Plant traits interacting with sediment properties regulate sediment microbial composition under different aquatic DIC levels caused by rising atmospheric CO2

Li, Yang; He, Qiankun; Ma, Xiaowen; Wang, Huijun; Liu, Chunhua; Yu, Dan

doi:10.1007/s11104-019-04312-6

Cited by 12 publications

(3 citation statements)

References 82 publications

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“…Shallow lake ecosystems are rich in bacteria and archaea community, which play a crucial role as decomposers in biogeochemical cycles, biodegradation and biotransformation of pollutants ( Reid et al, 2019 ; Williams and Ducklow, 2019 ). However, bacterial communities have been found to be susceptible to a wide range of environmental factors, including abiotic (e.g., organic matter, nitrogen, phosphorus, and temperature) and biotic factors (e.g., aquatic plant succession; Cheng et al, 2016 ; Li et al, 2019 ; Ma et al, 2023 ). Archaea are the main prokaryotes after bacteria ( Spang et al, 2017 ), whose distribution and diversity can also be affected by different environmental factors ( Gordon-Bradley et al, 2014 ).…”

Section: Introductionmentioning

confidence: 99%

Loss of submerged macrophytes in shallow lakes alters bacterial and archaeal community structures, and reduces their co-occurrence networks connectivity and complexity

Liu,

Huang,

Jiang

et al. 2024

Front. Microbiol.

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IntroductionBacteria and archaea are important components in shallow lake ecosystems and are crucial for biogeochemical cycling. While the submerged macrophyte loss is widespread in shallow lakes, the effect on the bacteria and archaea in the sediment and water is not yet widely understood.MethodsIn this study, 16S rRNA gene sequencing was used to explore the bacteria and archaea in samples taken from the sediment and water in the submerged macrophyte abundant (MA) and submerged macrophyte loss (ML) areas of Caohai Lake, Guizhou, China.ResultsThe results showed that the dominant bacterial phyla were Proteobacteria and Chloroflexi in the sediment; the dominant phyla were Proteobacteria, Actinobacteriota, and Bacteroidota in the water. The dominant archaea in sediment and water were the same, in the order of Crenarchaeota, Thermoplasmatota, and Halobacterota. Non-metric multidimensional scaling (NMDS) analyses showed that bacterial and archaeal community structures in the water were significantly affected by the loss of submerged macrophytes, but not by significant changes in the sediment. This suggests that the loss of submerged macrophytes has a stronger effect on the bacterial and archaeal community structures in water than in sediment. Furthermore, plant biomass (PB) was the key factor significantly influencing the bacterial community structure in water, while total nitrogen (TN) was the main factor significantly influencing the archaeal community structure in water. The loss of submerged macrophytes did not significantly affect the alpha diversity of the bacterial and archaeal communities in either the sediment or water. Based on network analyses, we found that the loss of submerged macrophytes reduced the connectivity and complexity of bacterial patterns in sediment and water. For archaea, network associations were stronger for MA network than for ML network in sediment, but network complexity for archaea in water was not significantly different between the two areas.DiscussionThis study assesses the impacts of submerged macrophyte loss on bacteria and archaea in lakes from microbial perspective, which can help to provide further theoretical basis for microbiological research and submerged macrophytes restoration in shallow lakes.

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Section: Introductionmentioning

confidence: 99%

Loss of submerged macrophytes in shallow lakes alters bacterial and archaeal community structures, and reduces their co-occurrence networks connectivity and complexity

Liu,

Huang,

Jiang

et al. 2024

Front. Microbiol.

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“…Studies show that co-existing bacterial communities in sediment and water exhibit various and diverse environmental vulnerabilities and preferences (Zhang et al, 2021 ). The diversity, composition, and structure of bacterial communities can be affected by abiotic (including biological matter, hydrological conditions, and temperature) and biological factors (such as typical plants) (Zhang et al, 2014 ; Li et al, 2019 ; Xia et al, 2020 ). Due to the difference of habitats, there are significant differences in the diversity and composition of plankton bacterial communities and sediment bacterial communities in lakes (Jiao et al, 2020 ; Zhang et al, 2021 ).…”

Section: Introductionmentioning

confidence: 99%

A limited overlap of interactions between the bacterial community of water and sediment in wetland ecosystem of the Yellow River floodplain

et al. 2023

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IntroductionAquatic ecosystems in floodplains provide homes for a variety of active bacterial populations. However, the coexistence pattern of bacterial communities of water and sediment in these ecosystems is unclear.MethodsIn the present study, Illumina Mi-Seq sequencing were to assess bacteria's co-occurrence patterns in the water and sediment of different time dynamics and plant communities of the Yellow River floodplain ecosystem.Results and discussionThe results showed that compared to water, the α-diversity of the bacterial community was way greater in sediment. The bacterial community structure significantly differed between water and sediment, and there was a limited overlap of interactions between the bacterial community of water and sediment. In addition, bacteria in water and sediment coexisting show different temporal shifts and community assembly patterns. The water was selected for specific groups of microorganisms that assemble over time in a non-reproducible and non-random way, whereas the sediment environment was relatively stable, and the bacterial communities were gathered randomly. The depth and plant cover significantly influenced the structure of a bacterial community in the sediment. The bacterial community in sediment formed a more robust network than those in water to cope with external changes. These findings improved our comprehension of the ecological trends of water and sediment bacterium colonies coexisting enhanced the biological barrier function, and the capacity of floodplain ecosystems to provide services and offered support for doing so.

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“…La mayoría de los humedales fluviales en las planicies costeras del mundo registran alta concentración de nutrientes relacionadas con la eutrofización que provoca declinación o pérdida de macrófitas sumergidas enraizadas (Salk et al 2018, Cruz-Ramírez et al 2019. La explicación de los efectos de la eutrofización sobre esta vegetación se complica por estresores aditivos como salinidad, nutrientes, pH, oxígeno disuelto y luz, incluidos los parámetros reguladores como perifiton, fitoplancton, sólidos totales suspendidos y concentración de clorofila, y más reciente el incremento de CO 2 atmosférico que eleva la temperatura en los ecosistemas acuáticos (Moreno-Marín et al 2018, Li et al 2019, Tootoonchi et al 2020. La drástica reducción de biomasa sumergida impacta en la provisión de alimento y de hábitat estructurados, lo que favorece la riqueza y dominancia de los productores primarios, así como los procesos biogeoquímicos asociados que influyen en la asimilación de nutrientes, la mejora en la calidad del agua y el incremento de fauna acuática (Yang et al 2008, Kouamé et al 2011, Lone et al 2014.…”

Section: Introductionunclassified

Predicción in vitro del estrés de Vallisneria americana Michx. por enriquecimiento de iones amonio y nitrato

Ruiz-Carrera

Sánchez

Contreras-Sánchez

et al. 2021

Ecosist. Recur. Agropec.

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El enriquecimiento de nutrientes es un factor de estrés involucrado en la declinación de vegetación sumergida. Sin embargo, la sensibilidad fisiológica o toxicológica de los genotipos varía debido a las interacciones microbióticas y el desbalance fisicoquímico del agua, las cuales han sido abordadas mediante una aproximación reduccionista y experimentos controlados. El objetivo del estudio fue evaluar, en un modelo de cultivo in vitro de Vallisneria americana, diferentes fuentes y concentraciones de N sobre la supervivencia y el crecimiento de hojas y raíces. Las plantas juveniles in vitro se expusieron a concentraciones de 500 a 2 000 µg L−1 de N total con fuentes de NH4, NO3 y NH4:NO3 (1:1) en un diseño factorial 4 x 3, en evaluaciones de corto y mediano plazo. La supervivencia fue inversamente proporcional a los síntomas de clorosis, necrosis o ruptura de tejidos. La primera elongación foliar se midió con un método no destructivo. Mientras que a los 25 días, se cuantificó la longitud individual y promedio de hojas y raíces, número de hojas regeneradas y número de raíces. Las plantas no mostraron síntomas de vulnerabilidad. El NH4 en todas sus concentraciones inhibió el crecimiento de los nueve parámetros analizados. En contraste, el NH4:NO3 causó dos inhibiciones a nivel de hoja y el NO3 estimuló todos los crecimientos de hojas y raíces. La predicción de crecimiento resulta prometedora para discriminar factores de estrés sobre la vegetación sumergida de los Pantanos de Centla.

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Plant traits interacting with sediment properties regulate sediment microbial composition under different aquatic DIC levels caused by rising atmospheric CO2

Cited by 12 publications

References 82 publications

Loss of submerged macrophytes in shallow lakes alters bacterial and archaeal community structures, and reduces their co-occurrence networks connectivity and complexity

Loss of submerged macrophytes in shallow lakes alters bacterial and archaeal community structures, and reduces their co-occurrence networks connectivity and complexity

A limited overlap of interactions between the bacterial community of water and sediment in wetland ecosystem of the Yellow River floodplain

Predicción in vitro del estrés de Vallisneria americana Michx. por enriquecimiento de iones amonio y nitrato

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