Abstract
This review will introduce very recent studies using solid-state nuclear magnetic resonance (NMR) and molecular dynamics (MD) simulation on the structure and dynamics of spider dragline silks conducted by the author’s research group. Spider dragline silks possess extraordinary mechanical properties by combining high tensile strength with outstanding elongation before breaking, and therefore continue to attract attention of researchers in biology, biochemistry, biophysics, analytical chemistry, polymer technology, textile technology, and tissue engineering. However, the inherently non-crystalline structure means that X-ray diffraction and electron diffraction methods provide only limited information because it is difficult to study the molecular structure of the amorphous region. The most detailed picture of the structure and dynamics of the silks in the solid state experimentally have come from solid-state NMR measurements coupled with stable isotope labeling of the silks and the related silk peptides. In addition, combination of solid-state NMR and MD simulation was very powerful analytical tools to understand the local conformation and dynamics of the spider dragline silk in atomic resolution. In this review, the author will emphasize how solid-state NMR and MD simulation have contributed to a better understanding of the structure and dynamics in the spider dragline silks.
Highlights
There are a variety of silkworms and spiders, each producing silk with unique primary and higher order structures [1,2]
The unique properties of spider silks are essentially originated from the structure and dynamics, and the atomic resolution information on the structure gives us the answer to why the silk has such unique and excellent properties [1,7,12]
We previously reviewed about nuclear magnetic resonance (NMR) studies of silk several times [86,87,88,89,90,91] and most recently, an excellent review about NMR characterization of silk including spider silk was published by Guo and Yarger [92]
Summary
There are a variety of silkworms and spiders, each producing silk with unique primary and higher order structures [1,2]. Recent studies about the structure and dynamics of the dragline silks of two kinds of spiders, N. clavipes and Nephila clavata (N. clavata) in the dry and hydrated states using solid-state NMR
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