Use of IFNγ/IL10 Ratio for Stratification of Hydrocortisone Therapy in Patients With Septic Shock.

Large clinical trials testing hydrocortisone therapy in septic shock have produced conflicting results. Subgroups may benefit of hydrocortisone treatment depending on their individual immune response. We performed an exploratory analysis of the database from the international randomized controlled clinical trial Corticosteroid Therapy of Septic Shock (CORTICUS) employing machine learning to a panel of 137 variables collected from the Berlin subcohort comprising 83 patients including demographic and clinical measures, organ failure scores, leukocyte counts and levels of circulating cytokines. The identified theranostic marker was validated against data from a cohort of the Hellenic Sepsis Study Group (HSSG) (n = 246), patients enrolled in the clinical trial of Sodium Selenite and Procalcitonin Guided Antimicrobial Therapy in Severe Sepsis (SISPCT, n = 118), and another, smaller clinical trial (Crossover study, n = 20). In addition, in vitro blood culture experiments and in vivo experiments in mouse models were performed to assess biological plausibility. A low serum IFNγ/IL10 ratio predicted increased survival in the hydrocortisone group whereas a high ratio predicted better survival in the placebo group. Using this marker for a decision rule, we applied it to three validation sets and observed the same trend. Experimental studies in vitro revealed that IFNγ/IL10 was negatively associated with the load of (heat inactivated) pathogens in spiked human blood and in septic mouse models. Accordingly, an in silico analysis of published IFNγ and IL10 values in bacteremic and non-bacteremic patients with the Systemic Inflammatory Response Syndrome supported this association between the ratio and pathogen burden. We propose IFNγ/IL10 as a molecular marker supporting the decision to administer hydrocortisone to patients in septic shock. Prospective clinical studies are necessary and standard operating procedures need to be implemented, particularly to define a generic threshold. If confirmed, IFNγ/IL10 may become a suitable theranostic marker for an urging clinical need.

Heterochromatin formation in Drosophila requires genome-wide histone deacetylation in cleavage chromatin before mid-blastula transition in early embryogenesis.

Su(var) mutations define epigenetic factors controlling heterochromatin formation and gene silencing in Drosophila. Here, we identify SU(VAR)2-1 as a novel chromatin regulator that directs global histone deacetylation during the transition of cleavage chromatin into somatic blastoderm chromatin in early embryogenesis. SU(VAR)2-1 is heterochromatin-associated in blastoderm nuclei but not in later stages of development. In larval polytene chromosomes, SU(VAR)2-1 is a band-specific protein. SU(VAR)2-1 directs global histone deacetylation by recruiting the histone deacetylase RPD3. In Su(var)2-1 mutants H3K9, H3K27, H4K8 and H4K16 acetylation shows elevated levels genome-wide and heterochromatin displays aberrant histone hyper-acetylation. Whereas H3K9me2- and HP1a-binding appears unaltered, the heterochromatin-specific H3K9me2S10ph composite mark is impaired in heterochromatic chromocenters of larval salivary polytene chromosomes. SU(VAR)2-1 contains an NRF1/EWG domain and a C2HC zinc-finger motif. Our study identifies SU(VAR)2-1 as a dosage-dependent, heterochromatin-initiating SU(VAR) factor, where the SU(VAR)2-1-mediated control of genome-wide histone deacetylation after cleavage and before mid-blastula transition (pre-MBT) is required to enable heterochromatin formation.

The correlation of genome size and DNA methylation rate in metazoans.

Total DNA methylation rates are well known to vary widely between different metazoans. The phylogenetic distribution of this variation, however, has not been investigated systematically. We combine here publicly available data on methylcytosine content with the analysis of nucleotide compositions of genomes and transcriptomes of 78 metazoan species to trace the evolution of abundance and distribution of DNA methylation. The depletion of CpG and the associated enrichment of TpG and CpA dinucleotides are used to infer the intensity and localization of germline CpG methylation and to estimate its evolutionary dynamics. We observe a positive correlation of the relative methylation of CpG motifs with genome size. We tested this trend successfully by measuring total DNA methylation with LC/MS in orthopteran insects with very different genome sizes: house crickets, migratory locusts and meadow grasshoppers. We hypothesize that the observed correlation between methylation rate and genome size is due to a dependence of both variables from long-term effective population size and is driven by the accumulation of repetitive sequences that are typically methylated during periods of small population sizes. This process may result in generally methylated, large genomes such as those of jawed vertebrates. In this case, the emergence of a novel demethylation pathway and of novel reader proteins for methylcytosine may have enabled the usage of cytosine methylation for promoter-based gene regulation. On the other hand, persistently large populations may lead to a compression of the genome and to the loss of the DNA methylation machinery, as observed, e.g., in nematodes.

Near intron pairs and the metazoan tree.

Gene structure data can substantially advance our understanding of metazoan evolution and deliver an independent approach to resolve conflicts among existing hypotheses. Here, we used changes of spliceosomal intron positions as novel phylogenetic marker to reconstruct the animal tree. This kind of data is inferred from orthologous genes containing mutually exclusive introns at pairs of sequence positions in close proximity, so-called near intron pairs (NIPs). NIP data were collected for 48 species and utilized as binary genome-level characters in maximum parsimony (MP) analyses to reconstruct deep metazoan phylogeny. All groupings that were obtained with more than 80% bootstrap support are consistent with currently supported phylogenetic hypotheses. This includes monophyletic Chordata, Vertebrata, Nematoda, Platyhelminthes and Trochozoa. Several other clades such as Deuterostomia, Protostomia, Arthropoda, Ecdysozoa, Spiralia, and Eumetazoa, however, failed to be recovered due to a few problematic taxa such as the mite Ixodesand the warty comb jelly Mnemiopsis. The corresponding unexpected branchings can be explained by the paucity of synapomorphic changes of intron positions shared between some genomes, by the sensitivity of MP analyses to long-branch attraction (LBA), and by the very unequal evolutionary rates of intron loss and intron gain during evolution of the different subclades of metazoans. In addition, we obtained an assemblage of Cnidaria, Porifera, and Placozoa as sister group of Bilateria+Ctenophora with medium support, a disputable, but remarkable result. We conclude that NIPs can be used as phylogenetic characters also within a broader phylogenetic context, given that they have emerged regularly during evolution irrespective of the large variation of intron density across metazoan genomes.

Genomic and morphological evidence converge to resolve the enigma of Strepsiptera.

The phylogeny of insects, one of the most spectacular radiations of life on earth, has received considerable attention. However, the evolutionary roots of one intriguing group of insects, the twisted-wing parasites (Strepsiptera), remain unclear despite centuries of study and debate. Strepsiptera exhibit exceptional larval developmental features, consistent with a predicted step from direct (hemimetabolous) larval development to complete metamorphosis that could have set the stage for the spectacular radiation of metamorphic (holometabolous) insects. Here we report the sequencing of a Strepsiptera genome and show that the analysis of sequence-based genomic data (comprising more than 18 million nucleotides from nearly 4,500 genes obtained from a total of 13 insect genomes), along with genomic metacharacters, clarifies the phylogenetic origin of Strepsiptera and sheds light on the evolution of holometabolous insect development. Our results provide overwhelming support for Strepsiptera as the closest living relatives of beetles (Coleoptera). They demonstrate that the larval developmental features of Strepsiptera, reminiscent of those of hemimetabolous insects, are the result of convergence. Our analyses solve the long-standing enigma of the evolutionary roots of Strepsiptera and reveal that the holometabolous mode of insect development is more malleable than previously thought.

DNA methylation in Drosophila--a critical evaluation.

Drosophila belongs to the so-called "Dnmt2 only" organisms, and does not contain any of the canonical DNA methyltransferases (Dnmt1 and Dnmt3). Furthermore, no functional homologs of known 5-methylcytosine reader proteins are found. Nevertheless, there is strong evidence for DNA methylation in this organism. It has been suggested that DNA methylation in Drosophila is simply a byproduct of Dnmt2, which is a DNA methyltransferase (Dnmt) according to structure and type of catalysis but functions in vivo as a tRNA methyltransferase. However, concerning the very specific timing of cytosine methylation in Drosophila, their suggested functions in control of retrotransposon silencing and genome stability, and the obvious DNA methylation activity of Dnmt2 enzymes in the protozoans Dictyostelium discoideum and Entamoeba histolytica, we tend to disagree with this notation. Dnmt2 probably serves, and not only in Drosophila, as a methyltransferase of both specific DNA and tRNA targets.

Some novel intron positions in conserved Drosophila genes are caused by intron sliding or tandem duplication.

BACKGROUND: Positions of spliceosomal introns are often conserved between remotely related genes. Introns that reside in non-conserved positions are either novel or remnants of frequent losses of introns in some evolutionary lineages. A recent gain of such introns is difficult to prove. However, introns verified as novel are needed to evaluate contemporary processes of intron gain. RESULTS: We identified 25 unambiguous cases of novel intron positions in 31 Drosophila genes that exhibit near intron pairs (NIPs). Here, a NIP consists of an ancient and a novel intron position that are separated by less than 32 nt. Within a single gene, such closely-spaced introns are very unlikely to have coexisted. In most cases, therefore, the ancient intron position must have disappeared in favour of the novel one. A survey for NIPs among 12 Drosophila genomes identifies intron sliding (migration) as one of the more frequent causes of novel intron positions. Other novel introns seem to have been gained by regional tandem duplications of coding sequences containing a proto-splice site. CONCLUSIONS: Recent intron gains sometimes appear to have arisen by duplication of exonic sequences and subsequent intronization of one of the copies. Intron migration and exon duplication together may account for a significant amount of novel intron positions in conserved coding sequences.

The genome of the stick insect Medauroidea extradentata is strongly methylated within genes and repetitive DNA.

BACKGROUND: Cytosine DNA methylation has been detected in many eukaryotic organisms and has been shown to play an important role in development and disease of vertebrates including humans. Molecularly, DNA methylation appears to be involved in the suppression of initiation or of elongation of transcription. Resulting organismal functions are suggested to be the regulation of gene silencing, the suppression of transposon activity and the suppression of initiation of transcription within genes. However, some data concerning the distribution of methylcytosine in insect species appear to contradict such roles. PRINCIPAL FINDINGS: By comparison of MspI and HpaII restriction patterns in genomic DNA of several insects we show that stick insects (Phasmatodea) have highly methylated genomes. We isolated methylated DNA fragments from the Vietnamese Walking Stick Medauroidea extradentata (formerly known as Baculum extradentatum) and demonstrated that most of the corresponding sequences are repetitive. Bisulfite sequencing of one of these fragments and of parts of conserved protein-coding genes revealed a methylcytosine content of 12.6%, mostly found at CpG, but also at CpT and CpA dinucleotides. Corresponding depletions of CpG and enrichments of TpG and CpA dinucleotides in some highly conserved protein-coding genes of Medauroidea reach a similar degree as in vertebrates and show that CpG methylation has occurred in the germline of these insects. CONCLUSIONS: Using four different methods, we demonstrate that the genome of Medauroidea extradentata is strongly methylated. Both repetitive DNA and coding genes appear to contain high levels of methylcytosines. These results argue for similar functions of DNA methylation in stick insects as those already known for vertebrates.

Near intron positions are reliable phylogenetic markers: an application to holometabolous insects.

Today, the reconstruction of the organismal evolutionary tree is based mainly on molecular sequence data. However, sequence data are sometimes insufficient to reliably resolve in particular deep branches. Thus, it is highly desirable to find novel, more reliable types of phylogenetic markers that can be derived from the wealth of genomic data. Here, we consider the gain of introns close to older preexisting ones. Because correct splicing is impeded by very small exons, nearby pairs of introns very rarely coexist, that is, the gain of the new intron is nearly always associated with the loss of the old intron. Both events may even be directly connected as in cases of intron migration. Therefore, it should be possible to identify one of the introns as ancient (plesiomorphic) and the other as novel (derived or apomorphic). To test the suitability of such near intron pairs (NIPs) as a marker class for phylogenetic analysis, we undertook an analysis of the evolutionary positions of bees and wasps (Hymenoptera) and beetles (Coleoptera) in relation to moths (Lepidoptera) and dipterans (Diptera) using recently completed genome project data. By scanning 758 putatively orthologous gene structures of Apis mellifera (Hymenoptera) and Tribolium castaneum (Coleoptera), we identified 189 pairs of introns, one from each species, which are located less than 50 nt from each other. A comparison with genes from 5 other holometabolan and 9 metazoan outgroup genomes resulted in 22 shared derived intron positions found in beetle as well as in butterflies and/or dipterans. This strongly supports a basal position of hymenopterans in the holometabolous insect tree. In addition, we found 31 and 12 intron positions apomorphic for A. mellifera and T. castaneum, respectively, which seem to represent changes inside these branches. Another 12 intron pairs indicate parallel intron gains or extraordinarily small exons. In conclusion, we show here that the analysis of phylogenetically nested, nearby intron pairs is suitable to identify evolutionarily younger intron positions and to determine their relative age, which should be of equal importance for the understanding of intron evolution and the reconstruction of the eukaryotic tree.

Glimpses of evolution: heterochromatic histone H3K9 methyltransferases left its marks behind.

In eukaryotes, histone methylation is an epigenetic mechanism associated with a variety of functions related to gene regulation or genomic stability. Recently analyzed H3K9 methyltransferases (HMTases) as SUV39H1, Clr4p, DIM-5, Su(var)3-9 or SUVH2 are responsible for the establishment of histone H3 lysine 9 methylation (H3K9me), which is intimately connected with heterochromatinization. In this review, available data will be evaluated concerning (1) the phylogenetic distribution of H3K9me as heterochromatin-specific histone modification and its evolutionary stability in relation to other epigenetic marks, (2) known families of H3K9 methyltransferases, (3) their responsibility for the formation of constitutive heterochromatin and (4) the evolution of Su(var)3-9-like and SUVH-like H3K9 methyltransferases. Compilation and parsimony analysis reveal that histone H3K9 methylation is, next to histone deacetylation, the evolutionary most stable heterochromatic mark, which is established by at least two subfamilies of specialized heterochromatic HMTases in almost all studied eukaryotes.

The evolution of the histone methyltransferase gene Su(var)3-9 in metazoans includes a fusion with and a re-fission from a functionally unrelated gene.

BACKGROUND: In eukaryotes, histone H3 lysine 9 (H3K9) methylation is a common mechanism involved in gene silencing and the establishment of heterochromatin. The loci of the major heterochromatic H3K9 methyltransferase Su(var)3-9 and the functionally unrelated gamma subunit of the translation initiation factor eIF2 are fused in Drosophila melanogaster. Here we examined the phylogenetic distribution of this unusual gene fusion and the molecular evolution of the H3K9 HMTase Su(var)3-9. RESULTS: We show that the gene fusion had taken place in the ancestral line of winged insects and silverfishs (Dicondylia) about 400 million years ago. We cloned Su(var)3-9 genes from a collembolan and a spider where both genes ancestrally exist as independent transcription units. In contrast, we found a Su(var)3-9-specific exon inside the conserved intron position 81-1 of the eIF2gamma gene structure in species of eight different insect orders. Intriguinly, in the pea aphid Acyrthosiphon pisum, we detected only sequence remains of this Su(var)3-9 exon in the eIF2gamma intron, along with an eIF2gamma-independent Su(var)3-9 gene. This reveals an evolutionary re-fission of both genes in aphids. Su(var)3-9 chromo domains are similar to HP1 chromo domains, which points to a potential binding activity to methylated K9 of histone H3. SET domain comparisons suggest a weaker methyltransferase activity of Su(var)3-9 in comparison to other H3K9 HMTases. Astonishingly, 11 of 19 previously described, deleterious amino acid substitutions found in Drosophila Su(var)3-9 are seemingly compensable through accompanying substitutions during evolution. CONCLUSION: Examination of the Su(var)3-9 evolution revealed strong evidence for the establishment of the Su(var)3-9/eIF2gamma gene fusion in an ancestor of dicondylic insects and a re-fission of this fusion during the evolution of aphids. Our comparison of 65 selected chromo domains and 93 selected SET domains from Su(var)3-9 and related proteins offers functional predictions concerning both domains in Su(var)3-9 proteins.

Pivotal role of AtSUVH2 in heterochromatic histone methylation and gene silencing in Arabidopsis.

SU(VAR)3-9 like histone methyltransferases control heterochromatic domains in eukaryotes. In Arabidopsis, 10 SUVH genes encode SU(VAR)3-9 homologues where SUVH1, SUVH2 and SUVH4 (KRYPTONITE) represent distinct subgroups of SUVH genes. Loss of SUVH1 and SUVH4 causes weak reduction of heterochromatic histone H3K9 dimethylation, whereas in SUVH2 null plants mono- and dimethyl H3K9, mono- and dimethyl H3K27, and monomethyl H4K20, the histone methylation marks of Arabidopsis heterochromatin are significantly reduced. Like animal SU(VAR)3-9 proteins SUVH2 displays strong dosage-dependent effects. Loss of function suppresses, whereas overexpression enhances, gene silencing, causes ectopic heterochromatization and significant growth defects. Furthermore, modification of transgene silencing by SUVH2 is partially transmitted to the offspring plants. This epigenetic stability correlates with heritable changes in DNA methylation. Mutational dissection of SUVH2 indicates an implication of its N-terminus and YDG domain in directing DNA methylation to target sequences, a prerequisite for consecutive histone methylation. Gene silencing by SUVH2 depends on MET1 and DDM1, but not CMT3. In Arabidopsis, SUVH2 with its histone H3K9 and H4K20 methylation activity has a central role in heterochromatic gene silencing.

Phylogenetic mapping of intron positions: a case study of translation initiation factor eIF2gamma.

Eukaryotic translation initiation factor 2 (eIF2) is a G protein that delivers the methionyl initiator tRNA to the small ribosomal subunit and releases it upon GTP hydrolysis after the recognition of the initiation codon. eIF2 is composed of three subunits, alpha, beta, and gamma. Subunit gamma shows the strongest conservation, and it confers both tRNA and GTP/GDP binding. Using intron positioning and protein sequence alignment, here we show that eIF2gamma is a suitable phylogenetic marker for eukaryotes. We determined or completed the sequences of 13 arthropod eIF2gamma genes. Analyzing the phylogenetic distribution of 52 different intron positions in 55 distantly related eIF2gamma genes, we identified ancient ones and shared derived introns in our data set. Obviously, intron positioning in eIF2gamma is evolutionarily conserved. However, there were episodes of complete and partial intron losses followed by intron gains. We identified 17 clusters of intron positions based on their distribution. The evolution of these clusters appears to be connected with preferred exon length and can be used to estimate the relative timing of intron gain because nearby precursor introns had to be erased from the gene before the new introns could be inserted. Moreover, we identified a putative case of intron sliding that constitutes a synapomorphic character state supporting monophyly of Coleoptera, Lepidoptera, and Diptera excluding Hymenoptera. We also performed tree reconstructions using the eIF2gamma protein sequences and intron positioning as phylogenetic information. Our results support the monophyly of Viridoplantae, Ascomycota, Homobasidiomyceta, and Apicomplexa.

Su(var) genes regulate the balance between euchromatin and heterochromatin in Drosophila.

Histone lysine methylation is an epigenetic mark to index chromosomal subdomains. In Drosophila, H3-K9 di- and trimethylation is mainly controlled by the heterochromatic SU(VAR)3-9 HMTase, a major regulator of position-effect variegation (PEV). In contrast, H3-K27 methylation states are independently mediated by the Pc-group enzyme E(Z). Isolation of 19 point mutants demonstrates that the silencing potential of Su(var)3-9 increases with its associated HMTase activity. A hyperactive Su(var)3-9 mutant, pitkin(D), displays extensive H3-K9 di- and trimethylation within but also outside pericentric heterochromatin. Notably, mutations in a novel Su(var) gene, Su(var)3-1, severely restrict Su(var)3-9-mediated gene silencing. Su(var)3-1 was identified as "antimorphic" mutants of the euchromatic H3-S10 kinase JIL-1. JIL-1(Su(var)3-1) mutants maintain kinase activity and do not detectably impair repressive histone lysine methylation marks. However, analyses with seven different PEV rearrangements demonstrate a general role of JIL-1(Su(var)3-1) in controlling heterochromatin compaction and expansion. Our data provide evidence for a dynamic balance between heterochromatin and euchromatin, and define two distinct mechanisms for Su(var) gene function. Whereas the majority of Su(var)s encode inherent components of heterochromatin that can establish repressive chromatin structures [intrinsic Su(var)s], Su(var)3-1 reflects gain-of-function mutants of a euchromatic component that antagonize the expansion of heterochromatic subdomains [acquired Su(var)s].

Evolution of the trans-splicing Drosophila locus mod(mdg4) in several species of Diptera and Lepidoptera.

The modifier of mdg4 (mod[mdg4]) locus of Drosophila melanogaster (Dme) encodes chromatin proteins which are involved in position effect variegation, establishment of chromatin boundaries, nerve pathfinding, meiotic chromosome pairing and apoptosis. It was recently shown that mRNA trans-splicing is involved in the generation of at least 26 different mod(mdg4) transcripts. Here, we show that a similar complex mod(mdg4) locus exists in Drosophila pseudoobscura (Dps), Drosophila virilis (Dvi), Anopheles gambiae (Aga) and Bombyx mori (Bmo). As in D. melanogaster, most isoforms of these species contain a strongly conserved BTB/POZ domain (hereafter referred to as BTB domain) within the common N-terminal part and a Cys(2)His(2) motif containing FLYWCH domain within the isoform-specific C-terminal parts. By sequence comparison, we identified six novel isoforms in D. melanogaster and show that altogether 31 isoforms are perfectly conserved by sequence and position in the mod(mdg4) locus of the Drosophila species analyzed. We found significant differences in evolutionary speed of synonymous/nonsynonymous divergence between the various isoform specific exons. These results were extended by tree reconstruction analysis based on the evolved FLYWCH domains of predicted Mod(mdg4) proteins in Drosophila and Anopheles. Comparative analysis of mod(mdg4) gene structure in species of dipterans implicates that several internal inversions occurred making the mRNA trans-splicing mechanism indispensable for mod(mdg4) expression. Finally, we propose a model for the evolution of trans-splicing implementing effective regulation of many alternative gene products in a composite gene structure.

The modifier of mdg4 locus in Drosophila: functional complexity is resolved by trans splicing.

The modifier of mdg4 (mod(mdg4)) gene of Drosophila melanogaster has been identified in many different genetic assays. It has been independently identified through mutations isolated for their effects on position effect variegation (PEV), the properties of insulator sequences, correct pathfinding of growing nerve cells, meiotic pairing of chromosomes, or apoptosis. Molecular analysis of the mod(mdg4) locus revealed that it encodes a family of at least 26 protein isoforms. Inspired by the fact that some mod(mdg4) transcripts are encoded by both antiparallel DNA strands, it was shown that mRNA trans splicing is the mechanism used by this locus to produce mature transcripts. All Mod(mdg4) protein isoforms share a common N-terminal region of 402 amino acids, which includes the conserved BTB/POZ domain. However, the isoforms differ in their C-terminal ends. Most of the C-termini contain a conserved Cys2His2 protein motif, which we have named the FLYWCH motif. Genetic and immunological data indicate that mod(mdg4) encodes a family of related chromatin proteins. Recent results indicate a functional correlation between the large number of different isoforms and the pleiotropic mutant phenotypes of most mod(mdg4) mutations. We discuss the putative function of Mod(mdg4) proteins as chromatin modulators involved in higher order chromatin domains. We also provide evidence for the evolutionary conservation of several of the isoforms and the unusual structure of the locus.

Central role of Drosophila SU(VAR)3-9 in histone H3-K9 methylation and heterochromatic gene silencing.

Su(var)3-9 is a dominant modifier of heterochromatin-induced gene silencing. Like its mammalian and Schizosaccharomyces pombe homologues, Su(var) 3-9 encodes a histone methyltransferase (HMTase), which selectively methylates histone H3 at lysine 9 (H3-K9). In Su(var)3-9 null mutants, H3-K9 methylation at chromocentre heterochromatin is strongly reduced, indicating that SU(VAR)3-9 is the major heterochromatin-specific HMTase in Drosophila. SU (VAR)3-9 interacts with the heterochromatin-associated HP1 protein and with another silencing factor, SU(VAR)3-7. Notably, SU(VAR)3-9-HP1 interaction is interdependent and governs distinct localization patterns of both proteins. In Su(var)3-9 null mutants, concentration of HP1 at the chromocentre is nearly lost without affecting HP1 accumulation at the fourth chromosome. By contrast, in HP1 null mutants SU(VAR)3-9 is no longer restricted at heterochromatin but broadly dispersed across the chromosomes. Despite this interdependence, Su(var)3-9 dominates the PEV modifier effects of HP1 and Su(var)3-7 and is also epistatic to the Y chromosome effect on PEV. Finally, the human SUV39H1 gene is able to partially rescue Su(var)3-9 silencing defects. Together, these data indicate a central role for the SU(VAR)3-9 HMTase in heterochromatin-induced gene silencing in Drosophila.