Hydration-controlled bacterial motility and dispersal on surfaces

Dechesne, Arnaud; Wang, Gang; Gulez, Gamze; Or, Dani; Smets, Barth F.

doi:10.1073/pnas.1008392107

Cited by 171 publications

(244 citation statements)

References 34 publications

(30 reference statements)

Supporting

Mentioning

237

Contrasting

Order By: Relevance

“…For given geometry and cell size, the results depicted in Figure 5 show that cell flagellated velocity was relatively constant under saturated condition, and following air entry, the velocity gradually decreased with matric potential until it reached a critical value where capillary forces pin bacterial cells behind air-water interfaces rendering cells nonmotile [Dechesne et al, 2010;Wang and Or, 2010]. The results indicate that cell velocity never achieves to cell velocity in bulk solution due to cell-wall hydrodynamic interactions (see equation (6)).…”

Section: Bacterial Dispersal Characteristics From Individual To Populmentioning

confidence: 80%

“…However, in unsaturated porous media, heterogeneous geometry and hydration conditions restrict the motility of bacteria to a thin aqueous film due to the cell-wall viscous drag and capillary pinning forces [Dechesne et al, 2010;Wang and Or, 2010]. In the pore network model, we consider each corner of triangular-shaped bonds as a separate pathway for bacterial motion with own effective water film thickness, dðuÞ.…”

Section: Bacterial Motilitymentioning

confidence: 99%

“…Dispersal and self-motion play an important role in many biological and ecological processes, including the cycling of soil organic matter [Azam, 1998;Bardgett, 2011;Philippot et al, 2013], bioremediation of contaminated soils and aquifers [Hams and Bosma, 1997;Harms and Wick, 2006;Banitz et al, 2011], promoting the plant rhizosphere and root function, controlling the spread of pathogenic bacteria [Beattie and Lindow, 1995;Beattie, 2011;Van der Wal et al, 2013], and numerous other functions continuously being discovered. Despite the significant role of microbial dispersal in unsaturated soil, based mechanisms and rates remain unclear due to limited experimental data, soil opacity, and complex pore spaces all leading to conflicting reports concerning rates and modes of soil microbial dispersion [Boelens et al, 1994;Turnbull et al, 2001;Dechesne et al, 2010].…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Microbial dispersal in unsaturated porous media: Characteristics of motile bacterial cell motions in unsaturated angular pore networks

Ebrahimi

2014

Water Resources Research

Self Cite

109

View full text Add to dashboard Cite

The dispersal rates of self-propelled microorganisms affect their spatial interactions and the ecological functioning of microbial communities. Microbial dispersal rates affect risk of contamination of water resources by soil-borne pathogens, the inoculation of plant roots, or the rates of spoilage of food products. In contrast with the wealth of information on microbial dispersal in water replete systems, very little is known about their dispersal rates in unsaturated porous media. The fragmented aqueous phase occupying complex soil pore spaces suppress motility and limits dispersal ranges in unsaturated soil. The primary objective of this study was to systematically evaluate key factors that shape microbial dispersal in model unsaturated porous media to quantify effects of saturation, pore space geometry, and chemotaxis on characteristics of principles that govern motile microbial dispersion in unsaturated soil. We constructed a novel 3-D angular pore network model (PNM) to mimic aqueous pathways in soil for different hydration conditions; within the PNM, we employed an individual-based model that considers physiological and biophysical properties of motile and chemotactic bacteria. The effects of hydration conditions on first passage times in different pore networks were studied showing that fragmentation of aquatic habitats under dry conditions sharply suppresses nutrient transport and microbial dispersal rates in good agreement with limited experimental data. Chemotactically biased mean travel speed of microbial cells across 9 mm saturated PNM was $3 mm/h decreasing exponentially to 0.45 mm/h for the PNM at matric potential of 215 kPa (for 235 kPa, dispersal practically ceases and the mean travel time to traverse the 9 mm PNM exceeds 1 year). Results indicate that chemotaxis enhances dispersal rates by orders of magnitude relative to random (diffusive) motions. Model predictions considering microbial cell sizes relative to available liquid pathways sizes were in good agreement with experimental results for unsaturated soils. The new modeling platform enables quantitative consideration of key biophysical factors (e.g., pore space heterogeneities and hydration conditions) governing microbial interactions in 3-D soil pore spaces.

show abstract

Section: Bacterial Dispersal Characteristics From Individual To Populmentioning

confidence: 80%

Section: Bacterial Motilitymentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Microbial dispersal in unsaturated porous media: Characteristics of motile bacterial cell motions in unsaturated angular pore networks

Ebrahimi

2014

Water Resources Research

Self Cite

109

View full text Add to dashboard Cite

show abstract

“…Hydration status and pore-space characteristics are critical factors shaping nutrient fields and bacterial motility, and are thus key to understanding bacterial interactions in soil and other porous media such as dry food products (Barton and Ford, 1997;Dens and Van Impe, 2000;Wilson et al, 2002;Chang and Halverson, 2003;Or et al, 2007;Chen and Jin, 2011). Although motility has long been argued as a key factor for survival in heterogeneous environments and for biodiversity maintenance (Fenchel, 2002;Reichenbach et al, 2007;Vos and Velicer, 2008), it is only recently that crucial processes regulating bacterial motility within liquid films forming on partially hydrated rough surfaces have been quantified (Dechesne et al, 2010;Wang and Or, 2010). These studies have shown that surface roughness and aqueous-phase configuration impose capillary and hydrodynamic constraints limiting bacterial motility, and defined a surprisingly narrow range of hydration conditions where motility could confer ecological advantage on rough surfaces.…”

Section: Introductionmentioning

confidence: 99%

“…We employed a hybrid model that couples individual-based description of cell growth, motion and interactions within a nutrient field described by a (continuum-based) reaction À diffusion model (Kreft et al, 1998;Dechesne et al, 2010). The model resolves spatial and temporal nutrient diffusion fields subjected to prescribed boundary conditions, heterogeneity and local nutrient interception by individual cells.…”

Section: Introductionmentioning

confidence: 99%

Hydration dynamics promote bacterial coexistence on rough surfaces

Wang

2012

The ISME Journal

Self Cite

View full text Add to dashboard Cite

Identification of mechanisms that promote and maintain the immense microbial diversity found in soil is a central challenge for contemporary microbial ecology. Quantitative tools for systematic integration of complex biophysical and trophic processes at spatial scales, relevant for individual cell interactions, are essential for making progress. We report a modeling study of competing bacterial populations cohabiting soil surfaces subjected to highly dynamic hydration conditions. The model explicitly tracks growth, motion and life histories of individual bacterial cells on surfaces spanning dynamic aqueous networks that shape heterogeneous nutrient fields. The range of hydration conditions that confer physical advantages for rapidly growing species and support competitive exclusion is surprisingly narrow. The rapid fragmentation of soil aqueous phase under most natural conditions suppresses bacterial growth and cell dispersion, thereby balancing conditions experienced by competing populations with diverse physiological traits. In addition, hydration fluctuations intensify localized interactions that promote coexistence through disproportional effects within densely populated regions during dry periods. Consequently, bacterial population dynamics is affected well beyond responses predicted from equivalent and uniform hydration conditions. New insights on hydration dynamics could be considered in future designs of soil bioremediation activities, affect longevity of dry food products, and advance basic understanding of bacterial diversity dynamics and its role in global biogeochemical cycles.

show abstract

Hydration and diffusion processes shape microbial community organization and function in model soil aggregates

Ebrahimi

2015

Water Resources Research

Self Cite

128

View full text Add to dashboard Cite

The constantly changing soil hydration status affects gas and nutrient diffusion through soil pores and thus the functioning of soil microbial communities. The conditions within soil aggregates are of particular interest due to limitations to oxygen diffusion into their core, and the presence of organic carbon often acting as binding agent. We developed a model for microbial life in simulated soil aggregates comprising of 3-D angular pore network model (APNM) that mimics soil hydraulic and transport properties. Within these APNM, we introduced individual motile (flagellated) microbial cells with different physiological traits that grow, disperse, and respond to local nutrients and oxygen concentrations. The model quantifies the dynamics and spatial extent of anoxic regions that vary with hydration conditions, and their role in shaping microbial community size and activity and the spatial (self) segregation of anaerobes and aerobes. Internal carbon source and opposing diffusion directions of oxygen and carbon within an aggregate were essential to emergence of stable coexistence of aerobic and anaerobic communities (anaerobes become extinct when carbon sources are external). The model illustrates a range of hydration conditions that promote or suppress denitrification or decomposition of organic matter and thus affect soil GHG emissions. Model predictions of CO 2 and N 2 O production rates were in good agreement with limited experimental data. These limited tests support the dynamic modeling approach whereby microbial community size, composition, and spatial arrangement emerge from internal interactions within soil aggregates. The upscaling of the results to a population of aggregates of different sizes embedded in a soil profile is underway.

show abstract

Hydration-controlled bacterial motility and dispersal on surfaces

Cited by 171 publications

References 34 publications

Microbial dispersal in unsaturated porous media: Characteristics of motile bacterial cell motions in unsaturated angular pore networks

Microbial dispersal in unsaturated porous media: Characteristics of motile bacterial cell motions in unsaturated angular pore networks

Hydration dynamics promote bacterial coexistence on rough surfaces

Hydration and diffusion processes shape microbial community organization and function in model soil aggregates

Contact Info

Product

Resources

About