Abstract
Paubrasilia echinata (brazilwood) is an endangered native tree from the Brazilian Atlantic Forest whose seeds tolerate maturation drying, but, unlike classic orthodox seeds, they quickly lose viability after shedding. This work analyzed the biochemical and ultrastructural changes during the maturation of brazilwood seeds, with particular attention to the cell walls and organization of the cellular components. The physiological seed maturity was accompanied by increased starch content and decreased soluble sugars. Arabinose increased considerably and was the predominant cell-wall sugar during maturation, suggesting a rise in arabinans that contribute to greater cell wall flexibility. This increase was consistent with the cell wall infolding observed in the hypocotyl axis and cotyledons during the maturation of brazilwood seeds. Ultrastructural analyses showed changes in the number and distribution of protein bodies and amyloplasts and the reorganization of lipid droplets into large drops or masses during seed desiccation. Our findings demonstrate that brazilwood seeds behave like other orthodox seeds during maturation, performing the cell wall and metabolic changes before the major decline in the seed water content. However, the high vacuolization and reorganization of lipid bodies observed at 65 DAA suggest that cell deterioration occurs to some extent at the end of the maturation period and could be responsible for reducing the longevity of the brazilwood dried seeds.
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Acknowledgements
This work is part of the Master’s Thesis of the Plant Biodiversity and Environment Program – Institute of Botany of T. B. Mescia, supported by a FAPESP fellowship (Proc. no. 02/11227-1). M. R. Braga is a CNPq research fellow.
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This work was supported by FAPESP (Grants 00/06422–4 and 05/04139–7).
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TM, RL, and EC obtained the experimental data. MB, CB, and RCR designed the study. RL, CB, RCR, and MB contributed to the final version of the manuscript.
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Mescia, T.B., Louro, R.P., Barbedo, C.J. et al. Changes in cell wall composition and ultrastructure related to desiccation during the seed maturation of Paubrasilia echinata (brazilwood). Protoplasma 259, 1255–1269 (2022). https://doi.org/10.1007/s00709-021-01731-0
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DOI: https://doi.org/10.1007/s00709-021-01731-0