Price Jason S, Bever James D, Clay Keith
Indiana University, Department of Biology, 1001 East Third Street, Bloomington, IN 47405, USA.
New Phytol. 2004 Jun;162(3):729-743. doi: 10.1111/j.1469-8137.2004.01082.x.
• The strength and consistency of genotypic differences in disease resistance determine the potential for resistance evolution in host populations that rely on vegetative reproduction. Here we surveyed infection intensity of host genotypes across space and time to estimate genotypic and environmental effects on quantitative disease resistance. • Cloned fragments of 12 Euthamia graminifolia genotypes were grown in unweeded experimental fields and outdoor pots. Infection intensity was surveyed during 2 yr of natural infection by the non-systemic rust pathogen, Coleosporium asterum. • Five of six surveys detected infection intensity differences among genotypes, despite substantial variation in mean infection intensity across surveys. When resistance was defined relative to local pathogen density, 10-40% of resistance variation was due to host genotype. Although two genotypes exhibited greater resistance across environments, G × E interactions in resistance were common. Furthermore, infection intensity was unrelated to host size. • We conclude that quantitative resistance level can evolve in this system and show how logistic analysis (relative to local pathogen density) can provide insight into the mechanism(s) responsible for G × E interactions in infection intensity.
• 抗病性中基因型差异的强度和一致性决定了依赖营养繁殖的宿主种群中抗性进化的潜力。在此,我们调查了宿主基因型在空间和时间上的感染强度,以估计基因型和环境对数量抗病性的影响。
• 12种线叶泽兰基因型的克隆片段种植于未除草的试验田和室外花盆中。在由非系统性锈病病原菌紫菀鞘锈菌进行2年自然感染期间调查感染强度。
• 六项调查中有五项检测到基因型之间的感染强度差异,尽管各次调查中平均感染强度存在很大差异。当相对于当地病原菌密度定义抗性时,10%-40%的抗性变异归因于宿主基因型。尽管有两个基因型在各种环境中均表现出更强的抗性,但抗性中的基因型与环境互作很常见。此外,感染强度与宿主大小无关。
• 我们得出结论,该系统中的数量抗性水平可以进化,并展示了逻辑分析(相对于当地病原菌密度)如何能够深入了解感染强度中基因型与环境互作的机制。
