Proteomics reveals pathways linked to septoria canker resistance and susceptibility in Populus trichocarpa

R. Lenz, Him K. Shrestha, A. Carrell, J. Labbé, R. Hettich, P. Abraham, J. LeBoldus
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引用次数: 1

Abstract

A major threat to forest ecosystems and plantation forestry is the introduction of a non-native pathogen. Among non-domesticated populations with relatively high levels of genetic diversity, a measurable range of susceptibility to resistance can be expected. Identifying genetic determinants of resistant and susceptible individuals can inform the development of new strategies to engineer disease resistance. Here we describe pathogen-induced changes in the proteome of Populus trichocarpa stem tissue in response to Sphaerulia musiva (Septoria canker). This hemibiotrophic fungal pathogen causes stem canker disease in susceptible poplar genotypes. Proteomics analyses were performed on stem tissue harvested across 0-, 12-, 24- and 48-h post-inoculation with Septoria from three genotypes including one resistant (BESC-22) and two susceptible [BESC-801; Nisqually-1 (NQ-1)]. In total, 11,897 Populus proteins at FDR <0.01 were identified across all time points and genotypes. Analysis of protein abundances between genotypes revealed that the resistant poplar genotype (BESC-22) mounts a rapid and sustained defense response involving pattern recognition receptors, calcium signaling proteins, SAR inducers, transcriptional regulators, resistance proteins, and proteins involved with the hypersensitive response. One susceptible genotype (BESC-801) had a downregulated and delayed defense response whereas the second susceptible genotype (NQ-1) lacked a distinct pattern. Overall, the proteome-wide and protein-specific trends suggest that responses to the Septoria canker infection are genotype-specific for the naïve host, Populus trichocarpa.
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蛋白质组学揭示了与毛果杨溃疡病抗性和易感性相关的途径
对森林生态系统和人工林的主要威胁是外来病原体的引入。在遗传多样性水平相对较高的非驯化种群中,可以预期对抗性的易感性有一个可测量的范围。确定耐药和易感个体的遗传决定因素可以为制定新的工程抗病策略提供信息。在这里,我们描述了病原菌诱导的毛杨茎组织蛋白质组的变化,以响应Sphaerulia musiva (Septoria canker)。这种半生物营养真菌病原菌在易感杨树基因型中引起茎溃疡病。对接种Septoria后0、12、24和48小时收获的3种基因型的茎组织进行蛋白质组学分析,包括1种抗性基因型(BESC-22)和2种易感基因型(BESC-801);Nisqually-1 (NQ-1)]。在所有时间点和基因型中,共鉴定出11,897个FDR <0.01的杨树蛋白。基因型间蛋白丰度分析表明,抗性杨树基因型(BESC-22)具有快速和持续的防御反应,涉及模式识别受体、钙信号蛋白、SAR诱导剂、转录调节因子、抗性蛋白和超敏反应相关蛋白。一个易感基因型(BESC-801)具有下调和延迟的防御反应,而另一个易感基因型(NQ-1)缺乏明显的模式。总的来说,蛋白质组范围和蛋白质特异性趋势表明,对于naïve宿主trichocarpa来说,对脓毒菌感染的反应是基因型特异性的。
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