{"title":"How deep should we go to understand roots at the top of the world?","authors":"S?ren E. Weber, Colleen M. Iversen","doi":"10.1111/nph.19220","DOIUrl":null,"url":null,"abstract":"<p>Informed by vegetation maps across high-latitude landscapes, terrestrial biosphere models are a tool that can be used to predict changes in the composition and function of vegetation, above- and belowground, across the land surface in response to changing environmental conditions. However, terrestrial biosphere models represent vegetation characteristics at a finer grain than mapped vegetation communities. These models group plant species that colonize high-latitude biomes by their functional trait variation into plant functional types (PFTs) that characterize the impacts of plant species on, and their response to changes in, their surrounding abiotic and biotic environment. Blume-Werry <i>et al</i>. (<span>2023</span>) found that vegetation mapping units that broadly incorporate multiple plant species and functional types are too coarse, or encompass too much biological variation, to fully capture belowground plant trait variation. However, they did find that they could successfully cluster rooting depth observations into ‘Root Profile Types’, suggesting that modeling PFTs may be a useful tool to characterize above- and belowground linkages across high-latitude environments.</p><p>In many arctic and boreal ecosystems, plant roots are constrained by permafrost to a shallow ‘active layer’ of soil that thaws progressively over the course of each growing season. Blume-Werry <i>et al</i>. (<span>2023</span>) identified active layer thickness and the closely related minimum temperature of the coldest month as two of three main abiotic drivers constraining rooting depth distribution in their analysis (a third, cation exchange capacity, is more indicative of nutrient availability than a physical impediment). Furthermore, waterlogging can limit root distribution to surface, oxic soils, and can lead to a thick layer of poorly decomposed, organic peat at the soil surface with different characteristics from mineral soils (Fig. 1; Walker <i>et al</i>., <span>2003</span>). Indeed, Blume-Werry <i>et al</i>. (<span>2023</span>) found that despite similarities in species composition between wetland and graminoid tundra in CAVM mapping units, rooting depth in wetland tundra was shallower than graminoid tundra. This may indicate that waterlogged conditions can constrain rooting depth distribution, even in vegetation communities dominated by species with aerenchymatous roots. Ranging from rootless mosses and plant-like lichens to vascular graminoids and shrubs, and deciduous and evergreen trees, PFTs inhabiting the arctic tundra and boreal forest vary in their rooting depth distributions, their interactions with soil microbiota, and their ratio of belowground to aboveground tissues (e.g. root : shoot ratio; Chapin <i>et al</i>., <span>1996</span>). However, terrestrial biosphere models have often neglected the unique characteristics of the species that colonize high-latitude biomes, especially belowground (Iversen <i>et al</i>., <span>2015</span>, <span>2018</span>). While Blume-Werry <i>et al</i>. (<span>2023</span>) did not find that CAVM vegetation classifications could be used to predict and scale rooting depth distribution across the pan-Arctic, their approach can be further refined to link tundra plant rooting depth distribution with surrounding soil characteristics in models (Drewniak, <span>2019</span>).</p><p>The capability to predict belowground form and function across the vast expanse of the northern high latitudes is a tangled problem that spans spatial and temporal scales and encompasses biological and environmental considerations. The authors propose moving forward by considering ‘root functional types’. Here, we suggest a few additional paths forward so that we as a belowground research community might find the connections that unlock our understanding and prediction of belowground processes in a rapidly changing region of the world.</p><p>Blume-Werry <i>et al</i>. (<span>2023</span>) took on the important and difficult challenge of predicting root form and function from observed aboveground vegetation community composition across the pan-Arctic. The inability to capture large-scale variation in the depths of roots, and ensuing differences in modeled carbon emissions, with vegetation maps by Blume-Werry <i>et al</i>. stems from multiple possible sources, not least of which is that these maps are of aboveground vegetation. A solution proposed by the authors is to categorize ecosystems by their belowground, rather than aboveground, features. Understanding the role of the belowground in arctic and boreal ecosystems may require a belowground-focused approach coupled with remote sensing (Blume-Werry <i>et al</i>., <span>2023</span>; Yang <i>et al</i>., <span>2023</span>), mechanistic modeling, machine learning (Langford <i>et al</i>., <span>2019</span>; Shi <i>et al</i>., <span>2021</span>; Sulman <i>et al</i>., <span>2021</span>), and cross-disciplinary collaboration with empirical researchers (Sulman <i>et al</i>., <span>2021</span>; Blume-Werry <i>et al</i>., <span>2023</span>).</p>","PeriodicalId":48887,"journal":{"name":"New Phytologist","volume":null,"pages":null},"PeriodicalIF":9.4000,"publicationDate":"2023-08-26","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://onlinelibrary.wiley.com/doi/epdf/10.1111/nph.19220","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"New Phytologist","FirstCategoryId":"99","ListUrlMain":"https://onlinelibrary.wiley.com/doi/10.1111/nph.19220","RegionNum":1,"RegionCategory":"生物学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q1","JCRName":"Agricultural and Biological Sciences","Score":null,"Total":0}
引用次数: 0
Abstract
Informed by vegetation maps across high-latitude landscapes, terrestrial biosphere models are a tool that can be used to predict changes in the composition and function of vegetation, above- and belowground, across the land surface in response to changing environmental conditions. However, terrestrial biosphere models represent vegetation characteristics at a finer grain than mapped vegetation communities. These models group plant species that colonize high-latitude biomes by their functional trait variation into plant functional types (PFTs) that characterize the impacts of plant species on, and their response to changes in, their surrounding abiotic and biotic environment. Blume-Werry et al. (2023) found that vegetation mapping units that broadly incorporate multiple plant species and functional types are too coarse, or encompass too much biological variation, to fully capture belowground plant trait variation. However, they did find that they could successfully cluster rooting depth observations into ‘Root Profile Types’, suggesting that modeling PFTs may be a useful tool to characterize above- and belowground linkages across high-latitude environments.
In many arctic and boreal ecosystems, plant roots are constrained by permafrost to a shallow ‘active layer’ of soil that thaws progressively over the course of each growing season. Blume-Werry et al. (2023) identified active layer thickness and the closely related minimum temperature of the coldest month as two of three main abiotic drivers constraining rooting depth distribution in their analysis (a third, cation exchange capacity, is more indicative of nutrient availability than a physical impediment). Furthermore, waterlogging can limit root distribution to surface, oxic soils, and can lead to a thick layer of poorly decomposed, organic peat at the soil surface with different characteristics from mineral soils (Fig. 1; Walker et al., 2003). Indeed, Blume-Werry et al. (2023) found that despite similarities in species composition between wetland and graminoid tundra in CAVM mapping units, rooting depth in wetland tundra was shallower than graminoid tundra. This may indicate that waterlogged conditions can constrain rooting depth distribution, even in vegetation communities dominated by species with aerenchymatous roots. Ranging from rootless mosses and plant-like lichens to vascular graminoids and shrubs, and deciduous and evergreen trees, PFTs inhabiting the arctic tundra and boreal forest vary in their rooting depth distributions, their interactions with soil microbiota, and their ratio of belowground to aboveground tissues (e.g. root : shoot ratio; Chapin et al., 1996). However, terrestrial biosphere models have often neglected the unique characteristics of the species that colonize high-latitude biomes, especially belowground (Iversen et al., 2015, 2018). While Blume-Werry et al. (2023) did not find that CAVM vegetation classifications could be used to predict and scale rooting depth distribution across the pan-Arctic, their approach can be further refined to link tundra plant rooting depth distribution with surrounding soil characteristics in models (Drewniak, 2019).
The capability to predict belowground form and function across the vast expanse of the northern high latitudes is a tangled problem that spans spatial and temporal scales and encompasses biological and environmental considerations. The authors propose moving forward by considering ‘root functional types’. Here, we suggest a few additional paths forward so that we as a belowground research community might find the connections that unlock our understanding and prediction of belowground processes in a rapidly changing region of the world.
Blume-Werry et al. (2023) took on the important and difficult challenge of predicting root form and function from observed aboveground vegetation community composition across the pan-Arctic. The inability to capture large-scale variation in the depths of roots, and ensuing differences in modeled carbon emissions, with vegetation maps by Blume-Werry et al. stems from multiple possible sources, not least of which is that these maps are of aboveground vegetation. A solution proposed by the authors is to categorize ecosystems by their belowground, rather than aboveground, features. Understanding the role of the belowground in arctic and boreal ecosystems may require a belowground-focused approach coupled with remote sensing (Blume-Werry et al., 2023; Yang et al., 2023), mechanistic modeling, machine learning (Langford et al., 2019; Shi et al., 2021; Sulman et al., 2021), and cross-disciplinary collaboration with empirical researchers (Sulman et al., 2021; Blume-Werry et al., 2023).
根据高纬度景观的植被图,陆地生物圈模型是一种工具,可用于预测地表上和地下植被组成和功能的变化,以应对不断变化的环境条件。然而,陆地生物圈模型比绘制的植被群落更精细地代表了植被特征。这些模型将通过功能特征变化定居在高纬度生物群落中的植物物种分为植物功能类型(PFTs),PFTs表征了植物物种对周围非生物和生物环境变化的影响及其对变化的反应。Blume Werry等人。(2023)发现,广泛包含多种植物物种和功能类型的植被制图单元过于粗糙,或包含了太多的生物变异,无法完全捕捉地下植物特征变异。然而,他们确实发现,他们可以成功地将生根深度观测结果聚类为“根剖面类型”,这表明PFT建模可能是一个有用的工具,可以用来表征高纬度环境中的地上和地下联系。在许多北极和北方生态系统中,植物根系被永久冻土限制在一层浅的“活动层”土壤中,在每个生长季节逐渐融化。Blume Werry等人。(2023)在他们的分析中确定,活性层厚度和最冷月的密切相关的最低温度是限制生根深度分布的三个主要非生物驱动因素中的两个(第三个,阳离子交换能力,更能表明营养物质的可用性,而不是物理障碍)。此外,内涝会限制根系在表层有毒土壤中的分布,并会在土壤表面形成一层厚厚的分解不良的有机泥炭,其特征与矿物土壤不同(图1;Walker等人,2003年)。(2023)发现,尽管在CAVM绘图单元中,湿地和类禾本科苔原的物种组成相似,但湿地苔原的生根深度比类禾本科冻土带浅。这可能表明,积水条件会限制生根深度的分布,即使在由具有通气性根系的物种主导的植被群落中也是如此。从无根苔藓和植物状地衣到维管类禾本科植物和灌木,以及落叶和常绿树木,栖息在北极苔原和北方森林中的PFT在生根深度分布、与土壤微生物群的相互作用以及地下组织与地上组织的比例(如根 : 芽率;Chapin等人。,1996)。然而,陆地生物圈模型往往忽视了定居在高纬度生物群落,特别是地下的物种的独特特征(Iversen等人,20152018)。而Blume-Werry等人。(2023)没有发现CAVM植被分类可以用于预测和缩放泛北极地区的生根深度分布,他们的方法可以在模型中进一步完善,将苔原植物的生根深度分配与周围土壤特征联系起来(Drewniak,2019)。预测北高纬度广阔地区地下形态和功能的能力是一个复杂的问题,涉及空间和时间尺度,包括生物和环境因素。作者建议通过考虑“根函数类型”来向前推进。在这里,我们提出了一些额外的前进道路,以便我们作为地下研究社区能够找到联系,从而解锁我们对世界快速变化地区地下过程的理解和预测。Blume Werry等人。(2023)承担了从整个泛北极地区观测到的地上植被群落组成预测根系形态和功能的重要而艰巨的挑战。Blume Werry等人的植被图无法捕捉根系深度的大规模变化,以及随之而来的模拟碳排放的差异。源于多种可能的来源,尤其是这些地图是地上植被。作者提出的一个解决方案是根据地下而不是地上的特征对生态系统进行分类。了解地下环境在北极和北方生态系统中的作用可能需要一种以地下环境为重点的方法,并结合遥感(Blume Werry et al.,2023;Yang et al.,2021)、机械建模、机器学习(Langford et al.,2019;施等人,2021;Sulman等人,2021),以及与实证研究人员的跨学科合作(Sulman等人,2021;Blume Werry等人,2023)。
期刊介绍:
New Phytologist is a leading publication that showcases exceptional and groundbreaking research in plant science and its practical applications. With a focus on five distinct sections - Physiology & Development, Environment, Interaction, Evolution, and Transformative Plant Biotechnology - the journal covers a wide array of topics ranging from cellular processes to the impact of global environmental changes. We encourage the use of interdisciplinary approaches, and our content is structured to reflect this. Our journal acknowledges the diverse techniques employed in plant science, including molecular and cell biology, functional genomics, modeling, and system-based approaches, across various subfields.