Full text

Turn on search term navigation
Literature cited Azzimonti, G. 2012. Diversification de la resistance quantitative à la rouille brune du ble, à partir de la caracterisation des composantes de la reistance, L'institut des Sciences et Industries du Vivant et de L'Environnement, AgroParisTech. Azzimonti, G., C. Lannou, I. Sache, and H. Goyeau. 2013. Components of quantitative resistance to leaf rust in wheat cultivars: diversity, variability and specificity. Plant Pathology 62:970981. Bolton, M. D., J. A. Kolmer, and D. F. Garvin. 2008. Wheat leaf rust caused by Puccinia triticina. Molecular Plant Pathology 9:563575. Carlisle, D. J., L. R. Cooke, S. Watson, and A. E. Brown. 2002. Foliar aggressiveness of Northern Ireland isolates of Phytophthora infestans on detached leaflets of three potato cultivars. Plant Pathology 51:424434. Chung, C. L., J. M. Longfellow, E. K. Walsh, Z. Kerdieh, G. van Esbroeck, P. Balint-Kurti, and R. J. Nelson 2010. Resistance loci affecting distinct stages of fungal pathogenesis: use of introgression lines for QTL mapping and characterization in the maize - Setosphaeria turcica pathosystem. BMC Plant Biology 10:103. Deacon, J. W. 2006. Fungal Biology4th edn. Blackwell Publishing, Oxford, UK. Gandon, S., and Y. Michalakis 2000. Evolution of parasite virulence against qualitative or quantitative host resistance. Proceedings of the Royal Society B 267:985990. Garrett, K. A., and C. C. Mundt 1999. Epidemiology in mixed host populations. Phytopathology 89:984990. Geritz, S. H. A., E. Kisdi, G. Meszena, and J. A. J. Metz 1998. Evolutionary singular strategies and the adaptive growth and branching of the evolutionary tree. Evolutionary Ecology 12:3557. González, A. M., T. C. Marcel, and R. E. Niks 2012. Evidence for a minor gene–for–minor gene interaction explaining nonhypersensitive polygenic partial disease resistance. Phytopathology 102:10861093. Johnson, R. 1992. Past, present and future opportunities in breeding for disease resistance, with examples from wheat. In R. Johnson, and G. J. Jellis, eds. Breeding for Disease Resistance. Developments in Plant Pathology, pp. 322. Kluwer Academic Publishers, Dordrecht, The Netherlands. Jorge, V., A. Dowkiw, P. Faivre-Rampant, and C. Bastien 2005. Genetic architecture of qualitative and quantitative Melampsora larici-populina leaf rust resistance in hybrid poplar: genetic mapping and QTL detection. New Phytologist 167:113127. Kuo, Y., and S. Wang 2010. Broad-spectrum and durability: understanding of quantitative disease resistance. Current Opinion in Plant Biology 13:15. Lannou, C. 2012. Variation and selection of quantitative traits in plant pathogens. Annual Review of Phytopathology 50:319338. Lehman, J. S., and G. Shaner 1997. Selection of populations of Puccinia recondita f. sp. tritici for shortened latent period on a partially resistant wheat cultivar. Phytopathology 87:170176. Maynard Smith, J. 1982. Evolution and the Theory of Games. Cambridge University Press, Cambridge. McDonald, B. A., and C. Linde 2002. Pathogen population genetics, evolutionary potential, and durable resistance. Annual Review of Phytopathology 40:349379. Mundt, C. C. 2002. Use of multiline cultivars and cultivar mixtures for disease management. Annual Review of Phytopathology 40:381410. Mundt, C. C., C. Cowger, and K. A. Garrett 2002. Relevance of integrated disease management to resistance durability. Euphytica 124:245252. Palloix, A., V. Ayme, and B. Moury 2009. Durability of plant major resistance genes to pathogens depends on the genetic background, experimental evidence and consequences for breeding strategies. New Phytologist 183:190199. Pariaud, B. 2008. Agressivité de Puccinia Triticina (Agent de la Rouille Brune du blé) et son Adaptation à L'hôte - Aggressiveness of Puccinia Triticina (Causing Wheat Leaf Rust) and Adaptation to its Host, Paris XI University. Pariaud, B., V. Ravigne, F. Halkett, H. Goyeau, J. Carlier, and C. Lannou 2009a. Aggressiveness and its role in the adaptation of plant pathogens. Plant Pathology 58:409424. Pariaud, B., C. Robert, H. Goyeau, and C. Lannou 2009b. Aggressiveness components and adaptation to a host cultivar in wheat leaf rust. Phytopathology 99:869878. Pariaud, B., F. van den Berg, F. van den Bosch, S. J. Powers, O. Kaltz, and C. Lannou 2012. Shared influence of pathogen and host genetics on a trade-off between latent period and spore production capacity in the wheat pathogen, Puccinia triticina. Evolutionary Applications. 6:303312. Payne, R. W., D. A. Murray, S. A. Harding, D. B. Baird, and D. M. Soutar 2009. GenStat for Windows 12th edn. Introduction, VSN International, Hemel Hempstead. Sprent, P. 1993. Applied Nonparametric Statistical Methods, 2nd edn. Chapman and Hall, London, UK.
Word count: 687

Show less

© 2014. This work is published under http://creativecommons.org/licenses/by/3.0/ (the “License”). Notwithstanding the ProQuest Terms and Conditions, you may use this content in accordance with the terms of the License.

Abstract

This paper addresses the general concern in plant pathology that the introduction of quantitative resistance in the landscape can lead to increased pathogenicity. Hereto, we study the hypothetical case of a quantitative trait loci (QTL) acting on pathogen spore production per unit lesion area. To regain its original fitness, the pathogen can break the QTL, restoring its spore production capacity leading to an increased spore production per lesion. Or alternatively, it can increase its lesion size, also leading to an increased spore production per lesion. A data analysis shows that spore production per lesion (affected by the resistance QTL) and lesion size (not targeted by the QTL) are positively correlated traits, suggesting that a change in magnitude of a trait not targeted by the QTL (lesion size) might indirectly affect the targeted trait (spore production per lesion). Secondly, we model the effect of pathogen adaptation towards increased lesion size and analyse its consequences for spore production per lesion. The model calculations show that when the pathogen is unable to overcome the resistance associated QTL, it may compensate for its reduced fitness by indirect selection for increased pathogenicity on both the resistant and susceptible cultivar, but whereby the QTLs remain effective.

Details

Title
Quantitative resistance can lead to evolutionary changes in traits not targeted by the resistance QTLs
Author
van den Berg, Femke 1 ; Lannou, Christian 2 ; Gilligan, Christopher A 3 ; van den Bosch, Frank 1 

 Department of Computational and Systems Biology, Rothamsted Research, Harpenden, Hertfordshire, UK 
 INRA, UMR 1290 Bioger, Thiverval Grignon, France 
 Department of Plant Sciences, University of Cambridge, Cambridge, UK 
Pages
370-380
Section
Original Articles
Publication year
2014
Publication date
Mar 2014
Publisher
John Wiley & Sons, Inc.
e-ISSN
17524571
Source type
Scholarly Journal
Language of publication
English
DOI
https://doi.org/10.1111/eva.12130
ProQuest document ID
2299167613
Copyright
© 2014. This work is published under http://creativecommons.org/licenses/by/3.0/ (the “License”). Notwithstanding the ProQuest Terms and Conditions, you may use this content in accordance with the terms of the License.