Genomic, metabolic and phenotypic variability shapes ecological differentiation and intraspecies interactions of Alteromonas macleodii

Koch, Hanna; Germscheid, Nora; Freese, Heike M.; Noriega‐Ortega, Beatriz E.; Lücking, Dominik; Berger, Martine; Qiu, Galaxy; Marzinelli, Ezequiel M.; Campbell, Alexandra H.; Steinberg, Peter D.; Overmann, Jörg; Dittmar, Thorsten; Simon, Meinhard; Wietz, Matthias

doi:10.1038/s41598-020-57526-5

“…In addition to , which can outnumber cells by a factor of 10 or more, and marine heterotrophs like Alteromonas are capable of growing on these vesicles as a sole source of carbon (Biller, Schubotz, et al, 2014). Recent work also suggests that Alteromonas isolates derived from cultures of Prochlorococcus carry genes for the degradation of aromatic compounds produced by the cyanobacterium (Koch et al, 2020), which may provide a selective advantage. Additionally, metagenomics on a Synechococcus-associated culture revealed high abundance of TonB-dependent transporters in Muricauda, potentially involved in lipid uptake, and proteins involved in the export of lipids in the proteome of the Synechococcus host (Zheng et al, 2020).…”

Section: Resultsmentioning

confidence: 99%

Microbial Diversity of Co-occurring Heterotrophs in Cultures of Marine Picocyanobacteria

Kearney

¹

,

Thomas

²

,

Coe

³

et al. 2020

Preprint

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BackgroundProchlorococcus and Synechococcus are responsible for around 10% of global net primary productivity, serving as part of the foundation of marine food webs. Heterotrophic bacteria are often co-isolated with these picocyanobacteria in seawater enrichment cultures that contain no added organic carbon; heterotrophs grow on organic carbon supplied by the photolithoautotrophs. We have maintained these cultures of Prochlorococcus and Synechococcus for 100s to 1000s of generations; they represent ideal microcosms for examining the selective pressures shaping autotroph/heterotroph interactions. ResultsWe examine the diversity of heterotrophs in 74 enrichment cultures of these picocyanobacteria obtained from diverse areas of the global oceans. Heterotroph community composition differed between clades and ecotypes of the autotrophic ‘hosts’ but there was significant overlap in heterotroph community composition. Differences were associated with timing, location, depth, and methods of isolation, suggesting the particular conditions surrounding isolation have a persistent effect on long-term culture composition. The majority of heterotrophs in the cultures are rare in the global ocean; enrichment conditions favor the opportunistic outgrowth of these rare bacteria. We did find a few examples, such as heterotrophs in the family Rhodobacteraceae, that are ubiquitous and abundant in cultures and in the global oceans; their abundance in the wild is also positively correlated with that of picocyanobacteria. ConclusionsCollectively, the cultures converged on similar compositions, likely from bottlenecking and selection that happens during the early stages of enrichment for the picocyanobacteria. We highlight the potential for examining ecologically relevant relationships by identifying patterns of distribution of culture-enriched organisms in the global oceans.

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“…For instance, the most ubiquitous genus (present in over 60% of both culture types) is Marinobacter ( Figure 3C), which is well-known to be associated with picocyanobacteria in culture (Morris et al, 2008). In addition to Marinobacter, other genera present in at least 15% of cultures including Thalassospira, Methylophaga, Alteromonas, Alcanivorax, Maricaulis, Muricauda, and Hyphomonas (but not Shimia) have been associated with metabolism of hydrocarbons or C1 compounds derived from lipid catabolism (Coulon et al, 2007;Dong et al, 2018;Hara et al, 2003;Kappell et al, 2014;Koch et al, 2020;Kostka et al, 2011;Lea-Smith et al, 2015;Liu et al, 2007;López-Pérez et al, 2012;Neufeld et al, 2007;Vila et al, 2010;Yakimov et al, 2007;Zhao et al, 2010), suggesting that hydrocarbon metabolism might play an important role in their growth in these cultures. Indeed, previous work showed an upregulation of genes for fatty acid metabolism including lipid betaoxidation in co-culture of Alteromonas macleodii with Prochlorococcus (Biller et al, 2016).…”

Section: Resultsmentioning

confidence: 99%

“…Prochlorococcus secretes vesicles (potentially a source of lipids) in culture and in the wild (Biller et al, 2017;Biller, Schubotz, et al, 2014), which can outnumber cells by a factor of 10 or more, and marine heterotrophs like Alteromonas are capable of growing on these vesicles as a sole source of carbon (Biller, Schubotz, et al, 2014). Recent work also suggests that Alteromonas isolates derived from cultures of Prochlorococcus carry genes for the degradation of aromatic compounds produced by the cyanobacterium (Koch et al, 2020), which may provide a selective advantage. Additionally, metagenomics on a Synechococcusassociated culture revealed high abundance of TonB-dependent transporters in Muricauda, potentially involved in lipid uptake, and proteins involved in the export of lipids in the proteome of the Synechococcus host (Zheng et al, 2020).…”

Section: Resultsmentioning

confidence: 99%

Microbial Diversity of Co-occurring Heterotrophs in Cultures of Marine Picocyanobacteria

Kearney

¹

,

Coe

²

,

Chisholm

³

2020

Preprint

View full text Add to dashboard Cite

Prochlorococcus and Synechococcus are responsible for around 10% of global net primary productivity, serving as part of the foundation of marine food webs. Heterotrophic bacteria are often co-isolated with these picocyanobacteria in seawater enrichment cultures that contain no added organic carbon; heterotrophs grow on organic carbon supplied by the photolithoautotrophs. We have maintained these cultures of Prochlorococcus and Synechococcus for 100s to 1000s of generations; they represent ideal microcosms for examining the selective pressures shaping autotroph/heterotroph interactions. Here we examine the diversity of heterotrophs in 74 enrichment cultures of these picocyanobacteria obtained from diverse areas of the global oceans. Heterotroph community composition differed between clades and ecotypes of the autotrophic ‘hosts’ but there was significant overlap in heterotroph community composition. Differences were associated with timing, location, depth, and methods of isolation, suggesting the particular conditions surrounding isolation have a persistent effect on long-term culture composition. The majority of heterotrophs in the cultures are rare in the global ocean; enrichment conditions favor the opportunistic outgrowth of these rare bacteria. We did find a few examples, such as heterotrophs in the family Rhodobacteraceae, that are ubiquitous and abundant in cultures and in the global oceans; their abundance in the wild is also positively correlated with that of picocyanobacteria. Collectively, the cultures converged on similar compositions, likely from bottlenecking and selection that happens during the early stages of enrichment for the picocyanobacteria. We highlight the potential for examining ecologically relevant relationships by identifying patterns of distribution of culture-enriched organisms in the global oceans.IMPORTANCEOne of the biggest challenges in marine microbial ecology is to begin to understand the rules that govern the self-assembly of these complex communities. The picocyanobacteria Prochlorococcus and Synechococcus comprise the most numerous photosynthetic organisms in the sea and supply a significant fraction of the organic carbon that feeds diverse heterotrophic microbes. When initially isolated into cultures, Prochlorococcus and Synechococcus carry with them select heterotrophic microorganisms that depend on them for organic carbon. The cultures self-assemble into stable communities of diverse microorganisms and are microcosms for understanding microbial interdependencies. Primarily faster-growing, relatively rare, copiotrophic heterotrophic bacteria – as opposed to oligotrophic bacteria that are abundant in picocyanobacterial habitats – are selected for in these cultures, suggesting that these copiotrophs experience these cultures as they would high carbon fluxes associated with particles, phycospheres of larger cells, or actual attachment to picocyanobacteria in the wild.

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“…For instance, the most ubiquitous genus (present in over 60% of both culture types) is Marinobacter ( Figure 3C), which is wellknown to be associated with picocyanobacteria in culture (Morris et al, 2008). In addition to Marinobacter, other genera present in at least 15% of cultures including Thalassospira, Methylophaga, Alteromonas, Alcanivorax, Maricaulis, Muricauda, and Hyphomonas (but not Shimia) have been associated with metabolism of hydrocarbons or C1 compounds derived from lipid catabolism (Coulon et al, 2007;Dong et al, 2018;Hara et al, 2003;Kappell et al, 2014;Koch et al, 2020;Kostka et al, 2011;Lea-Smith et al, 2015;Liu et al, 2007;López-Pérez et al, 2012;Neufeld et al, 2007;Vila et al, 2010;Yakimov et al, 2007;Zhao et al, 2010), suggesting that hydrocarbon metabolism might play an important role in their growth in these cultures. Indeed, previous work showed an upregulation of genes for fatty acid metabolism including lipid beta-oxidation in co-culture of Alteromonas macleodii with Prochlorococcus (Biller et al, 2016).…”

Section: Resultsmentioning

confidence: 99%

“…Prochlorococcus secretes vesicles (potentially a source of lipids) in culture and in the wild (Biller et al, 2017;Biller, Schubotz, et al, 2014), which can outnumber cells by a factor of 10 or more, and marine heterotrophs like Alteromonas are capable of growing on these vesicles as a sole source of carbon (Biller, Schubotz, et al, 2014). Recent work also suggests that Alteromonas isolates derived from cultures of Prochlorococcus carry genes for the degradation of aromatic compounds produced by the cyanobacterium (Koch et al, 2020), which may provide a selective advantage. Additionally, metagenomics on a Synechococcus-associated culture revealed high abundance of TonB-dependent transporters in Muricauda, potentially involved in lipid uptake, and proteins involved in the export of lipids in the proteome of the Synechococcus host (Zheng et al, 2020).…”

Section: Resultsmentioning

confidence: 99%

Microbial Diversity of Co-occurring Heterotrophs in Cultures of Marine Picocyanobacteria

Kearney

¹

,

Thomas

²

,

Coe

³

et al. 2020

Preprint

1

0

View full text Add to dashboard Cite

BackgroundProchlorococcus and Synechococcus are responsible for around 10% of global net primary productivity, serving as part of the foundation of marine food webs. Heterotrophic bacteria are often co-isolated with these picocyanobacteria in seawater enrichment cultures that contain no added organic carbon; heterotrophs grow on organic carbon supplied by the photolithoautotrophs. We have maintained these cultures of Prochlorococcus and Synechococcus for 100s to 1000s of generations; they represent ideal microcosms for examining the selective pressures shaping autotroph/heterotroph interactions. ResultsWe examine the diversity of heterotrophs in 74 enrichment cultures of these picocyanobacteria obtained from diverse areas of the global oceans. Heterotroph community composition differed between clades and ecotypes of the autotrophic ‘hosts’ but there was significant overlap in heterotroph community composition. Differences were associated with timing, location, depth, and methods of isolation, suggesting the particular conditions surrounding isolation have a persistent effect on long-term culture composition. The majority of heterotrophs in the cultures are rare in the global ocean; enrichment conditions favor the opportunistic outgrowth of these rare bacteria. We did find a few examples, such as heterotrophs in the family Rhodobacteraceae, that are ubiquitous and abundant in cultures and in the global oceans; their abundance in the wild is also positively correlated with that of picocyanobacteria. ConclusionsCollectively, the cultures converged on similar compositions, likely from bottlenecking and selection that happens during the early stages of enrichment for the picocyanobacteria. We highlight the potential for examining ecologically relevant relationships by identifying patterns of distribution of culture-enriched organisms in the global oceans.

show abstract

Genomic, metabolic and phenotypic variability shapes ecological differentiation and intraspecies interactions of Alteromonas macleodii

Cited by 52 publications

References 143 publications

Microbial Diversity of Co-occurring Heterotrophs in Cultures of Marine Picocyanobacteria

Microbial Diversity of Co-occurring Heterotrophs in Cultures of Marine Picocyanobacteria

Microbial Diversity of Co-occurring Heterotrophs in Cultures of Marine Picocyanobacteria

Microbial Diversity of Co-occurring Heterotrophs in Cultures of Marine Picocyanobacteria

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