Single-cell variability of growth interactions within a two-species bacterial community

Guo, Xiaokan; Silva, Kalinga Pavan T.; Boedicker, James

doi:10.1088/1478-3975/ab005f

Cited by 12 publications

(11 citation statements)

References 80 publications

(93 reference statements)

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“…Although they have not yet been employed for investigating algal-associated communities, the capability of microchambers for co-culture has been demonstrated in other microbial communities. For example, Guo et al studied single-cell variability in an array of microwells using a co-culture system of Escherichia coli and Enterobacter cloacae [27]. The microfluidic platform enabled them to investigate the heterogeneity of cell growth rate at the single-cell level.…”

Section: Modeling Microbial Community Organizationmentioning

confidence: 99%

Microfluidic and mathematical modeling of aquatic microbial communities

Liu

Giometto

2020

Anal Bioanal Chem

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Aquatic microbial communities contribute fundamentally to biogeochemical transformations in natural ecosystems, and disruption of these communities can lead to ecological disasters such as harmful algal blooms. Microbial communities are highly dynamic, and their composition and function are tightly controlled by the biophysical (e.g., light, fluid flow, and temperature) and biochemical (e.g., chemical gradients and cell concentration) parameters of the surrounding environment. Due to the large number of environmental factors involved, a systematic understanding of the microbial community-environment interactions is lacking. In this article, we show that microfluidic platforms present a unique opportunity to recreate well-defined environmental factors in a laboratory setting in a high throughput way, enabling quantitative studies of microbial communities that are amenable to theoretical modeling. The focus of this article is on aquatic microbial communities, but the microfluidic and mathematical models discussed here can be readily applied to investigate other microbiomes.

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Section: Modeling Microbial Community Organizationmentioning

confidence: 99%

Microfluidic and mathematical modeling of aquatic microbial communities

Liu

Giometto

2020

Anal Bioanal Chem

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“…Are there important consequences for populations when two rare phenotypes of different species interact? One recent experiment to report on this concept [90], examined the coupling of growth rates within small, mixed populations of E. coli and Enterobacter cloacae. Using a microwell device to create replicate groups containing only a few cells of each species, it was found that the mean and variability of growth rates was higher in co-cultures than single strain cultures.…”

Section: Single-cell Heterogeneity In Communicationmentioning

confidence: 99%

Computation in bacterial communities

Ostovar¹,

Naughton²,

Boedicker³

2020

Phys. Biol.

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Bacteria across many scales are involved in a dynamic process of information exchange to coordinate activity and community structure within large and diverse populations. The molecular components bacteria use to communicate have been discovered and characterized, and recent efforts have begun to understand the potential for bacterial signal exchange to gather information from the environment and coordinate collective behaviors. Such computations made by bacteria to coordinate the action of a population of cells in response to information gathered by a multitude of inputs is a form of collective intelligence. These computations must be robust to fluctuations in both biological, chemical, and physical parameters as well as to operate with energetic efficiency. Given these constraints, what are the limits of computation by bacterial populations and what strategies have evolved to ensure bacterial communities efficiently work together? Here the current understanding of information exchange and collective decision making that occur in microbial populations will be reviewed. Looking toward the future, we consider how a deeper understanding of bacterial computation will inform future direction in microbiology, biotechnology, and biophysics.

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“…Most cellular properties are subject to random variability (noise) [1]- [3]. Although these fluctuations are traditionally studied in single-cell variables, such as protein levels, stochasticity also affects collective variables involving cell populations such as gene drift [4], [5], host invasion by pathogen cells [6], the survival of small groups to antimicrobial treatment [7], ecology of cell populations [8], size-based interactions [9] and metabolite production [10].…”

Section: Introductionmentioning

confidence: 99%

Cell size regulation and proliferation fluctuations in single-cell derived colonies

Nieto

Vargas-García

Pedraza

et al. 2022

Preprint

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Exponentially growing cells regulate their size by controlling their timing of division. Since two daughter cells are born as a result of this cell splitting, cell size regulation has a direct connection with cell proliferation dynamics. Recent models found more clues about this connection by suggesting that division occurs at a size-dependent rate. In this article, we propose a framework that couples the stochastic transient dynamics of both the cell size and the number of cells in the initial expansion of a single-cell-derived colony. We describe the population from the two most common perspectives. The first is known as Single Lineage: where only one cell is followed in each colony, and the second is Population Snapshots: where all cells in different colonies are followed. At a low number of cells, we propose a third perspective; Single Colony, where one tracks only cells with a common ancestor. We observe how the statistics of these three approaches are different at low numbers and how the Single Colony perspective tends to Population Snapshots at high numbers. Analyzing colony-to-colony fluctuations in the number of cells, we report an intriguing find: the extent of fluctuations first increases with time and then decreases to approach zero at large numbers of cells. In contrast, in classical size-independent proliferation models, where cell division occurs based on a pure timing mechanism, fluctuations in cell number increase monotonically over time to approach a nonzero value. We systematically study these differences and the convergence speed using different size control strategies.

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Single-cell variability of growth interactions within a two-species bacterial community

Cited by 12 publications

References 80 publications

Microfluidic and mathematical modeling of aquatic microbial communities

Microfluidic and mathematical modeling of aquatic microbial communities

Computation in bacterial communities

Cell size regulation and proliferation fluctuations in single-cell derived colonies

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