Molecular mechanisms of cellular determination: their relation to chromatin structure and parental imprinting

On the relations of phase separation and Hi-C maps to epigenetics

The relationship between compartmentalization of the genome and epigenetics is long and hoary. In 1928, Heitz defined heterochromatin as the largest differentiated chromatin compartment in eukaryotic nuclei. Müller's discovery of position-effect variegation in 1930 went on to show that heterochromatin is a cytologically visible state of heritable (epigenetic) gene repression. Current insights into compartmentalization have come from a high-throughput top-down approach where contact frequency (Hi-C) maps revealed the presence of compartmental domains that segregate the genome into heterochromatin and euchromatin. It has been argued that the compartmentalization seen in Hi-C maps is owing to the physiochemical process of phase separation. Oddly, the insights provided by these experimental and conceptual advances have remained largely silent on how Hi-C maps and phase separation relate to epigenetics. Addressing this issue directly in mammals, we have made use of a bottom-up approach starting with the hallmarks of constitutive heterochromatin, heterochromatin protein 1 (HP1) and its binding partner the H3K9me2/3 determinant of the histone code. They are key epigenetic regulators in eukaryotes. Both hallmarks are also found outside mammalian constitutive heterochromatin as constituents of larger (0.1-5 Mb) heterochromatin-like domains and smaller (less than 100 kb) complexes. The well-documented ability of HP1 proteins to function as bridges between H3K9me2/3-marked nucleosomes contributes to polymer-polymer phase separation that packages epigenetically heritable chromatin states during interphase. Contacts mediated by HP1 'bridging' are likely to have been detected in Hi-C maps, as evidenced by the B4 heterochromatic subcompartment that emerges from contacts between large KRAB-ZNF heterochromatin-like domains. Further, mutational analyses have revealed a finer, innate, compartmentalization in Hi-C experiments that probably reflect contacts involving smaller domains/complexes. Proteins that bridge (modified) DNA and histones in nucleosomal fibres-where the HP1-H3K9me2/3 interaction represents the most evolutionarily conserved paradigm-could drive and generate the fundamental compartmentalization of the interphase nucleus. This has implications for the mechanism(s) that maintains cellular identity, be it a terminally differentiated fibroblast or a pluripotent embryonic stem cell.

Genome-wide gene expression effects of sex chromosome imprinting in Drosophila

Imprinting is well-documented in both plant and animal species. In Drosophila, the Y chromosome is differently modified when transmitted through the male and female germlines. Here, we report genome-wide gene expression effects resulting from reversed parent-of-origin of the X and Y chromosomes. We found that hundreds of genes are differentially expressed between adult male Drosophila melanogaster that differ in the maternal and paternal origin of the sex chromosomes. Many of the differentially regulated genes are expressed specifically in testis and midgut cells, suggesting that sex chromosome imprinting might globally impact gene expression in these tissues. In contrast, we observed much fewer Y-linked parent-of-origin effects on genome-wide gene expression in females carrying a Y chromosome, indicating that gene expression in females is less sensitive to sex chromosome parent-of-origin. Genes whose expression differs between females inheriting a maternal or paternal Y chromosome also show sex chromosome parent-of-origin effects in males, but the direction of the effects on gene expression (overexpression or underexpression) differ between the sexes. We suggest that passage of sex chromosome chromatin through male meiosis may be required for wild-type function in F1 progeny, whereas disruption of Y-chromosome function through passage in the female germline likely arises because the chromosome is not adapted to the female germline environment.

Lessons learned from studies of fission yeast mating-type switching and silencing

Stably maintaining specific states of gene expression during cell division is crucial for cellular differentiation. In fission yeast, such patterns result from directed gene rearrangements and chromosomally inherited epigenetic gene control mechanisms that control mating cell type. Recent advances have shown that a specific DNA strand at the mat1 locus is "differentiated" by a novel strand-specific imprint so that nonequivalent sister chromatids are produced. Therefore, cellular differentiation is a natural consequence of the fact that DNA strands are complementary and nonequivalent. Another epigenetic control that "silences" library copies of mat-information is due to heterochromatin organization. This is a clear case where Mendel's gene is composed of DNA plus the associated epigenetic moiety. Following up on initial genetic studies with more recent molecular investigations, this system has become one of the prominent models to understand mechanisms of gene regulation, genome integrity, and cellular differentiation. By applying lessons learned from these studies, such epigenetic gene control mechanisms, which must be installed in somatic cells, might explain mechanisms of cellular differentiation and development in higher eukaryotes.

Proper Gcn5 histone acetyltransferase expression is required for normal anteroposterior patterning of the mouse skeleton

Histone acetylation plays important roles in gene regulation. However, the functions of individual histone acetyltransferases (HATs) in specific developmental transcription programs are not well defined. To define the functions of Gcn5, a prototypical HAT, during mouse development, we have created a series of mutant Gcn5 alleles. Our previous work revealed that deletion of Gcn5 leads to embryonic death soon after gastrulation. Embryos homozygous for point mutations in the catalytic center of Gcn5 survive longer, but die soon after E16.0 and exhibit defects in cranial neural tube closure. Embryos bearing a hypomorphic Gcn5(flox(neo)) allele also exhibit neural closure defects and die at or soon after birth. We report here that Gcn5(flox(neo)/flox(neo)) and Gcn5(flox(neo)/Delta) embryos exhibit anterior homeotic transformations in lower thoracic and lumbar vertebrae. These defects are accompanied by a shift in the anterior expression boundary of Hoxc8 and Hoxc9. These data provide the first evidence that Gcn5 contributes to Hox gene regulation and is required for normal anteroposterior patterning of the mouse skeleton.

Variable expression of Cre recombinase transgenes precludes reliable prediction of tissue-specific gene disruption by tail-biopsy genotyping

The Cre/loxP-system has become the system of choice for the generation of conditional so-called knockout mouse strains, i.e. the tissue-specific disruption of expression of a certain target gene. We here report the loss of expression of Cre recombinase in a transgenic mouse strain with increasing number of generations. This eventually led to the complete abrogation of gene expression of the inserted Cre cDNA while still being detectable at the genomic level. Conversely, loss of Cre expression caused an incomplete or even complete lack of disruption for the protein under investigation. As Cre expression in the tissue of interest in most cases cannot be addressed in vivo during the course of a study, our findings implicate the possibility that individual tail-biopsy genotypes may not necessarily indicate the presence or absence of gene disruption. This indicates that sustained post hoc analyses in regards to efficacy of disruption for every single study group member may be required.

Epigenetic regulation of facultative heterochromatinisation in Planococcus citri via the Me(3)K9H3-HP1-Me(3)K20H4 pathway

Using RNA interference (RNAi) we have conducted a functional analysis of the HP1-like chromobox gene pchet2 during embryogenesis of the mealybug Planococcus citri. Knocking down pchet2 expression results in decondensation of the male-specific chromocenter that normally arises from the developmentally-regulated facultative heterochromatinisation of the paternal chromosome complement. Together with the disappearance of the chromocenter the staining levels of two associated histone modifications, tri-methylated lysine 9 of histone H3 [Me(3)K9H3] and tri-methylated lysine 20 of histone H4 [Me(3)K20H4], are reduced to undetectable levels. Embryos treated with double-stranded RNA (dsRNA) targeting pchet2 also exhibit chromosome abnormalities, such as aberrant chromosome condensation, and also the presence of metaphases that contain 'lagging' chromosomes. We conclude that PCHET2 regulates chromosome behavior during metaphase and is a crucial component of a Me(3)K9H3-HP1-Me(3)K20H4 pathway involved in the facultative heterochromatinisation of the (imprinted) paternal chromosome set.

Polycomb group protein RING1B is a direct substrate of Caspases-3 and -9

Both Caspase-3 and Caspase-9 play critical roles in the execution of mitochondria-mediated apoptosis. Caspase-9 binds to Apaf-1 in the presence of cytochrome c and dATP/ATP, and is activated by self-cleavage. Caspase-3 is activated by cleavage of caspase-8 and caspase-9. Over hundred direct caspase-3 substrates are identified whereas only few direct caspase-9 substrates are known. Here, we demonstrate that Ring1B, a component of polycomb protein complex that plays important roles in modulating chromatin structures, is a direct substrate of active caspase-3 and caspase-9 both in vitro and in vivo. The specific cleavage sites for caspase-3 and caspase-9 were mapped to Asp(175) and Asp(208), respectively. Importantly, cleavage of Ring1B by active caspases-3 and caspase-9 triggers the redistribution of Ring1B, from exclusive nuclear localization to even distribution throughout the entire cell. The transcriptional repression activity of Ring1B was also disrupted by caspase cleavage. Our data suggest that caspases-3 and caspase-9 play novel roles in transcription by regulating polycomb protein function through direct cleaving of Ring1B.

XNP-1/ATR-X acts with RB, HP1 and the NuRD complex during larval development in C. elegans

Mutations in the XNP/ATR-X gene cause several X-linked mental retardation syndromes in humans. The XNP/ATR-X gene encodes a DNA-helicase belonging to the SNF2 family. It has been proposed that XNP/ATR-X might be involved in chromatin remodelling. The lack of a mouse model for the ATR-X syndrome has, however, hampered functional studies of XNP/ATR-X. C. elegans possesses one homolog of the XNP/ATR-X gene, named xnp-1. By analysing a deletion mutant, we show that xnp-1 is required for the development of the embryo and the somatic gonad. Moreover, we show that abrogation of xnp-1 function in combination with inactivation of genes of the NuRD complex, as well as lin-35/Rb and hpl-2/HP1 leads to a stereotyped block of larval development with a cessation of growth but not of cell division. We also demonstrate a specific function for xnp-1 together with lin-35 or hpl-2 in the control of transgene expression, a process known to be dependent on chromatin remodelling. This study thus demonstrates that in vivo XNP-1 acts in association with RB, HP1 and the NuRD complex during development.

Polycomb group gene silencing proteins are concentrated in the perichromatin compartment of the mammalian nucleus

Human Polycomb group (PcG) proteins are involved in cell-type-dependent epigenetic gene silencing in an evolutionarily conserved manner. We have analysed the subnuclear localisation of these regulatory proteins in two different human cell lines and in rat liver tissue by means of light and electron immunomicroscopy using specific antibodies. We find that the PcG proteins HPC2, HPH1, BMI1 and RING1 are highly concentrated in the perichromatin compartment, situated at the surface of condensed chromatin domains. This compartment was demonstrated earlier to be the nuclear site where most pre-mRNA synthesis takes place. Interestingly, these PcG proteins are virtually absent from the interior of condensed chromatin areas. The present observations therefore show that transcriptionally active and PcG-silenced loci occur within the same spatially limited nuclear domain. Our novel high-resolution data strongly support the idea that epigenetic PcG-mediated gene silencing is a local event, rather than affecting large chromatin domains. In addition to being associated with the perichromatin region, PcG proteins also occur in the interchromatin space. Implications of these observations for higher order chromatin structure and for the mechanisms of PcG-mediated gene silencing are discussed.

A developmentally regulated ARF-like 5 protein (ARL5), localized to nuclei and nucleoli, interacts with heterochromatin protein 1

ARF-like proteins (ARLs) are distinct group of members of the ARF family of Ras-related GTPases. Although ARLs are very similar in primary structure to ARFs, their functions remain unclear. We cloned mouse (m) and human (h) ARL5 cDNAs to characterize the protein products and their molecular properties. mARL5 mRNA was more abundant in liver than in other adult tissues tested. mARL5, similar to mARL4, was developmentally regulated and localized to nuclei. hARL5 interacted with importin-alpha through its C-terminal bipartite nuclear localization signal. When expressed in COS-7 cells, mutant hARL5(T35N), which is predicted to be GDP bound, was concentrated in nucleoli. The N-terminus of hARL5, like that of ARF, was myristoylated. Yeast two-hybrid screening and in vitro protein-interaction assays showed that hARL5(Q80L), predicted to be GTP bound, interacted with heterochromatin protein 1alpha (HP1alpha), which is known to be associated with telomeres as well as with heterochromatin, and acted as a transcriptional suppressor in mammalian cells. The interaction was reproduced in COS cells, where hARL5(Q80L) was co-immunoprecipitated with HP1alpha. hARL5 interaction with HP1alpha was dependent on the nucleotide bound, and required the MIR-like motif. Moreover, hARL5(Q80L), but not hARL5 lacking the MIR-like motif, was partly co-localized with overexpressed HP1alpha. Our findings suggest that developmentally regulated ARL5, with its distinctive nuclear/nucleolar localization and interaction with HP1alpha, may play a role(s) in nuclear dynamics and/or signaling cascades during embryonic development.

The 2.1-kb inverted repeat DNA sequences flank the mat2,3 silent region in two species of Schizosaccharomyces and are involved in epigenetic silencing in Schizosaccharomyces pombe

The mat2,3 region of the fission yeast Schizosaccharomyces pombe exhibits a phenomenon of transcriptional silencing. This region is flanked by two identical DNA sequence elements, 2.1 kb in length, present in inverted orientation: IRL on the left and IRR on the right of the silent region. The repeats do not encode any ORF. The inverted repeat DNA region is also present in a newly identified related species, which we named S. kambucha. Interestingly, the left and right repeats share perfect identity within a species, but show approximately 2% bases interspecies variation. Deletion of IRL results in variegated expression of markers inserted in the silent region, while deletion of the IRR causes their derepression. When deletions of these repeats were genetically combined with mutations in different trans-acting genes previously shown to cause a partial defect in silencing, only mutations in clr1 and clr3 showed additive defects in silencing with the deletion of IRL. The rate of mat1 switching is also affected by deletion of repeats. The IRL or IRR deletion did not cause significant derepression of the mat2 or mat3 loci. These results implicate repeats for maintaining full repression of the mat2,3 region, for efficient mat1 switching, and further support the notion that multiple pathways cooperate to silence the mat2,3 domain.

Characterisation of set-1, a conserved PR/SET domain gene in Caenorhabditis elegans

The SET domain is a highly conserved domain shared between proteins of the antagonistic trithorax and Polycomb groups. It has been shown to play an important role in the assembly of either transcriptional activating or repressing protein complexes, and possesses a histone methyl-transferase activity. We report here the characterisation of the Caenorhabditis elegans gene, set-1, encoding a conserved SET-domain protein. We have analysed the developmental expression pattern of set-1 and show that maximal expression is observed early in development when set-1 is ubiquitously expressed. Its expression is more and more restricted as development progress. Gene inactivation by RNA interference shows that set-1 is an essential gene. Functional analysis of set-1 may contribute to the understanding of the molecular role of the SET domain.

Multiple effects of genetic background on variegated transgene expression in mice

BLG/7 transgenic mice express an ovine beta-lactoglobulin transgene during lactation. Unusually, transgene expression levels in milk differ between siblings. This variable expression is due to variegated transgene expression in the mammary gland and is reminiscent of position-effect variegation. The BLG/7 line was created and maintained on a mixed CBA x C57BL/6 background. We have investigated the effect on transgene expression of backcrossing for 13 generations into these backgrounds. Variable transgene expression was observed in all populations examined, confirming that it is an inherent property of the transgene array at its site of integration. There were also strain-specific effects on transgene expression that appear to be independent of the inherent variegation. The transgene, compared to endogenous milk protein genes, is specifically susceptible to inbreeding depression. Outcrossing restored transgene expression levels to that of the parental population; thus suppression was not inherited. Finally, no generation-dependent decrease in mean expression levels was observed in the parental population. Thus, although the BLG/7 transgene is expressed in a variegated manner, there was no generation-associated accumulated silencing of transgene expression.

Chromodomain protein Swi6-mediated role of DNA polymerase alpha in establishment of silencing in fission Yeast

Although DNA replication has been thought to play an important role in the silencing of mating type loci in Saccharomyces cerevisiae, recent studies indicate that silencing can be decoupled from replication. In Schizosaccharomyces pombe, mating type silencing is brought about by the trans-acting proteins, namely Swi6, Clr1-Clr4, and Rhp6, in cooperation with the cis-acting silencers. The latter contain an autonomous replication sequence, suggesting that DNA replication may be critical for silencing in S. pombe. To investigate the connection between DNA replication and silencing in S. pombe, we analyzed several temperature-sensitive mutants of DNA polymerase alpha. We find that one such mutant, swi7H4, exhibits silencing defects at mat, centromere, and telomere loci. This effect is independent of the checkpoint and replication defects of the mutant. Interestingly, the extent of the silencing defect in the swi7H4 mutant at the silent mat2 locus is further enhanced in absence of the cis-acting, centromere-proximal silencer. The chromodomain protein Swi6, which is required for silencing and is localized to mat and other heterochromatin loci, interacts with DNA polymerase alpha in vivo and in vitro in wild type cells. However, it does not interact with the mutant pol alpha and is delocalized away from the silent mat loci in the mutant. Our results demonstrate a role of DNA polymerase alpha in the establishment of silencing. We propose a recruitment model for the coupling of DNA replication with the establishment of silencing by the chromodomain protein Swi6, which may be applicable to higher eukaryotes.

A novel transrepression pathway of c-Myc. Recruitment of a transcriptional corepressor complex to c-Myc by MM-1, a c-Myc-binding protein

The protooncogene product c-Myc plays a role in transcription regulation both for activation and repression. While transactivation pathways of c-Myc either from the N-proximal or the C-proximal region that is linked to the chromatin remodeling complex have been identified, a transrepression pathway had been identified only from the C-proximal region via Max and Mad that recruit the histone deacetylase (HDAC) complex. We have reported that a novel c-Myc-binding protein, MM-1, repressed the E-box-dependent transcription activity of c-Myc (Mori, K., Maeda, Y., Kitaura, H., Taira, T., Iguchi-Ariga, S. M. M., and Ariga, H. (1998) J. Biol. Chem. 273, 29794-29800). To clarify the molecular mechanisms of MM-1 toward c-Myc, cDNAs encoding MM-1-binding proteins were screened by the two-hybrid method with MM-1 as a bait using a human HeLa cDNA library, and a cDNA encoding TIF1 beta/KAP1, a transcriptional corepressor, was obtained. MM-1 was found to bind to the central portion of TIF1 beta in vitro and in vivo, and these proteins were found to be colocalized in the nucleus. MM-1 and TIF1 beta complex in human HeLa cells was found to also contain c-Myc, mSin3, and HDAC1. Introduction of the C-terminal half of TIF1 beta as a dominant negative form abrogated the inhibitory activity of MM-1 toward c-Myc and greatly stimulated the transcription activity of c-Myc. Moreover, the inhibitory activity of MM-1 toward c-Myc was canceled by trichostatin A, an inhibitor of HDAC1. These results indicate that MM-1 is a connecting factor that forms a novel transcription repression pathway of c-Myc.

Chromatin condensation and sensitivity of DNA in situ to denaturation during cell cycle and apoptosis--a confocal microscopy study

The goal of this study was to construct high resolution 3D confocal images of regions of condensed and extended chromatin in cell nuclei and individual chromosomes. It has been shown previously that sensitivity of DNA in situ to denaturation correlates with chromatin condensation and varies during cell cycle and apoptosis. Thus, detection of DNA which was partially denatured in situ provided a means to image areas of condensed chromatin. DNA denaturation was detected using a metachromatic dye acridine orange (AO) which differentially stains single stranded (ss) and double-stranded (ds) DNA sections. Early studies of denaturability of cellular DNA utilized flow cytometry and standard fluorescence microscopy. These techniques could not reveal small local differences in DNA denaturability within cell nucleus or in individual chromosomes. For instance, it was not possible to detect the initial points of chromosome condensation in G2-phase of the division cycle or in apoptosis. In order to achieve this goal we have recently extended these studies by applying confocal microscopy. We investigated DNA denaturability in normal human fibroblasts and HL-60 leukemic cells, at different stages of cell cycle and apoptosis. Following removal of RNA and partial denaturation of DNA with acid cells were stained with AO. Green (530 nm) and red (640 nm) fluorescence (exc. 457 nm) of non-denatured and denatured DNA was imaged by confocal microscopy. Blind deconvolution was used to further improve the quality of 3D images. Photobleaching of AO fluorescence was minimized and a correction for chromatic aberration and register shift was implemented. Nuclei of interphase cells exhibited predominantly green fluorescence representing AO binding to ds DNA. Punctuate areas of red fluorescence representing AO binding to denatured DNA and most likely associated with local regions of condensed chromatin were also present in all interphase nuclei. The proportion of denatured DNA increased in cells entering mitosis. In prophase individual condensing chromosomes exhibited varied proportions of green and red fluorescence indicating different content of denatured chromatin. In some chromosomes bands of denatured and denaturation-resistant chromatin were clearly resolved. In metaphase and anaphase chromosomes exhibited red fluorescence along all length of their arms indicating the highest and uniform susceptibility to denaturation. In telophase chromosomes contained predominantly denaturation-resistant DNA again and denaturated regions were significantly less abundant. At cytokinesis some decondensing chromosomes were still resolved. At this stage almost all regions of denatured DNA were located close to nuclear envelope. These regions may correspond to pockets of heterochromatin reforming at nuclear periphery. In early apoptosis condensation of chromatin appeared to commence in several distinct regions within nucleus. Some apoptotic bodies contained condensed chromatin surrounding central regions of extended chromatin. At late stages of apoptosis the whole volume of apoptotic bodies was occupied by condensed chromatin.

The synovial sarcoma associated protein SYT interacts with the acute leukemia associated protein AF10

As a result of the synovial sarcoma associated t(X;18) translocation, the human SYT gene on chromosome 18 is fused to either the SSX1 or the SSX2 gene on the X chromosome. Although preliminary evidence indicates that the (fusion) proteins encoded by these genes may play a role in transcriptional regulation, little is known about their exact function. We set out to isolate interacting proteins through yeast two hybrid screening of a human cDNA library using SYT as a bait. Of the positive clones isolated, two were found to correspond to the acute leukemia t(10;11) associated AF10 gene, a fusion partner of MLL. Confirmation of these results was obtained via co-immunoprecipitation of endogenous and exogenous, epitope-tagged, SYT and AF10 proteins from cell line extracts and colocalization of epitope-tagged SYT and AF10 proteins in transfected cells. Subsequent sequential mutation analysis revealed a highly specific interaction of N-terminal SYT fragments with C-terminal AF10 fragments. The N-terminal interaction domain of the SYT protein was also found to be present in several SYT orthologs and homologs. The C-terminal interaction domain of AF10 is located outside known functional domains. Based on these results, a model is proposed in which the SYT and AF10 proteins act in concert as bipartite transcription factors. This model has implications for the molecular mechanisms underlying the development of both human synovial sarcomas and acute leukemias.

Altered retinoic acid sensitivity and temporal expression of Hox genes in polycomb-M33-deficient mice

The Polycomb group genes are required for the correct expression of the homeotic complex genes and segment specification during Drosophila embryogenesis and larval development. In mouse, inactivation studies of several Polycomb group genes indicate that they are also involved in Hox gene regulation. We have used our previously generated M33 mutants to study the function of M33, the mouse homologue of the Polycomb gene of Drosophila. In this paper, we show that in the absence of M33, the window of Hoxd4 retinoic acid (RA) responsiveness is opened earlier and that Hoxd11 gene expression is activated earlier in development This indicates that M33 antagonizes the RA pathway and has a function in the establishment of the early temporal sequence of activation of Hox genes. Despite the early activation, A-P boundaries are correct in later stages, indicating a separate control mechanism for early aspects of Hox regulation. This raises a number of interesting issues with respect to the roles of both Pc-G proteins and Hox regulatory mechanisms. We propose that a function of the M33 protein is to control the accessibility of retinoic acid response elements in the vicinity of Hox genes regulatory regions by direct or indirect mechanisms or both. This could provide a means for preventing ectopic transactivation early in development and be part of the molecular basis for temporal colinearity of Hox gene expression.

Chromatin complexes as aperiodic microcrystalline arrays that regulate genome organisation and expression

The current understanding of chromatin-mediated repression in Metazoa stems largely from work on two systems in Drosophila: heterochromatin-induced position-effect variegation and repression of the homeotic genes by the Polycomb-group of genes. A common feature of these two systems is the cooperative assembly of multimeric complexes which can epigenetically silence gene activity. Moreover, both older and more recent work has suggested that these complexes can themselves associate to give rise to larger complexes: The specificity of the association is likely to be determined by complementarity of the structural components of the complexes. Here, we aim to accommodate these, and other, features of chromatin-mediated repression in a single hypothesis, namely the crystallisation hypothesis. This hypothesis views the nucleus as being an environment that favours the formation of chromatin complexes which behave as aperiodic microcrystalline arrays constructed through the cooperative assembly of different types of lattice unit. The lattice units possess regions of structural complementarity that allow interactions between complexes. Aperiodicity confers specificity on the complexes and is a key feature of the model which, we suggest, provides a gene with a "chromosomal address." The chromosomal address allows the side-by-side alignment of homologous chromosomal regions, a properly that may be important in a variety of biologically relevant situations. Aperiodicity is also a feature of the hypothesis that is directly testable.

Chromatin and chromosomal controls in development

Chromatin and chromosomes have major regulatory roles in development. Nucleosome positioning and modification, chromatin structural transitions and domain organization all contribute to the regulation of individual genes and gene families. Chromosomal position and nuclear compartmentalization represent important contributory factors in determining cell fate. These controls may explain many interesting and unexplored features of developmental systems.

A chromodomain protein, Swi6, performs imprinting functions in fission yeast during mitosis and meiosis

Inheritance of stable states of gene expression is essential for cellular differentiation. In fission yeast, an epigenetic imprint marking the mating-type (mat2/3) region contributes to inheritance of the silenced state, but the nature of the imprint is not known. We show that a chromodomain-containing Swi6 protein is a dosage-critical component involved in imprinting the mat locus. Transient overexpression of Swi6 alters the epigenetic imprint at the mat2/3 region and heritably converts the expressed state to the silenced state. The establishment and maintenance of the imprint are tightly coupled to the recruitment and the persistence of Swi6 at the mat2/3 region during mitosis as well as meiosis. Remarkably, Swi6 remains bound to the mat2/3 interval throughout the cell cycle and itself seems to be a component of the imprint. Our analyses suggest that the unit of inheritance at the mat2/3 locus comprises the DNA plus the associated Swi6 protein complex.

Nucleotide sequence of the feline Bmi-1 coding region

The bmi-1 gene was discovered as a clonal integration site of the Moloney murine leukaemia virus in B-cell lymphomas. The Bmi-1 protein contains the RING finger motif and is homologous to two Drosophila proteins known to be part of a multimeric protein complex involved in repressing gene transcription. A similar role for the highly conserved Bmi-1 protein in mammalian cells has been suggested. The coding regions for the mouse and human genes are known and are 92% homologous. This study involved PCR amplification, cloning, and sequencing of the 980bp feline bmi-1 coding region which was shown to be 92% and 97% homologous to the mouse and human genes respectively. From the open reading frame the feline protein is 326 amino acids in length and is 99% homologous to the human protein and 97% homologous to the mouse protein. This data is consistent with the closer relationship between the feline and human genomes and provides another experimental system in which to analyse Bmi-1 function.

Locus control regions and epigenetic chromatin modifiers

Locus control regions are defined as gene regulatory sequences that enable chromosomal position-independent gene expression in transgenic mice. Recent studies have shown the ability of such regions to overcome the highly repressive effect of heterochromatin and have identified both trans-acting and cis-acting factors that participate in gene silencing and activation mechanisms.

Identification of heterochromatin protein 1 (HP1) as a phosphorylation target by Pim-1 kinase and the effect of phosphorylation on the transcriptional repression function of HP1(1)

Pim-1, a protooncogene product, is a serine/threonine kinase and is thought to play a role in signal transduction in blood cells. Few phosphorylated target proteins for Pim-1, however, have been identified. In the present study, two-hybrid screening to clone cDNAs encoding proteins binding to Pim-1 was carried out, and a cDNA for heterochromatin protein 1gamma (HP1gamma) was obtained. Binding assays both in yeast and in vitro pull-down using the purified HP1gamma and Pim-1 expressed in Escherichia coli showed that Pim-1 directly bound to the chromo shadow domain of HP1gamma. HP1gamma was also associated with Pim-1 in human HeLa cells and the serine clusters located at the center of HP1gamma were phosphorylated by Pim-1 in vitro. Furthermore, a transcription repression activity of HP1gamma was further stimulated by the deletion of the serine clusters targeted by Pim-1. These results suggest that Pim-1 affects the structure or silencing of chromatin by phosphorylating HP1.

Mammalian chromodomain proteins: their role in genome organisation and expression

The chromodomain is a highly conserved sequence motif that has been identified in a variety of animal and plant species. In mammals, chromodomain proteins appear to be either structural components of large macromolecular chromatin complexes or proteins involved in remodelling chromatin structure. Recent work has suggested that apart from a role in regulating gene activity, chromodomain proteins may also play roles in genome organisation. This article reviews progress made in characterising mammalian chromodomain proteins and emphasises their emerging role in the regulation of gene expression and genome organisation. BioEssays 22:124-137, 2000.

The murine heterochromatin protein M31 is associated with the chromocenter in round spermatids and Is a component of mature spermatozoa

In mature sperm the normal nucleosomal packaging of DNA found in somatic and meiotic cells is transformed into a highly condensed form of chromatin which consists mostly of nucleoprotamines. Although sperm DNA is highly condensed it is nevertheless packaged into a highly defined nuclear architecture which may be organized by the heterochromatic chromocenter. One major component of heterochromatin is the heterochromatin protein 1 which is involved in epigenetic gene silencing. In order to investigate the possible involvement of heterochromatin protein in higher order organization of sperm DNA we studied the localization of the murine homologue of heterochromatin protein 1, M31, during chromatin reorganization in male germ cell differentiation. Each cell type in the testis showed a unique distribution pattern of M31. Colocalization to the heterochromatic regions were found in Sertoli cells, in midstage pachytene spermatocytes, and in round spermatids in which M31 localizes to the centromeric chromocenter. M31 cannot be detected in elongated spermatids or mature spermatozoa immunocytologically, but could be detected in mature spermatozoa by Western blotting. We suggest that M31, a nuclear protein involved in the organization of chromatin architecture, is involved in higher order organization of sperm DNA.

Heterochromatin protein 1 modifies mammalian PEV in a dose- and chromosomal-context-dependent manner

Locus control regions (LCRs) are gene regulatory elements in mammals that can overcome the highly repressive effects normally associated with heterochromatic transgene locations (for example the centromere) in mice. Deletion of essential LCR sequences renders the cognate gene susceptible to this form of repression, so a proportion of the cells from transgenic mice that would normally express the transgene are silenced-a phenomenon known as position effect variegation (PEV). We show here that PEV can also occur when the transgene is non-centromeric and that the extent of variegation can be developmentally regulated. Furthermore, by overexpressing a mammalian homologue (M31) of Drosophila melanogaster heterochromatin protein 1 (HP1; refs 7,8) in transgenic mouse lines that exhibit PEV, it is possible to modify the proportion of cells that silence the transgene in a dose-dependent manner. Thus, we show M31 overexpression to have two contrasting effects which are dependent on chromosomal context: (i) it enhanced PEV in those lines with centromeric or pericentromeric transgene locations; and (ii) it suppressed PEV when the transgene was non-centromeric. Our results indicate that components or modifiers of heterochromatin may have a chromosomal-context-dependent role in gene silencing and activation decisions in mammals.

Proteins recognized by antibodies against isolated cytological heterochromatin from rat liver cells change their localization between cell species and between stages of mitosis (interphase vs metaphase)

Heterochromatin in the cell nucleus seems to concentrate various proteins, such as Drosophila heterochromatin protein 1, which maintain the repressed state of gene expression. However, it still remains obscure how protein composition related to chromatin structure is different between heterochromatin and euchromatin in interphase nuclei. We isolated cytological heterochromatin from sonicated interphase nuclei obtained from rat liver cells and prepared antisera against it. The dense heterochromatic bodies seen in the preparation of intact nuclei were duplicated in a relatively pure form during the preparation of heterochromatin. In the sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) analysis, differences between the fractions of heterochromatin and euchromatin were noted by their protein composition. Isolated heterochromatin was then digested by DNase after partial digestion with trypsin and its dense structure changed to become highly sensitive to DNase. The prepared antibodies reacted with the heterochromatin region of rat liver cell nuclei and isolated cytological heterochromatin; however, they did not react with euchromatin. Using immunohistochemistry, the antibodies bound to each cell nucleus in all tissues observed; some cell types were distinguished by their differential stainability (e.g. staining in the cytoplasm). Staining of the mitotic cells showed that the proteins recognized by the antibodies were localized in the cytoplasm and, in part, on the chromosomes. Based on the results of molecular cloning from rat liver cDNA library using the antibodies as a probe, it seemed that the antibodies mainly recognized two proteins similar to arginase and general vesicular transport factor p115, respectively. The results obtained from these experiments reveal that some proteins located in the heterochromatin of interphase liver cell nuclei seem to play important roles in condensing a portion of the chromatin structure during interphase and suggest that proteins composing heterochromatin might be changed according to cell types or the stage of the cell cycle.

Sectorial gene repression in the control of development

Some evidence suggests that a number of regulator genes and gene clusters will likely be found to share with HOX complexes the property of being repressible ('superrepressible') through factor-driven conformational changes over whole sectors of chromatin, and of being assigned body locations in which they are either stably superrepressed or poised for transcription, according to determinants that act vectorially across a morphological zone. Such a subpopulation of regulator genes is expected to include, notably, genes governing developmental processes and might be thought to number, in mammals, between one hundred and several hundreds. When superrepressed, regulator genes are anticipated either to block programs of gene action or to permit these programs to unfold. To a significant extent, development would be determined by successive intersections of the paths of gene action deployment with superrepressed genes. These intersections, in cell lines advancing toward terminal differentiation, would be responsible for the progressive narrowing of the range of gene action programs potentially still available for later development. One implication of this model is that mosaic and regulative embryos are distinct merely by virtue of the time of onset of superrepression in their different cell lineages. Determination and transdetermination are considered to express the differential distribution over the genome of bound regulatory factors that function as molecular tools of superrepression, notably polycomb-group-like proteins. In turn, superrepressed genes are anticipated to be differentially distributed over cell types and thus to furnish a major framework for progressive differentiation and for the progressive limitation of the developmental potential of cells.

Genetic dissection of X-linked interspecific hybrid placental dysplasia in congenic mouse strains

Interspecific hybridization in the genus Mus results in male sterility and X-linked placental dysplasia. We have generated several congenic laboratory mouse lines (Mus musculus) in which different parts of the maternal X chromosome were derived from M. spretus. A strict positive correlation between placental weight and length of the M. spretus-derived part of the X chromosome was shown. Detailed analysis was carried out with one congenic strain that retained a M. spretus interval between 12.0 and 30.74 cM. This strain consistently produced hyperplastic placentas that exhibited an average weight increase of 180% over the weight of control placentas. In derived subcongenic strains, however, increased placental weight could no longer be observed. Morphometric analysis of these placentas revealed persistence of abnormal morphology. Fully developed placental hyperplasia could be reconstituted by recombination of proximal and central M. spretus intervals with an intervening M. musculus region. These results may suggest that placental dysplasia of interspecific mouse hybrids is caused by multiple loci clustered on the X chromosome that act synergistically. Alternatively, it is possible that changes in chromatin structure in interspecific hybrids that influence gene expression are dependent on the length of the alien chromosome.

KAP-1 corepressor protein interacts and colocalizes with heterochromatic and euchromatic HP1 proteins: a potential role for Krüppel-associated box-zinc finger proteins in heterochromatin-mediated gene silencing

Krüppel-associated box (KRAB) domains are present in approximately one-third of all human zinc finger proteins (ZFPs) and are potent transcriptional repression modules. We have previously cloned a corepressor for the KRAB domain, KAP-1, which is required for KRAB-mediated repression in vivo. To characterize the repression mechanism utilized by KAP-1, we have analyzed the ability of KAP-1 to interact with murine (M31 and M32) and human (HP1alpha and HP1gamma) homologues of the HP1 protein family, a class of nonhistone heterochromatin-associated proteins with a well-established epigenetic gene silencing function in Drosophila. In vitro studies confirmed that KAP-1 is capable of directly interacting with M31 and hHP1alpha, which are normally found in centromeric heterochromatin, as well as M32 and hHP1gamma, both of which are found in euchromatin. Mapping of the region in KAP-1 required for HP1 interaction showed that amino acid substitutions which abolish HP1 binding in vitro reduce KAP-1 mediated repression in vivo. We observed colocalization of KAP-1 with M31 and M32 in interphase nuclei, lending support to the biochemical evidence that M31 and M32 directly interact with KAP-1. The colocalization of KAP-1 with M31 is sometimes found in subnuclear territories of potential pericentromeric heterochromatin, whereas colocalization of KAP-1 and M32 occurs in punctate euchromatic domains throughout the nucleus. This work suggests a mechanism for the recruitment of HP1-like gene products by the KRAB-ZFP-KAP-1 complex to specific loci within the genome through formation of heterochromatin-like complexes that silence gene activity. We speculate that gene-specific repression may be a consequence of the formation of such complexes, ultimately leading to silenced genes in newly formed heterochromatic chromosomal environments.

Point mutations in the WD40 domain of Eed block its interaction with Ezh2

The Polycomb group proteins are involved in maintenance of the silenced state of several developmentally regulated genes. These proteins form large aggregates with different subunit compositions. To explore the nature of these complexes and their function, we used the full-length Eed (embryonic ectoderm development) protein, a mammalian homolog of the Drosophila Polycomb group protein Esc, as a bait in the yeast two-hybrid screen. Several strongly interacting cDNA clones were isolated. The cloned cDNAs all encoded the 150- to 200-amino-acid N-terminal fragment of the mammalian homolog of the Drosophila Enhancer of zeste [E(z)] protein, Ezh2. The full-length Ezh2 bound strongly to Eed in vitro, and Eed coimmunoprecipitated with Ezh2 from murine 70Z/3 cell extracts, confirming the interaction between these proteins observed in yeast. Mutations T1031A and T1040C in one of the WD40 repeats of Eed, which account for the hypomorphic and lethal phenotype of eed in mouse development, blocked binding of Ezh2 to Eed in a two-hybrid interaction in yeast and in mammalian cells. These mutations also blocked the interaction between these proteins in vitro. In mammalian cells, the Gal4-Eed fusion protein represses the activity of a promoter bearing Gal4 DNA elements. The N-terminal fragment of the Ezh2 protein abolished the transcriptional repressor activity of Gal4-Eed protein when they were coexpressed in mammalian cells. Eed and Ezh2 were also found to bind RNA in vitro, and RNA altered the interaction between these proteins. These findings suggest that Polycomb group proteins Eed and Ezh2 functionally interact in mammalian cells, an interaction that is mediated by the WD40-containing domain of Eed protein.

Histone deacetylase homologs regulate epigenetic inheritance of transcriptional silencing and chromosome segregation in fission yeast

Position-effect control at the silent mat2-mat3 interval and at centromeres and telomeres in fission yeast is suggested to be mediated through the assembly of heterochromatin-like structures. Therefore, trans-acting genes that affect silencing may encode either chromatin proteins, factors that modify them, or factors that affect chromatin assembly. Here, we report the identification of an essential gene, clr6 (cryptic loci regulator), which encodes a putative histone deacetylase that when mutated affects epigenetically maintained repression at the mat2-mat3 region and at centromeres and reduces the fidelity of chromosome segregation. Furthermore, we show that the Clr3 protein, when mutated, alleviates recombination block at mat region as well as silencing at donor loci and at centromeres and telomeres, also shares strong homology to known histone deacetylases. Genetic analyses indicate that silencing might be regulated by at least two overlapping histone deacetylase activities. We also found that transient inhibition of histone deacetylase activity by trichostatin A results in the increased missegregation of chromosomes in subsequent generations and, remarkably, alters the imprint at the mat locus, causing the heritable conversion of the repressed epigenetic state to the expressed state. This work supports the model that the level of histone deacetylation has a role in the assembly of repressive heterochromatin and provides insight into the mechanism of epigenetic inheritance.

The human polycomb group complex associates with pericentromeric heterochromatin to form a novel nuclear domain

The Polycomb group (PcG) complex is a chromatin-associated multiprotein complex, involved in the stable repression of homeotic gene activity in Drosophila. Recently, a mammalian PcG complex has been identified with several PcG proteins implicated in the regulation of Hox gene expression. Although the mammalian PcG complex appears analogous to the complex in Drosophila, the molecular mechanisms and functions for the mammalian PcG complex remain unknown. Here we describe a detailed characterization of the human PcG complex in terms of cellular localization and chromosomal association. By using antibodies that specifically recognize three human PcG proteins- RING1, BMI1, and hPc2-we demonstrate in a number of human cell lines that the PcG complex forms a unique discrete nuclear structure that we term PcG bodies. PcG bodies are prominent novel nuclear structures with the larger PcG foci generally localized near the centromeres, as visualized with a kinetochore antibody marker. In both normal fetal and adult fibroblasts, PcG bodies are not randomly dispersed, but appear clustered into defined areas within the nucleus. We show in three different human cell lines that the PcG complex can tightly associate with large pericentromeric heterochromatin regions (1q12) on chromosome 1, and with related pericentromeric sequences on different chromosomes, providing evidence for a mammalian PcG-heterochromatin association. Furthermore, these heterochromatin-bound PcG complexes remain stably associated throughout mitosis, thereby allowing the potential inheritance of the PcG complex through successive cell divisions. We discuss these results in terms of the known function of the PcG complex as a transcriptional repression complex.

Chromatin modification of imprinted H19 gene in mammalian spermatozoa

The allele-specific epigenetic markings of endogenously imprinted genes in placental mammals occur during gametogenesis. The identification of the molecular nature of gametic imprints is the first step towards understanding the mechanistic basis of epigenesis in embryonic and adult somatic tissues. The specific question addressed in this work is whether the closely positioned but oppositely imprinted insulin-like growth factor 2 (IGF 2) and H19 genes, which have similar temporal regulation during development, differ in chromatin structure in mammalian spermatozoa. During terminal differentiation of mammalian spermatozoa, about 3-15% of the haploid genome retains a quasisomatic-type chromatin structure, whereas the remaining genomes interact with protamines that are further cross-linked by-S-S- bridges. Micrococcal nuclease (MNase) and DNase I digestions of human (HSN) and porcine sperm nuclei (PSN) showed that the IGF 2 gene in both types of nuclei retained somatic-type nucleosomes that were close-packed with a periodicity of 150 bp. However, the H19 gene in both species was predominantly organised by unique structural repeats, which were 650-674 bp in PSN and 438-522 bp in HSN, condensing at least 20 kb of chromatin. These results, together with previous studies, suggest that epigenetic chromatin modification leading to preferential condensation of the paternal H19 allele in embryonic tissues is already present in the germ cells.

Interaction of SP100 with HP1 proteins: a link between the promyelocytic leukemia-associated nuclear bodies and the chromatin compartment

The PML/SP100 nuclear bodies (NBs) were first described as discrete subnuclear structures containing the SP100 protein. Subsequently, they were shown to contain the PML protein which is part of the oncogenic PML-RARalpha hybrid produced by the t(15;17) chromosomal translocation characteristic of acute promyelocytic leukemia. Yet, the physiological role of these nuclear bodies remains unknown. Here, we show that SP100 binds to members of the heterochromatin protein 1 (HP1) families of non-histone chromosomal proteins. Further, we demonstrate that a naturally occurring splice variant of SP100, here called SP100-HMG, is a member of the high mobility group-1 (HMG-1) protein family and may thus possess DNA-binding potential. Both HP1 and SP100-HMG concentrate in the PML/SP100 NBs, and overexpression of SP100 leads to enhanced accumulation of endogenous HP1 in these structures. When bound to a promoter, SP100, SP100-HMG and HP1 behave as transcriptional repressors in transfected mammalian cells. These observations present molecular evidence for an association between the PML/SP100 NBs and the chromatin nuclear compartment. They support a model in which the NBs may play a role in certain aspects of chromatin dynamics.

Mammalian Polycomb group genes are categorized as a new type of early response gene induced by B-cell receptor cross-linking

Polycomb group (PcG) genes were initially described in Drosophila melanogaster as regulators of the homeobox gene. Four mammalian homologues, mel-18, bmi-1, M33 and rae-28, are analyzed in this study. They not only regulate mammalian homeotic genes by analogy with their Drosophila counterparts, but also have some influence on the growth and differentiation of B lymphocytes. Here we report that these four mammalian PcG genes are rapidly induced after antigen-receptor cross-linking in B cells. Thus we would like to propose that mammalian PcG genes can be categorized as a new type of immediate early gene.

The chromo and SET domains of the Clr4 protein are essential for silencing in fission yeast

Heritable inactivation of specific regions of the genome is a widespread, possibly universal phenomenon for gene regulation in eukaryotes. Self-perpetuating, clonally inherited chromatin structure has been proposed as the explanation for such phenomena as position-effect variegation (PEV) and control of segment determination and differentiation in flies, X-chromosome inactivation and parental imprinting in mammals, gene silencing by paramutation in maize and silencing of the mating-type loci in yeasts. We have now found that the clr4 gene, which is essential for silencing of centromeres and the mating-type loci in Schizosaccharomyces pombe, encodes a protein with high homology to the product of Su(var)3-9, a gene affecting PEV in Drosophila. Like Su(var)3-9p, Clr4p contains SET and chromo domains, motifs found in proteins that modulate chromatin structure. Site-directed mutations in the conserved residues of the chromo domain confirm that it is required for proper silencing and directional switching of the mating type, like SET domain. Surprisingly, RNA differential display experiments demonstrated that clr4+ can mediate transcriptional activation of certain other loci. These results show that clr4 plays a critical role in silencing at mating-type loci and centromeres through the organization of repressive chromatin structure and demonstrate a new, activator function for Clr4p.

Multiple epigenetic events regulate mating-type switching of fission yeast

Two epigenetic events at mat1, one of which is DNA strand specific, are required to initiate recombination during mating-type switching. The third, a chromosomally borne imprinted event at the mat2/3 interval regulates silencing and directionality of switching, and prohibits interchromosomal recombination. We speculate that the unit of inheritance in the mat2/3 interval is both DNA plus its associated chromatin structure. Such a control is likely to be essential in maintaining particular states of gene expression during development.

The Drosophila Fab-7 chromosomal element conveys epigenetic inheritance during mitosis and meiosis

Polycomb group (PcG) and trithorax group (trxG) gene products are responsible for the maintenance of repressed and active expression patterns of many developmentally important regulatory genes including the homeotic genes. In Drosophila embryos, Polycomb protein and the trxG protein GAGA factor colocalize at the Fab-7 DNA element of the bithorax complex. In transgenic lines, the Fab-7 element induces extensive silencing on a flanking GAL4-driven lacZ reporter and mini-white genes. However, a short single pulse of GAL4 during embryogenesis is sufficient to release PcG-dependent silencing from the transgene. Such an activated state of Fab-7 is mitotically inheritable through development and can be transmitted in a GAL4-independent manner to the subsequent generations through female meiosis. Thus, Fab-7 is a switchable chromosomal element, which can convey memory of epigenetically determined active and repressed chromatin states.

white+ transgene insertions presenting a dorsal/ventral pattern define a single cluster of homeobox genes that is silenced by the polycomb-group proteins in Drosophila melanogaster

We used the white gene as an enhancer trap and reporter of chromatin structure. We collected white+ transgene insertions presenting a peculiar pigmentation pattern in the eye: white expression is restricted to the dorsal half of the eye, with a clear-cut dorsal/ventral (D/V) border. This D/V pattern is stable and heritable, indicating that phenotypic expression of the white reporter reflects positional information in the developing eye. Localization of these transgenes led us to identify a unique genomic region encompassing 140 kb in 69D1-3 subject to this D/V effect. This region contains at least three closely related homeobox-containing genes that are constituents of the iroquois complex (IRO-C). IRO-C genes are coordinately regulated and implicated in similar developmental processes. Expression of these genes in the eye is regulated by the products of the Polycomb-group (Pc-G) and trithorax-group (trx-G) genes but is not modified by classical modifiers of position-effect variegation. Our results, together with the report of a Pc-G binding site in 69D, suggest that we have identified a novel cluster of target genes for the Pc-G and trx-G products. We thus propose that ventral silencing of the whole IRO-C in the eye occurs at the level of chromatin structure in a manner similar to that of the homeotic gene complexes, perhaps by local compaction of the region into a heterochromatin-like structure involving the Pc-G products.

SET1, a yeast member of the trithorax family, functions in transcriptional silencing and diverse cellular processes

The trithorax gene family contains members implicated in the control of transcription, development, chromosome structure, and human leukemia. A feature shared by some family members, and by other proteins that function in chromatin-mediated transcriptional regulation, is the presence of a 130- to 140-amino acid motif dubbed the SET or Tromo domain. Here we present analysis of SET1, a yeast member of the trithorax gene family that was identified by sequence inspection to encode a 1080-amino acid protein with a C-terminal SET domain. In addition to its SET domain, which is 40-50% identical to those previously characterized, SET1 also shares dispersed but significant similarity to Drosophila and human trithorax homologues. To understand SET1 function(s), we created a null mutant. Mutant strains, although viable, are defective in transcriptional silencing of the silent mating-type loci and telomeres. The telomeric silencing defect is rescued not only by full-length episomal SET1 but also by the conserved SET domain of SET1. set1 mutant strains display other phenotypes including morphological abnormalities, stationary phase defects, and growth and sporulation defects. Candidate genes that may interact with SET1 include those with functions in transcription, growth, and cell cycle control. These data suggest that yeast SET1, like its SET domain counterparts in other organisms, functions in diverse biological processes including transcription and chromatin structure.

Locus control regions: overcoming heterochromatin-induced gene inactivation in mammals

Differentiation of specific cell types during the development of mammals requires the selective silencing or activation of tissue-specific genes. Locus control regions (LCRs) are gene regulatory elements that act in cis to ensure that active transcriptional units are established in all cells of a given cell lineage. Over the past year, it has become clear that this process takes place at the level of chromatin remodelling, and that LCRs ensure that this decision is made by both alleles in every cell. Studies on LCRs and analysis of gene expression in transgenic mice at the single cell level has revealed that the breakdown in LCR function accompanying the deletion of specific sequences results in a phenomenon known as position effect variegation, described in detail in yeast and Drosophila. Thus, when located in close proximity to heterochromatin a transgene linked to a disabled LCR is randomly silenced in a proportion of cells. This finding implies that all subregions within an LCR are necessary to ensure the establishment of an open chromatin configuration of a gene even when the latter is located in a highly heterochromatic region.

Self-association of chromo domain peptides

The chromo domain is a sequence motif first recognised in the Drosophila polycomb protein and heterochromatin protein (HP1), two proteins associated with stable and heritable transcriptional silencing. Polycomb is one of a number of genes that are required to prevent ectopic homeotic gene expression in Drosophila, while HP1, the product of the Drosophila melanogaster Su(var)205 gene, is associated with the phenomenon of position effect variegation. These proteins are believed to be components of chromatin-associated multi-protein complexes that bring about stable transcriptional silencing and the chromo domain has been implicated in chromatin targeting, probably through protein-protein interaction. Recently, mammalian homologues of both polycomb and HP1 have been described. Here we demonstrate for the first time that oligopeptides containing a chromo domain derived from the mouse polycomb homologue M33 form multimeric complexes in solution, supporting the role of the chromo domain in multiprotein complex assembly.