Nucleolar transformation in plants grown on clinostats

Summary Cells of carrot calli (Daucus carota L.) grown on clinostats (simulated weightlessness) exhibit increases in nucleolar number and volume. In clinostat-grown whole barley plants (Hordeum vulgare L. cv. Steptoe), nucleoli in 70% of root meristem and root cortical cells in the 1 mm root apex exhibit multiple nodulations after one day of growth. The nucleolar nodules (1.1 m mean diameter) are densely and finely fibrous, distinctly different from the nucleolus in which the content is so compact that the granular component is masked. Control nucleoli (from vertically rotated and stationary seedlings) rarely exhibit nodule-like protrusions, are not compact, and contain a well defined granular component. Proteins that are heat soluble, characteristic of many stress responses, rapidly increase in barley grown on clinostats. Barley growth on clinostats is slowly and steadily inhibited. There is no difference between vertically rotated and stationary controls for any of the parameters measured, indicating that clinostat motion per se does not affect significantly barley development. The evidence taken together suggests that barley plants germinated and grown on clinostats are stressed, the effects of which are expressed sequentially by alteration of nucleolar morphology, increased production of heat-soluble proteins, and decreased plant growth. Similar stress-related changes may be expected to occur in plants subjected to weightlessness during space flight. It is therefore of interest that nucleoli in wheat roots (Triticum aestivum L. cv. Broom) obtained from the space flight IML-1 mission show irregularity that is not observed in any of the ground controls for the flight experiment.Abbreviations Act D actinomycin D - C clinostat rotation - EM electron microscopy - LM light microscopy - R vertical rotation - rDNA ribosomal DNA - S stationary