Reduced DNA polytenization of a minichromosome region undergoing position-effect variegation in Drosophila

Somatic reversion of chromosomal position effects in Drosophila melanogaster

A transgene was inserted at several different chromosomal sites in Drosophila melanogaster, where its expression was subject to genomic position effects. Quantitative position effects and variegated and constant patterned position effects were observed. We investigated the status of the affected gene in the somatic cells where it normally functions. The FLP site-specific recombinase was used to remove the gene from the chromosome and its expression was then evaluated. We show that the FLP recombinase functions in cells that have finished their developmental program of mitoses. When FLP acts on directly repeated copies of its target site (FRT), the DNA flanked by those FRTs is excised from the chromosome as a closed circle. The extrachromosomal circle is maintained in nondividing cells, and a gene located on such a circle can be expressed. We then demonstrate that a gene subject to either variegated or constant position effect can be relieved of that effect by excision of the gene from the chromosome in cells where it would otherwise be inactive. We also observed a strong inhibition of FLP-mediated recombination for target sites located near centric heterochromatin.

Misdivision analysis of centromere structure in maize

The size and organization of a representative plant centromere from the supernumerary B chromosome were determined using a repeated sequence specific to the centric region. Several derivatives of the B chromosome that suffered from misdivision of the centromere were analyzed for the content and organization of their B repeat. In all these derivatives, major rearrangements were detected. Some misdivisions produced a significant reduction in size of the B-specific cluster. These results demonstrate that the B repeat is part of the functional centromere, that it is spread throughout its length, and that plant centromeres are composed of repeat units that can be significantly changed in copy number without a change in function.

Autosomal location of a new subtype of 1.688 satellite DNA of Drosophila melanogaster

During the screening of a Drosophila melanogaster YAC library with DNA from the minichromosome Dp(1;f)1187 we isolated a clone, yw20D5, which contains a new subtype of 1.688 satellite DNA. Although the sequences of several monomers subcloned from the YAC show a considerable variation in length, the derived consensus sequence is 356-bp long. This new subtype and the one constituted by the 353-bp repeats are both located on the left arm heterochromatin of chromosome 3, arranged in separate arrays. Despite their autosomal location, phylogenetic relationships among 1.688 satellite sequences suggest that they may have originated from the 359-bp repeats of the X chromosome heterochromatin. We have used the new 356-bp repeats to investigate whether sequences related to the 1.688 satellite are dispersed along the euchromatic arms of the autosomes in a similar way to that in which they are found along the X chromosome euchromatin.

Centric heterochromatin and the efficiency of achiasmate disjunction in Drosophila female meiosis

The chromosomal requirements for achiasmate (nonexchange) homolog disjunction in Drosophila female meiosis I have been identified with the use of a series of molecularly defined minichromosome deletion derivatives. Efficient disjunction requires 1000 kilobases of overlap in the centric heterochromatin and is not affected by homologous euchromatin or overall size differences. Disjunction efficiency decreases linearly as heterochromatic overlap is reduced from 1000 to 430 kilobases of overlap. Further observations, including rescue experiments with nod kinesin-like protein transgenes, demonstrate that heterochromatin does not act solely to promote chromosome movement or spindle attachment. Thus, it is proposed that centric heterochromatin contains multiple pairing elements that act additively to initiate or maintain the proper alignment of achiasmate chromosomes in meiosis I. How heterochromatin could act to promote chromosome pairing is discussed here.

Position-effect variegation in Drosophila depends on dose of the gene encoding the E2F transcriptional activator and cell cycle regulator

A dominant mutation due to the insertion of a P-element at 93E on the third chromosome of Drosophila melanogaster enhances position-effect variegation. The corresponding gene was cloned by transposon tagging and the sequence of the transcript revealed that it corresponds to the gene encoding the transcriptional activator and cell cycle regulator dE2F. The transposon-tagged allele is homozygous viable, and the insertion of the transposon in an intron correlates with a strong reduction in the amount of transcript. A homozygous lethal null allele was found to behave as a strong enhancer when heterozygous. Overexpression of the gene in transgenic flies has the opposite effect of suppressing variegation. A link is established here, and discussed, between the dose of a transcriptional activator, which controls the cell cycle, and epigenetic silencing of chromosomal domains in Drosophila.

Perturbation of nuclear architecture by long-distance chromosome interactions

SUMMARY

Position-effect variegation (PEV) describes the stochastic transcriptional silencing of a gene positioned adjacent to heterochromatin. Using FISH, we have tested whether variegated expression of the eye-color gene brown in Drosophila is influenced by its nuclear localization. In embryonic nuclei, a heterochromatic insertion at the brown locus is always spatially isolated from other heterochromatin. However, during larval development this insertion physically associates with other heterochromatic regions on the same chromosome in a stochastic manner. These observations indicate that the brown gene is silenced by specific contact with centromeric heterochromatin. Moreover, they provide direct evidence for long-range chromosome interactions and their impact on three-dimensional nuclear architecture, while providing a cohesive explanation for the phenomenon of PEV.

DNA representation of variegating heterochromatic P-element inserts in diploid and polytene tissues of Drosophila melanogaster

Position-effect variegation (PEV) is the mosaic expression of a euchromatic gene brought into juxtaposition with heterochromatin. Fourteen different transformed Drosophila melanogaster lines with variegating P-element inserts were used to examine the DNA levels of these transgenes. Insert sites include pericentric, telomeric and fourth chromosome regions. Southern blot analyses showed that the heterochromatic hsp26 transgenes are underrepresented 1.3- to 33-fold in polytene tissue relative to the endogenous euchromatic hsp26 gene. In contrast, the heterochromatic hsp26 transgenes are present in approximately the same copy number as the endogenous euchromatic hsp26 gene in diploid tissue. It appears unlikely that DNA loss could account for the lack of gene expression in diploid tissues seen with these examples of PEV.

Heterochromatin and gene regulation in Drosophila

We have recently learned more about the biochemistry of heterochromatin and about how heterochromatic environments affect gene function. New findings have emphasized the distinctions between telomeric and pericentric heterochromatin in Drosophila and have suggested a mosaic structure within pericentric heterochromatin. Theories concerning the mechanism of inactivation of euchromatic genes in heterochromatic environments have been tested using transgenes inserted into heterochromatin. The current data support a competition/chromatin structure model, in which multiprotein repressor complexes compete with transcriptional activators to assemble an active or inactive chromatin structure.

Characterization of a sex-influenced modifier of gene expression and suppressor of position-effect variegation in Drosophila

Modifier of white (Mow), a dominant transacting gene, has been identified through a mutagenic screen for second-site loci that alter the level of expression of the white eye color locus. Mow reduces the expression of white in most developmental stages, but enhances its expression in the pupal stage, the time at which the major contribution to the adult phenotype is made. Tests with an Alcohol dehydrogenase promoter-white reporter and a series of white truncation constructs have shown that Mow fails to affect the reporter; cis-regulatory mutations of white also show no response, suggesting a requirement for white regulatory domains for interaction with Mow. A quantitative analysis of steady-state transcript levels reveals that the white mRNA level decreases in the presence of one dose of Mow in larvae and adults, but the reduction is greater in females than males. Two other functionally related genes, brown and scarlet, also exhibit a similar sexually dimorphic alteration in expression, mediated by Mow. In the mid-pupal stage, by contrast, the level of white and brown mRNA is increased by Mow. In addition, Mow acts as a weak suppressor of position effect variegation (PEV). These observations suggest a connection between dosage modulation of gene expression and suppression of position-effect variegation.

Developmental timing and tissue specificity of heterochromatin-mediated silencing

Heterochromatic position-effect variegation (PEV) describes the mosaic phenotype of a euchromatic gene placed next to heterochromatin. Heterochromatin-mediated silencing has been studied extensively in Drosophila, but the lack of a ubiquitous reporter gene detectable at any stage has prevented a direct developmental characterization of this phenomenon. Current models attribute variegation to the establishment of a heritable silent state in a subset of the cells and invoke differences in the timing of silencing to explain differences in the patch size of various mosaic patterns. In order to follow the course of heterochromatic silencing directly, we have generated Drosophila lines variegating for a lacZ reporter that can be induced in virtually all cells at any developmental stage. Our data indicate that silencing begins in embryogenesis and persists in both somatic and germline lineages. A heterogeneity in the extent of silencing is also revealed; silencing is suppressed in differentiated tissues but remains widespread in larval imaginal discs containing precursor cells for adult structures. Using eye development as an example, we propose that the mosaic phenotype is determined during differentiation by a variegated relaxation in heterochromatic silencing. Though unpredicted by prevailing models, this mechanism is evident in other analogous systems.

Copy number and orientation determine the susceptibility of a gene to silencing by nearby heterochromatin in Drosophila

The classical phenomenon of position-effect variegation (PEV) is the mosaic expression that occurs when a chromosomal rearrangement moves a euchromatic gene near heterochromatin. A striking feature of this phenomenon is that genes far away from the junction with heterochromatin can be affected, as if the heterochromatic state "spreads." We have investigated classical PEV of a Drosophila brown transgene affected by a heterochromatic junction approximately 60 kb away. PEV was enhanced when the transgene was locally duplicated using P transposase. Successive rounds of P transposase mutagenesis and phenotypic selection produced a series of PEV alleles with differences in phenotype that depended on transgene copy number and orientation. As for other examples of classical PEV, nearby heterochromatin was required for gene silencing. Modifications of classical PEV by alterations at a single site are unexpected, and these observations contradict models for spreading that invoke propagation of heterochromatin along the chromosome. Rather, our results support a model in which local alterations affect the affinity of a gene region for nearby heterochromatin via homology-based pairing, suggesting an alternative explanation for this 65-year-old phenomenon.

Around the genomes: the Drosophila genome project

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Meiosis in Drosophila: seeing is believing

Recently many exciting advances have been achieved in our understanding of Drosophila meiosis due to combined cytological and genetic approaches. New techniques have permitted the characterization of chromosome position and spindle formation in female meiosis I. The proteins encoded by the nod and ncd genes, two genes known to be needed for the proper partitioning of chromosomes lacking exchange events, have been identified and found to be kinesin-like motors. The effects of mutations in these genes on the spindle and chromosomes, together with the localization of the proteins, have yielded a model for the mechanism of female meiosis I. In male meiosis I, the chromosomal regions responsible for homolog pairing have been resolved to the level of specific DNA sequences. This provides a foundation for elucidating the molecular basis of meiotic pairing. The cytological techniques available in Drosophila also have permitted inroads into the regulation of sister-chromatid segregation. The products of two genes (mei-S332 and ord) essential for sister-chromatid cohesion have been identified recently. Additional advances in understanding Drosophila meiosis are the delineation of a functional centromere by using minichromosome derivatives and the identification of several regulatory genes for the meiotic cell cycle.

Islands of complex DNA are widespread in Drosophila centric heterochromatin

Heterochromatin is a ubiquitous yet poorly understood component of multicellular eukaryotic genomes. Major gaps exist in our knowledge of the nature and overall organization of DNA sequences present in heterochromatin. We have investigated the molecular structure of the 1 Mb of centric heterochromatin in the Drosophila minichromosome Dp1187. A genetic screen of irradiated minichromosomes yielded rearranged derivatives of Dp1187 whose structures were determined by pulsed-field Southern analysis and PCR. Three Dp1187 deletion derivatives and an inversion had one breakpoint in the euchromatin and one in the heterochromatin, providing direct molecular access to previously inaccessible parts of the heterochromatin. End-probed pulsed-field restriction mapping revealed the presence of at least three "islands" of complex DNA, Tahiti, Moorea, and Bora Bora, constituting approximately one half of the Dp1187 heterochromatin. Pulsed-field Southern analysis demonstrated that Drosophila heterochromatin in general is composed of alternating blocks of complex DNA and simple satellite DNA. Cloning and sequencing of a small part of one island, Tahiti, demonstrated the presence of a retroposon. The implications of these findings to heterochromatin structure and function are discussed.

Localization of centromere function in a Drosophila minichromosome

The DNA elements responsible for centromere activity in a metazoan have been localized using the Drosophila minichromosome Dp1187. Deleted minichromosomes were generated by irradiation mutagenesis, and their molecular structures were determined by pulsed-field Southern blot analysis. Analyses of the transmission behavior of Dp1187 derivatives localized sequences necessary for chromosome inheritance within the centric heterochromatin. The essential core of the centromere is contained within a 220 kb region that includes significant amounts of complex DNA. Completely normal inheritance also requires approximately 200 kb on either side of the essential core. This flanking DNA predominantly contains highly repeated sequences, and the amount required for normal transmission differs among division types and between the sexes. We propose that the essential core is the site of kinetochore formation and that flanking DNA provides two functions: sister chromatid cohesion and indirect assistance in kinetochore formation or function.

X-chromosome inactivation and cell memory

Mammalian X-chromosome inactivation is an excellent example of the faithful maintenance of a determined chromosomal state. As such, it may provide insight into the mechanisms for cell memory, defined as the faithful maintenance of a determined state in clonally derived progeny cells. We review here the aspects of X-chromosome inactivation that are relevant to cell memory and discuss the various molecular mechanisms that have been proposed to explain its occurrence, with emphasis on DNA methylation and a recently proposed mechanism that depends on the timing of replication.

Cis-effects of heterochromatin on heterochromatic and euchromatic gene activity in Drosophila melanogaster

Chromosomal rearrangements that juxtapose heterochromatin and euchromatin can result in mosaic inactivation of heterochromatic and euchromatic genes. This phenomenon, position effect variegation (PEV), suggests that heterochromatic and euchromatic genes differ in their regulatory requirements. This report describes a novel method for mapping regions required for heterochromatic genes, and those that induce PEV of a euchromatic gene. P transposase mutagenesis was used to generate derivatives of a translocation that variegated for the light+ (lt+) gene and carried the euchromatic white+ (w+) gene on a transposon near the heterochromatin-euchromatin junction. Cytogenetic and genetic analyses of the derivatives showed that P mutagenesis resulted in deletions of several megabases of heterochromatin. Genetic and molecular studies showed that the derivatives shared a euchromatic breakpoint but differed in their heterochromatic breakpoint and their effects on seven heterochromatic genes and the w+ gene. Heterochromatic genes differed in their response to deletions. The lt+ gene was sensitive to the amount of heterochromatin at the breakpoint but the heterochromatic 40Fa gene was not. The severity of variegated w+ phenotype did not depend on the amount of heterochromatin in cis, but varied with local heterochromatic environment. These data are relevant for considering mechanisms of PEV of both heterochromatic and euchromatic genes.

Position effect variegation in Drosophila is associated with an altered chromatin structure

A euchromatic gene placed in the vicinity of heterochromatin by a chromosomal rearrangement generally exhibits position effect variegation (PEV), a clonally inherited pattern showing gene expression in some somatic cells but not in others. The mechanism responsible for this loss of gene expression is investigated here using fly lines carrying a P element containing the Drosophila melanogaster white and hsp26 genes. Following mobilization of the P element, a screen for variegation of white expression recovered inserts at pericentric, telomeric, and fourth chromosome regions. Previously identified suppressors of PEV suppressed white variegation of pericentric and fourth chromosome inserts but not telomeric inserts on the second and third chromosomes. This implies a difference in the mechanism for gene repression at telomeres. Heat shock-induced hsp26 expression was reduced from pericentric and fourth chromosome inserts but not from telomeric inserts. Chromatin structure analysis revealed that the variegating inserts showed a reduction in accessibility to restriction enzyme digestion in the hsp26 regulatory region in isolated nuclei. Micrococcal nuclease digests showed that pericentric inserts were packaged in a more regular nucleosome array than that observed for euchromatic inserts. These data suggest that altered chromatin packaging plays a role in PEV.

Interactions between the nod+ kinesin-like gene and extracentromeric sequences are required for transmission of a Drosophila minichromosome

In this study, we demonstrate a role for extracentromeric sequences in chromosome inheritance. Genetic analyses indicate that transmission of the Drosophila minichromosome Dp1187 is sensitive to the dosage of nod+, a kinesin-like gene required for the meiotic transmission of achiasmate chromosomes. Minichromosome deletions displayed increased loss rates in females heterozygous for a loss-of-function allele of nod (nod/+). We have analyzed the structures of nod-sensitive deletions and conclude that multiple regions of Dp1187 interact genetically with nod+ to promote normal chromosome transmission. Most nod+ interactions are observed with regions that are not essential for centromere function. We propose that normal chromosome transmission requires forces generated outside the kinetochore, perhaps to maintain tension on kinetochore microtubules and stabilize the attachment of achiasmate chromosomes to the metaphase spindle.

Targeted expression of SV40 T antigen in the hair follicle of transgenic mice produces an aberrant hair phenotype

Directed expression of SV40 large T antigen (TAg) in transgenic mice can induce tissue-specific tumorigenesis and useful cell lines exhibiting differentiated characteristics can be established from resultant tumor cells. In an attempt to produce an immortalised mouse hair follicle cortical cell line for the study of hair keratin gene control, SV40 TAg expression was targeted to the hair follicles of transgenic mice using a sheep hair gene promoter. Expression of SV40 TAg in the follicle cortex disrupted normal fiber ultrastructure, producing a marked phenotypic effect. Affected hairs were wavy or severely kinked (depending on the severity of the phenotype) producing an appearance ranging from a ruffled coat to a stubble covering the back of the mouse. The transgenic hairs appeared to be weakened at the base of the fibers, leading to premature hair-loss and a thinner pelage, or regions of temporary nudity. No follicle tumors or neoplasia were apparent and immortalisation of cortical cells could not be established in culture. In situ hybridisation studies in the hair follicle using histone H3 as a cell proliferation marker suggested that cell proliferation had ceased prior to commencement of K2.10-TAg expression and was not re-established in the differentiating cortical cells. Hence, TAg was unable to induce cell immortalisation at that stage of cortical cell differentiation. However, transgenic mice developed various other abnormalities including vertebral abnormalities and bladder, liver and intestinal tumors, which resulted in reduced life expectancy.

The Drosophila salivary gland chromocenter contains highly polytenized subdomains of mitotic heterochromatin

Peri-centromeric regions of Drosophila melanogaster chromosomes appear heterochromatic in mitotic cells and become greatly underrepresented in giant polytene chromosomes, where they aggregate into a central mass called the chromocenter. We used P elements inserted at sites dispersed throughout much of the mitotic heterochromatin to analyze the fate of 31 individual sites during polytenization. Analysis of DNA sequences flanking many of these elements revealed that middle repetitive or unique sequence DNAs frequently are interspersed with satellite DNAs in mitotic heterochromatin. All nine Y chromosome sites tested were underrepresented > 20-fold on Southern blots of polytene DNA and were rarely or never detected by in situ hybridization to salivary gland chromosomes. In contrast, nine tested insertions in autosomal centromeric heterochromatin were represented fully in salivary gland DNA, despite the fact that at least six were located proximal to known blocks of satellite DNA. The inserted sequences formed diverse, site-specific morphologies in the chromocenter of salivary gland chromosomes, suggesting that domains dispersed at multiple sites in the centromeric heterochromatin of mitotic chromosomes contribute to polytene beta-heterochromatin. We suggest that regions containing heterochromatic genes are organized into dispersed chromatin configurations that are important for their function in vivo.

Unusual properties of genomic DNA molecules spanning the euchromatic-heterochromatic junction of a Drosophila minichromosome

While investigating the copy number of minichromosome Dp(1;f)1187 sequences in the polyploid chromosomes of ovarian nurse and follicle cells of Drosophila melanogaster we discovered that restriction fragments spanning the euchromatic-heterochromatic junction of the chromosome and extending into peri-centromeric sequences had the unusual property of being selectively resistant to transfer out of agarose gels during Southern blotting, leading to systematic reductions in Dp1187-specific hybridization signals. This property originated from the peri-centromeric sequences contained on the junction fragments and was persistently associated with Dp1187 DNA, despite attempts to ameliorate the effect by altering experimental protocols. Transfer inhibition was unlikely to be caused by an inherent physical property of repetitive DNA sequences since, in contrast to genomic DNA, cloned restriction fragments spanning the euchromatic-heterochromatic junction and containing repetitive sequences transferred normally. Finally, the degree of inhibition could be suppressed by the addition of a Y chromosome to the genotype. On the basis of these observations and the fact that peri-centromeric regions of most eukaryotic chromosomes are associated with cytologically and genetically defined heterochromatin, we propose that peri-centromeric sequences of Dp1187 that are incorporated into heterochromatin in vivo retain some component of heterochromatic structure during DNA isolation, perhaps a tightly bound protein or DNA modification, which subsequently causes the unorthodox properties observed in vitro.

A transposable element can drive the concerted evolution of tandemly repetitious DNA

Recombination and conversion have been proposed to drive the concerted evolution of tandemly repeated DNA sequences. However, specific correction events within the repeated genes of multicellular organisms have not been observed directly, so their nature has remained speculative. We investigated whether the excision of transposable P elements from tandemly repeated sequences would induce unequal gene conversion. Genetically marked elements located in a subtelomeric repeat were mobilized, and the structure of the region was analyzed in progeny. We observed that the number of repeats was frequently altered. Decreases were more common than increases, and this bias probably resulted from intrinsic mechanisms governing P element-induced double-strand break repair. Our results suggest that transposable elements play an important role in the evolution of repetitious DNA.

The protein encoded by the Drosophila position-effect variegation suppressor gene Su(var)3-9 combines domains of antagonistic regulators of homeotic gene complexes

Modifier mutations of position-effect variegation (PEV) represent a useful tool for a genetic and molecular dissection of genes connected with chromatin regulation in Drosophila. The Su(var)3-9 gene belongs to the group of haplo suppressor loci which manifest a triplo enhancer effect. Mutations show a strong suppressor effect even in the presence of PEV enhancer mutations, indicating a central role of this gene in the regulation of PEV. By molecular analysis, Su(var)3-9 could be correlated with a 2.4 kb transcript which encodes a putative protein of 635 amino acids containing a chromo domain and a region of homology to Enhancer of zeste and trithorax, two antagonistic regulators of the Antennapedia and Bithorax gene complexes, as well as to the human protein ALL-1/Hrx which is implicated in acute leukemias. This region of homology is found in all four proteins at the C-terminus. The homology of Su(var)3-9 to both negative (Polycomb and Enhancer of zeste) and positive (trithorax) regulators of the Antennapedia and Bithorax complexes also suggests similarities in the molecular processes connected with stable transmission of a determined state and the clonal propagation of heterochromatinization.

A rosy future for heterochromatin

The demonstration by Zhang and Spradling (1) of efficient P element transposition into heterochromatic regions will aid ongoing studies of heterochromatin structure and function. P element insertions will provide entry points for further molecular analysis of heterochromatin and will allow the isolation of small and large heterochromatic deficiencies. The generation of heterochromatic P insertions also will aid the study of heterochromatic genes. Of the heterochromatic insertions isolated by Zhang and Spradling, five were homozygous lethal, and one of these defined a lethal locus not previously uncovered by heterochromatic deficiencies. P elements have previously been used to mutagenize and clone specific heterochromatic genes (14, 19, 26). New methods, like those described here (1, 32), should allow the efficient identification and molecular isolation of other single-copy heterochromatic genes. Furthermore, since position-effect suppression allowed the recovery of heterochromatic P insertions, it may also allow the recovery of insertions in euchromatic regions previously refractory to P mutagenesis. Studies of position-effect variegation show that genes normally found in heterochromatin require a heterochromatic context for normal expression and that heterochromatin is inhibitory to euchromatic gene expression (16). The physical basis of these related phenomena--chromatin assembly, nuclear positioning, and/or heterochromatin elimination--can be resolved only with a more thorough understanding of heterochromatin structure and functions. Analyzing heterochromatin also will help define the chromosomal components responsible for inheritance processes such as chromosome pairing, sister chromatid adhesion, and centromere function. These efforts will be facilitated by the effective use of P elements combined with other current molecular-genetic approaches.

Insertional mutagenesis of Drosophila heterochromatin with single P elements

Insertional mutagenesis with transposable P elements has greatly facilitated the identification and analysis of genes located throughout the 70% of the Drosophila melanogaster genome classified as euchromatin. In contrast, genetically marked P elements have only rarely been shown to transpose into heterochromatin. By carrying out single P element insertional mutagenesis under conditions where position-effect variegation was suppressed, we efficiently generated strains containing insertions at diverse sites within centromeric and Y-chromosome heterochromatin. The tendency of P elements to transpose locally was shown to operate within heterochromatin, and it further enhanced the recovery of heterochromatic insertions. Three of the insertions disrupted vital genes known to be present at low density in heterochromatin. Strains containing single P element insertions will greatly facilitate the structural and functional analysis of this poorly understood genomic component.

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.

Position-effect variegation and the new biology of heterochromatin

The phenomenon of position-effect variegation has long been used as evidence for the importance of chromosome position to gene expression in eukaryotes. Investigations published within the past few years demonstrate that position-effect variegation is caused by multiple mechanisms, and that direct tests of hypotheses are possible with numerous model systems.

Modification of the Drosophila heterochromatic mutation brownDominant by linkage alterations

The variegating mutation brownDominant (bwD) of Drosophila melanogaster is associated with an insertion of heterochromatin into chromosome arm 2R at 59E, the site of the bw gene. Mutagenesis produced 150 dominant suppressors of bwD variegation. These fall into two classes: unlinked suppressors, which also suppress other variegating mutations; and linked chromosome rearrangements, which suppress only bwD. Some rearrangements are broken at 59E, and so might directly interfere with variegation caused by the heterochromatic insertion at that site. However, most rearrangements are translocations broken proximal to bw within the 52D-57D region of 2R. Translocation breakpoints on the X chromosome are scattered throughout the X euchromatin, while those on chromosome 3 are confined to the tips. This suggests that a special property of the X chromosome suppresses bwD variegation, as does a distal autosomal location. Conversely, two enhancers of bwD are caused by translocations from the same part of 2R to proximal heterochromatin, bringing the bwD heterochromatic insertion close to the chromocenter with which it strongly associates. These results support the notion that heterochromatin formation at a genetic locus depends on its location within the nucleus.

Epigenetic effects in eukaryotic gene expression

In the broadest terms, epigenetic phenomena in eukaryotes depend on the interaction of alleles or repeated sequences or on the mitotic inheritance of chromatin states or methylation patterns. One of the most exciting aspects of the study of epigenetic phenomena is the insight that can be gained into the structure and assembly of higher-order chromatin structures, an important subject that has proved refractory to current biochemical methodologies. Rapid progress in the study of gene inactivation in fungi, plants, and invertebrates will provide new hypotheses to be tested in mammals.

Analysis of Drosophila chromosome 4 using pulsed field gel electrophoresis

Previous estimates of the size of Drosophila melanogaster chromosome 4 have indicated that it is 1% to 4% of the genome or approximately 6 Mb. We have used pulsed field gel electrophoresis (PFGE) to separate megabase-sized molecules of D. melanogaster chromosomal DNA. Southern blots of these gels were probed with DNA fragments from the cubitus interruptus and zfh-2 genes, which are located on chromosome 4. They each identify the same-sized distinct band that migrates at approximately 5.2 Mb in DNA preparations from the Kc cell line. We interpret this band to be intact chromosome 4. In DNA obtained from embryos of various D. melanogaster wild-type strains, this chromosome band showed strain-specific size variation that ranged from 4.5 to 5.2 Mb. The D. melanogaster chromosome 4 probes also identified a single, 2.4 Mb band in embryonic DNA from Drosophila simulans. We conclude that D. simulans chromosome 4 is substantially smaller than that of D. melanogaster, presumably owing to differences in the amount of heterochromatic DNA sequences. Our simple DNA preparation from embryos and PFGE conditions should permit preparative isolation of chromosome 4 DNA and will facilitate the molecular mapping of this chromosome.

Cytogenetical localization of Zygotic hybrid rescue (Zhr), a Drosophila melanogaster gene that rescues interspecific hybrids from embryonic lethality

Hybrid females from crosses between Drsophila melanogaster males and females of its sibling species, D. simulans, D. mauritiana, or D. sechellia die as embryos. This lethality is believed to be caused by incompatibility between the X chromosome of D. melanogaster and the maternal cytoplasm. Zygotic hybrid rescue (Zhr) prevents this embryonic lethality and has been cytogenetically mapped to a proximal region of the X chromosome of D. melanogaster, probably in the centromeric heterochromatin. We have carried out high resolution cytological mapping of Zhr using deficiencies and duplications of the X heterochromatin. Deletions of the Zhr+ gene from the hybrid genome exhibit the Zhr phenotype. On the contrary, addition of the wild-type gene to the hybrid genome causes embryonic lethality, regardless of sex. The Zhr locus has been narrowed down to the region covered by Dp(1;f)1162 but not covered Dp(1;f)1205, a chromosome carrying a duplication of heterochromatin located slightly distal to the In(1)sc8 heterochromatic break-point.

Synthesis of free X duplications carrying a specific region of the centromeric heterochromatin in Drosophila melanogaster

Free X duplication chromosomes of Drosophila melanogaster were synthesized by X-ray irradiating the In(1)scL8Lsc8R chromosome which has a deletion in the distal half of hA and the proximal half of hB of the centromeric heterochromatin. Fifty-nine duplications have been isolated and cytogenetically analyzed. They all carry wild-type allele of the yellow gene, y+, which should come from the distal tip of In(1)scL8Lsc8R. They appear to be telocentric and predominantly heterochromatic. Majority of the duplications, especially in the classes MEDIUM and LARGE, can pair with XYL.YS in the male meiosis, indicating that they carry male meiotic pairing site(s) that is known to be located exclusively in the X heterochromatin. Complementation test in the males, Df(1)svr, v/Dp, y+, demonstrates that most of the duplications in the classes MEDIUM and LARGE carry euchromatin enough to cover the deletion. The portion of the euchromatin should be of the very proximal region close to the irradiated X chromosome centromere.

Preferential transposition of Drosophila P elements to nearby chromosomal sites

Two different schemes were used to demonstrate that Drosophila P elements preferentially transpose into genomic regions close to their starting sites. A starting element with weak rosy+ marker gene expression was mobilized from its location in the subtelomeric region of the 1,300-kb Dp1187 minichromosome. Among progeny lines with altered rosy+ expression, a much higher than expected frequency contained new insertions on Dp1187. Terminal deficiencies were also recovered frequently. In a second screen, a rosy(+)-marked element causing a lethal mutation of the cactus gene was mobilized in male and female germlines, and viable revertant chromosomes were recovered that still contained a rosy+ gene due to an intrachromosomal transposition. New transpositions recovered using both methods were mapped between 0 and 128 kb from the starting site. Our results suggested that some mechanism elevates the frequency 43-67-fold with which a P element inserts near its starting site. Local transposition is likely to be useful for enhancing the rate of insertional mutation within predetermined regions of the genome.

Efficient and dispersed local P element transposition from Drosophila females

We have investigated how Drosophila P element insertions are distributed in the chromosomal region near their starting site. A single P element residing in the euchromatin of minichromosome Dp1187 was mobilized following a cross to the delta 2-3 (99B) strain, and progeny bearing transpositions were identified with a minimum of bias by performing Southern blots on progeny. Approximately 1-2% of all progeny minichromosomes contained new insertions. Many of these "local transpositions" landed very close to or within the starting P element; however, nearly 1% of all progeny chromosomes contained new insertions 1-180 kb from the donor element. More local insertions were observed in the progeny of females than from male parents, and most occurred in a preferred orientation relative to the starting element. These observations suggested that donor elements are frequently excised and reinserted locally without ever dissociating from a transposition complex. The high frequency and diverse distribution of local transpositions recovered from females suggested that the efficiency of insertional mutagenesis can be significantly enhanced by using a starting P element(s) located near the target of interest.

Examination of DNA sequences undergoing chromatin conformation changes at a variegating breakpoint in Drosophila melanogaster

Position effect variegation in Drosophila melanogaster is associated with the inability of certain genes to be correctly expressed in a proportion of cells, giving a mosaic phenotype. The lack of expression is thought to be due to alterations in the gene's chromatin structure due to its proximity to a region of heterochromatin. Because of the difficulties involved, there is little biochemical data to support the intuitively appealing model of 'heterochromatin spreading' used to explain this phenomenon. Differences in restriction fragment length were used to distinguish DNA regions from either normal (non-position affected) or rearranged (position affected) chromosomes so as to examine possible changes in gene copy number and the effects of endogenous nucleases. DNA sequences at the breakpoint of In(1)wm4, which variegates for the white gene, were assayed under conditions where the chromatin conformation was altered using second site modifier mutations (Su(var) or En(var)). No change in the DNA sequence copy number was observed at either chromosome breakpoint, relative to wild type, when either suppressor or enhancer mutations were present. Therefore copy number change, through differential polyploidization or somatic gene loss, is not affected by Su(var) or En(var) induced changes in the chromatin conformation. Initial experiments showed a gross difference in the sensitivity of DNA to endogenous nucleases that appeared associated with Su(var) and En(var) mutations. En(var) mutation bearing samples appeared delayed in the digestion, relative to Su(var).(ABSTRACT TRUNCATED AT 250 WORDS)

Replication forks are not found in a Drosophila minichromosome demonstrating a gradient of polytenization

Differential DNA replication is widely held to influence polytene chromosome structure by causing the dramatic reductions in heterochromatic DNA content that are characteristic of most endopolyploid cells. The "underreplication model" of heterochromatic sequence underrepresentation predicts that replication intermediates should populate regions of DNA between fully polytenized euchromatic sequences and underpolytenized heterochromatic sequences. We directly tested this prediction using Dp1187, a 1300 kb Drosophila minichromosome containing well-defined heterochromatic regions. DNA from a euchromatic/heterochromatic junction region of Dp1187, demonstrating a significant gradient of underrepresentation in larval salivary glands, lacked the stalled replication forks predicted by the underreplication model. We consider an alternative mechanism leading to heterochromatic sequence underrepresentation involving a process of DNA elimination.

Nucleotide variation and molecular structure of the heterochromatic repetitive AluI DNA in the brine shrimp Artemia franciscana

It has been suggested that DNA bending could play a role in the regulation of gene expression, chromosome segregation, specific recombination and/or DNA packaging. We have previously demonstrated that an AluI DNA family of repeats is the major component of constitutive heterochromatin in the brine shrimp A. franciscana. By the analysis of cloned oligomeric (monomer to hexamer) heterochromatic fragments we verified that the repetitive AluI DNA shows a stable curvature that determines a solenoidal geometry to the double helix. This particular structure could be of relevant importance in conferring the characteristic heterochromatic condensation. In this paper we evaluate how the point mutations that occurred during the evolution of the AluI sequence of A. franciscana could influence the sequence-dependent tridimensional conformation. The obtained data underline that, in spite of the high sequence mutation frequency (10%) of the repetitive DNA, the general structure of the heterochromatic DNA is not greatly influenced, but rather there is a substantial variation of the copy number of the repetitive AluI fragment. This variation could be responsible for the hypothetical function of the constitutive heterochromatin.

Heterochromatin protein 1, a known suppressor of position-effect variegation, is highly conserved in Drosophila

The Su(var)205 gene of Drosophila melanogaster encodes heterochromatin protein 1 (HP1), a protein located preferentially within beta-heterochromatin. Mutation of this gene has been associated with dominant suppression of position-effect variegation. We have cloned and sequenced the gene encoding HP1 from Drosophila virilis, a distantly related species. Comparison of the predicted amino acid sequence with Drosophila melanogaster HP1 shows two regions of strong homology, one near the N-terminus (57/61 amino acids identical) and the other near the C-terminus (62/68 amino acids identical) of the protein. Little homology is seen in the 5' and 3' untranslated portions of the gene, as well as in the intronic sequences, although intron/exon boundaries are generally conserved. A comparison of the deduced amino acid sequences of HP1-like proteins from other species shows that the cores of the N-terminal and C-terminal domains have been conserved from insects to mammals. The high degree of conservation suggests that these N- and C-terminal domains could interact with other macromolecules in the formation of the condensed structure of heterochromatin.

Distinct families of site-specific retrotransposons occupy identical positions in the rRNA genes of Anopheles gambiae

Two distinct site-specific retrotransposon families, named RT1 and RT2, from the sibling mosquito species Anopheles gambiae and A. arabiensis, respectively, were previously identified. Both were shown to occupy identical nucleotide positions in the 28S rRNA gene and to be flanked by identical 17-bp target site duplications. Full-length representatives of each have been isolated from a single species, A. gambiae, and the nucleotide sequences have been analyzed. Beyond insertion specificity, RT1 and RT2 share several structural and sequence features which show them to be members of the LINE-like, or non-long-terminal-repeat retrotransposon, class of reverse transcriptase-encoding mobile elements. These features include two long overlapping open reading frames (ORFs), poly(A) tails, the absence of long terminal repeats, and heterogeneous 5' truncation of most copies. The first ORF of both elements, particularly ORF1 of RT1, is glutamine rich and contains long tracts of polyglutamine reminiscent of the opa repeat. Near the carboxy ends, three cysteine-histidine motifs occur in ORF1 and one occurs in ORF2. In addition, each ORF2 contains a region of sequence similarity to reverse transcriptases and integrases. Alignments of the protein sequences from RT1 and RT2 reveal 36% identity over the length of ORF1 and 60% identity over the length of ORF2, but the elements cannot be aligned in the 5' and 3' noncoding regions. Unlike that of RT2, the 5' noncoding region of RT1 contains 3.5 copies of a 500-bp subrepeat, followed by a poly(T) tract and two imperfect 55-bp subrepeats, the second spanning the beginning of ORF1. The pattern of distribution of these elements among five siblings species in the A. gambiae complex is nonuniform. RT1 is present in laboratory and wild A. gambiae, A. arabiensis, and A. melas but has not been detected in A. quadriannulatus or A. merus. RT2 has been detected in all available members of the A. gambiae complex except A. merus. Copy number fluctuates, even among the offspring of individual wild female A. gambiae mosquitoes. These findings reflect a complex evolutionary history balancing gain and loss of copies against the coexistence of two elements competing for a conserved target site in the same species for perhaps millions of years.

Distinct families of site-specific retrotransposons occupy identical positions in the rRNA genes of Anopheles gambiae

Two distinct site-specific retrotransposon families, named RT1 and RT2, from the sibling mosquito species Anopheles gambiae and A. arabiensis, respectively, were previously identified. Both were shown to occupy identical nucleotide positions in the 28S rRNA gene and to be flanked by identical 17-bp target site duplications. Full-length representatives of each have been isolated from a single species, A. gambiae, and the nucleotide sequences have been analyzed. Beyond insertion specificity, RT1 and RT2 share several structural and sequence features which show them to be members of the LINE-like, or non-long-terminal-repeat retrotransposon, class of reverse transcriptase-encoding mobile elements. These features include two long overlapping open reading frames (ORFs), poly(A) tails, the absence of long terminal repeats, and heterogeneous 5' truncation of most copies. The first ORF of both elements, particularly ORF1 of RT1, is glutamine rich and contains long tracts of polyglutamine reminiscent of the opa repeat. Near the carboxy ends, three cysteine-histidine motifs occur in ORF1 and one occurs in ORF2. In addition, each ORF2 contains a region of sequence similarity to reverse transcriptases and integrases. Alignments of the protein sequences from RT1 and RT2 reveal 36% identity over the length of ORF1 and 60% identity over the length of ORF2, but the elements cannot be aligned in the 5' and 3' noncoding regions. Unlike that of RT2, the 5' noncoding region of RT1 contains 3.5 copies of a 500-bp subrepeat, followed by a poly(T) tract and two imperfect 55-bp subrepeats, the second spanning the beginning of ORF1. The pattern of distribution of these elements among five siblings species in the A. gambiae complex is nonuniform. RT1 is present in laboratory and wild A. gambiae, A. arabiensis, and A. melas but has not been detected in A. quadriannulatus or A. merus. RT2 has been detected in all available members of the A. gambiae complex except A. merus. Copy number fluctuates, even among the offspring of individual wild female A. gambiae mosquitoes. These findings reflect a complex evolutionary history balancing gain and loss of copies against the coexistence of two elements competing for a conserved target site in the same species for perhaps millions of years.

Somatic instability of a Drosophila chromosome

A mitotically unstable chromosome, detectable because of mosaic expression of marker genes, was generated by X-ray mutagenesis in Drosophila. Nondisjunction of this chromosome is evident in mitotic chromosome preparations, and premature sister chromatid separation is frequent. The mosaic phenotype is modified by genetic elements that are thought to alter chromatin structure. We hypothesize that the mitotic defects result from a breakpoint deep in the pericentric heterochromatin, within or very near to the DNA sequences essential for centromere function. This unique chromosome may provide a tool for the genetic and molecular dissection of a higher eukaryotic centromere.

Dodeca satellite: a conserved G+C-rich satellite from the centromeric heterochromatin of Drosophila melanogaster

To identify sequences from the centromeric region, we have constructed a Drosophila melanogaster yeast artificial chromosome (YAC) library and screened it with purified DNA from the minichromosome Dp(1;f)1187 derived from the X chromosome. We describe the structure of one clone isolated in this way. This YAC is structurally unstable and contains tandemly repeated G+C-rich 11-mer and 12-mer units, which we call dodeca satellite. Most of this satellite is located near the centromere of an autosome. Cross-hybridizing sequences are found in the genomes of organisms as distant as Arabidopsis thaliana and Homo sapiens.

Silencing: the establishment and inheritance of stable, repressed transcription states

Silencing refers to a particular type of transcriptional repression characterized by the formation of a genetically heritable, repressed transcriptional state. Examples of silencing include position-effect variegation, X-chromosome inactivation, and the repression of the silent mating-type gene loci in yeast. Recent discoveries suggest that silencing in yeast, like silencing in larger eukaryotes, results from a particular chromatin structure that defines a chromosomal domain. In addition, a chromosomal origin of DNA replication is required for silencing in yeast, suggesting that DNA replication plays a role in forming functional chromosomal domains.