温带山地森林的火后细胞外酶活性

IF 2.4 3区农林科学 Q2 SOIL SCIENCE

Soil Science Society of America Journal Pub Date : 2024-08-25 DOI:10.1002/saj2.20745

Regina O'Kelley, Abigail Evered, Hayley Peter‐Contesse, Jennifer Moore, Kate Lajtha

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引用次数: 0

摘要

野火是一种干扰，预计其频率和严重程度都会增加，这种变化可能会影响土壤生态系统中碳（C）的动态变化。火灾会改变土壤微生物可利用的碳源类型，增加热源碳和粗落木，如果树木大量死亡，则会减少根部渗出物和落叶中的碳。为了研究碳资源组成的这种变化对推动碳循环的微生物过程的影响，我们考察了俄勒冈州火灾 1 年后的土壤采样中的微生物活动，采样点的土壤烧伤严重程度从未曾烧伤到高度烧伤不等。我们发现有证据表明，火灾后根圈的引燃损失可能会减少火灾后土壤中 C 的损失。我们测量了获得碳和获得氮（N）的胞外酶的潜在活性，并通过测量可矿化的碳和氮确定了微生物资源需求的背景。在被烧毁的地点，EEA 的降幅高达 46%，但仅限于 5 厘米以下的深度，而且在土壤烧毁严重程度较高的地点降幅更大。这些结果与树木死亡驱动的地下机制相一致。我们推断，在树木死亡率高的地点，由于失去了根瘤层的启动作用，地表下的 EEAs 减少了，而死根的输入有助于矿化碳的稳定。

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Postfire extracellular enzyme activity in a temperate montane forest

Wildfire is a disturbance expected to increase in frequency and severity, changes that may impact carbon (C) dynamics in the soil ecosystem. Fire changes the types of C sources available to soil microbes, increasing pyrogenic C and coarse downed wood, and if there is substantial tree mortality, decreasing C from root exudates and leaf litter. To investigate the impact of this shift in the composition of C resources on microbial processes driving C cycling, we examined microbial activity in soil sampled from an Oregon burn 1 year after fire from sites spanning a range in soil burn severity from unburned to highly burned. We found evidence that postfire rhizosphere priming loss may reduce soil C loss after fire. We measured the potential activity of C‐acquiring and nitrogen (N)‐acquiring extracellular enzymes and contextualized the microbial resource demand using measurements of mineralizable C and N. Subsurface mineralizable C and N were unaltered by fire and negatively correlated with hydrolytic extracellular enzyme activity (EEA) in unburned, but not burned sites. EEA was lower in burned sites by up to 46%, but only at depths below 5 cm, and with greater decreases in sites with high soil burn severity. These results are consistent with a subsurface mechanism driven by tree mortality. We infer that in sites with high tree mortality, subsurface EEAs decreased due to loss of rhizosphere priming and that inputs of dead roots contributed to mineralizable C stabilization.

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来源期刊

Soil Science Society of America Journal 农林科学-土壤科学

CiteScore

5.40

自引率

3.40%

发文量

130

审稿时长

3.6 months

期刊介绍： SSSA Journal publishes content on soil physics; hydrology; soil chemistry; soil biology; soil biochemistry; soil fertility; plant nutrition; pedology; soil and water conservation and management; forest, range, and wildland soils; soil and plant analysis; soil mineralogy, wetland soils. The audience is researchers, students, soil scientists, hydrologists, pedologist, geologists, agronomists, arborists, ecologists, engineers, certified practitioners, soil microbiologists, and environmentalists. The journal publishes original research, issue papers, reviews, notes, comments and letters to the editor, and book reviews. Invitational papers may be published in the journal if accepted by the editorial board.