Constitution of stable artificial oil bodies with triacylglycerol, phospholipid, and caleosin

Seed oil bodies are lipid storage organelles of 0.5-2 microm in diameter and comprise a triacylglycerol matrix shielded by a monolayer of phospholipids and proteins. These proteins include abundant structural proteins, oleosins, and at least two minor proteins termed caleosin and steroleosin. This study examined if artificial oil bodies (AOBs) composed of triacylglycerol and phospholipid could be stabilized by oleosin, caleosin, or steroleosin. Our results showed that stabilization effects could be realized by oleosin or caleosin but not by steroleosin. The sizes of the AOBs constituted with oleosin (0.5-2 microm) or caleosin (50-200 nm) were similar to or 10 times smaller than those of the native oil bodies. Recombinant caleosin expressed in Escherichia coli also encapsulated AOBs with a size, topology, and stability comparable to those encapsulated with native caleosin. A proteinase K digestion indicated that caleosin anchored the AOBs via its central hydrophobic domain of approximately 4 kDa. Isoelectrofocusing revealed that the isoelectric point of the caleosin-stabilized AOBs was pH 4.0. Aggregation of AOBs was observed at a pH lower than 4.5; thus, their stability and integrity were presumably contributed by surface caleosin via electronegative repulsion and steric hindrance. The caleosin-stabilized AOBs were thermostable up to 70 degrees C and potentially useful for biotechnological applications.     

Minimizing the central hydrophobic domain in oleosin for the constitution of artificial oil bodies

Oleosin, a unique structural protein anchoring onto the surface of seed oil bodies by its central hydrophobic domain, stabilizes these lipid-storage organelles as discrete entities. Stable artificial oil bodies have been successfully constituted with native or recombinant oleosins. In this study, recombinant sesame oleosin with 12 residues stepwise truncated from its central hydrophobic domain of 72 residues was overexpressed in Escherichia coli, was purified to homogeneity, and was used for the constitution. Artificial oil bodies constituted by truncated oleosins with the central hydrophobic domain longer than 36 residues were as stable as native sesame oil bodies, and those constituted by truncated oleosins lacking more than half of the original central hydrophobic domain inclined to coalesce upon collision or aggregation.     

Oil Binding of Heat‐Treated Waxy Wheat Starch Granules and Starch Granule Ghosts Produced with Concentrated KI and I2

Dry waxy wheat starch granules were heat‐treated at 120°C for 5 hr, and then shaken vigorously in a biphasic system of oil and water. Non‐heat‐ treated starch remained in the aqueous phase, whereas the heat‐treated starch granules showed a strong oil‐binding ability that was lost by trypsin treatment. This result showed that the starch granule surface protein changed from hydrophilic to hydrophobic due to the heat treatment. The presence of starch granule surface protein was ascertained by staining with fluorescamine and fluorescence microscopic observation. Heat‐treated waxy wheat starch granules were incubated with a 25% KI/10% I₂ (w/v) solution, which produced “ghosts” (exterior and interior) structures. The exteriors stained red‐brown, whereas the interiors stained black‐brown. Sonication (20 kHz for 255 sec) followed by centrifugation separated the structures, which were then shaken vigorously in an oil and water system. Only the exterior ghosts exhibited a remarkable emulsification property, which disappeared after trypsin treatment. The ghosts from unheated control granules did not show emulsification. The presence of protein in the exterior ghost fraction was further substantiated by fluorescamine treatment. No protein was detectable in the interior fraction with this dye. From these results, we suggest that the ghost fraction of the waxy wheat starch contained the starch granule surface protein that was made hydrophobic by heat treatment. Also, the nature of the induced emulsification property of the exterior fraction (ghosts) and the oil‐binding ability of the heat‐treated waxy wheat starch granules coincided. Both were due to the hydrophobic nature of the same starch granule surface protein, which showed that the ghosts were the swollen form of the outer region of the waxy starch granule.     

Method for bacterial expression and purification of sesame cystatin via artificial oil bodies

A method was developed for production of sesame cystatin, a thermostable cysteine protease inhibitor. Sesame cystatin was first expressed in Escherichia coli as an insoluble recombinant protein fused to oleosin, a unique structural protein of seed oil bodies, by a short hydrophilic linker peptide. Stable artificial oil bodies were constituted with triacylglycerol, phospholipid, and the insoluble oleosin-cystatin fusion protein. After centrifugation, the oleosin-cystatin fusion protein was exclusively found in the artificial oil bodies. Proteolytic cleavage with papain, a cysteine protease effectively inhibited by cystatin, separated soluble cystatin from oleosin that was firmly embedded in the artificial oil bodies. After recentrifugation, papain that coexisted with cystatin in the collected supernatant was denatured by incubating at 55 degrees C for 30 min. The insoluble denatured papain was removed by one more centrifugation, and the expressed cystatin of high yield and purity was harvested simply by concentrating the ultimate supernatant. Comparable inhibitory activity toward papain was observed between the expressed cystatin and the native one purified from sesame seeds. This method is presumably applicable to production of other protease inhibitors whose target proteases are economically available.     

不同品种花生油脂体粒径电位和蛋白质组成的分析

为了探索不同品种花生油脂体的物理和化学性质差异,以5种（豫花23,豫花27,豫花9719,豫花9830和豫花9502）油脂含量不同的花生品种为原料,采用水剂法提取油脂体,并对提取后油脂体的粒径、ζ电位、氨基酸组成、蛋白质分子量分布进行分析比较。结果表明：提取后,5种花生油脂体粒径间存在一定差异,以豫花9719的粒径较大;花生油脂体均含有油脂体蛋白和贮藏蛋白,但不同品种间存在蛋白质种类的差异;5种花生油脂体在pH值为3.0时ζ电位为正值,在pH值为7.4和pH值为9.0时ζ电位为负值,盐浓度的增加会降低油脂体ζ电位的绝对值;5种花生油脂体的蛋白质均为极性带负电氨基酸质量分数均大于非极性带正电或不带电氨基酸,但氨基酸总量各不相同,以豫花27较低。该研究可为花生油脂体的品质特性研究和应用产品开发提供参考。     

Extraction and characterization of oil bodies from soy beans: a natural source of pre-emulsified soybean oil

Soybeans contain oil bodies that are coated by a layer of oleosin proteins. In nature, this protein coating protects the oil bodies from environmental stresses and may be utilized by food manufacturers for the same purpose. In this study, oil bodies were extracted from soybean using an aqueous extraction method that involved blending, dispersion (pH 8.6), filtration, and centrifugation steps. The influence of NaCl (0-250 mM), thermal processing (30-90 degrees C, 20 min) and pH (2-8) on the properties and stability of the oil bodies was analyzed using zeta-potential, particle size, and creaming stability measurements. The extracted oil bodies were relatively small ( d 32 approximately 250 nm), and their zeta-potential went from around +12 mV to -20 mV as the pH was increased from 2 to 8, with an isoelectric point around pH 4. The oil bodies were stable to aggregation and creaming at low (pH = 2) and high (pH >/= 6) pH values but were unstable at intermediate values (3 相似文献   

Detection and localization of oxidized proteins in muscle cells by fluorescence microscopy

In meat, no detailed studies on the intracellular distribution of oxidized proteins during oxidative stress have been performed, to our knowledge. Therefore, we used fluorescence microscopy to detect and locate protein carbonyls, oxidation products of basic amino acids, generated in bovine M. Rectus abdominis during either exposition to a chemical free radical generating system, or refrigerated storage, or cooking. The technique consisted of an immunohistochemical detection of carbonyls by reaction with the specific probe DNPH (2,4-dinitrophenylhydrazine) followed by the sequential addition of a first antibody against DNPH-carbonylated proteins and a CY3-labeled secondary antibody. The fluorescence of the CY3 probe increased regularly with level of free radical generating system and storage time. Moreover, an important heterogeneity of carbonyl distribution was observed, with a higher oxidation level at the periphery than inside the muscle cells. Cooking induced fluorescence increase only at the periphery of cells. Specific coloration of collagen by Sirius red showed that collagen was not involved in fluorescence. We can deduce that accumulation of oxidized proteins observed in the cell periphery was linked to membrane protein oxidation and not to connective tissue oxidation. Biochemical assays were performed in parallel on membrane and myofibrillar proteins to provide complementary quantitative data on level of oxidized proteins.     

Interface characterization and aging of bovine serum albumin stabilized oil-in-water emulsions as revealed by front-surface fluorescence

This paper is devoted to the application of front-surface fluorescence to the study of aging and oxidation of oil-in-water emulsions. Emulsions with two oil droplet sizes were stabilized with bovine serum albumin (BSA) and stored at 37 or 47 degrees C. Lipid oxidation was demonstrated by measurement of hydroperoxides and headspace pentane. Front-surface fluorescence spectra (excitation wavelength = 355 nm) revealed gradual formation of oxidized lipid-protein adducts during the 4 weeks of storage. Fluorescence (excitation = 290 nm) of BSA tryptophanyl residues (Trp) declined during the first day of aging and then decreased slightly and linearly. Fourth-derivative Trp spectra exhibited peaks at 316 and 332 nm. Their evolution indicated that the ratio of Trp in hydrophobic environments to total Trp increased in small droplet emulsions. This suggests that, during lipid oxidation, the adsorbed and nonadsorbed protein underwent various degrees of Trp degradations, polymerization, and aggregation. Thus, front-surface fluorescence makes it possible to evaluate, noninvasively, protein modification and lipid oxidation end-products during processing and storage of food emulsions.     

Microstructure and Composition of Digitaria exilis Stapf (acha): A Potential Crop

Microstructure of the mature caryopsis of Digitaria exilis Stapf was studied by light and scanning electron microscopy and compared to chemical composition. The general structure of the caryopsis was similar to that of other grains, notably the millets. Thin bracts (the palea and lemma) and two glumes encased the caryopsis which consists of the thin, compressed layers of pericarp, testa, and cuticle surrounding the endosperm and embryonic tissues. The endosperm consisted of a single layer of aleurone cells and the starchy endosperm. The aleurone layer was thin over most of the starchy endosperm and thicker at the junction of the embryo and starchy endosperm. Aleurone cells contained lipid droplets and protein bodies. The cell contents of the starchy endosperm consisted of simple, polyhedral starch granules, lipid droplets, and protein bodies. Protein bodies were more abundant toward the periphery, and diminished toward the central portion of the starchy endosperm. Cells in certain regions of the embryo contained few, small, spherical starch granules and an abundance of protein bodies. Protein bodies containing phytic acid inclusions were located in the scutellum of the embryo. Compositional analyses revealed that the grain contained 8.2% protein, 2.1% fat, 0.48% fiber, and 1.4% ash.     

Effect of Specific Mechanical Energy on Protein Bodies and α-Zeins in Corn Flour Extrudates

Zeins, the storage proteins of corn, are located in spherical entities called protein bodies. The disruption of protein bodies and zein release during extrusion may influence the texture of corn-based extruded foods. In this work, chemical and microscopic studies were conducted on corn flour that had been extruded under mild to extreme conditions to determine the specific mechanical energy (SME) required to break apart protein bodies and release α-zein, and to assess changes in protein-protein interactions. Transmission electron microscopy with immunolocalization of α-zein revealed that starch granules and protein bodies remained intact under mild processing conditions (SME 35–40 kJ/kg), but under harsher conditions, protein bodies were disrupted and α-zein was released. At SME ≈100 kJ/kg, protein bodies appeared highly deformed and fused together with the α-zein released, whereas at higher SME, protein bodies were completely disrupted and α-zein was dispersed and may have formed protein fibrils. Protein in extrudates was less soluble in urea and SDS than in unprocessed corn flour, but it was readily extracted with urea, SDS, and 2-ME. This was likely due to protein aggregation upon processing due to a prevalence of hydrophobic interactions and disulfide bonds. This research directly relates SME during extrusion to chemical and structural changes in corn proteins that may affect the texture of corn-based, ready-to-eat food products.     

大豆丛枝菌根共生结构和多聚磷累积双定位方法

【目的】多聚磷是丛枝菌根内磷的主要贮存形式,定性、定量观察多聚磷对于解析菌根中磷代谢具有重要意义。随着植物体内越来越多的参与菌根真菌与寄主植物之间营养交换过程的基因被鉴定,迫切需要进一步提高根内菌根共生结构和多聚磷累积的染色和定位分析技术。【方法】本研究利用丛枝菌根真菌Glomus mosseae侵染的大豆植株,采集新鲜根样制片,一部分薄根片利用低浓度荧光染料麦胚凝集素,室温染色30 min,在波长488 nm的蓝光激发下使用荧光显微镜观察拍照;另一部分薄根片利用荧光染料4’,6-二脒基-2-苯基吲哚二盐酸盐(DAPI)进行染色,在波长405 nm紫外光激发下观察并拍照;进一步取新鲜制备的薄根片,先后用以上两种荧光染料进行染色,分别在波长405 nm和488 nm的激发光下观察并拍照,完成了菌根共生结构和多聚磷的共定位。【结果】1)使用荧光染料麦胚凝集素,大豆丛枝菌根真菌侵染结构的荧光标记活性染色法,可以清晰地检测到大豆丛枝菌根中所有的共生结构,包括丛枝,泡囊和根内菌丝等。2)在丛枝菌根真菌侵染的根中,各种共生结构都呈现出黄色荧光,为DAPI与多聚磷结合在紫外光激发下的呈色。根段中部分细胞内的蓝白色斑点为DAPI与细胞核中DNA结合的显色结果。在含有成熟丛枝结构的细胞中,也可观察到大部分丛枝呈蓝白色,主要是丛枝膜质结构的呈色。因此,利用荧光染料4’,6-二脒基-2-苯基吲哚二盐酸盐染色法定位多聚磷,能很好地区分多聚磷酸盐、DNA和膜质。3)在以上研究的基础上,通过荧光光路的切换,可以同时观察到菌根共生结构和多聚磷的共定位。处于发育阶段的整个丛枝中多聚磷累积的亮黄色清晰可见。在成熟的丛枝中,由于膜质结构发达,对累积在丛枝结构中的多聚磷的染色观察产生了一定影响,导致仅仅局部的多聚磷累积清晰可见。【结论】本研究建立的大豆菌根共生结构与多聚磷累积的双定位分析系统,能够直观观察植物与丛枝菌根真菌的养分交换,清晰地对丛枝菌根共生结构中多聚磷的累积进行定位分析,可作为从组织和细胞水平研究菌根共生体的重要技术手段。     

Extraction of soybean oil from single cells

Single cells prepared from autoclaved soybeans and cellulase treatment of the cells were effective in digesting the cell walls of and extracting the oil from soybeans. The first cell wall of the soybean single cell was completely removed using cellulases; the thin and transparent second cell wall of the cell was swollen. Oil in the cell formed spherical or hemispherical oil drops, and oil leaking from the oil bodies was observed. The oil was almost retained within the second cell wall. Water-extractable substances were obtained at approximately >60% of the weight. Flotation of oil drops by centrifugation was easily done. Ambient n-hexane extraction was also possible; however, residual oil remained in the oil bodies. Protease or peptidase digested the structure of the oil bodies; however, separation of the oil and the hydrolysates was impossible. The oil from the oil bodies was obtained effectively (>85%) by pressing the single cells and/or cellulase-treated single cells.     

基于薄膜干燥-真空抽滤技术的核桃油体提取及破乳研究

为降低实际生产中油体破乳的成本,实现油体的绿色、高值化综合利用,该研究通过低速离心（2 862 g,15 min）将去衣核桃仁水提物分离成油体富集物、清液和沉淀组分,其中,油体富集物通过薄膜干燥和真空抽滤破乳制备核桃油和富含磷脂和膜蛋白的高值附加产品。在此过程中,系统考察了脂质和蛋白质在3个离心组分中的分布和性质,并研究了油体富集物在薄膜干燥过程中的破乳机制。结果表明：去衣核桃仁中的脂质主要分布在油体富集物（占核桃仁脂质总量的85.69%）中,而蛋白质主要分布在清液（占核桃仁蛋白质总量的23.58%,主要是清蛋白和球蛋白）和沉淀（占核桃仁蛋白质总量的65.04%,主要是谷蛋白）中。油体富集物在薄膜干燥的过程中表现出向变稠-变软-液态的形态转变,液态物料通过真空抽滤分离为游离油（占核桃仁脂质总量的81.78%）和磷脂-膜蛋白富集物。磷脂-膜蛋白富集物主要成分质量分数分别为：中性脂占67.23%、蛋白质占19.41%（其中,膜蛋白占蛋白成分的50%以上）、磷脂占6.61%和其他成分（如鞘氨醇）占6.75%。激光共聚焦显微镜和电导率分析表明,在薄膜干燥过程中,油体会随着水分的蒸发逐渐聚合为更...     

超声复合酸处理促进花生分离蛋白的亚基解离

为了改善蛋白质的功能特性,该研究分析了超声复合酸处理对花生分离蛋白的溶解性、紫外光谱、荧光光谱、二级结构及纳米结构等的影响,并探讨不同处理条件下蛋白聚集体结构变化的机理。结果表明,超声作用可以明显促进花生分离蛋白的不溶性聚集体向可溶性聚集体转变,单独超声及超声复合酸处理使其溶解度相对于对照分别增加了12.9%和15.3%（P<0.05）;电泳、紫外和荧光光谱表明,超声和酸作用均有助于亚基解离及蛋白质结构展开,从而促进更多的酪氨酸、色氨酸和苯丙氨酸等疏水性基团暴露;圆二色谱分析显示,与对照相比,在超声复合酸处理使花生分离蛋白的a-螺旋增加21.9%,β-折叠减少3.6%,无规则卷曲增加1.8%（P<0.05）;纳米结构表明,超声复合酸处理最大程度地降低了花生分离蛋白的颗粒大小。该研究证实,在酸性条件下进行超声处理,能显著促进花生分离蛋白的亚基解离和结构展开。该研究为后期蛋白亚基重新相互作用形成不同功能的改性蛋白提供参考。     

Stabilization of soybean oil bodies using protective pectin coatings formed by electrostatic deposition

Soybeans contain oil bodies that are naturally coated by a layer of phospholipids and proteins. In nature, this coating protects the oil bodies from environmental stresses and could be utilized by food manufacturers for the same purpose. However, natural oil bodies are physically unstable to aggregation because of the relatively weak electrostatic repulsion between them, which limits their application in many foods. In this study, oil bodies were extracted from soybean using an aqueous extraction method and then coated by a pectin layer using electrostatic deposition. The influence of NaCl (0-500 mM), pH (2-8), and freeze-thaw cycling (-20 degrees C, 22 h/40 degrees C, 2 h) on the properties and stability of the oil bodies coated by the pectin layer was analyzed using zeta-potential, particle size, and creaming stability measurements. These results suggest that pectin-coated oil bodies have similar or improved stability compared to uncoated oil bodies and may provide a new way of creating functional soy products for use in the food and other industries.     

Grape epicatechin conjugates prevent erythrocyte membrane protein oxidation

Epicatechin conjugates obtained from grape have shown antioxidant activity in various systems. However, how these conjugates exert their antioxidant benefits has not been widely studied. We assessed the activity of epicatechin and epicatechin conjugates on the erythrocyte membrane in the presence and absence of a peroxyl radical initiator, to increase our understanding of their mechanisms. Thus, we studied cell membrane fluidity by fluorescence anisotropy measurements, morphology of erythrocytes by scanning electron microscopy, and finally, red cell membrane proteins by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Our data showed that incubation of red cells in the presence of epicatechin derivatives altered membrane fluidity and erythrocyte morphology but not the membrane protein pattern. The presence in the medium of the peroxyl radical initiator 2,2'-azobis(amidinopropane) dihydrochloride (AAPH) resulted in membrane disruptions at all levels analyzed, causing changes in membrane fluidity, cell morphology, and protein degradation. The presence of antioxidants avoided protein oxidation, indicating that the interaction of epicatechin conjugates with the lipid bilayer might reduce the accessibility of AAPH to membranes, which could explain in part the inhibitory ability of these compounds against hemolysis induced by peroxidative insult.     

Preparation and characterization of water/oil and water/oil/water emulsions containing biopolymer-gelled water droplets

The purpose of this study was to create water-in-oil (W/O) and water-in-oil-in-water (W/O/W) emulsions containing gelled internal water droplets. Twenty weight percent W/O emulsions stabilized by a nonionic surfactant (6.4 wt % polyglycerol polyricinoleate, PGPR) were prepared that contained either 0 or 15 wt % whey protein isolate (WPI) in the aqueous phase, with the WPI-containing emulsions being either unheated or heated (80 degrees C for 20 min) to gel the protein. Optical microscopy and sedimentation tests did not indicate any significant changes in droplet characteristics of the W/O emulsions depending on WPI content (0 or 15%), shearing (0-7 min at constant shear), thermal processing (30-90 degrees C for 30 min), or storage at room temperature (up to 3 weeks). W/O/W emulsions were produced by homogenizing the W/O emulsions with an aqueous Tween 20 solution using either a membrane homogenizer (MH) or a high-pressure valve homogenizer (HPVH). For the MH the mean oil droplet size decreased with increasing number of passes, whereas for the HPVH it decreased with increasing number of passes and increasing homogenization pressure. The HPVH produced smaller droplets than the MH, but the MH produced a narrower particle size distribution. All W/O/W emulsions had a high retention of water droplets (>95%) within the larger oil droplets after homogenization. This study shows that W/O/W emulsions containing oil droplets with gelled water droplets inside can be produced by using MH or HPVH.     

Prokaryotic Expression of Mouse Sox2 Gene and Preparation of Its Polyclonal Antibody

Sox2, one of genes which express in embryonic stem (ES) cells, plays an important role in selfrenewal of ES cells, and is used to make induced pluripotent stem (iPS) cells. In this study, we subcloned mouse (Mus muscules) full-length Sox2 cDNA and inserted Sox2 into pET-41 a expression vector. Then the recombinant vector was transformed into Escherichia coli BL21 (DE3) cells to express Sox2 fusion protein. The expressed products were identified by Western blot using anti-GST antibody. The result indicated that the size of Sox2 fusion protein was in 61 kD. And the protein was recovered from the SDS-PAGE. And we used the sox2 fusion protein to prepare polyclonal antibody. The Dot blotting result showed that the anti-Sox2 antiserum had 1:12,800 titers. The antibody will be useful for studying the function of Sox2 and its role in ES cell self-renewal.     

Ability of surfactant hydrophobic tail group size to alter lipid oxidation in oil-in-water emulsions

Oxidation of oil-in-water emulsion droplets is influenced by the properties of the interfacial membrane surrounding the lipid core. Previous work has shown that an important factor in the oxidation of oil-in-water emulsions is surfactant properties that impact interactions between water-soluble prooxidants and lipids in the emulsion droplet. The purpose of this research was to study the impact of surfactant hydrophobic tail group size on lipid oxidation in oil-in-water emulsions stabilized by polyoxyethylene 10 lauryl ether (Brij-lauryl) or polyoxyethylene 10 stearyl ether (Brij-stearyl). The ability of iron to decompose cumene peroxide was similar in hexadecane emulsions stabilized by Brij-stearyl and Brij-lauryl. Oxidation of methyl linoleate in hexadecane emulsions containing cumene peroxide was greater in droplets stabilized by Brij-lauryl than in those stabilized by Brij-stearyl at pH 3 with no differences observed at pH 7.0. Oxidation of salmon oil was greater in emulsions stabilized by Brij-lauryl than in those stabilized by Brij-stearyl as determined by both lipid peroxides and headspace propanal. These results suggest that surfactant hydrophobic tail group size may play a minor role in lipid oxidation in oil-in-water emulsions.     

Efficient system of artificial oil bodies for functional expression and purification of recombinant nattokinase in Escherichia coli

Nattokinase, a serine protease, and pronattokinase, when expressed in Escherichia coli, formed insoluble aggregates without enzymatic activity. For functional expression and purification, nattokinase or pronattokinase was first overexpressed in E. coli as an insoluble recombinant protein linked to the C terminus of oleosin, a structural protein of seed oil bodies, by an intein fragment. Artificial oil bodies were reconstituted with triacylglycerol, phospholipid, and the insoluble recombinant protein thus formed. Soluble nattokinase was subsequently released through self-splicing of intein induced by temperature alteration, with the remaining oleosin-intein residing in oil bodies and the leading propeptide of pronattokinase, when present, spontaneously cleaved in the process. Active nattokinase with fibrinolytic activity was harvested by concentrating the supernatant. Nattokinase released from oleosin-intein-pronattokinase exhibited 5 times higher activity than that released from oleosin-intein-nattokinase, although the production yields were similar in both cases. Furthermore, active nattokinase could be harvested in the same system by fusing pronattokinase to the N terminus of oleosin via a different intein linker, with self-splicing induced by 1,4-dithiothreitol. These results have shown a great potential of this system for bacterial expression and purification of functional recombinant proteins.