Structure and post-translational modifications of the web silk protein spidroin-1 from Nephila spiders

Santos-Pinto, José Roberto Aparecido dos; Lamprecht, Günther; Chen, Wei-Qiang; Heo, Seok; Hardy, John G.; Priewalder, Helga; Scheibel, Thomas; Palma, Mário Sérgio; Lubec, Gert

doi:10.1016/j.jprot.2014.01.002

Cited by 41 publications

(47 citation statements)

References 48 publications

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“…Already, today, recombinant DNA technology, in combination with Escherichia coli expression systems, has revolutionized silk research and is opening up new commercial avenues ( Table 5 ). However, silk presents a number of specific challenges; for example, the silk molecules cannot be post‐translationally modified, but this is required to faithfully mimic the silk protein . The expression of native‐sized silk proteins is also not possible using standard E. coli expression systems because of the highly repetitive nature of the gene constructs, the very high glycine content of the protein, and the high molecular weight of the product (250–320 kDa).…”

Section: (Old) New Silk Industries: Opportunities and Challenges For mentioning

confidence: 99%

The Biomedical Use of Silk: Past, Present, Future

Holland

Numata

Rnjak‐Kovacina

et al. 2018

Adv Healthcare Materials

555

509

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Humans have long appreciated silk for its lustrous appeal and remarkable physical properties, yet as the mysteries of silk are unraveled, it becomes clear that this outstanding biopolymer is more than a high‐tech fiber. This progress report provides a critical but detailed insight into the biomedical use of silk. This journey begins with a historical perspective of silk and its uses, including the long‐standing desire to reverse engineer silk. Selected silk structure–function relationships are then examined to appreciate past and current silk challenges. From this, biocompatibility and biodegradation are reviewed with a specific focus of silk performance in humans. The current clinical uses of silk (e.g., sutures, surgical meshes, and fabrics) are discussed, as well as clinical trials (e.g., wound healing, tissue engineering) and emerging biomedical applications of silk across selected formats, such as silk solution, films, scaffolds, electrospun materials, hydrogels, and particles. The journey finishes with a look at the roadmap of next‐generation recombinant silks, especially the development pipeline of this new industry for clinical use.

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Section: (Old) New Silk Industries: Opportunities and Challenges For mentioning

confidence: 99%

The Biomedical Use of Silk: Past, Present, Future

Holland

Numata

Rnjak‐Kovacina

et al. 2018

Adv Healthcare Materials

555

509

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“…MaSp1 and MaSp2 isolated from N. clavipes dragline silk fibers contain phosphorylation sites in their respective repetitive regions [58,59], as does FibRep [38], the fibroin light chain and the P25 [60]. The impact of these phosphorylations on the silk formation process have not been thoroughly studied, but phosphorylation in general affect soluble proteins by altering conformational states.…”

Section: Are There Post-translational Modifications Of Silk Proteins?mentioning

confidence: 99%

Silk Spinning in Silkworms and Spiders

Andersson

Johansson

Rising

2016

IJMS

126

141

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Spiders and silkworms spin silks that outcompete the toughness of all natural and manmade fibers. Herein, we compare and contrast the spinning of silk in silkworms and spiders, with the aim of identifying features that are important for fiber formation. Although spiders and silkworms are very distantly related, some features of spinning silk seem to be universal. Both spiders and silkworms produce large silk proteins that are highly repetitive and extremely soluble at high pH, likely due to the globular terminal domains that flank an intermediate repetitive region. The silk proteins are produced and stored at a very high concentration in glands, and then transported along a narrowing tube in which they change conformation in response primarily to a pH gradient generated by carbonic anhydrase and proton pumps, as well as to ions and shear forces. The silk proteins thereby convert from random coil and alpha helical soluble conformations to beta sheet fibers. We suggest that factors that need to be optimized for successful production of artificial silk proteins capable of forming tough fibers include protein solubility, pH sensitivity, and preservation of natively folded proteins throughout the purification and initial spinning processes.

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“…Expression has been reported using the natural cDNAs as well as codon-optimized synthetic genes (Prince et al, 1995;Xia et al, 2010;Xu et al, 2007). Although endogenous spidroins expressed in MA glands have been shown to experience post-translational modifications (PTMs), including phosphorylation and hydroxylation, it is unclear whether these PTMs to spidroins are necessary for production of high-quality synthetic silk fibers (Dos Santos-Pinto et al, 2014). Using a bioreactor to optimize growth conditions, metabolically engineered bacterial strains have been generated to cope with intrinsically large numbers of Ala and Gly codons within the natural cDNAs, a strategy that has been effectively utilized to express some of the largest spidroin constructs (Xia et al, 2010).…”

Section: Production Of Recombinant Silk Proteinsmentioning

confidence: 99%