Add to ORKGConversion of spider silk proteins from soluble dope to insoluble fibers involves pH-dependent dimerization of the N-terminal domain (NT). This conversion is tightly regulated to prevent premature precipitation and enable rapid silk formation at the end of the duct. Three glutamic acid residues that mediate this process in the NT from Euprosthenops australis major ampullate spidroin 1 are well conserved among spidroins. However, NTs of minor ampullate spidroins from several species, including Araneus ventricosus (AvMiSp NT), lack one of the glutamic acids. Here we investigate the pH-dependent structural changes of AvMiSp NT, revealing that it uses the same mechanism but involves a non-conserved glutamic acid residue instead. Homology modeli...
The exceptional strength and extensibility of spider dragline silk have been thought to be facilitat...
Spider major ampullate (MA) silk, with its combination of strength and extensibility, outperforms an...
Spiders produce multiple silks with different physical properties that allow them to occupy a divers...
The N-terminal (NT) domain of spider silk proteins (spi-droins) is crucial for their storage at high...
The mechanisms controlling the conversion of spider silk proteins into insoluble fibres, which happe...
Formation of spider silk from its constituent proteins-spidroins-involves changes from soluble helic...
The spidroin N-terminal domain (NT) is responsible for high solubility and pH-dependent assembly of ...
When the major ampullate spidroins (MaSp1) are called upon to form spider dragline silk, one of natu...
Spider silks are protein-based fibers with remarkable mechanical qualities. Perhaps even more impre...
Web spiders connect silk proteins, so-called spidroins, into fibers of extraordinary toughness. The ...
Web spiders synthesize silk fibres, nature’s toughest biomaterial, through the controlled assembly o...
A huge variety of proteins are able to form fibrillar structures, especially at high protein concent...
The well-tuned spinning technology from spiders has attracted many researchers with the promise of p...
The exceptional strength and extensibility of spider dragline silk have been thought to be facilitat...
The exceptional strength and extensibility of spider dragline silk have been thought to be facilitat...
Spider major ampullate (MA) silk, with its combination of strength and extensibility, outperforms an...
Spiders produce multiple silks with different physical properties that allow them to occupy a divers...
The N-terminal (NT) domain of spider silk proteins (spi-droins) is crucial for their storage at high...
The mechanisms controlling the conversion of spider silk proteins into insoluble fibres, which happe...
Formation of spider silk from its constituent proteins-spidroins-involves changes from soluble helic...
The spidroin N-terminal domain (NT) is responsible for high solubility and pH-dependent assembly of ...
When the major ampullate spidroins (MaSp1) are called upon to form spider dragline silk, one of natu...
Spider silks are protein-based fibers with remarkable mechanical qualities. Perhaps even more impre...
Web spiders connect silk proteins, so-called spidroins, into fibers of extraordinary toughness. The ...
Web spiders synthesize silk fibres, nature’s toughest biomaterial, through the controlled assembly o...
A huge variety of proteins are able to form fibrillar structures, especially at high protein concent...
The well-tuned spinning technology from spiders has attracted many researchers with the promise of p...
The exceptional strength and extensibility of spider dragline silk have been thought to be facilitat...
The exceptional strength and extensibility of spider dragline silk have been thought to be facilitat...
Spider major ampullate (MA) silk, with its combination of strength and extensibility, outperforms an...
Spiders produce multiple silks with different physical properties that allow them to occupy a divers...