Temporal order of replication of mouse ribosomal RNA genes during the cell cycle

The timing of replication of mouse ribosomal RNA (rRNA) genes was determined in cultured cells by using 5-bromodeoxyuridine labeling of DNA coupled with synchronization. Two subclasses of rRNA genes were characterized that differ in their temporal order of replication during S-phase. Approximately half of the rDNA repeat units replicated primarily during the first half of S-phase and the other 50% preferentially in the second half. This difference in replication timing was consistently observed for the approximately 400 rDNA repeat units of NIH3T3 fibroblasts, but not for plasmid DNA containing fragments of rRNA genes that had been stably transfected into the genome of these cells. The rDNA fragments inserted into these transfection vectors contained the recently mapped origin of bidirectional replication with or without amplification-promoting sequences, or none of the above. Since the plasmid DNA that was integrated into the host cell genome replicated randomly during S-phase we conclude that the integrated plasmid DNA is either replicated from a chromosomal origin in the neighborhood of its integration site or that inserts are replicated from their own origins and the timing of replication is determined by flanking sequences. Received: 7 July 1997; in revised form: 1 October 1997; Accepted: 1 October 1997     

Dosage of 5 S and ribosomal genes during oogenesis of Drosophila melanogaster

During growth, the Drosophila egg chamber increases its DNA content over a thousandfold, mainly by polyploidization of the nurse cell nuclei. We wanted to determine if 5 S and ribosomal genes are replicated to the same extent as the remaining DNA. Egg chambers were mass fractionated to represent different size classes and, therefore, different stages of oogenesis. Nucleic acids were extracted from each class of egg chambers, and after removal and quantitation of the RNA, the content of 5 S and ribosomal genes in the different DNA fractions was assayed by filter hybridization. Diploid DNA and DNA from polytene salivary gland cells served as references. It was concluded that: (1) Ribosomal genes become underreplicated as oogenesis proceeds, but to a much lower extent than in polytene chromosomes of salivary glands of the same organism. (2) By contrast, 5 S genes are equally replicated in egg chambers of all stages of oogenesis. (3) Notwithstanding the large increase in DNA content of egg chambers during oogenesis, the increase in total RNA content (mostly ribosomal RNA) is over 15 times as large.     

In vitro transcription of Drosophila ribosomal genes using Drosophila RNA polymerases

Drosophila RNA polymerases I &; II were used to transcribe a recombinant bacterial plasmid containing one copy of Drosophila ribosomal DNA. Both supercoiled and relaxed, closed circular plasmids were used. With Mg⁺² as the divalent cation, enzyme I is much more active on both forms of the plasmid; the relaxed form in particular supports almost no RNA synthesis by enzyme II. When Mn⁺² is present, differences in template efficiencies are minimal. The differences observed in the absence of Mn⁺² seem to depend only on different preferences for the physical state of the template and not on recognition of specific promotor sequences, since enzyme I shows no strand selection when transcribing these plasmids.     

Relationship between rates of synthesis and intracellular distribution of ribosomal proteins during oogenesis in the mouse

Ribosomal proteins are synthesized continuously in nonequimolar amounts during oogenesis in the mouse (M. J. LaMarca and P. M. Wassarman, 1979, Develop. Biol. 73, 103), even though ribosomal proteins are found in equimolar amounts in ribosomes. In this report, the distribution of newly synthesized ribosomal proteins between the cytoplasm and germinal vesicle (nucleus) of fully grown mouse oocytes has been examined. As compared to total newly synthesized protein, ribosomal proteins were found to be highly concentrated in the oocyte's germinal vesicle. Furthermore, an inverse relationship was found between rates of synthesis of individual ribosomal proteins and percentages of newly synthesized ribosomal proteins associated with germinal vesicles. As a result of this relationship, the amounts of newly synthesized ribosomal proteins associated with germinal vesicles approximated an equimolar situation. Even in the presence of actinomycin D, oocytes continued to synthesize ribosomal proteins which were found associated with germinal vesicles in amounts similar to those observed in the absence of the drug. These results suggest that, although synthesis of ribosomal proteins by mouse oocytes is not coordinately regulated, a post-translational mechanism exists for adjusting the stoichiometry of these proteins within the oocyte's germinal vesicle; this mechanism apparently is not dependent upon concomitant ribosomal-RNA synthesis.