Tree Plantation Systems Influence Nitrogen Retention and the Abundance of Nitrogen Functional Genes in the Solomon Islands.

IF 3.1 4区 化学 Q2 CHEMISTRY, MULTIDISCIPLINARY
Chemical Research in Chinese Universities Pub Date : 2015-12-22 eCollection Date: 2015-01-01 DOI:10.3389/fmicb.2015.01439
Frédérique Reverchon, Shahla H Bai, Xian Liu, Timothy J Blumfield
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引用次数: 0

Abstract

Tree mono-plantations are susceptible to soil nutrient impoverishment and mixed species plantations have been proposed as a way of maintaining soil fertility while enhancing biodiversity. In the Solomon Islands, mixed species plantations where teak (Tectona grandis) is inter-planted with a local tree species (Flueggea flexuosa) have been used as an alternative to teak mono-plantations and are expected to increase soil microbial diversity and modify microbial biogeochemical processes. In this study, we quantified the abundance of microbial functional genes involved in the nitrogen (N) cycle from soil samples collected in teak, flueggea, and mixed species plantations. Furthermore, we measured soil properties such as pH, total carbon (C) and total N, stable N isotope composition (δ(15)N), and inorganic N pools. Soil pH and δ(15)N were higher under teak than under flueggea, which indicates that intercropping teak with flueggea may decrease bacterial activities and potential N losses. Higher C:N ratios were found under mixed species plantations than those under teak, suggesting an enhancement of N immobilization that would help preventing fast N losses. However, inorganic N pools remained unaffected by plant cover. Inter-planting teak with flueggea in mixed species plantations generally increased the relative abundance of denitrification genes and promoted the enrichment of nosZ-harboring denitrifiers. However, it reduced the abundance of bacterial amoA (ammonia monooxygenase) genes compared to teak mono-plantations. The abundance of most denitrification genes correlated with soil total N and C:N ratio, while bacterial and archeal nitrification genes correlated positively with soil NH4 (+) concentrations. Altogether, these results show that the abundance of bacterial N-cycling functional guilds vary under teak and under mixed species plantations, and that inter-planting teak with flueggea may potentially alleviate N losses associated with nitrification and denitrification and favor N retention. Mixed plantations could also allow an increase in soil C and N stocks without losing the source of income that teak trees represent for local communities.

所罗门群岛的植树造林系统影响氮的保留和氮功能基因的丰度。
单一树种种植容易造成土壤养分贫乏,因此有人提出了混交树种种植,以此在提高生物多样性的同时保持土壤肥力。在所罗门群岛,柚木(Tectona grandis)与当地树种(Fluggea flexuosa)混合种植已被用来替代柚木单一种植,并有望增加土壤微生物多样性和改变微生物生物地球化学过程。在这项研究中,我们对从柚木、柚木和混合树种种植园采集的土壤样本中涉及氮(N)循环的微生物功能基因的丰度进行了量化。此外,我们还测量了土壤特性,如 pH 值、总碳(C)和总氮、稳定氮同位素组成(δ(15)N)以及无机氮库。柚木下的土壤 pH 值和δ(15)N 值均高于绒毛草下的土壤 pH 值和δ(15)N 值,这表明柚木与绒毛草间作可减少细菌活动和潜在的氮损失。混合树种种植下的 C:N 比值高于柚木种植下的 C:N 比值,这表明柚木提高了氮的固定性,有助于防止氮的快速流失。不过,无机氮库仍然不受植物覆盖的影响。在混交树种种植园中,柚木与红花檵木的间种通常会增加反硝化基因的相对丰度,并促进富含 nosZ 的反硝化菌的生长。不过,与柚木单一种植相比,它降低了细菌amoA(氨单氧酶)基因的丰度。大多数反硝化基因的丰度与土壤总氮和 C:N 比率相关,而细菌和原核硝化基因与土壤 NH4 (+) 浓度呈正相关。总之,这些结果表明,细菌氮循环功能区的丰度在柚木和混交树种种植下有所不同,柚木与绒毛草混交种植有可能减轻与硝化和反硝化相关的氮损失,有利于氮的保留。混合种植还可以增加土壤中的碳和氮储量,同时又不会失去柚木为当地社区带来的收入来源。
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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来源期刊
CiteScore
5.30
自引率
6.50%
发文量
152
审稿时长
3.0 months
期刊介绍: The journal publishes research articles, letters/communications and reviews written by faculty members, researchers and postgraduates in universities, colleges and research institutes all over China and overseas. It reports the latest and most creative results of important fundamental research in all aspects of chemistry and of developments with significant consequences across subdisciplines. Main research areas include (but are not limited to): Organic chemistry (synthesis, characterization, and application); Inorganic chemistry (bio-inorganic chemistry, inorganic material chemistry); Analytical chemistry (especially chemometrics and the application of instrumental analysis and spectroscopy); Physical chemistry (mechanisms, catalysis, thermodynamics and dynamics); Polymer chemistry and polymer physics (mechanisms, material, catalysis, thermodynamics and dynamics); Quantum chemistry (quantum mechanical theory, quantum partition function, quantum statistical mechanics); Biochemistry; Biochemical engineering; Medicinal chemistry; Nanoscience (nanochemistry, nanomaterials).
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