Summary
Four independent osmoregulatory mutants,osml, osm3,osm4, and osm7, were isolated on the basis of their requirement for growth medium of high osmotic strength. In normal low-osmoticstrength medium, in contrast to wild-type cells, the mutants grow poorly or not at all; in distilled water mutant cells are immobilized and eventually swell and burst. The mutants were examined by ordinary brightfield and phase-contrast microscopy, videomicroscopy, and electron microscopy. The four mutants showed different defects in the contractile vacuole (CV) cycle. Timing of various stages of the CV cycle showed thatosm1 was affected primarily in the early stage of the cycle when the CV begins to grow,osm3 primarily in midcycle when vacuoles fuse to form the CV proper,osm7 at a late stage of the cycle at docking and fusion of the CV with the plasma membrane, andosm4 during contraction of the CV. At the electron microscopic level, in dilute medium, mutant cells by comparison with wild-type cells had large autophagosomes, swollen mitochondria, and dilated ER cisternae. Although electron microscopy showed general abnormalities of the contractile vacuoles consistent with the videomicroscopic observations of living cells, no obvious vacuole membrane abnormalities were seen which would explain the mutational defects. The mutations help define the separate processes that contribute to the coordinated CV cycle inChlamydomonas, and open the way to eventual isolation of some of the genes responsible for CV function.
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Abbreviations
- CV:
-
contractile vacuole
- TAP:
-
Tris-acetate-phosphate medium
- TAP+L:
-
medium supplemented with lactose
- TAP+S:
-
medium supplemented with sucrose or other sugar
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Luykx, P., Hoppenrath, M. & Robinson, D.G. Osmoregulatory mutants that affect the function of the contractile vacuole inChlamydomonas reinhardtii . Protoplasma 200, 99–111 (1997). https://doi.org/10.1007/BF01280738
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DOI: https://doi.org/10.1007/BF01280738