An investigation into the effect of potassium ions on the folding of silk fibroin studied by generalized two-dimensional NMR-NMR correlation and Raman spectroscopy

We used generalized two-dimensional NMR-NMR correlation to examine the effect of potassium ions on the conformation transition in silk fibroin to investigate the possibility that the fairly high K+ ion content found in the distal end of silk-secreting ducts in the silkworms could have a bearing on natural formation of the silk fiber. This has enabled us to propose a detailed mechanism for the transition process. Our evidence indicates that increasing the [K+] from 0 to 3.7 mg.g(-1) in the silk fibroin, as is thought to occur as the silk fibroin moves through the secretory pathway to the spigot, produces a sequence of secondary structural changes: helix and/or random coil-->helix-like-->beta-sheet-like-->beta-sheet. The sequence is the same as that produced in silk fibroin films by decreasing the pH of fibroin from 6.8 to 4.8. In addition, we used Raman spectroscopy to study the effect of K+ ions on the Fermi doublet resonance of the tyrosyl phenolic ring at 850 and 830 cm(-1). The intensity ratio I(850)/I(830) at these wave numbers indicated that the hydrogen bonding formed by the tyrosyl phenolic-OH becomes more stable with an increase in the K+ ion concentration as above. Our investigation on the effect of K+ ions on fibroin may help provide a theoretical basis for understanding the natural silk-spinning process and the conditions required for biomimetic spinning. It may also have relevance to the aggregation of other beta-sheet proteins, including prion proteins, neurofibrillary proteins and amyloid plaques.     

Electron microscope examination of fibroin precipitated from silk fibroin solutions

The structure of gels formed from solutions of silk fibroin has been observed by electron microscopy. The gels consist of fibrils, and possible methods of formation of these fibrils are suggested.     

In vitro production of Bombyx mori silk fibroin by organ culture of the posterior silk glands; isotope labeling and fluorination of the silk fibroin

An in vitro silk fibroin production system has been developed by culture of posterior silk glands from Bombyx mori. A large amount of the silk fibroin was produced continuously and effectively with a rotation culture procedure. Modified Grace's insect medium was used, and oxygen bubbling in the medium was performed. In addition, half of the medium was replaced with fresh medium every 6 h. The production yield of silk fibroin produced after 100 h culture was 81 mg/g wet weight of posterior silk gland. This culture system was used successfully for efficient (15)N isotope labeling of silk fibroin, which is required for (15)N solid state nuclear magnetic resonance (NMR) analysis of silk fibroin. Moreover, the introduction of fluorinated amino acids into silk fibroin was also carried out using this culture system. (c) 1993 John Wiley & Sons, Inc.     

The fine structure of silk fibroin

The fine structure of Bombyx mori silk fibroin was investigated by electron microscopy and X-ray diffraction techniques. Examination of silk fibers fragmented with ultrasonic radiation and negatively stained revealed the presence of ribbon-like filaments of well-defined lateral dimensions. Analysis of the breadths of the equatorial reflections in the X-ray diffraction pattern of fibroin yielded similar dimensions for the lateral extent of the crystallites. It is concluded that the crystalline material in B. mori silk fibroin is in the form of ribbon-like filaments of considerable length parallel to the fiber axis and of lateral dimensions approximately 20 x 60 A.     

The biosynthesis of fibroin. I. The intracellular form of silk fibroin of Bombyx mori L

After in vivo labeling with [³H]glycine the synthesis and transport of fibroin has been studied by radioautography and cell fractionation.Radioactivity appearing in the cytoplasm is rapidly transferred to the lumen where it accumulates in the so-called silk layer before reaching the central core of secreted fibroin. By sucrose density gradients it was demonstrated that the radioactivity appears immediately in the fibroin fraction, no precursors being observed.A simple fractionation procedure, based on the utilization of detergent, gives three fractions tentatively interpreted as synthesis, transport, and accumulation compartments in accordance with their kinetics of labeling.     

An ESR study of spin-labeled silk fibroin membranes and spin-labeled glucose oxidase immobilized in silk fibroin membranes

This article describes the characteristics of silk fibroin membranes and glucose oxidase, immobilized in membranes as determined by a variety of physical methods, mainly the spin-label electron spin resonance (ESR) method. The properties of membranes insolubilized by different methods, i. e., immersion in 80% methanol aqueous solution, uniaxially drawing by placing on a stretcher, and hydration by placing in a desiccator of 96% relative humidity (RH) for 17 h, are compared. The results are also analyzed in relation to ESR spectra of spin-labeled immobilized glucose oxidase and 4-hydroxy-2,2,6,6-tetramethyl-1-piperidinyloxy as a model of the substrate. It is concluded that the heterogeneous structures of the swollen membranes in water differ locally among membranes insolubilized by different methods, but the immobilized state of the enzyme in such membranes is mostly similar. This is correlated to the fact that the thermal or pH stabilities are essentially same among glucose-oxidase-immobilized silk fibroin membranes insolubilized by different methods.     

Genetic polymorphism in normal human fibroblasts as analyzed by two-dimensional polyacrylamide gel electrophoresis.

Two dimensional gel electrophoresis has been used to measure the degree of genetic polymorphism among the proteins of normal human fibroblasts. Autoradiographic analysis of the gel protein profiles from radioactively labeled cells allowed comparison of as many as 300 discrete polypeptides at a time. In addition, a newly developed technique for double label autoradiography was used to increase the sensitivity of the system for detection of small differences in the protein profiles of different cell lines. Only about 1.2% of the proteins of different cell lines were found to differ in their electrophoretic mobility. This corresponds to an average heterozygosity of approximately 0.6%. Previous studies of genetic polymorphism using different methods of one-dimensional electrophoretic analysis have estimated the average heterozygosity of the human population at about 6.7%. Detailed mathematical analysis shows the variation of the observed from the expected number of differences to be statistically highly significant. While the reasons for this difference are not clear, the observation of low levels of genetic polymorphism on two-dimensional gels should enhance the usefulness of this technique for detection of altered proteins in inherited disease.     

Localization of the genes for silk fibroin in silk gland cells of Bombyx mori.

Radioactive iodinated silk fibroin messenger RNA and ribosomal RNA have been used as probes to localize their genes in tissue sections of Bombyx mori by in situ hybridization. From filter hybridization experiments it is inferred that the majority of the grains produced by in situ hybridization with fibroin mRNA represents specific hybridization to fibroin genes. Sections of the posterior silk gland where silk is synthesized have been compared with those of the middle gland which does not synthesize fibroin. Glands have been analyzed from the second through the fifth (last) larval instar during feeding and moulting periods. During later stages when the gland cells increase their DNA content by polyploidization, serial sections were required to follow the distribution of grains through entire nuclei. At all stages, both ribosomal DNA and fibroin genes are distributed randomly throughout the nuclei without a preferred relationship to any nuclear structure.     

Flexibility regeneration of silk fibroin in vitro

Although natural silk fibers have excellent strength and flexibility, the regenerated silk materials generally become brittle in the dry state. How to reconstruct the flexibility for silk fibroin has bewildered scientists for many years. In the present study, the flexible regenerated silk fibroin films were achieved by simulating the natural forming and spinning process. Silk fibroin films composed of silk I structure were first prepared by slow drying process. Then, the silk fibroin films were stretched in the wet state, following the structural transition from silk I to silk II. The difference between the flexible film and different brittle regenerated films was investigated to reveal the critical factors in regulating the flexibility of regenerated silk materials. Compared with the methanol-treated silk films, although having similar silk II structure and water content, the flexible silk films contained more bound water rather than free water, implying the great influence of bound water on the flexibility. Then, further studies revealed that the distribution of bound water was also a critical factor in improving silk flexibility in the dry state, which could be regulated by the nanoassembly of silk fibroin. Importantly, the results further elucidate the relation between mechanical properties and silk fibroin structures, pointing to a new mode of generating new types of silk materials with enhanced mechanical properties in the dry state, which would facilitate the fabrication and application of regenerated silk fibroin materials in different fields.     

Degradation mechanism and control of silk fibroin

Controlling the degradation process of silk is an important and interesting subject in the field of biomaterials. In the present study, silk fibroin films with different secondary conformations and nanostructures were used to study degradation behavior in buffered protease XIV solution. Different from previous studies, silk fibroin films with highest β-sheet content achieved the highest degradation rate in our research. A new degradation mechanism revealed that degradation behavior of silk fibroin was related to not only crystal content but also hydrophilic interaction and then crystal-noncrystal alternate nanostructures. First, hydrophilic blocks of silk fibroin were degraded. Then, hydrophobic crystal blocks that were formerly surrounded and immobilized by hydrophilic blocks became free particles and moved into solution. Therefore, on the basis of the mechanism, which enables the process to be more controllable and flexible, controlling the degradation behavior of silk fibroin without affecting other performances such as its mechanical or hydrophilic properties becomes feasible, and this would greatly expand the applications of silk as a biomedical material.     

用桑蚕丝素蛋白制备邻苯二酚酶传感器

从蘑菇组织中提取邻苯二酚粗酶 ,利用丝素蛋白在甲醇作用下 ,其分子结构由可溶性randomcoil向不容性 β -sheet发生转变 ,从而将邻苯二酚粗酶固定在丝素蛋白膜中 ,制得邻苯一酚酶传感器。该传感器在pH6 0的KH2 PO4 -Na2 HPO4 工作介质中具有良好的响应特性 ,工作线性范围为 1 0× 10 - 5- 2 5× 10 - 4mol L ,检测限 5 0× 10 - 6 mol L ,响应时间 2min。酶经丝素蛋白的固定后具有较强的耐热性能 ,并能比较长时间保持酶的活性。该传感器在KH2 PO4 -Na2 HPO4 缓冲溶液的保存下 ,其使用寿命可达 2个月以上     

Phase behavior and hydration of silk fibroin

The osmotic stress method was applied to study the thermodynamics of supramolecular self-assembly phenomena in crystallizable segments of Bombyx mori silkworm silk fibroin. By controlling compositions and phases of silk fibroin solution, the method provided a means for the direct investigation of microscopic and thermodynamic details of these intermolecular interactions in aqueous media. It is apparent that as osmotic pressure increases, silk fibroin molecules are crowded together to form silk I structure and then with further increase in osmotic pressure become an antiparallel beta-sheet structure, silk II. A partial ternary phase diagram of water-silk fibroin-LiBr was constructed based on the results. The results provide quantitative evidence that the silk I structure must contain water of hydration. The enhanced control over structure and phase behavior using osmotic stress, as embodied in the phase diagram, could potentially be utilized to design a new route for water-based wet spinning of regenerated silk fibroin.     

Compliant film of regenerated Antheraea pernyi silk fibroin by chemical crosslinking

A compliant film was prepared by chemical crosslinking of fibroin from silk fiber of wild silkworm, Antheraea pernyi. The silk fiber was dissolved in concentrated aqueous lithium thiocyanate and desalinated by dialysis. The film was cast from the regenerated aqueous solution, and crosslinked by polyethylene glycol diglycidyl ether (PEG-DE). This film showed high water resistively while maintaining random coil and -helix structure, unlike films prepared by organic solvent treatment that causes β-sheet formation. The films containing about 20 wt.% crosslinker were remarkably compliant and tenacious. These features, combined with the living-cell affinity of the wild silkworm fibroin, are expected to be useful in biomedical applications.