Development of a Laboratory Model of a Phototroph-Heterotroph Mixed-Species Biofilm at the Stone/Air Interface

Villa, Federica; Pitts, Betsey; Lauchnor, Ellen G.; Cappitelli, Francesca; Stewart, Philip S.

doi:10.3389/fmicb.2015.01251

Cited by 44 publications

(58 citation statements)

References 75 publications

(101 reference statements)

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“…Natural microbial communities have evolved numerous mechanisms for ensuring species coexistence, most notably the biofilm mode of growth. Spatial metabolite gradients within biofilms can allow otherwise slower growing species to establish metabolic niches favorable for their growth [21][22][23][24]. Cross feeding of secreted metabolic byproducts is another mechanism used by microbial communities to enhance the competitiveness of slower growing species and achieve community stability [17][18][19][20].…”

Section: Discussionmentioning

confidence: 99%

“…These cross-feeding relationships are a result of metabolic specialization and establish a food web within the community that maximizes utilization of available resources. When combined with the biofilm mode of growth and associated diffusional limitations, cross feeding establishes local metabolic niches that allow otherwise slower growing species to coexist with faster growing species and is hypothesized to stabilize the community against environmental perturbations [21][22][23][24]. The spatial partitioning of metabolism and physical immobilization by secreted polymers make biofilm cultures distinct from planktonic cultures grown in well-mixed environments where coexistence is not possible unless the species have the same growth rate.…”

Section: Introductionmentioning

confidence: 99%

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Byproduct Cross Feeding and Community Stability in an In Silico Biofilm Model of the Gut Microbiome

Henson

Phalak

2017

Processes

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Abstract:The gut microbiome is a highly complex microbial community that strongly impacts human health and disease. The two dominant phyla in healthy humans are Bacteroidetes and Firmicutes, with minor phyla such as Proteobacteria having elevated abundances in various disease states. While the gut microbiome has been widely studied, relatively little is known about the role of interspecies interactions in promoting microbiome stability and function. We developed a biofilm metabolic model of a very simple gut microbiome community consisting of a representative bacteroidete (Bacteroides thetaiotaomicron), firmicute (Faecalibacterium prausnitzii) and proteobacterium (Escherichia coli) to investigate the putative role of metabolic byproduct cross feeding between species on community stability, robustness and flexibility. The model predicted coexistence of the three species only if four essential cross-feeding relationships were present. We found that cross feeding allowed coexistence to be robustly maintained for large variations in biofilm thickness and nutrient levels. However, the model predicted that community composition and short chain fatty acid levels could be strongly affected only over small ranges of byproduct uptake rates, indicating a possible lack of flexibility in our cross-feeding mechanism. Our model predictions provide new insights into the impact of byproduct cross feeding and yield experimentally testable hypotheses about gut microbiome community stability.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Byproduct Cross Feeding and Community Stability in an In Silico Biofilm Model of the Gut Microbiome

Henson

Phalak

2017

Processes

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“…Biofilm micro-fragments from Saint Cave were analysed by CLSM (Olympus FV 300 -Argon, 488.0nm, He-Ne, 543.5nm), exploiting their self-fluorescence property [36].…”

Section: Microscopy Analysismentioning

confidence: 99%

Fungi and Bacteria in Indoor Cultural Heritage Environments: Microbial-related Risks for Artworks and Human Health

Carlo¹,

Chisesi²,

Barresi³

et al. 2016

eer

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Cultural heritage constitutive materials can provide excellent substrates for microbial colonization, highly influenced by thermo-hygrometric parameters. In cultural heritage-related environments, a detrimental microbial load may be present both on manufacts surface and in the aerosol. In this study, bacterial and fungal colonisation has been investigated in three Sicilian confined environments (archive, cave and hypogea), each with peculiar structures and different thermo-hygrometric parameters. Particular attention has been paid to microorganisms able to induce artifacts biodeterioration and to release biological particles in the aerosol (spores, cellular debrides, toxins and allergens) potentially dangerous for the human health (visitors/users). Results provided information on the composition of the biological consortia, highlighting also the symbiotic relationships between micro (cyanobacteria, bacteria and fungi) and macro-organisms (plants, bryophyte and insects). The results of this integrated approach, including molecular biology techniques, are essential for a complete understanding of both microbial colonization of the cultural objects and the potential relationship with illness to human.

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“…We consider here stability of steady states of the chemostat system, beginning with the single species community model (28)- (31), which has two possible steady states, namely washout (P 1 (t) = 0) and viable (P 1 …”

Section: Appendix D Linearization and Stabilitymentioning

confidence: 99%

“…It is not immediately clear why this should be the case, as competition for resources, e.g., space or nutrients, is possible, and it seems that oxygenic phototrophs might be expected to be able to outcompete heterotrophic neighbors for those resources. Even so, multispecies communities are observed including in environments where heterotrophs might not be able to persist on their own [1]. Further, there are at least some examples of communities where resident phototrophs lack critical anabolic capabilities and must instead rely on nearby organisms to supply them [2].…”

Section: Introductionmentioning

confidence: 99%

Photorespiration and Rate Synchronization in a Phototroph-Heterotroph Microbial Consortium

et al. 2017

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Abstract:The process of oxygenic photosynthesis is robust and ubiquitous, relying centrally on input of light, carbon dioxide, and water, which in many environments are all abundantly available, and from which are produced, principally, oxygen and reduced organic carbon. However, photosynthetic machinery can be conflicted by the simultaneous presence of carbon dioxide and oxygen through a process sometimes called photorespiration. We present here a model of phototrophy, including competition for RuBisCO binding sites between oxygen and carbon dioxide, in a chemostat-based microbial population. The model connects to the idea of metabolic pathways to track carbon and degree of reduction through the system. We find decomposition of kinetics into elementary flux modes a mathematically natural way to study synchronization of mismatched rates of photon input and chemostat turnover. In the single species case, though total biomass is reduced by photorespiration, protection from excess light exposures and its consequences (oxidative and redox stress) may result. We also find the possibility that a consortium of phototrophs with heterotrophs can recycle photorespiration byproduct into increased biomass at the cost of increase in oxidative product (here, oxygen).

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Development of a Laboratory Model of a Phototroph-Heterotroph Mixed-Species Biofilm at the Stone/Air Interface

Cited by 44 publications

References 75 publications

Byproduct Cross Feeding and Community Stability in an In Silico Biofilm Model of the Gut Microbiome

Byproduct Cross Feeding and Community Stability in an In Silico Biofilm Model of the Gut Microbiome

Fungi and Bacteria in Indoor Cultural Heritage Environments: Microbial-related Risks for Artworks and Human Health

Photorespiration and Rate Synchronization in a Phototroph-Heterotroph Microbial Consortium

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