Weinblum Nati, Cna'ani Alon, Yaakov Beery, Sadeh Adi, Avraham Lior, Opatovsky Itai, Tzin Vered
The Albert Katz International School for Desert Studies, Jacob Blaustein Institutes for Desert Research, Ben-Gurion University of the Negev, Beersheba, Israel.
Jacob Blaustein Center for Scientific Cooperation, Jacob Blaustein Institutes for Desert Research, Ben-Gurion University of the Negev, Beersheba, Israel.
Front Plant Sci. 2021 Feb 26;12:630155. doi: 10.3389/fpls.2021.630155. eCollection 2021.
The two-spotted spider mite (TSSM; ) is a ubiquitous polyphagous arthropod pest that has a major economic impact on the tomato () industry. Tomato plants have evolved broad defense mechanisms regulated by the expression of defense genes, phytohormones, and secondary metabolites present constitutively and/or induced upon infestation. Although tomato defense mechanisms have been studied for more than three decades, only a few studies have compared domesticated cultivars' natural mite resistance at the molecular level. The main goal of our research was to reveal the molecular differences between two tomato cultivars with similar physical (trichome morphology and density) and agronomic traits (fruit size, shape, color, cluster architecture), but with contrasting TSSM susceptibility. A net house experiment indicated a mite-resistance difference between the cultivars, and a climate-controlled performance and oviposition bioassay supported these findings. A transcriptome analysis of the two cultivars after 3 days of TSSM infestation, revealed changes in the genes associated with primary and secondary metabolism, including salicylic acid and volatile biosynthesis (volatile benzenoid ester and monoterpenes). The genes, , and , encoding enzymes that synthesize the monoterpenes linalool, β-myrcene, limonene, and β-phellandrene were highly expressed in the resistant cultivar. The volatile profile of these cultivars upon mite infestation for 1, 3, 5, and 7 days, revealed substantial differences in monoterpenoid and phenylpropanoid volatiles, results consistent with the transcriptomic data. Comparing the metabolic changes that occurred in each cultivar and upon mite-infestation indicated that monoterpenes are the main metabolites that differ between cultivars (constitutive levels), while only minor changes occurred upon TSSM attack. To test the effect of these volatile variations on mites, we subjected both the TSSM and its corresponding predator, , to an olfactory choice bioassay. The predator mites were only significantly attracted to the TSSM pre-infested resistant cultivar and not to the susceptible cultivar, while the TSSM itself showed no preference. Overall, our findings revealed the contribution of constitutive and inducible levels of volatiles on mite performance. This study highlights monoterpenoids' function in plant resistance to pests and may inform the development of new resistant tomato cultivars.
二斑叶螨(TSSM;)是一种广泛存在的多食性节肢动物害虫,对番茄()产业造成重大经济影响。番茄植株已进化出广泛的防御机制,这些机制受防御基因、植物激素以及组成型存在和/或在受到侵害时诱导产生的次生代谢产物的表达调控。尽管对番茄防御机制的研究已有三十多年,但只有少数研究在分子水平上比较了驯化品种对叶螨的天然抗性。我们研究的主要目标是揭示两个番茄品种在分子水平上的差异,这两个品种具有相似的物理(表皮毛形态和密度)和农艺性状(果实大小、形状、颜色、簇状结构),但对二斑叶螨的易感性相反。一个网室实验表明了这两个品种在抗螨性上的差异,并且一个气候控制的性能和产卵生物测定支持了这些发现。对二斑叶螨侵害3天后的两个品种进行转录组分析,揭示了与初级和次级代谢相关的基因变化,包括水杨酸和挥发性物质生物合成(挥发性苯酯和单萜)。编码合成单萜芳樟醇、β-月桂烯、柠檬烯和β-水芹烯的酶的基因、和在抗性品种中高度表达。这些品种在叶螨侵害1、3、5和7天后的挥发性物质谱显示,单萜类和苯丙烷类挥发性物质存在显著差异,结果与转录组数据一致。比较每个品种以及在叶螨侵害后发生的代谢变化表明,单萜是品种间(组成型水平)不同的主要代谢产物,而在二斑叶螨攻击后只发生了微小变化。为了测试这些挥发性物质变化对叶螨的影响,我们对二斑叶螨及其相应的捕食者进行了嗅觉选择生物测定。捕食螨只被预先受到二斑叶螨侵害的抗性品种显著吸引,而对易感品种没有吸引力,而二斑叶螨本身没有偏好。总体而言,我们的研究结果揭示了挥发性物质的组成型和诱导型水平对叶螨性能的影响。这项研究突出了单萜类化合物在植物抗虫性中的作用,并可能为新的抗性番茄品种的开发提供信息。
