Summary
Neurons in cultures of central nervous tissue exhibited marked structural changes when exposed to hypertonic solutions. Cellular reactions were described in living neurons as well as after fixation and staining in preparations observed with both the light and electron microscope. The structures involved in these changes were mainly the nucleolus, the nucleus and the Nissl substance.
Nucleolus
In living neurons, observed with phase contrast optics, the nucleolus became invisible in hypertonic medium. This change occurred within a few seconds, and it was reversible when the cells were brought back to isotonic solutions. Fixation of the cells while exposed to hypertonic solution caused the nucleolus to reappear as a granular body. In stained preparations it appeared as a more irregular body in contrast to the smoothly outlined nucleolus in normal cells. In electron microscopic preparations of neurons which were fixed while exposed to hypertonic solutions the nucleolus was visible only as “nucleolar shadow”, overlaid by a few small irregular bodies of higher electron density than other nuclear contents.
Nucleus
The nuclear membrane of living neurons exposed to hypertonic media lost much of its sharp definition and became rather hazy in outline. The nuclear diameter increased about 10% in hypertonic medium, and the nuclear space became somewhat denser when observed with the phase contrast microscope. In Nissl stained preparations the nuclear space was filled with many small granular or rod-shaped bodies in contrast to the clear vesicular appearance of the nuclei of untreated cells. In electron microscopic preparations the nuclear space exhibited a spotty appearance due to the presence of electron dense and light areas.
Nissl Substance
In living neurons immersed in hypertonic solutions the Nissl substance showed a slight increase in phase density, especially after repeated changes between hypertonic and isotonic solutions. Sometimes a distinct striation in the Nissl substance appeared. In Nissl stained preparations there was no marked change observed in comparison with normal cells. However, in the electron microscope, the Nissl substance of hypertonically treated cells exhibited a marked structural change. The membrane-bound spaces of the endoplasmic reticulum assumed a rather precise orientation parallel to the cell membrane so that in extreme cases a concentric arrangement of endoplasmic cisternae was observed. The normal arrangement of ribosomal granules in rosettes and clusters became disturbed and the granules were more uniformly distributed.
The cells as whole units showed a distinct shrinkage in hypertonic solution which may account for the more crowded appearance of various organelles such as mitochondria and Golgi complexes. There was also a marked increase in agranular reticulum profiles and small membrane bound vesicles in treated cells. Vacuoles appeared frequently in the cytoplasm of treated cells; they disappeared upon re-immersion in isotonic medium.
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This investigation was supported by USPHS Grants NB 03114-04, NB 00690-11 and 5 T 1 GM 495 from the National Institutes of Health, Bethesda, Maryland.
Acknowledgement. Mrs. Eleanor W. Morris and Mr. Edwin E. Pitsinger, Jr. gave indispensible aid with the management of the cultures and with photographic procedures.
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Rennels, M.L., Hild, W. Morphological alterations in mammalian neurons in vitro in response to hypertonic solutions. Zeitschrift für Zellforschung 67, 620–635 (1965). https://doi.org/10.1007/BF00340328
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DOI: https://doi.org/10.1007/BF00340328