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

被引：113

作者：

Leprince O. ^{[1
,4
]}

Van Aelst A.C. ^{[2
]}

Pritchard H.W. ^{[3
]}

Murphy D.J. ^{[1
]}

机构：

[1] Department of Brussica Research, John Innes Centre, Colney

[2] Department of Plant Cytology, Agric. University of Wageningen, NL-6703 BD Wageningen

[3] Jodrell Laboratory, Royal Botanic Gardens Kew, Ardingly, West Sussex RH17 6TN, Wakehurst Place

[4] Department of Plant Physiology, Wageningen Agricultural University, NL-6703 BD Wageningen

来源：

Planta | 1997年 / 204卷 / 1期

关键词：

Desiccation sensitivity; Imbibition; Oil body; Oleosin; Recalcitrant seed; Seed storage;

D O I：

10.1007/s004250050236

中图分类号：

学科分类号：

摘要：

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 ill oilseed development may be to stabilize oil bodies during seed imbibition prior to germination.

引用

页码：109 / 119

页数：10

共 29 条

[1]

Barford N.M., Krog N., Buchheim W., Lipid-protein-emulsifier-water interactions in whippable emulsions, Food Proteins, pp. 144-158, (1989)

[2]

Berjak P., Farrant J.M., Pammenter N.W., The basis for recalcitrant seed behaviour: Cell biology of the homoiohydrous seed condition, Recent Advances in the Development and Germination of Seeds (NATO-ASI-Ser), pp. 89-108, (1989)

[3]

Cummins I., Hills M.J., Ross J.H.E., Hobbs D.H., Watson M.D., Murphy D.J., Differential temporal and spatial expression of genes involved in storage oil and oleosin accumulation in developing rapeseed embryos: Implications for the role of oleosins and the mechanisms of oil-body formation, Plant Mol Biol, 23, pp. 1015-1027, (1993)

[4]

Ellis R.H., Hong T.D., Roberts E.H., An intermediate category of seed storage behaviour? II Effects of provenance, immaturity, and imbibition on desiccation-tolerance in coffee, J Exp Bot, 42, pp. 653-1637, (1991)

[5]

Hamilton S., Hamilton R.J., Sewell P.A., Extraction of lipids and derivative formation, Lipid Analysis. A Practical Approach, pp. 13-64, (1992)

[6]

Huang A.H.C., Oil bodies and oleosins in seeds, Annu Rev Plant Physiol Plant Mol Biol, 43, pp. 177-200, (1992)

[7]

Huang A.H.C., Oleosins and oil bodies in seeds and other organs, Plant Physiol, 110, pp. 1055-1061, (1996)

[8]

International rules for seed testing, Seed Sci Technol, 13, pp. 356-513, (1985)

[9]

Kalinski A., Melroy D.L., Dwivedi R.S., Herman E.M., A soybean vacuolar protein P34 related to thiol proteases is synthesized as a glycoprotein precursor during seed maturation, J Biol Chem, 267, pp. 12068-12076, (1992)

[10]

Leprince O., Walters-Vertucci C., A calorimetric study of the glass transition behaviors in axes of bean seeds with relevance to storage stability, Plant Physiol, 109, pp. 1471-1481, (1995)

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