Efficient Biosynthetic Fabrication of Spidroins with High Spinning Performance

Overview

Journal Adv Sci (Weinh)

Specialty Biomedical Engineering

Date 2024 Mar 23

PMID 38520721

Authors

Baoyang Lin

Jingjun Xie

Bingbing Gao

Bingfang He

Affiliations

Soon will be listed here.

Abstract

The unique 3D structure of spider silk protein (spidroin) determines the excellent mechanical properties of spidroin fiber, but the difficulty of heterologous expression and poor spinning performance of recombinant spider silk protein limit its application. A high-yield low-molecular-weight biomimetic spidroin (Amy-6rep) is obtained by sequence modification, and its excellent spinning performance is verified by electrospinning it for use as a nanogenerator. Amy-6rep increases the highly fibrogenic microcrystalline region in the core repeat region of natural spidroin with limited sequence length and replaces the polyalanine sequence with an amyloid polypeptide through structural similarity. Due to sequence modification, the expression of Amy-6rep increased by ≈200%, and the self-assembly performance of Amy-6rep significantly increased. After electrospinning with Amy-6rep, the nanofibers exhibit good tribopower generation capacity. In this paper, a biomimetic spidroin sequence design with high yield and good spinning performance is reported, and a strategy for electrospinning to produce an artificial nanogenerator is explored.

Citing Articles

Silk Protein Gene Engineering and Its Applications: Recent Advances in Biomedicine Driven by Molecular Biotechnology.

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PMID: 39881670 PMC: 11776523. DOI: 10.2147/DDDT.S504783.

Artificial Spidroin Nanogenerator-Based Articulus Wound Dressing.

Ma X, Li S, Gao B ChemistryOpen. 2024; 14(2):e202400257.

PMID: 39473315 PMC: 11808259. DOI: 10.1002/open.202400257.

Efficient Biosynthetic Fabrication of Spidroins with High Spinning Performance.

Lin B, Xie J, Gao B, He B Adv Sci (Weinh). 2024; 11(22):e2400128.

PMID: 38520721 PMC: 11165546. DOI: 10.1002/advs.202400128.

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