增强花粉管在高温下的性能有助于番茄耐高温果实的生产。

Sorel Valere Ouonkap Yimga, Meenakshisundaram Palaniappan, Kelsey Pryze, Emma Jong, Mohammad Foteh Ali, Benjamin Styler, Rasha Althiab Almasaud, Alexandria F. Harkey, Robert W. Reid, Ann E. Loraine, Steven E. Smith, Gloria K. Muday, James B. Pease, Ravishankar Palanivelu, Mark A. Johnson
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引用次数: 0

摘要

在关键的生殖期,极端温度的上升威胁着主要谷物和水果作物的产量。开花植物的繁殖依赖于足够数量的花粉粒的发育,以及花粉粒产生细胞延伸(花粉管)的能力,花粉管通过雌蕊伸长,将精子细胞输送到雌配子进行双重受精。生命周期的这些关键阶段对温度很敏感,并限制了高温(HT)条件下的生产力。以往的研究已经调查了高温对花粉发育的影响,但对于在花粉管生长阶段施加高温如何影响生育力却知之甚少。在这里,我们将番茄作为示范水果作物,利用栽培品种在异常炎热的生长季节生产水果的优势,确定高温如何影响花粉管的生长阶段。我们发现,仅在花粉管生长阶段接触高温,对热敏感栽培品种的果实生物量和结实率的限制比对耐高温栽培品种更明显。重要的是,我们发现耐高温的塔毛利帕斯(Tamaulipas)栽培品种的花粉管在高温下的体内和体外生长都有所增强。通过分析花粉管转录组对高温的反应,我们对花粉管细胞耐热性的分子基础提出了假设,并确定了与生殖耐热性相关的两种反应模式(应激反应的诱导增强,以及受热应激抑制的生长途径的基础水平提高)。重要的是,我们定义了花粉管应激反应的关键组成部分,确定了增强的 ROS 平衡和花粉管胼胝质的合成与沉积是塔毛利帕斯花粉管生殖耐热性的重要组成部分。我们的工作确定了花粉管生长阶段是提高生殖耐热性的可行目标,并界定了在高温条件下能够结果的作物品种中发生改变的关键途径。
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Enhanced pollen tube performance at high temperature contributes to thermotolerant fruit production in tomato.
Rising temperature extremes during critical reproductive periods threaten the yield of major grain and fruit crops. Flowering plant reproduction depends on development of sufficient numbers of pollen grains and on their ability to generate a cellular extension, the pollen tube, which elongates through the pistil to deliver sperm cells to female gametes for double fertilization. These critical phases of the life cycle are sensitive to temperature and limit productivity under high temperature (HT). Previous studies have investigated the effects of HT on pollen development, but little is known about how HT applied during the pollen tube growth phase affects fertility. Here, we used tomato as a model fruit crop to determine how HT affects the pollen tube growth phase, taking advantage of cultivars noted for fruit production in exceptionally hot growing seasons. We found that exposure to HT solely during the pollen tube growth phase limits fruit biomass and seed set more significantly in thermosensitive cultivars than in thermotolerant cultivars. Importantly, we found that pollen tubes from the thermotolerant Tamaulipas cultivar have enhanced growth in vivo and in vitro under HT. Analysis of the pollen tube transcriptome's response to HT allowed us to develop hypotheses for the molecular basis of cellular thermotolerance in the pollen tube and we define two response modes (enhanced induction of stress responses, and higher basal levels of growth pathways repressed by heat stress) associated with reproductive thermotolerance. Importantly, we define key components of the pollen tube stress response identifying enhanced ROS homeostasis and pollen tube callose synthesis and deposition as important components of reproductive thermotolerance in Tamaulipas. Our work identifies the pollen tube growth phase as a viable target to enhance reproductive thermotolerance and delineates key pathways that are altered in crop varieties capable of fruiting under HT conditions.
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