Collaborative Research: Role of soil microbiome resilience in ecosystem recovery following severe wildfire

合作研究：土壤微生物组恢复力在严重野火后生态系统恢复中的作用

• 批准号: 2114870
• 负责人: Sydney Glassman
• 金额: $ 21.12万
• 依托单位: University of California-Riverside
• 依托单位国家: 美国
• 项目类别: Standard Grant
• 财政年份: 2021
• 资助国家: 美国
• 起止时间: 2021-08-01 至 2024-07-31
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=2114870&HistoricalAwards=false
• 关键词: Collaborative; Research; Role; soil; microbiome

Wildfire is a natural feature of healthy forest ecosystems. There is concern because the frequency and intensity of these events are increasing as our climate warms. Among their many impacts, wildfire disturbances impact the microorganisms present in forest soils that catalyze a series of key ecosystem processes, ranging from the establishment of tree seedlings to the cycling of carbon and nitrogen. Research to date has revealed that the composition of soil microbiomes is altered by wildfire, but critical information is lacking on how increasingly severe wildfires in western US forests will affect the recovery of soil microbial communities, with cascading impacts on forest ecosystems. This research uses a unique series of burn pile scars in a lodgepole pine forest in northern Colorado as a proxy for the decadal recovery of the soil environment following severe wildfire. The work will use diverse microbiological and geochemical analyses to determine how soil chemistry and microbiomes change up to 50-years following fire. Insights gained here will assist with forest management following severe wildfire in the western US and will be incorporated into new educational opportunities at the participating research institutions. The project will enrich a variety of courses taught by the researchers, include training opportunities for undergraduate and graduate students, and provide cooperative extension to forest managers as well as public outreach activities.There is an increasing appreciation that changing wildfire regimes may drive long-term alterations in both above- and below-ground ecosystem structure. This research will investigate the resilience of soil microbiomes (i.e., their ability to return to pre-fire levels) following severe wildfire in lodgepole pine forests, (2) the functional implications of shifts in microbiome structure, and (3) the ability of altered soil microbiomes to support tree regeneration via rhizosphere interactions. Together, this research will test the hypothesis that altered soil chemical and physical properties drive the soil microbiome to an alternate steady state following severe wildfire, with implications for the establishment of new pine seedlings and subsequent ecosystem recovery. To test this, the work leverages a unique experimental opportunity consisting of burn pile scars throughout a forest ecosystem, thus ensuring that the chrono-sequence controls for fuel type and load, elevation, climate, and aspect. Furthermore, the approach integrates diverse analytical tools including metagenomic interrogations of soil microbiomes, mass-spectrometry characterization of soil chemistry, and vegetation manipulation greenhouse experiments. Together, our results will represent the first insights into the extent of resilience of burned soil microbiomes across a 50-year post-fire recovery period, and the ability of lodgepole pine seedlings to recruit beneficial rhizosphere communities that aid in tree re-establishment.This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.

野火是健康森林生态系统的自然特征。人们之所以担心，是因为随着气候变暖，这些事件的频率和强度都在增加。在众多影响中，野火干扰会影响森林土壤中存在的微生物，这些微生物催化一系列关键的生态系统过程，从树苗的生长到碳和氮的循环。迄今为止的研究表明，野火改变了土壤微生物组的组成，但缺乏关于美国西部森林日益严重的野火将如何影响土壤微生物群落的恢复以及对森林生态系统产生连锁影响的关键信息。这项研究利用科罗拉多州北部黑松森林中一系列独特的烧伤痕迹作为严重野火后土壤环境十年恢复的指标。这项工作将使用多种微生物和地球化学分析来确定火灾后 50 年内土壤化学和微生物组如何变化。在这里获得的见解将有助于美国西部严重野火后的森林管理，并将被纳入参与研究机构的新教育机会中。该项目将丰富研究人员教授的各种课程，包括为本科生和研究生提供培训机会，并为森林管理者提供合作推广以及公共宣传活动。人们越来越认识到，不断变化的野火状况可能会推动地上和地下生态系统结构的长期改变。这项研究将调查黑松林严重野火后土壤微生物组的恢复能力（即恢复到火灾前水平的能力），（2）微生物组结构变化的功能影响，以及（3）改变的土壤微生物组通过根际相互作用支持树木再生的能力。这项研究将共同​​检验这样的假设：严重野火后，土壤化学和物理特性的改变促使土壤微生物组进入另一种稳定状态，这对新松树幼苗的建立和随后的生态系统恢复具有影响。为了测试这一点，这项工作利用了一个独特的实验机会，包括整个森林生态系统的燃烧堆疤痕，从而确保燃料类型和负载、海拔、气候和坡向的时间序列控制。此外，该方法集成了多种分析工具，包括土壤微生物组的宏基因组询问、土壤化学的质谱表征以及植被操纵温室实验。总之，我们的研究结果将首次深入了解烧毁土壤微生物组在火灾后 50 年恢复期内的恢复程度，以及黑松幼苗招募有益根际群落以帮助树木重建的能力。该奖项反映了 NSF 的法定使命，并通过使用基金会的智力价值和更广泛的影响审查标准进行评估，被认为值得支持。

项目成果

Distinct fungal and bacterial responses to fire severity and soil depth across a ten-year wildfire chronosequence in beetle-killed lodgepole pine forests

在被甲虫杀死的黑松林中，十年野火时间序列中真菌和细菌对火灾严重程度和土壤深度的独特反应

• DOI: 10.1016/j.foreco.2023.121160
• 发表时间: 2023
• 期刊: Forest Ecology and Management
• 影响因子: 3.7
• 作者: Caiafa, Marcos V.;Nelson, Amelia R.;Borch, Thomas;Roth, Holly K.;Fegel, Timothy S.;Rhoades, Charles C.;Wilkins, Michael J.;Glassman, Sydney I.
• 通讯作者: Glassman, Sydney I.