丝素蛋白材料在皮肤创伤愈合中的研究进展

摘要：丝素蛋白是一种天然的高分子纤维蛋白,其结构的特殊性决定了较好的机械性能,再因其优良的生物相容性、降解产物无毒等特点,被广泛用于各种材料的研究。通过各种化学修饰和负载生长因子等,使丝素蛋白在体内外具有促进成纤维细胞增殖分化的作用,拥有诱导创面愈合的功能,同时其可部分降解,具有缓释性能好,柔韧性强,透气以及透水等较好的理化性质不但在皮肤组织工程学中的广泛的应用,并且在敷料领域的研究也显示了其治疗烧烫伤、创伤达到抑制疤痕、促进伤口快速愈合的治疗效果。总之,通过改良丝素蛋白材料的加工方法,通过化学修饰、其他物质复合等手段得到适合于皮肤修复的具有优良性能的各种材料,是具有很大潜力的极具临床价值的皮肤修复材料。本文旨在综述国内及国外学者的各种关于丝素蛋白生物材料治疗皮肤损伤的研究最新进展。     

Natural silk fibroin as a support for enzyme immobilization

Silk fibroin derived from Bombyx mori cocoon is being developed and utilized for purposes besides traditional textile material. Fibroin can be easily made up into various forms, several of which can serve as enzyme-immobilized supports. There are numerous reports on immobilized enzymes using these forms of silk fibroin as supports in which the enzyme-immobilized fibroin membranes were characterized in detail by means of spectrophotometry, infrared spectra, NMR, ESR. Enzyme-immobilized fibroin membranes have been successfully used in several biosensors for the determinations of glucose, hydrogen peroxide and uric acid in which glucose and urate biosensors in a flow injection system were able rapidly to analyze various biosamples including human whole blood or serum.     

Spider silk fibroin enhances insulin secretion and reduces blood glucose levels in diabetic mice

Fibroin silk proteins make up the cocoons of silkworms and spider webs and are rich in glycine and alanine residues. Recent studies have shown that silk fibroin hydrolysate from silkworms improves blood glucose and lipid metabolism. In the present study, we investigated the anti-diabetic effects of spider silk fibroin protein in type 2 diabetic mice. Recombinant AvMaSp-R, which consists of the 240 amino acid repetitive domain of major ampullate silk protein (AvMaSp) from the spider Araneus ventricosus, was produced in baculovirus-infected insect cells. We tested the effects of oral AvMaSp-R administration on serum insulin and blood glucose levels in diabetic mice and found that AvMaSp-R increases serum insulin levels and reduces blood glucose levels in diabetic mice. Consequently, our results are the first to provide evidence that silk fibroin protein from spiders enhances insulin secretion, which leads to reduced blood glucose levels in type 2 diabetic mice.     

Fabrication and characterization of biomaterial film from gland silk of muga and eri silkworms

This study discusses the possibilities of liquid silk (Silk gland silk) of Muga and Eri silk, the indigenous non mulberry silkworms of North Eastern region of India, as potential biomaterials. Silk protein fibroin of Bombyx mori, commonly known as mulberry silkworm, has been extensively studied as a versatile biomaterial. As properties of different silk‐based biomaterials vary significantly, it is important to characterize the non mulberry silkworms also in this aspect. Fibroin was extracted from the posterior silk gland of full grown fifth instars larvae, and 2D film was fabricated using standard methods. The films were characterized using SEM, Dynamic contact angle test, FTIR, XRD, DSC, and TGA and compared with respective silk fibers. SEM images of films reveal presence of some globules and filamentous structure. Films of both the silkworms were found to be amorphous with random coil conformation, hydrophobic in nature, and resistant to organic solvents. Non mulberry silk films had higher thermal resistance than mulberry silk. Fibers were thermally more stable than the films. This study provides insight into the new arena of research in application of liquid silk of non mulberry silkworms as biomaterials. © 2012 Wiley Periodicals, Inc. Biopolymers 99: 292–333, 2013.     

Conformational transitions in model silk peptides

Protein structural transitions and beta-sheet formation are a common problem both in vivo and in vitro and are of critical relevance in disparate areas such as protein processing and beta-amyloid and prion behavior. Silks provide a "databank" of well-characterized polymorphic sequences, acting as a window onto structural transitions. Peptides with conformationally polymorphic silk-like sequences, expected to exhibit an intractable beta-sheet form, were characterized using Fourier transform infrared spectroscopy, circular dichroism, and electron diffraction. Polymorphs resembling the silk I, silk II (beta-sheet), and silk III (threefold polyglycine II-like helix) crystal structures were identified for the peptide fibroin C (GAGAGS repetitive sequence). Two peptides based on silk amorphous sequences, fibroin A (GAGAGY) and fibroin V (GDVGGAGATGGS), crystallized as silk I under most conditions. Methanol treatment of fibroin A resulted in a gradual transition from silk I to silk II, with an intermediate state involving a high proportion of beta-turns. Attenuated total reflectance Fourier transform infrared spectroscopy has been used to observe conformational changes as the peptides adsorb from solution onto a hydrophobic surface. Fibroin C has a beta-strand structure in solution but adopts a silk I-like structure upon adsorption, which when dried on the ZnSe crystal contains silk III crystallites.     

Sugar Nucleotides from the Fungus Aureobasidium

Peptides showing inhibitory activity against the angiotensin I-converting enzyme (ACE) were investigated from the fibroin fraction of discarded silk fabric. Fibroin, which was hydrolyzed with alcalase after partial hydrolysis with hot aqueous 40% CaCl₂, released two major active peptides showing ACE-inhibitory activity. The two peptides were identified as glycyl-valyl-glycyl-tyrosine (GVGY) and glycyl-valyl-glycyl-alanyl-glycyl-tyrosine (GVGAGY) by analyses with a protein sequencer and LC/MS/MS. GVGY, whose ACE-inhibitory activity has not previously been reported, showed a blood pressure-depressing effect on spontaneously hypertensive rat (SHR).     

RGD-functionalized bioengineered spider dragline silk biomaterial

Spider silk fibers have remarkable mechanical properties that suggest the component proteins could be useful biopolymers for fabricating biomaterial scaffolds for tissue formation. Two bioengineered protein variants from the consensus sequence of the major component of dragline silk from Nephila clavipes were cloned and expressed to include RGD cell-binding domains. The engineered silks were characterized by CD and FTIR and showed structural transitions from random coil to insoluble beta-sheet upon treatment with methanol. The recombinant proteins were processed into films and fibers and successfully used as biomaterial matrixes to culture human bone marrow stromal cells induced to differentiate into bone-like tissue upon addition of osteogenic stimulants. The recombinant spider silk and the recombinant spider silk with RGD encoded into the protein both supported enhanced the differentiation of human bone marrow derived mesenchymal stem cells (hMSCs) to osteogenic outcomes when compared to tissue culture plastic. The recombinant spider silk protein without the RGD displayed enhanced bone related outcomes, measured by calcium deposition, when compared to the same protein with RGD. Based on comparisons to our prior studies with silkworm silks and RGD modifications, the current results illustrate the potential to bioengineer spider silk proteins into new biomaterial matrixes, while also highlighting the importance of subtle differences in silk sources and modes of presentation of RGD to cells in terms of tissue-specific outcomes.     

New silk protein: modification of silk protein by gene engineering for production of biomaterials

The interest in silk fibroin morphology and structure have increased due to its attractiveness for bio-related applications. Silk fibers have been used as sutures for a long time in the surgical field, due to the biocompatibility of silk fibroin fibers with human living tissue. In addition, it has been demonstrated that silk can be used as a substrate for enzyme immobilization in biosensors. A more complete understanding of silk structure would provide the possibility to further exploit silk fibroin for a wide range of new uses, such as the production of oxygen-permeable membranes and biocompatible materials. Silk fibroin-based membranes could be utilized as soft tissue compatible polymers. Baculovirus-mediated transgenesis of the silkworm allows specific alterations in a target sequence. Homologous recombination of a foreign gene downstream from a powerful promoter, such as the fibroin promoter, would allow the constitutive production of a useful protein in the silkworm and the modification of the character of silk protein. A chimeric protein consisted of fibroin and green fluorescent protein was expressed under the control of fibroin in the posterior silk gland and the gene product was spun into the cocoon layer. This technique, gene targeting, will lead to the modification and enhancement of physicochemical properties of silk protein.     

Blood pressure-depressing activity of a peptide derived from silkworm fibroin in spontaneously hypertensive rats

Peptides showing inhibitory activity against the angiotensin I-converting enzyme (ACE) were investigated from the fibroin fraction of discarded silk fabric. Fibroin, which was hydrolyzed with alcalase after partial hydrolysis with hot aqueous 40% CaCl(2), released two major active peptides showing ACE-inhibitory activity. The two peptides were identified as glycyl-valyl-glycyl-tyrosine (GVGY) and glycyl-valyl-glycyl-alanyl-glycyl-tyrosine (GVGAGY) by analyses with a protein sequencer and LC/MS/MS. GVGY, whose ACE-inhibitory activity has not previously been reported, showed a blood pressure-depressing effect on spontaneously hypertensive rat (SHR).     

New silk protein: modification of silk protein by gene engineering for production of biomaterials.

The interest in silk fibroin morphology and structure have increased due to its attractiveness for bio-related applications. Silk fibers have been used as sutures for a long time in the surgical field, due to the biocompatibility of silk fibroin fibers with human living tissue. In addition, it has been demonstrated that silk can be used as a substrate for enzyme immobilization in biosensors. A more complete understanding of silk structure would provide the possibility to further exploit silk fibroin for a wide range of new uses, such as the production of oxygen-permeable membranes and biocompatible materials. Silk fibroin-based membranes could be utilized as soft tissue compatible polymers. Baculovirus-mediated transgenesis of the silkworm allows specific alterations in a target sequence. Homologous recombination of a foreign gene downstream from a powerful promoter, such as the fibroin promoter, would allow the constitutive production of a useful protein in the silkworm and the modification of the character of silk protein. A chimeric protein consisted of fibroin and green fluorescent protein was expressed under the control of fibroin in the posterior silk gland and the gene product was spun into the cocoon layer. This technique, gene targeting, will lead to the modification and enhancement of physicochemical properties of silk protein.     

Air Filter Devices Including Nonwoven Meshes of Electrospun Recombinant Spider Silk Proteins

Based on the natural sequence of Araneus diadematus Fibroin 4 (ADF4), the recombinant spider silk protein eADF4(C16) has been engineered. This highly repetitive protein has a molecular weight of 48kDa and is soluble in different solvents (hexafluoroisopropanol (HFIP), formic acid and aqueous buffers). eADF4(C16) provides a high potential for various technical applications when processed into morphologies such as films, capsules, particles, hydrogels, coatings, fibers and nonwoven meshes. Due to their chemical stability and controlled morphology, the latter can be used to improve filter materials. In this protocol, we present a procedure to enhance the efficiency of different air filter devices, by deposition of nonwoven meshes of electrospun recombinant spider silk proteins. Electrospinning of eADF4(C16) dissolved in HFIP results in smooth fibers. Variation of the protein concentration (5-25% w/v) results in different fiber diameters (80-1,100 nm) and thus pore sizes of the nonwoven mesh.Post-treatment of eADF4(C16) electrospun from HFIP is necessary since the protein displays a predominantly α-helical secondary structure in freshly spun fibers, and therefore the fibers are water soluble. Subsequent treatment with ethanol vapor induces formation of water resistant, stable β-sheet structures, preserving the morphology of the silk fibers and meshes. Secondary structure analysis was performed using Fourier transform infrared spectroscopy (FTIR) and subsequent Fourier self-deconvolution (FSD).The primary goal was to improve the filter efficiency of existing filter substrates by adding silk nonwoven layers on top. To evaluate the influence of electrospinning duration and thus nonwoven layer thickness on the filter efficiency, we performed air permeability tests in combination with particle deposition measurements. The experiments were carried out according to standard protocols.     

Ultrastructure of posterior silk gland cells and liquid silk in Indian tasar silkworm,Antheraea mylitta drury (Lepidoptera : Saturniidae)

The ultrastructural characteristics of the posterior silk glands of the mature Antheraea mylitta (Lepidoptera : Saturniidae) larvae were clarified. Fibroin globules containing a small dense mass of fibroin fibers are produced in Golgi vacuoles, and released from the apical surface into the lumen by exocytosis. Bundles of microfilaments, which serve as a dynamic skeleton, are well developed. Numerous autophagosomes originating; from mitochondria accumulate in both basal and apical ends of the gland cell; the degenerated materials are released in the basement membrane and into the gland lumen, respectively. These materials invade the central fibroin column, leaving digested vacuoles in the fibroin cocoon filament. Ours may be the first finding of this rare phenomenon in which the degenerated lysosomes originated from mitochondria in both liquid silk in the lumen and cocoon filament.     

Induction of osteogenic differentiation of osteoblast-like cells MG-63 during cultivation on fibroin microcarriers

We have developed microcarriers made from silk fibroin. Microcarriers can be used as a substrate for cell cultivation and cell delivery during cell-based therapy and for the construction of bioengineered tissue. Fibroin microcarriers were mineralized, which led to the appearance of calcium phosphate crystals on their surface. The ability of mineralized and nonmineralized microcarriers to support osteogenic differentiation of the osteoblast-like cell line MG-63 was estimated by alkaline phosphatase activity, an early marker of bone formation. The experiment showed cells actively proliferating on the surface of both mineralized and nonmodified microcarriers. Culturing MG-63 on the surface of fibroin microcarriers resulted in an increase of alkaline phosphatase activity indicative of osteogenic differentiation of MG-63 cells in the absence of inductors. The level of alkaline phosphatase was higher when mineralized microcarriers were used. Alkaline phosphatase activity of MG-63 cells cultivated using traditional two-dimensional approaches were close to zero. As opposed to conventional monolayer culturing, microcarrier culture cells are in a three-dimensional environment that is closer to physiological conditions. This can have a significant impact on their morphology and functional properties. During this study, we also characterized mechanical properties of porous scaffolds used for microcarriers.     

Ultrastructural observations on the organogenesis of the posterior silk gland of the silkworm, Bombyx mori

In the early stages of development (0 to 48 hr after organogenesis) the posterior silk gland cells of the silkworm, Bombyx mori, have characteristics of undifferentiated cells, that is, there are a number of free ribosomes in the cytoplasm and development of rough endoplasmic reticulum (rER) and Golgi bodies is very poor. Mitotic cells are frequently found. At ～ 60 hr when differentiation of the silk gland to the posterior, middle, and anterior divisions is completed, mitotic cells were no longer observable and the posterior silk gland is now composed of two rows of cells regularly packed forming a tubular structure. Differentiation of the cytoplasm is, however, not yet apparent and only a slight proliferation of rER can be observed. At 84 to 144 hr, proliferation of rER and transformation of rER from lamellar to vesico-tubular configuration are observed and Golgi vacuoles begin to enlarge. Just before hatching, the ultrastructures of cells are very similar to those of the later stage of the fifth instar when fibroin is synthesized extensively; the cytoplasm is filled with vesico-tubular rER, Golgi bodies, free secretory granules of fibroin, and mitochondria. Fibroin is probably synthesized, transported, and secreted in a manner similar to that in the fifth instar larvae.     

Intramolecular homologous recombination event occurred in the spider egg case silk gene CySp2 of wasp spider Argiope bruennichi

To gain further understanding of egg case silk proteins gene family, Zhao et al. (2006) isolated two full-length cDNAs for egg case silk proteins, cylindrical silk protein 1 (CySp1) and cylindrical silk protein 2 (CySp2), from the wasp spider, Argiope bruennichi. CySp2 was reported to contain no apparent Signal peptide sequences, and the CySp1-CySp2 complex, which would possess a signal peptide, would be transported across the endoplasmic reticulum and secreted to the Golgi. According to a report by Hayashi, genomic DNA sequencing is one approach that can be successfully utilized to retrieve 5′ ends of silk genes; using this method, we retrieved the 5’ end of CySp1. We found that CySp2 contained a typical signal peptide similar to that found in CySp1; thus, due to technical limitations, an artificial error had occurred in the CySp2 sequence reported by Zhao et al.     

Translation of silk fibroin messenger RNA in an Ehrlich ascites cell-free extract.

RNA identified by its base composition and T1 RNase oligonucleotide pattern as the message for silk fibroin was purified from mature posterior silk glands of Bombyx mori larvae and used to direct polypeptide synthesis in an Ehrlich ascites cell-free extract. Fibroin mRNA stimulated [3-H]alanine incorporation about 3- to 4-fold in the presence of 80 mM K+ and 4 mM Mg-2+. The stimulation was reduced in the presence of 5 times 10-minus 6 to 10-minus 4 M aurintricarboxylic acid, an inhibitor of the initiation of protein synthesis. The cell-free products were heterogeneous in size, including peptides as large as 100,000 daltons. They co-precipitated with carrier fibroin sequences after digestion with trypsin. A large fraction of the polypeptides synthesized in response to fibroin mRNA was precipitated by antiserum directed against amino acid sequences in noncrystalline region polypeptides of fibroin. Furthermore, after digestion with chymotrypsin, a major fraction of the cell-free products specifically co-precipitated with crystalline region sequences of native fibroin. The size and amino acid composition of the fibroin crystalline region polypeptides isolated from the cell-free products were similar to those from native fibroin.     

Use of spider silk fibres as an innovative material in a biocompatible artificial nerve conduit

Defects of peripheral nerves still represent a challenge for surgical nerve reconstruction. Recent studies concentrated on replacement by artificial nerve conduits from different synthetic or biological materials. In our study, we describe for the first time the use of spider silk fibres as a new material in nerve tissue engineering. Schwann cells (SC) were cultivated on spider silk fibres. Cells adhered quickly on the fibres compared to polydioxanone monofilaments (PDS). SC survival and proliferation was normal in Live/Dead assays. The silk fibres were ensheathed completely with cells. We developed composite nerve grafts of acellularized veins, spider silk fibres and SC diluted in matrigel. These artificial nerve grafts could be cultivated in vitro for one week. Histological analysis showed that the cells were vital and formed distinct columns along the silk fibres. In conclusion, our results show that artificial nerve grafts can be constructed successfully from spider silk, acellularized veins and SC mixed with matrigel.