AI Article Synopsis
- Bacterial adhesion to inorganic/nanoengineered surfaces is crucial in biotechnology and medicine, as it influences pathogen-related events.
- The study reveals that specific nanostructured surfaces alter E. coli's behavior, causing changes in morphology and genetic expression, particularly the disappearance of type-1 fimbriae.
- Proteomic analysis shows significant shifts in proteins related to stress and defense mechanisms in bacteria on these surfaces, indicating that surface topography significantly impacts bacterial responses and could guide the design of advanced antibacterial materials.
Article Abstract
Bacterial adhesion onto inorganic/nanoengineered surfaces is a key issue in biotechnology and medicine, because it is one of the first necessary steps to determine a general pathogenic event. Understanding the molecular mechanisms of bacteria-surface interaction represents a milestone for planning a new generation of devices with unanimously certified antibacterial characteristics. Here, we show how highly controlled nanostructured substrates impact the bacterial behavior in terms of morphological, genomic, and proteomic response. We observed by atomic force microscopy (AFM) and scanning electron microscopy (SEM) that type-1 fimbriae typically disappear in Escherichia coli adherent onto nanostructured substrates, as opposed to bacteria onto reference glass or flat gold surfaces. A genetic variation of the fimbrial operon regulation was consistently identified by real time qPCR in bacteria interacting with the nanorough substrates. To gain a deeper insight into the molecular basis of the interaction mechanisms, we explored the entire proteomic profile of E. coli by 2D-DIGE, finding significant changes in the bacteria adherent onto the nanorough substrates, such as regulations of proteins involved in stress processes and defense mechanisms. We thus demonstrated that a pure physical stimulus, that is, a nanoscale variation of surface topography, may play per se a significant role in determining the morphological, genetic, and proteomic profile of bacteria. These data suggest that in depth investigations of the molecular processes of microorganisms adhering to surfaces are of great importance for the design of innovative biomaterials with active biological functionalities.
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| http://dx.doi.org/10.1021/nn102692m | DOI Listing |
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