Control of DNA replication and spatial distribution of defined DNA sequences in salivary gland cells of Drosophila melanogaster

In dividing cells, each sequence replicates exactly once in each S-phase, but in cells with polytene chromosomes, some sequences may replicate more than once or fail to replicate during S-phase. Because of this differential replication, the control of replication in polytene cells must have some unusual features. Dennhöfer (1982a) has recently concluded that the total DNA content of the polytene cells of Drosophila salivary glands exactly doubles in each S-phase. This observation, along with previous studies demonstrating satellite underreplication in salivary gland cells, led us to consider the hypothesis that there is a doubling of DNA mechanism for the control of DNA replication in polytene cells. With this mechanism, a doubling of DNA content, rather than the replication of each sequence, would signal the end of a cycle of DNA replication. To test this hypothesis, we have reinvestigated the replication of several sequences (satellite, ribosomal, histone and telomere) in salivary gland cells using quantitative in situ hybridization. We find that underreplication of some sequences does occur. In addition we have repeated Dennhöfer's cytophotometric and labeling studies. In contrast to Dennhöfer, we find that the total DNA contents of nonreplicating nuclei do reflect this partial replication, in accord with Rudkin's (1969) result. We conclude that DNA replication in polytene cells is controlled by modifications of the mechanism operating in dividing cells, where control is sequence autonomous, and not by a doubling of DNA mechanism. — In situ hybridization to unbroken salivary gland nuclei reveals the distribution of specific sequences. As expected, satellite, histone and 5S sequences are usually in a single cluster. This rules out the possibility that sequences known to be underreplicated in chromosomal DNA exist as extrachromosomal copies. Telomere sequences are grouped into two to six clusters, as if the chromosome ends are partially but not completely paired in salivary gland nuclei.     

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.     

Synthesis and characterization of amplified DNA in oocytes of the house cricket,Acheta domesticus (Orthoptera: Gryllidae)

At a time in the life cycle when a large proportion of the oocytes of Acheta incorporate ³H-thymidine into an extrachromosomal DNA body, synthesis of a satellite or minor band DNA, the density of which is greater than main band DNA, is readily detected. Synthesis of the satellite DNA is not detectable in tissues, the cells of which do not have a DNA body, or in ovaries in which synthesis of extrachromosomal DNA by the oocytes is completed. The DNA body contains the amplified genes which code for ribosomal RNA. However, less than 1 percent of the satellite DNA, all of which appears to be amplified in the oocyte, is complementary to ribosomal 18S and 28S RNA. In situ hybridization demonstrates that non-ribosomal elements, like the ribosomal elements of the satellite DNA, are localized in the DNA body.Abbreviations used rRNA ribosomal RNA, includes 18S and 28S RNA - rDNA gene sequences complementary to rRNA - cRNA complementary RNA synthesized in vitro     

Cytologische Lokalisation von 5S und 18/25S RNA Genorten in Mitose-Chromosomen von Vicia faba

Homologous in situ hybridization with tritiated 4S, 5S and 18/25S RNA from root tip meristems of Vicia faba has been used to study the pattern of distribution of DNA sequences coding for these RNAs in the diploid nuclei. 5S RNA hybridizes to two regions of the satellites of the pair of satellited chromosomes. The sites differ in the level of in situ hybridization implicating different degrees of redundancy. 18/25S RNA hybridization is concentrated to the secondary constriction of these satellite chromosomes. Both, 5S and 18/25S ribosomal RNA gene sites are located on the same pair of chromosomes, but obviously the sequences are not contiguous. An association of 5S RNA cistrons with heterochromatin is assumed. Additional RNA gene sites as well as 4S RNA gene sites are not detectable.     

Histone gene expression during the cell cycle studied by in situ hybridisation

Cloned sea urchin histone gene DNA sequences have been in situ hybridized to histone RNA sequences in the cytoplasm of unsynchronized populations of Friend erythroleukemic cells, HeLa S3 and Chinese Hamster Ovary cells. S phase cells were detected by [³H]thymidine labelling of cell cultures prior to preparation for in situ hybridization. Autoradiography of the hybridized preparations has shown that in unsynchronized cells histone sequences are present in abundance in the cytoplasm of S phase cells only.     

Chromosome banding in Amphibia. XXIV. The B chromosomes of Gastrotheca espeletia (Anura,Hylidae)

The mitotic chromosomes of an Ecuadorian population of the marsupial frog Gastrotheca espeletia were analyzed by means of banding techniques and fluorescence in situ hybridization. This species is characterized by unusual supernumerary (B) chromosomes. The maximum number of B chromosomes is 9 and they occur in three different morphological types. Banding analyses show that the B chromosomes are completely heterochromatic, consist of AT base pair-rich repeated DNA sequences, replicate their DNA in very late S-phase of the cell cycle, and are probably derived from a centromeric or paracentromeric region of a standard (A) chromosome. Exceptionally, the B chromosomes carry 18S + 28S ribosomal RNA genes and the conserved vertebrate telomeric DNA sequence appears to be underrepresented. Flow cytometric measurements of the nuclear DNA content differentiate between individuals with different numbers of B chromosomes. Significantly more B chromosomes are present in female than in male animals.     

Differential localization of ribosomal proteins S14 and 7/8 in egg chambers of D. melanogaster

Summary The localization of Drosophila melanogaster ribosomal proteins S14, and 7/8 during oogenesis was studied by indirect immune fluorescence microscopy. The acidic proteins S14¹ and 7/8¹ were isolated from D. melanogaster embryonic ribosomal proteins by carboxymethylcellulose chromatography (Chooi 1980). Antibodies raised against each of these proteins were applied to ovariole squashes, and the position of each antibody was localized by fluorescein labeled sheep antirabbit IgGs. Anti-S14 was found predominantly in nurse cell nuclei, follicle cell nuclei, oocytes and, to a much lesser degree, in nurse cell and follicle cell cytoplasm. In contrast, anti-7/8 was found in major quantities in nurse cell and follicle cell cytoplasm, and oocytes. Anti-7/8 in the nurse cell and follicle cell nuclei was either not detectable or at a strikingly lower level than that found in the corresponding cytoplasm. The egg chamber patterns of localization of these two proteins were also found in salivary gland cells. However, in Drosophila tissue culture cells, these patterns were altered; both anti-S14 and anti-7/8 were detected only in the cytoplasm.     

Ultrastructural changes in nurse and follicle cells during late stages of oogenesis in Drosophila melanogaster

Summary During stages 11 and 12, follicle cells surrounding the nurse cells produce lysosomes which presumably aid in the breakdown of the nurse cells. Accompanying a DNA reduction in nurse cell nuclei are several characteristic morphological changes including the appearance of intranuclear rod-like structures and nuclear granules about 300 Å in diameter. Similarities between structures seen in Drosophila nurse cell nuclei and those seen in other organisms are discussed.This research was supported by U. S. Public Health Service Grants 5TIGM903-3 and 1-F1-GM-33, 385-01 and National Science Foundation grant GB-7457.     

Satellite DNA of Anopheles stephensi liston (Diptera: Culicidae)

Four satellite DNAs in the Anopheles stephensi genome have been defined on the basis of their banding properties in Hoechst 33258-CsCl density gradients. Two of these satellites, satellites I and II, are visible on neutral CsCl density gradients as a light density peak forming approximately 15% of total cellular DNA. Hoechst-CsCl density gradient profiles of DNA extracted from polytene tissues indicates that these satellites are underreplicated in larval salivary gland cells and adult female Malpighian tubules and possibly also in ovarian nurse cells. The chromosomal location of satellite I on mitotic and polytene chromosomes has been determined by in situ hybridisation. Sequences complementary to satellite I are present in approximately equal amounts on a heterochromatic arm of the X and Y chromosomes and are also present, in smaller amounts, at the centromere of chromosome 3. A quantitative analysis of the in situ hybridisation experiments indicates that sequences complementary to satellite I at these two sites differ in their replicative behaviour during polytenisation: heterosomal satellite I sequences are under-replicated relative to chromosome 3 sequences in polytene larval salivary gland and ovarian nurse cell nuclei.     

A molecular and cytogenetic survey of major repeated DNA sequences in tomato (Lycopersicon esculentum)

Summary The major families of repeated DNA sequences in the genome of tomato (Lycopersicon esculentum) were isolated from a sheared DNA library. One thousand clones, representing one million base pairs, or 0.15% of the genome, were surveyed for repeated DNA sequences by hybridization to total nuclear DNA. Four major repeat classes were identified and characterized with respect to copy number, chromosomal localization by in situ hybridization, and evolution in the family Solanaceae. The most highly repeated sequence, with approximately 77000 copies, consists of a 162 bp tandemly repeated satellite DNA. This repeat is clustered at or near the telomeres of most chromosomes and also at the centromeres and interstitial sites of a few chromosomes. Another family of tandemly repeated sequences consists of the genes coding for the 45 S ribosomal RNA. The 9.1 kb repeating unit in L. esculentum was estimated to be present in approximately 2300 copies. The single locus, previously mapped using restriction fragment length polymorphisms, was shown by in situ hybridization as a very intense signal at the end of chromosome 2. The third family of repeated sequences was interspersed throughout nearly all chromosomes with an average of 133 kb between elements. The total copy number in the genome is approximately 4200. The fourth class consists of another interspersed repeat showing clustering at or near the centromeres in several chromosomes. This repeat had a copy number of approximately 2100. Sequences homologous to the 45 S ribosomal DNA showed cross-hybridization to DNA from all solanaceous species examined including potato, Datura, Petunia, tobacco and pepper. In contrast, with the exception of one class of interspersed repeats which is present in potato, all other repetitive sequences appear to be limited to the crossing-range of tomato. These results, along with those from a companion paper (Zamir and Tanksley 1988), indicate that tomato possesses few highly repetitive DNA sequences and those that do exist are evolving at a rate higher than most other genomic sequences.     

Absence of ribosomal DNA amplification in the meroistic (telotrophic) ovary of the large milkweed bug Oncopeltus fasciatus (Dallas) (Hemiptera: Lygaeidae)

In the typical meroistic insect ovary, the oocyte nucleus synthesizes little if any RNA. Nurse cells or trophocytes actively synthesize ribosomes which are transported to and accumulated by the oocyte. In the telotrophic ovary a morphological separation exists, the nurse cells being localized at the apical end of each ovariole and communicating with the ooocytes via nutritive cords. In order to determine whether the genes coding for ribosomal RNA (rRNA) are amplified in the telotrophic ovary of the milkweed bug Oncopeltus fasciatus, the percentages of the genome coding for ribosomal RNA in somatic cells, spermatogenic cells, ovarian follicles, and nurse cells were compared. The oocytes and most of the nurse cells of O. fasciatus are uninucleolate. DNA hybridizing with ribosomal RNA is localized in a satellite DNA, the density of which is 1.712 g/cm(-3). The density of main-band DNA is 1.694 g/cm(-3). The ribosomal DNA satellite accounts for approximately 0.2% of the DNA in somatic and gametogenic tissues of both males and females. RNA-DNA hybridization analysis demonstrates that approximately 0.03% of the DNA in somatic tissues, testis, ovarian follicles, and isolated nurse cells hybridizes with ribosomal RNA. The fact that the percentage of DNA hybridizing with rRNA is the same in somatic and in male and female gametogenic tissues indicates that amplification of ribosomal DNA does not occur in nurse cells and that if it occurs in oocytes, it represents less than a 50-fold increase in ribosomal DNA. An increase in total genome DNA accounted by polyploidization appears to provide for increasing the amount of ribosomal DNA in the nurse cells.     

Mitochondrial development during Drosophila oogenesis: distribution,density and in situ RNA hybridizations

The changes in distribution and density of mitochondria and the level of mitochondrial RNA during Drosophila oogenesis were studied simultaneously in the 3 cell types ie follicle cells, nurse cells and oocyte, making up the egg chamber. Up to stage 6, mitochondrial density (mitochondrial and cellular areas ratio) was elevated and increased similarly in both follicle and nurse cells. Thereafter the mitochondrial density of follicle cells continued to increase and that of the nurse cells declined markedly while the nurse cell mitochondria assembled in dense groups and decreased in size. This can be related to a transfer of nurse cell cytoplasm, including mitochondria, to the oocyte. In the oocyte from stage 4 to stage 7 we observed a significant decrease of the mitochondrial density due to the absence of mitochondrial biogenesis. Then the cytoplasm transfer caused mitochondrial density to increase up to the level found in the nurse cells at the end of oogenesis. The mature oocyte contains enough mitochondria to supply 15 000 somatic cells. Our results strongly suggest that the variations in size, distribution and density of mitochondria relate to the particular energetic requirements of the different cell types during the first half of oogenesis. Later they relate to the developmental requirements of the nurse cells and the oocyte, in particular the storage of mitochondria in the oocyte. The level of mitochondrial RNA was studied through in situ hybridization. Throughout oogenesis the follicle and nurse cell RNA evolved similarly. Up to stage 9, there was no change in RNA densities in these cells, suggesting a correlation with the cell volume and/or the nuclear DNA content. Thereafter the cellular RNA concentration declined rapidly. In the oocyte the RNA concentration evolved differently especially from stage 10 to the end, the RNA density being stabilized. This can be related to the injection of nurse cell mitochondria, followed by their assignment to reserve status. Our results suggest that the mt RNA density is under extramitochondrial control mechanisms.     

Localisation of reiterated nucleotide sequences in Drosophila and mouse by in situ hybridisation of complementary RNA

The location of highly reiterated nucleotide sequences on the chromosomes has been studied by the technique of in situ hybridisation between the DNA of either Drosophila melanogaster salivary gland chromosomes or mouse chromosomes and tritium labelled complementary RNA (c-RNA) transcribed in vitro from appropriate templates with the aid of DNA dependent RNA polymerase extracted from Micrococcus lysodeikticus. The location of the hybrid material was identified by autoradiography after RNase treatment. — When Drosophila c-RNA, transcribed from whole DNA, was annealed with homologous salivary chromosomes in the presence of formamide the well defined labelling was confined to the chromocentre. With heat instead of formamide denaturation there was evidence of discontinuous labelling in various chromosome regions as well, apparently associated with banding. Xenopus ribosomal RNA showed no evidence of annealing to Drosophila chromosomes with the comparatively short exposure times used here. — When mouse satellite DNA was used as template the resulting c-RNA showed no hybridisation to Drosophila chromosomes but, when annealed with mouse chromosomes, the centromeric regions were intensely labelled. The interphase nuclei showed several distinct regions of high activity which suggested aggregation of centromeric regions of both homologous and non-homologous chromosomes. The results of annealing either c-RNA or labelled satellite DNA to homologous chromosomes were virtually indistinguishable. Incubation of Drosophila c-RNA with mouse chromosomes provided no evidence of localisation of grains. — It is inferred that both in mouse and Drosophila the centromeric regions of all chromosomes are enriched in highly reiterated sequences. This may be a general phenomenon and it might be tentatively suggested that the highly reiterated sequences play some role in promoting the close physical approximation of homologous and non-homologous chromosomes or chromosome regions to facilitate regulation of function.     

Number of the repetitive euchromatic 5S RNA genes in polyploid tissues of Drosophila hydei

Repetitive genes localized within heterochromatin, such as the rDNA in Drosophila, replicate several steps less than the bulk DNA during polytenization. The 5S RNA genes of Drosophila hydei were chosen as a model system to inquire whether underreplication also occurs if the repetitive gene cluster is localized in the euchromatin. Filter saturation hybridization showed that there are 320 5S RNA gene copies in the haploid genome. Setting the diploid number at 100%, it was found that the DNA of polytene salivary glands reached only 79% of this value, and the DNA of polyploid ovarian tissue reached only 72% of this value. Although the latter two saturation values are less than the diploid standard, they are not as low as the 50% saturation value predicted for a one-step reduction. This may reflect a slower replication of these genes compared to the bulk DNA. These results imply that underreplication is not a general characteristic of repetitive genes but depends on their localization in the euchromatic or heterochromatic part of the genome.