表层海洋微尺度模型中的新兴生态学。

IF 5.1 1区 生物学 Q1 MICROBIOLOGY
mBio Pub Date : 2024-11-13 Epub Date: 2024-10-09 DOI:10.1128/mbio.02372-24
Falk Eigemann, Jutta Hoffmann, Charlotte Schampera, Shuting Liu, Luis M Bolaños, Mats Heemeyer, Craig A Carlson, Stephen Giovannoni, Ferdi L Hellweger
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引用次数: 0

摘要

微生物过程在微观尺度上运行,而现有的生态系统模型无法解决这一问题。在这里,我们提出了一个新颖的模型,该模型采用拉格朗日-欧勒混合方法,以生态学相关的时间尺度模拟 1 mL 的三维立方体。该模型模拟了单个微生物,包括三个浮游植物大小等级,以及健康、衰老和死亡的生命周期阶段;共营养和低营养异养细菌;以及分辨率为 50 µm 的溶解有机物。扩散、剪切、沉积、趋化和附着过程都得到了明确的解析。新出现的生态系统定量表征显示:(1) 共养生物主要附着在真核浮游植物上生长,几乎所有碳都来自浮游植物,而低养生物则生长在蓝藻的渗出物和裂解物上;(2) 植物圈与环境水体中基质出现的昼夜模式形成鲜明对比,颗粒附着在浮游植物上生长,几乎所有碳都来自浮游植物;(3) 浮游植物圈与环境水体中基质出现的昼夜模式形成鲜明对比,颗粒附着在浮游植物上生长。(3)附着的细菌减少了来自植物圈的碳通量,从而降低了对真核生物的趋化效率,使其低于对蓝藻的趋化效率;(4)剪切力降低了趋化效率和附着生物的适应性;(5)趋化的主要益处是找到附着伙伴。这些模式与现有观测结果一致。我们的研究提供了对海洋细菌微尺度生态学的见解,而开源代码则是该领域进一步研究的工具。 重要意义全球大量的二氧化碳固定是由海洋浮游植物完成的,其中相当一部分以溶解有机碳的形式释放出来,并由异养细菌进一步处理。因此,浮游植物和细菌之间的相互作用,即它们之间的碳通量,是全球碳和气候系统中的一个重要过程。一些细菌发展出了专门的行为特征,如游泳和附着,以增加碳的获取。这些相互作用发生在微米尺度上,例如浮游植物附近(植物圈),但现有的生物地球化学模型通常只能模拟到垂直方向 1 米或水平方向约 100 千米的尺度。我们提出了一个新的微尺度模型,并用它来预测表层海洋的通量和其他特征。该模型对各类浮游植物和细菌之间的通量以及行为特征的作用做出了重要预测,并为该领域的进一步研究提供了基础和工具。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Emergent ecology in a microscale model of the surface ocean.

Microbial processes operate at the microscale, which is not resolved by existing ecosystem models. Here, we present a novel model that simulates a 1 mL three-dimensional cube using a hybrid Lagrangian-Eulerian approach, at ecologically relevant timescales. The model simulates individual microbes, including three phytoplankton size classes with healthy, senescent, and dead lifecycle stages; copiotrophic and oligotrophic heterotrophic bacteria; and dissolved organic matter at 50 µm resolution. Diffusion, shear, sedimentation, chemotaxis, and attachment processes are explicitly resolved. The emerging quantitative representation of the ecosystem shows that (1) copiotrophs grow mostly attached to eukaryotic phytoplankters and get almost all of their carbon from them vs. oligotrophs that grow on exudates and lysates of cyanobacteria; (2) contrasting diel patterns in substrate appearance in the phycosphere vs. ambient water and growth of particle-associated copiotrophs vs. free-living oligotrophs; (3) attached bacteria reduce carbon flux from the phycosphere, lowering chemotactic efficiency toward eukaryotes below that toward cyanobacteria; (4) shear reduces chemotactic efficiency and fitness of the copiotroph; and (5) the main benefit of chemotaxis is to locate attachment partners. These patterns are consistent with available observations. Our study provides insights into the microscale ecology of marine bacteria, and the open-source code is a tool for further research in this area.IMPORTANCEA large amount of global CO2 fixation is performed by marine phytoplankton, and a substantial fraction of that is released as dissolved organic carbon and further processed by heterotrophic bacteria. The interaction between phytoplankton and bacteria, i.e., the carbon flux between them, is therefore an important process in the global carbon and climate system. Some bacteria have developed specialized behavioral traits, like swimming and attachment, to increase their carbon acquisition. These interactions occur at the micrometer scale, for example, the immediate vicinity of phytoplankters (the phycosphere), but existing biogeochemical models typically only simulate down to the 1 meter vertical or ~100 kilometer horizontal scale. We present a new microscale model and use it to predict fluxes and other features in the surface ocean. The model makes important predictions about the fluxes between various types of phytoplankton and bacteria and the role of behavioral traits, and it provides a basis and tool for further research in this area.

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来源期刊
mBio
mBio MICROBIOLOGY-
CiteScore
10.50
自引率
3.10%
发文量
762
审稿时长
1 months
期刊介绍: mBio® is ASM''s first broad-scope, online-only, open access journal. mBio offers streamlined review and publication of the best research in microbiology and allied fields.
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