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.     

A cytogenetic analysis of X- ray induced male steriles on the Y chromosome of Drosophila melanogaster

A total of 1020 B ^s Yy ⁺chromosomes was screened for the induction of male sterile mutations by X irradiation. The 29 recovered mutations were analyzed by genetic complementation and the metaphase chromosomes stained with Hoechst 33258 and observed with fluorescence microscopy. The cytological and genetic maps derived from this analysis were compared to similar maps of the Y chromosome mutations isolated in an earlier study (Brosseau, 1960). Unlike the previous work we have identified only 6 male fertility loci (2 on the short arm, 4 on the long arm) on the Y chromosome. These loci are distributed along the length of the long arm and are likely to reside at two separate sites on the short arm. There is no apparent clustering of these fertility factors in this heterochromatic chromosome. The deletions obtained in this study were observed to be unstable and the nature of this instability was investigated. The original Y chromosome was marked at both telomeres with normally X-linked genes. The loss of one or the other of these markers was accompanied in many cases by the concomitant loss of large segments of Y chromosome material. The possible mechanism of this loss is discussed.Author to whom correspondence should be sent     

The Location of the nucleolus organizer regions in Drosophila hydei

The positions of the nucleolus organizer regions in metaphase chromosomes of Drosophila hydei were detected by in situ hybridization experiments. In agreement with earlier conclusions the nucleolus of the X chromosome was found to originate in a terminal region of the heterochromatic arm. The Y chromosome contains two nucleolus organizers, one in a terminal position of the long arm, and the other in the short arm. The implications with respect to the evolution of the Y chromosome are discussed.     

Distribution of heterochromatin on the mitotic chromosomes of Musca domestica L. in relation to the activity of male-determining factors

In the housefly, male sex is determined by a dominant factor, M, located either on the Y, on the X, or on any of the five autosomes. M factors on autosome I and on fragments of the Y chromosome show incomplete expressivity, whereas M factors on the other autosomes are fully expressive. To test whether these differences might be caused by heterochromatin-dependent position effects, we studied the distribution of heterochromatin on the mitotic chromosomes by C-banding and by fluorescence in situ hybridization of DNA fragments amplified from microdissected mitotic chromosomes. Our results show a correlation between the chromosomal position of M and the strength of its male-determining activity: weakly masculinizing M factors are exclusively located on chromosomes with extensive heterochromatic regions, i.e., on autosome I and on the Y chromosome. The Y is known to contain at least two copies of the M factor, which ensures a strong masculinizing effect despite the heterochromatic environment. The heterochromatic regions of the sex chromosomes consist of repetitive sequences that are unique to the X and the Y, whereas their euchromatic parts contain sequences that are ubiquitously found in the euchromatin of all chromosomes of the complement. Received: 20 February 1998; in revised form: 11 May 1998 / Accepted: 23 May 1998     

Hoechst 33258 banding of Drosophila nasutoides metaphase chromosomes

Hoechst 33258 banding of D. nasutoides metaphase chromosomes is described and compared with Q and C bands. The C band positive regions of the euchromatic autosomes, the X and the Y fluoresce brightly, as is typical of Drosophila and other species. The fluorescence pattern of the large heterochromatic chromosome is atypical, however. Contrary to the observations on other species, the C negative bands of the large heterochromatic chromosome are brightly fluorescent with both Hoechst 33258 and quinacrine. Based on differences in the various banding patterns, four classes of heterochromatin are described in the large heterochromatic chromosome and it is suggested that each class may correspond to an AT-rich DNA satellite.     

Spermatogonial exchange involving the X but not the y chromosome inDrosophila Melanogaster

Summary The distal uninverted portion of In(1)sc⁸, which carriesy ⁺ andac ⁺, is occasionally lost during spermatogonial divisions. This is accomplished by exchange between the protion of the proximal heterochromatin that has been removed distally by the inversion and some other heterochromatin in the complement (see alsoLindsley 1955b).. The majority of the recombiants recovered from males carrying In(1)sc⁸ arise through exchange with the Y chromosome (12/15). The majority of the recombinants recovered from males carring In(1)sc^8L, EN^R, which is characterized by a heterochromatic second arm, do not arise through exchange with the Y chromosome (18/22). The absolute frequencies of Y involvement with In(1)sc⁸ (7/105067) and In(1)sc^8L, EN^R,(2/38588), however, are comparable. The heterochromatic constitution of the recombinants examined is consistent with the hypothesis that an observed excess of recombinants recoverred from In(1)sc^8L, EN^R as compared with In(1)sc⁸ is accounted for by Y independent recombinants and is the consequence of exchange between the second heterochromatin arm of In(1)EN^R and the distal heterochromatin of In(1)sc^8L. A maximum of six different regions of exchange between these two regions may be inferred from the constitution of the recombinants. This inference is considered to support the hypothesis that pairing and exchange between heterochromatic regions are not strictly homologous.With 6 Figures in the TextOperated by Union Carbide Nuclear Company for the U.S. Atomic Energy Commission.Part of the material was presented to the Graduate School of the California Institute of Technology in partial fulfillment of requirements for the degree of Doctor of Philosophy supported by an Atomic Energy Commission predoctoral fellowship. Further experimentation has been pursued under a National Research Council postdoctoral fellowship at the University and under a National Science Foundation postdoctoral fellowship at the University of Missouri. Experimentation was completed at Oak Ridge.     

Sex chromatin and nucleolar analyses inRumex acetosa L.

Summary Rumex acetosa (sorrel) is a dioecious plant with a XX/XY₁Y₂ sex chromosome system. Both the Y chromosomes are nearly entirely heterochromatic and it has been hypothesised that they can persist as chromocenters in male interphase nuclei. Using specific antibodies against 5-methylcytosine and histone H4 acetylated at terminal lysine 5, global levels of DNA methylation and histone acetylation were studied on the sex chromosomes and autosomes of both sexes. The heterochromatic Y chromosomes did not display a higher methylation level compared to the autosomes. The only prominent hypermethylation signals were found at two nucleolar organising regions located on the autosome pair V, as confirmed by in situ hybridisation with 25S rDNA probe and staining. Immunoanalysis of DNA methylation on female and male interphase nuclei neither revealed any sex-specific differences. Two active (silverpositive) nucleoli and two likely inactive nucleolar organising regions (displaying prominent methylation signals) were found in both sexes. In a fraction of nuclei isolated from leaf cells, two peripheral bodies strongly positive for 4,6-diamidino-2-phenylindole were observed only in males, never in females. These heterochromatin regions were depleted in histone H4 acetylation at terminal lysine 5 and corresponded, according to in situ hybridisation with a Y-chromosome-specific repetitive probe, to the two Y chromosomes. We conclude that the peripheral condensed bodies observed exclusively in male nuclei represent the constitutive heterochromatin of the Y chromosomes which is characterised by a substantial histone H4 underacetylation.     

Molecular cytogenetic characterization of <Emphasis Type="Italic">Rumex papillaris</Emphasis>, a dioecious plant with an XX/XY<Subscript>1</Subscript>Y<Subscript>2</Subscript> sex chromosome system

Rumex papillaris Boiss, & Reut., an Iberian endemic, belongs to the section Acetosa of the genus Rumex whose main representative is R. acetosa L., a species intensively studied in relation to sex-chromosome evolution. Here, we characterize cytogenetically the chromosomal complement of R. papillaris in an effort to enhance future comparative genomic approaches and to better our understanding of sex chromosome structure in plants. Rumex papillaris, as is common in this group, is a dioecious species characterized by the presence of a multiple sex chromosome system (with females 2n = 12 + XX and males 2n = 12 + XY₁Y₂). Except for the X chromosome both Y chromosomes are the longest in the karyotype and appear heterochromatic due to the accumulation of at least two satellite DNA families, RAE180 and RAYSI. Each chromosome of pair VI has an additional major heterochromatin block at the distal region of the short arm. These supernumerary heterochromatic blocks are occupied by RAE730 satellite DNA family. The Y-related RAE180 family is also present in an additional minor autosomal locus. Our comparative study of the chromosomal organization of the different satellite-DNA sequences in XX/XY and XX/XY₁Y₂ Rumex species demonstrates that of active mechanisms of heterochromatin amplification occurred and were accompanied by chromosomal rearrangements giving rise to the multiple XX/XY₁Y₂ chromosome systems observed in Rumex. Additionally, Y₁ and Y₂ chromosomes have undergone further rearrangements leading to differential patterns of Y-heterochromatin distribution between Rumex species with multiple sex chromosome systems.     

Homolog pairing and sister chromatid cohesion in heterochromatin in <Emphasis Type="Italic">Drosophila</Emphasis> male meiosis I

Drosophila males undergo meiosis without recombination or chiasmata but homologous chromosomes pair and disjoin regularly. The X–Y pair utilizes a specific repeated sequence within the heterochromatic ribosomal DNA blocks as a pairing site. No pairing sites have yet been identified for the autosomes. To search for such sites, we utilized probes targeting specific heterochromatic regions to assay heterochromatin pairing sequences and behavior in meiosis by fluorescence in situ hybridization (FISH). We found that the small fourth chromosome pairs at heterochromatic region 61 and associates with the X chromosome throughout prophase I. Homolog pairing of the fourth chromosome is disrupted when the homolog conjunction complex is perturbed by mutations in SNM or MNM. On the other hand, six tested heterochromatic regions of the major autosomes proved to be largely unpaired after early prophase I, suggesting that stable homolog pairing sites do not exist in heterochromatin of the major autosomes. Furthermore, FISH analysis revealed two distinct patterns of sister chromatid cohesion in heterochromatin: regions with stable cohesion and regions lacking cohesion. This suggests that meiotic sister chromatid cohesion is incomplete within heterochromatin and may occur at specific preferential sites.     

Genomic and cytological analysis of the<Emphasis Type="Italic"> Y</Emphasis> chromosome of <Emphasis Type="Italic">Drosophila melanogaster</Emphasis>: telomere-derived sequences at internal regions

The genomic analysis of heterochromatin is essential for studying chromosome behavior as well as for understanding chromosome evolution. The Y chromosome of Drosophila melanogaster is entirely heterochromatic and the under-representation of this chromosome in genomic libraries together with the difficulty of assembling its sequence has made its study very difficult. Here, we present the construction of bacterial artificial chromosome (BAC) contigs from regions h14, h16 and the centromeric region h18. The analysis of these contigs shows that telomere-derived sequences are present at internal regions. In addition, immunostaining of prometaphase chromosomes with an antibody to the kinetochore-specific protein BubR1 has revealed the presence of this protein in some Y chromosome regions rich in telomere-related sequences. Collectively, our data provide further evidence for the hypothesis that the Drosophila Y chromosomes might have evolved from supernumerary chromosomes.The first two authors contributed equally to this workAntonia Martín-Gallardo died Monday, 23 August 2004, after a long battle with cancerThe GenBank Accession numbers for the sequences reported in this paper are AJ549653–96, AJ549701–2, AJ549725–6, AJ 549737–8, AJ549747–8, AJ549751–2, AJ 586980, AJ781048–58     

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     

The effect of JIL-1 on position-effect variegation is proportional to the total amount of heterochromatin in the genome

In this study we have taken advantage of recent whole genome sequencing studies that have determined the DNA content in the heterochromatic regions of each Drosophila chromosome to directly correlate the effect on position-effect variegation of a pericentric insertion reporter line, 118E-10 with the total amount of heterochromatic DNA. Heterochromatic DNA levels were manipulated by adding or subtracting a Y chromosome as well as by the difference in the amount of pericentric heterochromatin between the X and Y chromosome. The results showed a direct, linear relationship between the amount of heterochromatic DNA in the genome and the expression of the w marker gene in the 118E-10 pericentric reporter line and that increasing amounts of heterochromatic DNA resulted in increasing amounts of pigment/gene activity. In Drosophila heterochromatic spreading and gene silencing is counteracted by H3S10 phosphorylation by the JIL-1 kinase, and we further demonstrate that the haplo-enhancer effect of JIL-1 is proportional to the amount of total heterochomatin, suggesting that JIL-1's activity is dynamically modulated to achieve a more or less constant balance depending on the levels of heterochromatic factors present.     

Independence between modification of genetic position effects and formation of lampbrush loops by the Y chromosome of Drosophila hydei

Summary The phenotype of the variegation position effect white-mottled-2 in Drosophila hydei is modified by supernumerary Y chromosomes and by fractions thereof. Different translocated Y fragments have varying degrees of effectiveness in suppressing the mutant phenotype in the mottled eyes. In fragments derived from similar regions of the Y chromosome the suppressive ability is related to their cytological lengths. In contrast, fragments derived from distinctive regions of the Y chromosome differ markedly in their effectiveness, and these differences are not necessarily correlated with the cytological length. In particular, fragments of the distal region of Y^L are more effective in enhancing the wild phenotype than are proximal fragments of similar size.The mutation white-mottled-2 is accompanied by a complex rearrangement of the X chromosome. This inhibits crossing over between large regions of the X chromosome in structural heterozygotes; it causes also a delay of development and a considerable reduction of viability in homozygous females and hemizygous males. XO males are inviable. The inviability of these males is partially covered by Y fragments. With respect to viability, the fragments show similar regional differences in effectiveness as in the modification of the mottled phenotype.There is also a parental effect on the modulation of the white-mottled-2 phenotype.There is no correlation between the activity of Y chromosomal factors on spermiogenesis and the activity of Y factors on the modification of the variegation position effect. Suppression of Y chromosomal sites which normally unfold lampbrush loops during the spermatocyte stage and whose activity has previously been shown to be indispensible for normal differentiation of the male germ line cells does not result in any visible alterations of the effectiveness on the mottling. So there is obviously independence between these two different genetic activities of Y chromosomal factors.     

Chromosomal description of the rodent generaOecomys andNectomys from Brazil

We analysed karyotypes of five taxa of the rodent generaOecomys andNectomys, trapped in 14 localities in an area ranging from 8° to 29°S on Brazilian territory.Oecomys cf.concolor, collected in the Amazon and in two localities of the Cerrado biome, showed a 2n=60 karyotype constituted by a pair of large subtelocentric chromosomes, a small metacentric pair and 27 acrocentric pairs. The X chromosome was a large submetacentric and a subtelo-submetacentric, the morphology of the latter showing variable C-banding patterns. In all three localities the Y chromosome was a medium size heterochromatic acrocentric. Two individuals from the Cerrado had a heterochromatic acrocentric B-chromosome.Oecomys cf.bicolor presented two cytotypes, 2n=80 in the specimens from the Cerrado biome and 2n=82 in individuals trapped in the Amazon. The 2n=80 cytotype 1 showed a large subtelocentric, 22 biarmed pairs (medium to small) and 16 acrocentric autosomal pairs. The karyotype of the 2n=82 cytotype 2 is constituted by 15 biarmed chromosomes (median to small) and 25 acrocentric pairs with heterochromatic blocks at pericentromeric regions. The sexual pairs were the same (large submetacentric X and median acrocentric Y) in both cytotypes. InO. cf.concolor and in both cytotypes ofO. cf.bicolor the nucleolar organizer regions were observed in 1-3 pairs, located in the short arms.Nectomys genus presented two cytotypes, 2n=52–55 (N. rattus, with 0–3 biarmed heterochromatic accessory chromosomes) and 2n=56–59 (N. squamipes, bearing 0–3 biarmed, heterochromatic, B-chromosomes). These 2 cytotypes occupy disjunct regions of South America, with overlapping areas in the Brazilian states of Pernambuco, Bahia, and Mato Grosso do Sul.     

Y chromosome-specific mutations induced by a giant transposon in Drosophila hydei

Summary The w ^m Co duplication of Drosophila hydei (Dp (1; Y) 16B2-17B1) contains 13–16 bands in salivary gland chromosomes. The duplication resides preferentially in the X heterochromatin or on the Y chromosome. In some stocks frequent (up to 4×10^-3) exchanges of the duplication occur between different Y chromosomes (T(X; Y) and free Y) or between the X and the Y chromosome. About 60% of the T(X; Y)-Y exchanges induce mutations in the Y chromosomal male fertility genes of the recipient Y chromosome. From the mutational spectrum generated by the T(X; Y)-Y transpositions and from the variable efficiency as acceptor of different X-Y translocations it can be concluded that the exchanges show a remarkable site specificity: distal positions in the long arm of the Y chromosome are occupied preferentially. More proximal positions in the long arm of insertions into the short arm of the Y chromosome are found only with a lower frequency. No transpositions to the autosomes have been recovered. Duplications are lost with highly differing frequencies. The losses are not linked with insertions of the w ^m Co element into a new position and are more frequent than transpositions. Therefore, we regard the w ^m Co element as a giant transposon.     

Novel Y‐chromosome polymorphisms in Chinese domestic yak

Y‐chromosome‐specific haplotypes (Y‐haplotypes) constructed using single nucleotide polymorphisms (Y‐SNPs) in the MSY (male‐specific region of the Y‐chromosome) are valuable in population genetic studies. But sequence variants in the yak MSY region have been poorly characterized so far. In this study, we screened a total of 16 Y‐chromosome‐specific gene segments from the ZFY, SRY, UTY, USP9Y, AMELY and OFD1Y genes to identify Y‐SNPs in domestic yaks. Six novel Y‐SNPs distributed in the USP9Y (g.223C>T), UTY19 (g.158A>C and g.169C>T), AMELY2 (g.261C>T), OFD1Y9 (g.165A>G) and SRY4 (g.104G>A) loci, which can define three Y‐haplotypes (YH1, YH2 and YH3) in yaks, were discovered. YH1 was the dominant and presumably most ancient haplotype based on the comparison of UTY19 locus with other bovid species. Interestingly, we found informative UTY19 markers (g.158A>C and g.169C>T) that can effectively distinguish the three yak Y‐haplotypes. The nucleotide diversity was 1.7 × 10^?4 ± 0.3 × 10^?4, indicating rich Y‐chromosome diversity in yaks. We identified two highly divergent lineages (YH1 and YH2 vs. YH3) that share similar frequencies (YH1 +  YH2: 0.82–0.89, YH3: 0.11–0.18) among all three populations. In agreement with previous mtDNA studies, we supported the hypothesis that the two highly divergent lineages (YH1 and YH2 vs. YH3) derived from a single gene pool, which can be explained by the reunion of at least two paternal populations with the divergent lineages already accumulated before domestication. We estimated a divergence time of 408 110 years between the two divergent lineages, which is consistent with the data from mitochondrial DNA in yaks.     

An analysis of white-mottled mutants inDrosophila hydei,with observations on X-Y exchanges in the male

Chromosomes and phenotypes of four different sex-linkedwhite-mottled mutants of the position-effect variogation type were studied. Three mutants (w ^m1,w ^m2,w ^m3) are X-chromosomal rearrangements which shift the w⁺ locus into a position close to heterochromatin, but which have different ouchromatic and heterochromatic breaks. The fourth, a spontaneous derivative ofw ^m1, is an insertional duplication of part of the X chromosome, including thew ⁺ andN ⁺loci. The duplicated segment is inserted into the distal part of the long arm of the heterochromatic Y chromosome. It is designated,w ^m CoY, orXw ^m Co when transferred to the X chromosome.Three chromosomal types (w ^m1,w ^m CoY) and (Xw ^m Co) having the same cuchromatic break near thew ⁺ locus, cause large-spotted eyes whereas two others (w ^m2,w ^m3) produce a popper-and-salt type of mottling. From the position of the various eu- and heterochromatic breaks, it appears that the distance of thew ⁺ locus to the point of reunion with heterochromatin, rather than the amount or type of adjoining heterochromatin, dietates the phenotypic action of the displacedw ⁺ locus, in the sense of a spreading effect on two proposed functional subunits within thew ⁺ locus.The pigmentation background against which the mottling effect is produced, i.e., a givenw-allele with its characteristic colour, or other eye colour mutations, does not seem to affect the type of mottling. Drosopterins and ommochromes react in the same way to modifing factors like temperature and supernumerary Y chromosomes. Two mutants (w ^m2 andw ^m CoY) while reacting in the same manner to Y chromosomes showed an opposite temperature response.By exchange between the heterochromatin of the Y and X chromosome inw/w ^m CoY males thew ^m Co duplication was transferred between the sex chromosomes with a certain regularity. It is not yet known wether the exchanges are mitotic or meiotic in origin but their heterochromatic nature has been demonstrated cytologically.     

Genetic factors affecting normal growth of testes inDrosophila hydei

Summary A marked growth in the length of testes ofDrosophila hydei males occurred during pupal development. This growth continued over the first 8 days of adult life and in the young adults sperm were not produced until the testes increased approximately threefold in length to about 28 mm. The length of testes is correlated with genetic factors on the X and Y chromosomes. In males lacking a Y chromosome (X/O) or the short arm (Y^S) of the Y chromosome (X/Y^L) the testes were about half the length of testes of control males (X/Y) or double Y males (X/Y/Y). Males with deletions of the distal Y^L chromosome arm had testicular lengths equivalent to the controls. Males with short testes (X/O and X/Y^L) showed disruptions to spermatogenesis at meiosis and an absence of normal spermatid elongation. Reduction of active ribosomal RNA genes on the X chromosome in X/O caused an increased expression ofbobbed (bb) and a corresponding reduction in length of testes. Severelybobbed X/O males had very few cysts of spermatogonia and these cysts did not develop into primary spermatocytes.     

Modification of the DNA content in translocated regions of Drosophila polytene chromosomes

The DNA content of translocated polytene chromosome regions in Drosophila melanogaster is affected by heterochromatic position effect. Microdensitometric studies on w ^m258-21 translocation heterozygotes showed (Hartmann-Goldstein and Cowell, 1976; Cowell and Hartmann Goldstein, 1980) that band region 3D1-E2, adjacent to the breakpoint, contained less DNA than the homologous non-translocated region whereas the neighbouring 3C1-10 region contained more DNA than its non-translocated counterpart. In the nuclei selected for measurement the translocated X chromosome was morphologically euchromatic, but both regions undergo heterochromatisation in other nuclei within the same salivary gland. To explore the relationship between changes in DNA content and heterochromatisation, the effect on DNA content of two known modifiers of heterochromatisation has now been studied. Larvae cultured at 15° C, which exhibit more heterochromatisation than those grown at 25° C, have the same relative DNA contents as at the higher temperature. The addition of a Y chromosome markedly reduced heterochromatisation; in XXY larvae there was no difference between the DNA contents of translocated and non-translocated 3D1-E2 regions, and in region 3C1-10 the percentage excess of DNA in the translocated homologue was approximately double that found in XX larvae. The relationship between replication behaviour and compaction suggested by these results is discussed.     

Cytological dissection of sex chromosome heterochromatin of Drosophila hydei

Prophase chromosomes of Drosophila hydei were stained with 0.5 g/ml Hoechst 33258 and examined under a fluorescence microscope. While autosomal and X chromosome heterochromatin are homogeneously fluorescent, the entirely heterochromatic Y chromosome exhibits an extremely fine longitudinal differentiation, being subdivided into 18 different regions defined by the degree of fluorescence and the presence of constrictions. Thus high resolution Hoechst banding of prophase chromosomes provides a tool comparable to polytene chromosomes for the cytogenetic analysis of the Y chromosome of D. hydei. — D. hydei heterochromatin was further characterized by Hoechst staining of chromosomes exposed to 5-bromodeoxyuridine for one round of DNA replication. After this treatment the pericentromeric autosomal heterochromatin, the X heterochromatin and the Y chromosome exhibit numerous regions of lateral asymmetry. Moreover, while the heterochromatic short arms of the major autosomes show simple lateral asymmetry, the X and the Y heterochromatin exhibit complex patterns of contralateral asymmetry. These observations, coupled with the data on the molecular content of D. hydei heterochromatin, give some insight into the chromosomal organization of highly and moderately repetitive heterochromatic DNA.