Some Observations on the Structure and Function of the Spinning Apparatus in the Silkworm <i>Bombyx </i><i>mori</i>

Asakura, Tetsuo; Umemura, Kosuke; Nakazawa, Yasumoto; Hirose, Haruko; Higham, James P.; Knight, David P.

doi:10.1021/bm060874z

Cited by 146 publications

(217 citation statements)

References 39 publications

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“…This was similar to the internal drawdown taper observed in the anterior narrowing of the spider and silkworm glands. 23,37 The role of the transition site in fiber formation merits further physiological and structural investigation.…”

Section: Silk Gland Structure and Fiber Formationmentioning

confidence: 99%

Silk tape nanostructure and silk gland anatomy of trichoptera

2011

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Caddisflys (order Trichoptera) construct elaborate protective shelters and food harvesting nets with underwater adhesive silk. The silk fiber resembles a nanostructured tape composed of thousands of nanofibrils (∼ 120 nm) oriented with the major axis of the fiber, which in turn are composed of spherical subunits. Weaker lateral interactions between nanofibrils allow the fiber to conform to surface topography and increase contact area. Highly phosphorylated (pSX)(4) motifs in H-fibroin blocks of positively charged basic residues are conserved across all three suborders of Trichoptera. Electrostatic interactions between the oppositely charged motifs could drive liquid-liquid phase separation of silk fiber precursors into a complex coacervates mesophase. Accessibility of phosphoserine to an anti-phosphoserine antibody is lower in the lumen of the silk gland storage region compared to the nascent fiber formed in the anterior conducting channel. The phosphorylated motifs may serve as a marker for the structural reorganization of the silk precursor mesophase into strongly refringent fibers. The structural change occurring at the transition into the conducting channel makes this region of special interest. Fiber formation from polyampholytic silk proteins in Trichoptera may suggest a new approach to create synthetic silk analogs from water-soluble precursors.

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Section: Silk Gland Structure and Fiber Formationmentioning

confidence: 99%

Silk tape nanostructure and silk gland anatomy of trichoptera

2011

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“…While the structure and function of spinning ducts in spiders 1 and silk worms 2,3 have been studied extensively, microscopic models of silk protein ͑fibroin͒ aggregation and silk fiber formation have still to be experimentally verified. 1,4,5 In-situ synchrotron radiation ͑SR͒ micro-small-angle X-ray and micro-wide-angle X-ray scattering ͑ -SAXS and -WAXS͒ experiments during forced silking of Nephila spiders 6 provide microstructural information on the nascent silk thread at the exit of the spigots.…”

Section: Introductionmentioning

confidence: 99%

A microfluidic cell for studying the formation of regenerated silk by synchrotron radiation small- and wide-angle X-ray scattering

et al. 2008

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A tube-in-square-pipe microfluidic glass cell has been developed for studying the aggregation and fiber formation from regenerated silk solution by in-situ smallangle X-ray scattering using synchrotron radiation. Acidification-induced aggregation has been observed close to the mixing point of the fibroin and buffer solution. The fibrous, amorphous material is collected in a water bath. Micro-wide-angle X-ray scattering of the dried material confirms its ␤-sheet nature.

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“…Such a material in principle could challenge the animals due to the relatively high forces needed for processing. However, liquid crystal structures have been observed in silk ducts of spider and silkworm silk glands, which disappear right before the dope enters the spinneret [38,39]. These structures reduce inter-molecular friction resulting in a lower viscosity and thereby reducing the energetic effort of spinning a fibre.…”

Section: Natural Silk Processingmentioning

confidence: 99%

Applicability of biotechnologically produced insect silks

Herold

Scheibel

2017

Zeitschrift Für Naturforschung C

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Silks are structural proteins produced by arthropods. Besides the well-known cocoon silk, which is produced by larvae of the silk moth Bombyx mori to undergo metamorphosis inside their silken shelter (and which is also used for textile production by men since millennia), numerous further less known silk-producing animals exist. The ability to produce silk evolved multiple independent times during evolution, and the fact that silk was subject to convergent evolution gave rise to an abundant natural diversity of silk proteins. Silks are used in air, under water, or like honey bee silk in the hydrophobic, waxen environment of the bee hive. The good mechanical properties of insect silk fibres together with their non-toxic, biocompatible, and biodegradable nature renders these materials appealing for both technical and biomedical applications. Although nature provides a great diversity of material properties, the variation in quality inherent in materials from natural sources together with low availability (except from silkworm silk) impeded the development of applications of silks. To overcome these two drawbacks, in recent years, recombinant silks gained more and more interest, as the biotechnological production of silk proteins allows for a scalable production at constant quality. This review summarises recent developments in recombinant silk production as well as technical procedures to process recombinant silk proteins into fibres, films, and hydrogels.

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Some Observations on the Structure and Function of the Spinning Apparatus in the Silkworm Bombyx mori

Cited by 146 publications

References 39 publications

Silk tape nanostructure and silk gland anatomy of trichoptera

Silk tape nanostructure and silk gland anatomy of trichoptera

A microfluidic cell for studying the formation of regenerated silk by synchrotron radiation small- and wide-angle X-ray scattering

Applicability of biotechnologically produced insect silks

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