分子植物育种
(
网络版
), 2016
年
,
第
14
卷
,
第
1062-1071
页
Fenzi Zhiwu Yuzhong (Online), 2016, Vol.14, 1062-1071
Copyright © 2016 BioPublisher 1069
Stupar R.M., 2011, Targeted mutagenesis of duplicated
genes in soybean with zinc-finger nucleases, Plant Physiol,
156(2): 466-473
Feng Z.Y., Zhang B.T., Ding W.N., Liu X.D., Yang D.L., Wei
P.L., Cao F.Q., Zhu S.H., Zhang F., Mao Y.F., and Zhu J.K.,
2013, Efficient genome editing in plants using a
CRISPR/Cas system, Cell Res, 23(10): 1229-1232
Fichtner F., Castellanos R.U., and Ülker B., 2014, Precision
genetic modifications: a new era in molecular biology and
crop improvement, Planta, 239(4): 921-939
Gaj T., Gersbach C.A., and Barbas C.F., 2013, ZFN, TALEN,
and CRISPR/Cas-based methods for genome engineering,
Trends in Biotechnology, 31(7): 397-405
Garneau J.E., Dupuis M.È., Villion M., Romero D.A.,
Barrangou R., Boyaval P., Fremaux C., Horvath P.,
Magadán A.H., and Moineau S., 2010, The CRISPR/Cas
bacterial immune system cleaves bacteriophage and
plasmid DNA, Nature, 468(7320): 67-71
Hanin M., Volrath S., Bogucki A., Briker M., Ward E., and
Paszkowski J., 2001, Gene targeting in Arabidopsis, Plant
J., 28(6): 671-677
Haun W., Coffman A., Clasen B.M., Demorest Z.L., Lowy A.,
Ray E., Retterath A., Stoddard T., Juillerat A., Cedrone F.,
Mathis L., Voytas D.F., and Zhang F., 2014, Improved
soybean oil quality by targeted mutagenesis of the fatty
acid desaturase 2 gene family, Plant Biotechnol J., 12(7):
934-940
Horvath P., and Barrangou R., 2010, CRISPR/Cas, the immune
system of bacteria and archaea, Science, 327(5962):
167-170
Iida S., and Terada R., 2005, Modification of endogenous
natural genes by gene targeting in rice and other higher
plants, Plant Mol. Biol., 59(1): 205-219
Jia H., and Wang N., 2014, Targeted Genome Editing of Sweet
Orange Using Cas9/sgRNA, PLoS One, 9(4): e93806
Jiang W.Z., Zhou H.B., Bi H.H., Fromm M., Yang B., and
Weeks
D.P.,
2013,
Demonstration
of
CRISPR/Cas9/sgRNA-mediated
targeted
gene
modification in Arabidopsis, tobacco, sorghum and rice,
Nucleic Acids Res., 41(20): e188
Jinek M., Chylinski K., Fonfara I., Hauer M., Doudna J.A., and
Charpentier E., 2012, A programmable dual-RNA-guided
DNA endonuclease in adaptive bacterial immunity,
Science, 337(6096): 816-821
Lee K.Y., Lund P., Lowe K., and Dunsmuir P., 1990,
Homologous recombination in plant cells after
Agrobacterium-mediated transformation, Plant Cell,
2(5): 415-425
Lei Y., Lu L., Liu H.Y., Li S., Xing F., and Chen L.L., 2014,
CRISPR-P: a web tool for synthetic single-guide RNA
design of CRISPR-system in plants, Mol. Plant, 7(9):
1494-1496
Li J., Zhang Y., Chen K.L., Shan Q.W., Wang Y.P., Liang Z.,
and Gao C.X., 2013, CRISPR/Cas: a novel way of
RNA-guided genome editing, Yichuan(Hereditas), 35(11):
1265-1273(
李君
,
张毅
,
陈坤玲
,
单奇伟
,
王延鹏
,
梁振
,
高彩霞
, 2013, CRISPR/Cas: RNA
靶向的基因组定向编
辑新技术
,
遗传
, 35(11): 1265-1273)
Li J.F., Norville J.E., Aach J., McCormack M., Zhang D.D.,
Bush J., Church G.M., and Sheen J., 2013, Multiplex and
homologous recombination-mediated genome editing in
Arabidopsis and Nicotiana benthamiana using guide RNA
and Cas9, Nat. Biotechnol, 31(8): 688-691
Li T., Liu B., Spalding M.H., Weeks D.P., and Yang B., 2012,
High-efficiency TALEN-based gene editing produces
disease-resistant rice, Nat. Biotechnol, 30(5): 390-392
Liu L., and Fan X.D., 2014, CRISPR-Cas system: a powerful
tool for genome engineering, Plant Mol. Biol., 85(3):
209-218
Liu Y.J., Xu Y.Y., Xiao J., Ma Q.B., Li D., Xue Z., and Chong
K., 2011, OsDOG, a gibberellin-induced A20/AN1
zinc-finger
protein,
negatively
regulates
gibberellin-mediated cell elongation in rice, J. Plant
Physiol., 168(10): 1098-1105
Lloyd A., Plaisier C.L., Carroll D., and Drews G.N., 2005,
Targeted mutagenesis using zinc-finger nucleases in
Arabidopsis, PNAS, 102(6): 2232-2237
Lor V.S., Starker C.G., Voytas D.F., Weiss D., and Olszewski
