Underreplication of satellite DNAs in polyploid ovarian tissue of Drosophila virilis

The satellite DNAs of Drosophila virilis have been examined in diploid and polyploid tissues by isopycnic ultracentrifugation and thermal denaturation experiments. Previous work has established that the satellite DNAs are under replicated in the polytene chromosomes of the salivary glands of D. virilis. The results of the present experiments demonstrate that this underreplication also takes place in the ovaries which contain nurse cells and follicle cells. These tissues are polyploid but do not show polytene chromosomes.     

Analysis of DNAs from two species of the virilis group of Drosophila and implications for satellite DNA evolution

The DNAs from two virilis group species of Drosophila, D. lummei and D. kanekoi, have been analyzed. D. lummei DNA has a major satellite which, on the basis of CsCl equilibrium centrifugation, thermal denaturation, renaturation and in situ hybridization is identical to D. virilis satellite I. D. kanekoi DNA has a major satellite at the same buoyant density in neutral CsCl gradients as satellite III of D. virilis. However, on the basis of alkaline CsCl gradients, the satellite contains a major and a minor component, neither one of which is identical to D. virilis satellite III. By in situ hybridization experiments, sequences complementary to the major component of the D. kanekoi satellite are detected in only some species and in a way not consistent with the phylogeny of the group. However, by filter hybridization experiments using nick-translated D. kanekoi satellite as well as D. lummei satellite I and D. virilis satellite III DNAs as probes, homologous sequences are detected in the DNAs of all virilis group species. Surprisingly, sequences homologous to these satellite DNAs are detected in DNAs from non-virilis group Drosophila species as well as from yeast, sea urchin, Xenopus and mouse.     

Changes in Chromosomal Localization of Heterochromatin-binding Proteins during the Cell Cycle in Drosophila

We examined the heterochromatic binding of GAGA factor and proliferation disrupter (Prod) proteins during the cell cycle in Drosophila melanogaster and sibling species. GAGA factor binding to the brown^Dominant AG-rich satellite sequence insertion was seen at metaphase, however, no binding of GAGA factor to AG-rich sequences was observed at interphase in polytene or diploid nuclei. Comparable mitosis-specific binding was found for Prod protein to its target satellite in pericentric heterochromatin. At interphase, these proteins bind numerous dispersed sites in euchromatin, indicating that they move from euchromatin to heterochromatin and back every cell cycle. The presence of Prod in heterochromatin for a longer portion of the cell cycle than GAGA factor suggests that they cycle between euchromatin and heterochromatin independently. We propose that movement of GAGA factor and Prod from high affinity sites in euchromatin occurs upon condensation of metaphase chromosomes. Upon decondensation, GAGA factor and Prod shift from low affinity sites within satellite DNA back to euchromatic sites as a self-assembly process.     

Studies of He-T DNA sequences in the pericentric regions of Drosophila chromosomes

He-T DNA is a complex set of repeated DNA sequences with sharply defined locations in the polytene chromosomes of Drosophila melanogaster. He-T sequences are found only in the chromocenter and in the terminal (telomere) band on each chromosome arm. Both of these regions appear to be heterochromatic and He-T sequences are never detected in the euchromatic arms of the chromosomes (Young et al. 1983). In the study reported here, in situ hybridization to metaphase chromosomes was used to study the association of He-T DNA with heterochromatic regions that are under-replicated in polytene chromosomes. Although the metaphase Y chromosome appears to be uniformly heterochromatic, He-T DNA hybridization is concentrated in the pericentric region of both normal and deleted Y chromosomes. He-T DNA hybridization is also concentrated in the pericentric regions of the autosomes. Much lower levels of He-T sequences were found in pericentric regions of normal X chromosomes; however compound X chromosomes, constructed by exchanges involving Y chromosomes, had large amounts of He-T DNA, presumably residual Y sequences. The apparent co-localization of He-T sequences with satellite DNAs in pericentric heterochromatin of metaphase chromosomes contrasts with the segregation of satellite DNA to alpha heterochromatin while He-T sequences hybridize to beta heterochromatin in polytene nuclei. This comparison suggests that satellite sequences do not exist as a single block within each chromosome but have interspersed regions of other sequences, including He-T DNA. If this is so, we assume that the satellite DNA blocks must associate during polytenization, leaving the interspersed sequences looped out to form beta heterochromatin. DNA from D. melanogaster has many restriction fragments with homology to He-T sequences. Some of these fragments are found only on the Y. Two of the repeated He-T family restriction fragments are found entirely on the short arm of the Y, predominantly in the pericentric region. Under conditions of moderate stringency, a subset of He-T DNA sequences cross-hybridizes with DNA from D. simulans and D. miranda. In each species, a large fraction of the cross-hybridizing sequences is on the Y chromosome.     

The distribution of satellite and main-band DNA components in the melanogaster species subgroup of Drosophila

Fractionation of total adult DNA of five of the seven species of the melanogaster species sub-group of Drosophila in actinomycin D and distamycin A caesium density gradients has revealed the presence of three main-band DNA components, common to all species, and ten satellite DNAs that are distributed between the species. Satellite DNAs are either unique to a species or common to two or more species. The abundance of a common satellite DNA varies between species. There is no simple relationship between the presence of a satellite DNA and a branch point of phylogenetic divergence; nevertheless the arrangement of the species in a phylogeny that is based on the numbers of satellites held in common accurately reflects the pattern of relationships between the same species based on differences in inversions of polytene chromosomes. The species can be similarly arranged according to the compositions of their mitochondrial DNAs. It is possible that the same basic set of sequences, each of low frequency, is common to all species with arbitrary or selected amplification of particular sequences to differing extents in individual species. The conservation of satellites in the group and the close parallel between the distributions of satellites and inversions between the species suggests that either the processes that operate to change both chromosomal phenomena are similarly time-dependent and occurring at relatively low rates or that their rates of change are restricted according to some undetermined functions of these aspects of the genome.     

Repetitive DNA sequences in Drosophila

The satellite DNAs of Drosophila melanogaster and D. virilis have been examined by isopycnic centrifugation, thermal denaturation, and in situ molecular hybridization. The satellites melt over a narrow temperature range, reassociate rapidly after denaturation, and separate into strands of differing buoyant density in alkaline CsCl. In D. virilis and D. melanogaster the satellites constitute respectively 41% and 8% of the DNA isolated from diploid tissue. The satellites make up only a minute fraction of the DNA isolated from polytene tissue. Complementary RNA synthesized in vitro from the largest satellite of D. virilis hybridized to the centromeric heterochromatin of mitotic chromosomes, although binding to the Y chromosome was low. The same cRNA hybridized primarily to the -heterochromatin in the chromocenter of salivary gland nuclei. The level of hybridization in diploid and polytene nuclei was similar, despite the great difference in total DNA content. The centrifugation and hybridization data imply that the -heterochromatin either does not replicate or replicates only slightly during polytenization. Similar but less extensive data are presented for D. melanogaster. — In D. melanogaster cRNA synthesized from total DNA hybridized to the entire chromocenter (- and -heterochromatin) and less intensely to many bands on the chromosome arms. The X chromosome was more heavily labeled than the autosomes. In D. virilis the X chromosome showed a similar preferential binding of cRNA copied from main peak sequences.—It is concluded that the majority of repetitive sequences in D. virilis and D. melanogaster are located in the - and -heterochromatin. Repetitive sequences constitute only a small percentage of the euchromatin, but they are widely distributed in the chromosomes. During polytenization the -heterochromatin probably does not replicate, but some or all of the repetitive sequences in the -heterochromatin and the euchromatin do replicate.     

Localization of <Emphasis Type="Italic">Dras1</Emphasis> gene in polytene chromosomes of sibling species of <Emphasis Type="Italic">Drosophila virilis</Emphasis> group

The Dras1 gene was mapped by in situ hybridization to polytene chromosomes of several sibling species of the Drosophila virilis group and their hybrids. A 1037-bp fragment of Dras1 gene from the D. virilis genome was used as the probe. The gene sequence was localized in the region of a 25 A-B disk in chromosome 2 (in accordance with the D. virilis polytene chromosome map (Gubenko and Evgen’ev, 1984).     

The distribution of sequences complementary to human satellite DNAs I,II and IV in the chromosomes of chimpanzee (Pan troglodytes), gorilla (Gorilla gorilla) and orang utan (Pongo pygmaeus)

Human satellite DNAs I, II and IV were transcribed to yield radioactive complementary RNAs (cRNAs). These cRNAs were hybridised to metaphase chromosomes of man, chimpanzee (Pan troglodytes), gorilla (Gorilla gorilla) and orang utan (Pongo pygmaeus). The results of this in situ hybridisation were analysed quantitatively and compared with accepted chromosome homologies based on Giemsa banding patterns. The cRNA to satellite II (cRNAII) did not hybridise to chimpanzee chromosomes, although its hybridisation to chromosomes of gorilla and orang utan yielded more autoradiograph grains than hybridisation to human chromosomes, and cRNAIV hybridised to many chromosomes of gorilla and chimpanzee but was almost entirely restricted to the Y chromosome in orang utan. Most sites of hybridisation were located on homologous chromosomes in all four species, but there were a number of sites which showed no correspondence between satellite DNA location and chromosome banding patterns, and others where a given chromosomal location hybridised with different cRNAs in each species. These results are in contrast to those found for many transcribed DNA sequences, where the same sequence is usually located at homologous chromosome sites in different species, and appear to cast doubt on many proposed models of satellite DNA function.     

Three euchromatic DNA sequences under-replicated in polytene chromosomes of Drosophila are localized in constrictions and ectopic fibers

We examined three regions of under-represented euchromatic DNA sequences (histone, Ubx, and 11 A), for their possible correlation with euchromatic constrictions in polytene chromosomes of Drosophila melanogaster. Cloned sequences were hybridized to filters and to chromosomes prepared for light microscopy. Under-represented sequences hybridized to DNA within constrictions and in ectopic fibers. In contrast, adjacent sequences that were fully endoreplicated in the Ubx and 11A regions in polytene cells hybridized to sites just adjacent to their respective constrictions. For one region (Ubx), sequences under-represented in salivary gland cells were fully endoreplicated in fat body cells. For this particular region, the morphology of the polytene chromosomes differs between these two cell types in that the specific constriction is absent at this region in fat body polytene chromosomes, thus strengthening the correlation between under-representation and chromosome constrictions. Although all three sequences are in regions that have been classified by others as intercalary heterochromatin, we detect no common functional or sequence organizational feature for these examples of under-represented DNA. We suggest that the lower efficiencies of the replication origins, or special regions of termination at these sites, are the primary cause of the under-replication, and that this under-replication is sufficient to confer the properties of intercalary heterochromatin.     

Reduced Rates of Sequence Evolution of Y-Linked Satellite DNA in Rumex (Polygonaceae)

One characteristic of sex chromosomes is the accumulation of a set of different types of repetitive DNA sequences in the Y chromosomes. However, little is known about how this occurs or about how the absence of recombination affects the subsequent evolutionary fate of the repetitive sequences in the Y chromosome. Here we compare the evolutionary pathways leading to the appearance of three different families of satellite-DNA sequences within the genomes of Rumex acetosa and R. papillaris, two dioecious plant species with a complex XX/XY₁Y₂ sex-chromosome system. We have found that two of these families, one autosomic (the RAE730 family) and one Y-linked (the RAYSI family), arose independently from the ancestral duplication of the same 120-bp repeat unit. Conversely, a comparative analysis of the three satellite-DNA families reveals no evolutionary relationships between these two and the third, RAE180, also located in the Y chromosomes. However, we have demonstrated that, regardless of the mechanisms that gave rise to these families, satellite-DNA sequences have different evolutionary fates according to their location in different types of chromosomes. Specifically, those in the Y chromosomes have evolved at half the rate of those in the autosomes, our results supporting the hypothesis that satellite DNAs in nonrecombining Y chromosomes undergo lower rates of sequence evolution and homogenization than do satellite DNAs in autosomes.[Reviewing Editor: DR. Jerzy Jurka]     

Species-specific localization of DNA from pericentromeric heterochromatin on polytene chromosomes in the salivary gland cells and 3D-nuclear organization nurse cells in Drosophila virilis and Drosophila kanekoi (Diptera: Drosophilidae)

Microdissection of the chromocenter of D. virilis salivary gland polytene chromosomes has been carried out and the region-specific DNA library (DvirIII) has been obtained. FISH was used for DvirIII hybridization with salivary gland polytene chromosomes and ovarian nurse cells of D. virilis and D. kanekoi. Localization of DvirIII in the pericentromeric regions of chromosomes and in the telomeric region of chromosome 5 was observed in both species. Moreover, species specificity in the localization of DNA sequences of DvirIII in some chromosomal regions was detected. In order to study the three-dimensional organization of pericentromeric heterochromatin region of polytene chromosomes of ovarian nurse cells of D. virilis and D. kanekoi, 3S FISH DvirIII was performed with nurse cells of these species. As a result, species specificity in the distribution of DvirIII signals in the nuclear space was revealed. Namely, the signal was detected in the local chromocenter at one pole of the nucleus in D. virilis, while the signal from the telomeric region of chromosome 5 was detected on another pole. At the same time, DvirIII signals in D. kanekoi are localized in two separate areas in the nucleus: the first belongs to the pericentromeric region of chromosome 2 and another to pericentromeric regions of the remaining chromosomes.     

Analysis of the chromocenter DNA composition in polytene chromosomes of <Emphasis Type="Italic">Drosophila orena</Emphasis> ovarian nurse cells

Chromocenter DNA fragments of polytene chromosomes of Drosophila orena ovarian nurse cells were cloned from a region-specific library (Dore1) in a plasmid vector to yield 133 clones. A total of 76 clones were selected and sequenced. The total length of the sequenced fragments was 23940 bp. Analysis with several software packages revealed various repetitive sequences among the fragments of the Dore1 library, including mobile genetic elements (25 fragments homologous to various LTR retrotransposons, five fragments homologous to LINEs, three fragments homologous to Helitrons, one fragment homologous to Polinton, and one fragment homologous to the mini-me non-LTR retrotransposon), four minisatellites, a satellite (SAR_DM), the (TATATG)n simple sequence repeat, and a low-complexity T-rich repeat. Sequences homologous to protein-coding genes were also found in the Dore1 library. Various repetitive DNA sequences and gene homologs were identified as conserved sequences of pericentric heterochromatin of polytene chromosomes of ovarian nurse cells in nine species of the melanogaster species subgroup.     

A Yeast Artificial Chromosome Clone Map of the Drosophila Genome

We describe the mapping of 979 randomly selected large yeast artificial chromosome (YAC) clones of Drosophila DNA by in situ hybridization to polytene chromosomes. Eight hundred and fifty-five of the clones are euchromatic and have primary hybridization sites in the banded portions of the polytene chromosomes, whereas 124 are heterochromatic and label the chromocenter. The average euchromatic clone contains about 211 kb and, at its primary site, labels eight or nine contiguous polytene bands. Thus, the extent as well as chromosomal position of each clone has been determined. By direct band counts, we estimate our clones provide about 76% coverage of the euchromatin of the major autosomes, and 63% coverage of the X. When previously reported YAC mapping data are combined with ours, euchromatic coverage is extended to about 90% for the autosomes and 82% for the X. The distribution of gap sizes in our map and the coverage achieved are in good agreement with expectations based on the assumption of random coverage, indicating that euchromatic clones are essentially randomly distributed. However, certain gaps in coverage, including the entire fourth chromosome euchromatin, may be significant. Heterochromatic sequences are underrepresented among the YAC clones by two to three fold. This may result, at least in part, from underrepresentation of heterochromatic sequences in adult DNA (the source of most of the clones analyzed), or from clone instability.     

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.     

Comparative polytene chromosome maps of <Emphasis Type="Italic">D. montana</Emphasis> and <Emphasis Type="Italic">D. virilis</Emphasis>

Chromosomal inversion polymorphism was characterized in Finnish Drosophila montana populations. A total of 14 polymorphic inversions were observed in Finnish D. montana of which nine had not been described before. The number of polymorphic inversions in each chromosome was not significantly different from that expected, assuming equal chance of occurrence in the euchromatic genome. There was, however, no correlation between the number of polymorphic inversions and that of fixed inversions in each chromosome. Therefore, a simple neutral model does not explain the evolutionary dynamics of inversions. Furthermore, in contrast to results obtained by others, no significant correlation was found between the two transposable elements (TEs) Penelope and Ulysses and inversion breakpoints in D. montana. This result suggests that these TEs were not involved in the creation of the polymorphic inversions seen in D. montana. A comparative analysis of D. montana and Drosophila virilis polytene chromosomes 4 and 5 was performed with D. virilis bacteriophage P1 clones, thus completing the comparative studies of the two species.     

Cytological localization and organization of dispersed middle repetitive DNA sequences of Drosophila subobscura

To study the middle repetitive fraction of the Drosophila subobscura genome, 26 phage clones containing repetitive sequences were examined by Southern DNA blot analysis and by in situ hybridization to polytene chromosomes. These results led to a classification of the clones according to five different types of hybridization patterns. Two types, each containing seven clones, are characterized by hybridization at 100 to 300 sites dispersed over the euchromatic parts of the chromosomes, and in addition by one prominently labelled chromosome band. One of these two classes also showed strong labelling of the chromocentre. The remaining types of hybridization pattern lacked a prominent band but showed hybridization either to the euchromatic regions or to the chromocentre or both. Chromosome A (=X) was the preferred location of prominently labelled bands and it also showed an excess of labelling by some clones. Some of the cloned dispersed sequences were localized cytologically on chromosomes of larvae from crosses between different strains of D. subobscura and between two closely related species, in order to detect heterozygosity at hybridization sites. Comparisons of the chromosomal distribution of labelling sites showed differences in number and location, indicating the possibility of transposition events.     

Two AT-rich satellite DNAs in the chironomid Glyptotendipes barbipes (Staeger)

Two AT-rich satellite DNAs are present in the genome of Glyptotendipes barbipes. The two satellites have densities of 1.680 g/cm³ (=21% GC) and of 1.673 g/cm³ (=13% GC) in neutral CsCl-density gradients. The main band DNA has a density of 1.691 g/cm³ (=32% GC). This value is in agreement with the 33% GC-content of G. barbipes DNA calculated from thermal denaturation (T_M=83° C). — In brain DNA as well as in salivary gland DNA the two satellite sequences together comprise 12–15% of the total G. barbipes DNA. Comparisons of the density profiles of DNA extracted from polytene and non-polytene larval tissue gave no hints for underreplication of the satellite DNAs during polytenization. — The two satellite DNAs have been isolated from total DNA by Hoechst 33258-CsCl density centrifugation and then localized in the polytene salivary gland chromosomes by in situ hybridization. Both satellite sequences hybridize to all heterochromatic centromere bands of all four chromosomes of G. barbipes. Satellite I (1.673 g/cm³) hybridizes mainly with the middle of the heterochromatin, satellite II (1.680 g/cm³) hybridizes with two bands at the margin of the heterochromatin. In situ hybridization with polytene chromosomes of Chironomus thummi revealed the presence of G. barbipes satellite sequences also in the Ch. thummi genome at various locations, mainly the centromere regions.     

Heat-shock DNA homology in distantly related species of Drosophila

Polytene chromosomes of D. melanogaster and D. virilis were hybridized in situ with ¹²⁵I labeled mRNA isolated from polysomes of D. melanogaster tissue culture cells incubated at 37° C. ¹²⁵I mRNA hybridized preferentially with subdivisions 87A and 87Cl of the D. melanogaster 3R chromosome; grains were also observed at regions 93D, 95D and over the chromocenter. A considerable cross hybridization of this mRNA with D. virilis polytene chromosomes was observed. The 29C region of the D. virilis second chromosome was the main site of hybridization. Significant grain numbers also appeared in region 20F of the same chromosome. The two regions mentioned belong to heat shock loci in the latter species. Based on label intensity we conclude that region 29C of D. virilis contains DNA sequences retaining molecular homology with those at subdivisions 87A and 87Cl of D. melanogaster. SDS-polyacrylamide gel electrophoresis revealed similar distributions of heat shock proteins in the two species studied.     

Satellite DNA and speciation: A species specific satellite DNA of Drosophila guanchel

The heterochromatin of the chromosomes of Drosophila gunche consists mainly of a satellite DNA composed of multiple, tandemly arranged copies of a 290 b p basic sequence. Five clones containing one or two copies of the basic unit were sequenced. As expected from CsCl density centrifugation and AT specific staining of mitotic chromosomes the sequence is AT rich. The average nucleotid variability between the cloned sequences is 11.6%. In situ hybridization on the mitotic chromosomes revealed, that this satellite DNA is present in the centromeric regions of all chromosomes but the Y. The nucleotide variability between copies of different tandem clusters seems to be higher than between members of the same cluster. The copy number of the sequence in the haploid genome was estimated to be approximately 80000. The sequence is species specific and is not present in the genome of sibling species D. subobscura and D. madeiren-sis. The evolutionary origin of the satellite DNA and its possible role in species formation is discussed.