High-level expression of orange fluorescent protein in the silkworm larvae by the Bac-to-Bac system

Antioxidant High-Fluorescent Silkworm Silk Development Based on Quercetin-Induced Luminescence

The fluorescent silk produced by feeding silkworms with traditional fluorescent dyes is limited in functionality and suffers from fluorescence quenching, rendering it unsuitable for long-term stable performance as a medical implant material in the human body. This work introduces an innovative strategy to develop a novel multifunctional fluorescent silk composite by incorporating quercetin (QR), a naturally occurring molecule with aggregation-induced emission (AIE) characteristics, into the diet of silkworms. Silk derived from QR-fed silkworms presents significant enhancements in fluorescence, antioxidant, and mechanical properties, with the QR-2.5% group presenting the best overall performance. The resulting silk exhibits superstrong blue fluorescence when exposed to 405 nm laser light, with a breaking strength of 4.26 ± 0.42 cN/D and a breaking energy of 5.96 ± 1.32 cN/cm, improvements of 15.76% and 18.25%, respectively, in comparison with regular silk. Fourier transform infrared spectroscopy (FTIR) analysis indicates that QR induces a structural transformation of fibroin protein from α-helix and random coil to β-sheet configuration, thereby increasing silk crystallinity. Additionally, compared with regular silk, the antioxidant properties of both sericin and silk fibroin increased by 88.66% and 17.25%, respectively. At the same time, this multifunctional silk has excellent biocompatibility and strong cell adhesion. The high-strength, uniformly luminescent silk developed in this study has outstanding antioxidant and mechanical properties. It effectively avoids the fluorescence quenching issue common in traditional fluorescent silk materials and introduces new functionalities. This advancement is significant for increasing the utility of functionally modified silk.

Thermochromic Silks for Temperature Management and Dynamic Textile Displays

HIGHLIGHTS

Wearable and smart textiles are constructed by integrating embroidery technology and 5G cloud communication, showing promising applications in temperature management and real-time dynamic textile displays. Thermochromism is introduced into the natural silk to produce high-performance thermochromic silks (TCSs) through a low cost, sustainable, efficient, and scalable strategy. The interfacial bonding of the continuously produced TCSs is in situ analyzed and improved through pre-solvent treatment and is confirmed using synchrotron Fourier transform infrared microspectroscopy.

ABSTRACT

Silks have various advantages compared with synthetic polymer fibers, such as sustainability, mechanical properties, luster, as well as air and humidity permeability. However, the functionalization of silks has not yet been fully developed. Functionalization techniques that retain or even improve the sustainability of silk production are required. To this end, a low-cost, effective, and scalable strategy to produce TCSs by integrating yarn-spinning and continuous dip coating technique is developed herein. TCSs with extremely long length (> 10 km), high mechanical performance (strength of 443.1 MPa, toughness of 56.0 MJ m⁻³, comparable with natural cocoon silk), and good interfacial bonding were developed. TCSs can be automatically woven into arbitrary fabrics, which feature super-hydrophobicity as well as rapid and programmable thermochromic responses with good cyclic performance: the response speed reached to one second and remained stable after hundreds of tests. Finally, applications of TCS fabrics in temperature management and dynamic textile displays are demonstrated, confirming their application potential in smart textiles, wearable devices, flexible displays, and human–machine interfaces. Moreover, combination of the fabrication and the demonstrated applications is expected to bridge the gap between lab research and industry and accelerate the commercialization of TCSs. [Image: see text]

SUPPLEMENTARY INFORMATION

The online version contains supplementary material available at 10.1007/s40820-021-00591-w.

Functional silk: colored and luminescent

Silkworm silk is among the most widely used natural fibers for textile and biomedical applications due to its extraordinary mechanical properties and superior biocompatibility. A number of physical and chemical processes have also been developed to reconstruct silk into various forms or to artificially produce silk-like materials. In addition to the direct use and the delicate replication of silk's natural structure and properties, there is a growing interest to introduce more new functionalities into silk while maintaining its advantageous intrinsic properties. In this review we assess various methods and their merits to produce functional silk, specifically those with color and luminescence, through post-processing steps as well as biological approaches. There is a highlight on intrinsically colored and luminescent silk produced directly from silkworms for a wide range of applications, and a discussion on the suitable molecular properties for being incorporated effectively into silk while it is being produced in the silk gland. With these understanding, a new generation of silk containing various functional materials (e.g., drugs, antibiotics and stimuli-sensitive dyes) would be produced for novel applications such as cancer therapy with controlled release feature, wound dressing with monitoring/sensing feature, tissue engineering scaffolds with antibacterial, anticoagulant or anti-inflammatory feature, and many others.

Expression of UreB and HspA of Helicobacter pylori in silkworm pupae and identification of its immunogenicity

For mass production of urease B subunit (UreB) and heat shock protein A subunit (HspA) of Helicobacter pylori with Bombyx mori nuclear polyhedrosis virus (BmNPV) baculovirus expression system (BES) and to determine whether they could be used as an oral vaccine against H. pylori, besides, to determine the time course of expressed recombinant protein and the optimum acquisition time directly through green fluorescence, HspA and enhanced green fluorescence protein (EGFP) genes were cloned into vector pFastBacDual to form donor vector pFastBacDual-(EGFP) (HspA), UreB gene was cloned into vector pFastBacDual to form donor vector pFastBacDual-UreB,then they were transformed into E. coli BmDH10Bac to obtain the recombinant Bacmid-(EGFP) (HspA) and Bacmid-UreB respectively. They were used to transfect BmN cells and generated the recombinant baculovirus BmNPV-(EGFP) (HspA) and BmNPV-UreB. Using these recombinant baculovirus BmNPV-(EGFP) (HspA) and BmNPV-UreB inoculated the silkworm pupae, a recombinant HspA and UreB protein were expressed in silkworm pupae, which were around 13 and 62 kDa in sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) and western blot analysis. After oral immunization of mice, serum specific IgG antibodies against HspA and UreB in vaccine group were much higher than that in mock and native silkworm powder control groups. The results indicated that the expressed recombinant HspA and UreB in silkworm pupae would possess good immunogenicity. In addition, when EGFP and HspA proteins were expressed, a direct correlation between the increase in intensity of fluorescence and HspA concentration.

Demonstration of protein absorption in the intestinal epithelium of fish and mice by laser scanning confocal microscopy

Selective permeability for small proteins and oligopeptides occurs in the intestinal epithelium of many animal species and humans. Whole proteins are sometimes endocytosed and undergo partial hydrolysis in intestinal epithelial cells with the probable release of essential oligopeptides into the bloodstream. Increased permeability to certain proteins can cause asthma and other metabolic disorders. Permeable proteins have also been successfully used to deliver vaccines or drugs via oral consumption. Protein absorption has been inferred in many cases and demonstrated in some cases by histochemical, tracer, and analytical techniques. However, the nature and importance of protein absorption remains largely unknown. Here, we demonstrate the movement of two lumenal proteins (GFP: 26 kDa and OFP: 23 kDa) across the intestinal epithelium of fish and mice using laser scanning confocal microscopy. The results provide evidence that small proteins can be taken up intact by intestinal epithelial cells, even though large proteins are digested to single amino acids or protein fragments before they are absorbed. Our results suggest that it is possible to orally administer some small proteinous medicines for therapeutic purposes.

Characterization of a late gene, ORF75 from Bombyx mori nucleopolyhedrovirus

Open reading frame 75 (Bm-p33) of Bombyx mori nucleopolyhedrovirus (BmNPV) is a homologue of Autographa californica multiple nucleopolyhedrovirus ORF92. The gene is conserved among all baculoviruses that have been completely sequenced to date and is considered to be a baculovirus core set gene. No amino acid mutation was found in Bm-p33 sequences among six BmNPV strains differing in geography, phenotype, or host. The Bm-p33 transcript can be detected as early as 12 h post infection (h p.i.) and remains detectable until 96 h p.i. The Bm-p33 protein was detected in cell lysates from 18 h p.i. through 96 h p.i., and no positive band could be detected in budded viruses (BVs) and occlusion-derived viruses (ODVs) by western blot using anti-Bm-p33 serum. Immunofluorescence microscopy indicated that Bm-p33 accumulated in the nuclear membrane and the intranuclear region, especially near the nuclear membrane of the virus-infected cells. Bm75 RNAi significantly decreased the mRNA level. However, no obvious effects on ODV formation and BV production in BmNPV-infected cells could be detected. Bm-p33 is a BmNPV late gene encoding a nonstructural protein which may function mainly in the nucleus of the infected cells.