Modifiers of terminal deficiency-associated position effect variegation in Drosophila

Terminal deletions of a Drosophila minichromosome (Dp(1;f)1187) dramatically increase the position effect variegation (PEV) of a yellow(+) body-color gene located in cis. Such terminal deficiency-associated PEV (TDA-PEV) can be suppressed by the presence of a second minichromosome, a phenomenon termed "trans-suppression." We performed a screen for mutations that modify TDA-PEV and trans-suppression. Seventy suppressors and enhancers of TDA-PEV were identified, but no modifiers of trans-suppression were recovered. Secondary analyses of the effects of these mutations on different PEV types identified 10 mutations that modify only TDA-PEV and 6 mutations that modify TDA-PEV and only one other type of PEV. One mutation, a new allele of Su(var)3-9, affects all forms of PEV, including silencing associated with the insertion of a transgene into telomeric regions (TPE). This Su(var)3-9 allele is the first modifier of PEV to affect TPE and provides a unique link between different types of gene silencing in Drosophila. The remaining mutations affected multiple PEV types, indicating that general PEV modifiers impact TDA-PEV. Modifiers of TDA-PEV may identify proteins that play important roles in general heterochromatin biology, including proteins involved in telomere structure and function and the organization of chromosomes in the interphase nucleus.     

5-Bromodeoxyuridine suppresses position effect variegation of transgenes in HeLa cells

An ectopic gene integrated in the host genome is occasionally silenced due to a position effect of its adjacent chromatin structure. We found that 5-bromodeoxyuridine clearly activated such a transgene in HeLa cells. The transgene was also activated to various degrees by inhibitors of histone deacetylase, DNA topoisomerases, or DNA methyltransferase. The peptide antibiotic distamycin A potentiated markedly the effect of 5-bromodeoxyuridine. Transient expression of an artificial AT-hook protein termed MATH20 also potentiated its effect although significantly activated the transgene alone. Since distamycin A and MATH20 are able to displace histone H1 and other DNA-binding proteins bound to specific AT-rich sequences by a dominant, mutually exclusive fashion, these results suggest that 5-bromodeoxyuridine targets such an AT-rich sequence located adjacent to the silenced transgene, resulting in chromatin accessibility.     

Cytogenetic and molecular aspects of position effect variegation in Drosophila

Variations in compaction of chromosomal material of the rearrangements Dp(1;f) 1337, Dp(1;f) R, Dp(1;1)pn2b, and T(1;4)w ^m258-21, which display an extended position effect, were characterized. Morphological changes found in these rearangements were assigned to two major types: (i) continuous compaction, in which bands and interbands located distal to the eu/heterochromatin junction fuse into one compacted block of chromatin. The extent of compaction is increased by enhancers of position effect (low temperature, removal of the Y or 2R chromosome heterochromatin). In extreme cases compaction extends over dozens of bands. (ii) Discontinuous compaction, in which at least two zones of compaction separated by morphologically normal zones can readily be identified. As a result, some regions located at a greater distance from heterochromatin may be compacted more frequently than others than map nearer to it. A few regions (1D, 2B1-12, 2D) were shown to be most frequently compacted in all rearrangements investigated. The 2B13-18, 2C1-2, 2E, and 2F regions exhibited the lowest frequencies of compaction. Compaction of the zone containing the 2B1-12 bands is always accompanied by inactivation of the ecs locus, which maps in the 2B3-5 puff. At the same time the 2C1-2 and 2E bands located nearer to the breakpoint can retain normal morphology and puffing in response to ecdysterone. The results are interpreted as morphological manifestations of the discontinuity of the spreading effect.by W. Beermann     

Cytogenetic and molecular aspects of position effect variegation in Drosophila melanogaster

A new genetic model system for studying position effect variegation in Drosophila melanogaster was found. It allows the analysis of genetic inactivation and changes in chromosome morphology in the same cells. In T(1;2)dor ^var7 strains the 2B5 early ecdysone puff, and the ecs locus which maps in this puff are translocated into the vicinity of centromeric heterochromatin. The ecs locus plays a key role in the system of ecdysone puffs: genetic damage to this locus results in loss of sensitivity of cells to the hormone and, as a consequence, ecdysone-induced puffs do not develop. In the T(1;2)dor ^var7 chromosome the ecs and at least five adjoining loci are inactivated in a variegated fashion. In the salivary gland cells of T(1;2)dor ^var7/ ecs^lt435 0 h prepupae which do not show the ecdysone puffs, the morphology of the 2B region was analysed. In all cases where the ecs locus was inactivated, a dense block of chromatin reminiscent of a solid band was found in the 2B region instead of the four bands 2B1–2, 3–4, 5 and 6. Sometimes compaction of the chromatin reached the 2A1–2 or even 1E1–4 bands. Formation of the compact block of chromatin coincided with late replication in this region. In situ hybridization of polytene chromosomes with a DNA clone from the ecs locus showed that when the dense chromatin block was present, no DNA was accessible for hybridization in 2B5. Hybridization of DNA of another clone located in the region of the translocation breakpoint (2B7–8) was found only in polytene chromosomes of larvae grown at 25° C, and never in those grown at 18° C, independently of the morphology of the 2B5 puff. The possibility that in the case of block formation both late replication and, as a consequence, underreplication of chromosome DNA take place, is discussed.Dedicated to Professor W. Beermann on the occasion of his 65th birthday     

Cytogenetic and molecular aspects of position effect variegation in Drosophila melanogaster

A chromosomal region subjected to position effect variegation was analysed for possible DNA under-replication. DNA clones from the vicinity of the euheterochromatin junction and from a distance of hundreds of kilobase pairs were used as probes. Formation of compact blocks of chromatin is regarded as a characteristic feature of position effect variegation. It was shown that in T (1;2) dor ^var7 males undergoing position effect variegation clones representing the DNA nearest to the breakpoint in 2B7 hybridized normally in situ to the compact blocks, providing evidence against DNA underreplication. In females the same clones did not hybridize to the compact blocks. These variations in hybridization may be related to different degrees of compaction of chromosome regions in males and females. A correlation between the degree of underreplication and the level of cell polyteny was shown by Southern-blot hybridization of a DNA probe from the 2B region to DNA from an X/O strain carrying Dp (1;1)pn2b displaying position effect variegation and compaction in 94% of salivary gland cells. Almost complete underreplication of the DNA of this region was found in salivary gland cells (with a maximal degree of polyteny), intermediate underreplication was found in fat body cells (with an intermediate degree of polyteny), and replication was not disturbed in diploid cells of the larval cephalic complex.by W. Beermann     

In vivo protein trapping in Drosophila.

The deciphering of complete genome sequences has opened a post-genomic proteomics era. While the sequence of many proteins is now known, attention will increasingly focus on the complex interaction networks that regulate their activity, and the analysis of protein distribution in the cell will be crucial to elucidating their function. A new generation of gene trapping devices, protein trap transposons, offers a way of analysing In vivo the dynamics of sub-cellular distribution of a large number of proteins. Many transgenic lines have already been established and are available. Screens focusing on particular cell compartments can be devised.     

Dosage-dependent modifiers of position effect variegation in Drosophila and a mass action model that explains their effect

Twelve dominant enhancers of position effect variegation, representing four loci on the second and third chromosomes of Drosophila melanogaster, have been induced by P-element mutagenesis. Instead of simple transposon insertions, seven of these mutations are cytologically visible duplications and three are deficiencies. The duplications define two distinct regions, each coinciding with a locus that also behaves as a dominant haplo-dependent suppressor of variegation. Conversely, two of the deficiencies overlap with a region that contains a haplo-dependent enhancer of variegation while duplications of this same region act to suppress variegation. The third deficiency defines another haplo-dependent enhancer. These data indicate that loci capable of modifying variegation do so in an antipodal fashion through changes in the wild-type gene copy number and may be divided into two reciprocally acting classes. Class I modifiers enhance variegation when duplicated or suppress variegation when deficient. Class II modifiers enhance when deficient but suppress when duplicated. From our data, and those of others, we propose that in Drosophila there are about 20 to 30 dominant loci that modify variegation. Most appear to be of the class I type whereas only two class II modifiers have been identified so far. From these observations we put forth a model, based on the law of mass action, for understanding how such suppressor-enhancer loci function. We propose that each class I modifier codes for a structural protein component of heterochromatin and their effects on variegation are a consequence of their dosage dependent influence on the extent of the assembly of heterochromatin at the chromosomal site of the position effect. It is further proposed that class II modifiers may inhibit the class I products directly, bind to hypothetical termination sites that define heterochromatin boundaries or promote euchromatin formation. Consistent with our mass action model we find that combining two enhancers together produce additive and not epistatic effects. Also, since different enhancers have different relative strengths on different variegating mutants, we suggest that heterochromatic domains are constructed by a combinatorial association of proteins. The mass action model proposed here is of general significance for any assembly driven reaction and has implications for understanding a wide variety of biological phenomena.(ABSTRACT TRUNCATED AT 400 WORDS)     

Neuronal acetylcholine receptors in Drosophila: the ARD protein is a component of a high-affinity alpha-bungarotoxin binding complex.

The ard gene of Drosophila melanogaster encodes a structural homologue of vertebrate nicotinic acetylcholine receptors (AChR) and is expressed exclusively in nervous tissue. To study the nature of the ARD protein, antibodies were raised against fusion constructs containing two regions of this polypeptide. One segment is putatively extracellular (amino acids 65-212), the other domain is exposed to the cytoplasm (amino acids 305-444). The ARD antisera obtained served to investigate the physical relationship between the ARD protein and alpha-bungarotoxin (alpha-Btx) binding sites occurring in Drosophila. Two different high-affinity binding sites for [125I]alpha-Btx, a highly potent antagonist of vertebrate muscle AChR, were detected in fly head membranes. Equilibrium binding and kinetic studies revealed Kd values of approximately 0.1 nM (site 1) and approximately 4 nM (site 2). The estimated maximal binding (Bmax) was approximately 240 and 1080 fmol/mg protein respectively. Both sites exhibited a nicotinic-cholinergic pharmacology. Immunoprecipitation experiments with the ARD antisera indicated that the ARD protein is associated with the [125I]alpha-Btx binding site 1 only. These data support the previously postulated hypothesis that the ARD protein is part of an alpha-Btx binding neuronal AChR of Drosophila. Furthermore, they indicate heterogeneity in nicotinic-cholinergic binding sites in the insect nervous system.     

Position effect variegation in Drosophila: towards a genetics of chromatin assembly

The formation of a highly condensed chromosome structure (heterochromatin) in a region of a eukaryotic chromosome can inactivate the genes within that region. Genetic studies using the fruitfly Drosophila melanogaster have identified several essential genes which influence the formation of heterochromatin. My purpose in this review is to summarize some recent work on the genetics of heterochromatin assembly in Drosophila and a recent model for how chromosomal proteins may interact to form a heterochromatic structure.     

In vivo function of a novel Siah protein in Drosophila

The Siah proteins, mammalian homologues of the Drosophila Sina protein, function as E3 ubiquitin ligase enzymes and target a wide range of cellular proteins for degradation. Here, I investigate the in vivo function of the fly protein, Sina-Homologue (SinaH), which is highly similar to Sina. Flies that completely lack SinaH are viable and in combination with a mutation in the gene, Ebi, show an extra dorsal central bristle phenotype. I also show that SinaH and Ebi can interact with each other both in vivo and in vitro suggesting that they act in the same physical complex. Flies that lack both Sina and Sina-Homologue were also created and show visible eye and bristle phenotypes, which can be explained by an inability to degrade the neuronal repressor, Tramtrack. I find no evidence for redundancy in the function of Sina and SinaH.     

Heterochromatin of the Drosophila melanogaster Y chromosome as modifier of position effect variegation: the time of its action.

Summary Addition of heterochromatin suppresses while subtraction enhances position effect variegation. The heterochromatin-sensitive period has been determined in white/white-apricot variegated eyes of Y ^S w ^a /w ^a ; Dp (1;3) w ^265-58 flies. When such larvae, carrying a Y-short (Y ^S ) arm at the distal end of one X chromosome, are X-rayed, mitotic recombination leads to one daughter cell with two Y ^S arms and an adjacent daughter cell with no Y ^S arm. When induced after clonal initiation, the frequency of dark clones developing from daughter cells with two Y ^S arms is significantly higher than the frequency of dark clones in the rest of the eye; and this frequency is. even higher when induced before clonal initiation. The modifying action of the Y-heterochromatin is exerted, therefore, during and after clonal initiation. Surprisingly, the frequency of dark clones developing from cells with no Y ^S arm is not lower than the frequency of dark clones in the rest of the eye.     

Genetic and molecular complexity of the position effect variegation modifier mod(mdg4) in Drosophila

mod(mdg4), also known as E(var)3-93D, is involved in a variety of processes, such as gene silencing in position effect variegation (PEV), the control of gypsy insulator sequences, regulation of homeotic gene expression, and programmed cell death. We have isolated a large number of mod(mdg4) cDNAs, representing 21 different isoforms generated by alternative splicing. The deduced proteins are characterized by a common N terminus of 402 amino acids, including the BTB/POZ-domain. Most of the variable C termini contain a new consensus sequence, including four positioned hydrophobic amino acids and a Cys(2)His(2) motif. Using specific antibodies for two protein isoforms, we demonstrate different distributions of the corresponding proteins on polytene chromosomes. Mutations in the genomic region encoding exons 1-4 show enhancement of PEV and homeotic transformation and affect viability and fertility. Homeotic and PEV phenotypes are enhanced by mutations in other trx-group genes. A transgene containing the common 5' region of mod(mdg4) that is present in all splice variants known so far partially rescues the recessive lethality of mod(mdg4) mutant alleles. Our data provide evidence that the molecular and genetic complexity of mod(mdg4) is caused by a large set of individual protein isoforms with specific functions in regulating the chromatin structure of different sets of genes throughout development.     

The size and internal structure of a heterochromatic block determine its ability to induce position effect variegation in Drosophila melanogaster

In the In(1LR)pn2a rearrangement, the 1A-2E euchromatic segment is transposed to the vicinity of X heterochromatin (Xh), resulting in position effect variegation (PEV) of the genes in the 2BE region. Practically the whole X-linked heterochromatin is situated adjacent to variegated euchromatic genes. Secondary rearrangements showing weakening or reversion of PEV were obtained by irradiation of the In(1LR)pn2a. These rearrangements demonstrate a positive correlation between the strength of PEV of the wapl locus and the sizes of the adjacent heterochromatic blocks carrying the centromere. The smallest PEV-inducing fragment consists of a block corresponding to approximately 10% of Xh and containing the entire XR, the centromere, and a very proximal portion of XL heterochromatin. Heterochromatic blocks retaining the entire XR near the 2E region, but lacking the centromere, show no PEV. Reversion of PEV was also observed as a result of an internal rearrangement of the Xh blocks where the centromere is moved away from the eu-heterochromatin boundary but the amount of X heterochromatin remaining adjacent to 2E is unchanged. We propose a primary role of the X pericentromeric region in PEV induction and an enhancing effect of the other blocks, positively correlated with their size.     

Nurse cell polytene chromosomes of Drosophila melanogaster otu mutants: Morphological changes accompanying interallelic complementation and position effect variegation

Combinations of certain mutant alleles of the ovarian tumor gene permit the production of viable eggs. Two alleles that behave in this way are otu⁷ and otu¹. Females homozygous for either allele are sterile, and their ovarian nurse cells (NC) contain giant polytene chromosomes of various morphologies. Fertile flies (otu⁺ / otu⁺, otu⁻ / otu⁷, otu⁺ / otu¹¹) have endopolyploid nurse cells with typical dispersed chromosomes. Fertile hybrids (otu⁷ / otu¹¹) produce large numbers of polytene chromosomes comparable to, and often larger than, classic salivary gland (SG) chromosomes. Therefore, these otu hybrids provide a unique system for studying, at the chromosomal level, the activation and expression of genes functioning during oogenesis. The otu gene encodes a long and a short isoform. The normal long isoform appears to be responsible for the dispersion of chromosomes during the endomitotic DNA replications occurring in ovarian NCs. The genetic inactivation of euchromatic genes placed next to pericentric heterochromatin by a chromosomal rearrangement is accompanied by the compaction of corresponding chromosome regions. A comparative study of the manifestation of position-effect variegation for the polytene chromosomes of SG cells and NCs was made using the Dp(1;1)pn2b and Dp(1;f)1337 rearrangements. The percentage frequencies of block formation in the SG and NC nuclei for Dp (1;1) pn2b rearrangement were 92.6% vs. 15.8%, respectively; for Dp(1;f) 1337, these values were 56.8% vs. 9.7%. Therefore heterochromatin belonging to germ line chromosomes is in a configuration that is far less likely to inactivate inserted segments of euchromatin than is heterachromatin from somatic chromosomes. Dev. Genet. 20:163–174. 1997. © 1997 Wiley-Liss, Inc.     

In vivo analysis of a fluorescent SUMO fusion in transgenic Drosophila

Sumoylation, the covalent attachment of SUMO, a 90 amino acid peptide related to ubiquitin, is a major modulator of protein functions. Fluorescent SUMO protein fusions have been used in cell cultures to visualize SUMO in vivo but not in multicellular organisms. We generated a transgenic line of Drosophila expressing an mCherry-SUMO fusion. We analyzed its pattern in vivo in salivary gland nuclei expressing Venus-HP1 to recognize the different chromatin components (Chromocenter, chromosome IV). We compared it to SUMO immunostaining on squashed polytene chromosomes and observed similar patterns. In addition to the previously reported SUMO localizations (chromosome arms and chromocenter), we identify 2 intense binding sites: the fourth chromosome telomere and the DAPI-bright band in the region 81F.