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.     

Phylogenomic analysis reveals dynamic evolutionary history of the Drosophila heterochromatin protein 1 (HP1) gene family

Heterochromatin is the gene-poor, satellite-rich eukaryotic genome compartment that supports many essential cellular processes. The functional diversity of proteins that bind and often epigenetically define heterochromatic DNA sequence reflects the diverse functions supported by this enigmatic genome compartment. Moreover, heterogeneous signatures of selection at chromosomal proteins often mirror the heterogeneity of evolutionary forces that act on heterochromatic DNA. To identify new such surrogates for dissecting heterochromatin function and evolution, we conducted a comprehensive phylogenomic analysis of the Heterochromatin Protein 1 gene family across 40 million years of Drosophila evolution. Our study expands this gene family from 5 genes to at least 26 genes, including several uncharacterized genes in Drosophila melanogaster. The 21 newly defined HP1s introduce unprecedented structural diversity, lineage-restriction, and germline-biased expression patterns into the HP1 family. We find little evidence of positive selection at these HP1 genes in both population genetic and molecular evolution analyses. Instead, we find that dynamic evolution occurs via prolific gene gains and losses. Despite this dynamic gene turnover, the number of HP1 genes is relatively constant across species. We propose that karyotype evolution drives at least some HP1 gene turnover. For example, the loss of the male germline-restricted HP1E in the obscura group coincides with one episode of dramatic karyotypic evolution, including the gain of a neo-Y in this lineage. This expanded compendium of ovary- and testis-restricted HP1 genes revealed by our study, together with correlated gain/loss dynamics and chromosome fission/fusion events, will guide functional analyses of novel roles supported by germline chromatin.     

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.     

The structure of mouse HP1 suggests a unique mode of single peptide recognition by the shadow chromo domain dimer

The heterochromatin protein 1 (HP1) family of proteins is involved in gene silencing via the formation of heterochromatic structures. They are composed of two related domains: an N-terminal chromo domain and a C-terminal shadow chromo domain. Present results suggest that chromo domains may function as protein interaction motifs, bringing together different proteins in multi-protein complexes and locating them in heterochromatin. We have previously determined the structure of the chromo domain from the mouse HP1beta protein, MOD1. We show here that, in contrast to the chromo domain, the shadow chromo domain is a homodimer. The intact HP1beta protein is also dimeric, where the interaction is mediated by the shadow chromo domain, with the chromo domains moving independently of each other at the end of flexible linkers. Mapping studies, with fragments of the CAF1 and TIF1beta proteins, show that an intact, dimeric, shadow chromo domain structure is required for complex formation.     

The hinge and chromo shadow domain impart distinct targeting of HP1-like proteins

Drosophila heterochromatin-associated protein 1 (HP1) is an abundant component of heterochromatin, a highly condensed compartment of the nucleus that comprises a major fraction of complex genomes. Some organisms have been shown to harbor multiple HP1-like proteins, each exhibiting spatially distinct localization patterns within interphase nuclei. We have characterized the subnuclear localization patterns of two newly discovered Drosophila HP1-like proteins (HP1b and HP1c), comparing them with that of the originally described fly HP1 protein (here designated HP1a). While HP1a targets heterochromatin, HP1b localizes to both heterochromatin and euchromatin and HP1c is restricted exclusively to euchromatin. All HP1-like proteins contain an amino-terminal chromo domain, a connecting hinge, and a carboxyl-terminal chromo shadow domain. We expressed truncated and chimeric HP1 proteins in vivo to determine which of these segments might be responsible for heterochromatin-specific and euchromatin-specific localization. Both the HP1a hinge and chromo shadow domain independently target heterochromatin, while the HP1c chromo shadow domain is implicated solely in euchromatin localization. Comparative sequence analyses of HP1 homologs reveal a conserved sequence block within the hinge that contains an invariant sequence (KRK) and a nuclear localization motif. This block is not conserved in the HP1c hinge, possibly accounting for its failure to function as an independent targeting segment. We conclude that sequence variations within the hinge and shadow account for HP1 targeting distinctions. We propose that these targeting features allow different HP1 complexes to be distinctly sequestered in organisms that harbor multiple HP1-like proteins.     

Novel Drosophila heterochromatin protein 1 (HP1)/origin recognition complex-associated protein (HOAP) repeat motif in HP1/HOAP interactions and chromocenter associations

Association of the highly conserved heterochromatin protein, HP1, with the specialized chromatin of centromeres and telomeres requires binding to a specific histone H3 modification of methylation on lysine 9. This modification is catalyzed by the Drosophila Su(var)3-9 gene product and its homologues. Specific DNA binding activities are also likely to be required for targeting this activity along with HP1 to specific chromosomal regions. The Drosophila HOAP protein is a DNA-binding protein that was identified as a component of a multiprotein complex of HP1 containing Drosophila origin recognition complex (ORC) subunits in the early Drosophila embryo. Here we show direct physical interactions between the HOAP protein and HP1 and specific ORC subunits. Two additional HP1-like proteins (HP1b and HP1c) were recently identified in Drosophila, and the unique chromosomal distribution of each isoform is determined by two independently acting HP1 domains (hinge and chromoshadow domain) (47). We find heterochromatin protein 1/origin recognition complex-associated protein (HOAP) to interact specifically with the originally described predominantly heterochromatic HP1a protein. Both the hinge and chromoshadow domains of HP1a are required for its interaction with HOAP, and a novel peptide repeat located in the carboxyl terminus of the HOAP protein is required for the interaction with the HP1 hinge domain. Peptides that interfere with HP1a/HOAP interactions in co-precipitation experiments also displace HP1 from the heterochromatic chromocenter of polytene chromosomes in larval salivary glands. A mutant for the HOAP protein also suppresses centric heterochromatin-induced silencing, supporting a role for HOAP in centric heterochromatin.     

Transposable elements as artisans of the heterochromatic genome in Drosophila melanogaster

Over 50 years ago Barbara McClintock discovered that maize contains mobile genetic elements, but her findings were at first considered nothing more than anomalies. Today it is widely recognized that transposable elements have colonized all eukaryotic genomes and represent a major force driving evolution of organisms. Our contribution to this special issue deals with the theme of transposable element-host genome interactions. We bring together published and unpublished work to provide a picture of the contribution of transposable elements to the evolution of the heterochromatic genome in Drosophila melanogaster. In particular, we discuss data on 1) colonization of constitutive heterochromatin by transposable elements, 2) instability of constitutive heterochromatin induced by the I factor, and 3) evolution of constitutive heterochromatin and heterochromatic genes driven by transposable elements. Drawing attention to these topics may have direct implications on important aspects of genome organization and gene expression.     

Functional domain analysis of human HP1 isoforms in Drosophila

Three subtypes of HP1, a conserved non-histone chromosomal protein enriched in heterochromatin, have been identified in humans, HP1alpha, beta and gamma. In the present study, we utilized a Drosophila system to characterize human HP1 functions. Over-expression of HP1beta in eye imaginal discs caused abnormally patterned eyes, with reduced numbers of ommatidia, and over-expression of HP1gamma in wing imaginal discs caused abnormal wings, in which L4 veins were gapped. These phenotypes were specific to the HP1 subtypes and appear to reflect suppressed gene expression. To determine the molecular domains of HP1 required for each specific phenotype, we constructed a series of chimeric molecules with HP1beta and HP1gamma. Our data show that the C-terminal chromo shadow domain (CSD) of HP1gamma is necessary for HP1gamma-type phenotype, whereas for the HP1beta-type phenotype both the chromo domain and the CSD are required. These results suggest human HP1 subtypes use different domains to suppress gene expression in Drosophila cells.     

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.     

Specificity of the HP1 chromo domain for the methylated N-terminus of histone H3

Recent studies show that heterochromatin-associated protein-1 (HP1) recognizes a 'histone code' involving methylated Lys9 (methyl-K9) in histone H3. Using in situ immunofluorescence, we demonstrate that methyl-K9 H3 and HP1 co-localize to the heterochromatic regions of Drosophila polytene chromosomes. NMR spectra show that methyl-K9 binding of HP1 occurs via its chromo (chromosome organization modifier) domain. This interaction requires methyl-K9 to reside within the proper context of H3 sequence. NMR studies indicate that the methylated H3 tail binds in a groove of HP1 consisting of conserved residues. Using fluorescence anisotropy and isothermal titration calorimetry, we determined that this interaction occurs with a K(D) of approximately 100 microM, with the binding enthalpically driven. A V26M mutation in HP1, which disrupts its gene silencing function, severely destabilizes the H3-binding interface, and abolishes methyl-K9 H3 tail binding. Finally, we note that sequence diversity in chromo domains may lead to diverse functions in eukaryotic gene regulation. For example, the chromo domain of the yeast histone acetyltransferase Esa1 does not interact with methyl- K9 H3, but instead shows preference for unmodified H3 tail.     

pR plasmid replication provides evidence that single-stranded DNA induces the SOS system in vivo

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 HPI 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.     

pR plasmid replication provides evidence that single-stranded DNA induces the SOS system in vivo

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 HPI 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.     

HP1: a functionally multifaceted protein

HP1 (heterochromatin protein 1) is a nonhistone chromosomal protein first discovered in Drosophila melanogaster because of its association with heterochromatin. Numerous studies have shown that such a protein plays a role in heterochromatin formation and gene silencing in many organisms, including fungi and animals. Cytogenetic and molecular studies, performed in Drosophila and other organisms, have revealed that HP1 associates with heterochromatin, telomeres and multiple euchromatic sites. There is increasing evidence that the different locations of HP1 are related to multiple different functions. In fact, recent work has shown that HP1 has a role not only in heterochromatin formation and gene silencing, but also in telomere stability and in positive regulation of gene expression.     

HP1 controls genomic targeting of four novel heterochromatin proteins in Drosophila

Heterochromatin is important for the maintenance of genome stability and regulation of gene expression; yet our knowledge of heterochromatin structure and function is incomplete. We identified four novel Drosophila heterochromatin proteins (HPs). Three of these proteins (HP3, HP4 and HP5) interact directly with HP1, whereas HP6 in turn binds to each of these three proteins. Immunofluorescence microscopy and genome-wide mapping of in vivo binding sites shows that all four proteins are components of heterochromatin. Depletion of HP1 causes redistribution of all four proteins, indicating that HP1 is essential for their heterochromatic targeting. Finally, mutants of HP4 and HP5 are dominant suppressors of position effect variegation, demonstrating their importance in heterochromatic gene silencing. These results indicate that HP1 acts as a docking platform for several mediator proteins that contribute to heterochromatin function.     

MU2 and HP1a regulate the recognition of double strand breaks in Drosophila melanogaster

Chromatin structure regulates the dynamics of the recognition and repair of DNA double strand breaks; open chromatin enhances the recruitment of DNA damage response factors, while compact chromatin is refractory to the assembly of radiation-induced repair foci. MU2, an orthologue of human MDC1, a scaffold for ionizing radiation-induced repair foci, is a widely distributed chromosomal protein in Drosophila melanogaster that moves to DNA repair foci after irradiation. Here we show using yeast 2 hybrid screens and co-immunoprecipitation that MU2 binds the chromoshadow domain of the heterochromatin protein HP1 in untreated cells. We asked what role HP1 plays in the formation of repair foci and cell cycle control in response to DNA damage. After irradiation repair foci form in heterochromatin but are shunted to the edge of heterochromatic regions an HP1-dependent manner, suggesting compartmentalized repair. Hydroxyurea-induced repair foci that form at collapsed replication forks, however, remain in the heterochromatic compartment. HP1a depletion in irradiated imaginal disc cells increases apoptosis and disrupts G2/M arrest. Further, cells irradiated in mitosis produced more and brighter repair foci than to cells irradiated during interphase. Thus, the interplay between MU2 and HP1a is dynamic and may be different in euchromatin and heterochromatin during DNA break recognition and repair.     

Oxymoron no more: the expanding world of heterochromatic genes

Heterochromatin has been oversimplified and even misunderstood. In particular, the existence of heterochromatic genes is often overlooked. Diverse types of genes reside within regions classified as constitutive heterochromatin and activating influences of heterochromatin on gene expression in Drosophila are well documented. These properties are usually considered paradoxical because heterochromatin is commonly portrayed as "silent chromatin". In the past, studies of heterochromatic genes were limited to a few Drosophila genes. However, the recent discovery of several hundred heterochromatic genes in Drosophila, plants and mammals through sequencing projects offers new opportunities to examine the variety of ways in which heterochromatin influences gene expression. Comparative genomics is revealing diverse origins of heterochromatic genes and remarkable evolutionary fluidity between heterochromatic and euchromatic domains. These features justify a broader view of heterochromatin, one that accommodates repressive, permissive and activating effects on gene expression, and recognizes chromosomal and evolutionary transitional states between heterochromatin and euchromatin.     

Mapping of a mouse homolog of a heterochromatin protein gene the X chromosome.

Modifiers of position-effect-variegation in Drosophila are thought to encode proteins that are either structural components of heterochromatin or enzymes that modify these components. We have recently shown that a sequence motif found in one Drosophila modifier gene, Heterochromatin protein 1 (HP1), is conserved in a wide variety of animal and plant species (Singh et al. 1991). Using this motif, termed chromo box, we have cloned a mouse candidate modifier gene, M31, that also shows considerable sequence homology to Drosophila HP1. Here we report evidence of at least four independently segregating loci in the mouse homologous to the M31 cDNA. One of these loci--Cbx-rs1--maps to the X Chromosome (Chr), 1 cM proximal to Amg and outside the X-inactivation center region.