Presence of a glycine-cysteine-rich beta-protein in the oberhautchen layer of snake epidermis marks the formation of the shedding layer

Review: mapping proteins localized in adhesive setae of the tokay gecko and their possible influence on the mechanism of adhesion

The digital adhesive pads that allow gecko lizards to climb vertical surfaces result from the modification of the oberhautchen layer of the epidermis in normal scales. This produces sticky filaments of 10-100 μm in length, called setae that are composed of various proteins. The prevalent types, termed corneous beta proteins (CBPs), have a low molecular weight (12-20 kDa) and contain a conserved central region of 34 amino acids with a beta-conformation. This determines their polymerization into long beta-filaments that aggregate into corneous beta-bundles that form the framework of setae. Previous studies showed that the prevalent CBPs in the setae of Gekko gecko are cysteine-rich and are distributed from the base to the tip of adhesive setae, called spatulae. The molecular analysis of these proteins, although the three-dimensional structure remains undetermined, indicates that most of them are charged positively and some contain aromatic amino acids. These characteristics may impede adhesion by causing the setae to stick together but may also potentiate the van der Waals interactions responsible for most of the adhesion process on hydrophobic or hydrophilic substrates. The review stresses that not only the nanostructural shape and the high number of setae present in adhesive pads but also the protein composition of setae influence the strength of adhesion to almost any type of substrate. Therefore, formulation of dry materials mimicking gecko adhesiveness should also consider the chemical nature of the polymers utilized to fabricate the future dry adhesives in order to obtain the highest performance.

Evidence of a molecular boundary lubricant at snakeskin surfaces

During slithering locomotion the ventral scales at a snake's belly are in direct mechanical interaction with the environment, while the dorsal scales provide optical camouflage and thermoregulation. Recent work has demonstrated that compared to dorsal scales, ventral scales provide improved lubrication and wear protection. While biomechanic adaption of snake motion is of growing interest in the fields of material science and robotics, the mechanism for how ventral scales influence the friction between the snake and substrate, at the molecular level, is unknown. In this study, we characterize the outermost surface of snake scales using sum frequency generation (SFG) spectra and near-edge X-ray absorption fine structure (NEXAFS) images collected from recently shed California kingsnake (Lampropeltis californiae) epidermis. SFG's nonlinear optical selection rules provide information about the outermost surface of materials; NEXAFS takes advantage of the shallow escape depth of the electrons to probe the molecular structure of surfaces. Our analysis of the data revealed the existence of a previously unknown lipid coating on both the ventral and dorsal scales. Additionally, the molecular structure of this lipid coating closely aligns to the biological function: lipids on ventral scales form a highly ordered layer which provides both lubrication and wear protection at the snake's ventral surface.