بررسی فیلوژنی ژنوتیپ‌های نخود ایکاردا با تودة بومی بیونیچ (Bivanij) غرب ایران

نوع مقاله : مقالات پژوهشی

نویسندگان

1 دانشگاه لرستان

2 پیام نور کرج

3 لرستان

چکیده

با وجود اینکه ایران یکی از خاستگاهای عمده نخود (Cicer arietinum L.) در دنیا به شمار می‌آید، اطلاعات اندکی از ساختار تنوع ژنتیکی این گیاه در ایران موجود است. در این تحقیق، تنوع ژنتیکی 18 ژنوتیپ نخود اصلاح شده و مورد کشت و کار در غرب ایران با استفاده از نشانگر تصادفی RAPD مورد مطالعه قرار گرفتند. از میان ١٨ آغازگری که در مطالعه به‌کار رفتند، ۱۷ آغازگر (آغازگر OPM-05 قطعه‌ای تولید نکرد) در مجموع ۲۰۸ قطعه DNAی واضح و قابل امتیازدهی تکثیر نمودند. از مجموع کل تعداد باندهای حاصل، تعداد ۲۰۱ باند چندشکل (۶۶/۹۶%) بودند. متوسط تعداد بانددهی به‌ازای هر آغازگر۲/۱۲ باند بود. تجزیه خوشه‌ای داده‌ها براساس ضریب تشابه دایس (Dice) و به روش UPGMA (ضریب همبستگی کوفنتیک؛ ۹۸/۰= r) ژنوتیپ‌های نخود را به شِش گروه تقسیم نمود. بر مبنای دندروگرام حاصل، بیشترین فاصله ژنتیکی بین رقم بومی و خوشه ششم به‌دست آمد. قرارگرفتن بخش وسیعی از ژنوتیپ‌ها در داخل یک گروه، بیانگر این نکته است که با وجود عدم حضور ژنوتیپ‌های تکراری در این ژرم‌پلاسم، اکثر ژنوتیپ‌ها شباهت ژنتیکی بسیار بالایی با یکدیگر نشان می‌دهند. همچنین گروه‌بندی توده‌ی محلی بیونیچ در بزرگترین خوشه می‌تواند احتمالاً بیانگر این موضوع باشد که ژنوتیپ‌های اصلاح شده‌ی ایکاردا از یک توده‌ی بومی غرب ایران منشأ گرفته باشند. نتایج این مطالعه می‌تواند در جلوگیری از آسیب‌پذیری ژرم‌پلاسم نخود زراعی، افزایش تنوع ژنتیکی و مستندسازی ژرم‌پلاسم نخود مفید فایده باشد.

کلیدواژه‌ها

عنوان مقاله [English]

Assessment of relationship between chickpea genotypes from ICARDA with a western Iranian landrace (Bivanij)

نویسندگان [English]

  • farhad Nazarian Firouzabadi 1
  • Mahin Rahimi 2
  • Ahmad Ismaili 3
1 Lorestan University
2 Payam-e-Nour University
3 Lorestan University
چکیده [English]

Introduction
Despite the fact that Iran is one of the major chickpea (Cicer arietinum L.) center of origins, limited information is available regarding chickpea genetic variation and diversity. Genetic diversity information is crucial for the choice of proper parents to establish new breeding programs. Chickpea germplasm is poor, suggesting the need for gaining enough knowledge of genetic diversity among available chickpea genotypes. A number of molecular techniques have been developed to unveil the genetic potentials of plant materials. Random Amplified Polymorpic DNA (RAPD) seems to be a reliable molecular marker to investigate the genetic diversity of chickpea genotypes in IRAN. The objectives of present research was: (1) to investigate the power of RAPD markers for estimation of genetic diversity among chickpea genotypes in west of Iran, (2) to investigate the genetic relationships between chickpea genotypes, and (3) to determine whether chickpea genotypes could be distinguished by RAPD marker data.

Materials and Methods
Random amplified polymorphic DNA markers (RAPD) were used to assess the genetic relationship between 18 different chickpea genotypes representing the cultivated chickpea cultivars in west of Iran. Genomic DNA was isolated according to Murray & Thompson (1980). Eighteen oligonucleotide primers were selected according to the number of literature published with the highest number of polymorphic bands. Polymerase chain reaction (PCR) was carried out in a total volume of 25 μl including 2 units of Taq DNA polymerase, 30 ng of genomic DNA template, 10 pmol of primers, 0.2 mM of dNTPs, and 2.5 μl of 10 × reaction buffer. DNA amplifications were performed in a thermocycler. The thermal profile was as follow: One time denaturation at 94◦C (5 min), followed by 40 cycles of denaturation at 94◦C (3 min), annealing at each primer proper Tm (1 min) and extension at 72◦C (2 min) and one time final extension at 72◦C (5 min). PCR products were analyzed on 1.5 % agarose gels in TBE buffer running at 100 V for 2h. The gels were stained using ethidium bromide and visualized with UV light. The reproducibility of the DNA band patterns was evaluated duplicate gel electrophoresis analysis. Only clear and repeatedly amplified RAPD DNA bands were scored as (1) for present bands and (0) for absent ones.

Results and Discussion
Out of 18 random RAPD primers used in this study, 17 primers amplified genomic DNA across all the genotypes. In total, 201 polymorphic bands (96.63%) out of 208 reproducibly scoreable RAPD markers were generated (OPM-05 primer did not produce any band). On average, 12.2 bands per primer were observed in RAPD analysis. Cluster analysis using Dice coefficient of similarity and UPGMA (r=0.98) method based on polymorphic fragments, grouped all eighteen genotypes into 6 groups with 77% accuracy. Based on dendrogram obtained, Bivanij (Landrace genotype) showed the least similarity with the 6th cluster. Although there was no redundancy among the genotypes tested, the majority of genotypes were clustered together. ICARDA genotypes may have been improved from an Iranian landrace.

Conclusions
Genetic diversity among chickpea cultivars using RAPD markers have been studied by a number of researchers. Although in most cases a low level of polymorphism with RAPD markers have been reported, this study showed a considerable amount of polymorphism. Furthermore, our results showed that cultivated chickpea cultivars in west of Iran have many genes in common. We recommend further studies to be conducted by using more number of chickpea genotypes as well as more robust molecular markers. Results of this study can be used in germplasm management/conservation practices, developing core collections and as guidance to plant geneticist and breeders for planning future explorations, and crop improvement purposes. These findings may help to avoid genetic vulnerability and erosion, keeping chickpea genetic diversity and germplasm.

کلیدواژه‌ها [English]

  • Chickpea
  • DNA
  • Genetic diversity
  • Germplasm
  • RAPD molecular marker

مراجع

1. Abo-elwafa, A., Murai, K., and Shimada, T. 1995. Intra-and Inter-specific variation in Lens revealed by RAPD markers. Theoretical and Applied Genetics 90: 335-340.
2. Ahmad, F., and Slinkard, A.E. 1992. Genetic relationships in the genus Cicer L. as revealed by polyacrylamide gel electrophoresis of seed storage proteins. Theoretical and Applied Genetics 84: 688-692.
3. Bagheri, A., Nezami, A., and Ganjali, A. 1999. Chickpea agronomy and Breeding. Jehad-e-daneshgahi, Mashhad. (In Persian).
4. Bayazid, B. 1996. The study of genetic diversity among cultivated chickpea cultivars under two moisture levels and correlation analysis of agronomical Traits. M.Sc Thesis, Faculty of Agriculture, Tabriz University. (In Persian with English Summary).
5. Collard, B.C.Y., Pang, E.C.K., and Taylor, P.W.J. 2003. Selection of wild Cicer accessions for the generation of mapping population segregation to ascochyta blight. Euphytica 130: 1-9.
6. Davis, T.M. 1995. A method of enhancing detection and interpretation of co-dominant RAPD markers. Theoretical and Applied Genetics 91: 582-588.
7. Emamjomeh, A. 2000. Evaluation of genetic distance drought resistance and analysis of adaptation, using RAPD-PCR in Iranian chickpea. M.Sc Thesis, Faculty of Agriculture, Razi University, Kermanshah, Iran. (In Persian with English Summary).
8. Fazeli, F., and Choghamirza, K. 2011. Genetic variation in Iranian chickpea (Cicer arietinum L. Kabuli type) based on agronomic traits and RAPD marker. Iranian Journal of Agronomy and Plant Breeding 27(4): 555-579. (In Persian with English Summary).
9. Friesen, N., Fritsch, R., and Bachmann, K. 1997. Hybrid origin of some ornamentals of allium subgenus Melanocrommyum verified with GISH and RAPD. Theoretical and Applied Genetics 95: 1229-238.
10. Gaur, P.M., and Slinkard, A.E. 1990. Genetic control and linkage relations of additional isozyme markers in chickpea. Theoretical and Applied Genetics 80: 648-659.
11. Gharhyazi, B. 1997. Application of DNA markers in plant breeding (Abstract). In: Abstract book of the 4th Iranian Agronomy and Plant Breeding Congress. (In Persian).
12. Hu, J., and Carlos, F. 1991. Identification of broccoli and cauliflower cultivars with RAPD markers. Plant Cell Reports 10: 505-511.
13. Iruela, M., Rubio, J., Cubero, J.I., Gill, J., and Millan, T. 2002. Phylogenetic analysis in the genus Cicer and cultivated chickpea using RAPD and ISSR markers. Theoretical and Applied Genetics 104: 643-651.
14. Labdi, M., Robertson, L.D., Singh, K.B., and Charrier, A. 1996. Genetic diversity and phylogenetic relationships among the annual Cicer species as revealed by isozyme polymorphisms. Euphytica 88: 181-188.
15. Lu, J. 1996. Comparative analysis of genetic diversity in pea assessed by RFLP and PCR based methods. Theoretical and Applied Genetics 93: 1103-1111.
16. Millan, T., Clarke, J., Siddique, H.M., Buhariwalla, K., Gaur, M., Kumar, J., Gill, J., Kahl, G., and Winter, P. 2006. Chickpea molecular breeding: New tools and concepts. Euphytica 147: 81-103.
17. Murray, M.G., and Thompson, W.F. 1980. RAPD isolation of high molecular weight plant DNA. Nucleic Acid Research 8: 4321-4325.
18. Rao, L.S., UshaRani, P., Deshmukh, P.S., Kumar, P.A., and Panguluri. S.K. 2007. RAPD and ISSR fingerprinting in cultivated chickpea (Cicer arietinum L.) and its wild progenitor Cicer reticulatum Ladizinsky. Genetic Resources and Crop Evolution 54 (6): 1235-1244.
19. Robertson, L.D., Ocampo, B., and Singh, K.B. 1997. Morphological variation in wild annual Cicer species in comparison with the cultigens. Euphytica 95: 309-319.
20. Sabaghpour, S.H. 1998. Chickpea Genetics. Agriculture Education Publisher. (In Persian).
21. Samiezadeh-Lahiji, H. 1997. The assessment of genetypic and phenotypic variation of quantitative traits, their correlation with Iranian chickpea yield. M.Sc. Thesis, Islamic Azad University of Karaj, Karaj, Iran. (In Persian).
22. Sant, V.J., Patankar, A.G., Sarode, N.D., Mhase, L.B., Sainani, M.N., Deshmukh, R.B., Ranjekar, P.K., and Gupta, V.S. 1999. Potential of DNA markers in detecting divergence and in analyzing heterosis in Indian elite chickpea cultivars. Theoretical and Applied Genetics 98: 1217-1225.
23. Sharma, P.C. 1995. Abundance and polymorphism of di-triand tetra nucleotide tandem repeats in chickpea. Theoretical and Applied Genetics 90: 90-960.
24. Sharma, S.K., Dawson, I.K., and Waugh, R. 1995. Relationship among cultivated and wild lentils revealed by RAPD analysis. Theoretical and Applied Genetics 91: 647-654.
25. Singh, K.B., Malhotra, R.S., Halila, M.H., Nights E.J., and Verma, M.M. 1994. Current status and future strategy in breeding chickpea for resistance to biotic and abiotic stresses. Euphytica 73: 137-149.
26. Sudupak, M.A., Akkaya, M.S., and Kencea, K. 2002. Analysis of genetic relationships among perennial and annual Cicer species growing in turkey using RAPD markers. Theoretical and Applied Genetics 105(8): 1220-1228.
27. Tilman, D., and Wedin, D. 1996. Productivity and sustainability influenced by biodiversity in grassland ecosystem. Nature 379: 718-720.
28. Van Rheenen, H.A., Pundir, R.P.S., and Miranda, J.H. 1993. How to accelerate the genetic improvement of a recalcitrant crop species such as chickpea. Current Science 65: 414-417.
29. Weeden, N.F. 1992. Marker locus, Adh-1, for resistance to pea enation mosaic virus. Journal of Heredity 79(2): 128-131.
30. Wolff, K., and Morgan-Richards, M. 1998. PCR markers distinguish plantago major subspecies. Theoretical and Applied Genetics 96: 282-286.
ارسال نظر در مورد این مقاله
CAPTCHA Image
پژوهش‌های حبوبات ایران
دوره 6، شماره 2 - شماره پیاپی 2
اردیبهشت 1394
صفحه 9-18

فایل ها

هم رسانی

ارجاع به این مقاله

آمار