Nutrients drive transcriptional changes that maintain metabolic homeostasis but alter genome architecture in <i>Microcystis</i>

Steffen, Morgan M.; Dearth, Stephen P.; Dill, Brian D.; Li, Zhou; Larsen, Kristen M; Campagna, Shawn R.; Wilhelm, Steven W.

doi:10.1038/ismej.2014.78

Cited by 83 publications

(76 citation statements)

References 63 publications

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“…Simultaneously, transcriptome‐based characterization of interactions between co‐occurring organisms would contribute to the current knowledge about the molecular mechanisms involved in the intraspecies and interspecies cyanobacterial interactions. Regulatory molecular mechanisms, such as activity of transposable elements, enabling cells to face various environmental conditions, like N availability (Steffen et al ., ) and grazing (Harke et al ., ), may facilitate adaptability through the regulation of the production of metabolites.…”

Section: Discussionmentioning

confidence: 99%

Chemically mediated interactions between Microcystis and Planktothrix: impact on their growth, morphology and metabolic profiles

Briand

Reubrecht

Mondeguer

et al. 2019

Environmental Microbiology

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Summary Freshwater cyanobacteria are known for their ability to produce bioactive compounds, some of which have been described as allelochemicals. Using a combined approach of co‐cultures and analyses of metabolic profiles, we investigated chemically mediated interactions between two cyanobacterial strains, Microcystis aeruginosa PCC 7806 and Planktothrix agardhii PCC 7805. More precisely, we evaluated changes in growth, morphology and metabolite production and release by both interacting species. Co‐culture of Microcystis with Planktothrix resulted in a reduction of the growth of Planktothrix together with a decrease of its trichome size and alterations in the morphology of its cells. The production of intracellular compounds by Planktothrix showed a slight decrease between monoculture and co‐culture conditions. Concerning Microcystis, the number of intracellular compounds was higher under co‐culture condition than under monoculture. Overall, Microcystis produced a lower number of intracellular compounds under monoculture than Planktothrix, and a higher number of intracellular compounds than Planktothrix under co‐culture condition. Our investigation did not allow us to identify specifically the compounds causing the observed physiological and morphological changes of Planktothrix cells. However, altogether, these results suggest that co‐culture induces specific compounds as a response by Microcystis to the presence of Planktothrix. Further studies should be undertaken for identification of such potential allelochemicals.

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Section: Discussionmentioning

confidence: 99%

Chemically mediated interactions between Microcystis and Planktothrix: impact on their growth, morphology and metabolic profiles

Briand

Reubrecht

Mondeguer

et al. 2019

Environmental Microbiology

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“…Collectively, they comprise the central foundation of the current molecular biology paradigm: genes (DNA) for genetic information storage, transcription (mRNA) for gene expression, proteins for structural and metabolic/enzymatic activities, and metabolites for the substrates/inhibitors/products of metabolism. Recent advances in ‐omics technologies have facilitated their application to microbial consortia/communities, which have been designated as metagenomics , metatranscriptomics , metaproteomics , and meta‐metabolomics . Even a brief inspection of scientific literature over the past 10 years will clearly reveal how these ‐omics technologies have revolutionized microbial ecology.…”

Section: Metaproteomics Among the Various ‐Omics Technologiesmentioning

confidence: 99%

Microbial metaproteomics for characterizing the range of metabolic functions and activities of human gut microbiota

et al. 2015

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The human gastrointestinal (GI) tract is a complex, dynamic ecosystem that consists of a carefully tuned balance of human host and microbiota membership. The microbiome is not merely a collection of opportunistic parasites, but rather provides important functions to the host that are absolutely critical to many aspects of health, including nutrient transformation and absorption, drug metabolism, pathogen defense, and immune system development. Microbial metaproteomics provides the ability to characterize the human gut microbiota functions and metabolic activities at a remarkably deep level, revealing information about microbiome development and stability as well as their interactions with their human host. Generally, microbial and human proteins can be extracted and then measured by high performance mass spectrometry (MS)-based proteomics technology. Here we review the field of human gut microbiome metaproteomics, with a focus on the experimental and informatics considerations involved in characterizing systems ranging from low-complexity model gut microbiota in gnotobiotic mice, to the emerging gut microbiome in the GI tract of newborn human infants, and finally to an established gut microbiota in human adults.

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“…In comparison, studies that have tried to pin down nutrient availabilities, such as for nitrogen and other distinct environmental conditions to the level of microcystin production, have resulted in controversial results. A steady expression independent of nitrate availability as seen by Sevilla and colleagues () was contradicted by the downregulation of mcy under nitrate limitation in other studies (Harke and Gobler, ; Steffen et al ., ). Apart from contradictory mcy expression patterns in these studies, the comprehensive transcriptomic investigations of Steffen and colleagues () were able to uncover unforeseen correlations between nitrogen availability and potential genomic reorganization via the activation of transposases and insertion sequences.…”

Section: Transcriptomicsmentioning

confidence: 97%

“…A steady expression independent of nitrate availability as seen by Sevilla and colleagues () was contradicted by the downregulation of mcy under nitrate limitation in other studies (Harke and Gobler, ; Steffen et al ., ). Apart from contradictory mcy expression patterns in these studies, the comprehensive transcriptomic investigations of Steffen and colleagues () were able to uncover unforeseen correlations between nitrogen availability and potential genomic reorganization via the activation of transposases and insertion sequences. Thus, they proposed the concept of nutrients as evolutionary drivers for the formation of subspecies, with the microcystin gene cluster as a top candidate for genomic mobilization under nitrogen‐reduced conditions.…”

Section: Transcriptomicsmentioning

confidence: 97%

“…This suggests a significant selective pressure to maintain a functional form of the cluster or to rapidly eject dysfunctional forms that arise, potentially through the action of co-localized transposases. Indeed, the alteration of nutrient concentrations that elicit transposase expression in Microcystis, also leads to an alternate genomic architecture (Steffen et al, 2014). This raises the question as to the extent to which re-arrangements can occur within the gene cluster before the organism deems these pathways redundant.…”

Section: Genomicsmentioning

confidence: 99%

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Advances in genomics, transcriptomics and proteomics of toxin‐producing cyanobacteria

D’Agostino

Woodhouse

Makower

et al. 2016

Environ Microbiol Rep

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A common misconception persists that the genomes of toxic and non-toxic cyanobacterial strains are largely conserved with the exception of the presence or absence of the genes responsible for toxin production. Implementation of -omics era technologies has challenged this paradigm, with comparative analyses providing increased insight into the differences between strains of the same species. The implementation of genomic, transcriptomic and proteomic approaches has revealed distinct profiles between toxin-producing and non-toxic strains. Further, metagenomics and metaproteomics highlight the genomic potential and functional state of toxic bloom events over time. In this review, we highlight how these technologies have shaped our understanding of the complex relationship between these molecules, their producers and the environment at large within which they persist.

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Nutrients drive transcriptional changes that maintain metabolic homeostasis but alter genome architecture in Microcystis

Cited by 83 publications

References 63 publications

Chemically mediated interactions between Microcystis and Planktothrix: impact on their growth, morphology and metabolic profiles

Chemically mediated interactions between Microcystis and Planktothrix: impact on their growth, morphology and metabolic profiles

Microbial metaproteomics for characterizing the range of metabolic functions and activities of human gut microbiota

Advances in genomics, transcriptomics and proteomics of toxin‐producing cyanobacteria

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