Does stomatal patterning in amphistomatous leaves minimize the CO2 diffusion path length within leaves?

Jacob Lewis Watts, Graham J Dow, Thomas N Buckley, Chris D Muir
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Abstract

Photosynthesis is co-limited by multiple factors depending on the plant and its environment. These include biochemical rate limitations, internal and external water potentials, temperature, irradiance, and carbon dioxide (CO2). Amphistomatous leaves have stomata on both abaxial and adaxial leaf surfaces. This feature is considered an adaptation to alleviate CO2 diffusion limitations in productive environments where other factors are not limiting as the diffusion path length from stomate to chloroplast is effectively halved. Plants can also reduce CO2 limitations through other aspects of optimal stomatal anatomy: stomatal density, distribution, patterning, and size. A number of studies have demonstrated that stomata are overdispersed on a single leaf surface; however, much less is known about stomatal anatomy in amphistomatous leaves, especially the coordination between leaf surfaces, despite their prevelance in nature and near ubiquity among crop species. Here we use novel spatial statistics based on simulations and photosynthesis modeling to test hypotheses about how amphistomatous plants may optimize CO2 limitations in the model angiosperm Arabidopsis thaliana grown in different light environments. We find that 1) stomata are overdispersed, but not ideally dispersed, on both leaf surfaces across all light treatments; 2) abaxial and adaxial leaf surface patterning are independent; and 3) the theoretical improvements to photosynthesis from abaxial-adaxial stomatal coordination are miniscule (≪ 1%) across the range of feasible parameter space. However, we also find that 4) stomatal size is correlated with the mesophyll volume that it supplies with CO2, suggesting that plants may optimize CO2 diffusion limitations through alternative pathways other than ideal, uniform stomatal spacing. We discuss the developmental, physical, and evolutionary constraits which may prohibit plants from reaching the theoretical adaptive peak of uniform stomatal spacing and inter surface stomatal coordination. These findings contribute to our understanding of variation in the anatomy of amphistomatous leaves.
双口叶片的气孔模式是否使CO2在叶片内的扩散路径长度最小化?
光合作用受到多种因素的共同限制,这取决于植物及其环境。这些包括生化速率限制,内部和外部水势,温度,辐照度和二氧化碳(CO2)。两口生叶在叶的背面和正面都有气孔。这一特征被认为是一种适应,以减轻二氧化碳在生产环境中的扩散限制,在其他因素不受限制的情况下,从气孔到叶绿体的扩散路径长度有效地减半。植物还可以通过最佳气孔解剖的其他方面来减少二氧化碳的限制:气孔密度、分布、模式和大小。许多研究表明,气孔在单叶表面过度分散;然而,尽管它们在自然界中普遍存在,在作物物种中几乎无处不在,但人们对双气孔叶片的气孔解剖学知之甚少,特别是叶片表面之间的协调。本文采用基于模拟和光合作用模型的空间统计方法,验证了在不同光环境下生长的模式被子植物拟南芥(Arabidopsis thaliana)如何优化CO2限制的假设。研究发现:1)在所有光照处理下,气孔在叶片表面都是过度分散的,但不是理想的;2)叶片背面和正面的图案是独立的;3)在可行的参数空间范围内,从理论上讲,从轴向和轴向气孔协调对光合作用的改善是微小的(≪1%)。然而,我们也发现4)气孔大小与其提供CO2的叶肉体积相关,这表明植物可能通过其他途径优化CO2扩散限制,而不是理想的、均匀的气孔间距。我们讨论了可能阻止植物达到均匀气孔间距和表面间气孔协调的理论适应峰值的发育、物理和进化限制。这些发现有助于我们理解分口叶片的解剖学变异。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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