Transcription factor levels enable metabolic diversification of single cells of environmental bacteria

Guantes, Raúl; Benedetti, Ilaria; Silva‐Rocha, Rafael

doi:10.1038/ismej.2015.193

Cited by 15 publications

(6 citation statements)

References 71 publications

(78 reference statements)

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“…In combination with the NH 1 4 limitation experiment, the results demonstrate that phenotypic heterogeneity in a certain metabolic activity (i.e., N 2 fixation) can be driven by different modes of limitation (here limitation in NH 1 4 and H 2 S) in a single microbial population (i.e., C. phaeobacteroides). These results might be best understood in terms of a general feedback between growth state and gene expression (Klumpp et al, 2009;Scott et al, 2010;Kiviet et al, 2014;New et al, 2014;Solopova et al, 2014;Kotte et al, 2014;Guantes et al, 2016;Nordholt et al, 2017).…”

Section: Resultsmentioning

confidence: 99%

“…Phenotypic heterogeneity helps microbial populations (Ackermann, ) to adapt to fluctuating environmental conditions (Balaban et al ., ; Kussell and Leibler, ; Acar et al ., ; Beaumont et al ., ; Ratcliff and Denison, ; Arnoldini et al ., ; Schreiber et al ., ), aids in the division of labour within isogenic cell populations (Ackermann et al ., ) and can result from negative frequency‐dependent interactions in mixed resource environments (Healey et al ., ). Multiple studies on phenotypic heterogeneity have been conducted with microbial model strains, while only a few studies have investigated environmental isolates (Ziv et al ., ; Holland et al ., ; New et al ., ; Miot et al ., ; Guantes et al ., ) or natural microbial populations (Kopf et al ., ; Zimmermann et al ., ; Sheik et al ., ). Thus, there remains a knowledge gap as to how phenotypic heterogeneity is controlled in environmental bacteria without long laboratory culture history and in natural microbial populations.…”

Section: Introductionmentioning

confidence: 99%

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Substrate and electron donor limitation induce phenotypic heterogeneity in different metabolic activities in a green sulphur bacterium

Zimmermann

Escrig

Lavik

et al. 2018

Environ Microbiol Rep

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Populations of genetically identical cells can display marked variation in phenotypic traits; such variation is termed phenotypic heterogeneity. Here, we investigate the effect of substrate and electron donor limitation on phenotypic heterogeneity in N and CO fixation in the green sulphur bacterium Chlorobium phaeobacteroides. We grew populations in chemostats and batch cultures and used stable isotope labelling combined with nanometer-scale secondary ion mass spectrometry (NanoSIMS) to quantify phenotypic heterogeneity. Experiments in H S (i.e. electron donor) limited chemostats show that varying levels of NH4+ limitation induce heterogeneity in N fixation. Comparison of phenotypic heterogeneity between chemostats and batch (unlimited for H S) populations indicates that electron donor limitation drives heterogeneity in N and CO fixation. Our results demonstrate that phenotypic heterogeneity in a certain metabolic activity can be driven by different modes of limitation and that heterogeneity can emerge in different metabolic processes upon the same mode of limitation. In conclusion, our data suggest that limitation is a general driver of phenotypic heterogeneity in microbial populations.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Substrate and electron donor limitation induce phenotypic heterogeneity in different metabolic activities in a green sulphur bacterium

Zimmermann

Escrig

Lavik

et al. 2018

Environ Microbiol Rep

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“…neighbors having different phenotypes) can facilitate division of labor between cells. This can be of benefit in the context of anabolic pathways: cells can benefit from economies of scale by specializing on the biosynthesis of a subset of metabolites, while exchanging end products with neighbors specializing on complementary pathways (Johnson et al , 2012; Guantes et al , 2015).…”

Section: Introductionmentioning

confidence: 99%

Spatially Correlated Gene Expression in Bacterial Groups: The Role of Lineage History, Spatial Gradients, and Cell-Cell Interactions

Vliet

Winkler

et al. 2018

Cell Systems

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Gene expression levels in clonal bacterial groups have been found to be spatially correlated. These correlations can partly be explained by the shared lineage history of nearby cells, although they could also arise from local cell-cell interactions. Here, we present a quantitative framework that allows us to disentangle the contributions of lineage history, long-range spatial gradients, and local cell-cell interactions to spatial correlations in gene expression. We study pathways involved in toxin production, SOS stress response, and metabolism in Escherichia coli microcolonies and find for all pathways that shared lineage history is the main cause of spatial correlations in gene expression levels. However, long-range spatial gradients and local cell-cell interactions also contributed to spatial correlations in SOS response, amino acid biosynthesis, and overall metabolic activity. Together, our data show that the phenotype of a cell is influenced by its lineage history and population context, raising the question of whether bacteria can arrange their activities in space to perform functions they cannot achieve alone.

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“…Previous studies characterized how genetic composition in a population changes slowly through mutations and becomes diverse in environments where nutrients are limited and fluctuate [4][5][6][7][8][9][10][11]. In recent years, it became clear that a genetically identical population can also diversify phenotypically [12][13][14][15][16][17][18][19][20][21][22][23]. Phenotypic diversity can have significant effects on ecological dynamics of populations and species [24]; for example, it has a critical role in population survival through catastrophic environmental changes [25], promoting sustenance of microbial species [26,27].…”

Section: Introductionmentioning

confidence: 99%

The emergence of metabolic heterogeneity and diverse growth responses in isogenic bacterial cells

Şimşek

Kim

2018

The ISME Journal

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Microorganisms adapt to frequent environmental changes through population diversification. Previous studies demonstrated phenotypic diversity in a clonal population and its important effects on microbial ecology. However, the dynamic changes of phenotypic composition have rarely been characterized. Also, cellular variations and environmental factors responsible for phenotypic diversity remain poorly understood. Here, we studied phenotypic diversity driven by metabolic heterogeneity. We characterized metabolic activities and growth kinetics of starved Escherichia coli cells subject to nutrient upshift at single-cell resolution. We observed three subpopulations with distinct metabolic activities and growth phenotypes. One subpopulation was metabolically active and immediately grew upon nutrient upshift. One subpopulation was metabolically inactive and non-viable. The other subpopulation was metabolically partially active, and did not grow upon nutrient upshift. The ratio of these subpopulations changed dynamically during starvation. A long-term observation of cells with partial metabolic activities indicated that their metabolism was later spontaneously restored, leading to growth recovery. Further investigations showed that oxidative stress can induce the emergence of a subpopulation with partial metabolic activities. Our findings reveal the emergence of metabolic heterogeneity and associated dynamic changes in phenotypic composition. In addition, the results shed new light on microbial dormancy, which has important implications in microbial ecology and biomedicine.

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Transcription factor levels enable metabolic diversification of single cells of environmental bacteria

Cited by 15 publications

References 71 publications

Substrate and electron donor limitation induce phenotypic heterogeneity in different metabolic activities in a green sulphur bacterium

Substrate and electron donor limitation induce phenotypic heterogeneity in different metabolic activities in a green sulphur bacterium

Spatially Correlated Gene Expression in Bacterial Groups: The Role of Lineage History, Spatial Gradients, and Cell-Cell Interactions

The emergence of metabolic heterogeneity and diverse growth responses in isogenic bacterial cells

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