marker-assisted selection in wheat - ictsd

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Chapter 19 – Technical, economic and policy considerations on marker-assisted selection in crops 401countries, the technology can be used ata relatively low operational cost. At leastfor major crops such as rice, maize, wheatand soybean, significant numbers of linkedmarkers have been identified for genes ofinterest, and ongoing selection programmeshave found them to be useful for makingrapid genetic gains. Incorporating thesetools into active breeding strategies willallow more rapid and efficient improvementof varieties for target traits.As national programmes in developingcountries vary in their capacities to absorbbiotechnology tools, priority-setting andidentification of MAS strategies should bedone on a case-by-case basis, ideally supportedby strong breeding programmes.Individual national programmes will haveto be selective in their choice of technologiesand markers to ensure that the level ofinvestment is appropriate to justify the costsand produce the most rapid returns. Thismeans that, while fully functioning biotechnologylaboratories may not be feasible inall countries, initiating MAS is an importantfirst step towards using modern biotechnologyapproaches in plant improvement.As the success of biotechnology applicationsdepends on the existence of strongcrop improvement programmes, policymakersand international developmentagencies must ensure that the limited fundsallocated to traditional agricultural researchare not curtailed to support biotechnologyactivities. International aid agencies andagricultural research institutes should playa role in building research capacity withinnational programmes, encouraging public–private sector partnerships, and promotingtechnology transfer.ReferencesAyala, L., Henry, M., Gonzalez-de-Leon, D., van Ginkel, M., Mujeeb-Kazi, A., Keller, B. &Khairallah, M. 2001. A diagnostic molecular marker allowing study of Th. Intermedium derivedresistance to BYDV in bread wheat segregating populations. Theor. Appl. Genet. 102: 942–949.Bouchez, A., Hospital, F., Causse, M., Gallais, A. & Charcosset, A. 2002. Marker assisted introgressionof a favorable alleles at quantitative trait loci between maize elite lines. Genetics 162:1945–1959.Brennan, J.P. 1989. An analysis of economic potential of some innovations in a wheat breeding programme.Austr. J. Agric. Econ. 33 (1): 48–55.Byerlee, D. & Traxler, G. 2001. The role of technology spillovers and economies of size in theefficient design of agricultural research systems. In P. Pardey & M. Taylor, eds. Agricultural sciencepolicy: changing global agendas, pp. 161–186. Baltimore, MD, USA, The Johns HopkinsUniversity Press.Brown, S.M. & Kresovich, S. 1996. Molecular characterization for plant genetic resource conservation.In A.H. Paterson, ed. Genome mapping in plants, pp. 85–93. Austin, TX, USA, R.G. Landers Co.Castro, A.J., Chen, X., Corey, A., Filichkina, T., Hayes, P., Mundt, C., Richardson, K., Sandoval-Islas, S. & Vivar, H. 2003. Pyramiding and validation of quantitative trait loci (QTL) allelesdetermining resistance to barley stripe rust: effects on adult plant resistance. Crop Sci. 43:2234–2239.Chavarriaga-Aquirre, P., Maya, M.M., Tohme, J., Duque, M.C., Iglesias, C., Bonierbale, M.W.,Kresovich, S. & Kochert, G. 1999. Using microsatellites, isozymes and AFLPs to evaluate geneticdiversity and redundency in the cassava core collection and to assess the usefulness of DNA basedmarkers to maintain germplasm collections. Mol. Breeding 5: 263–273.
402Marker-assisted selection – Current status and future perspectives in crops, livestock, forestry and fishCregan, P.B., Mudge, J., Fickus, E.W., Danesh, D., Denny, R. & Young, N.D. 1999. Two simplesequence repeat markers to select for soybean cyst nematode resistance conditioned by the rhg1locus. Theor. Appl. Genet. 99: 811–818.Dean, R.E., Dahlberg, J.A., Hopkins, M.S. & Kresovich, S. 1999. Genetic redundancy and diversityamong ‘Orange’ accessions in the US sorghum collection as assessed with simple sequence repeat(SSR) markers. Crop Sci. 39: 22–32.Dilday, R.H. 1990. Contribution of ancestral lines in the development of new cultivars of rice. CropSci. 30: 905–911.Dreher, K., Morris, M.L., Khairallah, M., Ribaut, J-M., Pandey, S. & Srinivasan, G. 2002. Ismarker-assisted selection cost-effective compared with conventional plant breeding methods? Thecase of quality protein maize. In R. Evenson, V. Santaniello & D. Zilberman, eds. Economic andsocial issues in agricultural biotechnology, pp. 203–236. Wallingford, UK, CABI.Dreher, K., Khairallah, M., Ribaut, J-M. & Morris, M.L. 2003. Money matters (I): Costs of fieldand laboratory procedures associated with conventional and marker-assisted maize breeding atCIMMYT. Mol. Breeding 11: 221–234.Dubcovsky, J. 2004. Marker assisted selection in public breeding programs: the wheat experience.Crop Sci. 44: 1895–1898.Dudley, J.W. 1993. Molecular markers in plant improvement: manipulation of genes affecting quantitativetraits. Crop Sci. 33: 660–668.Eagles, H.A., Bariana, H.S., Ogbonnaya, F.C., Rebetzke, G.J., Hollamby, G.H., Henry, R.J.,Henschke, P.H. & Carter, M. 2001. Implementation of markers in Australian wheat breeding.Austr. J. Agric. Res. 52: 1349–1356.Fulton, T.M., Grandillo, S., Beck-Bunn, T., Fridman, E., Frampton, A., Lopez, J., Petiard, V.,Uhlig, J., Zamir, D. & Tanksley, S.D. 2000. Advanced backcross QTL analysis of a Lycoperssiconesculentum x Lycopersicon parvifolium cross. Theor. Appl. Genet. 100: 1025–1042.Gardiner, J., Melia-Hancock, S., Hoisington, D.A., Chao, S. & Coe, E.H. 1993. Development of acore RFLP map in maize using an immortalized F 2 population. Genetics 134: 917–930.Gowda, M., Venu, R.C., Roopalakshmi, K., Sreerekha, M.V. & Kulkarni, R.S. 2003. Advances inrice breeding. Mol. Breeding 11: 337–352.Han, F., Romagosa, I., Ullrich, S.E., Jones, B.L., Hayes, P.M. & Wesenberg, D.M. 1997. Molecularmarker-assisted selection for malting quality traits in barley. Mol. Breeding 3: 427–437.Hittalmani, S., Parco, A., Mew, T.V., Zeigler, R.S. & Huang, N. 2000. Fine mapping and DNAmarker assisted pyramiding of the three major genes for blast resistance in rice. Theor. Appl. Genet.100: 1121–1128.Hoisington, D.A. & Melchinger, A.E. 2004. From theory to practice - marker assisted selection inmaize. In: H. Lorz & G. Wenzel, eds. Biotechnology in agriculture and forestry: molecular markersystems, pp. 335–352. Berlin, Heidelberg, Germany, Springer-Verlag.Huang, N., Angelels, E.R., Domingo, J., Mgapantay, G., Singh, S., Zhang, G., Kumaravadivel,N., Bennett, J. & Kush, G.S. 1997. Pyramiding of bacterial blight resistance genes in rice: markerassisted selection using RFLP and PCR. Theor. Appl. Genet. 95: 313–320.Jenkins, S. & Gibson, N. 2002. High-throughput SNP genotyping. Comp. Funct. Genom. 3: 57–66.Lagudah, E.S., Moullet, O. & Appels, R. 1997. Map-based cloning of a gene sequence encodinga nucleotide binding domain and a leucine-rich region at the Cre3 nematode resistance locus ofwheat. Genome 40: 659–665.
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iiiContentsAcknowledgementsForeword
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Section v - marker-assisted selecti
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viiForewordSince almost the beginni
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ixAbbreviations and acronymsAATFAB-
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xiFIVIMSFNPFSCFSILGABIGASGCAGCPGDPG
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xiiiOBMOECDOIEOPVPAGEPBRsPCRPGRFAPI
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xvContributorsAmalia BaroneProfesso
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xviiElcio Perpétuo GuimarãesSenio
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xixAndrea SonninoSenior Agricultura
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Chapter 1Marker-assisted selection
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Chapter 1 - An overview of the issu
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Chapter 3Molecular markers for use
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This book provides a comprehensive
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