Amplification of ribosomal DNA in Acheta. IV. The number of cistrons for 28S and 18S ribosomal RNA

Structural organization of Acheta rDNA. Evidence for differential amplification of soma and germ-line-specific rDNA sequences

Amplification is one of the mechanisms whereby the expression of genes can be specifically reinforced. Ribosomal gene amplification in amphibian and insect oocytes is a particularly well documented case. We studied heterogeneity, amplification and size of Acheta domesticus (insects; Orthoptera) ribosomal DNA and characteristics of male and female somatic or germ line rDNAs by analysis of genomic clones from a conventional and a microclone library. The length of the Acheta rDNA repeat unit (transcription unit and non-transcribed spacer (NTS] varied from 47 x 10(3) to 60 x 10(3) base-pairs, with highest variability within the NTS region. Deletions, fragment length heterogeneity and size variability in small steps of individual NTS segments are responsible for the observed size variation. The number of rDNA repeat units per haploid genome of Acheta was determined as 190(+/- 10%). The rDNA is amplified 14(+/- 10%)-fold in the oocyte, producing about 10,000 gene copies per cell. Our results show that the amplification mechanism does not favor individual fragments within the repeat unit. Thus, it can be concluded that amplification does not change the chromosomal characteristics of the rDNA pool. Two fragments specific for oocyte rDNA suggest that the rearrangements accompanying amplification are preferentially located in one distinct EcoRI fragment. Certain regions of Acheta rDNA contain cell-type-specific fragments: it was thus possible to characterize one purely male fragment and a second one specific for male and female soma but not for germ line rDNA. We show that Acheta rDNA reveals a combination of many features reported from different organisms and novel tissue-specific alterations on an extremely large repeat unit. The tissue-specific alterations indicate sexual and soma/germ line differentiation events that are derived by as yet unknown mechanisms.

The ribosomal DNA transcription unit of the house cricket, Acheta domesticus

A composite map representing a single ribosomal DNA repeat unit of the house cricket, Acheta domesticus, was constructed from overlapping cloned fragments. Sites in the repeat unit for nine restriction enzymes were mapped. R-loop mapping of sequences coding for 18 S and 28 S RNA demonstrates that the 58-kb ribosomal DNA repeat unit contains a novel-sized internal transcribed spacer of 8.4 kb. The existence of this large spacer was confirmed in genomic DNA, most if not all of the genomic repeat units containing such a spacer. A 15- to 17-kb ribosomal RNA precursor transcript is synthesized as predicted on the basis of the size of the internal transcribed spacer. The 5.8 S RNA gene is localized to a 1-kb sequence immediately 5' to the 28 S gene. The coding regions examined contain no intervening sequences analogous to those described within ribosomal DNA of other eukaryotes. Only 11% of the repeat unit codes for mature ribosomal RNA, while the remainder is nontranscribed (71%) and transcribed (18%) spacer DNA.

Length heterogeneity of amplified circular rDNA molecules in oocytes of the house cricket Acheta domesticus (Orthoptera: Gryllidae)

Amplification of the genes coding for rRNA occurs in the oocytes of a wide variety of organisms. The amplification process appears to be mediated through a rolling-circle mechanism. The approximate molecular weight of the smallest rDNA circles is equivalent to the estimated combined molecular weight of DNA which codes for a single ribosomal RNA precursor molecule and an associated non-transcribed spacer DNA sequence. RNA-DNA hybridization studies carried out on oocytes of the house cricket, Acheta domesticus, suggest that DNA coding for rRNA accounts for only a small fraction of the rDNA satellite, all of which is amplified in the oocyte. In order to test the possibility that the remainder of the amplified rDNA represents spacer and to determine whether a rolling-circle mechanism might also be involved in amplification in A. domesticus oocytes, rDNA was isolated from ovaries of A. domesticus and spread for electron microscopy. A large proportion of the rDNA isolated from ovaries is circular, while main-band DNA and rDNA prepared from other tissues demonstrates few if any circles. The mean size of the smallest rDNA circles is approximately 8 times longer than the length estimated for DNA which codes for 18S and 28 S rRNA. Denaturation mapping shows the rDNA circles to contain two major readily denaturing regions located about equidistant from one another on the circle. Each readily denaturing region accounts for 4--6% of the total DNA in the circle. The fact that only 12% of the average molecule is required to code for A. domesticus 18S and 28S rRNA is consistent with the hybridization data. Considerable size heterogeneity exists in the length of the smallest class of rDNA molecules. In the rDNA of other species such heterogeneity has been shown to reside in the non-transcribed spacer.

Visualization of ribosomal gene activity: silver stains proteins associated with rRNA transcribed from oocyte chromosomes

Cricket oocyte chromosomes were stained with silver at pachytene when certain chromosome regions are active in rDNA amplification and rRNA transcription. The silver preferentially stained the known locations of 18S + 28S ribosomal cistrons. Cytochemical tests revealed that the silver binds neither to the rDNA nor transcribed rRNA, but rather to proteins which rapidly associate with the freshly-transcribed rRNA. As rRNA transcription proceeds, the quantity of silver stainable proteins progressively increases. The silver procedure can be used to visualize gene activity at the rDNA sites with conventional light microscopy.

Frequencies of circular units of nucleolar DNA in oocytes of two insects, Acheta domesticus and dytiscus marginalis, and changes of nucleolar morphology during oogenesis

The organization of the extrachromosomal nucleolar material in oocytes of two insect species with different ovary types, the house cricket Acheta domesticus (panoistic ovary) and the water beetle Dytiscus marginalis (meroistic ovary), was studied with light and electron microscopic techniques. Stages early in oogenesis were compared with fully vitellogenic stages (mid-to-late diplotene). The arangement of the nucleolar material undergoes a marked change from a densely aggregated to a dispersed state. The latter was characterized by high transcriptional activity. In spread and positively stained preparations of isolated nucleolar material, a high frequency of small circular units of transcribed rDNA was observed and rings with small numbers (1--5) of pre-rRNA genes were predominant. The observations suggest that the 'extra DNA body' observed in early oogenic stages of both species represents a dense aggregate ofnumerous short circular units of nucleolar chromatin, with morphological subcomponents identifiable in ultrathin sections. These apparently remain in close association with the chromosomal nucleolar organizer(s). The observations further indicate that the individual small nucleolar subunit circles dissociate and are dispersed as actively transcribed rDNA units later in diplotene. The results are discussed in relation to principles of the ultrastructural organization of nucleoli in other cell types as well as in relation to possible mechanisms of gene amplification.

The three-dimensional organization of the amplified ribosomal DNA complex in Acheta

The major chromomere of pachytene chromosome 6 in the oocytes of Acheta (Orthoptera) is a region of amplification for ribosomal RNA cistrons (28 S and 18 S). This chromomere was isolated and studied with the scanning electron microscope. It has an outer shell that is smooth at early stages but divides into polygonal plates as indentations appear on its surface. These indentations increase in number as the DNA copies separate from each other and as the ribosomal RNA synthesis progresses. The vertices of the polygonal plates coincide with the positions at which the DNA copies reach the surface of the chromomere during their "puffing" process. The combined information gained from scanning and transmission electron microscopy, DNA measurements, DNA.RNA hybridization, and cytochemistry, leads to a three-dimensional picture of the organization of the amplified ribosomal DNA in its association with ribosomal RNA and protein.