Abstract
An orb web’s prey capture thread features tiny glue droplets, each formed of an adhesive glycoprotein core surrounded by an aqueous layer. Small molecules in the aqueous layer confer droplet hygroscopicity and maintain glycoprotein viscoelasticity, causing droplet volume and glycoprotein performance to track changes in environmental humidity. Droplet extension combines with that of a thread’s supporting flagelliform fibers to sum the adhesive forces of multiple droplets, creating an effective adhesive system. We combined measurements of the force on an extending droplet, as gauged by the deflection of its support line, with measurements of glycoprotein volume and droplet extension to determine the Young’s modulus (E) and toughness of three species’ glycoproteins. We did this at five relative humidities between 20–90% to assess the effect of humidity on these properties. When droplets of a thread span extend, their extensions are constrained and their glycoprotein filaments remain covered by aqueous material. This was also the case during the first extension phase of the individual droplets that we examined. However, as extension progressed, the aqueous layer was progresses disrupted, exposing the glycoprotein. During the first extension phase E ranged from 0.00003 GPa, a value similar to that of fibronectin, a glycoprotein that anchors cells in the extracellular matrix, to 0.00292 GPa, a value similar to that of resilin in insect ligaments. Second phase E increased 4.7–19.4-fold. When compared at the same humidity the E of each species’ glycoprotein was less than 5% of the value reported for its flagelliform fibers. This difference may facilitate the coordinated extension of these two capture thread components that is responsible for summing the thread’s adhesive forces.
Highlights
The multiple uses that spiders make of their proteinaceous silk threads have made an important contribution to the success of this 47,055-species clade [1,2,3,4,5,6]
Droplets appear to form on a filament to minimize the surface energy of the thinning aqueous sheath because these droplets have a lower surface to volume ratio than that of a continuous cylinder of aqueous material, a phenomenon described by Plateau-Rayleigh instability [19]. We evaluated this by computing a ratio of the circumference of what would have been a continuously aqueous layer coated glycoprotein filament divided by the cross-sectional area of the aqueous layer
Flagelliform fiber toughness ranged from 211–272 MJ/m3 [12], whereas Phase 1 glycoprotein toughness ranged from 0.10–4.05 MJ/m3
Summary
The multiple uses that spiders make of their proteinaceous silk threads have made an important contribution to the success of this 47,055-species clade [1,2,3,4,5,6]. Adhesive viscous prey capture threads are laid as a spiral on the web’s radii and prevent insects from escaping the web before a spider can Elastic modulus and toughness of orb spider glycoprotein glue locate, run to, and subdue them [15, 16]. These composite threads are produced by two types of silk glands that open on adjacent spigots on a spider’s paired posterior lateral spinnerets [17]. Threads from the two spinnerets merge and Plateau Rayleigh instability quickly reconfigures the cylinder of aggregate material that surrounds the two flagelliform fibers into a series of regularly spaced droplets, a core of adhesive glycoprotein coalescing inside of each droplet Fig 1A–1C) [18,19,20]
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