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.     

Identical satellite DNA sequences in sibling species of Drosophila

The evolution of simple satellite DNAs was examined by DNA-DNA hybridization of ten Drosophila melanogaster satellite sequences to DNAs of the sibling species, Drosophila simulans and Drosophila erecta. Seven of these repeat types are present in tandem arrays in D. simulans and each of the ten sequences is repeated in D. erecta. In thermal melts, six of the seven satellite sequences in D. simulans and seven of the ten sequences in D. erecta melted within 1 deg.C of the corresponding values in D. melanogaster. The remaining sequences melted within 3 deg.C of the homologous hybrids. Therefore, there is little or no alteration in those satellite sequences held in common, despite a period of about ten million years since the divergence of D. melanogaster and D. simulans from a common ancestor. Simple satellite sequences appear to be more highly conserved than coding regions of the genome, on a per nucleotide basis. Since multiple copies of three satellite sequences could not be detected in D. simulans yet are present in D. erecta, a species more distantly related to D. melanogaster than is D. simulans, these sequences show discontinuities in evolution. There were major quantitative variations between species, showing that satellite DNAs are prone to massive amplification or diminution events over timespans as short as those separating sibling species. In D. melanogaster, these sequences amount to 21% of the genome but only 5% in D. simulans and 0.4% in D. erecta. There was a general trend of lower abundance with evolutionary distance for most satellites, suggesting that the amounts of different satellite sequences do not vary independently during evolution.     

FLP-mediated DNA mobilization to specific target sites in Drosophila chromosomes.

The ability to place a series of gene constructs at a specific site in the genome opens new possibilities for the experimental examination of gene expression and chromosomal position effects. We report that the FLP- FRT site-specific recombination system of the yeast 2mu plasmid can be used to integrate DNA at a chromosomal FRT target site in Drosophila. The technique we used was to first integrate an FRT- flanked gene by standard P element-mediated transformation. FLP was then used to excise the FRT- flanked donor DNA and screen for FLP-mediated re-integration at an FRT target at a different chromosome location. Such events were recovered from up to 5% of the crosses used to screen for mobilization and are easily detectable by altered linkage of a white reporter gene or by the generation of a white + gene upon integration.     

Localization of Drosophila nasutoides satellite DNAs in metaphase chromosomes

Metaphase chromosomes of D. nasutoides were hybridized situ with ³H-cRNA synthesized from the four satellites which make up 50–60% of the total DNA of this species. All four satellites were localized in the large, metacentric, heterochromatic chromosome four. They did not, however, appear to hybridize to centromeric or other constitutive heterochromatin, nor did they, with the exception of satellite I, seem to hybridize in the specific regions of chromosome four which, on the basis of C, Q, and H banding and AT contents, were predicted to contain some of these satellites. —Comparison of grain patterns with the results of fluorescent staining indicated that satellite-bearing heterochromatin was not always associated with other fractions of constitutive heterochromatin in interphase nuclei and was, at least partially, decondensed in some larger nuclei.     

Heterochromatic chromosomes and satellite DNAs of Drosophila nasutoides

Drosophila nasutoides is distinguished from other Drosophila species in that the metaphase karyotype shows a pair of very large V-shaped chromosomes. With Giemsa, a distinctive C-banding pattern is revealed along the arms of this large chromosome, indicating a largely heterochromatic nature. Furthermore, the banding patterns of the arms are symmetrical, indicating that it is an iso-chromosome. A comparison between the metaphase karyotype and polytene chromosomes suggests that the large V chromosome appears as the dot chromosome in polytene squash. One autosome has twice the arm length of typical Drosophila polytene chromosomes and arose either by centric fusion and a pericentric inversion, or by translocation connecting distal ends with a subsequent loss of one centromere. This chromosome appears to have a short arm which ectopically pairs with the proximal region of the long arm, representing a duplication of about ten bands. When the nuclear DNA is examined by neutral CsCl gradient, four satellites are observed. As much as sixty percent of the total DNA appears as satellites in the lysate of larval brains. No satellite was detectable in the lysate of salivary glands. These observations led us to suggest that the heterochromatic nature of the large V chromosome is due to the presence of all four satellites in this chromosome and that this large chromosome appears as the dot because of the under-reduplication of the satellites during polytenization.     

Gradual evolution of a specific satellite DNA family in Drosophila ambigua, D. tristis, and D. obscura

The highly repetitive satellite DNA family "ATOC180" is specific for the three closely related species Drosophila obscura, D. ambigua, and D. tristis but does not occur in their closest relatives D. subsilvestris and D. bifasciata. Approximately 10,000 copies/haploid genome of approximately 180-bp repetition units are tandemly arranged in the centromeric heterochromatin of all chromosomes of all three species. Molecular analysis of 29 cloned repeats shows much intra- and interspecific sequence homogeneity. Single nucleotide changes are the main source of variability and distinguish the sequence-, subfamily- and species-specific ATOC180 repeats from each other. Based on these nucleotide differences, phylogenetic dendrograms were constructed and compared with published trees for other traits. The data indicate that the sequences of the ATOC180 satellite DNA family probably arose in a phylogenetically "short period" during the anagenetic evolution of the common ancestor of D. obscura, D. tristis, and D. ambigua, as a consequence of a process of genome reorganization, followed by a "long period" of entirely gradual sequence evolution. For the latter period, an evolutionary rate of 3 x 10(-8) substitutions/site/year was calculated.      

Cloning and characterization of KM190, a specific satellite DNA family of Drosophila kitumensis and D. microlabis.

The nucleotide sequences of nine clones, pKA191/l-4 from Drosophila kitumensis and pMR.190/1–5 from D. microlabis, were determined. They represent a tandemly arranged and highly repetitive satellite DNA family, KM190, which is specific for the two species.     

A specific chromosome element,the telomere of Drosophila polytene chromosomes

The submicroscopic organization of terminal chromosome regions of Drosophila hydei polytene chromosomes is described. A compact region composed of tightly packed fibrils of 100 to 125 Å diameter embedded in an amorphous material is located at each of the chromosome ends of the 5 long chromosome arms. From this compact region, sometimes containing cavities, fibrils extend onto the nearest normal band region. The diameter of the extending fibrils is 100–125 Å, 200–250 Å or 400 Å. Pronase digestion of fixed and squashed chromosomes reduced the electron density of the amorphous matrix in the compact regions but failed to affect the diameter of the fibrils. The extending fibrils, however, showed a decrease in diameter after pronase digestion. The most frequently observed diameter values were 100–125 Å. — The volume of the terminal structures, including the compact region as well as the extending fibrils, is characteristically different for the various elements of the karyotype. Chromosome 2 displays the largest terminal structure, whereas chromosome 4 only occasionally shows the presence of compact regions. — End to end association of the long chromosome arms involves the fusion of the compact terminal structures. The non-random distribution of end to end association seems to be correlated with the volume of the terminal structures. Chromosome 2 which contains the largest compact terminal region is more frequently involved in end to end associations than any other chromosome arm. — The terminal regions show replication of DNA. They belong to the group of regions which display a discontinuous labeling pattern along the chromosomes, representing a late phase of the replication cycle. — The unique structural organization of the terminal chromosome regions, which is never observed at any other location of the genome supports the idea that they are morphological manifestations of the postulated telomeres.     

Microdissection and cloning of DNA from a specific region of Drosophila melanogaster polytene chromosomes

Fragments from section 3 of the salivary gland X chromosome of D. melanogaster were dissected with a micromanipulator. The DNA was extracted, cut and ligated to a λ vector in a volume of a few nanoliters in an oil chamber monitored through a microscope. From about 10 pg of DNA we obtained 80 recombinant clones, a sample of which were analysed and shown to contain Drosophila DNA which hybridises in situ to the region of section 3 of the X chromosome. With this technique we can isolate clones from any desired region as small as 200 kb from the euchromatic arms of polytene chromosomes. This paper is dedicated to Professor W. Beermann on the occasion of his sixtieth birthday     

A telomeric satellite in Drosophila virilis and its sibling species

Telomere elongation by telomerase is the most widespread mechanism among eukaryotes. However, alternative mechanisms such as homologous recombination between terminal satellite DNAs are probably used in lower dipteran insects and in some plants. Drosophila melanogaster uses the very unusual telomere elongation pathway of transposition of telomere-specific retrotransposable elements. The uniqueness of this telomere elongation mechanism raises the question of its origin. We, therefore, analyzed sequences located at telomeres of fairly distantly related Drosophila species, and in this paper we describe the characterization of complex satellite DNA sequences located at the telomeres of D. virilis and other species in the virilis group. We suggest an involvement of these DNA satellites in telomere elongation by homologous recombination similar to that found in lower dipterans. Our findings raise the possibility that telomere elongation by specific retrotransposons as found in D. melanogaster and its sibling species is a recent event in the evolution of dipteran insects.     

A sequence specific to B chromosomes of Brachycome dichromosomatica

Supernumerary B chromosomes represent one of many causes of numerical chromosome variation that exist in higher plants and animals. Sequences of DNA unique to B chromosomes of Brachycome dichromosomatica were enriched prior to cloning and resultant clones hybridizing only to plants containing B chromosomes were further investigated. Sequences of DNA that were characterised include members of a family of 176-bp tandem repeats that are specific to the B chromosomes of B. dichromosomatica, an annual Australian native plant species with only two pairs of A chromosomes and up to three dispensable B chromosomes. Sequence analysis of these six related clones indicated that some regions of the sequence are more highly conserved than others or, alternatively, that some adenine residues at the NdeII site are methylated. The repeat is homologous to DNA from Brachycome ciliaris var. languinosa but not to DNA from other related taxa growing in the vicinity of the B. dichromosomatica populations.     

Pericentromeric regions containing 1.688 satellite DNA sequences show anti-kinetochore antibody staining in prometaphase chromosomes of Drosophila melanogaster

A striking characteristic of the centromeric heterochromatin of Drosophila melanogaster is that each chromosome carries different satellite DNA sequences. Here we show that while the major component of the 1.688 satellite DNA family expands across the centromere of the X chromosome the rest of the minor variants are located at pericentromeric positions in the large autosomes. Immunostaining of prometaphase chromosomes with the kinetocore-specific anti-BUB1 antibody reveals the transient presence of this centromeric protein in all the regions containing the 1.688 satellite.     

B chromosomes in Amazonian cichlid species

B chromosomes are reported in three different Amazonian cichlid species. One to three supernumerary microchromosomes were detected in the peacock bass Cichla monoculus (4 out of 28 specimens) and Cichla sp. (4 out of 13 specimens), and pike cichlids Crenicichla reticulata (2 out of 5 specimens), with no similar standard chromosomal morphology. C-banding revealed that B chromosomes are totally heterochromatic. We suggest two scenarios for the origin of these B chromosomes either by chromosomal breakdowns due to mutagenic action of methyl mercury present in the aquatic environment or by interspecific origin due to hybridization events.     

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.     

A system for mapping DNA sequences in the chromosomes of Drosophila melanogaster

Individual segments of the chromosomal DNA in D. melanogaster were isolated, and the sequences they contain were analyzed for repetition and mapped within the polytene chromosomes. Isolation was achieved by first constructing circular hybrid DNA molecules consisting of single chromosomal segments linked by poly(dA):poly(dT) joints to single molecules of the tetracycline resistance plasmid, pSC101. Tetracycline-sensitive E. coli were transformed to resistance by this heterogeneous population of hybrid molecules and homogeneous populations of different hybrids were isolated from the clones of transformants. Three hybrid plasmids (pDm 1, 2, and 4) were studied in detail. Each exhibits the structure expected from the method of construction and none exhibits internal sequence repetition detectable by reassociation kinetics. The D. melanogaster sequences in pDm2 and 4 belong to a single class defined by little or no repetition within the genome and localization to a single chromomeric region in the polytene chromosomes. The characteristics of this class, which also includes 4 of a second set of 6 hybrids, are not compatible with tandem repetition models for the chromomere. The sequences in pDm1 are repeated 90 times and are located in 15 different chromomeric regions and within the chromocentric β-heterochromatin. This distribution is of the kind predicted by certain regulatory models, for example, that of Britten and Davidson (1969).     

Two highly repetitive DNA satellites of Drosophila hydei localized within the α-heterochromatin of specific chromosomes

Two major highly repetitive satellites have been isolated from nuclear DNA of Drosophila hydei by sequential centrifugations in Ag⁺/Cs₂SO₄, actinomycin D/CsCl and CsCl. Their CsCl-densities are 1.696 and 1.714 g/cm³. In diploid larval brains they comprise about 13% and 4% respectively of the DNA. Both satellites are localized and chromosome specific. The 1.696 component was shown to be derived from the X-heterochromatin by comparison of different stocks containing different amounts of X-heterochromatin and by in situ hybridization of the ¹²⁵I-labelled light single strand of this satellite. Since the amount of X-heterochromatin equals the amount of this satellite it was concluded that the 1.696 satellite is the only major DNA component of the X-heterochromatin besides minor DNA fractions (e.g. rDNA). The other highly repetitive satellite (1.714 g/cm³) hybridized in situ to all four acrocentric autosome pairs of D. hydei, but neither to the X nor to the small dot-like sixth chromosome, and not to the Y.     

Molecular characterization and chromosomal localization of two families of satellite DNA in Prochilodus lineatus (Pisces,Prochilodontidae), a species with B chromosomes

Prochilodus lineatus, an abundant species in the Mogi-Guaçu river basin, represents a large part of the region's fishing potential. Karyotypic analyses based on classic cytogenetic techniques have revealed the presence of 54 meta-submetacentric type chromosomes, together with the occurrence of small supernumerary chromosomes with intra and interindividual variations. This paper describes the genomic organization of two families of satellite DNA in the P. lineatus genome. The chromosomal localization these two repetitive DNA families through fluorescence in situ hybridization (FISH) demonstrated that the SATH1 satellite DNA family, composed of approximately 900 bp, was located in the pericentromeric region of a group of chromosomes of the standard complement, as well as on all the B chromosomes. The SATH2 satellite family has a monomeric unit of 441 bp and was located in the pericentromeric regions of some chromosomes of the standard complement, but was absent in the B chromosomes. Double FISH analyses showed that these two families participate jointly in the pericentromeric organization of several chromosomes of this species. The data obtained in this study support the hypothesis that the B chromosomes derive from chromosomes of the standard complement, which are carriers of the SATH1 satellite DNA.     

Isolation and identification of a novel satellite DNA family highly conserved in several Cervidae species

In an attempt to amplify cervid satellite II DNA from the genomes of Indian muntjac and Chinese muntjac, a pair of primers derived from the white tailed deer satellite II DNA clone (OvDII) yielded a prominent approximately 1 kb polymerase chain reaction (PCR) product (in addition to the expected 0.7 kb satellite II DNA fragments) in both species. The approximately 1 kb products were cloned, sequenced, and analyzed by Southern blotting and fluorescence in situ hybridization (FISH). This revealed that the approximately 1 kb cloned sequences indeed represent a previously unknown cervid satellite DNA family, which is now designated as cervid satellite IV DNA. Approximately 1 kb PCR clones were also obtained from the genomes of the black tailed deer and Canadian woodland caribou with similar primer pairs. Extremely high sequence conservation (over 90% homology) was observed among the clones generated from all four deer species and PCR-Southern hybridization experiments further verified the co-amplification of two kinds of satellite DNA sequences with the same pair of primers. This satellite DNA was found to co-localize with centromeric proteins at the kinetochore by a simultaneous FISH and immunofluorescence study. Due to its high sequence conservation and close association with kinetochores, the newly identified satellite DNA may have a functional centromeric role.     

Recognition of specific DNA sequences in eukaryotic chromosomes.

The packaging of DNA into chromatin probably places certain restrictions on how specific DNA sequences can be recognized by DNA sequence specific recognition proteins (SRP). Several unique features of this type of interaction are discussed. Specifically, as a consequence of the coiling of the DNA about a histone core, it is proposed that DNA recognition sites will be compound and that each element of the compound recognition site will be about 10 - 20 b.p. in length and distributed at approximately 80 b.p. intervals--the periodicity of the DNA wrapping around the nucleosome.