Mireia Gómez-Gallego, Damien Sellier, Alan Dickson, Martin K-F Bader, Sebastian Leuzinger, Nari Williams
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引用次数: 0
Abstract
Phloem plays a major role in plant physiology, health and growth. However, little research has addressed the impact of biotic and abiotic stressors on phloem structure and development. This study extends recent interest on stress impact on phloem to further understand its physiological limits by exploring a common combination of stressors within forest systems: reduced light availability and concomitant foliar pathogenic infection. We compared juvenile Pinus radiata D. Don. plants growing under optimal light conditions to plants growing under reduced light availability and exposure to pathogenic infection. We monitored foliar gas exchange and took destructive samples for nonstructural carbohydrate (NSC) analysis and phloem anatomy in spring and early summer. We used software-assisted image analysis to determine cell composition and area of conducting phloem, and a fluid dynamics model to derive phloem hydraulic parameters. Phloem showed environmental plasticity within the same growing season. We found changes in phloem anatomy in shaded and infected plants, including an increased sieve cell density and permeability, and reduced cell wall thickness. While intrinsic phloem hydraulic efficiency was maintained at the tissue level in stressed plants, the reduction in phloem cross-sectional area resulted in an eventual decline in phloem sap flow rate. Thus, phloem cross-sectional area was dynamically adjusted to match reduced translocation requirements. In addition, shaded and infected plants experienced reduced growth and C assimilation, as well as greater necrotic photosynthetic tissue, but showed similar levels of total NSC than control plants. The high levels of NSC observed in our stressed plants are an important finding that suggests that radial growth cessation and, by association, phloem formation impairment are induced by sink limitation instead of reduced carbohydrate supply to the meristem.
韧皮部在植物的生理、健康和生长中起着重要作用。然而,关于生物和非生物胁迫源对韧皮部结构和发育的影响的研究很少。本研究通过探索森林系统中常见的压力源组合:光可用性降低和伴随的叶面致病性感染,扩展了最近对韧皮部胁迫影响的兴趣,进一步了解其生理极限。我们比较了辐射松(Pinus radiata D. Don)幼松。在最佳光照条件下生长的植物与在光照利用率降低和暴露于致病性感染下生长的植物比较。在春季和初夏对叶片气体交换进行监测,并采集破坏性样品进行非结构碳水化合物分析和韧皮部解剖。我们使用软件辅助图像分析来确定导电韧皮部的细胞组成和面积,并使用流体动力学模型来推导韧皮部的水力参数。韧皮部在同一生长季节表现出环境可塑性。我们发现遮荫和侵染植物韧皮部解剖结构发生了变化,包括筛细胞密度和通透性增加,细胞壁厚度减少。虽然韧皮部固有水力效率维持在组织水平,但韧皮部截面积的减少最终导致韧皮部液流速率的下降。因此,韧皮部横截面积被动态调整以匹配减少的转运需求。此外,遮荫和侵染植株的生长和C同化减少,光合组织坏死加剧,但总NSC水平与对照植株相近。在我们的胁迫植物中观察到的高水平NSC是一个重要的发现,表明径向生长停止和韧皮部形成损伤是由汇限制引起的,而不是由分生组织碳水化合物供应减少引起的。
期刊介绍:
Plant, Cell & Environment is a premier plant science journal, offering valuable insights into plant responses to their environment. Committed to publishing high-quality theoretical and experimental research, the journal covers a broad spectrum of factors, spanning from molecular to community levels. Researchers exploring various aspects of plant biology, physiology, and ecology contribute to the journal's comprehensive understanding of plant-environment interactions.
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