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An intermediate-voltage electron microscopic study of freeze-substituted generative cell in pear (Pyrus communis L.): features with relevance to cell-cell communication between the two cells of a germinating pollen

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Abstract

The ultrastructure of the generative cell (GC) wall complex in germinating pear (Pyrus communis L.) pollen was studied with the aim of identifying features that may shed light on the mechanism of uptake of substances by the GC from its host, the vegetative cell (VC). The techniques of rapid freeze-fixation and freeze-substitution, serial sectioning, and conventional and intermediate-voltage transmission electron microscopy were employed. The wall complex consisted of two plasma membranes (PMs), one derived from the GC and the other from the VC. A nonfibrillar wall material occurred in the space between the two PMs. Plasmodesmata could not be identified in this wall complex. However, in localized areas the wall complex formed processes that protruded into the VC cytoplasm. In other areas, the wall complex showed certain cup-shaped invaginations. Certain double membrane bound multivesicular bodies occurred in the GC cytoplasm; their morphological characteristics indicated that they may have been derived from the GC wall complex. The data indicate that in pear the GC surface is amplified by wall processes, presumably to perform a role analogous to transfer cells.

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  1. Department of Agronomy and Range Science, University of California, 276 Hunt Hall, 95616, Davis, CA, USA

    Suresh C. Tiwari

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  1. Suresh C. Tiwari
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Tiwari, S.C. An intermediate-voltage electron microscopic study of freeze-substituted generative cell in pear (Pyrus communis L.): features with relevance to cell-cell communication between the two cells of a germinating pollen. Sexual Plant Reprod 7, 177–186 (1994). https://doi.org/10.1007/BF00228491

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  • DOI: https://doi.org/10.1007/BF00228491

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