Basic HTML Version
杨飞等
, 2011,
转基因技术在植物耐盐研究中的应用
,
分子植物育种
Vol.9 No.16 (doi: 10.5376/mpb.cn.2011.09.0016)
1117
杂,几乎涉及从植株到器官、组织、生理生化直至
分子的各个水平,这就给耐盐基因工程带来很大难
度和挑战。相信随着对植物耐盐机理以及耐盐分子
生物学研究的不断深入和生物技术的开拓创新,加
上作物遗传转化技术的日臻完善,将有更多的耐盐
转基因作物应用于生产实践,并最终培育出能用于
生产实践的耐盐作物品种,使开发广袤的盐碱地成
为现实,从而推动我国和世界盐碱地及次生盐碱地
的开发利用。
作者贡献
杨飞、鲍维巨、吴国泉是本研究的实验设计和实验研
究的执行人;杨飞、林雁完成数据分析,论文初稿的写作;
方巍,吴菊,林林,李元梅参与实验设计,试验结果分析;
鲍维巨、吴国泉是项目的构思者及负责人,指导实验设计,
数据分析,论文写作与修改。全体作者都阅读并同意最终的
文本。
致谢
本研究由浙江省科技计划项目课题(2009C32037)资助。
参考文献
Abebe T., C.Guenzi A., Martin B., and C.Cushman J., 2003,
Tolerance of mannitol-accumulating transgenic wheat to
water stress and salinity, Plant Physiol., 131(4): 1748-1755
An S.H., Choi H.W., Hwang I.S., Hong J.K., and Hwang B.K.,
2008, A novel pepper membrane-located receptor-like
protein gene
CaMRP1
is required for disease susceptibility,
methyl jasmonate insensitivity and salt tolerance, Plant
Mol. Biol., 67(5): 519-533
Anil G., Chandan S., Neeti S., and Anita G., 1999, Taming
abiotic stresses in plant through genetic engineering:
current strategies and perspective, Plant Sci., 143(1):
101-111
Avonce N., Leyman B., Thevelein J., and Iturriaga G., 2005,
Trehalose metabolism and glucose sensing in plants,
Biochem. Soc. Trans., 33(1): 276-279
Bahieldin A., Mahfouz H.T., Eissa H.F., Saleh O.M., Ramadan
A.M., Ahmed I.A., Dyer W.E., El-Itriby H.A., and Madkour
M.A., 2005, Field evaluation of transgenic wheat plants
stably expressing the
HVA1
gene for drought tolerance,
Physiol. Plant, 123(4): 421-427
Bing L., Zhao B.C., Shen Y.Z., Huang Z.J., and Ge R.C., 2008,
Progress of study on salt tolerance and salt tolerant related
genes in plant, Hebei Shifan Daxue Xuebao (Journal of
Hebei Normal University (Natural Sciences Edition)), 32(2):
243-248 (
邴雷
,
赵宝存
,
沈银柱
,
黄占景
,
葛荣朝
, 2008,
植物耐盐性及耐盐相关基因的研究进展
,
河北师范大
学学报
(
自然科学版
), 32(2): 243-248)
Blumwald E., 2000, Sodium transprot and salt tolerance in
plants, Curr. Opin. Cell Biol., 12: 431-434
Chen J., and Wang Z.Y., 2002, Progess in the study of plant
MYB transcription factors, Zhiwu Shengli Yu
Fenzishengwuxue Xuebao (Journal of Plant Physiology
and Molecular Biology), 28(2): 81-88 (
陈俊
,
王宗阳
,
2002,
植物
MYB
类转录因子研究进展
,
植物生理与分
子生物学学报
, 28(2): 81-88)
Chen M., Wang Q.Y., Cheng X.G., Xu Z.S., Li L.S., Ye X.G.,
Xia L.Q., and Ma Y.Z., 2007,
GmDREB2
, a soybean
DRE-binding transcription factor, conferred drought and
high-salt tolerance in transgenic plants, Biochem. Biophys.
Res. Commun., 353(2): 299-305
Chen Q., Tang H.R., Dong X.L., Hou Y.X., Luo Y., Jiang Y.,
and Huang Q.Y., 2009, Progress in the study of plant Myb
transcription factors, Giyinzuxue Yu Yingyongshengwu-
xue (Genomics and Applied Biology), 28(2): 365-372 (
陈
清
,
汤浩茹
,
董晓莉
,
侯艳霞
,
罗娅
,
蒋艳
,
黄琼瑶
,
2009,
植物
Myb
转录因子的研究进展
,
基因组学与应用
生物学
, 28(2): 365-372)
Cui R.L., and Diao X.M., 2005, Advances on cloning and
translation of the salt tolerance genes in plant, China
Biotechnology, 25(8): 25-30 (
崔润丽
,
刁现民
, 2005,
植
物耐盐相关基因克隆与转化研究进展
,
中国生物工程
杂志
, 25(8): 25-30)
Dai X.Y., Wu D.P., and Zhou J., 2007, Cloning and expression
of trehalose synthase genes in
Escherchia coli.
, Acta
Genetica Sinica, 27(2): 158-164 (
戴秀玉
,
吴大鹏
,
周坚
,
2007,
大肠杆菌海藻糖合成酶基因的克隆和表达
,
遗传
学报
, 27(2): 158-164)
Dai X.Y., Xu Y.Y., Ma Q.B., Xu W.Y., Wang T., Xue Y.B., and
Chong K., 2007, Overexpression of an R1R2R3 MYB gene,
OsMYB3R-2
, increases tolerance to freezing, drought, and
salt stress in transgenic
Arabidopsis
, Plant Physiol., 143(4):
1739-1751
Du J.Y., Chen X.Y., Li W., and Gao.Q., 2004, Expression and
regulation of genes induced by drought stress in plant,
Shengwu Jishu Tongxun (Biotechnology Bulletin), 2:
10-14 (
杜金友
,
陈晓阳
,
李伟
,
高琼
, 2004,
干旱胁迫诱
导下植物基因的表达与调控
,
生物技术通讯
, 2: 10-14)
Gao Z.M., and Peng Z.H., 2005, Construction of co-expressing
vector for glybet synthesis and salt tolerance, Linye Kexue
Yanjiu (Forest Research), 18(3): 231-235 (
高志民
,
彭镇