ABSTRACT
The immediate block of ribosome biosynthesis in heat-shocked tomato cell cultures is primarily caused by the complete inhibition of pre-rRNP processing. Depending on the heat-shock conditions synthesis of pre-rRNP goes on, though at a reduced level. Synthesis and/or preservation of pre-rRNP during heat shock as well as its efficient processing in the recovery period are thoroughly improved by preconditioning of cells to the hyperthermic treatment. Such preinduced cultures are characterized by their content of preformed heat-shock proteins, whose dominant representative (hsp 70) becomes highly enriched in the characteristic granular rRNP material observed in nucleoli of heat-shocked cells. This is shown by immune fluorescence staining and microautoradiography.
Subject(s)
Heat-Shock Proteins/biosynthesis , Hot Temperature , Plants/metabolism , RNA, Ribosomal/biosynthesis , Autoradiography , Cell Compartmentation , Cell Nucleolus/metabolism , Cells, Cultured , Electrophoresis/methods , ImmunochemistrySubject(s)
Chloroplasts , RNA, Ribosomal , Binding Sites , Chloroplasts/cytology , Drug Stability , Electrophoresis, Polyacrylamide Gel , Hot Temperature , Isotope Labeling , Magnesium , Molecular Weight , Nucleic Acid Conformation , Nucleic Acid Denaturation , Osmolar Concentration , Phosphorus Radioisotopes , Plants , Plants, Toxic , Ribosomes , Spectrophotometry , Spectrophotometry, Ultraviolet , Time Factors , NicotianaABSTRACT
The RNA of the blue-green alga Anacystis nidulans contains three ribosomal RNA species with molecular weights of 0.56x10(6), 0.9x10(6), and 1.1x10(6) if the RNA is extracted in the absence of Mg(2+). The 0.9x10(6)mol.wt. rRNA is extremely slowly labelled in (32)P-incorporation experiments. This rRNA may be a cleavage product of the 1.1x10(6)mol.wt. rRNA from the ribosomes of cells in certain physiological states (e.g. light-deficiency during growth). The cleavage of the 1.1x10(6)mol.wt. rRNA during the extraction procedure can be prevented by the addition of 10mm-MgCl(2). (32)P-pulse-labelling studies demonstrate the rapid synthesis of two ribosomal precursor RNA species. One precursor RNA migrating slightly slower than the 1.1x10(6)mol.wt. rRNA appears much less stable than the other precursor RNA, which shows the electrophoretic behaviour of the 0.7x10(6)mol.wt. rRNA. Our observations support the close relationship between bacteria and blue-green algae also with respect to rRNA maturation. The conversion of the ribosomal precursor RNA species into 0.56x10(6)- and 1.1x10(6)-mol.wt. rRNA species requires Mg(2+) in the incubation medium.