Nuclear pore complexes (NPCs) gate the only conduits for nucleocytoplasmic transport in eukaryotes. Their gate is formed by nucleoporins containing large intrinsically disordered domains with multiple phenylalanine-glycine repeats (FG domains). In combination, these are hypothesized to form a structurally and chemically homogeneous network of random coils at the NPC center, which sorts macromolecules by size and hydrophobicity. Instead, we found that FG domains are structurally and chemically heterogeneous. They adopt distinct categories of intrinsically disordered structures in non-random distributions. Some adopt globular, collapsed coil configurations and are characterized by a low charge content. Others are highly charged and adopt more dynamic, extended coil conformations. Interestingly, several FG nucleoporins feature both types of structures in a bimodal distribution along their polypeptide chain. This distribution functionally correlates with the attractive or repulsive character of their interactions with collapsed coil FG domains displaying cohesion toward one another and extended coil FG domains displaying repulsion. Topologically, these bipartite FG domains may resemble sticky molten globules connected to the tip of relaxed or extended coils. Within the NPC, the crowding of FG nucleoporins and the segregation of their disordered structures based on their topology, dimensions, and cohesive character could force the FG domains to form a tubular gate structure or transporter at the NPC center featuring two
Spiders produce high performance fibers with diverse mechanical properties and biological functions. Molecular and biochemical studies of spider egg case silk have revealed that the main constituent of the large diameter fiber contains the fibroin TuSp1. Here we demonstrate by SDS-PAGE and protein silver staining the presence of a distinct ϳ300-kDa polypeptide that is found in solubilized egg case sacs. Combining matrix-assisted laser desorption ionization tandem time-of-flight mass spectrometry and reverse genetics, we have isolated a novel gene called AcSp1-like and demonstrate that its protein product is assembled into the small diameter fibers of egg case sacs and wrapping silks from the black widow spider, Latrodectus hesperus. BLAST searches of the NCBInr protein data base using the amino acid sequence of AcSp1-like revealed similarity to AcSp1, an inferred protein proposed to be a component of wrapping silk. However, the AcSp1-like protein was found to display more nonuniformity in its internal iterated repeat modules than the putative AcSp1 fibroin. Real time quantitative PCR analysis demonstrates that the AcSp1-like gene displays an aciniform glandrestricted pattern of expression. The amino acid composition of the fibroins extracted from the luminal contents of the aciniform glands was remarkably similar to the predicted amino acid composition of the AcSp1-like protein, which supports the assertion that AcSp1-like protein represents the major constituent stored within the aciniform gland. Collectively, our findings provide the first direct molecular evidence for the involvement of the aciniform gland in the production of a common fibroin that is assembled into the small diameter threads of egg case and wrapping silk of cob weavers.The ability to spin multiple task-specific silks is a defining feature of the diverse order Araneae (Ͼ37,000 described species). Araneoid spiders use specialized abdominal glands to manufacture up to seven different protein-based silks/glues that have diverse mechanical properties (1). Spinning high performance fibers with different mechanical properties enable spiders to perform a wide range of functions, including prey capture, locomotion, and protection of developing offspring (2).Amino acid sequences of spider fibroins (spidroins) share a number of distinctive features. Repeats of four fundamental amino acid motifs characterize the majority of sequenced spider silks as follows: (i) alternating glycine and alanine ((GA) n ), (ii) polyalanine (A n ), (iii) GGX (X ϭ subset of residues), and (iv) GPGGX. Biochemical studies indicate that these motifs correspond to distinct structural modules, e.g. A n and (GA) n repeats form crystalline -sheets, whereas -spirals are generated from a series of concatenated -turns from the repeat structure GPGGX (3). It has been proposed that these different structural modules contribute to the mechanics of the fibers. Combinations of these motifs form larger repetitive units termed ensemble repeats, which are organized in tandem copies throug...
Spiders spin high performance fibers with diverse biological functions and mechanical properties. Molecular and biochemical studies of spider prey wrapping silks have revealed the presence of the aciniform silk fibroin AcSp1-like. In our studies we demonstrate the presence of a second distinct polypeptide present within prey wrapping silk. Combining matrix-assisted laser desorption ionization tandem time-of-flight mass spectrometry and reverse genetics, we have isolated a novel gene called MiSp1-like and demonstrate that its protein product is a constituent of prey wrap silks from the black widow spider, Latrodectus hesperus. BLAST searches of the NCBInr protein database using the amino acid sequence of MiSp1-like revealed similarity to the conserved C-terminal domain of silk family members. In particular, MiSp1-like showed the highest degree of sequence similarity to the nonrepetitive C-termini of published orb-weaver minor ampullate fibroin molecules. Analysis of the internal amino acid sequence of the black widow MiSp1-like revealed polyalanine stretches interrupted by glycine residues and glycine-alanine couplets within MiSp1-like as well as repeats of the heptameric sequence AGGYGQG. Real-time quantitative PCR analysis demonstrates that the MiSp1-like gene displays a minor ampullate gland-restricted pattern of expression. Furthermore, amino acid composition analysis, coupled with scanning electron microscopy of raw wrapping silk, supports the assertion that minor ampullate silks are important constituents of black widow spider prey wrap silk. Collectively, our findings provide direct molecular evidence for the involvement of minor ampullate fibroins in swathing silks and suggest composite materials play an important role in the wrap attack process for cob-weavers.
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