Designing Metabolic Division of Labor in Microbial Communities

Thommes, Meghan; Wang, Taiyao; Zhao, Qi; Paschalidis, Ioannis Ch.; Segrè, Daniel

doi:10.1128/msystems.00263-18

Cited by 100 publications

(63 citation statements)

References 108 publications

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“…MultiPlus [114] has two fixed objectives: minimizing the number of reactions and minimizing the exchanged metabolites, in a de novo synthesis pathway; starting from an hypergraph that integrates several GEM models. Following a MILP optimization approach, DOLMN [115] identifies communities able to survive under constraints (e.g. limited number of reactions) that are difficult to identify manually.…”

Section: Generic Methods Optimizing Pathway Distributions Have Been Amentioning

confidence: 99%

“…At least 215 and 203 internal reactions to grow, respectively for 2 and 3 strain consortia. Loss one reaction is not compensated with adding one metabolite in the medium (nonlinear boundary) [115] Maximizing -4 E. coli case of study: -GR: 0.736 gDWh −1 -Strains ratio: Ec1-Ec2=50%, Ec3-Ec4=50%. Direct competition Ec1-Ec4 and Ec2-Ec3 -Gut microbiome case of study: values depending on fibre uptake from B. thetaiotaomicron:…”

Section: Human Gut Strains From Agora Collectionmentioning

confidence: 99%

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Metabolic Modelling Approaches for Describing and Engineering Microbial Communities

García-Jiménez¹,

Torres²,

Nogales³

2020

Preprint

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Microbes do not live in isolation but in microbial communities. The relevance of microbial communities is increasing due to the awareness about their biotechnological influences in a huge number of environmental, health and industrial processes. Hence, being able to control and engineer the output of both natural and synthetic communities would be of great interest. However, most of the available methods and biotechnological applications (both in vivo and in silico) have been developed in the context of isolated microbes. In vivo microbial consortia development, i.e. to reproduce the community life conditions in the wet-lab, is extremely difficult and expensive requiring of computational approaches to advance knowledge about microbial communities, mainly with descriptive modelling, and further with engineering modelling. In this review we provide a detailed compilation of available examples of engineered microbial communities as a launch pad for an exhaustive and historical revision of those computational methods devoted so far toward the better understanding, and rational engineering of natural and synthetic microbial communities.

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Section: Generic Methods Optimizing Pathway Distributions Have Been Amentioning

confidence: 99%

Section: Human Gut Strains From Agora Collectionmentioning

confidence: 99%

Metabolic Modelling Approaches for Describing and Engineering Microbial Communities

García-Jiménez¹,

Torres²,

Nogales³

2020

Preprint

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“…Similarly, genome-scale metabolic models have been used to aide in the design of large scale communities by predicting metabolites that can be released by the producer without detriment to fitness, and conditions that encourage the establishment of stable communities (Pacheco et al, 2019). Thommes et al (2019) used genome scale metabolic models of E. coli to compute feasible division of labor strategies that could arise from an initial monoculture through loss of function in genes, giving insight into possible avenues for engineering community formation. Angulo et al (2019) demonstrated a mathematical method for identifying "driver species" in an ecological network.…”

Section: Modeling Approachesmentioning

confidence: 99%

From Microbial Communities to Distributed Computing Systems

Karkaria¹,

Treloar²,

Barnes³

et al. 2020

Front. Bioeng. Biotechnol.

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A distributed biological system can be defined as a system whose components are located in different subpopulations, which communicate and coordinate their actions through interpopulation messages and interactions. We see that distributed systems are pervasive in nature, performing computation across all scales, from microbial communities to a flock of birds. We often observe that information processing within communities exhibits a complexity far greater than any single organism. Synthetic biology is an area of research which aims to design and build synthetic biological machines from biological parts to perform a defined function, in a manner similar to the engineering disciplines. However, the field has reached a bottleneck in the complexity of the genetic networks that we can implement using monocultures, facing constraints from metabolic burden and genetic interference. This makes building distributed biological systems an attractive prospect for synthetic biology that would alleviate these constraints and allow us to expand the applications of our systems into areas including complex biosensing and diagnostic tools, bioprocess control and the monitoring of industrial processes. In this review we will discuss the fundamental limitations we face when engineering functionality with a monoculture, and the key areas where distributed systems can provide an advantage. We cite evidence from natural systems that support arguments in favor of distributed systems to overcome the limitations of monocultures. Following this we conduct a comprehensive overview of the synthetic communities that have been built to date, and the components that have been used. The potential computational capabilities of communities are discussed, along with some of the applications that these will be useful for. We discuss some of the challenges with building co-cultures, including the problem of competitive exclusion and maintenance of desired community composition. Finally, we assess computational frameworks currently available to aide in the design of microbial communities and identify areas where we lack the necessary tools.

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“…In natural environments, microorganisms rarely live autonomously, but interact with other individuals to form complex communities, in which they secrete a variety of toxins to compete with each other, or share metabolites to mutually benefit their survival. Among a variety of modes of microbial interaction, metabolic division of labor (MDOL) is one of the most widespread phenomena, where distinct populations perform different but complementary steps of the same metabolic pathway [1][2][3][4] . MDOL controls numerous ecologically and environmentally important biochemical processes.…”

Section: Introductionmentioning

confidence: 99%

Substrate traits govern the assembly and spatial organization of microbial community engaged in metabolic division of labor

Fang

Chen

Nie

et al. 2020

Preprint

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Metabolic division of labor (MDOL) is widespread in nature, whereby a complex metabolic pathway is shared between different strains within a community for mutual benefit. However, little is known about how communities engaged in MDOL assemble and spatially organize. We hypothesized that when degradation of an organic compound is carried out via MDOL, substrate concentration and its toxicity modulate the benefit allocation between the two microbial populations, thus governing the assembly of this community. We tested this hypothesis by combining individual-based simulations with pattern formation assays using a synthetic microbial community. We found that while the frequency of the first population increases with an increase in substrate concentration, this increase is capped with an upper bound determined by the biotoxicity of the substrate. In addition, our model showed that substrate concentration and its toxicity affect levels of intermixing between strains. These predictions were quantitatively verified using an engineered system composed of two strains degrading salicylate through MDOL. Our results demonstrate that the structure of the microbial communities can be quantitatively predicted from simple environmental factors, such as substrate concentration and its toxicity, which provides novel perspectives on understanding the assembly of natural communities, as well as insights into how to manage artificial microbial systems.

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Designing Metabolic Division of Labor in Microbial Communities

Cited by 100 publications

References 108 publications

Metabolic Modelling Approaches for Describing and Engineering Microbial Communities

Metabolic Modelling Approaches for Describing and Engineering Microbial Communities

From Microbial Communities to Distributed Computing Systems

Substrate traits govern the assembly and spatial organization of microbial community engaged in metabolic division of labor

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