«Previous Article|Table of Contents|Next Article»

¡¶±±·½Ô°ÒÕ¡·[ISSN:1001-0009/CN:23-1247/S]

Issue:

2012Äê13ÆÚ

Page:

127-131

Research Field:

Publishing date:

Info

Title:

Establishment and Optimization of Chrysanthemum SSR-PCR Reaction System

Author(s):

LI Ya-hui ¹; 2; HUANG Cong-lin²; DONG Ran¹

1.College of Gardening£¬Jilin Agricultural University£¬Changchun£¬Jilin 130118£»
2.Beijing Agro-Biotechnology Research Center£¬Beijing Academy of Agriculture and Forestry Sciences£¬Beijing 100097

Keywords:

chrysanthemum; SSR markers; orthogonal design; optimization of reaction system

PACS:

S 682.1+1

DOI:

-

Abstract:

In order to obtain the optimal SSR-PCR system for Chrysanthemum moriforlium£¬an orthogonal diagram Lª­16(45) experimental design was employed to evaluate five factors (template DNA£¬Mg2+£¬dNTP£¬primer and Taq DNA polymerase) at four different levels.The fully random single factor experiment was used to select the optimal level for each factor to optimize the SSR-PCR amplification system.The results showed that an optimal SSR-PCR system for chrysanthemum was obtained as following£º60 ng DNA template£¬2.0 mmol/L Mg2+£¬0.1 mmol/L dNTP£¬0.3 ¦Ìmol/L primer£¬1 U Taq DNA polymerase in 25 ¦ÌL reaction system.The optimal annealing temperature for SSR-PCR reaction system was determined as 53.1¡æ by gradient PCR.The suitable thermal cycling conditions with initial melting at 95¡æ for 5 min£¬followed by 35 cycles at 94¡æ for 50 s£¬53.1¡æ for 50 s£¬72¡æ for 50 s£»then keep the reaction mixture at 4¡æ after a final extension step of 72¡æ for 8 min.The optimized system would be effective as a solid foundation for chrysanthemum SSR analysis£®

References:

[1]Chen J Y.Studies the origin of Chinese Florist¡¯s chrysanthemum [J].Acta Hort£¬1985,167:349-361.
[2]Anderson N O.Flower breeding and genetics£ºIssues£¬Challenges and opportunities for the 21st century.[J].Springer£¬2007£¨3£©:389-395.
[3]´÷˼À¼.ÖйúÔÔÅà¾Õ»¨ÆðÔ´µÄ×ÛºÏÑо¿[D].±±¾©:±±¾©ÁÖÒµ´óѧͼÊé¹Ý,1994.
[4]·½Ðû¾û,ÎâΪÈË,ÌƼÍÁ¼,µÈ.×÷ÎïDNA±ê¼Ç¸¨ÖúÓýÖÖ[M].±±¾©:¿Æѧ³ö°æÉç,2001£®
[5]Cho Y G,Ishil T,Temnykh S,et al.Diversity of microsatellites derived from genomic libraries and Genbank sequences in rice (Oryza sativa L.)[J].Thero Apple Genet£¬2000£¬100:713-722.
[6]Vogel J M,DuPont E I,Wilmington D E,et al.Application of genetic diagnostics to plant genome analysis and plant breeding[J].Hort Science,1996,31(7):1107-1108.
[7]Akkaya M S,Bhagwat A A,Cregan P B,et al.Length polymorphism of simple sequence repeat DNA in soybean[J].Genetics,1992,132:1131-l139.
[8]Ma Z Q,Roder M S,Sorrells M E,et al.Frequencies and sequence characteristics of di-,tri-.and tetranucleocide microsatellites in wheat[J].Geneome,1996,39:123-130.
[9]Chin E C L,Shu H£¬Smith J S C,et al.Maize simple repetive DNA sequence aboundance and allele variation[J].Genome,1996,39(5):886-873.
[10]Taramino G,Tingey S.Simple sequence repeats for germplasm analysis and mapping in maize [J].Genome£¬1996£¬39(2)£º277-287.
[11]Broun P£¬Tanksley S D.Characterization and genetic mapping of simple repeat sequence in the tomato genome[J].Mol Cen Genet,1996,2(50):39-49.
[12]ÕÅ´º»ª,ÖÜÓÀÖ¾,ÑÖÒþ,µÈ.ÊýÀíͳ¼Æ·½·¨[M].¼ÃÄÏ:ɽ¶«´óѧÉç,1992.
[13]Murray M G,Thompson W F.Rapid isolation of high molecular weight plant DNA[J].Nucleic Acids Research,1980,8(25):4321-4325.
[14]Huang G W G,Cipriani M£¬MorganteR,et al.Testolin.Microsatellite DNA in Actinidia chinensis£ºisolation£¬characterisation,and homology in related species[J].Theor Appl Genet,1998£¬97:1269-1278. [15]ÕÔÊÀºÆ,ÖÜÇåÃ÷,½¯½¨ÐÛ,µÈ.Õý½»Éè¼ÆÓÅ»¯Ñ̲ÝSSR·´Ó¦Ìåϵ[J].ºþÄÏÅ©Òµ¿Æѧ,2007(6):48-51.
[16]Ñî·«,ÔøÀö,ÕÔ×Ó¸Õ,µÈ.ÍòÊÙ¾ÕSSR-PCR·´Ó¦ÌåϵµÄÓÅ»¯[J].ÉϺ£½»Í¨´óѧѧ±¨,2001(1)£º22-27.
[17]ÌïÒåéð,Íõ²Êºç,ÕżÌäø,µÈ.Æ»¹û»ùÒò×éRAPD·´Ó¦ÌåϵӰÏìÒò×ÓµÄÓÅ»¯[J].À³ÑôÅ©±¨,2003,20(3):157-161.

Memo

Memo:

-

Common functions

Last Update: 2014-09-16