Lipid-rich tapetosomes in Brassica tapetum are composed of oleosin-coated oil droplets and vesicles, both assembled in and then detached from the endoplasmic reticulum

Tapetosomes are abundant organelles in tapetum cells of floral anthers in Brassicaceae species. They contain triacylglycerols (TAGs), the amphipathic protein oleosins and putative vesicles and play a predominant role in pollen-coat formation. Here we report the biogenesis and structures of tapetosomes in Brassica. Immunofluorescence confocal microscopy revealed that during early anther development, the endoplasmic reticulum (ER) luminal protein calreticulin existed as a network in tapetum cells, which contained no oleosins. Subsequently, oleosins appeared together with calreticulin in the ER network, which possessed centers with a higher ratio of oleosin to calreticulin. Finally, the ER network largely disappeared, and solitary tapetosomes containing oleosins and calreticulin became abundant. Transmission electron microscopy also revealed a close association between a maturing tapetosome and numerous ER cisternae. Mature, solitary tapetosomes were isolated and found to contain oleosins, calreticulin and the ER luminal binding protein (BiP). Isolated tapetosomes were treated with sodium carbonate and subfractionated by centrifugation. Two morphologically distinct constituents were isolated: low-density oil droplets, which contained oleosins and TAGs, and relatively high-density cisternae-like vesicles, which possessed calreticulin and BiP. Thus, tapetosomes are composed of oleosin-coated oil droplets and vesicles, both of which are assembled in and then detached from the ER. The structure and biogenesis of tapetosomes are unique among eukaryotic organelles. After tapetum cells lyzed, oleosins but not calreticulin and BiP of tapetosomes were transferred to the pollen surface.     

Identification, subcellular localization, and developmental studies of oleosins in the anther of Brassica napus

mRNAs encoding putative oleosins have been detected in the tapetum of developing anthers in Brassica and Arabidopsis, but the authentic proteins have not been previously documented. Antibodies against a synthetic 15-residue polypeptide that represents a portion of the putative tapetum oleosins encoded by two cloned Brassica napus genes were raised. Using these antibodies for immunoblotting after SDS-PAGE of the sporophytic extracts of B. napus developing anthers, two oleosins of ～ 48 and 45 kDa were detected. These two oleosins were judged to be the putative oleosins encoded by cloned Brassica genes because of their identical N-terminal sequences. The two oleosins were present in the anthers only during the developmental stage when the tapetum cells were packed with organelles. A fraction of low-density organelles was isolated from the developing anthers by flotation centrifugation. The fraction contained plastoglobule-filled plastids and lipid-containing particles. The structures of these two isolated organelles were similar to those in situ in the tapetum cells. Of subcellular fractions of the anther homogenate, the two oleosins were present exclusively in the low-density organelle fraction. They were absent in the surface fractions of the developing microspores and the mature pollen, although fragmented oleosin molecules were earlier reported to be present on the pollen. By immunocytochemistry, immunogold particles were found largely on the periphery of the plastoglobuli inside the plastids in the tapetum cells. The antibodies also detected oleosins on the surface of storage oil bodies inside the maturing microspores. Apparently, the gametophytic microspore oil-body oleosins share common epitopes at the generally non-conserved C-terminal domain with the sporophytic tapetum oleosins.     

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.     

Structural requirements of oleosin domains for subcellular targeting to the oil body.

We have investigated the protein domains responsible for the correct subcellular targeting of plant seed oleosins. We have attempted to study this targeting in vivo using "tagged" oleosins in transgenic plants. Different constructs were prepared lacking gene sequences encoding one of three structural domains of natural oleosins. Each was fused in frame to the Escherichia coli uid A gene encoding beta-glucuronidase (GUS). These constructs were introduced into Brassica napus using Agrobacterium-mediated transformation. GUS activity was measured in washed oil bodies and in the soluble protein fraction of the transgenic seeds. It was found that complete Arabidopsis oleosin-GUS fusions undergo correct subcellular targeting in transgenic Brassica seeds. Removal of the C-terminal domain of the Arabidopsis oleosin comprising the last 48 amino acids had no effect on overall subcellular targeting. In contrast, loss of the first 47 amino acids (N terminus) or amino acids 48 to 113 (which make up a lipophilic core) resulted in impaired targeting of the fusion protein to the oil bodies and greatly reduced accumulation of the fusion protein. Northern blotting revealed that this reduction is not due to differences in mRNA accumulation. Results from these measurements indicated that both the N-terminal and central oleosin domain are important for targeting to the oil body and show that there is a direct correlation between the inability to target to the oil body and protein stability.     

Tapetosomes in Brassica tapetum accumulate endoplasmic reticulum-derived flavonoids and alkanes for delivery to the pollen surface

Tapetosomes are abundant organelles in tapetum cells during the active stage of pollen maturation in Brassicaceae species. They possess endoplasmic reticulum (ER)-derived vesicles and oleosin-coated lipid droplets, but their overall composition and function have not been established. In situ localization analyses of developing Brassica napus anthers revealed flavonoids present exclusively in tapetum cells, first in an ER network along with flavonoid-3'-hydroxylase and then in ER-derived tapetosomes. Flavonoids were absent in the cytosol, elaioplasts, vacuoles, and nuclei. Subcellular fractionation of developing anthers localized both flavonoids and alkanes in tapetosomes. Subtapetosome fractionation localized flavonoids in ER-derived vesicles, and alkanes and oleosins in lipid droplets. After tapetum cell death, flavonoids, alkanes, and oleosins were located on mature pollen. In the Arabidopsis thaliana mutants tt12 and tt19 devoid of a flavonoid transporter, flavonoids were present in the cytosol in reduced amounts but absent in tapetosomes and were subsequently located on mature pollen. tt4, tt12, and tt19 pollen was more susceptible than wild-type pollen to UV-B irradiation on subsequent germination. Thus, tapetosomes accumulate ER-derived flavonoids, alkanes, and oleosins for discharge to the pollen surface upon cell death. This tapetosome-originated pollen coat protects the haploidic pollen from UV light damage and water loss and aids water uptake.     

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.     

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.     

Constituents of the tapetosomes and elaioplasts in Brassica campestris tapetum and their degradation and retention during microsporogenesis

In Brassica anthers during microsporogenesis, the tapetum cells contain two abundant lipid-rich organelles, the tapetosomes possessing oleosins and triacylglycerols (TAGs), and the elaioplasts having unique polypeptides and neutral esters. B. campestris, for its simplicity of possessing only the AA genome and one predominant oleosin of 45 kDa, was studied. In the developing anthers, the lipids and proteins of the tapetosomes and elaioplasts were concomitantly accumulated but selectively degraded or retained. Upon incubation of isolated tapetosomes in a pH-5 medium, the predominant 45 kDa oleosin underwent selective enzymatic proteolysis to a 37 kDa fragment, which was not further hydrolyzed upon prolonged incubation. The unreacted 45 kDa oleosin was retained in the organelles, whereas the 37 kDa fragment was released to the exterior. The fragment would become the predominant 37 kDa polypeptide in the pollen coat. Isolated tapetosomes did not undergo hydrolysis of the TAGs upon incubation in media of diverse pHs. An alkaline lipase in the soluble fraction of the anther extract was presumed to be the enzyme that would hydrolyze the tapetosome TAGs, which disappeared in the anthers during development. The tapetum elaioplasts contained several unique polypeptides of 31-36 kDa. The gene encoding a 32 kDa polypeptide was cloned, and its deduced amino acid sequence was homologous to those of two proteins known to be present on the surface of fibrils in chromoplasts. Upon incubation of isolated elaioplasts in media of diverse pHs, the organelle polypeptides were degraded completely and most rapidly at pH 5, whereas the neutral esters remained unchanged; these neutral esters would become the major lipid components of the pollen coat. The findings show that the constituents of the two major tapetum organelles underwent very different paths of degradation, or modification, and transfer to the pollen surface.     

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.     

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.     

Oleosin fusion expression systems for the production of recombinant proteins

For the production of recombinant proteins, product purification is potentially difficult and expensive. Plant oleosins are capable of anchoring onto the surface of natural or artificial oil bodies. The oleosin fusion expression systems allow products to be extracted with oil bodies. In vivo, oleosin fusions are produced and directly localized to natural oil bodies in transgenic plant seeds. Via the oleosin fusion technology the thrombin inhibitor hirudin has been successfully produced and commercially used in Canada. In vitro, artificial oil bodies have been used as “carriers” for the recombinant proteins expressed in transformed microbes. In this article, plant oleosins, strategies and limitations of the oleosin fusion expression systems are summarized, alongside with progress and applications. The oleosin fusion expression systems reveal an available way to produce recombinant biopharmaceuticals at large scale.     

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.     

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)     

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.     

Oleosin KD 18 on the surface of oil bodies in maize. Genomic and cDNA sequences and the deduced protein structure

Oleosins are newly discovered, abundant, and small Mr hydrophobic proteins localized on the surface of oil bodies in diverse seeds. So far, most of the studies have been on the general characteristics of the proteins, and only one protein (maize KD 16) has been studied using a cDNA clone containing an incomplete coding sequence. Here, we report the sequences of a genomic clone and a cDNA clone of a new maize oleosin (KD 18). There is no intron in the gene. The 5'-flanking region contains potential regulatory elements including RY repeats, CACA consensus, and CATC boxes, which are presumably involved in the specific expression of the proteins in maturing seeds. The deduced amino acid sequence was analyzed for secondary structures. We suggest that KD 18 of 187-amino acid residues contains three major structural domains: a largely hydrophilic domain at the N terminus, a hydrophobic hairpin alpha-helical domain at the center, and an amphipathic alpha-helix domain at the C terminus. These structural domains are very similar to those of oleosin KD 16. However, the KD 18 and KD 16 amino acid sequences as well as nucleotide sequences are highly similar only at the central domain (72 and 71%, respectively). The similarities are highest at the loop region of the alpha-helical hairpin. These results suggest that KD 18 and KD 16 are isoforms, encoded by genes derived from a common ancestor gene. We propose that the hairpin domain acts as an indispensible internal signal for intracellular trafficking of oleosins during protein synthesis as well as an anchor for oleosins on the oil bodies. The other two domains can undergo relatively massive amino acid substitutions without impairing the structure/function of the oleosins or have evolved to generate oleosins having different functions.     

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