Gene family of oleosin isoforms and their structural stabilization in sesame seed oil bodies

Oleosins are structural proteins sheltering the oil bodies of plant seeds. Two isoform classes termed H- and L-oleosin are present in diverse angiosperms. Two H-oleosins and one L-oleosin were identified in sesame oil bodies from the protein sequences deduced from their corresponding cDNA clones. Sequence analysis showed that the main difference between the H- and L-isoforms is an insertion of 18 residues in the C-terminal domain of H-oleosins. H-oleosin, presumably derived from L-oleosin, was duplicated independently in several species. All known oleosins can be classified as one of these two isoforms. Single copy or a low copy number was detected by Southern hybridization for each of the three oleosin genes in the sesame genome. Northern hybridization showed that the three oleosin genes were transcribed in maturing seeds where oil bodies are being assembled. Artificial oil bodies were reconstituted with triacylglycerol, phospholipid, and sesame oleosin isoforms. The results indicated that reconstituted oil bodies could be stabilized by both isoforms, but L-oleosin gave slightly more structural stability than H-oleosin.     

Surface structure and properties of plant seed oil bodies

Storage triacylglycerols (TAG) in plant seeds are present in small discrete intracellular organelles called oil bodies. An oil body has a matrix of TAG, which is surrounded by phospholipids (PL) and alkaline proteins, termed oleosins. Oil bodies isolated from mature maize (Zea mays) embryos maintained their discreteness, but coalesced after treatment with trypsin but not with phospholipase A2 or C. Phospholipase A2 or C exerted its activity on oil bodies only after the exposed portion of oleosins had been removed by trypsin. Attempts were made to reconstitute oil bodies from their constituents. TAG, either extracted from oil bodies or of a 1:2 molar mixture of triolein and trilinolein, in a dilute buffer were sonicated to produce droplets of sizes similar to those of oil bodies; these droplets were unstable and coalesced rapidly. Addition of oil body PL or dioleoyl phosphatidylcholine, with or without charged stearylamine/stearic acid, or oleosins, to the medium before sonication provided limited stabilization effects to the TAG droplets. High stability was achieved only when the TAG were sonicated with both oil body PL (or dioleoyl phosphatidylcholine) and oleosins of proportions similar to or higher than those in the native oil bodies. These stabilized droplets were similar to the isolated oil bodies in chemical properties, and can be considered as reconstituted oil bodies. Reconstituted oil bodies were also produced from TAG of a 1:2 molar mixture of triolein and trilinolein, dioleoyl phosphatidylcholine, and oleosins from rice (Oryza sativa), wheat (Triticum aestivum), rapeseed (Brassica napus), soybean (Glycine max), or jojoba (Simmondsia chinensis). It is concluded that both oleosins and PL are required to stabilize the oil bodies and that oleosins prevent oil bodies from coalescing by providing steric hindrance. A structural model of an oil body is presented. The current findings on seed oil bodies could be extended to the intracellular storage lipid particles present in diverse organisms.     

Identification of Three Novel Unique Proteins in Seed Oil Bodies of Sesame

Graduate Institute of Agricultural Biotechnology, National Chung-HsingUniversity, Taichung, Taiwan 40227, ROC Plant seeds store triacylglycerolsin discrete organelles called oil bodies. An oil body preservesa matrix of triacylglycerols surrounded by a monolayer of phospholipidsembedded with abundant structural proteins termed oleosins andprobably some uninvestigated minor proteins of higher molecularmass. Three polypeptides of 27, 37, and 39 kDa (temporarilydenominated as Sopl, Sop2, and Sop3) were regularly co-purifiedwith seed oil bodies of sesame. Comparison of amino acid compositionindicated that they were substantially less hydrophobic thanthe known oleosins, and thus should not be aggregated multimersof oleosins. The results of immuno-recognition to sesame proteinsextracted from subcellular fractions of mature seeds, varioustissues, and oil bodies purified from different stages of seedformation revealed that these three polypeptides were uniqueproteins gathered in oil bodies, accompanying oleosins and triacylglycerols,during the active assembly of the organelles in maturing seeds.Both in vivo and in intro, immunofluorescence labeling usingsecondary antibodies conjugated with FITC (fluorescein isothiocyanate)confirmed the localization of these three polypeptides in oilbodies. ¹To whom correspondence should be addressed     

Lipids,Proteins, and Structure of Seed Oil Bodies from Diverse Species

Oil bodies isolated from the mature seeds of rape (Brassica napus L.), mustard (Brassica juncea L.), cotton (Gossypium hirsutum L.), flax (Linus usitatis simum), maize (Zea mays L.), peanut (Arachis hypogaea L.), and sesame (Sesamum indicum L.) had average diameters that were different but within a narrow range (0.6-2.0 [mu]m), as measured from electron micrographs of serial sections. Their contents of triacylglycerols (TAG), phospholipids, and proteins (oleosins) were correlated with their sizes. The correlation fits a formula that describes a spherical particle surrounded by a shell of a monolayer of phospholipids embedded with oleosins. Oil bodies from the various species contained substantial amounts of the uncommon negatively charged phosphatidylserine and phosphatidylinositol, as well as small amounts of free fatty acids. These acidic lipids are assumed to interact with the basic amino acid residues of the oleosins on the surface of the phospholipid layer. Isoelectrofocusing revealed that the oil bodies from the various species had an isoelectric point of 5.7 to 6.6 and thus possessed a negatively charged surface at neutral pH. We conclude that seed oil bodies from diverse species are very similar in structure. In rapeseed during maturation, TAG and oleosins accumulated concomitantly. TAG-synthesizing acyltransferase activities appeared at an earlier stage and peaked during the active period of TAG accumulation. The concomitant accumulation of TAG and oleosins is similar to that reported earlier for maize and soybean, and the finding has an implication for the mode of oil body synthesis during seed maturation.     

Oleosin genes in maize kernels having diverse oil contents are constitutively expressed independent of oil contents

In seeds, the subcellular storage oil bodies have a matrix of oils (triacylglycerols) surrounded by a layer of phospholipids embedded with abundant structural proteins called oleosins. We used two maize (Zea mays L.) strains having diverse kernel (seed) oil contents to study the effects of varying the oil and oleosin contents on the structure of the oil bodies. Illinois High Oils (IHO, 15% w/w oils) and Illinois Low Oils (ILO, 0.5%) maize kernels were the products of breeding for diverse oil contents for about 100 generations. In both maize strains, although the genes for oil synthesis had apparently been modified drastically, the genes encoding oleosins appeared to be unaltered, as revealed by Southern blot analyses of the three oleosin genes and sodium dodecyl sulfate-polyacrylamide gel electrophoresis with immunoblotting of the oleosins. In addition, both strains contained the same three oleosin isoforms of a defined proportion, and both accumulated oils and oleosins coordinately. Oleosins in both strains were restricted to the oil bodies, as shown by analyses of the various subcellular fractions separated by sucrosedensity-gradient centrifugation. Electron microscopy of the embryos and the isolated organelles revealed that the oil bodies in IHO were larger and had a spherical shape, whereas those in ILO were smaller and had irregular shapes. We conclude that in seeds, oleosin genes are expressed independent of the oil contents, and the size and shape of the oil bodies are dictated by the ratio of oils to oleosins synthesized during seed maturation. The extensive breeding for diverse oil contents has not altered the apparent mechanism of oil-body synthesis and the occurrence of hetero-dimer or -multimer of oleosin isoforms on the oil bodies.Abbreviations IHO Illinois High Oils - ILO Illinois Low Oils This work was supported by a USDA NRICGP grant. We thank Dr. J.W. Dudley of the University of Illinois for the IHO and ILO maize kernels, and Dr. W. Thomson for discussion on the stereological method.     

Cloning and secondary structure analysis of caleosin, a unique calcium-binding protein in oil bodies of plant seeds

Plant seed oil bodies comprise a matrix of triacylglycerols surrounded by a monolayer of phospholipids embedded with abundant oleosins and some minor proteins. Three minor proteins, temporarily termed Sops 1-3, have been identified in sesame oil bodies. A cDNA sequence of Sop1 was obtained by PCR cloning using degenerate primers derived from two partial amino acid sequences, and subsequently confirmed via immunological recognition of its over-expressed protein in Escherichia coli. Alignment with four published homologous sequences suggests Sop1 as a putative calcium-binding protein. Immunological cross-recognition implies that this protein, tentatively named caleosin, exists in diverse seed oil bodies. Caleosin migrated faster in SDS-PAGE when incubated with Ca2+. A single copy of caleosin gene was found in sesame genome based on Southern hybridization. Northern hybridization revealed that both caleosin and oleosin genes were concurrently transcribed in maturing seeds where oil bodies are actively assembled. Hydropathy plot and secondary structure analysis suggest that caleosin comprises three structural domains, i.e., an N-terminal hydrophilic calcium-binding domain, a central hydrophobic anchoring domain, and a C-terminal hydrophilic phosphorylation domain. Compared with oleosin, a conserved proline knot-like motif is located in the central hydrophobic domain of caleosin and assumed to involve in protein assembly onto oil bodies.     

Oleosins prevent oil-body coalescence during seed imbibition as suggested by a low-temperature scanning electron microscope study of desiccation-tolerant and -sensitive oilseeds

In order to clarify further the physiological role of oleosins in seed development, we characterized the oil-body proteins of several oilseeds exhibiting a range of desiccation sensitivities from the recalcitrant (Theobroma cacao L., Quercus rubra L.), intermediate (Coffea arabica L., Azadirachta indica A. Juss.) and orthodox categories (Sterculia setigera Del., Brassica napus L.). The estimated ratio of putative oleosins to lipid in oil bodies of Q. rubra was less than 5% of the equivalent values for rapeseed oil bodies. No oleosin was detected in T. cacao oil bodies. In A. indica cotyledons, oil bodies contained very low amounts of putative oleosins. Oil bodies both from C. arabica and S. setigera exhibited a similar ratio of putative oleosins to lipid as found in rapeseed. In C. arabica seeds, the central domain of an oleosin was partially sequenced. Using a low temperature field-emission scanning electron microscope, the structural stability of oil bodies was investigated in seeds after drying, storage in cold conditions and rehydration. Despite the absence or relative dearth of oleosins in desiccation-sensitive, recalcitrant oilseeds, oil bodies remained relatively stable after slow or fast drying. In A. indica seeds exposed to a lethal cold storage treatment, no significant change in oil-body sizes was observed. In contrast, during imbibition of artificially dried seeds containing low amounts of putative oleosins, the oil bodies fused to form large droplets, resulting in the loss of cellular integrity. No damage to the oil bodies occurred in imbibed seeds of Q. rubra, C. arabica and S. setigera. Thus the rehydration phase appears to be detrimental to the stability of oil bodies when these are present in large amounts and are lacking oleosins. We therefore suggest that one of the functions of oleosins in oilseed development may be to stabilize oil bodies during seed imbibition prior to germination. Received: 22 April 1997 / Accepted: 5 June 1997     

Determination and analyses of the N-termini of oil-body proteins, steroleosin, caleosin and oleosin.

Seed oil bodies comprise a triacylglycerol matrix shielded by a monolayer of phospholipids and proteins. These surface proteins include an abundant structural protein, oleosin, and at least two minor protein classes termed caleosin and steroleosin. Two steroleosin isoforms (41 and 39 kDa), one caleosin (27 kDa), and two oleosin isoforms (17 and 15 kDa) have been identified in oil bodies isolated from sesame seeds. The signal peptides responsible for targeting of these proteins to oil bodies have not been experimentally determined. Hydropathy analyses indicate that the hydrophobic domain putatively responsible for oil-body anchoring is located in the N-terminal region of steroleosin, but in the central region of caleosin or oleosin. Direct amino acid sequencing showed that both steroleosin isoforms possessed a free methionine residue at their N-termini while caleosin and oleosin isoforms were N-terminally blocked. Mass spectrometry analyses revealed that N-termini of both caleosin and 17 kDa oleosin were acetylated after the removal of the first methionine. In addition, deamidation was observed at a glutamine residue in the N-terminal region of 17 kDa oleosin.     

Analysis of the Three Essential Constituents of Oil Bodies in Developing Sesame Seeds

Oil bodies of plant seeds contain a matrix of triacylglycerolssurrounded by a monolayer of phospholipids embedded with alkalineproteins termed oleosins. Triacylglycerols and two oleosin isoformsof 17 and 15 kDa were exclusively accumulated in oil bodiesof developing sesame seeds. During seed development, 17 kDaoleosin emerged later than 15 kDa oleosin, but it was subsequentlyfound to be the most abundant protein in mature oil bodies.Phosphotidylcholine, the major phospholipid in oil bodies, wasamassed in microsomes during the formation of oil bodies. Priorto the formation of these oil bodies, a few oil droplets ofsmaller size were observed both in vivo and in vitro. Theseoil droplets were unstable, presumably due to the lack of sterichindrance shielded by the oleosins. The temporary maintenanceof these droplets as small entities seemed to be achieved byphospholipids, presumably wrapped in ER. Oil bodies assembledin late developing stages possessed a higher ratio of oleosin17 kDa over oleosin 15 kDa and were utilized earlier duringgermination. It seems that the proportion of oleosin 17 kDaon the surface of oil bodies is related to the priority of theirutilization. (Received July 16, 1997; Accepted October 27, 1997)     

Characterization of oil bodies in jelly fig achenes.

Thin-layer chromatography analysis revealed that the contents stored in oil bodies isolated from jelly fig (Ficus awkeotsang Makino) achenes were mainly neutral lipids (>90% triacylglycerols and approximately 5% diacylglycerols). Fatty acids released from the neutral lipids of achene oil bodies were highly unsaturated (62.65% alpha-linolenic acid, 18.24% linoleic acid, and 10.62% oleic acid). The integrity of isolated oil bodies was presumably maintained via electronegative repulsion and steric hindrance provided by their surface proteins. Immunological cross-recognition using antibodies against sesame oil-body proteins indicated that two oleosin isoforms and one caleosin were present in these oil bodies. MALDI-MS analyses confirmed that the three full-length cDNA fragments obtained by PCR cloning from maturing achenes encoded the two jelly fig oleosin isoforms and one caleosin identified by immunological screening.     

Characterization of the charged components and their topology on the surface of plant seed oil bodies.

Oil bodies of plant seeds contain a triacylglycerol matrix surrounded by a monolayer of phospholipids embedded with alkaline proteins called oleosins. Oil bodies isolated from maize (Zea mays L.) in a medium of pH 7.2 maintained their entities but aggregated when the pH was lowered to 6.8 and 6.2. Aggregation did not lead to coalescence and was reversible with an elevation of the pH. Further decrease of the pH from 6.2 to 5.0 retarded the aggregation. Aggregation at pH 7.2 was induced with 2 mM CaCl2 or MgCl2 but not with NaCl. Aggregation at pH 6.8 was prevented by 10 microM sodium dodecyl sulfate but not with NaCl. We conclude that oil bodies have a negatively charged surface at pH 7.2 and an isoelectric point of about 6.0. This conclusion is supported by isoelectrofocusing results and by theoretical calculation of the positive charges in the oleosins and the negative charges in phosphatidylserine, phosphatidylinositol, and free fatty acids. Apparently, lowering of the pH from 7.2 to 6.2 protonates the histidine residues in the oleosins, and neutralizes the oil bodies. Further decrease of the pH to 5.0 likely protonates the free fatty acids and produces positively charged organelles. Similar charge properties were observed in the oil bodies isolated from rape, flax, and sesame seeds. An analysis of the oleosin secondary structures reveals an N-terminal amphipathic domain, a central hydrophobic anti-parallel beta-strand domain (not found in any other known protein), and a C-terminal amphipathic alpha-helical domain. In the two amphipathic domains, the positively charged residues are orientated toward the interior facing the negative charged lipids, whereas the negatively charged residues are exposed to the exterior. The negatively charged surface is a major factor in maintaining the oil bodies as stable individual entities.     

Expression and subcellular targeting of a soybean oleosin in transgenic rapeseed. Implications for the mechanism of oil-body formation in seeds

Two genomic clones, encoding isoforms A and B of the 24 kDa soybean oleosin and containing 5 kbp and 1 kbp, respectively, of promoter sequence, were inserted separately into rapeseed plants. T₂ seeds from five independent transgenic lines, three expressing isoform A and two expressing isoform B, each containing one or two copies of the transgene, were analysed in detail. In all five lines, the soybean transgenes exhibited the same patterns of mRNA and protein accumulation as the resident rapeseed oleosins, i.e. their expression was absolutely seed-specific and peaked at the mid-late stages of cotyledon development. The 24 kDa soybean oleosin was targeted to and stably integrated into oil bodies, despite the absence of a soybean partner isoform. The soybean protein accumulated in young embryos mainly as a 23 kDa polypeptide, whereas a 24 kDa protein predominated later in development. The ratio of rapeseed:soybean oleosin in the transgenic plants was about 5:1 to 6:1, as determined by SDS-PAGE and densitometry. Accumulation of these relatively high levels of soybean oleosin protein did not affect the amount of endogenous rapeseed oleosin. Immunoblotting studies showed that about 95% of the recombinant soybean 24 kDa oleosin (and the endogenous 19 kDa rapeseed oleosin) was targeted to oil bodies, with the remainder associated with the microsomal fraction. Sucrose density-gradient centrifugation showed that the oleosins were associated with a membrane fraction of buoyant density 1.10–1.14 g ml^?1, which partially overlapped with several endoplasmic reticulum (ER) markers. Unlike oleosins associated with oil bodies, none of the membrane-associated oleosins could be immunoprecipitated in the presence of protein A-Sepharose, indicating a possible conformational difference between the two pools of oleosin. Complementary electron microscopy-immunocytochemical studies of transgenic rapeseed revealed that all oil bodies examined could be labelled with both the soybean or rapeseed anti-oleosin antibodies, indicating that each oil body contained a mixed population of soybean and rapeseed oleosins. A small but significant proportion of both soybean and rapeseed oleosins was located on ER membranes in the vicinity of oil bodies, but none were detected on the bulk ER cisternae. This is the first report of apparent targeting of oleosins via ER to oil bodies in vivo and of possible associated conformational/ processing changes in the protein. Although oil-body formation per se can occur independently of oleosins, it is proposed that the relative net amounts of oleosin and oil accumulated during the course of seed development are a major determinant of oil-body size in desiccation-tolerant seeds.     

Oleosins in the gametophytes of Pinus and Brassica and their phylogenetic relationship with those in the sporophytes of various species

Oleosins, which are structural proteins on the surface of intracellular oil bodies, have been found in the sporophytic seeds of angiosperms. Here, we report an oleosin from the female gametophyte of gymnosperm Pinus ponderosa Laws, seed and another oleosin from the male gametophyte of Brassica napus L. With the pine seed gametophyte, we identified two putative oleosins of 15 and 10 kDa, which are similar to the oleosins in angiosperm seeds in terms of their presence in the oil bodies in massive quantity. The complete sequence of the cDNA encoding the gametophytic 15-kDa oleosin was obtained, and it has a predicted amino-acid sequence similar to those of oleosins in angiosperm sporophytic seeds. A Brassica napus pollen cDNA sequence, which was reported earlier, would encode an amino-acid sequence somewhat similar to those of seed oleosins. We tested if the dissimilarity signifies a substantially different oleosin in the Brassica male gametophyte or an analytic error. By direct sequencing of a polymerase chain reaction (PCR)-amplified fragment of genomic DNA, we obtained evidence showing that this reported dissimilarity is likely to have arisen from a sequencing error. Our predicted sequence of the Brassica pollen oleosin has all the structural characteristics of seed oleosins. A phylogenic tree of 20 oleosins, including those from sporophytic and gametophytic tissues of angiosperm and gymnosperm, was constructed based on their amino-acid sequences. We discuss the evolution of oleosins, and conclude that oleosins are ancient proteins with multiple lineages whose root cannot be determined at this time.Abbreviations PCR polymerase chain reaction - TAG triacylglycerols This work was supported by USDA grant 91-01439 (AHCH). We thank Dr. Mike Lassner of Calgene, Inc., (Davis, Calif., USA) for providing us with the unpublished jojoba oleosin amino acid sequence.     

Two distinct steroleosins are present in seed oil bodies.

In addition to oleosin isoforms, three minor proteins, Sop1, 2 and 3 are present in sesame oil bodies. Genes encoding Sop1 and Sop2, named caleosin and steroleosin for their calcium and sterol-binding capacity, respectively, have been cloned recently. Blast sequence analysis of the first 32 N-terminal residues revealed that Sop3 was presumably a steroleosin-like protein homologous to Sop2. A putative cDNA clone of Sop3 was obtained by PCR, and subsequently confirmed by immunological recognition with antibodies against its over-expressed protein in Escherichia coli. Although Sop2 and Sop3, tentatively named steroleosin-A and -B, were found homologous, they could not be cross-recognized immunologically. Sequence comparison showed that these two steroleosins possessed a conserved NADP+ binding subdomain but a diverse sterol-binding subdomain of different size. Both steroleosins were progressively accumulated in maturing seeds but with different cumulating patterns. Dehydrogenase activity detected in their expressed proteins indicated that steroleosin-B might comparably possess a broader sterol selectivity and higher NADP+ specificity than steroleosin-A. Immunological cross-recognition implies that steroleosin-B is present in seed oil bodies of diverse species. A structural model of an oil-body was drawn with all its known essential constituents, and secondary structure organizations of the three classes of oil-body proteins were compared.     

A unique caleosin in oil bodies of lily pollen

In view of the recent isolation of stable oil bodies as well as a unique oleosin from lily pollen, this study examined whether other minor proteins were present in this lipid-storage organelle. Immunological cross-recognition using antibodies against three minor oil-body proteins from sesame suggested that a putative caleosin was specifically detected in the oil-body fraction of pollen extract. A cDNA fragment encoding this putative pollen caleosin, obtained by PCR cloning, was confirmed by immunodetection and MALDI-MS analyses of the recombinant protein over-expressed in Escherichia coli and the native form. Caleosin in lily pollen oil bodies seemed to be a unique isoform distinct from that in lily seed oil bodies.     

甘蓝型油菜种子中油体的超微结构及蛋白质组分析

以甘蓝型油菜（Brassica napus L.）含油量较高的品种‘ZS11’、含油量中等的品种‘Westar’和‘Topas’以及含油量较低的品种‘ZS10’为实验材料,通过超微结构观察和统计,比较分析不同品种种子中油体形态、大小和数量的差异。研究结果显示,品种‘ZS11’种子子叶细胞油体排列致密,形态较小,大部分油体的直径低于1 μm;而在含油量中等或较低的品种中,种子子叶细胞油体排列均显疏松,其中‘Westar’和‘Topas’的油体较大,而‘ZS10’的油体大小不一。本研究还通过双向电泳分析进一步检测了‘Westar’和‘ZS11’种子中总蛋白和油体蛋白的差异表达情况。结果显示,‘Westar’和‘ZS11’种子总蛋白双向电泳图谱中,表达量具有2倍以上差异的蛋白质点共有57个;其中在‘Westar’中特异表达的种子总蛋白质点有24个,在‘ZS11’中有23个。在上述2个品种油体蛋白双向电泳图谱中,表达量具有2倍以上差异的蛋白质点共有52个,在品种‘Westar’中特异表达的有2个,‘ZS11’中有13个。表明不同含油量的油菜品种种子在油体的结构和蛋白组份上均存在差异。     

A novel role for oleosins in freezing tolerance of oilseeds in Arabidopsis thaliana

Oil bodies in seeds of higher plants are surrounded with oleosins. Here we demonstrate a novel role for oleosins in protecting oilseeds against freeze/thaw-induced damage of their cells. We detected four oleosins in oil bodies isolated from seeds of Arabidopsis thaliana , and designated them OLE1, OLE2, OLE3 and OLE4 in decreasing order of abundance in the seeds. For reverse genetics, we isolated oleosin-deficient mutants ( ole1 , ole2 , ole3 and ole4 ) and generated three double mutants ( ole1 ole2 , ole1 ole3 and ole2 ole3 ). Electron microscopy showed an inverse relationship between oil body sizes and total oleosin levels. The double mutant ole1 ole2 , which had the lowest levels of oleosins, had irregular enlarged oil-containing structures throughout the seed cells. Germination rates were positively associated with oleosin levels, suggesting that defects in germination are related to the expansion of oil bodies due to oleosin deficiency. We found that freezing followed by imbibition at 4°C abolished seed germination of single mutants ( ole1 , ole2 and ole3 ), which germinated normally without freezing treatment. The treatment accelerated the fusion of oil bodies and the abnormal-positioning and deformation of nuclei in ole1 seeds, which caused seed mortality. In contrast, ole1 seeds that had undergone freezing treatment germinated normally when incubated at 22°C instead of 4°C, because degradation of oils abolished the acceleration of fusion of oil bodies during imbibition. Taken together, our findings suggest that oleosins increase the viability of over-wintering oilseeds by preventing abnormal fusion of oil bodies during imbibition in the spring.     

An in vitro system to examine the effective phospholipids and structural domain for protein targeting to seed oil bodies.

An in vitro system was established to examine the targeting of proteins to maturing seed oil bodies. Oleosin, the most abundant structural protein, and caleosin, a newly identified minor constituent in seed oil bodies, were translated in a reticulocyte lysate system and simultaneously incubated with artificial oil emulsions composed of triacylglycerol and phospholipid. The results suggest that oil body proteins could spontaneously target to artificial oil emulsions in a co-translational mode. Incorporation of oleosin to artificial oil emulsions extensively protected a fragment of approximately 8 kDa from proteinase K digestion. In a competition experiment, in vitro translated caleosin and oleosin preferentially target to artificial oil emulsions instead of microsomal membranes. In oil emulsions with neutral phospholipids, relatively low protein targeting efficiency was observed. The targeting efficiency was substantially elevated when negatively charged phospholipids were supplemented to oil emulsions to mimic the native phospholipid composition of oil bodies. Mutated caleosin lacking various structural domains or subdomains was examined for its in vitro targeting efficiency. The results indicate that the subdomain comprising the proline knot motif is crucial for caleosin targeting to oil bodies. A model of direct targeting of oil-body proteins to maturing oil bodies is proposed.     

Purification and structural characterization of the central hydrophobic domain of oleosin

The oil bodies of rapeseeds contain a triacylglycerol matrix surrounded by a monolayer of phospholipids embedded with abundant structural alkaline proteins termed oleosins and some other minor proteins. Oleosins are unusual proteins because they contain a 70-80-residue uninterrupted nonpolar domain flanked by relatively polar C- and N-terminal domains. Although the hydrophilic N-terminal domain had been studied, the structural feature of the central hydrophobic domain remains unclear due to its high hydrophobicity. In the present study, we reported the generation, purification, and characterization of a 9-kDa central hydrophobic domain from rapeseed oleosin (19 kDa). The 9-kDa central hydrophobic domain was produced by selectively degrading the N and C termini with enzymes and then purifying the digest by SDS-PAGE and electroelution. We have also reconstituted the central domain into liposomes and synthetic oil bodies to determine the secondary structure of the domain using CD and Fourier transform infrared (FTIR) spectroscopy. The spectra obtained from CD and FTIR were analyzed with reference to structural information of the N-terminal domain and the full-length rapeseed oleosin. Both CD and FTIR analysis revealed that 50-63% of the domain was composed of beta-sheet structure. Detailed analysis of the FTIR spectra indicated that 80% of the beta-sheet structure, present in the central domain, was arranged in parallel to the intermolecular beta-sheet structure. Therefore, interactions between adjacent oleosin proteins would give rise to a stable beta-sheet structure that would extend around the surface of the seed oil bodies stabilizing them in emulsion systems. The strategies used in our present study are significant in that it could be generally used to study difficult proteins with different independent structural domains, especially with long hydrophobic domains.