基因工程在草坪草育种上的应用

doi:10.11733/j.issn.1007-0435.2002.03.006

›› 2002, Vol. 10 ›› Issue (3): 184-189.DOI: 10.11733/j.issn.1007-0435.2002.03.006

基因工程在草坪草育种上的应用

郭振飞, 卢少云

华南农业大学生命科学学院草坪草研究室, 广州, 510642

收稿日期:2002-01-25 修回日期:2002-04-25 出版日期:2002-08-15 发布日期:2002-08-15
作者简介:郭振飞(1964- ),男,湖北省钟祥市人.研究员,博士生导师,1996年获国务院政府特殊津贴.多年从事植物代谢、逆境生理与生物化学的研究,近年开展植物分子生物学及草坪草生物技术研究.电话:(020)85282469,Email:zhfguo@yahoo.com
基金资助:
广东省自然科学基金(010281);“十五”国家863项目资助课题

Application of Genetic Engineering in Turfgrass Breeding

GUO Zhen-fei, LU Shao-yun

Laboratory for Turfgrass Science, College of Life Science, South China Agricultural University, Guangzhou 510642, China

Received:2002-01-25 Revised:2002-04-25 Online:2002-08-15 Published:2002-08-15

摘要/Abstract

摘要： 综述草坪草的遗传转化和基因工程在草坪草育种上的应用。

关键词: 草坪草, 基因工程, 育种

Abstract: The transformation of turfgrass and applications of genetic engineering in turfgrass breeding were reviewed in the paper.

Key words: Turfgrass, Genetic engineering, Breeding

中图分类号:

S688.4

郭振飞, 卢少云. 基因工程在草坪草育种上的应用[J]. , 2002, 10(3): 184-189.

GUO Zhen-fei, LU Shao-yun. Application of Genetic Engineering in Turfgrass Breeding[J]. , 2002, 10(3): 184-189.

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[1] Chai B,Sticklen M B.Applications of biotechnology in turfgrass genetic improvement[J].Crop Sci,1998,38:1320～1338
[2] Ha S B,Wu F S,Thorne T K.Transgenic turf-type tall fescue(Festuca arundinacea Schreb).plants regenerated from protoplasts[J].Plant Cell Rep,1992,11:601～604
[3] Wang Z Y,Takamizo T,Iglesias V A,Osusky M,Nagel J,Potrykus I,Spangenberg G.Transgenic plants of tall fescue(Festuca arundinacea Schreb.)obtained by direct gene transfer to protoplasts[J].Bio/Technology,1992,10:691～696
[4] Dalton S J,Bettany A J E,Timms E,Morris P.The effect of selection pressure on transformation frequency and copy number in transgenic plants of tall fescue(Festuca arundinacea Schreb.)[J].Plant Sci,1995,108:63～70
[5] Spangenberg G,Wang Z Y,Nagel J,Potrykus I.Protoplast culture and generation of transgenic plants in red fescue(Festuca rubra L.)[J].Plant Sci,1994,97:83～94
[6] Lee L,Laramore C L,Day P,Tumer N E.Transformation and regeneration of creeping bentgrass(Agrostis palustris Huds.)protoplasts[J].Crop Sci,1996,36:401～406
[7] Wang G R,Binding H,Posselt U K.Fertile transgenic plants from direct gene transfer to protoplants of Lolium perenne L.and Lolium multiflorum Lam.[J].J.Plant Physiol,1997,151:83～90
[8] Kuai B,Morris P.The physiological state of suspension cultu-red cells affects the expression of the β-glucuronidase gene following transformation of tall fescue(Festuca arundinacea)protoplasts[J].Plant Sci,1995,110:235～247
[9] Kaeppler H F,Gu W,Somers D A,Rines H W,Cockburn A F.Silicon carbide fiber-mediated DNA delivery into plant cells[J].Plant Cell Rep,1990,9:415～418
[10] Kaeppler H F,Somers D A,Rines H W,Cockburn A F.Silicon carbide fiber-mediated stable transformation of plant cells[J].Theor.Appl.Genet,1992,84:560～566
[11] Frame B R,Drayton P R,Bagnall S V,Lewnau C J,Bullock W P.Production of fertile transgenic maize plants by silicon carbide whisker-mediated transformation [J].Plant J,1994,6:941～948
[12] Serik O,Ainur I,Murat K,Tetsuo M,Masaki I.Silicon carbide fiber-mediated DNA delivery into cells of wheat(Triticum aestivum L.)mature embryo[J].Plant Cell Rep,1996,16:133～136
[13] Dalton S H,Bettany A J E,Timms E,Morris P.Transgenic plants of Lolium multiflorum,Lolium perenne,Festuca arund-inacea and Agrostis stolonifera by silicaon carbide fibre-mediated transformation of cell suspension cultures[J].Plant Sci,1998,132:31～43
[14] Zhong H,Bolyard M G,Srinivasan C,Sticklen M B.Transgenic plants of turfgrass(Agrostis palustris Huds)from microprojectile bombardment of embyogenic callus[J].Plant Cell Rep,1993,13:1～6
[15] Spangenber G,Wang Z Y,Wu X L,Nagel J,Iglesias V A,Potrykus I.Transgenic tall fescue(Festuca arundinacea)and red fescue(F.rubra)plant from microprojectile bombardment of embyogenic suspension cells[J].J.Plant Physiol,1995,145:693～700
[16] Spangenberg G,Wang Z Y,Nagel J.Wu X L,Potrykus I.Transgenic perennial ryegrass(Lolium perenne)plants from microprojectile bombardment of embryogenic suspension cells[J].Plant Sci,1995,108:209～217
[17] Ye X,Wang Z Y,Wu X,Potrykus I,Spangenberg G.Transgenic Italian ryegrass(Lolium multiflorum)plants from microprojectile bombardment of embryogenic suspension cel-ls [J].Plant Cell Rep,1997,16:379～384
[18] Cho M J,Ha C D,Lemaux P G.Production of transgenic tall fescue and red fescue plants by particle bombardment of mature seed-derived highly regenerative tissues[J].Plant Cell Reports,2000,19:1084～1089
[19] Warkentin D,Chai B,Hajela R K,Zhong H,Sticklen M B.Development of transgenic creeping bentgrass(Agrostis palu-stris Huds.)for fungal disease resistnce[A].In:Sticklen M B,Kenna M P(eds).Turfgrass biotechnology-Cell and molecular genetic approaches to turfgrass improvement[C].Michigan:Ann Arbor Press,1997.153～161
[20] Liu C N,Zhong H,bargas J,Penner D,Sticklen M.Prevention of fungal diseases in transgenic bialaphos and glufosinate-resistant creeping bentgrass(Agrostis palustris L.)[J].Weed Sci,1998,46:139～146
[21] Meyer W,Zhang G,Lu S,Chen S, Chen T A, Funk R.Transformation of Kentucky bluegrass(Poa pratensis L.)with betaine aldehyde dehydrogenase gene for salt and drought tolerance[A].Annual Meetings Abstracts-American Society of Agronomy,Crop Science Society of America,Soil Science Society of American[C].Minneapolis Minnesota.November 5～9,2000.167
[22] 马忠华,张云芳,徐传祥,陈文峻,尹红华,蒯本科.早熟禾的组织培养和基困枪介导的基因转化体系的初步建立[J].复旦大学学报,1999,38:540～544
[23] Gould J,Devey M,Hasegawa O,Ulian E,Peterson G,Smith R H.Transformation of Zea mays L.using Agrobacterium tumef-actiens and shoot apex[J].Plant Physiol,1991,95:426～434
[24] Ishida Y,Saito H,Ohta S,Hiei Y,Komari T,Kumashiro T.High efficiency transformation of maize(Zea mays L.)medi-ated by Agrobacterium tumefaciens[J].Nature Biotechnology,1996,14:745～750
[25] Park S H,Pinson S R M,Smith R H.T-DNA integration into genomic DNA of rice following Agrobacterium inocultion of isolated shoot apices[J].Plant Mol Biol,1996,32:1135～1148
[26] Liang C M,Hwan K D.Agrobacterium-mediated transformation of Korean lawngrass(Zoysia japonica)[J].J.Korean Society Horticultural Science,2000,41:455～458
[27] Shimamoto K,Terada R,Izawa T,Fujimoto H.Fertile trans-genic rice plants regenerated from transformed protoplasts[J].Nature,1989,338:274～276
[28] Wan Y,Widholm J M,Lemaux P G.Type I callus as a bombardment target for generation fertile transgenic maize(Zea mays L.)[J].Planta,1995,196:7～14
[29] Dalton S J,Bettany A J E,Timms E,Morris P.The effect of selection pressure on transformation frequency and copy number in transgenic plants of tall fescue(Festuca arundinacea Schreb.)[J].Plant Sci,1995,108:63～70
[30] Zhong H,Liu C A,Vargas J,Penner D,Sticklen M B.Simultaneous control of weeds,dollar spot,and brown patch deseases in transgenic creeping bentgrass[A].In:Sticklen M B,Kenna M P(eds).Turfgrass biotechnology-cell and molecular genetic approaches to turfgrass improvement[C].MI:Ann Arbor Press,1997.203～210
[31] Lee L,Day P.Herbicide-resistant transgenic creeping bentgra-ss[A].In:Sticklen M B,Kenna M P(ed),Turfgrass biotechnology-Cell and molecular genetic approaches to turfg-raas improvement[C].MI:Ann Arbor Press,1997.195～202
[32] Kramer C,DiMaio J,Carswell G K,Shillito R D.Selection of transformed protoplast-derived Zea mays colonies with phosphinothricin and novel assay using pH indicator[J].Planta,1993,190:454～458
[33] Hartman C L,Lee L,Day P,Tumer N E.Herbicide resistanct turfgarss(Agrostis palustris Huds.)by biolistic transformation[J].Bio/Technology,1994,12:919～923
[34] Neuhaus J M.Plant chitinases[A].In:Datta S K,Muthukris-hnan S(eds),Pathogenesis-related proteins in plants[C].CRC Press,1999.77～105
[35] Green D E,Vargas J M,Chai B,Dykema N M,Sticklen M.The use of transgenic plants to confer resistance to brown patch caused by Rhizoctonia solani in Agrostis palustris[A].In:Clark J M,Kenna M P(eds),Fate nd Management of Turfgrass Chemicals[C].Washington,DC,Oxford University Press,2000.330～341
[36] Belanger F C,Laramore C,Bonos S,Meyer W A,Day P R.Development of improved turfgrass with herbicide resistance and enhanced disease resistance through transformation[A].In:Clark J M,Kenna M P(eds),Fate and Management of Turfgrass Chemicals[C].Washington,DC:Oxford University Press,2000.325～329
[37] Mittler R,Shulaev V,Lam E.Coordinated activation of programmed cell death and defense mechanisms in transgenic tobaco plants expressing a bacterial proton pump[J].Plant Cell,1995,7:29～42
[38] Zoubenko O,Uckun F,Hur Y,Chet I,Tumer N.Plant resistance to fungal infection induced by nontoxic pokeweed antiviral protein mutants[J].Nature Biotechnology,1997,15:992～996
[39] Chen Z,Silva H,Klessig D F.Active oxygen species in the induction of plant systemic acquired resistance by salicylic acid[J].Science,1993,162:1883～1886
[40] Wu G,Shortt B J,Lawrence E B,Levine E B,Fitzsimmons K C,Shah D M.Disease resistance conferred by expression of a gene encoding H2O2-generating glucose oxidase in transgenic potato plants[J].Plant Cell,1995,7:1357～1368
[41] Wang X,Zafian P,Choudhary M,Lawton M.The PR5K receptor protein kinase from Arabidopsis thaliana is structurally relted to a family of plant defense proteins[J].Proc.Natl.Acad.Sci.USA,1996,93:2598～2602
[42] Bray E A,Bailey-Serres J,Weretilnyk E.Responses to abiotic stresses[A].In:Buchanan B,Gruissem W,Jones R(eds).Biochemistry and Molecular Biology of Plants[C].Maryland:American Socieyt of Plant Physiologists,2000.1158～1203
[43] 沈义国,杜保兴,张劲松,陈受宜.山菠菜胆碱单氧化酶基因(CMO)的克隆与分析[J].生物工程学报,2001,17(1):1～5
[44] 刘风华,郭岩,谷冬梅,陈受宜.转甜菜碱醛脱氢酶基因植物耐盐性的分析[J].遗传学报,1997,24:54～58

基因工程在草坪草育种上的应用

Application of Genetic Engineering in Turfgrass Breeding

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