[Polycomb and trithorax control genome expression by determining the alternative epigenetic states of chromatin for key developmental regulators].

The Polycomb (PcG) and Trithorax (TrxG) group proteins are essential for development in all multicellular organisms. Mutations of the PcG and TrxG genes act as early embryonic lethals, while their overexpression correlates with malignancies. Comparative genome analysis showed that PcG and TrxG form a binary regulatory system that functions as an epigenetic rheostat to determine the threshold levels of extracellular signals affecting the expression levels of key developmental genes.

Loss of insulator activity by paired Su(Hw) chromatin insulators.

Chromatin insulators are regulatory elements that block the action of transcriptional enhancers when interposed between enhancer and promoter. The Drosophila Suppressor of Hairy wing [Su(Hw)] protein binds the Su(Hw) insulator and prevents enhancer-promoter interaction by a mechanism that is not understood. We show that when two copies of the Su(Hw) insulator element, instead of a single one, are inserted between enhancer and promoter, insulator activity is neutralized and the enhancer-promoter interaction may instead be facilitated. This paradoxical phenomenon could be explained by interactions between protein complexes bound at the insulators.

Chromatin complexes regulating gene expression in Drosophila.

Polycomb-group proteins form chromatin complexes at target genes such as Ubx, providing a cellular memory of gene activity in early development and determining the later activity of the gene. The complexes, whose constituents vary depending on site and genomic context, initiate at specific sites, but can extend to involve larger chromatin domains. How they persist through cell proliferation and how they silence gene activity are still open issues.

PcG complexes and chromatin silencing.

Silencing complexes in yeast and in the fly have many similarities. This repressive complex is assembled by a chain of recruitment; its extent and stability depend on the concentration of components and affect an extended chromatin region, probably through interactions with nucleosomes. Recent results show that assembly of the complex is antagonized by transcriptional activity in the region but is favored by interactions with other complexes nearby or in other regions that associate in the same nuclear environment. How such a complex interferes with transcriptional activity is not entirely clear but current evidence suggests that they compete with the chromatin structure required for the binding of activators.

Chromatin-silencing mechanisms in Drosophila maintain patterns of gene expression.

The Polycomb-Group proteins form chromatin complexes that can silence gene expression over large distances. The formation of these complexes at homeotic genes depends on early developmental events but the repressed state is then maintained through many cell divisions. In vivo, complexes formed at one genomic site can interact with those at other sites, suggesting that they, like heterochromatin complexes, affect the folding of chromatin and the organization of chromosomes in the nucleus.

P transposons controlled by the heat shock promoter.

We have transformed Drosophila melanogaster with modified P-element transposons, which express the transposase function from the heat-inducible hsp70 heat shock promoter. The Icarus transposon, which contains a direct hsp70-P fusion gene, behaved like a very active autonomous P element even before heat shock induction. Although heat shock led to abundant somatic transcription, transposition of the Icarus element was confined to germ line cells. To reduce the constitutive transposase activity observed for the Icarus element, we attenuated the translational efficiency of the transposase RNA by inserting the transposon 5 neomycin resistance gene between the hsp70 promoter and the P-element sequences. The resulting construct, called Icarus-neo, conferred resistance to G418, and its transposition was significantly stimulated by heat shock. Heat shocks applied during the embryonic or third instar larval stage had similar effects, indicating that transposition of P elements is not restricted to a certain developmental stage. Both Icarus and Icarus-neo destabilized snw in a P-cytotype background and thus at least partially overcome the repression of transposition. Our results suggest that the regulation of P-element transposition occurs at both the transcriptional and posttranscriptional levels.

Conserved DNA binding and self-association domains of the Drosophila zeste protein.

The zeste gene product is involved in two types of genetic effects dependent on chromosome pairing: transvection and the zeste-white interaction. Comparison of the predicted amino acid sequence with that of the Drosophila virilis gene shows that several blocks of amino acid sequence have been very highly conserved. One of these regions corresponds to the DNA binding domain. Site-directed mutations in this region indicate that a sequence resembling that of the homeodomain DNA recognition helix is essential for DNA binding activity. The integrity of an amphipathic helical region is also essential for binding activity and is likely to be responsible for dimerization of the DNA binding domain. Another very strongly conserved domain of zeste is the C-terminal region, predicted to form a long helical structure with two sets of heptad repeats that constitute two long hydrophobic ridges at opposite ends and on opposite faces of the helix. We show that this domain is responsible for the extensive aggregation properties of zeste that are required for its role in transvection phenomena. A model is proposed according to which the hydrophobic ridges induce the formation of open-ended coiled-coil structures holding together many hundreds of zeste molecules and possibly anchoring these complexes to other nuclear structures.

Structure of a polycomb response element and in vitro binding of polycomb group complexes containing GAGA factor.

Polycomb response elements (PREs) are regulatory sites that mediate the silencing of homeotic and other genes. The bxd PRE region from the Drosophila Ultrabithorax gene can be subdivided into subfragments of 100 to 200 bp that retain different degrees of PRE activity in vivo. In vitro, embryonic nuclear extracts form complexes containing Polycomb group (PcG) proteins with these fragments. PcG binding to some fragments is dependent on consensus sequences for the GAGA factor. Other fragments lack GAGA binding sites but can still bind PcG complexes in vitro. We show that the GAGA factor is a component of at least some types of PcG complexes and may participate in the assembly of PcG complexes at PREs.

Polycomb silencing mechanisms and genomic programming.

Polycomb complexes, best known for their role in the epigenetic silencing of homeotic genes, are now known to regulate a large number of functions in organisms from flies to man. They control transcription activators, pattern-forming genes, maintenance of stem cells and are implicated in cell proliferation and oncogenesis. Our understanding of Polycomb mechanisms derives principally from the study of homeotic genes in Drosophila, where they act in an all-or-none fashion to silence expression in inappropriate parts of the organism. This review summarizes what has been learned from homeotic genes and examines the possible extensions of Polycomb mechanisms to allow for dynamic regulatory behavior and the reprogramming of silenced chromatin states.

Two adjacent genomic zein sequences: structure, organization and tissue-specific restriction pattern.

A clone isolated from a library of genomic clones from Zea mays contains two adjacent zein light-chain genes. The nucleotide sequence of the two coding regions and their flanking sequences shows that the two genes represent two different subclasses of light-chain zeins. One belongs to an abundant and highly conserved class and the other, which is 88% homologous to the first, is less represented in the genome of maize line W64A. Both genes present in clone zE are anomalous: one contains a mutation that introduces a termination codon after 39 amino acids, the other has the ATG initiation codon mutated to CTG. The presence of inversions, insertions and short inverted or direct repeats in the flanking sequences suggests that zein genes may be subject to rearrangements and transpositions. Southern blot analysis of genomic DNA indicates that the particular arrangement represented by clone zE is present at least four times in maize line W64A but other arrangements are found in this and other maize lines. DNA extracted from different tissues and developmental stages is digested differently by enzymes sensitive to methylation of their target sequence. The results indicate that zein genes contain methylated sites that are demethylated in correlation with their expression.

Dosage compensation of the Drosophila white gene requires both the X chromosome environment and multiple intragenic elements.

The X-linked white gene when transposed to autosomes retains only partial dosage compensation. One copy of the gene in males expresses more than one copy but less than two copies in females. When inserted in ectopic X chromosome sites, the mini-white gene of the CaspeR vector can be fully dosage compensated and can even achieve hyperdosage compensation, meaning that one copy in males gives more expression than two copies in females. As sequences are removed gradually from the 5' end of the gene, we observe a progressive transition from hyperdosage compensation to full dosage compensation to partial dosage compensation. When the deletion reaches -17, the gene can no longer dosage compensate fully even on the X chromosome. A deletion reaching +173, 4 bp preceding the AUG initiation codon, further reduces dosage compensation both on the X chromosome and on autosomes. This truncated gene can still partially dosage compensate on autosomes, indicating the presence of dosage compensation determinants in the protein coding region. We conclude that full dosage compensation requires an X chromosome environment and that the white gene contains multiple dosage-compensation determinants, some near the promoter and some in the coding region.

Molecular analysis of the zeste-white interaction reveals a promoter-proximal element essential for distant enhancer-promoter communication.

We have analyzed the eye and testis enhancers located 1 kb upstream of the transcription start site of the white gene. Both enhancers confer the corresponding tissue-specific expression on a heterologous promoter as well as on the white promoter. The eye determinant consists of multiple elements, each able to stimulate eye-specific expression. It also contains five binding sites for the zeste protein while the immediately adjacent testis element contains none. Site-directed mutation of these zeste binding sites abolishes the zeste-white interaction but does not significantly affect the eye enhancer activity, indicating that they are not important for the eye enhancer activity per se. Other zeste binding sites just upstream of the promoter are not necessary for the zeste-white interaction. We conclude that the overlap of the eye enhancer with the zeste binding sites is responsible for the zeste-white interaction and explains why this interaction affects eye but not testis expression. Sequence deletion or substitution experiments suggested that the white promoter is internal to the transcription start site; the zeste protein is not required for distant enhancer action but a 95-bp promoter-proximal sequence is essential for distant enhancer-promoter interaction. This element may serve as an anchor to stabilize formation of a loop that brings the enhancer to the vicinity of the promoter.

Chromatin insulator elements block the silencing of a target gene by the Drosophila polycomb response element (PRE) but allow trans interactions between PREs on different chromosomes.

Polycomb response elements (PREs) can establish a silenced state that affects the expression of genes over considerable distances. We have tested the ability of insulator or boundary elements to block the repression of the miniwhite gene by the Ubx PRE. The gypsy element and the scs element interposed between PRE and miniwhite gene protect it against silencing but the scs' is only weakly effective. When the PRE-miniwhite gene construct is insulated from flanking chromosomal sequences by gypsy elements at both ends, it can still establish efficient silencing in some lines but not others. We show that this can be caused by interactions in trans with PREs at other sites. PRE-containing transposons inserted at different sites or even on different chromosomes can interact, resulting in enhanced silencing. These trans interactions are not blocked by the gypsy insulator and reveal the importance of nonhomologous associations between different regions of the genome for both silencing and activation of genes. The similarity between the behavior of PREs and enhancers suggests a model for their long-distance action.

Distinct parasegmental and imaginal enhancers and the establishment of the expression pattern of the Ubx gene.

The expression domain of the Ubx gene in Drosophila embryos is bounded by the product of the hb gene, acting as a repressor. We show that all Ubx fragments that bind Hb protein in vitro contain parasegmental enhancers active in the embryo in specific parasegmental patterns. We have found three new embryonic enhancer elements in the upstream region, in addition to the two previously identified. Each produces a pattern initially bounded at PS6 by Hb but sooner or later breaks down this boundary and begins to express in the anterior region. These enhancers do not respond to the long-term maintenance mediated by the Polycomb group of genes. They also cease functioning after germ band extension. Expression in imaginal tissues is due to a set of entirely separate and independent imaginal disc enhancers. These do not contain Hb binding sites and by themselves have no anterior/posterior positional information, although some distinguish between ventral and dorsal discs. A third kind of element, the Polycomb Response Element (PRE), has no enhancer activity but causes long-term maintenance of the expression domain of other enhancers present in the vicinity. The interaction of these elements results in the correct expression of Ubx in imaginal tissues.

The mcp element from the Drosophila melanogaster bithorax complex mediates long-distance regulatory interactions.

In the studies reported here, we have examined the properties of the Mcp element from the Drosophila melanogaster bithorax complex (BX-C). We have found that sequences from the Mcp region of BX-C have properties characteristic of Polycomb response elements (PREs), and that they silence adjacent reporters by a mechanism that requires trans-interactions between two copies of the transgene. However, Mcp trans-regulatory interactions have several novel features. In contrast to classical transvection, homolog pairing does not seem to be required. Thus, trans-regulatory interactions can be observed not only between Mcp transgenes inserted at the same site, but also between Mcp transgenes inserted at distant sites on the same chromosomal arm, or even on different arms. Trans-regulation can even be observed between transgenes inserted on different chromosomes. A small 800-bp Mcp sequence is sufficient to mediate these long-distance trans-regulatory interactions. This small fragment has little silencing activity on its own and must be combined with other Polycomb-Group-responsive elements to function as a "pairing-sensitive" silencer. Finally, this pairing element can also mediate long-distance interactions between enhancers and promoters, activating mini-white expression.

The Drosophila suppressor of underreplication protein binds to late-replicating regions of polytene chromosomes.

In many late-replicating euchromatic regions of salivary gland polytene chromosomes, DNA is underrepresented. A mutation in the SuUR gene suppresses underreplication and leads to normal levels of DNA polytenization in these regions. We identified the SuUR gene and determined its structure. In the SuUR mutant stock a 6-kb insertion was found in the fourth exon of the gene. A single SuUR transcript is present at all stages of Drosophila development and is most abundant in adult females and embryos. The SuUR gene encodes a protein of 962 amino acids whose putative sequence is similar to the N-terminal part of SNF2/SWI2 proteins. Staining of salivary gland polytene chromosomes with antibodies directed against the SuUR protein shows that the protein is localized mainly in late-replicating regions and in regions of intercalary and pericentric heterochromatin.

Molecular and cytogenetical characterization of the 10A1-2 band and adjoining region in the Drosophila melanogaster polytene X chromosome.

Some 300 kb of DNA from the 9F12-10A7 X chromosome region (seven bands) uncovered by Df(1)vL3 were cloned and 31 break points of chromosome rearrangements within the region were mapped. Positions of 12 genes found earlier in genetic saturation experiments, transcripts and P element-induced mutations were located on the physical map using either chromosome rearrangements or Southern blot hybridizations. Data on the position of the break points, genes and polytene chromosome bands allow the following conclusions to be made. (1) The size of the bands in the region varies between 4 kb (10A6 and 7) and 183-195 kb (10A1-2). The compaction ratio of DNA in bands varies from 8-36 (10A6 + 7) to 151-161 (10A1-2). Therefore, fine and thick bands appear to have different kinds of DNP packaging. (2) The bands differ in genetic content. Fine bands contain from one to three genes. In contrast, the 10A1-2 band contains three genes and at least six transcribed DNA fragments. (3) Comparison of genetic and physical maps shows that in this region 0.01 centiMorgan corresponds to 3.3 kb of DNA.

[Effect of four doses of the Su(UR)ES gene on intercalary heterochromatin in Drosophila melanogaster]. / Effekt chetyrekh doz gena Su(UR)ES na interkaliarnyi geterokhromatin u Drosophila melanogaster.

Polytene chromosomes of salivary glands of various Drosophila melanogaster strains containing two doses of the normal Su(UR)ES allele have a constant set of intercalary heterochromatin (IHC) sites. Their DNA is underreplicated, which leads to breaks and ectopic contacts emerging at a certain rate. Almost no underreplication, breaks, or ectopic conjugation are present in mutants lacking the normal Su(UR)ES gene product. It could be expected that an increase in the number of the Su(UR)ES+ gene doses would, in turn, drastically increase ectopic conjugation and breakage. To test this hypothesis, a strain of D. melanogaster was obtained with two additional doses of Su(UR)ES+ introduced into its genome. The flies with four gene doses exhibited a considerable increase in ectopic conjugation: both the proportion of regions participating in conjugation and the number of chromosomes with numerous contact nodes were increased. As a result, chromosomes that were straight and well-stretched in homozygotes for the mutation in Su(UR)ES became twisted and wound and contained many loops or nodes. Many chromosomes were wound too tightly for cytological analysis. Four doses of Su(UR)ES+ considerably increased the number of weak "points." For example, the 2R chromosome has only 3 weak points in strains with two doses of Su(UR)ES+ and as many as 22 weak points in the strain with four doses. In the transgenic strain, the frequency of breaks in previously known weak points increased, and new breaks appeared in 19 additional sites. All new break points appeared in the regions that were earlier described as regions of late replication in the S phase.

[Molecular-genetic analysis of of the band 10A1-2 in the Drosophila melanogaster chromosome X]. / Molekuliaeno-tsitogeneticheskii analiz diska 10A1-2 X-khromosomy Drosophila melanogaster.

With the help of in situ hybridization respective location of 33 microclones from the genomic library of the Drosophila melanogaster large band 10A1-2, 4 clones obtained by chromosomal walking and 18 chromosomal rearrangements with breakpoints in the limits of this band was determined. A DNA fragment homologous to poly(A)+ RNA from the 3rd instar larvae has been revealed. Summarizing the obtained and published data, at least 3 genes and 6 transcriptionally active fragments appear to be located in the 10A1-2 band. Using DNA clones from different regions of Drosophila melanogaster 10A1-2 as probes in some Diptera species, the 10A1-2 distal clone, carrying vermilion gene, in D. virilis was shown to be located in a very thin band of the 5A region, while the proximal clones of the 10A1-2 band were mapped in a large band of the 2B region. In D. paranaensis a sequence homologous to the vermilion gene DNA was mapped in a large band, whereas the proximal clones of the 10A1-2 band were localized in a different region. These results evidence for the fact that DNA sequences are not evolutionary fixed, i. e. in different species they may belong to different chromomeres.