Recombinant spider silk coatings functionalized with enzymes targeting bacteria and biofilms

Seijsing, Fredrik; Nilebäck, Linnea; Öhman, Oskar; Pasupuleti, Rajeev; Ståhl, Camilla; Seijsing, Johan; Hedhammar, My

doi:10.1002/mbo3.993

Cited by 16 publications

(21 citation statements)

References 17 publications

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“…Silicone implants coated with a recombinant spider silk protein were shown by Zeplin and co-workers to prompt a reduced inflammatory response in a preclinical study in rats, suggesting that coating medical implants in silk may enhance their biocompatibility [73]. More recently, recombinant spider silks functionalised with peptidoglycan degrading enzymes were reported to exhibit a bacteriolytic effect and prevent biofilm formation, further highlighting the materials potential as a coating for surgical implants [74]. Recombinant silk is also an effective biomaterial for use in drug delivery.…”

Section: Trends In Biotechnologymentioning

confidence: 99%

Host Systems for the Production of Recombinant Spider Silk

Whittall

Baker

Breitling

et al. 2021

Trends in Biotechnology

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Spider silk is renowned for its impressive mechanical properties. It is one of the strongest known biomaterials, possessing mechanical properties that outmatch both steel and Kevlar. However, the farming of spiders for their silk is unfeasible. Consequently, production of recombinant spider silk proteins (spidroins) in more amenable hosts is an exciting field of research. For large-scale production to be viable, a heterologous silk production system that is both highly efficient and cost effective is essential. Genes encoding recombinant spidroin have been expressed in bacterial, yeast, insect, and mammalian cells, in addition to many other platforms. This review discusses the recent advances in exploiting an increasingly diverse range of host platforms in the heterologous production of recombinant spidroins. Highlights Recombinant spidroins of comparable size and mechanical function to native silk proteins have been successfully produced by engineered E. coli. Recombinant spidroins have been expressed in transgenic plants, rice, and alfalfa. These expression platforms can potentially offer increased industrialscale economic viability over alternative host systems.

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Section: Trends In Biotechnologymentioning

confidence: 99%

Host Systems for the Production of Recombinant Spider Silk

Whittall

Baker

Breitling

et al. 2021

Trends in Biotechnology

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“…Manufacturing antimicrobial surfaces coated with endolysins and matrix-degrading enzymes is possible to obtain new materials, for example, bioengineered spider silk intended for drug-free sutures for reducing post-implantation infections [64]. All this evidence has led to propose phage lysins as novel antimicrobials to be used in the clinic, and as disinfectants for application in various branches of the economy such as the food industry [65].…”

Section: Phage Derived Enzymes Endolysins and Virion-associated Peptidoglycan Hydrolasesmentioning

confidence: 99%

Targeting biofilms using phages and their enzymes

Azeredo

Garcı́a

Drulis-Kawa

2021

Current Opinion in Biotechnology

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The complex biofilm architecture composed of extracellular polymeric structures (EPS) provides a protective shield to physiologically diverse bacterial cells immersed in its structure. The evolutionary interplay between bacteria and their viruses (phages) forced the latter ones to develop specific strategies to overcome the biofilm defensive barriers and kill sessile cells. Phages are equipped with a wide panel of enzyme-degrading EPS macromolecules which together are powerful weapons to combat biofilms. Antibiofilm performance can be achieved by combining phages or phage-borne enzymes with other antimicrobials such as antibiotics. Nevertheless, a variety of enzymes encoded in phage genomes still need to be explored. To advance in biofilm control strategies we must deepen the understanding of the biofilm biology itself, as well as discover and better exploit the unlimited antibacterial potential of phages.

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“…This drug-free silk suture shows excellent antibacteria adhesion toward Gram-positive Staphylococcus aureus ( S. aureus ) and Gram-negative Escherichia coli ( E. coli ). Moreover, the recombinant spider silk protein could also be functionalized with the peptidoglycan degrading endolysin SAL-1 and the biofilm-matrix-degrading enzyme Dispersin B (DspB) to realize the bactericidal properties and inhibit biofilm formation, simultaneously In addition to the abilities to promote cell adhesion and differentiation, spider-silk-inspired adhesive materials were also used to achieve anticell or antimicroorganism adhesion. …”

Section: Antiadhesion Applications Of the Spider-silk-inspired Adhesi...mentioning

confidence: 99%