Cedric Dicko scite author profile

Spidroins, the major silk proteins making up the spider's dragline silk, originate in two distinct tissue layers (A and B) in the spider's major ampullate gland. Formation of the complex thread from spidroins occurs in the lumen of the duct connected to the gland. Using pH-sensitive microelectrode probes, we showed that the spidroins traveling through the gland and duct experience a monotonic decrease in pH from 7.2 to 6.3. In addition, circular dichroism spectroscopy of material extracted from the gland showed a structural refolding concomitant with position in the gland and post-extraction changes in pH. We demonstrate that lowering the pH in vitro causes a dramatic conformational change in the protein from the A zone, converting it irreversibly from a coil to a predominantly beta-sheet structure. Furthermore, amino acid analyses have indicated that there are at least two distinct, though similar, proteins secreted in the A and B zones suggesting a potential factor in the progressive acidification as well as a pH sensitivity of the folding of spidroins in the gland. Thus, we provide, for the first time, a quantitative map of the pH value and position correlated with molecular structural folding in the silk gland characterizing the crucial role that pH plays in spider silk formation.

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Transition to a β-Sheet-Rich Structure in Spidroin in Vitro: The Effects of pH and Cations

Dicko

et al. 2004

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Unlike man-made fibers, the silks of spiders are spun from aqueous solutions and at atmospheric pressure in a process still poorly understood. The molecular mechanism of this process involves the conversion of a highly concentrated, predominantly disordered silk protein (spidroin) into beta-sheet-rich structures. To help store and transport the spidroins in solution, as well as probably control their conversion, a liquid crystalline arrangement is established in the storage region in the ampulla and persists into the duct. Although it has been suggested that changes in the concentration of hydrogen and metal ions play a role in the formation of the solid thread, there is no reported evidence that these ions influence the secondary structure of native spidroin in solution. Here, we demonstrate that pH values between approximately 3.5 and 4.5 induce a slow change of conformation from the disordered to the beta-sheet-rich form. We also report that Al(3+), K(+), and Na(+) ions induce similar changes in structure, while Ca(2+) and Mg(2+) stabilize the predominantly disorder state of the protein. Cs(+) and Li(+) have no apparent effect. Direct volumetric and spectrophotometric titration showed a pI of 4.22 +/- 0.33 and apparent pK values of 6.74 +/- 0.71 and 9.21 +/- 0.27, suggesting a mechanism for the effect of low pH on the protein and a rationale for the observed reduction in pH in the duct. We discuss the importance of these findings for the spinning process and the active role played by the spider to alter the kinetics of the transition.

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Complex three-dimensional self-assembly in proxies for atmospheric aerosols

et al. 2017

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Aerosols are significant to the Earth’s climate, with nearly all atmospheric aerosols containing organic compounds that often contain both hydrophilic and hydrophobic parts. However, the nature of how these compounds are arranged within an aerosol droplet remains unknown. Here we demonstrate that fatty acids in proxies for atmospheric aerosols self-assemble into highly ordered three-dimensional nanostructures that may have implications for environmentally important processes. Acoustically trapped droplets of oleic acid/sodium oleate mixtures in sodium chloride solution are analysed by simultaneous synchrotron small-angle X-ray scattering and Raman spectroscopy in a controlled gas-phase environment. We demonstrate that the droplets contained crystal-like lyotropic phases including hexagonal and cubic close-packed arrangements of spherical and cylindrical micelles, and stacks of bilayers, whose structures responded to atmospherically relevant humidity changes and chemical reactions. Further experiments show that self-assembly reduces the rate of the reaction of the fatty acid with ozone, and that lyotropic-phase formation also occurs in more complex mixtures more closely resembling compositions of atmospheric aerosols. We suggest that lyotropic-phase formation likely occurs in the atmosphere, with potential implications for radiative forcing, residence times and other aerosol characteristics.

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Secondary Structures and Conformational Changes in Flagelliform, Cylindrical, Major, and Minor Ampullate Silk Proteins. Temperature and Concentration Effects

et al. 2004

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Orb weaver spiders use exceptionally complex spinning processes to transform soluble silk proteins into solid fibers with specific functions and mechanical properties. In this study, to understand the nature of this transformation we investigated the structural changes of the soluble silk proteins from the major ampullate gland (web radial threads and spider safety line); flagelliform gland (web sticky spiral threads); minor ampullate gland (web auxiliary spiral threads); and cylindrical gland (egg sac silk). Using circular dichroism, we elucidated (i) the different structures and folds for the various silk proteins; (ii) irreversible temperature-induced transitions of the various silk structures toward beta-sheet-rich final states; and (iii) the role of protein concentration in silk storage and transport. We discuss the implication of these results in the spinning process and a possible mechanism for temperature-induced beta-sheet formation.

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Cedric Dicko

Spider Silk Protein Refolding Is Controlled by Changing pH

Transition to a β-Sheet-Rich Structure in Spidroin in Vitro: The Effects of pH and Cations

Complex three-dimensional self-assembly in proxies for atmospheric aerosols

Secondary Structures and Conformational Changes in Flagelliform, Cylindrical, Major, and Minor Ampullate Silk Proteins. Temperature and Concentration Effects

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