理论证据表明，根系穿透力与土壤紧实度相互作用，影响硝酸盐的捕获。

Theoretical evidence that root penetration ability interacts with soil compaction regimes to affect nitrate capture.

机构信息

Department of Plant Science, The Pennsylvania State University, University Park, PA 16802, USA.

出版信息

Ann Bot. 2022 Feb 11;129(3):315-330. doi: 10.1093/aob/mcab144.

DOI:10.1093/aob/mcab144

PMID:34850823

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8835659/

Abstract

BACKGROUND AND AIMS

Although root penetration of strong soils has been intensively studied at the scale of individual root axes, interactions between soil physical properties and soil foraging by whole plants are less clear. Here we investigate how variation in the penetration ability of distinct root classes and bulk density profiles common to real-world soils interact to affect soil foraging strategies.

METHODS

We utilize the functional-structural plant model 'OpenSimRoot' to simulate the growth of maize (Zea mays) root systems with variable penetration ability of axial and lateral roots in soils with (1) uniform bulk density, (2) plow pans and (3) increasing bulk density with depth. We also modify the availability and leaching of nitrate to uncover reciprocal interactions between these factors and the capture of mobile resources.

KEY RESULTS

Soils with plow pans and bulk density gradients affected overall size, distribution and carbon costs of the root system. Soils with high bulk density at depth impeded rooting depth and reduced leaching of nitrate, thereby improving the coincidence of nitrogen and root length. While increasing penetration ability of either axial or lateral root classes produced root systems of comparable net length, improved penetration of axial roots increased allocation of root length in deeper soil, thereby amplifying N acquisition and shoot biomass. Although enhanced penetration ability of both root classes was associated with greater root system carbon costs, the benefit to plant fitness from improved soil exploration and resource capture offset these.

CONCLUSIONS

While lateral roots comprise the bulk of root length, axial roots function as a scaffold determining the distribution of these laterals. In soils with high soil strength and leaching, root systems with enhanced penetration ability of axial roots have greater distribution of root length at depth, thereby improving capture of mobile resources.

摘要

背景与目的

尽管已经深入研究了单个根轴尺度上的强土根穿透问题，但土壤物理特性与整株植物的土壤觅食之间的相互作用仍不清楚。在这里，我们研究了不同根类别的穿透能力变化以及常见于现实土壤中的体密度分布如何相互作用，从而影响土壤觅食策略。

方法

我们利用功能结构植物模型“OpenSimRoot”来模拟具有可变轴向和侧根穿透能力的玉米（Zea mays）根系在具有（1）均匀体密度、（2）犁底层和（3）随深度增加体密度的土壤中的生长情况。我们还修改了硝酸盐的可用性和淋失，以揭示这些因素与移动资源捕获之间的相互作用。

主要结果

具有犁底层和体密度梯度的土壤会影响整个根系的大小、分布和碳成本。深土壤中高体密度会阻碍根系的生长和降低硝酸盐的淋失，从而提高氮素和根长的吻合度。虽然增加轴向或侧根类别的穿透能力会产生类似的净根长，但增强轴向根的穿透能力会增加更深土壤中根长的分配，从而放大氮素的获取和地上生物量。虽然增强两种根类别的穿透能力都会增加根系的碳成本，但改善土壤探测和资源捕获对植物适应性的好处会抵消这些成本。

结论

虽然侧根构成了根长的大部分，但轴向根作为确定这些侧根分布的支架。在土壤强度高和淋失严重的土壤中，具有增强轴向根穿透能力的根系在更深的土壤中有更大的根长分布，从而更好地捕获移动资源。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/93e5/8835659/7c65f2c20a3c/mcab144f0001.jpg

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理论证据表明，根系穿透力与土壤紧实度相互作用，影响硝酸盐的捕获。

Theoretical evidence that root penetration ability interacts with soil compaction regimes to affect nitrate capture.

机构信息

Department of Plant Science, The Pennsylvania State University, University Park, PA 16802, USA.