Climate change-related warming reduces thermal sensitivity and modifies metabolic activity of coastal benthic bacterial communities

Seidel, Laura; Broman, Elias; Nilsson, Emelie; Ståhle, Magnus; Ketzer, João Marcelo Medina; Pérez-Martínez, Clara; Turner, Stephanie; Hylander, Samuel; Pinhassi, Jarone; Forsman, Anders; Dopson, Mark

doi:10.1038/s41396-023-01395-z

Cited by 10 publications

(7 citation statements)

References 76 publications

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“…This resulted in less nitrite and nitrate, potentially explaining a portion of the observed among-site variation. This study complements and adds a layer of generality to previous studies suggesting significant effects of climate change on the more intensively studied prokaryotic communities ( Seidel et al, 2022a , b , 2023 ).…”

Section: Discussionsupporting

confidence: 71%

Baltic Sea coastal sediment-bound eukaryotes have increased year-round activities under predicted climate change related warming

Li,

Nilsson,

Seidel

et al. 2024

Front. Microbiol.

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Climate change related warming is a serious environmental problem attributed to anthropogenic activities, causing ocean water temperatures to rise in the coastal marine ecosystem since the last century. This particularly affects benthic microbial communities, which are crucial for biogeochemical cycles. While bacterial communities have received considerable scientific attention, the benthic eukaryotic community response to climate change remains relatively overlooked. In this study, sediments were sampled from a heated (average 5°C increase over the whole year for over 50 years) and a control (contemporary conditions) Baltic Sea bay during four different seasons across a year. RNA transcript counts were then used to investigate eukaryotic community changes under long-term warming. The composition of active species in the heated and control bay sediment eukaryotic communities differed, which was mainly attributed to salinity and temperature. The family level RNA transcript alpha diversity in the heated bay was higher during May but lower in November, compared with the control bay, suggesting altered seasonal activity patterns and dynamics. In addition, structures of the active eukaryotic communities varied between the two bays during the same season. Hence, this study revealed that long-term warming can change seasonality in eukaryotic diversity patterns. Relative abundances and transcript expression comparisons between bays suggested that some taxa that now have lower mRNA transcripts numbers could be favored by future warming. Furthermore, long-term warming can lead to a more active metabolism in these communities throughout the year, such as higher transcript numbers associated with diatom energy production and protein synthesis in the heated bay during winter. In all, these data can help predict how future global warming will affect the ecology and metabolism of eukaryotic community in coastal sediments.

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Section: Discussionsupporting

confidence: 71%

Baltic Sea coastal sediment-bound eukaryotes have increased year-round activities under predicted climate change related warming

Li,

Nilsson,

Seidel

et al. 2024

Front. Microbiol.

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“…Both in the presence or absence of the invertebrate, the predicted functional changes were consistent with the observed changes in community structure but may also be related with short-term adaptations to distinct climate scenarios. For instance, in the case of a temperature increase to 15 • C-25 • C, a decrease in pathways related with carbohydrate metabolism may be part of a strategy to reduce heat generation [80]. Conversely, an increase in functions related to stress response, such as signal transduction pathways and cell mobility, was observed for this and other scenarios, both in the presence or absence of E. crypticus.…”

Section: Discussionmentioning

confidence: 87%

Structural and Functional Shifts in the Microbial Community of a Heavy Metal-Contaminated Soil Exposed to Short-Term Changes in Air Temperature, Soil Moisture and UV Radiation

Silva,

Alves,

Malheiro

et al. 2024

Genes

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The interplay between metal contamination and climate change may exacerbate the negative impact on the soil microbiome and, consequently, on soil health and ecosystem services. We assessed the response of the microbial community of a heavy metal-contaminated soil when exposed to short-term (48 h) variations in air temperature, soil humidity or ultraviolet (UV) radiation in the absence and presence of Enchytraeus crypticus (soil invertebrate). Each of the climate scenarios simulated significantly altered at least one of the microbial parameters measured. Irrespective of the presence or absence of invertebrates, the effects were particularly marked upon exposure to increased air temperature and alterations in soil moisture levels (drought and flood scenarios). The observed effects can be partly explained by significant alterations in soil properties such as pH, dissolved organic carbon, and water-extractable heavy metals, which were observed for all scenarios in comparison to standard conditions. The occurrence of invertebrates mitigated some of the impacts observed on the soil microbial community, particularly in bacterial abundance, richness, diversity, and metabolic activity. Our findings emphasize the importance of considering the interplay between climate change, anthropogenic pressures, and soil biotic components to assess the impact of climate change on terrestrial ecosystems and to develop and implement effective management strategies.

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“…This decrease in diversity is detrimental to community health as a high diversity (combination of different species) buffers against environmental changes ( Elmqvist et al, 2003 ). For instance, an increase in temperature influences the microbial community composition and their energy- and nutrient cycling, which further impacts marine carbon cycling ( Abirami et al, 2021 ; Seidel et al, 2023a ). A decline in microbial diversity in the heated bay surface waters of this investigation is supported by previous studies of the heated bay benthic microbial communities ( Seidel et al, 2022a ).…”

Section: Discussionmentioning

confidence: 99%

“…The heated bay warming also leads to compression of sediment geochemical layers such that, e.g., the sulfate/methane transition zone occurs closer to the sediment surface along with shifts in seasonal bottom water microbial communities altering, e.g., the cyanobacterial bloom pattern ( Seidel et al, 2022a ). Furthermore, a laboratory-based thermal gradient study demonstrated the ability of the control and heated bay benthic community’s response to potential future marine heatwaves ( Seidel et al, 2023a ). The data show a broader thermal tolerance in the heated bay coupled with elevated RNA transcripts related to stress.…”

Section: Introductionmentioning

confidence: 99%

Climate change induces shifts in coastal Baltic Sea surface water microorganism stress and photosynthesis gene expression

Seidel,

Broman,

Ståhle

et al. 2024

Front. Microbiol.

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The world’s oceans are challenged by climate change linked warming with typically highly populated coastal areas being particularly susceptible to these effects. Many studies of climate change on the marine environment use large, short-term temperature manipulations that neglect factors such as long-term adaptation and seasonal cycles. In this study, a Baltic Sea ‘heated’ bay influenced by thermal discharge since the 1970s from a nuclear reactor (in relation to an unaffected nearby ‘control’ bay) was used to investigate how elevated temperature impacts surface water microbial communities and activities. 16S rRNA gene amplicon based microbial diversity and population structure showed no difference in alpha diversity in surface water microbial communities, while the beta diversity showed a dissimilarity between the bays. Amplicon sequencing variant relative abundances between the bays showed statistically higher values for, e.g., Ilumatobacteraceae and Burkholderiaceae in the heated and control bays, respectively. RNA transcript-derived activities followed a similar pattern in alpha and beta diversity with no effect on Shannon’s H diversity but a significant difference in the beta diversity between the bays. The RNA data further showed more elevated transcript counts assigned to stress related genes in the heated bay that included heat shock protein genes dnaKJ, the co-chaperonin groS, and the nucleotide exchange factor heat shock protein grpE. The RNA data also showed elevated oxidative phosphorylation transcripts in the heated (e.g., atpHG) compared to control (e.g., atpAEFB) bay. Furthermore, genes related to photosynthesis had generally higher transcript numbers in the control bay, such as photosystem I (psaAC) and II genes (psbABCEH). These increased stress gene responses in the heated bay will likely have additional cascading effects on marine carbon cycling and ecosystem services.

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Climate change-related warming reduces thermal sensitivity and modifies metabolic activity of coastal benthic bacterial communities

Cited by 10 publications

References 76 publications

Baltic Sea coastal sediment-bound eukaryotes have increased year-round activities under predicted climate change related warming

Baltic Sea coastal sediment-bound eukaryotes have increased year-round activities under predicted climate change related warming

Structural and Functional Shifts in the Microbial Community of a Heavy Metal-Contaminated Soil Exposed to Short-Term Changes in Air Temperature, Soil Moisture and UV Radiation

Climate change induces shifts in coastal Baltic Sea surface water microorganism stress and photosynthesis gene expression

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