Transcriptional repression of euchromatic genes by Drosophila heterochromatin protein 1 and histone modifiers

In Drosophila, heterochromatin protein 1 (HP1) suppresses the expression of euchromatic genes that are artificially translocated adjacent to heterochromatin by expanding heterochromatin structure into neighboring euchromatin. The purpose of this study was to determine whether HP1 functions as a transcriptional repressor in the absence of chromosome rearrangements. Here, we show that Drosophila HP1 normally represses the expression of four euchromatic genes in a dosage-dependent manner. Three genes regulated by HP1 map to cytological region 31 of chromosome 2, which is immunostained by anti-HP1 antibodies in the salivary gland. The repressive effect of HP1 is decreased by mutation in Su(var)3-9, whose mammalian orthologue encodes a histone H3 methyltransferase and mutation in Su(var)2-1, which is correlated with histone H4 deacetylation. These data provide genetic evidence that an HP1-family protein represses the expression of euchromatic genes in a metazoan, and that histone modifiers cooperate with HP1 in euchromatic gene repression.

Molecular biology of the chromo domain: an ancient chromatin module comes of age

The chromo domain motif is found in proteins from fungi, protists, plants, fish, insects, amphibians, birds, and mammals. The chromo domain peptide fold may have its origins as a chromosomal protein in a common ancestor of archea and eukaryota, making it a particularly ancient protein structural module. Chromo domains have been found in single or multiple copies in proteins with diverse structures and activities, most or all of which are connected with chromosome structure/function. In this review, our current knowledge of chromo domain properties is summarized and a variety of contexts in which chromo domains participate in aspects of chromatin metabolism are discussed.

Decisive factors: a transcription activator can overcome heterochromatin silencing

Eukaryotes organize certain chromosomal intervals into domains capable of silencing most genes. Examples of silencing domains include the HML/HMR loci and subtelomeric chromatin in yeast, the Barr body X chromosome in mammals, and the pericentric heterochromatin of Drosophila. Silencing chromatin is often correlated with more regularized nucleosomal array than that found in active chromatin, and transcriptional activators appear to be missing from their target sites in silent chromatin. In Drosophila, gene silencing by heterochromatin is often variegated, indicating that a gene may escape silencing in some cells. In a recent study, Ahmad and Henikoff(1) show that a yeast activator can compete successfully with Drosophila heterochromatic silencing factors for target sites in DNA. This competition, together with developmental change in the stability of heterochromatin itself, decides the transcriptional state for a gene subject to heterochromatin repression.

Phosphorylation site mutations in heterochromatin protein 1 (HP1) reduce or eliminate silencing activity

HP1 is an essential heterochromatin-associated protein in Drosophila. HP1 has dosage-dependent effects on the silencing of euchromatic genes that are mislocalized to heterochromatin and is required for the normal expression of at least two heterochromatic genes. HP1 is multiply phosphorylated in vivo, and HP1 hyperphosphorylation is correlated with heterochromatin assembly during development. The purpose of this study was to test whether HP1 phosphorylation modifies biological activity and biochemical properties of HP1. To determine sites of HP1 phosphorylation in vivo and whether phosphorylation affects any biochemical properties of HP1, we expressed Drosophila HP1 in lepidopteran cultured cells using a recombinant baculovirus vector. Phosphopeptides were identified by matrix-assisted laser desorption ionization/time of flight mass spectroscopy; these peptides contain target sites for casein kinase II, protein tyrosine kinase, and PIM-1 kinase. Purified HP1 from bacterial (unphosphorylated) and lepidopteran (phosphorylated) cells has similar secondary structure. Phosphorylation has no effect on HP1 self-association but alters the DNA binding properties of HP1, suggesting that phosphorylation could differentially regulate HP1-dependent interactions. Serine-to-alanine and serine-to-glutamate substitutions at consensus protein kinase motifs resulted in reduction or loss of silencing activity of mutant HP1 in transgenic flies. These results suggest that dynamic phosphorylation/dephosphorylation regulates HP1 activity in heterochromatic silencing.

Expression and functional analysis of three isoforms of human heterochromatin-associated protein HP1 in Drosophila

Heterochromatin-associated protein 1 (HP1) is a nonhistone chromosomal protein associated with pericentromeric heterochromatin in Drosophila. HP1-like proteins have also been found associated with heterochromatin in human cells. The goal of this study was to determine whether proteins of the structurally conserved human HP1 family exhibit conserved heterochromatin targeting and silencing properties in Drosophila. We established transgenic lines of Drosophila melanogaster expressing each of the three human HP1 proteins, HP1Hsalpha, HP1HSbeta, and HP1Hsgamma, under the Hsp70 heat shock promoter. We show that all three isoforms of human HP1 are stably expressed in Drosophila and are associated with heterochromatin in Drosophila chromosomes. Like Drosophila HP1, all three human HP1 proteins are delocalized by an HP1-POLYCOMB chimeric protein, implying that both human HP1 and Drosophila HP1 interact in a common protein complex, and that at least some aspects of heterochromatin structure are highly conserved throughout the evolution of eukaryotes. Ectopic expression of two of the three human HP1 family proteins significantly enhances heterochromatic silencing in Drosophila.

Heterochromatin protein 1 binds to nucleosomes and DNA in vitro

Heterochromatin protein 1 (HP1) is a nonhistone chromosomal protein primarily associated with the pericentric heterochromatin and telomeres in Drosophila. The molecular mechanism by which HP1 specifically recognizes and binds to chromatin is unknown. The purpose of this study was to test whether HP1 can bind directly to nucleosomes. HP1 binds nucleosome core particles and naked DNA. HP1-DNA complex formation is length-dependent and cooperative but relatively sequence-independent. We show that histone H4 amino-terminal peptides bind to monomeric and dimeric HP1 in vitro. Acetylation of lysine residues had no significant effect on in vitro binding. The C-terminal chromo shadow domain of HP1 specifically binds H4 N-terminal peptide. Neither the chromo domain nor chromo shadow domain alone binds DNA; intact native HP1 is required for such interactions. Together, these observations suggest that HP1 may serve as a cross-linker in chromatin, linking nucleosomal DNA and nonhistone protein complexes to form higher order chromatin structures.

Heterochromatin protein 1 is required for the normal expression of two heterochromatin genes in Drosophila

The Su(var)2-5 locus, an essential gene in Drosophila, encodes the heterochromatin-associated protein HP1. Here, we show that the Su(var)2-5 lethal period is late third instar. Maternal HP1 is still detectable in first instar larvae, but disappears by third instar, suggesting that developmentally late lethality is probably the result of depletion of maternal protein. We demonstrate that heterochromatic silencing of a normally euchromatic reporter gene is completely lost by third instar in zygotically HP1 mutant larvae, implying a defect in heterochromatin-mediated transcriptional regulation in these larvae. However, expression of the essential heterochromatic genes rolled and light is reduced in Su(var)2-5 mutant larvae, suggesting that reduced expression of essential heterochromatic genes could underlie the recessive lethality of Su(var)2-5 mutations. These results also show that HP1, initially recognized as a transcriptional silencer, is required for the normal transcriptional activation of heterochromatic genes.

The HP1 protein family: getting a grip on chromatin

HP1 was first described in Drosophila as a heterochromatin-associated protein with dosage-dependent effects on heterochromatin-induced gene silencing. Recently, membership of the HP1 protein family has expanded tremendously. A number of intriguing interactions between HP1 and other proteins have been described, implicating HP1 in gene regulation, DNA replication, and nuclear architecture.

Phosphorylation of heterochromatin protein 1 by casein kinase II is required for efficient heterochromatin binding in Drosophila

Heterochromatin-associated protein 1 (HP1) is a nonhistone chromosomal protein with a dose-dependent effect on heterochromatin mediated position-effect silencing. It is multiply phosphorylated in vivo. Hyperphosphorylation of HP1 is correlated with heterochromatin assembly. We report here that HP1 is phosphorylated by casein kinase II in vivo at three serine residues located at the N and C termini of the protein. Alanine substitution mutations in the casein kinase II target phosphorylation sites dramatically reduce the heterochromatin binding activity of HP1, whereas glutamate substitution mutations, which mimic the charge contributions of phosphorylated serine, have apparently wild-type binding activity. We propose that phosphorylation of HP1 promotes protein-protein interaction between HP1 and target binding proteins in heterochromatin.

Developmental regulation of heterochromatin-mediated gene silencing in Drosophila

The roles of differentiation, mitotic activity and intrinsic promoter strength in the maintenance of heterochromatic silencing were investigated during development using an inducible lacZ gene as an in vivo probe. Heterochromatic silencing is initiated at the onset of gastrulation, approximately 1 hour after heterochromatin is first visible cytologically. A high degree of silencing is maintained in the mitotically active imaginal cells from mid-embryogenesis until early third instar larval stage, and extensive relaxation of silencing is tightly associated with the onset of differentiation. Relaxation of silencing can be triggered in vitro by ecdysone. In contrast, timing and extent of silencing at both the initiation and relaxation stages are insensitive to changes in cell cycle activity, and intrinsic promoter strength also does not influence the extent of silencing by heterochromatin. These data suggest that the silencing activity of heterochromatin is developmentally programmed.

Time out: developmental regulation of heterochromatic silencing in Drosophila

Transcriptional silencing by heterochromatin represents a model for developmental gene silencing. Current models of heterochromatin envision DNA-protein complexes that prevent access by euchromatic transcription factors. Here, we summarize the evidence that heterochromatin acts at the chromatin level to silence genes and the status of current models of heterochromatin silencing, and we highlight some recent progress in understanding the composition and regulation of heterochromatin in Drosophila.

Mutations in yeast proliferating cell nuclear antigen define distinct sites for interaction with DNA polymerase delta and DNA polymerase epsilon

The importance of the interdomain connector loop and of the carboxy-terminal domain of Saccharomyces cerevisiae proliferating cell nuclear antigen (PCNA) for functional interaction with DNA polymerases delta (Poldelta) and epsilon (Pol epsilon) was investigated by site-directed mutagenesis. Two alleles, pol30-79 (IL126,128AA) in the interdomain connector loop and pol30-90 (PK252,253AA) near the carboxy terminus, caused growth defects and elevated sensitivity to DNA-damaging agents. These two mutants also had elevated rates of spontaneous mutations. The mutator phenotype of pol30-90 was due to partially defective mismatch repair in the mutant. In vitro, the mutant PCNAs showed defects in DNA synthesis. Interestingly, the pol30-79 mutant PCNA (pcna-79) was most defective in replication with Poldelta, whereas pcna-90 was defective in replication with Pol epsilon. Protein-protein interaction studies showed that pcna-79 and pcna-90 failed to interact with Pol delta and Pol epsilon, respectively. In addition, pcna-90 was defective in interaction with the FEN-1 endo-exonuclease (RTH1 product). A loss of interaction between pcna-79 and the smallest subunit of Poldelta, the POL32 gene product, implicates this interaction in the observed defect with the polymerase. Neither PCNA mutant showed a defect in the interaction with replication factor C or in loading by this complex. Processivity of DNA synthesis by the mutant holoenzyme containing pcna-79 was unaffected on poly(dA) x oligo(dT) but was dramatically reduced on a natural template with secondary structure. A stem-loop structure with a 20-bp stem formed a virtually complete block for the holoenzyme containing pcna-79 but posed only a minor pause site for wild-type holoenzyme, indicating a function of the POL32 gene product in allowing replication past structural blocks.

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.

In vivo assay for protein-protein interactions using Drosophila chromosomes

The ability of a chimeric HP1-Polycomb (Pc) protein to bind both to heterochromatin and to euchromatic sites of Pc protein binding was exploited to detect stable protein-protein interactions in vivo. Previously, we showed that endogenous Pc protein was recruited to ectopic heterochromatic binding sites by the chimeric protein. Here, we examine the association of other Pc group (Pc-G) proteins. We show that Posterior sex combs (Psc) protein also is recruited to heterochromatin by the chimeric protein, demonstrating that Psc protein participates in direct protein-protein interaction with Pc protein or Pc-associated protein. In flies carrying temperature-sensitive alleles of Enhancer of zeste[E(z)] the general decondensation of polytene chromosomes that occurs at the restrictive temperature is associated with loss of binding of endogenous Pc and chimeric HP1-Polycomb protein to euchromatin, but binding of HP1 and chimeric HP1-Polycomb protein to the heterochromatin is maintained. The E(z) mutation also results in the loss of chimera-dependent binding to heterochromatin by endogenous Pc and Psc proteins at the restrictive temperature, suggesting that interaction of these proteins is mediated by E(z) protein. A myc-tagged full-length Suppressor 2 of zeste [Su(z)2] protein interacts poorly or not at all with ectopic Pc-G complexes, but a truncated Su(z)2 protein is strongly recruited to all sites of chimeric protein binding. Trithorax protein is not recruited to the heterochromatin by the chimeric HP1-Polycomb protein, suggesting either that this protein does not interact directly with Pc-G complexes or that such interactions are regulated. Ectopic binding of chimeric chromosomal proteins provides a useful tool for distinguishing specific protein-protein interactions from specific protein-DNA interactions important for complex assembly in vivo.

Functional analysis of the chromo domain of HP1

Heterochromatin protein 1 (HP1) is a non-histone chromosomal protein in Drosophila with dosage-dependent effects on heterochromatin-mediated gene silencing. An evolutionarily conserved amino acid sequence in the N-terminal half of HP1 (the 'chromo domain') shares > 60% sequence identity with a motif found in the Polycomb protein, a silencer of homeotic genes. We report here that point mutations in the HP1 chromo domain abolish the ability of HP1 to promote gene silencing. We show that the HP1 chromo domain, like the Polycomb chromo domain, has chromosome binding activity, but to distinct chromosomal sites. We constructed a chimeric HP1-Polycomb protein, consisting of the chromo domain of Polycomb in the context of HP1, and show that it binds to both heterochromatin and Polycomb binding sites in polytene chromosomes. In flies expressing chimeric HP1-Polycomb protein, endogenous HP1 is mislocalized to Polycomb binding sites, and endogenous polycomb is misdirected to the heterochromatic chromocenter, suggesting that both proteins are recruited to their distinct chromosomal binding sites through protein-protein contacts. Chimeric HP1-Polycomb protein expression in transgenic flies promotes heterochromatin-mediated gene silencing, supporting the view that the chromo domain homology reflects a common mechanistic basis for homeotic and heterochromatic silencing.

Increased phosphorylation of HP1, a heterochromatin-associated protein of Drosophila, is correlated with heterochromatin assembly

The heterochromatin-associated nonhistone chromosomal protein HP1 exerts dosage-dependent effects on the silencing of genes juxtaposed to pericentric heterochromatin in Drosophila melanogaster. Here, we report that HP1 is multiply phosphorylated in Drosophila tissue, predominantly at serine and threonine residues. Pulse-labeling studies of explanted Drosophila tissues suggest that phosphorylation is relatively rapid and that phosphate is incorporated into existing protein. Maternally synthesized HP1 is underphosphorylated. The appearance of more highly phosphorylated HP1 isoforms at 1.5-2 h of development coincides with the embryonic stage at which cytologically visible heterochromatin appears and HP1 concentrates in heterochromatin. The extent of HP1 phosphorylation is lower in polytene tissue, where heterochromatin is underrepresented. These results are consistent with a role for phosphorylation of HP1 in the assembly and maintenance of heterochromatin in Drosophila.

A heat shock-activated cDNA rescues the recessive lethality of mutations in the heterochromatin-associated protein HP1 of Drosophila melanogaster

HP1 is a small nonhistone chromosomal protein of Drosophila melanogaster predominantly localized to the pericentric heterochromatin. We have shown previously that mutations in the HP1 coding sequences are associated with dominant suppression of heterochromatic position-effect variegation, and with recessive lethality. When fused to an Hsp70 heat shock gene promoter, the cDNA encoding HP1 supports the heat shock-inducible accumulation of HP1 protein in transgenic flies; this cDNA construct complements the dominant suppression of position-effect variegation associated with mutations in the HP1 gene. Here, we report experiments demonstrating that the heat shock-driven HP1 cDNA is capable of fully rescuing the recessive lethality associated with HP1 mutations in a heat shock-dependent fashion. If heat shock-induced HP1 expression is delayed for as long as 5 days, more than half of the mutant flies still survive until adulthood, consistent with a substantial maternal contribution to embryonic and larval viability. Elevating HP1 levels as late as 7-8 days of development is sufficient to enhance variegation three-fold, suggesting that the extent of heterochromatic position effect can be modified subsequent to the initial appearance of HP1 in the nuclei of syncytial blastoderm embryos.

Molecular cloning of a human homologue of Drosophila heterochromatin protein HP1 using anti-centromere autoantibodies with anti-chromo specificity

We have identified a novel autoantibody specificity in scleroderma that we term anti-chromo. These antibodies recognize several chromosomal antigens with apparent molecular mass of between 23 and 25 kDa, as determined by immunoblots. Anti-chromo autoantibodies occur in 10–15% of sera from patients with anti-centromere antibodies (ACA). We used anti-chromo antibodies to screen a human expression library and obtained cDNA clones encoding a 25 kDa chromosomal autoantigen. DNA sequence analysis reveals this protein to be a human homologue of HP1, a heterochromatin protein of Drosophila melanogaster. We designate our cloned protein HP1Hs alpha. Epitope mapping experiments using both human and Drosophila HP1 reveal that anti-chromo antibodies target a region at the amino terminus of the protein. This region contains a conserved motif, the chromo domain (or HP1/Pc box), first recognized by comparison of Drosophila HP1 with the Polycomb gene product. Both proteins are thought to play a role in creating chromatin structures in which gene expression is suppressed. Anti-chromo thus defines a novel type of autoantibody that recognizes a conserved structural motif found on a number of chromosomal proteins.

Overlapping domains of the heterochromatin-associated protein HP1 mediate nuclear localization and heterochromatin binding

The Drosophila protein HP1 is a 206 amino acid heterochromatin-associated nonhistone chromosomal protein. Based on the characterization of HP1 to date, there are three properties intrinsic to HP1: nuclear localization, heterochromatin binding, and gene silencing. In this work, we have concentrated on the identification of domains responsible for the nuclear localization and heterochromatin binding properties of HP1. We have expressed a series of beta-galactosidase/HP1 fusion proteins in Drosophila embryos and polytene tissue and have used beta-galactosidase enzymatic activity to identify the subcellular localization of each fusion protein. We have identified two functional domains in HP1: a nuclear localization domain of amino acids 152-206 and a heterochromatin binding domain of amino acids 95-206. Both of these functional domains overlap an evolutionarily conserved COOH-terminal region.

The heterochromatin-associated protein HP-1 is an essential protein in Drosophila with dosage-dependent effects on position-effect variegation

Chromosome rearrangements which place euchromatic genes adjacent to a heterochromatic breakpoint frequently result in gene repression (position-effect variegation). This repression is thought to reflect the spreading of a heterochromatic structure into neighboring euchromatin. Two allelic dominant suppressors of position-effect variegation were found to contain mutations within the gene encoding the heterochromatin-specific chromosomal protein HP-1. The site of mutation for each allele is given: one converts Lys169 into a nonsense (ochre) codon, while the other is a frameshift after Ser10. In flies heterozygous for one of the mutant alleles (Su(var)2-504), a truncated HP-1 protein was detectable by Western blot analysis. An HP-1 minigene, consisting of HP-1 cDNA under the control of an Hsp70 heat-inducible promoter, was transduced into flies by P element-mediated germ line transformation. Heat-shock driven expression of this minigene results in elevated HP-1 protein level and enhancement of position-effect variegation. Levels of variegating gene expression thus appear to depend upon the level of expression of a heterochromatin-specific protein. The implications of these observations for mechanism of heterochromatic position effects and heterochromatin function are discussed.

Boundary functions in the control of gene expression

Recent experiments using stably transformed genes in mouse and Drosophila have demonstrated that elimination of euchromatic position effects can be used as a functional assay for domain boundaries. These studies will lead to an analysis of boundary structure, and in addition will provide clues to the mechanism(s) of gene regulation by higher order chromatin packaging.

Mutation in a heterochromatin-specific chromosomal protein is associated with suppression of position-effect variegation in Drosophila melanogaster

We report here that a point mutation in the gene which encodes the heterochromatin-specific nonhistone chromosomal protein HP-1 in Drosophila melanogaster is associated with dominant suppression of position-effect variegation. The mutation, a G-to-A transition at the first nucleotide of the last intron, causes missplicing of the HP-1 mRNA. This suggests that heterochromatin-specific proteins play a central role in the gene suppression associated with heterochromatic position effects.

Distribution patterns of HP1, a heterochromatin-associated nonhistone chromosomal protein of Drosophila

We have previously reported the identification of a nonhistone chromosomal protein (nhcp-19; now called HP1) preferentially associated with the heterochromatin of Drosophila melanogaster. A detailed study of the HP1 distribution pattern on polytene chromosomes by immunofluorescent staining, using monoclonal antibody C1A9, has been carried out. The results indicate that this protein is found within the centric beta-heterochromatin, in cytological regions 31, 41 and 80, and throughout polytene chromosome 4. Staining of telomeres is frequently observed, those of chromosome arms 2R and 3R and the X chromosome being the most conspicuous. Analysis of a fourth chromosome insertional translocation T(3;4)f/In(3L)P confirms an autonomous interaction with chromosome 4 material. Similarly, the beta-heterochromatin distal to light on chromosome arm 2L, moved to position 97D2 on chromosome arm 3R in the rearrangement ltx13, is prominently stained using the C1A9 antibody. Staining of intact salivary glands indicates that this rearranged segment of beta-heterochromatin is not associated with the polytene chromocenter, but provides an independent structural reference point. HP1 is not observed in the nuclei of the early syncytial embryo, but becomes concentrated in the nuclei at the syncytial blastoderm stage (ca. nuclear division cycle 10). This suggests that heterochromatin formation occurs at approximately the same stage at which nuclei first become transcriptionally competent. Thus, the C1A9 antibody may serve as a useful marker for both structural and functional studies of the Drosophila nucleus.

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.

Hsp28stl: a P-element insertion mutation that alters the expression of a heat shock gene in Drosophila melanogaster

We have identified and cloned a mutant allele of the small heat shock gene Hsp28 of Drosophila melanogaster. This allele, which we have called Hsp28stl, produces small amounts of a single aberrantly large, heat-inducible transcript in heat-shocked flies, while a normal-sized Hsp28 transcript is present only in fertile females. No Hsp28 transcript at all is detected in mutant prepupae, a stage when wildtype flies show high levels of Hsp28 RNA. We have cloned the Hsp28stl allele, and have found that a 1.3-kb defective P-element is present 5' to Hsp28 in the mutant line. The site of P-element insertion lies between the Hsp28 "TATA box" sequence and the Hsp28 RNA cap site; in contrast to previously described P-element insertions, the element at Hsp28stl is flanked by a two base pair duplication of the insertional target sequence. The results suggest that this insert may separate elements regulating heat-inducible and developmental expression of Hsp28, leading to the different patterns of transcription observed.

Chromatin structure of a P-element-transduced hsp-28 gene in Drosophila melanogaster

The Drosophila hsp-28 gene was heat inducible when transduced to novel chromosomal sites even when no direct selection for transduced gene expression was imposed. The pattern of DNase I-hypersensitive sites 5' to the wild type and transduced copy of hsp-28 was similar. In addition, DNase I-hypersensitive sites occurred within the P-element sequences flanking transduced loci.

Micrococcal nuclease as a DNA structural probe: its recognition sequences, their genomic distribution and correlation with DNA structure determinants

We have analyzed micrococcal nuclease (MNase) DNA cleavage patterns at the sequence level by examining 2.3 X 10(3) base-pairs of data derived from the Drosophila melanogaster 44D larval cuticle locus. Within this region, MNase preferentially cleaved 140 sites. Clusters of these sites appear to generate the preferential MNase eukaryotic DNA cleavage sites seen on agarose gels at roughly 100 to 300 base-pair intervals. These clusters of preferential cleavage sites rarely occur within gene coding regions. The analysis revealed that duplex DNA sequences preferentially cleaved by MNase are generally determined by a single strand sequence: d(A-T)n, where n greater than or equal to 1, flanked by a 5' dC or dG. Cleavage of the other strand is generally staggered 5' by several nucleotides and occurs even if such sequences are absent on that strand. An empirical predictive DNA cleavage model derived from a statistical analysis of the sequence level data was applied to seven eukaryotic gene loci of known sequence. The predicted patterns were in good general agreement with the previously observed eukaryotic gene/spacer cleavage pattern. Statistical analysis also revealed that sites of predicted preferential DNA cleavage occur less frequently in protein coding regions than for randomized sequences of the same length and nucleotide content. Comparison of the MNase cleavage patterns to the sequence-dependent pattern of binding energies between duplex DNA strands indicates that MNase preferentially cleaves sequences with low helix stability.

Chromatin structure at the 44D larval cuticle gene locus in Drosophila: the effect of a transposable element insertion

The chromatin structure of the larval cuticle gene cluster at 44D was characterized in embryos from wild-type (Oregon R) and a variant line (2/3) of Drosophila melanogaster. A major DNase I hypersensitive (DH) site was found between genes II and III in the chromatin, in a position 5' to the transcriptional start of the genes in the cluster. The introduction of a 7.3 kilobase transposable element into the cluster in the 2/3 variant enhanced the sensitivity of the major site in 2/3 chromatin but had no other effect upon the pattern of DH sites associated with the wild-type sequences. The wild-type sequences were packaged into an ordered nucleosome-like array in embryos, as revealed by digestion with the chemical cleavage reagent (methidiumpropyl-EDTA) iron (II) [MPE . Fe(II)]. Nucleolytic cleavage within the transposable element chromatin shows it to be organized in an ordered array punctuated by several DH sites. While the patterns of DNase I hypersensitivity are similar in the vicinity of the direct terminal repeats, the patterns revealed by micrococcal nuclease and MPE . Fe(II) are not, indicating a different chromatin organization of these two identical sequences.

A cytological approach to the ordering of events in gene activation using the Sgs-4 locus of Drosophila melanogaster

The polytene chromosomes of Drosophila strains that differ in the synthesis of the major salivary gland glue protein sgs-4 were examined by indirect immunofluorescence using antisera to several nonhistone chromosomal proteins. The Oregon-R X chromosome, which produces sgs-4 messenger RNA, showed a strong fluorescent band at locus 3C11-12 when stained with anti-RNA polymerase II, whereas the null mutant Berkeley 1 failed to exhibit fluorescence at that locus. The presence of another antigen (Band 2), normally associated with developmentally active loci, was clearly evident at locus 3C11-12 of both transcriptionally competent and null strains, indicating that the association of Band 2 antigen with the chromatin is an event independent of RNA polymerase II binding. Antibodies directed against Drosophila topoisomerase I stained 3C11-12 in the Sgs-4+ (wild-type) strain brightly, but gave significantly less staining in the null strain. This indicates that the high concentrations of topoisomerase I seen at active loci are closely associated with the transcriptional event. In some of these analyses, we have made use of flies heterozygous for the wild-type and null alleles in order to make internally controlled comparisons. The results suggest that this type of analysis will enable conclusions to be drawn concerning the interdependence and order of action of chromosomal proteins involved in developmental gene activation.

Chromatin structure and transcriptional activity of an X-linked heat shock gene in drosophila pseudoobscura

Nuclease digestion of isolated nuclei was used to test whether differential chromatin structure exists for a dosage-compensated heat shock gene in Drosophila pseudoobscura. No differences were observed in nuclease sensitivity at this locus in males and females, either under heat shock or non-heat shock conditions, using micrococcal nuclease or DNase I. Although the higher level of nuclease sensitivity characterized by the induced state was removed when nuclei were prepared in high salt (0.45 M sodium chloride), this procedure did not reveal covert differences in X-linked chromatin structure between males and females. However, a clear difference was observed in the nuclease sensitivity at low level (uninduced) and high level (heat-induced) expression of the X-linked heat shock gene, suggesting that the same gene transcribed at two steady state rates can have different chromatin structures.

Analysis of DNA structural patterns and sequence organization at the larval cuticle locus in Drosophila melanogaster

We examined the pattern of DNA organization at the larval cuticle gene complex 44D of Drosophila melanogaster, using micrococcal nuclease and the 1,10-phenanthroline-cuprous complex. The initial cleavage patterns obtained with both reagents exhibited "gaps" at the positions of each of the genes examined, as well as at a pseudogene sequence contained within the complex. An additional gap for which no gene exists was observed for both patterns. The cleavage pattern obtained with micrococcal nuclease was unaltered, at a level of resolution of +/- 50 base pairs, in a mutant containing a transposable element. Analysis of the sequence data from this 5.5-kilobase gene cluster indicated that the sequence per se, and not the general base composition, is a dominant factor in determining the patterns observed.