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.     

Membrane topology and sequence requirements for oil body targeting of oleosin

Oleosin protein is targeted to oil bodies via the endoplasmic reticulum (ER) and consists of a lipid-submerged hydrophobic (H) domain that is flanked by cytosolic hydrophilic domains. We investigated the relationship between oleosin ER topology and its subsequent ability to target to oil bodies. Oleosin variants were created to yield differing ER membrane topologies and tagged with a reporter enzyme. Localisation was assessed by fractionation after transient expression in embryonic cells. Membrane-straddled topologies with N-terminal sequence in the ER lumen and C-terminal sequence in the cytosol were unable to target to oil bodies efficiently. Similarly, a translocated topology with only ER membrane and lumenal sequence was unable to target to oil bodies efficiently. Both topology variants accumulated proportionately higher in ER microsomal fractions, demonstrating a block in transferring from ER to oil bodies. The residual oil body accumulation for the inverted topology was shown to be because of partial adoption of native ER membrane topology, using a reporter variant, which becomes inactivated by ER-mediated glycosylation. In addition, the importance of H domain sequence for oil body targeting was assessed using variants that maintain native ER topology. The central proline knot motif (PKM) has previously been shown to be critical for oil body targeting, but here the arms of the H domain flanking this motif were shown to be interchangeable with only a moderate reduction in oil body targeting. We conclude that oil body targeting of oleosin depends on a specific ER membrane topology but does not require a specific sequence in the H domain flanking arms.     

Role of the proline knot motif in oleosin endoplasmic reticulum topology and oil body targeting.

An Arabidopsis oleosin was used as a model to study oleosin topology and targeting to oil bodies. Oleosin mRNA was in vitro translated with canine microsomes in a range of truncated forms. This allowed proteinase K mapping of the membrane topology. Oleosin maintains a conformation with a membrane-integrated hydrophobic domain flanked by N- and C-terminal domains located on the outer microsome surface. This is a unique membrane topology on the endoplasmic reticulum (ER). Three universally conserved proline residues within the "proline knot" motif of the oleosin hydrophobic domain were substituted by leucine residues. After in vitro translation, only minor differences in proteinase K protection could be observed. These differences were not apparent in soybean microsomes. No significant difference in incorporation efficiency on the ER was observed between the two oleosin forms. However, as an oleosin-beta-glucuronidase translational fusion, the proline knot variant failed to target to oil bodies in both transient embryo expression and in stably transformed seeds. Fractionation of transgenic embryos expressing oleosin-beta-glucuronidase fusions showed that the proline knot variant accumulated in the ER to similar levels compared with the native form. Therefore, the proline knot motif is not important for ER integration and the determination of topology but is required for oil body targeting. The loss of the proline knot results in an intrinsic instability in the oleosin polypeptide during trafficking.     

In vivo targeting of a sunflower oil body protein in yeast secretory (sec) mutants

A sunflower oleosin was expressed in yeast to study the in vivo insertion of the protein into the endoplasmic reticulum (ER) and subsequent transfer to lipid bodies. The oleosin cDNA was expressed in a range of yeast secretory (sec) mutants to determine the precise targeting pathway of the oleosin to the ER. Subcellular fractionation experiments indicated that the signal recognition particle (SRP) is required for oleosin targeting to the ER and hence subsequent deposition on the lipid bodies in vivo. The expression of oleosin in a range of sec61 mutant alleles confirmed the role of the SEC61 translocon in insertion of oleosin into the ER membrane, as well as indicating an unusual substrate/translocon interaction for one particular allele (sec61-3). Mistargeting of the oleosin due to impaired SRP function resulted in enhanced proteolysis of the plant protein in the transformed yeast, as determined by pulse-chase analysis. These data therefore provide the first in vivo evidence for the SRP-dependent targeting of the oleosin to the ER, and the subsequent requirement for a functional SEC61 translocon to mediate the correct insertion of the protein into the membrane.     

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)     

Targeting and membrane-insertion of a sunflower oleosin in vitro and in <Emphasis Type="Italic">Saccharomyces cerevisiae</Emphasis>: the central hydrophobic domain contains more than one signal sequence,and directs oleosin insertion into the endoplasmic reticulum membrane using a signal anchor sequence mechanism

A range of N- and C-terminal deletions of an oleosin from Helianthus annuus L. were used to study the endoplasmic reticulum (ER) targeting and membrane insertion of this protein both in vitro and in vivo in yeast ( Saccharomyces cerevisiae). Neither the N- nor the C-terminal hydrophilic domains are important for targeting and/or membrane insertion, with all the information required for these processes located within the central hydrophobic region of the protein. However, in vitro membrane-insertion experiments suggest that these domains are important for a correct topology of the oleosin within the ER membrane. The first half of the hydrophobic central domain, flanked by the positively charged N-terminal domain, is likely to function as a type-II signal-anchor (SAII) sequence. However, in the absence of the N-terminal 26 residues of this domain, the proline-knot region and the second half of this hydrophobic domain are sufficient to direct oleosin to the ER and to allow stable (but far less efficient) integration of the protein into the membrane. Taken together, these results indicate that oleosin contains more than one domain that is capable of interacting with the signal recognition particle to direct the protein to the ER membrane.     

Isoforms of soybean seed oil body membrane protein 24 kDa oleosin are encoded by closely related cDNAs

We have characterized two cDNA clones for 24 kDa soybean oleosin, the seed oil body membrane protein. Differences in the predicted amino acid sequences of the two clones and the presence of a doublet on immunoblots indicate that 24 kDa oleosin exists in at least two isoforms in soybean. The predicted amino acid sequence also contains a unique carboxy terminal region that is dominated by a series of different tandem amino acid repeats.     

Localization of seed oil body proteins in tobacco protoplasts reveals specific mechanisms of protein targeting to leaf lipid droplets

Oleosin, caleosin and steroleosin are normally expressed in developing seed cells and are targeted to oil bodies. In the present work, the cDNA of each gene tagged with fluorescent proteins was transiently expressed into tobacco protoplasts and the fluorescent patterns observed by confocal laser scanning microscopy. Our results indicated clear differences in the endocellular localization of the three proteins. Oleosin and caleosin both share a common structure consisting of a central hydrophobic domain flanked by two hydrophilic domains and were correctly targeted to lipid droplets (LD), whereas steroleosin, characterized by an N-terminal oil body anchoring domain, was mainly retained in the endoplasmic reticulum (ER). Protoplast fractionation on sucrose gradients indicated that both oleosin and caleosin-green fluorescent protein (GFP) peaked at different fractions than where steroleosin-GFP or the ER marker binding immunoglobulin protein (BiP), were recovered. Chemical analysis confirmed the presence of triacylglycerols in one of the fractions where oleosin-GFP was recovered. Finally, only oleosin- and caleosin-GFP were able to reconstitute artificial oil bodies in the presence of triacylglycerols and phospholipids. Taken together, our results pointed out for the first time that leaf LDs can be separated by the ER and both oleosin or caleosin are selectively targeted due to the existence of selective mechanisms controlling protein association with these organelles.     

Embryo-specific expression of soybean oleosin altered oil body morphogenesis and increased lipid content in transgenic rice seeds

Oleosin is the most abundant protein in the oil bodies of plant seeds, playing an important role in regulating oil body formation and lipid accumulation. To investigate whether lipid accumulation in transgenic rice seeds depends on the expression level of oleosin, we introduced two soybean oleosin genes encoding 24 kDa proteins into rice under the control of an embryo-specific rice promoter REG-2. Overexpression of soybean oleosin in transgenic rice leads to an increase of seed lipid content up to 36.93 and 46.06 % higher than that of the non-transgenic control, respectively, while the overall fatty acid profiles of triacylglycerols remained unchanged. The overexpression of soybean oleosin in transgenic rice seeds resulted in more numerous and smaller oil bodies compared with wild type, suggesting that an inverse relationship exists between oil body size and the total oleosin level. The increase in lipid content is accompanied by a reduction in the accumulation of total seed protein. Our results suggest that it is possible to increase rice seed oil content for food use and for use as a low-cost feedstock for biodiesel by overexpressing oleosin in rice seeds.     

The lipoxygenase-dependent oxygenation of lipid body membranes is promoted by a patatin-type phospholipase in cucumber cotyledons

Oilseed germination is characterized by the mobilization of storage lipids as a carbon and energy source for embryonic growth. In addition to storage lipid degradation in germinating oilseeds via the direct action of a triacylglycerol lipase (TGL) on the storage lipids, a second degradation pathway that is dependent on a specific lipid body trilinoleate 13-lipoxygenase (13-LOX) has been proposed in several plant species. The activity of this specific 13-LOX leads first to the formation of ester lipid hydroperoxides. These hydroperoxy fatty acids are then preferentially cleaved off by a TGL and serve as a substrate for glyoxysomal β-oxidation. As a prerequisite for triacylglycerol (TAG) mobilization, a partial degradation of the phospholipid monolayer and/or membrane proteins of the oil body has been discussed. Evidence has now been found for both processes: partial degradation of the proteins caleosin and oleosin was observed and simultaneously a patatin-like protein together with transient phospholipase (PLase) activity could be detected at the oil body membranes during germination. Moreover, in vitro experiments with isolated oil bodies from mature seeds revealed that the formation of 13-LOX-derived lipid peroxides in lipid body membranes is increased after incubation with the purified recombinant patatin-like protein. These experiments suggest that in vivo the degradation of storage lipids in cucumber cotyledons is promoted by the activity of a specific oil body PLase, which leads to an increased decomposition of the oil body membrane by the 13-LOX and thereby TAGs may be better accessible to LOX and TGL.     

The signal sequence receptor has a second subunit and is part of a translocation complex in the endoplasmic reticulum as probed by bifunctional reagents

Bifunctional cross-linking reagents were used to probe the protein environment in the ER membrane of the signal sequence receptor (SSR), a 24-kD integral membrane glycoprotein (Wiedmann, M., T. V. Kurzchalia, E. Hartmann, and T. A. Rapoport. 1987. Nature [Lond.]. 328:830-833). The proximity of several polypeptides was demonstrated. A 22-kD glycoprotein was identified tightly bound to the 34-kD SSR even after membrane solubilization. The 34-kD polypeptide, now termed alpha SSR, and the 22-kD polypeptide, the beta SSR, represent a heterodimer. We report on the sequence of the beta SSR, its membrane topology, and on the mechanism of its integration into the membrane. Cross-linking also produced dimers of the alpha-subunit of the SSR indicating that oligomers of the SSR exist in the ER membrane. Various bifunctional cross-linking reagents were used to study the relation to ER membrane proteins of nascent chains of preprolactin and beta-lactamase at different stages of their translocation through the membrane. The predominant cross-linked products obtained in high yields contained the alpha SSR, indicating in conjunction with previous results that it is a major membrane protein in the neighborhood of translocating nascent chains of secretory proteins. The results support the existence of a translocon, a translocation complex involving the SSR, which constitutes the specific site of protein translocation across the ER membrane.     

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.     

Stable oil bodies sheltered by a unique oleosin in lily pollen

Stable oil bodies were purified from mature lily (Lilium longiflorum Thunb.) pollen. The integrity of pollen oil bodies was maintained via electronegative repulsion and steric hindrance possibly provided by their surface proteins. Immunodetection revealed that a major protein of 18 kDa was exclusively present in pollen oil bodies and massively accumulated in late stages of pollen maturation. According to mass spectrometric analyses, this oil body protein possessed a tryptic fragment of 13 residues matching that of a theoretical rice oleosin. A complete cDNA fragment encoding this putative oleosin was obtained by PCR cloning with primers derived from its known 13-residue sequence. Sequence analysis as well as immunological non-cross-reactivity suggests that this pollen oleosin represents a distinct class in comparison with oleosins found in seed oil bodies and tapetum. In pollen cells observed by electron microscopy, oil bodies were presumably surrounded by tubular membrane structures, and encapsulated in the vacuoles after germination. It seems that pollen oil bodies are mobilized via a different route from that of glyoxysomal mobilization of seed oil bodies after germination.     

Dissociation of a 110-kD peripheral membrane protein from the Golgi apparatus is an early event in brefeldin A action

Brefeldin A (BFA) has a profound effect on the structure of the Golgi apparatus, causing Golgi proteins to redistribute into the ER minutes after drug treatment. Here we describe the dissociation of a 110-kD cytoplasmically oriented peripheral membrane protein (Allan, V. J., and T. E. Kreis. 1986. J. Cell Biol. 103:2229-2239) from the Golgi apparatus as an early event in BFA action, preceding other morphologic changes. In contrast, other peripheral membrane proteins of the Golgi apparatus were not released but followed Golgi membrane into the ER during BFA treatment. The 110-kD protein remained widely dispersed throughout the cytoplasm during drug treatment, but upon removal of BFA it reassociated with membranes during reformation of the Golgi apparatus. Although a 30-s exposure to the drug was sufficient to cause the redistribution of the 110-kD protein, removal of the drug after this short exposure resulted in the reassociation of the 110-kD protein and no change in Golgi structure. If cells were exposed to BFA for 1 min or more, however, a portion of the Golgi membrane was committed to move into and out of the ER after removal of the drug. ATP depletion also caused the reversible release of the 110-kD protein, but without Golgi membrane redistribution into the ER. These findings suggest that the interaction between the 110-kD protein and the Golgi apparatus is dynamic and can be perturbed by metabolic changes or the drug BFA.     

Guanine nucleotides modulate the effects of brefeldin A in semipermeable cells: regulation of the association of a 110-kD peripheral membrane protein with the Golgi apparatus

The release of a 110-kD peripheral membrane protein from the Golgi apparatus is an early event in brefeldin A (BFA) action, preceding the movement of Golgi membrane into the ER. ATP depletion also causes the reversible redistribution of the 110-kD protein from Golgi membrane into the cytosol, although no Golgi disassembly occurs. To further define the effects of BFA on the association of the 110-kD protein with the Golgi apparatus we have used filter perforation techniques to produce semipermeable cells. All previously observed effects of BFA, including the rapid redistribution of the 110-kD protein and the movement of Golgi membrane into the ER, could be reproduced in the semipermeable cells. The role of guanine nucleotides in this process was investigated using the nonhydrolyzable analogue of GTP, GTP gamma S. Pretreatment of semipermeable cells with GTP gamma S prevented the BFA-induced redistribution of the 110-kD protein from the Golgi apparatus and movement of Golgi membrane into the ER. GTP gamma S could also abrogate the observed release of the 110-kD protein from Golgi membranes which occurred in response to ATP depletion. Additionally, when the 110-kD protein had first been dissociated from Golgi membranes by ATP depletion, GTP gamma S could restore Golgi membrane association of the 110-kD protein, but not if BFA was present. All of these effects observed with GTP gamma S in semipermeable cells could be reproduced in intact cells treated with AlF4-. These results suggest that guanine nucleotides regulate the dynamic association/dissociation of the 110-kD protein with the Golgi apparatus and that BFA perturbs this process by interfering with the association of the 110-kD protein with the Golgi apparatus.     

Characterization and modelling of the hydrophobic domain of a sunflower oleosin

The oleosins are a group of hydrophobic proteins present on the surface of oil bodies in seeds, where they are thought to prevent coalescence. They contain a central hydrophobic domain of 68-74 residues that is thought to form a loop into the triacylglycerol matrix of the oil body, but the conformation adopted by this sequence is uncertain. We have therefore expressed an oleosin cDNA from sunflower (Helianthus annuus L.) in Escherichia coli as a fusion with maltose-binding protein (MBP) and isolated a peptide corresponding to the hydrophobic domain by sequential digestion with factor Xa (to remove the MBP) followed by trypsin and Staphylococcus V8 protease to remove the N- and C-terminal domains of the oleosin. Circular dichroism spectroscopy of the peptide in two solvent systems chosen to mimic the environment within the oil body (trifluoroethanol and SDS) demonstrated high proportions of alpha-helical structure, with no beta-sheet. A model was therefore developed in which the domain forms an alpha-helical hairpin structure, the two helices being separated by a turn region. We consider that this model is consistent with our current knowledge of oleosin structure and properties.     

Use of oil bodies and oleosins in recombinant protein production and other biotechnological applications

Oil bodies obtained from oilseeds have been exploited for a variety of applications in biotechnology in the recent past. These applications are based on their non-coalescing nature, ease of extraction and presence of unique membrane proteins—oleosins. In suspension, oil bodies exist as separate entities and, hence, they can serve as emulsifying agent for a wide variety of products, ranging from vaccines, food, cosmetics and personal care products. Oil bodies have found significant uses in the production and purification of recombinant proteins with specific applications. The desired protein can be targeted to oil bodies in oilseeds by affinity tag or by fusing it directly to the N or C terminal of oleosins. Upon targeting, the hydrophobic domain of oleosin embeds into the TAG matrix of oil body, whereas the protein fused with N and/or C termini is exposed on the oil body surface, where it acquires correct confirmation spontaneously. Oil bodies with the attached foreign protein can be separated easily from other cellular components. They can be used directly or the protein can be cleaved from the fusion. The desired protein can be a pharmaceutically important polypeptide (e.g. hirudin, insulin and epidermal growth factor), a neutraceutical polypeptide (somatotropin), a commercially important enzyme (e.g. xylanase), a protein important for improvement of crops (e.g. chitinase) or a multimeric protein. These applications can further be widened as oil bodies can also be made artificially and oleosin gene can be expressed in bacterial systems. Thus, a protein fused to oleosin can be expressed in Escherichia coli and after cell lysis it can be incorporated into artificial oil bodies, thereby facilitating the extraction and purification of the desired protein. Artificial oil bodies can also be used for encapsulation of probiotics. The manipulation of oleosin gene for the expression of polyoleosins has further expanded the arena of the applications of oil bodies in biotechnology.     

The signal recognition particle receptor is a complex that contains two distinct polypeptide chains

Signal recognition particle (SRP) and SRP receptor are known to be essential components of the cellular machinery that targets nascent secretory proteins to the endoplasmic reticulum (ER) membrane. Here we report that the SRP receptor contains, in addition to the previously identified and sequenced 69-kD polypeptide (alpha-subunit, SR alpha), a 30-kD beta-subunit (SR beta). When SRP receptor was purified by SRP-Sepharose affinity chromatography, we observed the co-purification of two other ER membrane proteins. Both proteins are approximately 30 kD in size and are immunologically distinct from each other, as well as from SR alpha and SRP proteins. One of the 30-kD proteins (SR beta) forms a tight complex with SR alpha in detergent solution that is stable to high salt and can be immunoprecipitated with antibodies to either SR alpha or SR beta. Both subunits are present in the ER membrane in equimolar amounts and co-fractionate in constant stoichiometry when rough and smooth liver microsomes are separated on sucrose gradients. We therefore conclude that SR beta is an integral component of SRP receptor. The presence of SR beta was previously masked by proteolytic breakdown products of SR alpha observed by others and by the presence of another 30-kD ER membrane protein (mp30) which co-purifies with SR alpha. Mp30 binds to SRP-Sepharose directly and is present in the ER membrane in several-fold molar excess of SR alpha and SR beta. The affinity of mp30 for SRP suggests that it may serve a yet unknown function in protein translocation.