Abstract
Morphological changes in the nuclear degeneration of the synergid (mainly the synergid that receives the pollen tube) and antipodal cells in Triticum aestivum were studied. Although located in the same embryo sac, and derived from the same megaspore, nuclear degeneration of the synergid and antipodal cells differs greatly. Nuclear degeneration in the synergid is characterized by pycnosis, i.e., total chromatin condensation, nuclear deformation and distinct shrinkage in volume, followed by the formation of an irregular and densely stained mass—the degenerated nucleus—while the nucleolus disappears prior to the degradation of chromatin. In contrast, in the nuclear degeneration of antipodal cells, chromatin is only partly condensed and the nuclear volume changes only slightly after the distinct chromatin condensation. Chromatolysis then occurs, i.e., stainable contents disappear while the nuclear envelope is retained. The nucleoli persist after the disappearance of the chromatin. The possible functions of nuclear degeneration of synergid and antipodal cells are discussed, especially with respect to the guidance of pollen tube growth and the proliferation of free-nuclear endosperm. The degeneration of synergids and antipodal cells in T. aestivum are distinct forms of programmed cell death, regarded as cytoplasmic cell death and nuclear degradation in advance of cell death, respectively.
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Acknowledgements
The Peking University Health Science Center (Beijing, P.R. China) provided excellent CLSM facilities and technical support. We thank Dr. Qun He for instruction in the use of Steedman’s wax, Prof. Shu-Jin Shen for correction in English writing and Dr. Cheng-Jun Ji for careful review of the manuscript.
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An, LH., You, RL. Studies on nuclear degeneration during programmed cell death of synergid and antipodal cells in Triticum aestivum. Sex Plant Reprod 17, 195–201 (2004). https://doi.org/10.1007/s00497-004-0220-1
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DOI: https://doi.org/10.1007/s00497-004-0220-1