Investigation of polymorphism of Markhoz goat microsatellite markers
Subject Areas :
Sajad Badbarin
1
,
Reza Seyedsharifi
2
,
Hassan Khamis Abadi
3
,
Javad Ahmadpanah
4
1 - Faculty of Kermanshah Agricultural and Natural Resources Research and Education Center
2 - Dept of Animal Science, Faculty of Agriculture, University of mohaghegh ardabili
3 - Faculty of Agricultural Research Education and Extension Organization (AREEO)
4 - Faculty of Agricultural Research Education and Extension Organization (AREEO)
Keywords: Genetic straucture, Markhoz goats, Microsatellite markers,
Abstract :
The use of molecular markers, especially microsatellite markers provides very valuable information about the existing genetic structure under study. This information can be used to protect an endangered species or to investigate the location of genes affecting quantitative traits (QTL). The purpose of this study was to emphasized the importance of microsatellite markers for the study of genetic diversity in Markhoz goats and their use in conservation strategies.In this study, blood samples were taken from 240 Markhz goats in Kurdistan province randomly. DNA extraction from whole blood samples was performed by salting out method. Then, the genetic diversity of 30 microsatellite markers was investigated using polymerase chain reaction (PCR). Alleles of each individual were identified using silver staining method. Genetic parameters related to the genetic structure of Markhoz goat were calculated using POPGENE software.Except for INRA040 marker, all markers used were well amplified. Among the amplified markers, MCM136 showed low polymorphism but other markers had high polymorphism. ILSTS030 markers with 6 alleles and MCM136 markers with 3 alleles produced the highest and lowest number of alleles, respectively. ILSTS030 marker showed the highest (0.7504) and MCM136 marker showed the lowest (0.0158) expected heterozygosity.Microsatellite markers seem to be a useful and reliable tool for identifying goat breeds and their use can be a solution to protect endangered breeds.
منابع
1-رشیدی، ا.، امام جمعه، ن.، میرائی آشتیانی، س ر.، رحیمی، ش.، واعظ ترشیزی، و ر. ١٣٧٩. برآورد مؤلفههای واریانس-کواریانس و پارامترهای ژنتیکی صفات وزن بدن در بزهای مرخز. علوم کشاورزی ایران. ٣٠: 462-455.
2-سالاری، ا.، امیری نیا، س.، قره داغی، ع ا.، شیری، س ا.، خدرزاده، ص. 1389. بررسی تنوع ژنتیکی گوسفند کردی خراسان با استفاده از نشانگرهای ریز ماهواره. مجله دانش و پژوهش علوم دامی. 7: 17-11.
3-عسگری، ن.، محمدآبادی، م ر.، بیگی نصیری، م ت.، باقی زاده، ا.، فیاضی، ج. 1387. مطالعه تنوع ژنتیکی بز کرکی رائینی بر اساس نشانگرهای ریزماهواره. دانش کشاورزی. 18(4): 161-155.
4-محمدآبادی، م ر.، شهابی، ا.، نوشری، ع ر.، عسگری، ن.، دیانی، ا.، خضری، ا. 1390. مطالعه تنوع ژنتیکی بز سرخ جبال بارز با استفاده از نشانگرهای ریزماهواره. نشریه علوم دامی ایران. 42(2): 131-125.
5-نژاد گشتی، م.، اسماعیل خانیان، س.، میرهادی، س ا.، همتی، و ب. 1384. بررسی تنوع ژنتیکی بز رائینی کرمان با استفاده از ١٠ جایگاه ریزماهوارهای. چهارمین همایش ملی بیوتکنولوژی جمهوری اسلامی ایران. کرمان.
6.An, ZW., Xie, LL., Cheng, H., Zhou, Y., Zhang, Q., He, XG., Huang, HS. (2009). A silver staining procedure for nucleic acids in polyacrylamide gels without fixation and pretreatment. Analytical Biochemistry, 391(1); 77-79.
7.Cano, EM., Marrube, G., Roldan, DL., Bidinost, F., Abad, M., Allain, D. (2007). QTL affecting fleece traits in Angora goats. Small Ruminant Research, 71; 158-164.
8.Chambers, GK., Macavoy, ES. (2000). Microsatellites: consensus and controversy. Comparative Biochemistry and Physiology, 126; 455-476.
9.De Araujo, AM., Guimaraes, SEF., Machado, TMM. (2006). Genetic diversity between herds of Alpine and Saanen dairy goats and the naturalized Brazilian moxoto breed. Genetic and Molecular Biology, 29; 67-74.
10.FAO. (2000). Conserving and developing farm animal diversity. In State of the world animal genetic resources. http://www. fao.org/ news/ 2000/ 001201-e.htm.
11.Geldermann, H. (1975). Investigation on inheritance of quantitative character in animals by gene markers. Theoretical and Applied Genetics, 46; 319-330.
12.Henderson, CR. (1975). Best linear unbiased estimation and prediction under a selection model. Biometrics, 31; 423-447.
13.Luis, A., Salazar, M., Hirata, H., Cavalli, AS., Machado, MO., Rosario, DC. (1998). Optimized Procedure for DNA isolation from fresh and cryopreserved clotted human blood useful in clinical molecular testing. Clinical Chemistry, 44; 1748-1750.
14.Mahmoudi, B., Daliri, M., Babayev, MS., Sadeghi, R. (2009). Genetic analysis of markhoz goats based on micro satellite markers. Journal of Animal and Veterinary Advances, 8(9); 1815-1815.
15.Martinez, AM., Acosta, J., Vegapla, JL., Delgado, JV. (2006). Analysis of the genetic structure of the canary goat populations using
microsatellites. Small Ruminant Research, 57; 249-255.
16.Nomura, K., Yonezawa, T., Mano, S., Kawakami, S., Shedlock, AM., Hasegawa, M. (2013). Domestication Process of the goat revealed by an analysis of the nearly complete mitochondrial protein-encoding genes. Proceedings of the National Academy of
Sciences of the United States of America, 105(46); 17659-64.
17.Sadeghi, R., Mahmoudi, B., Babayev, BS., Rameshknia, Y., Daliri, M. (2009). Genetic analysis in Tali goats based on 13 microsatellite markers. Research Journal of Biological Sciences, 4(6); 734-737.
18.Samuel, M., Lu, M., Pachuk, CJ., Satishchandran, C. (2003). A spectrophotometric method to quantify linear DNA. Analytical Biochemistry, 313(2); 301-306.
19.Sheriff, O., Alemayehu, K. (2018). Genetic diversity studies using microsatellite markers and their contribution in supporting sustainable sheep breeding programs: A review. Cogent Food and Agriculture, 4; 1-9.
20.Visser, C., Van Marle-Koster, E., Bovenhuis, H., Crooijmans, RPMA. (2011). QTL for mohair traits in South African Angora goats. Small Ruminant Research, 100; 8-14.
21.Wang, GZ., Chen, SS., Chao, TL., Ji, ZB., Hou, L., Qin, ZJ., Wang, JM. (2017). Analysis of genetic diversity of Chinese dairy goats via microsatellite markers. Journal of Animal Science, 95(5); 2304-2313
_||_