (0.05) and 126 (0.39) days, respectively. Phenotypic variance of milk solid no-fat percentage during lactation was not constant, the highest and the lowest permanent environmental variances were estimated at 5 (0.27) and 126 (0.79) days, respectively. Residual variance for the model considered to be constant for all days in milk (0.191). Genetic correlations between milk solid no-fat percentages at different days in milk were positive and ranged from 0.391 to 0.999. Permanent environmental correlation between Milk solid no-fat percentage at different days in milk were ranged from -0.343 to 0.999. Milk solid non fat percentage additive genetic and permanent environmental correlations between adjacent test days were more than between distant test days.
Conclusion Generally, results indicated that Shirvan Kurdi ewes had high milk solid no-fat production potential. Moreover, higher heritability for this trait at the end of lactation probably indicated higher contribution of additive genetic variation to the total variation and selection of ewes in this part of lactation would be preferred.
Acknowledgements The authors would like to thank the devoted team of Hossien Abad Kurdi sheep breeding station for their continuing collaboration in milk recording.

کلیدواژه‌ها [English]

Genetic parameters
Milk solid no-fat percentage
Sheep
Test Day Model

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