AFM reveals the interaction and nanoscale effects imposed by squalamine on Staphylococcus epidermidis.

The Gram-positive bacterium Staphylococcus epidermidis is responsible for important nosocomial infections. With the continuous emergence of antibiotic-resistant strains, the search for new treatments has been amplified in the last decades. A potential candidate against multidrug-resistant bacteria is squalamine, a natural aminosterol discovered in dogfish sharks. Despite its broad-spectrum efficiency, little is known about squalamine mode of action. Here, we used atomic force microscopy (AFM) imaging to decipher the effect of squalamine on S. epidermidis morphology, revealing the peptidoglycan structure at the bacterial surface after the drug action. Single-molecule force spectroscopy with squalamine-decorated tips shows that squalamine binds to the cell surface via the spermidine motif, most likely through electrostatic interactions between the amine groups of the molecule and the negatively-charged bacterial cell wall. We demonstrated that - although spermidine is sufficient for the initial attachment of squalamine to S. epidermidis - the integrity of the molecule needs to be conserved for its antimicrobial action. A deeper analysis of the AFM force-distance signatures suggests the implication of the accumulation-associated protein (Aap), one of the main adhesins of S. epidermidis, in the initial binding of squalamine to the bacterial cell wall. This work highlights that AFM -combined with microbiological assays at the bacterial suspension scale- is a valuable approach to better understand the molecular mechanisms behind the efficiency of squalamine antibacterial activity.

Supported lysozyme for improved antimicrobial surface protection.

Surface protection against biofilms is still an open challenge. Current strategies rely on coatings that are meant to guarantee antiadhesive or antimicrobial effects. While it seems difficult to ensure antiadhesion in complex media and against all the adhesive arsenal of microbes, strategies based on antimicrobials lack from sustainable functionalization methodologies to allow the perfect efficiency of the grafted molecules. Here we used the high affinity ligand-receptor interaction between biotin and streptavidin to functionalize surfaces with lysozyme, an enzyme that degrades the bacterial peptidoglycan cell wall. Biotinylated lysozyme was grafted on surfaces coated with streptavidin receptors. Using atomic force microscopy (AFM)-based single molecule force spectroscopy, we showed that grafting through ligand-receptor interaction allows the correct orientation of the enzyme on the substrate for enhanced activity towards the microbial target. The antibacterial efficiency was tested against Micrococcus luteus and revealed that surface protection was improved when lysozyme was grafted through the ligand-receptor interaction. These results suggest that bio-molecular interactions are promising for a sustainable grafting of antimicrobial agents on surfaces.