Your search keyword '"Dietrich, Lars E.P."' showing total 4 results

1. Phenazines affect biofilm formation by Pseudomonas aeruginosa in similar ways at various scales

Author

Ramos, Itzel, Dietrich, Lars E.P., Price-Whelan, Alexa, and Newman, Dianne K.

Subjects

*BIOFILMS, *PHENAZINE, *PSEUDOMONAS aeruginosa, *OXIDATION-reduction reaction, *MICROBIAL mutation, *GRAM-negative bacteria, *PHENOTYPES, *ORGANIC synthesis

Abstract

Abstract: Some pseudomonads produce phenazines, a group of small, redox-active compounds with diverse physiological functions. In this study, we compared the phenotypes of Pseudomonas aeruginosa strain PA14 and a mutant unable to synthesize phenazines in flow cell and colony biofilms quantitatively. Although phenazine production does not impact the ability of PA14 to attach to surfaces, as has been shown for Pseudomonas chlororaphis, it influences swarming motility and the surface-to-volume ratio of mature biofilms. These results indicate that phenazines affect biofilm development across a large range of scales, but in unique ways for different Pseudomonas species. [Copyright &y& Elsevier]

Published

2010

2. Metabolic Heterogeneity and Cross-Feeding in Bacterial Multicellular Systems.

Author

Evans, Christopher R., Kempes, Christopher P., Price-Whelan, Alexa, and Dietrich, Lars E.P.

Subjects

*SYNTROPHISM, *MICROFLUIDIC devices, *RAMAN microscopy, *RAMAN scattering, *DYNAMIC balance (Mechanics), *BACTERIAL metabolism

Abstract

Cells in assemblages differentiate and perform distinct roles. Though many pathways of differentiation are understood at the molecular level in multicellular eukaryotes, the elucidation of similar processes in bacterial assemblages is recent and ongoing. Here, we discuss examples of bacterial differentiation, focusing on cases in which distinct metabolisms coexist and those that exhibit cross-feeding, with one subpopulation producing substrates that are metabolized by a second subpopulation. We describe several studies of single-species systems, then segue to studies of multispecies metabolic heterogeneity and cross-feeding in the clinical setting. Many of the studies described exemplify the application of new techniques and modeling approaches that provide insights into metabolic interactions relevant for bacterial growth outside the laboratory. Metabolic diversification in bacterial systems arises from innate stochasticity and can be further promoted by growth in chemical gradients and/or constrained spaces. Metabolic heterogeneity can enable metabolite cross-feeding, and cross-feeding itself can promote the development of metabolically differentiated subpopulations. New techniques for characterizing metabolically diversified subpopulations in situ include those that incorporate three-dimensional dynamic flux balance analysis, 13C-metabolic flux analysis, growth in microfluidic devices, and stimulated Raman scattering microscopy. Metabolic heterogeneity is an important factor to incorporate into models of infection because it influences virulence and antibiotic susceptibility. [ABSTRACT FROM AUTHOR]

Published

2020

3. Molecular insights into RmcA-mediated c-di-GMP consumption: Linking redox potential to biofilm morphogenesis in Pseudomonas aeruginosa.

Author

Scribani Rossi, Chiara, Eckartt, Kelly, Scarchilli, Elisabetta, Angeli, Simone, Price-Whelan, Alexa, Di Matteo, Adele, Chevreuil, Maelenn, Raynal, Bertrand, Arcovito, Alessandro, Giacon, Noah, Fiorentino, Francesco, Rotili, Dante, Mai, Antonello, Espinosa-Urgel, Manuel, Cutruzzolà, Francesca, Dietrich, Lars E.P., Paone, Alessio, Paiardini, Alessandro, and Rinaldo, Serena

Subjects

*REDUCTION potential, *PSEUDOMONAS aeruginosa, *BIOFILMS, *TRANSMEMBRANE domains, *BIOENGINEERING, *MICROCYSTIS aeruginosa, *RHAMNOLIPIDS

Abstract

The ability of many bacteria to form biofilms contributes to their resilience and makes infections more difficult to treat. Biofilm growth leads to the formation of internal oxygen gradients, creating hypoxic subzones where cellular reducing power accumulates, and metabolic activities can be limited. The pathogen Pseudomonas aeruginosa counteracts the redox imbalance in the hypoxic biofilm subzones by producing redox-active electron shuttles (phenazines) and by secreting extracellular matrix, leading to an increased surface area-to-volume ratio, which favors gas exchange. Matrix production is regulated by the second messenger bis-(3′,5′)-cyclic-dimeric-guanosine monophosphate (c-di-GMP) in response to different environmental cues. RmcA (Redox modulator of c-di-GMP) from P. aeruginosa is a multidomain phosphodiesterase (PDE) that modulates c-di-GMP levels in response to phenazine availability. RmcA can also sense the fermentable carbon source arginine via a periplasmic domain, which is linked via a transmembrane domain to four cytoplasmic Per-Arnt-Sim (PAS) domains followed by a diguanylate cyclase (DGC) and a PDE domain. The biochemical characterization of the cytoplasmic portion of RmcA reported in this work shows that the PAS domain adjacent to the catalytic domain tunes RmcA PDE activity in a redox-dependent manner, by differentially controlling protein conformation in response to FAD or FADH2. This redox-dependent mechanism likely links the redox state of phenazines (via FAD/FADH2 ratio) to matrix production as indicated by a hyperwrinkling phenotype in a macrocolony biofilm assay. This study provides insights into the role of RmcA in transducing cellular redox information into a structural response of the biofilm at the population level. Conditions of resource (i.e. oxygen and nutrient) limitation arise during chronic infection, affecting the cellular redox state and promoting antibiotic tolerance. An understanding of the molecular linkages between condition sensing and biofilm structure is therefore of crucial importance from both biological and engineering standpoints. [ABSTRACT FROM AUTHOR]

Published

2023

4. Motility, Chemotaxis and Aerotaxis Contribute to Competitiveness during Bacterial Pellicle Biofilm Development.

Author

Hölscher, Theresa, Bartels, Benjamin, Lin, Yu-Cheng, Gallegos-Monterrosa, Ramses, Price-Whelan, Alexa, Kolter, Roberto, Dietrich, Lars E.P., and Kovács, Ákos T.

Subjects

*MOTILITY of bacteria, *CHEMOTAXIS, *DENTAL pellicle, *COMPETITION (Biology), *BIOFILMS, *CELLULAR signal transduction, *BACTERIA

Abstract

Biofilm formation is a complex process involving various signaling pathways and changes in gene expression. Many of the sensory mechanisms and regulatory cascades involved have been defined for biofilms formed by diverse organisms attached to solid surfaces. By comparison, our knowledge on the basic mechanisms underlying the formation of biofilms at air–liquid interfaces, that is, pellicles, is much less complete. In particular, the roles of flagella have been studied in multiple solid-surface biofilm models but remain largely undefined for pellicles. In this work, we characterize the contributions of flagellum-based motility, chemotaxis and oxygen sensing to pellicle formation in the Gram-positive Bacillus subtilis . We confirm that flagellum-based motility is involved in, but is not absolutely essential for, B. subtilis pellicle formation. Further, we show that flagellum-based motility, chemotaxis and oxygen sensing are important for successful competition during B. subtilis pellicle formation. We report that flagellum-based motility similarly contributes to pellicle formation and fitness in competition assays in the Gram-negative Pseudomonas aeruginosa . Time-lapse imaging of static liquid cultures demonstrates that, in both B. subtilis and P. aeruginosa , a turbulent flow forms in the tube and a zone of clearing appears below the air–liquid interface just before the formation of the pellicle but only in strains that have flagella. [ABSTRACT FROM AUTHOR]

Published

2015