Oxidative Stress Transcriptional Responses of at GaN Interfaces.

Microorganisms regulate their interactions with surfaces by altering the transcription of specific target genes in response to physicochemical surface cues. To assess the influence of surface charge and surface chemistry on the transcriptional oxidative stress response, we evaluated the expression of three genes, , , and from the Gram-negative bacterium, after a short exposure to GaN interfaces. We observed that both surface charge and surface chemistry were the factors regulating the transcriptional response of the target genes, which indicates that reactive oxygen species (ROS) generation and the ROS response at the GaN interfaces were affected by changing surface properties.

Modulating the Stress Response of at GaN Interfaces Using Surface Charge, Surface Chemistry, and Genetic Mutations.

The surface properties of inorganic materials can be used to modulate the response of microorganisms at the interface. We used the persistent photoconductivity properties of chemically treated gallium nitride substrates to evaluate the stress response of wild-type, ΔfliC, and ΔcsgG mutant exposed to charged surfaces. Substrate surface characterization and biological assays were used to correlate the physiological response to substrate surface charge.

Modification of the Surface Properties of Al Ga N Substrates with Gradient Aluminum Composition Using Wet Chemical Treatments.

The surface properties of biomolecular gradients are widely known to be important for controlling cell dynamics, but there is a lack of platforms for studying them in vitro using inorganic materials. The changes in various surface properties of an Al Ga N film (0.173 ≤ ≤ 0.