Megan A. Ferguson

Quantitative changes in the elasticity and adhesive properties of Escherichia coli ZK1056 prey cells during predation by bdellovibrio bacteriovorus 109J.

Atomic force microscopy (AFM) was used to explore the changes that occur in Escherichia coli ZK1056 prey cells while they are being consumed by the bacterial predator Bdellovibrio bacteriovorus 109J. Invaded prey cells, called bdelloplasts, undergo substantial chemical and physical changes that can be directly probed by AFM. In this work, we probe the elasticity and adhesive properties of uninvaded prey cells and bdelloplasts in a completely native state in dilute aqueous buffer without chemical fixation. Under these conditions, the rounded bdelloplasts were shown to be shorter than uninvaded prey cells. More interestingly, the extension portions of force curves taken on both kinds of cells clearly demonstrate that bdelloplasts are softer than uninvaded prey cells, reflecting a decrease in bdelloplast elasticity after invasion by Bdellovibrio predators. On average, the spring constant of uninvaded E. coli cells (0.23 +/- 0.02 N/m) was 3 times stiffer than that of the bdelloplast (0.064 +/- 0.001 N/m) when measured in a HEPES-metals buffer. The retraction portions of the force curves indicate that compared to uninvaded E. coli cells bdelloplasts adhere to the AFM tip with much larger pull-off forces but over comparable retraction distances. The strength of these adhesion forces decreases with increasing ionic strength, indicating that there is an electrostatic component to the adhesion events.

Characterizing Pilus-Mediated Adhesion of Biofilm-Forming E. coli to Chemically Diverse Surfaces Using Atomic Force Microscopy

Biofilms are complex communities of microorganisms living together at an interface. Because biofilms are often associated with contamination and infection, it is critical to understand how bacterial cells adhere to surfaces in the early stages of biofilm formation. Even harmless commensal Escherichia coli naturally forms biofilms in the human digestive tract by adhering to epithelial cells, a trait that presents major concerns in the case of pathogenic E. coli strains. The laboratory strain E. coli ZK1056 provides an intriguing model system for pathogenic E. coli strains because it forms biofilms robustly on a wide range of surfaces.E. coli ZK1056 cells spontaneously form living biofilms on polylysine-coated AFM cantilevers, allowing us to measure quantitatively by AFM the adhesion between native biofilm cells and substrates of our choice. We use these biofilm-covered cantilevers to probe E. coli ZK1056 adhesion to five substrates with distinct and well-characterized surface chemistries, including fluorinated, amine-terminated, and PEG-like monolayers, as well as unmodified silicon wafer and mica. Notably, after only 0–10 s of contact time, the biofilms adhere strongly to fluorinated and amine-terminated monolayers as well as to mica and weakly to “antifouling” PEG monolayers, despite the wide variation in hydrophobicity and charge of these substrates. In each case the AFM retraction curves display distinct adhesion profiles in terms of both force and distance, highlighting the cells’ ability to adapt their adhesive properties to disparate surfaces. Specific inhibition of the pilus protein FimH by a nonhydrolyzable mannose analogue leads to diminished adhesion in all cases, demonstrating the critical role of type I pili in adhesion by this strain to surfaces bearing widely different functional groups. The strong and adaptable binding of FimH to diverse surfaces has unexpected implications for the design of antifouling surfaces and antiadhesion therapies.

Rapid isolation of host-independent Bdellovibrio bacteriovorus

A new method of isolating host-independent Bdellovibrio bacteriovorus has been developed. Filtered suspensions of host-dependent cells are dropped in small volumes onto 0.2 microm membranes laid on rich media agar. Significant growth is observed within 1-2 days; these cells were confirmed to be B. bacteriovorus using microscopic observations and PCR.

Spatially Organized Films from Bdellovibrio bacteriovorus Prey Lysates

ABSTRACT Bdellovibrio bacteriovorus is a Gram-negative predator of other Gram-negative bacteria. Interestingly, Bdellovibrio bacteriovorus 109J cells grown in coculture with Escherichia coli ML-35 prey develop into a spatially organized two-dimensional film when located on a nutrient-rich surface. From deposition of 10 μl of a routine cleared coculture of B. bacteriovorus and E. coli cells, the cells multiply into a macroscopic community and segregate into an inner, yellow circular region and an outer, off-white region. Fluorescence in situ hybridization and atomic force microscopy measurements confirm that the mature film is spatially organized into two morphologically distinct Bdellovibrio populations, with primarily small, vibroid cells in the center and a complex mixture of pleomorphic cells in the outer radii. The interior region cell population exhibits the hunting phenotype while the outer region cell subpopulation does not. Crowding and high nutrient availability with limited prey appear to favor diversification of the B. bacteriovorus population into two distinct, thriving subpopulations and may be beneficial to the persistence of B. bacteriovorus in biofilms.

Using Microfluidics to Explore Chemotaxis by the Predatory Bacterium Bdellovibrio Bacteriovorus

Bdellovibrio bacteriovorus is a Gram-negative proteobacterium that preys upon a wide variety other Gram-negative bacteria in the environment. Sensing of and movement toward suitable prey is likely critical to survival of a predator, and indeed, twenty chemotaxis receptors and the associated signaling and flagellar proteins have been discovered in the Bdellovibrio genome. Nevertheless, Bdellovibrio chemotaxis has never been demonstrated using conventional assays, and the molecules that bind to its chemotaxis receptors have not yet been identified.We are using microfluidics to explore chemotaxis in individual Bdellovibrio predators. Microfluidics focuses on creating devices for controlling fluid at the micrometer scale, where fluid interfaces and concentration gradients can be finely manipulated. In this study, we designed and fabricated a microfluidic device within which gradients of sugars, metabolites, signaling molecules, and other molecules of interest can be established. Bdellovibrio predators are introduced to the gradient and are allowed to move in response to the molecules in their environment. Unlike conventional assays that measure chemotaxis as a “yes/no” response, relative degrees of response to molecular stimuli and negative responses can also be measured within this microfluidic device. Movement of the predatory bacteria within these gradients should provide critical information about the molecules responsible for Bdellovibrio chemotaxis toward prey.