Adaptive radiation by waves of gene transfer leads to fine-scale resource partitioning in marine microbes

Hehemann, Jan‐Hendrik; Arevalo, Philip; Datta, Manoshi Sen; Yu, Xiaoqian; Corzett, Christopher H.; Henschel, Andreas; Preheim, Sarah P.; Timberlake, Sonia; Alm, Eric J.; Polz, Martin F.

doi:10.1038/ncomms12860

Cited by 127 publications

(182 citation statements)

References 45 publications

(65 reference statements)

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“…Similarly, several genes involved in the degradation of red algal porphyran and agar were transferred from a marine bacterium to gut bacteria of surgeonfish (Rebuffet et al, 2011) and humans (Hehemann, 2010). Recently, analysis of a clade of Vibrionaceae revealed a complex series of independent acquisitions and transfers of alginate lyases and oligoalginate lyases between closely related populations, leading to fine-scale differentiation of the alginolytic potential (Hehemann et al, 2016). Here, we show that addition of a single exogenous gene to a pre-existing alginolytic system could confer an adaptive advantage on Z. galactanivorans by improving access to alginate gels and increasing its ability to degrade fresh algal biomass.…”

Section: Discussionmentioning

confidence: 99%

“…In the environment, polysaccharide degradation is thought to involve at least three ecophysiological types of bacteria: (i) pioneers, which have full degradation pathways and secrete soluble enzymes that break down polymers and produce diffusible products (ii) harvesters, which possess a complete set of degradation enzymes but do not secrete soluble enzymes and may benefit from the soluble enzymes secreted by pioneers and (iii) scavengers, which lack enzymes that cleave polysaccharides but can use small oligomers released by pioneers and harvesters (Hehemann et al, 2016). The presence of AlyA1containing bacteria acting as pioneers for the initial attack on algal biomass could influence community assembly by exposing new substrate niches for harvesters and scavengers.…”

Section: Discussionmentioning

confidence: 99%

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Genetic analyses unravel the crucial role of a horizontally acquired alginate lyase for brown algal biomass degradation by Zobellia galactanivorans

Zhu

Thomas

Larocque

et al. 2017

Environmental Microbiology

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Comprehension of the degradation of macroalgal polysaccharides suffers from the lack of genetic tools for model marine bacteria, despite their importance for coastal ecosystem functions. We developed such tools for Zobellia galactanivorans, an algae-associated flavobacterium that digests many polysaccharides, including alginate. These tools were used to investigate the biological role of AlyA1, the only Z. galactanivorans alginate lyase known to be secreted in soluble form and to have a recognizable carbohydrate-binding domain. A deletion mutant, ΔalyA1, grew as well as the wild type on soluble alginate but was deficient in soluble secreted alginate lyase activity and in digestion of and growth on alginate gels and algal tissues. Thus, AlyA1 appears to be essential for optimal attack of alginate in intact cell walls. alyA1 appears to have been recently acquired via horizontal transfer from marine Actinobacteria, conferring an adaptive advantage that might benefit other algae-associated bacteria by exposing new substrate niches. The genetic tools described here function in diverse members of the phylum Bacteroidetes and should facilitate analyses of polysaccharide degradation systems and many other processes in these common but understudied bacteria.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Genetic analyses unravel the crucial role of a horizontally acquired alginate lyase for brown algal biomass degradation by Zobellia galactanivorans

Zhu

Thomas

Larocque

et al. 2017

Environmental Microbiology

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“…9CS106 has a battery of seven alginate lyases; disruption of any one does not have a measurable fitness effect. We have shown recently that gene dosage directly translates into increased activity, which may be important in competitive situations (Hehemann et al ., ) but under the pure culture conditions chosen here high gene dosage is sufficiently redundant. Nonetheless, even in the environment, selection on redundant pathways will be weaker and may thus be an important factor in allowing the horizontal acquisition of slightly deleterious alleles or genes that can subsequently be optimized by mutation and selection.…”

Section: Resultsmentioning

confidence: 99%

“…F13, which has been found to be a generalist with regard to habitat association (Preheim et al, 2011), does not utilize the same resources in different habitats; instead, it exploits distinct resources depending on habitat; (2) habitat complexity strongly buffers mutant fitness costs, indicating less of a reliance on any one gene when many substrates are available; and (3) the loss of anabolic genes in these resource spectra is more detrimental than the loss of catabolic genes, perhaps due to redundancy of catabolic pathways. Redundancy of catabolic genes is adaptive to rapid growth under replete conditions, since it enables rapid ramping up of activity and can provide a competitive advantage during exploitation of resource pulses (Hehemann et al, 2016;Roller et al, 2016). Such conditions may capture an ecologically important life stage for vibrios.…”

Section: Resultsmentioning

confidence: 99%

“…F13, which associates with dead zooplankton and brown algal detritus (Preheim et al, 2011;Hehemann et al, 2016). While several metabolic traits across all vibrios, such as the degradation of chitin, suggest that the association with zooplankton is ancestral in vibrios (Hunt et al, 2008a), their ability to degrade algal polysaccharides is due to a series of very recent horizontal gene transfer events (Hehemann et al, 2016). Because these constituent resources of these habitats can be recreated in the lab, we use this model to ask: Does this generalist exploit the same resources and thus require the same genes and pathways across habitats?…”

Section: Introductionmentioning

confidence: 99%

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Natural resource landscapes of a marine bacterium reveal distinct fitness‐determining genes across the genome

Takemura

Corzett

Hussain

et al. 2017

Environmental Microbiology

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Heterotrophic bacteria exploit diverse microhabitats in the ocean, from particles to transient gradients. Yet the degree to which genes and pathways can contribute to an organism's fitness on such complex and variable natural resource landscapes remains poorly understood. Here, we determine the gene-by-gene fitness of a generalist saprophytic marine bacterium (Vibrio sp. F13 9CS106) on complex resources derived from its natural habitats - copepods (Apocyclops royi) and brown algae (Fucus vesiculosus) - and as reference substrates, glucose and the polysaccharide alginate, derived from brown algal cell walls. We find that resource complexity strongly buffers fitness costs of mutations, and that anabolic rather than catabolic pathways are more stringently required, likely due to functional redundancy in the latter. Moreover, while carbohydrate-rich algae requires several synthesis pathways, protein-rich Apocyclops does not, suggesting this ancestral habitat for Vibrios is a replete medium with metabolically redundant substrates. We also identify a candidate fitness trade-off for algal colonization: deletion of mshA increases mutant fitness. Our results demonstrate that gene fitness depends on habitat composition, and suggest that this generalist uses distinct resources in different natural habitats. The results further indicate that substrate replete conditions may lead to relatively relaxed selection on catabolic genes.

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Environmental gradients and physical barriers drive the basin‐wide spatial structuring of Mediterranean Sea and adjacent eastern Atlantic Ocean prokaryotic communities

Sebastián

Ortega−Retuerta

Gómez‐Consarnau

et al. 2021

Limnology & Oceanography

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The Mediterranean Sea is a miniature ocean divided by the Sicily Strait into two basins with a marked west to east trophic gradient and separated of the nearby eastern Atlantic Ocean by the Strait of Gibraltar. Here, we test the hypothesis that these physical and environmental barriers favor the development of specific prokaryotic assemblages, leading to changes in community structure both in the vertical and horizontal spatial scales. By analyzing taxonomic and phylogenetic diversity using amplicon sequence variants (ASVs) of the 16S rRNA gene, we show that there is indeed marked vertical segregation of prokaryotic groups, similar to that found in other areas of the ocean, but also a clear horizontal structuring among the two Mediterranean basins and the adjacent Atlantic waters. Prokaryotic diversity increased with depth and toward the Atlantic, whereas the easternmost stations displayed more phylogenetically diverse phylotypes, despite harboring globally less diverse communities. Basin-indicator taxa (ASVs) accounted for a large fraction of the community (between 50% and 80%) in each of the basins at the surface and bathypelagic layers, being associated with different environmental variables. The existence of biogeographic and environmental barriers in the Mediterranean Sea is likely related to the trophic gradient at the surface and the isolation of water bodies in depth due to the Gibraltar and Sicily straits. Our work highlights the importance of studying microbial regional biogeography and provides the basis for future studies on the impact of this regionalization in the function of Mediterranean Sea prokaryotic communities.

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Adaptive radiation by waves of gene transfer leads to fine-scale resource partitioning in marine microbes

Cited by 127 publications

References 45 publications

Genetic analyses unravel the crucial role of a horizontally acquired alginate lyase for brown algal biomass degradation by Zobellia galactanivorans

Genetic analyses unravel the crucial role of a horizontally acquired alginate lyase for brown algal biomass degradation by Zobellia galactanivorans

Natural resource landscapes of a marine bacterium reveal distinct fitness‐determining genes across the genome

Environmental gradients and physical barriers drive the basin‐wide spatial structuring of Mediterranean Sea and adjacent eastern Atlantic Ocean prokaryotic communities

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