Elucidating the picocyanobacteria salinity divide through ecogenomics of new freshwater isolates

Cabello‐Yeves, Pedro J.; Callieri, Cristiana; Picazo, Antonio; Schallenberg, Lena; Huber, Paula; Roda‐Garcia, Juan J.; Bartosiewicz, Maciej; Белых, О. И.; Тихонова, И. В.; Torcello-Requena, Alberto; Prado, Paula Martin De; Puxty, Richard John; Millard, Andrew; Camacho, Antonio; Rodrı́guez-Valera, Francisco; Scanlan, David J.

doi:10.1186/s12915-022-01379-z

Cited by 17 publications

(61 citation statements)

References 167 publications

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“…Rhodanases, (aryl)sulfatases and ABC transporters for sulfate (e.g. CysWT, CysPA) were detected in freshwater members, but not in marine isolates, probably as adaptations to limited sulfur amounts available in freshwater systems (Cabello‐Yeves, Callieri, et al, 2022; Cabello‐Yeves, Scanlan, et al, 2022). As expected, genes involved in the transport and biosynthesis of compatible solutes (betaine biosynthesis/transport–sarcosine N ‐methyltransferase, dimethylglycine N ‐methyltransferase; high‐affinity choline uptake protein BetP) are only present in marine and/or brackish isolates, providing a molecular basis for the salinity divide (Cabello‐Yeves, Callieri, et al, 2022; Cabello‐Yeves, Scanlan, et al, 2022).…”

Section: Prokaryotic Lineages With Known Habitat Transitionsmentioning

confidence: 99%

Adaptive genetic traits in pelagic freshwater microbes

Chiriac

Haber

Salcher

2022

Environmental Microbiology

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Pelagic microbes have adopted distinct strategies to inhabit the pelagial of lakes and oceans and can be broadly categorized in two groups: free‐living, specialized oligotrophs and patch‐associated generalists or copiotrophs. In this review, we aim to identify genomic traits that enable pelagic freshwater microbes to thrive in their habitat. To do so, we discuss the main genetic differences of pelagic marine and freshwater microbes that are both dominated by specialized oligotrophs and the difference to freshwater sediment microbes, where copiotrophs are more prevalent. We phylogenomically analysed a collection of >7700 metagenome‐assembled genomes, classified habitat preferences on different taxonomic levels, and compared the metabolic traits of pelagic freshwater, marine, and freshwater sediment microbes. Metabolic differences are mainly associated with transport functions, environmental information processing, components of the electron transport chain, osmoregulation and the isoelectric point of proteins. Several lineages with known habitat transitions (Nitrososphaeria, SAR11, Methylophilaceae, Synechococcales, Flavobacteriaceae, Planctomycetota) and the underlying mechanisms in this process are discussed in this review. Additionally, the distribution, ecology and genomic make‐up of the most abundant freshwater prokaryotes are described in details in separate chapters for Actinobacteriota, Bacteroidota, Burkholderiales, Verrucomicrobiota, Chloroflexota, and ‘Ca. Patescibacteria’.

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Section: Prokaryotic Lineages With Known Habitat Transitionsmentioning

confidence: 99%

Adaptive genetic traits in pelagic freshwater microbes

Chiriac

Haber

Salcher

2022

Environmental Microbiology

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“…Within freshwater ecosystems, isolates from the family Methylophilaceae (class Gammaproteobacteria) show a smaller genome size for pelagic than for sediment dwellers [ 20 ]. Additionally, two studies have shown that marine Cyanobacteria have smaller genome sizes than freshwater [ 21 , 22 ]. This literature already provides some insights on how genome size is linked to the environmental heterogeneity of freshwater and marine ecosystems.…”

Section: Introductionmentioning

confidence: 99%

Linking prokaryotic genome size variation to metabolic potential and environment

Rodríguez-Gijón

Buck

Andersson

et al. 2023

ISME Communications

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While theories and models have appeared to explain genome size as a result of evolutionary processes, little work has shown that genome sizes carry ecological signatures. Our work delves into the ecological implications of microbial genome size variation in benthic and pelagic habitats across environmental gradients of the brackish Baltic Sea. While depth is significantly associated with genome size in benthic and pelagic brackish metagenomes, salinity is only correlated to genome size in benthic metagenomes. Overall, we confirm that prokaryotic genome sizes in Baltic sediments (3.47 Mbp) are significantly bigger than in the water column (2.96 Mbp). While benthic genomes have a higher number of functions than pelagic genomes, the smallest genomes coded for a higher number of module steps per Mbp for most of the functions irrespective of their environment. Some examples of this functions are amino acid metabolism and central carbohydrate metabolism. However, we observed that nitrogen metabolism was almost absent in pelagic genomes and was mostly present in benthic genomes. Finally, we also show that Bacteria inhabiting Baltic sediments and water column not only differ in taxonomy, but also in their metabolic potential, such as the Wood-Ljungdahl pathway or the presence of different hydrogenases. Our work shows how microbial genome size is linked to abiotic factors in the environment, metabolic potential and taxonomic identity of Bacteria and Archaea within aquatic ecosystems.

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“…The copyright holder for this preprint this version posted October 21, 2022. ; https://doi.org/10.1101/2022.10.20.512849 doi: bioRxiv preprint freshwaters (Hugerth et al, 2015), while picocyanobacteria show the opposite trend (Cabello-Yeves et al, 2022). Further research must be done to understand how genome sizes vary between and within different aquatic environments, particularly brackish water bodies including pelagic and benthic microorganisms.…”

Section: Introductionmentioning

confidence: 99%

“…Within freshwater ecosystems, we can observe that isolates from the family Methylophilaceae (class Gammaproteobacteria) show a decrease in genome size in the transition from sediments to pelagic forms (Salcher et al, 2019). Additionally, several studies have shown that marine microbes have smaller genome sizes than freshwater microorganisms (Cabello-Yeves et al, 2022; Chen et al, 2021; Rodríguez-Gijón et al, 2022). Yet, genome size variation in the brackish realm remains debated: Actinobacteria in the brackish Baltic Sea show bigger genome sizes than in freshwaters (Hugerth et al, 2015), while picocyanobacteria show the opposite trend (Cabello-Yeves et al, 2022).…”

Section: Introductionmentioning

confidence: 99%

“…Additionally, several studies have shown that marine microbes have smaller genome sizes than freshwater microorganisms (Cabello-Yeves et al, 2022; Chen et al, 2021; Rodríguez-Gijón et al, 2022). Yet, genome size variation in the brackish realm remains debated: Actinobacteria in the brackish Baltic Sea show bigger genome sizes than in freshwaters (Hugerth et al, 2015), while picocyanobacteria show the opposite trend (Cabello-Yeves et al, 2022). Further research must be done to understand how genome sizes vary between and within different aquatic environments, particularly brackish water bodies including pelagic and benthic microorganisms.…”

Section: Introductionmentioning

confidence: 99%

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Linking prokaryotic genome size variation to metabolic potential and environment

Rodríguez-Gijón

Buck

Andersson

et al. 2022

Preprint

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Microbial genome size can be used as a predictor to explain the ecology and metabolism of Bacteria and Archaea across major biomes. Despite their ecological significance, the contribution of microbial genome size to differences in metabolic potential of benthic and pelagic prokaryotes are poorly studied. Here, we investigated how taxonomy and microbial genome size varies between benthic and pelagic habitats across environmental gradients of the brackish Baltic Sea. We also explored the relationships between that variation, the environmental heterogeneity, and microbial functions in these habitats. By analyzing Baltic metagenomes and MAGs, we observe that pelagic brackish Bacteria and Archaea present smaller genome sizes on average than pelagic marine and freshwater prokaryotes. Moreover, we found that prokaryotic genome sizes in Baltic sediments (3.47 Mbp) are significantly bigger than in the water column (2.96 Mbp). These differences in genome size persisted in Bacteria from the phyla level to the order level. For pelagic prokaryotes, the smallest genomes coded for a higher number of module steps per Mbp than bigger genomes for most of the functions, such as amino acid metabolism and central carbohydrate metabolism. However, we observed that nitrogen metabolism was almost absent in pelagic genomes and was mostly present in benthic genomes. Finally, we also show that Bacteria inhabiting Baltic sediments and water column not only differ in taxonomy, but also in their metabolic potential, such as the Wood-Ljungdahl pathway or presence of different hydrogenases.IMPORTANCEIn Bacteria and Archaea, genome size is the result of strong selection pressures shaping the ecology and metabolism of microbial lineages. Thanks to the development of metagenomic analysis of environmental samples in the last three decades, we can now survey the size of their genomes, quantify their functional capabilities, and infer the role they play in the environment. Here, by using four publicly available datasets together with one new unpublished dataset, we provide new insights on how genome size, metabolism and taxonomy are linked and how they differ between sediments and water column in the Baltic Sea. Moreover, we investigate differences in genome size of pelagic microorganisms across ecosystems, from the brackish Baltic Sea to marine and freshwater Bacteria and Archaea. Our results provide a comprehensive and contrasting view between the taxonomic and genetic diversity of sediments and water column and its implications on nutrient cycling in the Baltic Sea.

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Elucidating the picocyanobacteria salinity divide through ecogenomics of new freshwater isolates

Cited by 17 publications

References 167 publications

Adaptive genetic traits in pelagic freshwater microbes

Adaptive genetic traits in pelagic freshwater microbes

Linking prokaryotic genome size variation to metabolic potential and environment

Linking prokaryotic genome size variation to metabolic potential and environment

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