marker-assisted selection in wheat

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Chapter 9 – Molecular marker-assisted selection for resistance to pathogens in tomato 159Table 4Resistant heterozygous plants obtained in some cross combinations realized for pyramiding ofresistance genesCrossPyramidedgenesGenerationAnalysed plant(number)Resistant plant(number)(137 x Momor) F 1 BC 3 xTm2a – Frl(137 x Ontario) F 1 BC 3 Ve – PtoF 1 50 7(AD17 x Okitzu) F 1 BC 4 xTm2a – Frl(AD17 x Stevens) F 1 BC 4Sw5F 1 24 5(AD17 x Ontario) F 1 BC 4 x(AD17 x Stevens) F 1 BC 4Pto – Sw5 F 1 24 6(PI15 x Stevens) F 1 BC 4 x(PI15 x Ontario) F 1 BC 4Sw5 - Pto F 2 52 29Indeed, once a marker has been set up,its use on large populations for resistancescreening is then routine. Technical facilitiesare today available for screening manysamples simultaneously and also costs forequipment are decreasing. In addition, therapid development of new molecular techniques,combined with the ever-increasingknowledge about the structure and functionof resistance genes (Hulbert et al.,2001), will help to identify new molecularmarkers for MAS, such as single nucleotidepolymorphisms (SNPs). Moreover, thanksto the International Solanaceae GenomeProject (SOL), sequencing of the tomatogenome is in progress, and in a few yearsthis will enhance information on resistancegenes. This in turn will facilitate thedevelopment of molecular markers fromtranscribed regions of the genome, therebyallowing large-scale gene-assisted selection(GAS) to be achieved.Over the coming years, selection forpathogen resistance in tomato will beunderpinned by research aimed at: mappingother resistance genes for new pathogens;developing PCR-based functional markers(Andersen and Ludderstedt, 2003); designingthe most suitable breeding schemes(Peleman and van der Voort, 2003), especiallyfor transferring QTL resistances;large-scale screening through automation;allele-specific diagnostics (Yang et al.,2004); and DNA microarrays (Borevitzet al., 2003). In effect, the combination ofnew knowledge and new tools will lead tochanges in the strategies used for breedingby exploiting the potential of integrating“omics” disciplines with plant physiologyand conventional plant breeding, a processthat will drive the evolution of MASinto genomics-assisted breeding (Morganteand Salamini, 2003; Varshney, Graner andSorrells, 2005).ACKNOWLEDGEMENTSThe authors wish to thank Mr MarkWalters for editing the manuscript andAngela Cozzolino for her technical assistance.This research was partially financedby the Ministry of Agriculture andForestry of Italy in the framework ofproject PROMAR (Plant Protection by theUse of Molecular Markers). Contributionno. 119 from the Department of Soil, Plantand Environmental Sciences.REFERENCESAmmiraju, J.S.S., Veremis, J.C., Huang, X., Roberts, P.A. & Kaloshian, I. 2003. The heat-stableroot-nematode resistance gene Mi-9 from Lycopersicon peruvianum is localized on the short armof chromosome 6. Theor. Appl. Genet. 106: 478–484.
160Marker-assisted selection – Current status and future perspectives in crops, livestock, forestry and fishAndersen, J.R. & Lubberstedt, T. 2003. Functional markers in plants. Trends Plant Sci. 8: 554–560.Bai, Y., Huang, C-C., van der Hulst, R., Meijer-Dekens, F., Bonnema, G. & Lindhout, P. 2003.QTLs for tomato powdery mildew resistance (Oidium lycopersici) in Lycopersicon parviflorumG1.1601 co-localize with two qualitative powdery mildew resistance genes. Mol. Plant - MicrobeInteract. 16: 169–176.Bai, Y., van der Hulst, R., Huang, C-C., Wei, L., Stam, P. & Lindhout, P. 2004. Mapping Ol-4, agene conferring resistance to Oidium neolycopersici and originating from Lycopersicon peruvianumLA2172, requires multi-allelic, single locus markers. Theor. Appl. Genet. 109: 1215–1223.Balint-Kurti, P.J., Dixon, M.S., Jnes, D.A., Norcott, K.A. & Jones, J.D.G. 1994. RFLP linkageanalysis of the Cf-4 and Cf-9 genes for resistance to Cladosporium fulvum in tomato. Theor. Appl.Genet. 88: 691–700.Ballvora, A., Pierre, M., van den Ackerveken, G., Chornack, S., Rossier, O., Ganal, M., Lahaye,T. & Bonas, U. 2001 Genetic mapping and functional analysis of the tomato Bs4 locus governingrecognition of the Xanthomonas campestris pv.vesicatoria AvrBs4 protein. Mol. Plant-MicrobeInteract. 14: 629–638.Barone, A., Langella, R., Ercolano, M.R., Di Matteo, A. & Monti, L. 2004 Strategies for pathogenresistance gene transfer in tomato with the aid of molecular markers. In S.G. Pandalai, ed. Recentresearch developments in genetics and breeding, pp. 211–222. Kerala, India, Research Signpost.Behare, J., Laterrot, H., Sarfatti, M. & Zamir, D. 1991. RFLP mapping of the Stemphylium resistancegene in tomato. Mol. Plant-Microbe Interact. 4: 489–492.Borevitz, J.O., Liang, D., Plouffe, D., Chang, H-S., Zhu, T., Weigel, D., Berry, C.C., Winzeler, E. &Chory, J. 2003. Large-scale identification of single-feaqture polymorphisms in complex genomes.Genome Res. 13: 513–523.Bournival, B.L., Vallejos, C.E. & Scott, J.W. 1990. Genetic analysis of resistances to race 1 and 2 ofFusarium oxysporum f. sp. lycopersici from the wild tomato Lycopersicon pennellii. Theor. Appl.Genet. 79: 641–645.Brouwer, D.J., Jones, E.S. & St Clair, D.A. 2004. QTL analysis of quantitative resistance toPhytophthora infestans (late blight) in tomato and comparisons to potato. Genome 47: 475–492.Chagué, V., Mercier, J.C., Guénard, M., de Courcel, A.G.L. & Vedel, F. 1997. Identification ofRAPD markers linked to a locus involved in quantitative resistance to TYLCV in tomato by bulkedsegregant analysis. Theor. Appl. Genet. 95: 671–677.Chunwongse, J., Bunn, T.B., Crossman, C., Jing, J. & Tanksley, S.D. 1994. Chromosomal localizationand molecular-marker tagging of the powdery mildew resistance gene (Lv) in tomato. Theor.Appl. Genet. 89: 76–79.Chunwongse, J., Chunwongse, C., Black, L. & Hanson, P. 2002. Molecular mapping of the Ph-3gene for late blight resistance in tomato. J. Hort. Sci. & Biotech. 77: 281–286.Danesh, D., Aarons, S., McGill, G.E. & Young, N.D. 1994. Genetic dissection of oligenic resistanceto bacterial wilt in tomato. Mol. Plant-Microbe Interact. 7: 464–471.De Giovanni, C., Dell’Orco, P., Bruno, A., Ciccarese, F., Lotti, C. & Ricciardi, L. 2004. Identificationof PCR-based markers (RAPD, AFLP) linked to a novel powdery mildew resistance gene (ol-2) intomato. Plant Sci. 166: 41–48.Diwan, N., Fluhr, R., Eshed, Y., Zamir, D. & Tanksley, S.D. 1999. Mapping of Ve in tomato: a geneconferring resistance to broad-spectrum pathogen, Verticillium dahliae race 1. Theor. Appl. Genet.98: 315–319.
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MARKER-ASSISTED SELECTIONCurrent st
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iiiContentsAcknowledgementsForeword
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Section v - marker-assisted selecti
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viiithe specific gene or chromosome
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CIATCIMMYTCIPCIRADcMCMDCMVCORPOICAC
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xiiISNARISSRITPGRFAJGIKARILDLDLLD-M
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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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