g. nanowires) and indirect mechanisms (electron shuttles such AZD3965 order as flavins)

[15]. Shewanella spp. biofilms have been found to modulate the settlement (with inductive or inhibitory effects) of a variety of macroscopic algae and invertebrates such as Ulva spores [16–18], cypris [19], mussel larvae [20], or sea urchin larvae [21]. Shewanella spp. produce omega-3 fatty acids and other hydrocarbons, probably to increase the fluidity of the cell membrane in cold waters –most Shewanella strains are psychrotolerant- or as a result of a mutualist relationship between fish and bacteria living in their intestines [14, 22]. Indeed, they are being increasingly used as probiotics in aquaculture [23, 24] and, more recently, buy GSK2126458 as a source of hydrocarbon fuels [22]. Among all the members of the shewanellae family, only S. putrefaciens and S. algae are widely recognized to be pathogenic to human and animals, being involved in soft-tissue infections, ear infections, necrotising fasciitis, abscesses, bacteremia, and many other affections

[12, 25–29]. However, there is increasing evidence that point that other Shewanella species are also causative agents of human infections [30, 31]. For all these reasons, S. algae biofilms are of great interest in bacterial fouling studies as well as in many other fields. Figure 1 Tapping mode images in air of Shewanella algae adsorbed on treated polystyrene. (A) 10 × 10 μm2 bidimensional image showing bacterial dimensions and their characteristic flagella; (B) 3.2 × 3.2 μm2 three-dimensional image with bacterial surface roughness and flagella in detail. White arrows indicate the position

of flagella. In anti-biofilm assays, the nutritional Phosphoprotein phosphatase requirements that promote bacterial biofilm formation may not be the same as those employed in antimicrobial susceptibility testing, thus leading to the use of a different culture medium and frequently higher inocula [32]. In order to explore the effect of the culture conditions on the growth and biofilm formation of S. algae, nine media and two incubation temperatures were initially screened. Subsequently, the antibacterial activity of known antifouling biocides was determined using different media and inocula. Finally, in order to assess exhaustively the morphological and physical properties of S. algae biofilms developed in different media, a detailed examination was conducted by see more Confocal Laser Scanning Microscopy (CLSM) and Atomic Force Microscopy (AFM). Over the last few years, AFM has turned into a powerful technique not only for studying the morphology of soft materials such as polymers and biomaterials but also for obtaining information about different properties (mechanical, electrical, magnetic, etc.) of the samples.