Real-time monitoring of quorum sensing in 3D-printed bacterial aggregates using scanning electrochemical microscopy

Connell, Jodi L.; Kim, Jiyeon; Shear, Jason B.; Bard, Allen J.; Whiteley, Marvin

doi:10.1073/pnas.1421211111

Cited by 166 publications

(169 citation statements)

References 60 publications

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“…96) can spatially regulate biofilm formation 97 and dispersion 98 , and can also stimulate other virulence properties, such as antibiotic resistance 94,99 and per-sistence 96 . As these signals are often restricted to very short-range (<10 µm) effects 100 , they have the potential to generate fine-scale spatial structure. However, signalling is restricted to only those species with an appropriate receptor, suggesting that non-discriminatory metabolic interactions may be a more widespread force that generates spatial structure.…”

Section: Polymicrobial Infectionsmentioning

confidence: 99%

The biogeography of polymicrobial infection

et al. 2015

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Microbial communities are spatially organized in both the environment and the human body. Although patterns exhibited by these communities are described by microbial biogeography this discipline has previously only considered large-scale, global patterns. By contrast, the fine-scale positioning of a pathogen within an infection site can greatly alter its virulence potential. In this Review, we highlight the importance of considering spatial positioning in the study of polymicrobial infections and discuss targeting biogeography as a therapeutic strategy.

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Section: Polymicrobial Infectionsmentioning

confidence: 99%

The biogeography of polymicrobial infection

et al. 2015

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“…In one application, designer bacterial ecosystems that varied in geometry and spatial structure were printed using a gelatin-based material in order to study cell-to-cell interactions ([47, 48]; Table 1). In a second application, nano-scale 3D printing technology was used to print replicas of abdominal scales from rainbow peacock spiders ( Maratus robinsoni and M. chrysomelas ) and specialized hairs from blue tarantulas ( Poecilotheria metallica and Lampropelma violaceopes ) with comparable visual properties to the actual structures [49, 50].…”

Section: Workflow Methodologymentioning

confidence: 99%

“…18[29] Social behavior of zebrafish in response to varying stimuliZebrafish ( Danio rerio )Predatory fish model robot shoals comprising 3 zebrafish that varied in body size plus anchoring materials biologically-inspired zebrafish replicaABS plasticABS plasticABS plastic14 shoals1[68][28] [45] Influence of female body size on mate choice by malesNorthern map turtles ( Graptemys geographica )Replicas of female turtles that differed in body sizeABS plastic4[32] Evaluation of 3D printing as suitable method for field predation model studiesBrown anole ( Anolis sagrei )Lizard models using 2 print media, covered in clay, and field-tested for predationABS plastic, plastic-wood hybrid filament17This studyThermal ecology Comparing thermodynamics of 3D printed and copper lizard modelsTexas horned lizard ( Phrynosoma cornutum )Thermal models of lizardsABS plastic10[13]Tools—experimental areas Evaluation of 3D printed soil as suitable for fungal colonizationPlant pathogenic fungus ( Rhizoctonia solani )Artificial soil from 3D scans of soil with varying micropore structureNylon 1210[33] Comparing hydraulic properties of 3D printed soil relative to real soilSoilArtificial soil from 3D scans of soilResin (Visijet Crystal EX 200 Plastic Material)14[34] Microscale bacterial cell–cell interactions Pseudomonas aeruginosa and Staphlylococcus aureus “Designer” bacterial ecosystems that vary in size, geometry and spatial distance with exact starting quantities of P. aeruginosa and S. aureus GelatinNR[47, 48] Effect of interstitial space on predator–prey interactionsBlue crab ( Cal...…”

Section: Introductionmentioning

confidence: 99%

Benefits and limitations of three-dimensional printing technology for ecological research

et al. 2018

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BackgroundEcological research often involves sampling and manipulating non-model organisms that reside in heterogeneous environments. As such, ecologists often adapt techniques and ideas from industry and other scientific fields to design and build equipment, tools, and experimental contraptions custom-made for the ecological systems under study. Three-dimensional (3D) printing provides a way to rapidly produce identical and novel objects that could be used in ecological studies, yet ecologists have been slow to adopt this new technology. Here, we provide ecologists with an introduction to 3D printing.ResultsFirst, we give an overview of the ecological research areas in which 3D printing is predicted to be the most impactful and review current studies that have already used 3D printed objects. We then outline a methodological workflow for integrating 3D printing into an ecological research program and give a detailed example of a successful implementation of our 3D printing workflow for 3D printed models of the brown anole, Anolis sagrei, for a field predation study. After testing two print media in the field, we show that the models printed from the less expensive and more sustainable material (blend of 70% plastic and 30% recycled wood fiber) were just as durable and had equal predator attack rates as the more expensive material (100% virgin plastic).ConclusionsOverall, 3D printing can provide time and cost savings to ecologists, and with recent advances in less toxic, biodegradable, and recyclable print materials, ecologists can choose to minimize social and environmental impacts associated with 3D printing. The main hurdles for implementing 3D printing—availability of resources like printers, scanners, and software, as well as reaching proficiency in using 3D image software—may be easier to overcome at institutions with digital imaging centers run by knowledgeable staff. As with any new technology, the benefits of 3D printing are specific to a particular project, and ecologists must consider the investments of developing usable 3D materials for research versus other methods of generating those materials.Electronic supplementary materialThe online version of this article (10.1186/s12898-018-0190-z) contains supplementary material, which is available to authorized users.

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“…Bacteria employ chemical signaling to communicate among themselves upon the availability of favorable or detrimental compounds. Different aspects of this signaling have been shown in the bacterial cell-to-cell communication field (25,(122)(123)(124). The advent of novel technologies will help to obtain more detailed information on the intricate microbiotapathogen-host relationships to directly identify single molecules or more complex compounds present during in vivo infections.…”

Section: Approaches To Interfere With Bacterial Pathogenesismentioning

confidence: 99%

Bacterial Chat: Intestinal Metabolites and Signals in Host-Microbiota-Pathogen Interactions

2017

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Intestinal bacteria employ microbial metabolites from the microbiota and chemical signaling during cell-to-cell communication to regulate several cellular functions. Pathogenic bacteria are extremely efficient in orchestrating their response to these signals through complex signaling transduction systems. Precise coordination and interpretation of these multiple chemical cues is important within the gastrointestinal (GI) tract. Enteric foodborne pathogens, such as enterohemorrhagic Escherichia coli (EHEC) and Salmonella enterica serovar Typhimurium, or the surrogate murine infection model for EHEC, Citrobacter rodentium, are all examples of microorganisms that modulate the expression of their virulence repertoire in response to signals from the microbiota or the host, such as autoinducer-3 (AI-3), epinephrine (Epi), and norepinephrine (NE). The QseBC and QseEF two-component systems, shared by these pathogens, are involved in sensing these signals. We review how these signaling systems sense and relay these signals to drive bacterial gene expression; specifically, to modulate virulence. We also review how bacteria chat via chemical signals integrated with metabolite recognition and utilization to promote successful associations among enteric pathogens, the microbiota, and the host. KEYWORDS chemical signaling, Enterobacteriaceae, Escherichia, Salmonella, intestinal metabolites COMMENSALS AND PATHOGENS IN THE GUTT he large and diverse bacterial community in the human gut also has important functions in the physiology of the intestine. The intestinal mucosa forms a physical barrier that keeps the microbiota on the luminal side. The mucus layer is composed of mucin, glycoproteins, trefoil peptides, and surfactant phospholipids (Fig. 1). Altogether, they constitute a nutrient-rich mucus layer, which has an important role as a protective barrier against microorganisms (1). The biogeography of the gastrointestinal (GI) tract is diverse in its composition and density and its distinct chemical and physical features (2). The density and composition of bacterial communities change according to their location in the gut. Throughout the GI tract, there is significant variation in the physicochemical conditions and substrate availability that impact bacterial growth, differentially promoting or hampering the colonization of certain niches by various species. In the proximal colon, the high concentration of sugar substrates in the mucus allows the expansion of the saccharolytic members of the microbiota (Table 1). Inversely, the lower availability of sugar substrates in the distal colon triggers proteolysis, which decreases the bacterial growth rate and the diversity of the microbiota (1, 3). The resident microbiota, together with all chemical and physical features of the intestine, contribute to shape the metabolic landscape within the gut, producing a multitude of characterized and as-yet-unknown intestinal metabolites. Moreover, the microbial composition of the human GI tract varies with age, diet, host genetics, a...

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Real-time monitoring of quorum sensing in 3D-printed bacterial aggregates using scanning electrochemical microscopy

Cited by 166 publications

References 60 publications

The biogeography of polymicrobial infection

The biogeography of polymicrobial infection

Benefits and limitations of three-dimensional printing technology for ecological research

Bacterial Chat: Intestinal Metabolites and Signals in Host-Microbiota-Pathogen Interactions

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