McClure Ryan, Rivas-Ubach Albert, Hixson Kim K, Farris Yuliya, Garcia Marci, Danczak Robert, Davison Michelle, Paurus Vanessa L, Jansson Janet K
Biological Sciences Division, Pacific Northwest National Laboratory, Richland, Washington, USA.
Earth and Biological Sciences Directorate, Pacific Northwest National Laboratory, Richland, Washington, USA.
mBio. 2025 Jul 9;16(7):e0040425. doi: 10.1128/mbio.00404-25. Epub 2025 May 30.
Soil microorganisms interact to carry out decomposition of complex organic carbon and nitrogen compounds, such as chitin, but the high diversity and complexity of the soil microbiome and habitat have posed a challenge to elucidating such interactions. Here, we sought to address this challenge by analysis of a model soil consortium (MSC-2) consisting of eight soil bacterial species. Our aim was to elucidate the specific roles of the member species during chitin metabolism. Samples were collected from MSC-2 incubated in chitin-enriched soil over 3 months. Multi-omics was used to understand how the community composition, transcripts, proteins, and chitin decomposition shifted over time. The data clearly and consistently revealed a temporal shift during chitin decomposition with defined contributions by individual species. A genus member (sp001905665) was a key player in early steps of chitin decomposition, with other MSC-2 members being central in carrying out later steps. These results illustrate how multi-omics applied to a defined consortium untangles the interactions between soil microorganisms.
Although soil microorganisms carry out decomposition of organic matter in soil, the details are unclear due to the complexity of the soil microbiome and the heterogeneity of the soil habitat. Understanding carbon decomposition is of vital importance to determine how the soil carbon cycle functions. This is especially important with regard to understanding the fertility of soils and their ability to support plant growth. To overcome these challenges, we investigated in considerable detail a model soil community during its decomposition of a typical soil organic molecule-chitin. By using a multi-omics approach, we were able to decipher community interactions during chitin breakdown. This information provides a basis for understanding how more complex soil microbial communities interact in nature.
土壤微生物相互作用以分解复杂的有机碳和氮化合物,如几丁质,但土壤微生物群落和栖息地的高度多样性和复杂性给阐明这种相互作用带来了挑战。在这里,我们试图通过分析由八种土壤细菌物种组成的模型土壤群落(MSC - 2)来应对这一挑战。我们的目标是阐明成员物种在几丁质代谢过程中的具体作用。从在富含几丁质的土壤中培养3个月的MSC - 2中采集样本。使用多组学方法来了解群落组成、转录本、蛋白质和几丁质分解如何随时间变化。数据清晰且一致地揭示了几丁质分解过程中的时间变化以及各个物种的明确贡献。一个属成员(sp001905665)是几丁质分解早期步骤的关键参与者,而其他MSC - 2成员在后续步骤中起核心作用。这些结果说明了应用于特定群落的多组学如何解开土壤微生物之间的相互作用。
尽管土壤微生物在土壤中进行有机物分解,但由于土壤微生物群落的复杂性和土壤栖息地的异质性,细节尚不清楚。了解碳分解对于确定土壤碳循环如何运作至关重要。这对于理解土壤肥力及其支持植物生长的能力尤为重要。为了克服这些挑战,我们相当详细地研究了一个模型土壤群落对典型土壤有机分子——几丁质的分解过程。通过使用多组学方法,我们能够解读几丁质分解过程中的群落相互作用。这些信息为理解更复杂的土壤微生物群落在自然环境中如何相互作用提供了基础。
