QTL for plant growth and morphology

被引：34

作者：

Maloof, JN ^{[1
]}

机构：

[1] Univ Calif Davis, Plant Biol Sect, Davis, CA 95616 USA

来源：

CURRENT OPINION IN PLANT BIOLOGY | 2003年 / 6卷 / 01期

关键词：

D O I：

10.1016/S1369526602000080

中图分类号：

Q94 [植物学];

学科分类号：

071001 ;

摘要：

Individuals and strains within most species exhibit heritable, and sometimes dramatic, differences in their growth and morphology. Advances in marker genotyping and statistical methods have increased the precision and sensitivity with which the quantitative trait loci (QTL) that are responsible for these differences can be mapped. This has resulted in both a more refined picture of the genetic architecture of many growth traits and the cloning of several of the genes that underlie plant QTL.

引用

页码：85 / 90

页数：6

共 60 条

[11]

DEVICENTE MC, 1993, GENETICS, V134, P585

[12] The evolution of apical dominance in maize [J].

Doebley, J ;

Stec, A ;

Hubbard, L .

NATURE, 1997, 386 (6624) :485-488

[13]

DOEBLEY J, 1993, GENETICS, V134, P559

[14] A QTL for flowering time in Arabidopsis reveals a novel allele of CRY2 [J].

El-Assal, SED ;

Alonso-Blanco, C ;

Peeters, AJM ;

Raz, V ;

Koornneef, M .

NATURE GENETICS, 2001, 29 (04) :435-440

[15] fw2.2:: A quantitative trait locus key to the evolution of tomato fruit size [J].

Frary, A ;

Nesbitt, TC ;

Frary, A ;

Grandillo, S ;

van der Knaap, E ;

Cong, B ;

Liu, JP ;

Meller, J ;

Elber, R ;

Alpert, KB ;

Tanksley, SD .

SCIENCE, 2000, 289 (5476) :85-88

[16] A recombination hotspot delimits a wild-species quantitative trait locus for tomato sugar content to 484 bp within an invertase gene [J].

Fridman, E ;

Pleban, T ;

Zamir, D .

PROCEEDINGS OF THE NATIONAL ACADEMY OF SCIENCES OF THE UNITED STATES OF AMERICA, 2000, 97 (09) :4718-4723

[17] Two tightly linked QTLs modify tomato sugar content via different physiological pathways [J].

Fridman, E ;

Liu, YS ;

Carmel-Goren, L ;

Gur, A ;

Shoresh, M ;

Pleban, T ;

Eshed, Y ;

Zamir, D .

MOLECULAR GENETICS AND GENOMICS, 2002, 266 (05) :821-826

[18] A draft sequence of the rice genome (Oryza sativa L. ssp japonica) [J].

Goff, SA ;

Ricke, D ;

Lan, TH ;

Presting, G ;

Wang, RL ;

Dunn, M ;

Glazebrook, J ;

Sessions, A ;

Oeller, P ;

Varma, H ;

Hadley, D ;

Hutchinson, D ;

Martin, C ;

Katagiri, F ;

Lange, BM ;

Moughamer, T ;

Xia, Y ;

Budworth, P ;

Zhong, JP ;

Miguel, T ;

Paszkowski, U ;

Zhang, SP ;

Colbert, M ;

Sun, WL ;

Chen, LL ;

Cooper, B ;

Park, S ;

Wood, TC ;

Mao, L ;

Quail, P ;

Wing, R ;

Dean, R ;

Yu, YS ;

Zharkikh, A ;

Shen, R ;

Sahasrabudhe, S ;

Thomas, A ;

Cannings, R ;

Gutin, A ;

Pruss, D ;

Reid, J ;

Tavtigian, S ;

Mitchell, J ;

Eldredge, G ;

Scholl, T ;

Miller, RM ;

Bhatnagar, S ;

Adey, N ;

Rubano, T ;

Tusneem, N .

SCIENCE, 2002, 296 (5565) :92-100

[19]

Hagenblad J, 2002, GENETICS, V161, P289

[20] Towards a better understanding of the genetic and physiological basis for nitrogen use efficiency in maize [J].

Hirel, B ;

Bertin, P ;

Quilleré, I ;

Bourdoncle, W ;

Attagnant, C ;

Dellay, C ;

Gouy, A ;

Cadiou, S ;

Retailliau, C ;

Falque, M ;

Gallais, A .

PLANT PHYSIOLOGY, 2001, 125 (03) :1258-1270

← 1 2 3 4 5 6 →