Summary
Microsporogenesis inSelaginella was studied by fluorescence light microscopy and transmission electron microscopy. As in other examples of monoplastidic meiosis the plastids are involved in determination of division polarity and organization of microtubules. However, there are important differences: (1) the meiotic spindle develops from a unique prophase microtubule system associated with two plastids rather than from a typical quadripolar microtubule system associated with four plastids; (2) the division axes for first and second meiotic division are established sequentially, whereas as in all other cases the poles of second division are established before those of first division; and (3) the plastids remain in close contact with the nucleus throughout meiotic prophase and provide clues to the early determination of spindle orientation. In early prophase the single plastid divides in the plane of the future division and the two daughter plastids rotate apart until they lie on opposite sides of the nucleus. The procytokinetic plate (PCP) forms in association with the two slender plastids; it consists of two spindle-shaped microtubule arrays focused on the plastid tips with a plate of vesicles at the equatorial region and a picket row of microtubules around one side of the nucleus. Second plastid division occurs just before metaphase and the daughter plastids remain together at the spindle poles during first meiotic division. The meiotic spindle develops from merger of the component arrays of the PCP and additional microtubules emanating from the pair of plastid tips located at the poles. After inframeiotic interphase the plastids migrate to tetrahedral arrangement where they serve as poles of second division.
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Abbreviations
- AMS:
-
axial microtubule system
- FITC:
-
fluorescein isothiocyanate
- MTOC:
-
microtubule organizing center
- PCP:
-
procytokinetic plate
- QMS:
-
quadripolar microtubule system
- TEM:
-
transmission electron microscope (microscopy)
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Brown, R.C., Lemmon, B.E. Plastid polarity and meiotic spindle development in microsporogenesis ofSelaginella . Protoplasma 161, 168–180 (1991). https://doi.org/10.1007/BF01322729
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DOI: https://doi.org/10.1007/BF01322729