Buckley Christopher R, Caine Robert S, Gray Julie E
Department of Molecular Biology and Biotechnology, University of Sheffield, Sheffield, United Kingdom.
Front Plant Sci. 2020 Feb 11;10:1783. doi: 10.3389/fpls.2019.01783. eCollection 2019.
Rice ( L.) contributes to the diets of around 3.5 billion people every day and is consumed more than any other plant. Alarmingly, climate predictions suggest that the frequency of severe drought and high-temperature events will increase, and this is set to threaten the global rice supply. In this review, we consider whether water or heat stresses in crops - especially rice - could be mitigated through alterations to stomata; minute pores on the plant epidermis that permit carbon acquisition and regulate water loss. In the short-term, water loss is controlled alterations to the degree of stomatal "openness", or, in the longer-term, by altering the number (or density) of stomata that form. A range of molecular components contribute to the regulation of stomatal density, including transcription factors, plasma membrane-associated proteins and intercellular and extracellular signaling molecules. Much of our existing knowledge relating to stomatal development comes from research conducted on the model plant, . However, due to the importance of cereal crops to global food supply, studies on grass stomata have expanded in recent years, with molecular-level discoveries underscoring several divergent developmental and morphological features. Cultivation of rice is particularly water-intensive, and there is interest in developing varieties that require less water yet still maintain grain yields. This could be achieved by manipulating stomatal development; a crop with fewer stomata might be more conservative in its water use and therefore more capable of surviving periods of water stress. However, decreasing stomatal density might restrict the rate of CO uptake and reduce the extent of evaporative cooling, potentially leading to detrimental effects on yields. Thus, the extent to which crop yields in the future climate will be affected by increasing or decreasing stomatal density should be determined. Here, our current understanding of the regulation of stomatal development is summarised, focusing particularly on the genetic mechanisms that have recently been described for rice and other grasses. Application of this knowledge toward the creation of "climate-ready" rice is discussed, with attention drawn to the lesser-studied molecular elements whose contributions to the complexity of grass stomatal development must be understood to advance efforts.
水稻(Oryza sativa L.)每天为全球约35亿人提供食物,其消费量超过其他任何植物。令人担忧的是,气候预测表明,严重干旱和高温事件的发生频率将会增加,这将威胁到全球水稻供应。在本综述中,我们探讨了作物(尤其是水稻)中的水分或热胁迫是否可以通过改变气孔来缓解;气孔是植物表皮上的微小孔隙,可用于获取碳并调节水分流失。在短期内,水分流失通过改变气孔的“开放度”来控制,或者在长期内,通过改变形成的气孔数量(或密度)来控制。一系列分子成分参与气孔密度的调节,包括转录因子、质膜相关蛋白以及细胞内和细胞外信号分子。我们目前关于气孔发育的许多知识来自对模式植物拟南芥的研究。然而,由于谷类作物对全球粮食供应的重要性,近年来对禾本科植物气孔的研究有所增加,分子水平的发现突出了一些不同的发育和形态特征。水稻种植尤其耗水,因此人们希望培育出需水量较少但仍能保持谷物产量的品种。这可以通过操纵气孔发育来实现;气孔较少的作物可能在水分利用上更为保守,因此更有能力在水分胁迫时期存活下来。然而,降低气孔密度可能会限制二氧化碳的吸收速率,并减少蒸发冷却的程度,从而可能对产量产生不利影响。因此,未来气候下作物产量受气孔密度增加或减少影响的程度应该确定。在这里,我们总结了目前对气孔发育调控的理解,特别关注最近描述的水稻和其他禾本科植物的遗传机制。讨论了将这些知识应用于培育“适应气候变化”水稻的问题,并提请注意那些研究较少的分子元件,必须了解它们对禾本科植物气孔发育复杂性的贡献,才能推动相关工作的进展。
