Dividing the empire: boundary chromatin elements delimit the territory of enhancers

Transposable element-derived sequences in vertebrate development

Transposable elements (TEs) are major components of all vertebrate genomes that can cause deleterious insertions and genomic instability. However, depending on the specific genomic context of their insertion site, TE sequences can sometimes get positively selected, leading to what are called "exaptation" events. TE sequence exaptation constitutes an important source of novelties for gene, genome and organism evolution, giving rise to new regulatory sequences, protein-coding exons/genes and non-coding RNAs, which can play various roles beneficial to the host. In this review, we focus on the development of vertebrates, which present many derived traits such as bones, adaptive immunity and a complex brain. We illustrate how TE-derived sequences have given rise to developmental innovations in vertebrates and how they thereby contributed to the evolutionary success of this lineage.

Mechanism of chromosomal boundary action: roadblock, sink, or loop?

Boundary elements or insulators subdivide eukaryotic chromosomes into a series of structurally and functionally autonomous domains. They ensure that the action of enhancers and silencers is restricted to the domain in which these regulatory elements reside. Three models, the roadblock, sink/decoy, and topological loop, have been proposed to explain the insulating activity of boundary elements. Strong predictions about how boundaries will function in different experimental contexts can be drawn from these models. In the studies reported here, we have designed assays that test these predictions. The results of our assays are inconsistent with the expectations of the roadblock and sink models. Instead, they support the topological loop model.

Drosophila mini-white model system: new insights into positive position effects and the role of transcriptional terminators and gypsy insulator in transgene shielding

The white gene, which is responsible for eye pigmentation, is widely used to study position effects in Drosophila. As a result of insertion of P-element vectors containing mini-white without enhancers into random chromosomal sites, flies with different eye color phenotypes appear, which is usually explained by the influence of positive/negative regulatory elements located around the insertion site. We found that, in more than 70% of cases when mini-white expression was subject to positive position effects, deletion of the white promoter had no effect on eye pigmentation; in these cases, the transposon was inserted into the transcribed regions of genes. Therefore, transcription through the mini-white gene could be responsible for high levels of its expression in most of chromosomal sites. Consistently with this conclusion, transcriptional terminators proved to be efficient in protecting mini-white expression from positive position effects. On the other hand, the best characterized Drosophila gypsy insulator was poorly effective in terminating transcription and, as a consequence, only partially protected mini-white expression from these effects. Thus, to ensure maximum protection of a transgene from position effects, a perfect boundary/insulator element should combine three activities: to block enhancers, to provide a barrier between active and repressed chromatin, and to terminate transcription.

Interbands behave as decompacted autonomous units in Drosophila melanogaster polytene chromosomes

We studied whether interbands can be ectopically formed in Drosophila melanogaster polytene chromosomes. For comparative purposes, two types of P-element constructs were used. The first type was represented by P-element based insertions into compact bands. Sequences of these insertions or adjacent genomic sequences could be activated ectopically either by GAL4 or by dosage compensation machinery. In the second type, the DNA from transcriptionally silent interbands was positioned between the FRT sites, and was flanked by DNA sequences of genes that were also inactive in salivary glands. Electron microscopy analysis of salivary gland polytene chromosomes demonstrated that both types of constructs formed distinct, yet morphologically similar interbands. Notably, the second class of transposon insertions appeared in polytene chromosomes as two bands separated by one interband. Excision of interband material from such insertions resulted in fusion of newly appeared bands into a single band. We were able to confirm by molecular means that the DNA sequences in integrated constructs were intact, that chromatin organization of this DNA mimicked that of native interbands, and that it was accurately excised from the constructs by FLP. Thus, we demonstrate that transfer of interband DNA into a silent genetic environment does not compromise interband formation. Our results do not support the idea of the existence of distinct cytogenetic "band + interband" units, furthermore, they suggest the autonomy of the decompacted state of interbands.

Mechanism and control of V(D)J recombination versus class switch recombination: similarities and differences

V(D)J recombination is the process by which the variable region exons encoding the antigen recognition sites of receptors expressed on B and T lymphocytes are generated during early development via somatic assembly of component gene segments. In response to antigen, somatic hypermutation (SHM) and class switch recombination (CSR) induce further modifications of immunoglobulin genes in B cells. CSR changes the IgH constant region for an alternate set that confers distinct antibody effector functions. SHM introduces mutations, at a high rate, into variable region exons, ultimately allowing affinity maturation. All of these genomic alteration processes require tight regulatory control mechanisms, both to ensure development of a normal immune system and to prevent potentially oncogenic processes, such as translocations, caused by errors in the recombination/mutation processes. In this regard, transcription of substrate sequences plays a significant role in target specificity, and transcription is mechanistically coupled to CSR and SHM. However, there are many mechanistic differences in these reactions. V(D)J recombination proceeds via precise DNA cleavage initiated by the RAG proteins at short conserved signal sequences, whereas CSR and SHM are initiated over large target regions via activation-induced cytidine deaminase (AID)-mediated DNA deamination of transcribed target DNA. Yet, new evidence suggests that AID cofactors may help provide an additional layer of specificity for both SHM and CSR. Whereas repair of RAG-induced double-strand breaks (DSBs) involves the general nonhomologous end-joining DNA repair pathway, and CSR also depends on at least some of these factors, CSR requires induction of certain general DSB response factors, whereas V(D)J recombination does not. In this review, we compare and contrast V(D)J recombination and CSR, with particular emphasis on the role of the initiating enzymes and DNA repair proteins in these processes.

Pairing between gypsy insulators facilitates the enhancer action in trans throughout the Drosophila genome

The Suppressor of the Hairy wing [Su(Hw)] binding region within the gypsy retrotransposon is the best known chromatin insulator in Drosophila melanogaster. According to previous data, two copies of the gypsy insulator inserted between an enhancer and a promoter neutralize each other's actions, which is indicative of an interaction between the protein complexes bound to the insulators. We have investigated the role of pairing between the gypsy insulators located on homologous chromosomes in trans interaction between yellow enhancers and a promoter. It has been shown that trans activation of the yellow promoter strongly depends on the site of the transposon insertion, which is evidence for a role of surrounding chromatin in homologous pairing. The presence of the gypsy insulators in both homologous chromosomes even at a distance of 9 kb downstream from the promoter dramatically improves the trans activation of yellow. Moreover, the gypsy insulators have proved to stabilize trans activation between distantly located enhancers and a promoter. These data suggest that gypsy insulator pairing is involved in communication between loci in the Drosophila genome.

Transcriptional interference mediated by retrotransposons within the genome of their host: lessons from alleles of the white gene from Drosophila melanogaster

Systematic sequencing of model genomes has accelerated our knowledge on genome structure and shown that a large proportion of intergenic regions are made up of mobile element families. Among them, retrotransposons that are mobilized via an RNA intermediate and thus do not excise during their replication cycle are certainly essential factors able to imprint novel and heritable transcriptional regulation within the genome of their host. Today, a crucial complement to the systematic sequencing data is thus to elucidate the potential role of these elements in the regulation of nearby genes, and ultimately in the evolution of eukaryotic genomes.

Transforming growth factor-beta : biology and clinical relevance

Transforming growth factor-beta is a pleiotropic growth factor that has enthralled many investigators for approximately two decades. In addition to many reports that have clarified the basic mechanism of transforming growth factor-beta signal transduction, numerous laboratories have published on the clinical implication/application of transforming growth factor-beta . To name a few, dysregulation of transforming growth factor-beta signaling plays a role in carcinogenesis, autoimmunity, angiogenesis, and wound healing. In this report, we will review these clinical implications of transforming growth factor-beta .

The Mcp element from the bithorax complex contains an insulator that is capable of pairwise interactions and can facilitate enhancer-promoter communication

Chromatin insulators, or boundary elements, appear to control eukaryotic gene expression by regulating interactions between enhancers and promoters. Boundaries have been identified in the 3' cis-regulatory region of Abd-B, which is subdivided into a series of separate iab domains. Boundary elements such as Mcp, Fab-7, and Fab-8 and adjacent silencers flank the iab domains and restrict the activity of the iab enhancers. We have identified an insulator in the 755-bp Mcp fragment that is linked to the previously characterized Polycomb response element (PRE) and silences the adjacent genes. This insulator blocks the enhancers of the yellow and white genes and protects them from PRE-mediated repression. The interaction between the Mcp elements, each containing the insulator and PRE, allows the eye enhancer to activate the white promoter over the repressed yellow domain. The same level of white activation was observed when the Mcp element combined with the insulator alone was interposed between the eye enhancer and the promoter, suggesting that the insulator is responsible for the interaction between the Mcp elements.

Formation of a large, complex domain of histone hyperacetylation at human 14q32.1 requires the serpin locus control region

The human serine protease inhibitor (serpin) gene cluster at 14q32.1 is a useful model system to study cell-type-specific gene expression and chromatin structure. Activation of the serpin locus can be induced in vitro by transferring human chromosome 14 from non-expressing to expressing cells. Serpin gene activation in expressing cells is correlated with locus-wide alterations in chromatin structure, including the de novo formation of 17 expression-associated DNase I-hypersensitive sites (DHSs). In this study, we investigated histone acetylation throughout the proximal serpin subcluster. We report that gene activation is correlated with high levels of histone H3 and H4 acetylation at serpin gene promoters and other regulatory regions. However, the locus is not uniformly hyperacetylated, as there are regions of hypoacetylation between genes. Furthermore, genetic tests indicate that locus-wide controls regulate both gene expression and chromatin structure. For example, deletion of a previously identified serpin locus control region (LCR) upstream of the proximal subcluster reduces both gene expression and histone acetylation throughout the ∼130 kb region. A similar down regulation phenotype is displayed by transactivator-deficient cell variants, but this phenotype can be rescued by transfecting the cells with expression cassettes encoding hepatocyte nuclear factor-1α (HNF-1α) or HNF-4. Taken together, these results suggest that histone acetylation depends on interactions between the HNF-1α/HNF-4 signaling cascade and the serpin LCR.

The enhancer-blocking activity of the Fab-7 boundary from the Drosophila bithorax complex requires GAGA-factor-binding sites

In the work reported here we have analyzed the role of the GAGA factor [encoded by the Trithorax-like (Trl) gene] in the enhancer-blocking activity of Frontabdominal-7 (Fab-7), a domain boundary element from the Drosophila melanogaster bithorax complex (BX-C). One of the three nuclease hypersensitive sites in the Fab-7 boundary, HS1, contains multiple consensus-binding sequences for the GAGA factor, a protein known to be involved in the formation and/or maintenance of nucleosome-free regions of chromatin. GAGA protein has been shown to localize to the Fab-7 boundary in vivo, and we show that it recognizes sequences from HS1 in vitro. Using two different transgene assays we demonstrate that GAGA-factor-binding sites are necessary but not sufficient for full Fab-7 enhancer-blocking activity. We show that distinct GAGA sites are required for different enhancer-blocking activities at different stages of development. We also show that the enhancer-blocking activity of the endogenous Fab-7 boundary is sensitive to mutations in the gene encoding the GAGA factor Trithorax-like.

Regulated chromatin domain comprising cluster of co-expressed genes in Drosophila melanogaster

Recently, the phenomenon of clustering of co-expressed genes on chromosomes was discovered in eukaryotes. To explore the hypothesis that genes within clusters occupy shared chromatin domains, we performed a detailed analysis of transcription pattern and chromatin structure of a cluster of co-expressed genes. We found that five non-homologous genes (Crtp, Yu, CK2betates, Pros28.1B and CG13581) are expressed exclusively in Drosophila melanogaster male germ-line and form a non-interrupted cluster in the 15 kb region of chromosome 2. The cluster is surrounded by genes with broader transcription patterns. Analysis of DNase I sensitivity revealed 'open' chromatin conformation in the cluster and adjacent regions in the male germ-line cells, where all studied genes are transcribed. In contrast, in somatic tissues where the cluster genes are silent, the domain of repressed chromatin encompassed four out of five cluster genes and an adjacent non-cluster gene CG13589 that is also silent in analyzed somatic tissues. The fifth cluster gene (CG13581) appears to be excluded from the chromatin domain occupied by the other four genes. Our results suggest that extensive clustering of co-expressed genes in eukaryotic genomes does in general reflect the domain organization of chromatin, although domain borders may not exactly correspond to the margins of gene clusters.

Drosophila Su(Hw) insulator can stimulate transcription of a weakened yellow promoter over a distance

The insulator element from the gypsy transposon is a DNA sequence that blocks activation of a promoter by a transcriptional enhancer when placed between them. The insulator contains reiterated binding sites for the Suppressor of Hairy-wing [Su(Hw)] zinc-finger protein. A protein encoded by another gene, modifier of mdg4 [mod(mdg4)], is also required for the enhancer-blocking activity of the Su(Hw) insulator. Here we present evidence that the Su(Hw) insulator activates a weakened yellow promoter at a distance. Deletion of the upstream promoter region (UPR), located close by the TATA box, significantly reduces yellow expression. The Su(Hw) insulator placed at different positions relative to the yellow promoter partially compensates for loss of the UPR. Su(Hw) is able to stimulate yellow expression even if it is located at a 5-kb distance from the promoter. The stimulatory activity depends on the number of Su(Hw)-binding sites. Mutational analysis demonstrates that only the DNA-binding domain and adjacent regions of the Su(Hw) protein are required for stimulation of yellow transcription.

Developmental modulation of Fab-7 boundary function

The Fab-7 boundary functions to ensure the autonomous activity of the iab-6 and iab-7 cis-regulatory domains in the Drosophila Bithorax Complex from early embryogenesis through to the adult stage. Although Fab-7 is required only for the proper development of a single posterior parasegment, it is active in all tissues and stages of development that have been examined. In this respect, Fab-7 resembles conventional constitutive boundaries in flies and other eukaryotes that act through ubiquitous cis-elements and trans-acting factors. Surprisingly, however, we find that the constitutive activity of Fab-7 is generated by combining sub-elements with developmentally restricted boundary function. We provide in vivo evidence that the Fab-7 boundary contains separable regions that function at different stages of development. These findings suggest that the units (domains) of genetic regulation that boundaries delimit can expand or contract by switching insulator function off or on in a temporally regulated fashion.

Heritable transgene expression pattern imposed onto maize ubiquitin promoter by maize adh-1 matrix attachment regions: tissue and developmental specificity in maize transgenic plants

Matrix attachment regions (MARs) have been used to enhance transgene expression and to reduce transgene expression instability in various organisms. In plants, contradictory data question the role of MAR sequences. To assess the use of MAR sequences in maize, we have used two well-characterized MARs from the maize adh-1 region. The MARs have been cloned either 5' to or at both sides of a reporter gene expression cassette to reconstitute a MAR-based domain. Histochemical staining revealed a new transgene expression pattern in roots of regenerated plants and their progeny. Furthermore, MARs systematically induced variegation. We show here that maize adh-1 MARs are able to modify transgene expression patterns as a heritable trait, giving a new and complementary outcome following use of MARs in genetic transformation.

Genomic Imprinting: CTCF Protects the Boundaries

The DNA-binding protein CTCF, which acts as a chromatin 'insulator', regulates imprinting of the mammalian Igf2 and H19 genes in a methylation-sensitive manner. It has now been shown that CTCF is also required for protection against de novo methylation of the differentially methylated domain of H19 in the female germline.

Putative FLJ20436 gene characterisation in goat. Observed ubiquitous expression in goat and transgenic mice allowed to restrict the location of an hypothesised insulator element

Eukaryotic genomes are organised into independent domains through the establishment of boundaries which allow to have distinct pattern of gene expression both during development and in differentiated cells. The previously reported site independent expression of the mammary-specific goat alpha-lactalbumin gene in transgenic mice suggested the existence of cis-regulatory elements located upstream of this gene. The nearby presence of a second ubiquitously expressed gene (the cyclin T1 gene) allowed to define two chromatin domains putatively separated by a boundary insulator-like element. In this study, the characterisation of a third putative gene (FLJ20436) present between the alpha-lactalbumin and the cyclin T1 loci is reported. It was found to be a functional gene, ubiquitously expressed both in goat and transgenic mice. A complex pattern of alternative splicing events was observed in several analysed tissues leading to various mRNAs and putative FLJ20436 proteins, as suggested in human and mouse species. This allowed us to assign this gene to one of the two hypothesised chromatin domains, refining the location of the potential insulator element.

Proteomics and regulomics: the yin and yang of functional genomics

Protein analysis is a field of research with a long history. Recently, the development of a series of proteomics approaches, i.e., simultaneous analyses on all or a majority of proteins in a cell at a given state, has reinvigorated protein analyses. Mass Spectrometry also developed into one of the most versatile technical tools supporting or even enabling many proteomics-oriented approaches, providing a convenient link between experimental protein analysis and the corresponding amino acid sequences. Thus direct links to the genomic sequence can be established, which opens the door for a synergistic combination with genomic sequence analysis. This review focuses especially on aspects of genome-wide transcription control, regulomics in analogy to all the other -omics, and how a combination of MS-based proteomics with in silico regulomics analyses can produce synergistic effects in the quest to understand how cells function. This is illustrated on a real life example showing how the MS-analysis and in silico promoter analysis can extend the list of candidates for signaling pathways, here the MAP kinase pathway.

The eukaryotic genome: a system regulated at different hierarchical levels

Eukaryotic gene expression can be viewed within a conceptual framework in which regulatory mechanisms are integrated at three hierarchical levels. The first is the sequence level, i.e. the linear organization of transcription units and regulatory sequences. Here, developmentally co-regulated genes seem to be organized in clusters in the genome, which constitute individual functional units. The second is the chromatin level, which allows switching between different functional states. Switching between a state that suppresses transcription and one that is permissive for gene activity probably occurs at the level of the gene cluster, involving changes in chromatin structure that are controlled by the interplay between histone modification, DNA methylation, and a variety of repressive and activating mechanisms. This regulatory level is combined with control mechanisms that switch individual genes in the cluster on and off, depending on the properties of the promoter. The third level is the nuclear level, which includes the dynamic 3D spatial organization of the genome inside the cell nucleus. The nucleus is structurally and functionally compartmentalized and epigenetic regulation of gene expression may involve repositioning of loci in the nucleus through changes in large-scale chromatin structure.

The presence of a chromatin boundary appears to shield a transgene in tobacco from RNA silencing

We present isogenic transgenic tobacco lines that carry at a given chromosomal position a beta-glucuronidase (GUS) reporter gene either with or without the presence of the matrix-associated region known as the chicken lysozyme A element. Plants were generated with the Cre-lox site-specific recombination system using heterospecific lox sites. Analysis of GUS gene expression in plant populations demonstrates that the presence of the A element can shield against RNA silencing of the GUS gene. Protection was observed in two of three independent tobacco transformants. Plants carrying an A element 5' of the GUS gene always had stable GUS activity, but upon removal of this A element, the GUS gene became silenced over time in two lines, notably when homozygous.

In vitro and in vivo effects of a multimerized alphas 1-casein enhancer on whey acidic protein gene promoter activity

Experimental data obtained in previous works have led to postulate that enhancers increase the frequency of action of a linked promoter in a given cell and may have some insulating effects. The multimerized rabbit alpha s1-casein gene enhancer, the 6i multimer, was added upstream of the rabbit whey acidic protein gene (WAP) promoter (-6,300; +28 bp) fused to the firefly luciferase (luc) gene (6i WAP-luc construct). The 6i multimer increased reporter gene expression in mouse mammary HC11 cells. In transgenic mice, a very weak but significant increase was also observed. More noticeable, no silent lines were found when the 6i multimer was associated to the WAP-luc construct. This reflects the fact that the 6i multimer tends to prevent the silencing of the WAP-luc construct. After addition of the 5'HS4 insulator region from the chicken beta-globin locus upstream of the 6i multimer, similar luciferase levels were measured in 6i WAP-luc and 5'HS4 WAP-luc transgenic mice. Our present data and previous ones, which show that the 6i multimer has no insulating activity on a TK gene promoter construct indicate that the insulating activity of the 6i multimer is construct-dependent and not amplified by the 5'HS4 insulator.

A survey of the DNA sequences surrounding the Bari1 repeats in the pericentromeric h39 region of Drosophila melanogaster

In Drosophila melanogaster, clustered copies of the Bari1 transposon are only present in the pericentromeric h39 region of the second chromosome, where other clusters of repetitive elements, either found organized in large tandem arrays only in the h39 region (Responder, PortoI), or both in the h39 region and in other heterochromatic regions (Hoppel), are also observed. The topological relationship among the repetitive sequences of the h39 region and the nature of the sequences separating its large repeat clusters are at present largely unknown. To get new insights on the sequence composition of the heterochromatin and on the forces governing its origin and maintenance, we have cloned and analyzed part of the DNA sequences flanking the h39 Bari1 repeats. In a region spanning 3 and 9 kb, respectively, from the ends of a Bari1 array we found only single copies of the PortoI and Hoppel transposable elements, and five copies of a variant form of the Responder repeats. No large tandem arrays of any repeated element were present. In addition, a highly conserved 596 bp sequence, that may have a functional role, is present on both sides of the Bari1 repeats. We suggest that the current organization of the h39 heterochromatin implies some topological or functional constraint that prevents the formation of further arrays of repetitive elements in the region.

Stability of protein production from recombinant mammalian cells

One of the most important criteria for successful generation of a therapeutic protein from a recombinant cell is to obtain a cell line that maintains stability of production. If this is not achieved it can generate problems for process yields, effective use of time and money, and for regulatory approval of products. However, selection of a cell line that sustains stability of production over the required time period may be difficult to achieve during development of a therapeutic protein. There are several studies in the literature that have reported on the instability of protein production from recombinant cell lines. The causes of instability of production are varied and, in many cases, the exact molecular mechanisms are unknown. The production of proteins by cells is modulated by molecular events at levels ranging from transcription, posttranscriptional processing, translation, posttranslational processing, to secretion. There is potential for regulation of stability of protein production at many or all of these stages. In this study we review published information on stability of protein production for three industrially important cell lines: hybridoma, Chinese hamster ovary (CHO), and nonsecreting (NS0) myeloma cell lines. We highlight the most likely molecular loci at which instability may be engendered and indicate other areas of protein production that may affect stability from mammalian cells. We also outline approaches that could help to overcome the problems associated with unpredictable expression levels and maximized production, and indicate the consequences these might have for stability of production.

Protein:protein interactions and the pairing of boundary elements in vivo

Although it is now well-established that boundary elements/insulators function to subdivide eukaryotic chromosomes into autonomous regulatory domains, the underlying mechanisms remain elusive. One idea is that boundaries act as barriers, preventing the processive spreading of "active" or "silenced" chromatin between domains. Another is that the partitioning into autonomous functional units is a consequence of an underlying structural subdivision of the chromosome into higher order "looped" domains. In this view, boundaries are thought to delimit structural domains by interacting with each other or with some other nuclear structure. The studies reported here provide support for the looped domain model. We show that the Drosophila scs and scs' boundary proteins, Zw5 and BEAF, respectively, interact with each other in vitro and in vivo. Moreover, consistent with idea that this protein:protein interaction might facilitate pairing of boundary elements, we find that that scs and scs' are in close proximity to each other in Drosophila nuclei.

Rap1p and other transcriptional regulators can function in defining distinct domains of gene expression

Barrier elements that are able to block the propagation of transcriptional silencing in yeast are functionally similar to chromatin boundary/insulator elements in metazoans that delimit functional chromosomal domains. We show that the upstream activating sequences of many highly expressed ribosome protein genes and glycolytic genes exhibit barrier activity. Analyses of these barriers indicate that binding sites for transcriptional regulators Rap1p, Abf1p, Reb1p, Adr1p and Gcn4p may participate in barrier function. We also present evidence suggesting that Rap1p is directly involved in barrier activity, and its barrier function correlates with local changes in chromatin structure. We further demonstrate that tethering the transcriptional activation domain of Rap1p to DNA is sufficient to recapitulate barrier activity. Moreover, targeting the activation domain of Adr1p or Gcn4p also establishes a barrier to silencing. These results support the notion that transcriptional regulators could also participate in delimiting functional domains in the genome.

Analysis of the flanking regions of the human alpha-lactalbumin gene responsible for position-effect independent expression

Transgenic rats with the 130 kb bacterial artificial chromosome construct bLA, including the alpha-lactalbumin gene, had position-independent and copy number-dependent expression, which confirmed previous experiments using the 210 kb yeast artificial construct, yLALBA. To identify elements that confer a position effect, we compared the yLALBA and bLA sequences. yLALBA was chimeric. A common 32 kb region was identified and the total nucleotide sequence was determined. We previously analyzed transgenic rats using polymerase chain reaction to compare the integrity and expression of the transgenes. The -6 to +9 kb region is considered to be necessary for position-independent expression. Transgenic rats lacking the -3.4 to -0.85 kb region had a severe position effect. This 2.5 kb region contains two DNaseI hypersensitive sites at -1.0 and -2.8 kb. The 2.5 kb region is proposed to be a locus control region of the human alpha-lactalbumin gene.

SMC protein complexes and the maintenance of chromosome integrity

Structural maintenance of chromosomes (SMC) family proteins have attracted much attention for their unique protein structure and critical roles in mitotic chromosome organization. Elegant genetic and biochemical studies in yeast and Xenopus identified two different SMC heterodimers in two conserved multiprotein complexes termed 'condensin' and 'cohesin'. These complexes are required for mitotic chromosome condensation and sister chromatid cohesion, respectively, both of which are prerequisite to accurate segregation of chromosomes. Although structurally similar, the SMC proteins in condensin and cohesin appear to have distinct functions, whose specificity and cell cycle regulation are critically determined by their interactions with unique sets of associated proteins. Recent studies of subcellular localization of SMC proteins and SMC-containing complexes, identification of their interactions with other cellular factors, and discovery of new SMC family members have uncovered unexpected roles for SMC proteins and SMC-containing complexes in different aspects of genome functions and chromosome organization beyond mitosis, all of which are critical for the maintenance of chromosome integrity.

Identification of distal regulatory regions in the human alpha IIb gene locus necessary for consistent, high-level megakaryocyte expression

The alphaIIb/beta3-integrin receptor is present at high levels only in megakaryocytes and platelets. Its presence on platelets is critical for hemostasis. The tissue-specific nature of this receptor's expression is secondary to the restricted expression of alphaIIb, and studies of the alphaIIb proximal promoter have served as a model of a megakaryocyte-specific promoter. We have examined the alphaIIb gene locus for distal regulatory elements. Sequence comparison between the human (h) and murine (m) alphaIIb loci revealed high levels of conservation at intergenic regions both 5' and 3' to the alphaIIb gene. Additionally, deoxyribonuclease (DNase) I sensitivity mapping defined tissue-specific hypersensitive (HS) sites that coincide, in part, with these conserved regions. Transgenic mice containing various lengths of the h(alpha)IIb gene locus, which included or excluded the various conserved/HS regions, demonstrated that the proximal promoter was sufficient for tissue specificity, but that a region 2.5 to 7.1 kb upstream of the h(alpha)IIb gene was necessary for consistent expression. Another region 2.2 to 7.4 kb downstream of the gene enhanced expression 1000-fold and led to levels of h(alpha)IIb mRNA that were about 30% of the native m(alpha)IIb mRNA level. These constructs also resulted in detectable h(alpha)IIb/m(beta)3 on the platelet surface. This work not only confirms the importance of the proximal promoter of the alphaIIb gene for tissue specificity, but also characterizes the distal organization of the alphaIIb gene locus and provides an initial localization of 2 important regulatory regions needed for the expression of the alphaIIb gene at high levels during megakaryopoiesis.

Insulators prevent transcriptional interference between two promoters in a double gene construct for transgenesis

In transgenesis, the expression of two transgenes is often subject to mutual interference by each of the two expression cassettes when they are driven by different transcriptional regulatory elements in a single construct. To study this problem, we constructed vectors consisting of two expression units, one contains a strong ubiquitous promoter and the other contains a tissue-specific transcriptional element. The expression pattern of each transgene was examined in transfected cell lines and also in transgenic mice. In both cases, two expression units in a single construct were expressed in an independent manner and were controlled by their respective regulatory element only if we placed insulators at both ends of one expression unit. These results indicate that usage of insulators is a valuable tool for transfection of double gene constructs in transgenesis.

Evidence that DNase I hypersensitive site 5 of the human beta-globin locus control region functions as a chromosomal insulator in transgenic mice

We have previously reported that DNase I hypersensitive site 5 (5'HS5) of the human beta-globin locus control region functions as a chromatin insulator in stable transfection assays. In this report we show that a 3.2 kb DNA fragment containing the entire 5'HS5 region can protect a position-sensitive (A)gamma-globin gene against position effects in transgenic mice. Bracketing is required for function of 5'HS5 as an insulator. The 5'HS5 insulator operates in adult as well as in embryonic murine erythroid cells. The insulator has no significant stimulatory effects of its own. These results indicate that 5'HS5 can function as a chromatin insulator in vivo.

Topological constraints governing the use of the chicken HS4 chromatin insulator in oncoretrovirus vectors

The expression of integrated oncoretrovirus vectors is subject to the inhibitory effects of surrounding chromatin. A previous report from our laboratory indicated that such position effects can be overcome by flanking a reporter vector with the cHS4 chromatin insulator. To characterize this activity more thoroughly, we switched the promoter-gene combinations in the reporter vector and analyzed expression of these vectors flanked with the cHS4 fragment in both orientations following bone marrow transduction and transplantation in mice. The results indicate that the cHS4 fragment can function in both orientations and can insulate both the virus long-terminal-repeat (LTR) promoter and an internal phosphoglycerate kinase (Pgk) promoter. However, insulation of the LTR promoter diminished when the orientation of the cHS4 fragment placed the CTCF-binding core element immediately proximal to the U3 region, suggesting a minimal distance requirement. Moreover, placement of the cHS4 fragment in the U3 region of the 3' LTR dramatically decreased the level of expression from an internal Pgk promoter, presumably by blocking interaction with the 3' LTR enhancer. Finally, sorting studies suggest that the severity of position effects or autonomous promoter silencing increases as transduced progenitors differentiate into mature progeny. These findings have direct implications for the use of chromatin insulators such as cHS4 in oncoretrovirus vectors.

Hematopoietic stem cell gene therapy

Gene therapy applications that target hematopoietic stem cells (HSCs) offer great potential for the treatment of hematologic disease. Despite this promise, clinical success has been limited by poor rates of gene transfer, poor engraftment of modified cells, and poor levels of gene expression. We describe here the basic approach used for HSC gene therapy, briefly review some of the seminal clinical trials in the field, and describe several recent advances directed toward overcoming these limitations.

The gypsy insulators flanking yellow enhancers do not form a separate transcriptional domain in Drosophila melanogaster: the enhancers can activate an isolated yellow promoter

The best-characterized insulator in Drosophila melanogaster is the Su(Hw)-binding region contained within the gypsy retrotransposon. In the y(2) mutant, Su(Hw) protein partially inhibits yellow transcription by blocking the function of transcriptional enhancers located distally from the yellow promoter with respect to gypsy. Previously we have shown that yellow enhancers can overcome inhibition by a downstream insulator in the y(rh1) allele, when a second gypsy element is located upstream of the enhancers. To understand how two insulators neutralize each other, we isolated various deletions that terminate in the regulatory region of the y(rh1) allele. To generate these alleles we used DNA elongation by gene conversion of the truncated chromosomes at the end of the yellow regulatory region. We found that gypsy insulator can function at the end of the truncated chromosome. Addition of the gypsy insulator upstream of the yellow enhancers overcomes the enhancer-blocking activity of the gypsy insulator inserted between the yellow enhancers and promoter. These results suggest that the gypsy insulators do not form separate transcriptional domains that delimit the interactions between enhancers and promoters.

Coupling of enhancer and insulator properties identified in two retrotransposons modulates their mutagenic impact on nearby genes

We recently reported a novel transposition system in which two retroelements from Drosophila melanogaster, ZAM and Idefix, are highly mobilized and preferentially insert within intergenic regions. Among the loci where new copies are detected, a hot spot for their insertion was identified at the white locus, where up to three elements occurred within a 3-kb fragment upstream of the transcriptional start site of white. We have used these insertions as molecular entry points to throw light on the mutagenic effect exerted by multiple insertions of retrotransposons within intergenic regions of a genome. Analysis of the molecular mechanisms by which ZAM and Idefix elements interfere with the regulation of the white gene has shown that ZAM bears cis-acting regulatory sequences able to enhance transcription of the white gene in the eyes of the flies. This activation may be counteracted by Idefix, which acts as an insulator able to isolate the white gene from the upstream ZAM enhancer. In addition to revealing a novel insulator sequence with its own specific features, our data clearly illustrate how retroelements can act as epigenetic factors able to interfere with the transcriptional regulation of their host.

A potential role for human cohesin in mitotic spindle aster assembly

The cohesin multiprotein complex containing SMC1, SMC3, Scc3 (SA), and Scc1 (Rad21) is required for sister chromatid cohesion in eukaryotes. Although metazoan cohesin associates with chromosomes and was shown to function in the establishment of sister chromatid cohesion during interphase, the majority of cohesin was found to be off chromosomes and reside in the cytoplasm in metaphase. Despite its dissociation from chromosomes, however, microinjection of an antibody against human SMC1 led to disorganization of the metaphase plate and cell cycle arrest, indicating that human cohesin still plays an important role in metaphase. To address the mitotic function of human cohesin, the subcellular localization of cohesin components was reexamined in human cells. Interestingly, we found that cohesin localizes to the spindle poles during mitosis and interacts with NuMA, a spindle pole-associated factor required for mitotic spindle organization. The interaction with NuMA persists during interphase. Similar to NuMA, a significant amount of cohesin was found to associate with the nuclear matrix. Furthermore, in the absence of cohesin, mitotic spindle asters failed to form in vitro. Our results raise the intriguing possibility that in addition to its well demonstrated function in sister chromatid cohesion, cohesin may be involved in spindle assembly during mitosis.

Restricted chromosomal silencing in nucleolar dominance

Failure of one parent's chromosomes to organize nucleoli in an interspecific hybrid is an epigenetic phenomenon known as nucleolar dominance. Selective gene silencing on a scale of millions of bp is known to be involved, but the full extent to which nucleolus organizer region (NOR)-bearing chromosomes are inactivated beyond the NORs is unknown. Aided by genome sequence data for Arabidopsis thaliana, we have mapped the extent of nucleolar dominance-induced silencing in Arabidopsis suecica, the allotetraploid hybrid of A. thaliana and Arabidopsis arenosa. Using a sensitive reverse transcription PCR assay, we show that the four A. thaliana NORs, each approximately 4 Mbp in size, are approximately 99.5% silenced in A. suecica vegetative leaves, whereas the NORs inherited from A. arenosa remain fully active. The two A. thaliana NORs, NOR2 and NOR4, abut the telomeres on chromosomes 2 and 4, thus there are no genes distal to the NORs. The three protein-coding genes nearest NOR4 on its centromere-proximal side, the closest of which is only 3.1 kb from rRNA gene sequences, are shown to be transcribed in the hybrid despite the silencing of the adjacent approximately 4-Mbp NOR. These data argue against hypotheses in which NOR inactivation is attributed to the spread of silencing from adjacent chromosomal regions, but favor models in which NORs or rRNA genes are the targets of regulation.

Replacement of Fab-7 by the gypsy or scs insulator disrupts long-distance regulatory interactions in the Abd-B gene of the bithorax complex

Chromatin domain boundaries, like scs or gypsy insulators in Drosophila, have been identified in transgene assays through their enhancer-blocking activity. Boundary elements in the bithorax complex (BX-C), such as Fab-7 and Fab-8, have been identified genetically and been shown to have insulator activity in transgene assays. However, it is not clear whether boundary elements identified in transgene assays will function appropriately in chromosomal contexts such as BX-C. Using gene conversion, we have substituted the scs or gypsy insulators for Fab-7. We find that both scs and gypsy are very potent insulators in the ectoderm, but surprisingly, the insulating activity of gypsy (but not scs) is lost in the CNS. Our results reveal that the Fab-7 boundary must have special properties that scs and gypsy lack, which allow it to function appropriately in BX-C regulation.

Identification of a conserved erythroid specific domain of histone acetylation across the alpha-globin gene cluster

We have analyzed the pattern of core histone acetylation across 250 kb of the telomeric region of the short arm of human chromosome 16. This gene-dense region, which includes the alpha-globin genes and their regulatory elements embedded within widely expressed genes, shows marked differences in histone acetylation between erythroid and non-erythroid cells. In non-erythroid cells, there was a uniform 2- to 3-fold enrichment of acetylated histones, compared with heterochromatin, across the entire region. In erythroid cells, an approximately 100-kb segment of chromatin encompassing the alpha genes and their remote major regulatory element was highly enriched in histone H4 acetylated at Lys-5. Other lysines in the N-terminal tail of histone H4 showed intermediate and variable levels of enrichment. Similar broad segments of erythroid-specific histone acetylation were found in the corresponding syntenic regions containing the mouse and chicken alpha-globin gene clusters. The borders of these regions of acetylation are located in similar positions in all three species, and a sharply defined 3' boundary coincides with the previously identified breakpoint in conserved synteny between these species. We have therefore demonstrated that an erythroid-specific domain of acetylation has been conserved across several species, encompassing not only the alpha-globin genes but also a neighboring widely expressed gene. These results contrast with those at other clusters and demonstrate that not all genes are organized into discrete regulatory domains.

Promoter suppression in cultured mammalian cells can be blocked by the chicken beta-globin chromatin insulator 5'HS4 and matrix/scaffold attachment regions

Studies have indicated that two transcriptionally active units can repress one another when they lie adjacent in head-to-tail tandem on a chromosome. Repression of a downstream (3') unit by an upstream (5') unit is known as "transcriptional interference", whereas repression of a 5' unit by a 3' unit is termed "promoter suppression". These two processes can occur between head-to-tail tandem copies of a transgene, or between transgenes and adjacent chromosomal genes. Interference can be blocked by inserting a transcription terminator between adjacent units. Here, we report that "promoter suppression" could be blocked by the insulator 5' DNaseI hypersensitive site 4, or matrix/scaffold attachment regions (MAR/SARs), when these elements were interposed between adjacent units. Because intergenic spacers of many repeated eukaryotic genes contain MAR/SARs and insulators, our observations suggest that these elements have the ability to segregate repeated genes into domains that act independently of one another. Our observations also suggest strategies to design transgenes that can act as autonomous units of expression.

Features of nuclear architecture that influence gene expression in higher eukaryotes: confronting the enigma of epigenetics

Complex mechanisms that influence gene expression in mammalian cells have been studied intensively over recent years. Genetic elements that control both the tissue specific patterns and levels of gene expression together with the proteins they bind have been characterised in detail and are clearly pivotal in activating pathways of gene expression. But it is also clear that the behaviour of these genetic elements is complicated by epigenetic factors, so that their introduction into cells with the necessary developmental history-and hence appropriate global concentrations of essential transcription factors-will not guarantee the desired levels of transcription. Recent experiments have reinforced this view and confirmed that apparently critical functions performed by defined genetic elements at certain chromosomal sites are not inevitably recapitulated at other chromosomal locations. Hence, a re-evaluation of the function of critical control elements is required using experimental systems that simplify the range of factors arising from local chromatin organisation. In this way, it should be possible to reveal the intricacies of gene expression that might eventually allow us to reproduce natural levels of expression from artificial gene constructs in human cells. J. Cell. Biochem. Suppl. 35:69-77, 2000.

Insulation of enhancer-promoter communication by a gypsy transposon insert in the Drosophila cut gene: cooperation between suppressor of hairy-wing and modifier of mdg4 proteins

The Drosophila mod(mdg4) gene products counteract heterochromatin-mediated silencing of the white gene and help activate genes of the bithorax complex. They also regulate the insulator activity of the gypsy transposon when gypsy inserts between an enhancer and promoter. The Su(Hw) protein is required for gypsy-mediated insulation, and the Mod(mdg4)-67.2 protein binds to Su(Hw). The aim of this study was to determine whether Mod(mdg4)-67.2 is a coinsulator that helps Su(Hw) block enhancers or a facilitator of activation that is inhibited by Su(Hw). Here we provide evidence that Mod(mdg4)-67.2 acts as a coinsulator by showing that some loss-of-function mod(mdg4) mutations decrease enhancer blocking by a gypsy insert in the cut gene. We find that the C terminus of Mod(mdg4)-67.2 binds in vitro to a region of Su(Hw) that is required for insulation, while the N terminus mediates self-association. The N terminus of Mod(mdg4)-67.2 also interacts with the Chip protein, which facilitates activation of cut. Mod(mdg4)-67.2 truncated in the C terminus interferes in a dominant-negative fashion with insulation in cut but does not significantly affect heterochromatin-mediated silencing of white. We infer that multiple contacts between Su(Hw) and a Mod(mdg4)-67.2 multimer are required for insulation. We theorize that Mod(mdg4)-67.2 usually aids gene activation but can also act as a coinsulator by helping Su(Hw) trap facilitators of activation, such as the Chip protein.

The sea urchin sns insulator blocks CMV enhancer following integration in human cells

Insulators are a new class of genetic elements that attenuate enhancer function directionally. Previously, we characterized in sea urchin a 265-bp-long insulator, termed sns. To test insulator activity following stable integration in human cells, we placed sns between the CMV enhancer and a tk promoter upstream of a GFP transgene of plasmid or retroviral vectors. In contrast to controls, cells transfected or transduced with insulated constructs displayed a barely detectable fluorescence. Southern blot and PCR ruled out vector rearrangement following integration into host DNA; RNase protection confirmed the enhancer blocking activity. Finally, we demonstrate that two cis-acting sequences, previously characterized in sea urchin, are also specific binding sites for human proteins. We conclude that sns interferes with enhancer promoter interaction also in a human chromatin context. The relatively small size, evolutionary conservation and apparent lack of enhancer specificity might result useful in gene transfer experiments in human cells.

The 5' boundary of the human apolipoprotein B chromatin domain in intestinal cells

The 5' boundary of the chromosomal domain of the human apolipoprotein B (apoB) gene in intestinal cells has been localized and characterized. It is composed of two kinds of boundary elements; the first, functional boundary is an insulator activity exhibited by a 1.8 kb DNA fragment located between -58 and -56 kb upstream of the human apoB promoter. In this region, an enhancer-blocking activity has been mapped to a CTCF binding site that is located upstream of two apoB intestinal enhancers (IEs), the 315 IE and the 485 IE. The CTCF site represents a boundary between two types of chromatin structure: an open, DNaseI-sensitive region 3' of the CTCF site containing the intestinal regulatory elements and a closed, DNaseI-resistant region 5' of the CTCF site. The 1.8 kb fragment harboring the CTCF site also insulated mini-white transgenes against position effects in Drosophila melanogaster. The second, structural boundary is represented by a nuclear matrix attachment region (MAR), situated about 3 kb 5' of the CTCF site. This MAR may represent the 5' anchorage site for a chromosomal loop that functions to bring the intestinal regulatory elements closer to the apoB promoter.

Development of stable cell lines for production or regulated expression using matrix attachment regions

One of the major hurdles of isolating stable, inducible or constitutive high-level producer cell lines is the time-consuming selection procedure. Given the variation in the expression levels of the same construct in individual clones, hundreds of clones must be isolated and tested to identify one or more with the desired characteristics. Various boundary elements (BEs), matrix attachment regions, and locus control regions (LCRs) were screened for their ability to augment the expression of heterologous genes in Chinese hamster ovary (CHO) cells. Of the chromatin elements assayed, the chicken lysozyme matrix-attachment region (MAR) was the only element to significantly increase stable reporter expression. We found that the use of the MAR increases the proportion of high-producing clones, thus reducing the number of clones that need to be screened. These benefits are observed both for constructs with MARs flanking the transgene expression cassette, as well as when constructs are co-transfected with the MAR on a separate plasmid. Moreover, the MAR was co-transfected with a multicomponent regulatable beta-galactosidase expression system in C2C12 cells and several clones exhibiting regulated expression were identified. Hence, MARs are useful in the development of stable cell lines for production or regulated expression.

Insulators and boundaries: versatile regulatory elements in the eukaryotic genome

Insulators mark the boundaries of chromatin domains by limiting the range of action of enhancers and silencers. Although the properties of insulators have been well studied, their role in vivo has largely been a subject of speculation. Recent results make it possible to ascribe specific and essential functions to the insulators of Drosophila , yeast, and vertebrates. In some cases, insulator activity can be modulated by nearby regulatory elements, bound cofactors, or covalent modification of the DNA. Not simply passive barriers, insulators are active participants in eukaryotic gene regulation.