The role of fractures and lipids in the seed coat in the loss of hardseededness of six Mediterranean legume species

L. W. ZENG; P. S. COCKS; S. G. KAILIS; J. KUO

doi:10.1017/S0021859605005034

Abstract

Changes in the seed coat morphology of 12 annual legumes were studied using environmental scanning electron microscopy (ESEM). The seeds of Biserrula pelecinus L. cv. Casbah, Ornithopus sativus cv. Cadiz, Trifolium clypeatum L., T. spumosum L., T. subterraneum L. cv. Bacchus Marsh, Trigonella balansae Boiss. & Reuter., Trigonella monspeliaca L. and Vicia sativa subsp. amphicarpa Dorthes (morthes.) were examined by ESEM after exposure to field conditions for 6 months, while those of Medicago polymorpha L. cv. Circle Valley, Trifolium clypeatum L., T. glanduliferum Boiss., T. lappaceum L., T. spumosum L., and T. subterraneum L. cv. Dalkeith, were examined after 2 years' exposure. The entry of water into seeds was followed by covering various parts of the seed coat with petroleum jelly and soaking the treated seeds in dyes.

As the seeds softened over time, more and larger fractures appeared on the seed coat. Water entered the seed either through fractures, over the seed coat as a whole or through the lens. It is hypothesized that the formation of fractures occurs after physicochemical changes in the seed coat, probably associated with changes in the amount and nature of seed coat lipids.

The newly matured whole seeds of M. polymorpha cv. Circle Valley, T. clypeatum, T. glanduliferum, T. lappaceum, T. spumosum, and T. subterraneum cv. Dalkeith were analysed for lipid content in 1997. The seed coats of T. subterraneum cv. Dalkeith and T. spumosum were separated from the cotyledons and examined in detail for lipid content.

The lipid content of whole seeds ranged from 48 (T. lappaceum) to 167 mg/g (T. subterraneum cv. Dalkeith). Total lipid of the whole seeds of T. subterraneum cv. Dalkeith and T. glanduliferum declined by about 9 mg/g over 2 years, while in T. spumosum it declined by about 17 mg/g.

In contrast, the major fatty acids in the seed coat declined by 0·67 mg/g over the 2 years. Change in seed coat lipids showed a marked similarity to changes in hardseededness for both T. subterraneum cv. Dalkeith and T. spumosum. The results strongly suggest that seed softening is associated with loss of lipids in the seed coat, because lipids have physical characteristics that are altered at temperatures experienced in the field.

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Ross, K.A. Arntfield, S.D. Beta, T. Cenkowski, S. and Fulcher, R.G. 2008. Understanding and Modifying Water Uptake of Seed Coats Through Characterizing the Glass Transition. International Journal of Food Properties, Vol. 11, Issue. 3, p. 544.

Aslam, M. N. Kailis, S. Nelson, M. N. Bayliss, K. L. and Cowling, W. A. 2008. Variation in fatty acid composition among genetically homogeneous seeds of canola (Brassica napus), and implications for genotypic selection based on single seeds. Australian Journal of Agricultural Research, Vol. 59, Issue. 10, p. 926.

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Ross, Kelly A. Zhang, Lei and Arntfield, Susan D. 2010. Understanding Water Uptake from the Induced Changes Occurred During Processing: Chemistry of Pinto and Navy Bean Seed Coats. International Journal of Food Properties, Vol. 13, Issue. 3, p. 631.

An, D. Arntfield, S.D. Beta, T. and Cenkowski, S. 2010. Hydration properties of different varieties of Canadian field peas (Pisum sativum) from different locations. Food Research International, Vol. 43, Issue. 2, p. 520.

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Gama-Arachchige, N. S. Baskin, J. M. Geneve, R. L. and Baskin, C. C. 2013. Quantitative analysis of the thermal requirements for stepwise physical dormancy-break in seeds of the winter annual Geranium carolinianum (Geraniaceae). Annals of Botany, Vol. 111, Issue. 5, p. 849.

Tiryaki, Iskender and Topu, Mustafa 2014. A Novel Method to Overcome Coat-Imposed Seed Dormancy in Lupinus albus L. and Trifolium pratense L.. Journal of Botany, Vol. 2014, Issue. , p. 1.

Anjum, Naser A. Singh, Neetu Singh, Manoj K. Sayeed, Iqbal Duarte, Armando C. Pereira, Eduarda and Ahmad, Iqbal 2014. Single-bilayer graphene oxide sheet impacts and underlying potential mechanism assessment in germinating faba bean (Vicia faba L.). Science of The Total Environment, Vol. 472, Issue. , p. 834.

2014. Seeds. p. 1075.

Kigel, Jaime Rosental, Leah and Fait, Aaron 2015. Grain Legumes. Vol. 10, Issue. , p. 327.

Hudson, Alice R. Ayre, David J. and Ooi, Mark K. J. 2015. Physical dormancy in a changing climate. Seed Science Research, Vol. 25, Issue. 2, p. 66.

Subbaraj, Arvind K. Barrett, Brent A. Wakelin, Steve A. and Fraser, Karl 2015. Using non-targeted direct analysis in real time-mass spectrometry (DART-MS) to discriminate seeds based on endogenous or exogenous chemicals. Analytical and Bioanalytical Chemistry, Vol. 407, Issue. 26, p. 8047.

Liyanage, Ganesha S. and Ooi, Mark K.J. 2017. Do dormancy-breaking temperature thresholds change as seeds age in the soil seed bank?. Seed Science Research, Vol. 27, Issue. 1, p. 1.

Koen, J. Slabbert, M.M. Bester, C. and Bierman, F. 2017. Germination characteristics of dimorphic honeybush (Cyclopia spp.) seed. South African Journal of Botany, Vol. 110, Issue. , p. 68.

Vaz, T. A. A. Rodrigues‐Junior, A. G. Davide, A. C. Nakamura, A. T. Toorop, P. E. and Bekker, R. 2018. A role for fruit structure in seed survival and germination of Swartzia langsdorffii Raddi beyond dispersal. Plant Biology, Vol. 20, Issue. 2, p. 263.

Geneve, Robert L. Baskin, Carol C. Baskin, Jerry M. Gehan Jayasuriya, K.M.G. and Gama-Arachchige, Nalin S. 2018. Functional morpho-anatomy of water-gap complexes in physically dormant seed. Seed Science Research, Vol. 28, Issue. 3, p. 186.

Silva Dias, Luís Pires Pereira, Isabel and Soveral Dias, Alexandra 2019. Seed Germination in Cistus ladanifer: Heat Shock, Physical Dormancy, Soil Temperatures and Significance to Natural Regeneration. Plants, Vol. 8, Issue. 3, p. 63.

Hatami, Mehrnaz Hosseini, Sayed Mohsen Ghorbanpour, Mansour and Kariman, Khalil 2019. Physiological and antioxidative responses to GO/PANI nanocomposite in intact and demucilaged seeds and young seedlings of Salvia mirzayanii. Chemosphere, Vol. 233, Issue. , p. 920.

Janská, Anna Pecková, Eva Sczepaniak, Bogna Smýkal, Petr and Soukup, Aleš 2019. The role of the testa during the establishment of physical dormancy in the pea seed. Annals of Botany, Vol. 123, Issue. 5, p. 815.

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The role of fractures and lipids in the seed coat in the loss of hardseededness of six Mediterranean legume species

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The role of fractures and lipids in the seed coat in the loss of hardseededness of six Mediterranean legume species

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