What controls the availability of organic and inorganic P sources in top- and subsoils? A 33P isotopic labeling study with root exudate addition

IF 9.8 1区 农林科学 Q1 SOIL SCIENCE Soil Biology & Biochemistry Pub Date : 2023-10-01 DOI:10.1016/j.soilbio.2023.109129
Juanjuan Ai , Callum C. Banfield , Guodong Shao , Kazem Zamanian , Tobias Stürzebecher , Lingling Shi , Lichao Fan , Xia Liu , Sandra Spielvogel , Michaela A. Dippold
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Abstract

Phosphorus (P) is a major limiting nutrient for plant growth implying an often-intensive competition between microorganisms and plants in the rhizosphere. Increasing the P availability in subsoils may help to mitigate potential future P fertilizer shortages and to overcome P limitations due to droughts, which mainly affect topsoils. Root exudates provide easily available carbon and energy sources for microorganisms to mobilize soil nutrients. Nonetheless, details regarding the distinct processes underlying P mobilization from various P sources (free vs. sorbed PO43−; low molecular vs. complex organic P, e.g. ATP vs. plant litter P) as affected by root exudates are poorly understood, especially in subsoils. This study aimed to identify the controlling factors and microbial processes regulating the availability of organic and inorganic P in top- and subsoils by 33P isotopic labeling. The focus was on the potential key role of root exudates in P mobilization. We found that microbial communities in top- and subsoils used high- and low-available mineral P to a similar extent, but that the subsoil communities were much more efficient in mobilizing and incorporating complex litter-derived organic P. This capability of subsoil communities was even enhanced when root exudates were present. Microbial activity and nutrient-mobilizing mechanisms (e.g., P-related enzymes) clearly increased by root exudate addition, an effect that was generally higher in sub-than in topsoils. We conclude that subsoil communities are well capable of mobilizing and using complex organic P sources, especially if root exudates accelerate overall activity and P cycling. Thus, high root exudation is highly relevant for crops, which depend on subsoil nutrients and litter-derived P. Accordingly, detritusphere P, e.g. in subsoil root channels, is likely to be plant-available because of exudate-induced microbial P (re-)cycling processes.

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是什么控制了表土和底土中有机和无机磷源的可用性?添加根系分泌物的33P同位素标记研究
磷(P)是植物生长的主要限制性养分,这意味着根际微生物和植物之间经常存在激烈的竞争。增加底土的磷素有效性可能有助于缓解未来潜在的磷肥短缺,并克服主要影响表层土壤的干旱对磷素的限制。根系分泌物为微生物调动土壤养分提供了容易获得的碳和能量来源。尽管如此,关于不同磷源(游离与吸附PO43−)动员磷的不同过程的细节;低分子P与复杂有机P(如ATP与植物凋落物P)受根渗出物影响的关系尚不清楚,特别是在底土中。本研究旨在通过33P同位素标记,确定表层和底土有机磷和无机磷有效性的控制因素和微生物过程。重点是根系分泌物在磷动员中的潜在关键作用。研究发现,表层土壤和底土微生物群落对高效磷和低效磷的利用程度相似,但底土群落在动员和吸收复杂的凋落物有机磷方面效率更高,这种能力在根渗出物存在时甚至得到增强。根系分泌物的添加明显增加了微生物活性和养分调动机制(如磷相关酶),这种效应在下层土壤中普遍高于表层土壤。我们认为,地下群落具有很好的动员和利用复杂有机磷源的能力,特别是如果根系分泌物加速了整体活性和磷循环。因此,高根系渗出与作物高度相关,作物依赖于底土养分和凋落物衍生的磷。因此,由于渗出诱导的微生物磷(再)循环过程,碎屑层磷(例如在底土根通道中)可能是植物可利用的。
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来源期刊
Soil Biology & Biochemistry
Soil Biology & Biochemistry 农林科学-土壤科学
CiteScore
16.90
自引率
9.30%
发文量
312
审稿时长
49 days
期刊介绍: Soil Biology & Biochemistry publishes original research articles of international significance focusing on biological processes in soil and their applications to soil and environmental quality. Major topics include the ecology and biochemical processes of soil organisms, their effects on the environment, and interactions with plants. The journal also welcomes state-of-the-art reviews and discussions on contemporary research in soil biology and biochemistry.
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