He-T family DNA sequences in the Y chromosome of Drosophila melanogaster share homology with the X-linked Stellate genes

The genome of Drosophila melanogaster contains a class of repetitive DNA sequences called the He-T family, which is unusual in being confined to telomeric and heterochromatic regions. The specific He-T fragment designated Dm665 was cloned in yeast by selection for an autonomously replicating sequence (ARS). Dm665 contains a restriction fragment length polymorphism (RFLP) that is specific to males and thus derives from the Y chromosome. Deletion mapping using X-Y translocations indicates that sequences homologous to Dm665 occur in at least one major cluster in each arm of the Y chromosome. Among 20 yeast artificial chromosome (YAC) clones containing Drosophila sequences homologous with Dm665, four clones derive from defined regions of the long arm of the Y and two from the short arm. The sequence of Dm665 is 2443 bp long, consists of 59% A+T, and contains no significant open reading frames or direct or inverted repeats. However, Dm665 contains a region of 650 bp that shares homology with portions of the X-linked locus Stellate.by W. Hennig     

A dicentric chromosome of Drosophila melanogaster showing alternate centromere inactivation

Dicentric chromosomes are rarely found, because they interfere with normal cell division causing chromosome instability. By in situ hybridization of region-specific heterochromatic yeast artificial chromosomes we have found that the artificially generated C(1)A chromosome of Drosophila melanogaster has two potential centromeres: one carries all the sequences of the centromere of the Y chromosome and the other carries only a part of the Y centromeric region that is rich in telomere-related sequences. Immunostaining with anti-Bub1 (a kinetochore-specific marker) shows that, in spite of the differences in sequence, both centromeres can be active although as a rule only one at a time. In a small fraction of the chromosomes centromere inactivation is incomplete, giving rise to true dicentric chromosomes. The centromere inactivation is clonally inherited, providing a new example of epigenetic chromosome imprinting and the possibility of genetically dissecting this process. The involvement of telomere-related sequences in centromere function is discussed. Received: 15 September 1999; in revised form: 21 November 1999 / Accepted: 24 December 1999     

DNA sequences surrounding the centromere of chromosome 21.

The mapping and sequencing of two clones that surround the centromere of chromosome 21 are presented. These clones specify the most proximal known low-order repeat on 21p (p21-7D) and the most proximal known single-copy sequence on 21q (pUT-B37 at locus D21S120).     

Progressive loss of DNA sequences from terminal chromosome deficiencies in Drosophila melanogaster.

Terminal deficiencies at the tip of the X chromosome can be induced at a high frequency (0.2-0.3%) by irradiating Drosophila females carrying a homozygous mutator (mu-2) with low doses of X-rays. These terminal deficiencies are unstable, since over a period of 3 1/2 years DNA sequences were lost from their distal ends at a rate of 75 bp per generation, presumably due to the absence of a complete wild-type telomeric structure. Breakpoints of these deletions in the 5' upstream regulatory region of the yellow gene, giving rise to a mosaic cuticle pigmentation pattern typical of the y2 type, were used to define the location of tissue-specific cis-acting regulatory elements that are required for body, wing or bristle pigmentation.     

The Y chromosome of Drosophila melanogaster exhibits chromosome-wide imprinting

Genomic imprinting is well known as a regulatory property of a few specific chromosomal regions and leads to differential behavior of maternally and paternally inherited alleles. We surveyed the activity of two reporter genes in 23 independent P-element insertions on the heterochromatic Y chromosome of Drosophila melanogaster and found that all but one location showed differential expression of one or both genes according to the parental source of the chromosome. In contrast, genes inserted in autosomal heterochromatin generally did not show imprint-regulated expression. The imprints were established on Y-linked transgenes inserted into many different sequences and locations. We conclude that genomic imprinting affecting gene expression is a general property of the Drosophila Y chromosome and distinguishes the Y from the autosomal complement.     

Cytological and genetic analysis of the Y chromosome of Drosophila melanogaster

By applying quinacrine-, Hoechst- and N-banding techniques to neuroblast prometaphase chromosomes the Y chromosome of Drosophila melanogaster can be differentiated into 25 regions defined by the degree of fluorescence, the stainability after N-banding and the presence of constrictions. Thus these banding techniques provide an array of cytological landmarks along the Y chromosome that makes it comparable to a polytene chromosome for cytogenetic analysis. — 206 Y-autosome translocations (half of them carrying Y-linked sterile mutations) and 24 sterile y ⁺ Y chromosomes were carefully characterized by these banding techniques and used in extensive complementation analyses. The results of these experiments showed that: (1) there are four linearly ordered fertility factors in Y ^L and two fertility factors in Y ^S . (2) These fertility factors map to characteristic regions of the Y chromosome, specifically stained with the N-banding procedure. (3) The most extensively analyzed fertility factors are defined by a series of cytologically non-overlapping and genetically noncomplementing breaks and deficiencies distributed over large chromosome regions. For example, the breakpoints which inactivate the kl-5 and ks-1 loci are scattered along regions that contain about 3,000 kilobases (kb) DNA. Since these enormous regions formally define single genetic functions, the fertility genes of the Y chromosome have an as yet unappreciated physical dimension, being larger than euchromatic genes by two orders of magnitude.     

Timing of DNA replication of translocated Y chromosome sections in somatic cells of Drosophila melanogaster

The chronology of DNA replication was studied in cultured somatic cells of three stocks of Drosophila melanogaster marked by the presence of translocations between the Y chromosome and the X, 2nd and 3rd autosome, respectively. In all translocations the Y chromosome is split into two portions differently located. The different Y chromosome segments are always replicating later than euchromatin, but their timing of replication varies independently of the eu- or heterochromatic nature of the adjoining chromosome sections. This variation could be formally described as a position effect without spreading effect. It is concluded that there is evidence for the existence of factors controlling the timing of replication of the Y which are located on the chromosome itself.This is contribution No. 497 of the Euratom Biology Division. In Milano and Pavia this work was supported in part by grants of the Consiglio Nazionale delle Ricerche, Roma.     

Analysis of Y chromosome nucleolar organizer mutants in Drosophila melanogaster

Five Y chromosome nucleolar organizer (Y-NO) mutants were analyzed with respect to their rRNA gene numbers, phenotypes and additivity tests with other NO mutants. Four of these are indicative of a class of mutants in which most of the rRNA genes are transcribing functional rRNA. The other mutant has 80 genes, however, lethality and additivity tests suggests that many if not all of these rRNA genes are non-functional. The basis for the observed suppression of rRNA genes of the Y-NO region is discussed.     

Two DNA sequences specific for the canine Y chromosome

Data are presented on the characterization of two nucleotide sequences found exclusively in the DNA of male dogs. In polymerase chain reactions (PCRs) of canine genomic DNA with a decanucleotide primer of arbitrary sequence (OP-W17), two nucleotide segments (650 and 990 bp) were amplified only from male samples, whereas a number of other fragments between 400 and 2500 bp in size were amplified from both male and female samples. The two male-specific segments were cloned and sequenced, and terminal 24mer oligonucleotide primer pairs were synthesized. PCR with these specific primer pairs resulted in amplification of the two male-specific sequences only from DNA samples of 34 male dogs; no product was amplified from 42 samples of females. A segment of the SRY gene previously localized on the Y chromosome could be amplified in DNA samples that had the two new sequences. Eco RI digested genomic male DNA when hybridized with the 650 bp or the 990 bp sequences, resulted in a single band for each on Southern analysis; DNA from females did not yield any bands. Comparisons between the two new sequences and the SRY gene segment revealed no homologies. We concluded that the two new sequences are specific for the canine Y chromosome and do not contain the short characterized segment of the SRY gene.     

Changes in the fluorescence patterns of translocated Y chromosome segments in Drosophila melanogaster

Fluorescence analysis after quinacrine staining in squashes of Varese wild stock male larval ganglia confirmed that the Y chromosome has four characteristic sections of bright fluorescence. In one Y/X and in one Y/III translocation the section of bright fluorescence on the short arm of the Y is no longer bright when translocated onto the terminal portion of the X and on the right arm of the III chromosome, respectively. Fluorescence analysis has also permitted the identification of a structurally abnormal Y chromosome in a cell line of Drosophila melanogaster established in vitro. The findings in the two translocations call for caution in the interpretation of structural rearrangements by fluorescence analysis.     

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).     

Organization of DYZ2 repetitive DNA on the human Y chromosome

The location of the human Y-specific repetitive DNA sequence DYZ2 with HaeIII cleavage sites spaced at 2.1 kb was reexamined. Previous reports had mapped the 2000 DYZ2 copies to the very distal end of the heterochromatic Yq12 band. In the present study, a cloned DYZ2 fragment (pHY2.1) was used for Southern and slot blot analyses of male DNA as well as for nonradioactive in situ hybridization to chromosomes. DNA and metaphase preparations from 79 individuals with polymorphic or aberrant Y chromosomes were examined. DYZ2 repeats are not confined to the distal tip of Yq12, but extend through the entire heterochromatin of Yq12. In the naturally occurring length polymorphisms of Yq, the amount of DYZ2 sequence varies in proportion to the measured sizes of band Yq12. Explanations are presented for the fact that previous studies restricted the location of DYZ2 to the telomeric end of Yq12.     

Interspersion of repetitive and nonrepetitive DNA sequences in the Drosophila melanogaster genome

Cot analysis shows that the haploid Drosophila genome contains 12% rapidly reassociating, highly reiterated DNA, 12% middle repetitive DNA with an average reiteration frequency of 70, and 70% single-copy DNA. The distribution of the middle repetitive sequences in the genome has been studied by an examination in the electron microscope of the structures obtained when middle repetitive sequences present on large DNA strands reassociate and by the hydroxyapatite binding methods developed by Davidson et al. (1973). At least one third by weight of the middle repetitive sequences are interspersed in single-copy sequences. These interspersed middle repetitive sequences have a fairly uniform distribution of lengths from less than 0.5 to 13 kb, with a number average value of 5.6 kb. The average distance between middle repetitive sequences is greater than 13 kb. The data do not exclude the possibility that essentially all of the middle repetitive sequences have the interspersion pattern described above; however, it is possible that some of the middle repetitive sequences of Drosophila are clustered in stretches of length much greater than 13 kb. The interspersion pattern of the middle repetitive sequences in Drosophila is quite different from that which occurs in the sea urchin, in Xenopus, in rat, and probably many other higher eucaryotes.     

Identification of methylated sequences in genomic DNA of adult Drosophila melanogaster

The genome of Drosophila melanogaster contains methylated cytosines. Recent studies indicate that DNA methylation in the fruit fly depends on one DNA methyltransferase, dDNMT2. No obvious phenotype is associated with the downregulation of this DNA methyltransferase. Thus, identifying the target sequences methylated by dDNMT2 may constitute the first step towards understanding the biological functions of this enzyme. We used anti-5-methylcytosine antibodies as affinity column to identify the methylated sequences in the genome of adult flies. Our analysis demonstrates that components of retrotransposons and repetitive DNA sequences are putative substrates for dDNMT2. The methylation status of DNA encoding Gag, a protein involved in delivering the transposition template to its DNA target, was confirmed by sodium bisulfite sequencing.     

Evolution of Y chromosomal lampbrush loop DNA sequences of Drosophila

The evolutionary conservation of Y chromosomal DNA sequences of Drosophila hydei in different species of the genus Drosophila was studied by in situ hybridization and on genomic DNA blots of restriction enzyme digested DNA. We demonstrated that Y specific DNA sequences, which form major parts of lampbrush loops related to the male fertility genes, are only retained in a few closely related species during evolution. Other Y chromosomal DNA sequences, also present in lampbrush loops but with homology to autosomal and X chromosomal locations, were found in distant species. We propose a model for the evolution of the Y chromosomal lampbrush loops.