Conservation of sequence and structure flanking the mouse and human beta-globin loci: the beta-globin genes are embedded within an array of odorant receptor genes

Independent formation of DnaseI hypersensitive sites in the murine β-globin locus control region

Mammalian β-globin loci are composed of multiple orthologous genes whose expression is erythroid specific and developmentally regulated. The expression of these genes both from the endogenous locus and from transgenes is strongly influenced by a linked 15-kilobase region of clustered DNaseI hypersensitive sites (HSs) known as the locus control region (LCR). The LCR encompasses 5 major HSs, each of which is highly homologous among humans, mice, and other mammals. To analyze the function of individual HSs in the endogenous murine β-globin LCR, we have used homologous recombination in embryonic stem cells to produce 5 mouse lines, each of which is deficient for 1 of these major HSs. In this report, we demonstrate that deletion of the conserved region of 5′HS 1, 2, 3, 4, or 5/6 abolishes HS formation at the deletion site but has no influence on the formation of the remaining HSs in the LCR. Therefore, in the endogenous murine locus, there is no dominant or initiating site whose formation must precede the formation of the other HSs. This is consistent with the idea that HSs form autonomously. We discuss the implications of these findings for current models of β-globin regulation.

Independent formation of DnaseI hypersensitive sites in the murine β-globin locus control region

Mammalian β-globin loci are composed of multiple orthologous genes whose expression is erythroid specific and developmentally regulated. The expression of these genes both from the endogenous locus and from transgenes is strongly influenced by a linked 15-kilobase region of clustered DNaseI hypersensitive sites (HSs) known as the locus control region (LCR). The LCR encompasses 5 major HSs, each of which is highly homologous among humans, mice, and other mammals. To analyze the function of individual HSs in the endogenous murine β-globin LCR, we have used homologous recombination in embryonic stem cells to produce 5 mouse lines, each of which is deficient for 1 of these major HSs. In this report, we demonstrate that deletion of the conserved region of 5′HS 1, 2, 3, 4, or 5/6 abolishes HS formation at the deletion site but has no influence on the formation of the remaining HSs in the LCR. Therefore, in the endogenous murine locus, there is no dominant or initiating site whose formation must precede the formation of the other HSs. This is consistent with the idea that HSs form autonomously. We discuss the implications of these findings for current models of β-globin regulation.

Locus control region activity by 5′HS3 requires a functional interaction with β-globin gene regulatory elements: expression of novel β/γ-globin hybrid transgenes

The human β-globin locus control region (LCR) contains chromatin opening and transcriptional enhancement activities that are important to include in β-globin gene therapy vectors. We previously used single-copy transgenic mice to map chromatin opening activity to the 5′HS3 LCR element. Here, we test novel hybrid globin genes to identify β-globin gene sequences that functionally interact with 5′HS3. First, we show that an 850-base pair (bp) 5′HS3 element activates high-level β-globin gene expression in fetal livers of 17 of 17 transgenic mice, including 3 single-copy animals, but fails to reproducibly activate Aγ-globin transgenes. To identify the β-globin gene sequences required for LCR activity by 5′HS3, we linked the 815-bp β-globin promoter to Aγ-globin coding sequences (BGT34), together with either the β-globin intron 2 (BGT35), the β-globin 3′ enhancer (BGT54), or both intron 2 and the 3′ enhancer (BGT50). Of these transgenes, only BGT50 reproducibly expresses Aγ-globin RNA (including 7 of 7 single-copy animals, averaging 71% per copy). Modifications to BGT50 show that LCR activity is detected after replacing the β-globin promoter with the 700-bp Aγ-globin promoter, but is abrogated when an AT-rich region is deleted from β-globin intron 2. We conclude that LCR activity by 5′HS3 on globin promoters requires the simultaneous presence of β-globin intron 2 sequences and the 260-bp 3′ β-globin enhancer. The BGT50 construct extends the utility of the 5′HS3 element to include erythroid expression of nonadult β-globin coding sequences in transgenic animals and its ability to express antisickling γ-globin coding sequences at single copy are ideal characteristics for a gene therapy cassette.

Locus control region activity by 5′HS3 requires a functional interaction with β-globin gene regulatory elements: expression of novel β/γ-globin hybrid transgenes

The human β-globin locus control region (LCR) contains chromatin opening and transcriptional enhancement activities that are important to include in β-globin gene therapy vectors. We previously used single-copy transgenic mice to map chromatin opening activity to the 5′HS3 LCR element. Here, we test novel hybrid globin genes to identify β-globin gene sequences that functionally interact with 5′HS3. First, we show that an 850-base pair (bp) 5′HS3 element activates high-level β-globin gene expression in fetal livers of 17 of 17 transgenic mice, including 3 single-copy animals, but fails to reproducibly activate Aγ-globin transgenes. To identify the β-globin gene sequences required for LCR activity by 5′HS3, we linked the 815-bp β-globin promoter to Aγ-globin coding sequences (BGT34), together with either the β-globin intron 2 (BGT35), the β-globin 3′ enhancer (BGT54), or both intron 2 and the 3′ enhancer (BGT50). Of these transgenes, only BGT50 reproducibly expresses Aγ-globin RNA (including 7 of 7 single-copy animals, averaging 71% per copy). Modifications to BGT50 show that LCR activity is detected after replacing the β-globin promoter with the 700-bp Aγ-globin promoter, but is abrogated when an AT-rich region is deleted from β-globin intron 2. We conclude that LCR activity by 5′HS3 on globin promoters requires the simultaneous presence of β-globin intron 2 sequences and the 260-bp 3′ β-globin enhancer. The BGT50 construct extends the utility of the 5′HS3 element to include erythroid expression of nonadult β-globin coding sequences in transgenic animals and its ability to express antisickling γ-globin coding sequences at single copy are ideal characteristics for a gene therapy cassette.

Structural and functional conservation at the boundaries of the chicken beta-globin domain

We show that the 3' boundary of the chicken beta-globin locus bears striking structural similarities to the 5' boundary. In erythroid cells a clear transition in DNase I sensitivity of chromatin at the 3' end of the locus is observed, the location of this transition is marked by a constitutive DNase I hypersensitive site (HS), and DNA spanning this site has the enhancer-blocking capacity of an insulator. This HS contains a binding site for the transcription factor CTCF. As in the case of the 5' insulator, the CTCF site is both necessary and sufficient for the enhancer-blocking activity of the 3' boundary. The position of this insulator is consistent with our proposal that it may function to maintain the distinct regulatory programs of the globin genes and their closely appended 3' neighbor, an odorant receptor gene. We conclude that both boundaries of the chicken beta-globin domain are capable of playing functionally similar roles and that the same protein is a necessary component of the molecular mechanism through which these boundaries are defined.

Nuclear localization and histone acetylation: a pathway for chromatin opening and transcriptional activation of the human β-globin locus

We have investigated the mechanism, structural correlates, andcis-acting elements involved in chromatin opening and gene activation, using the human β-globin locus as a model. Full transcriptional activity of the human β-globin locus requires the locus control region (LCR), composed of a series of nuclease hypersensitive sites located upstream of this globin gene cluster. Our previous analysis of naturally occurring and targeted LCR deletions revealed that chromatin opening and transcriptional activity in the endogenous β-globin locus are dissociable and dependent on distinctcis-acting elements. We now report that general histone H3/H4 acetylation and relocation of the locus away from centromeric heterochromatin in the interphase nucleus are correlated and do not require the LCR. In contrast, LCR-dependent promoter activation is associated with localized histone H3 hyperacetylation at the LCR and the transcribed β-globin-promoter and gene. On the basis of these results, we suggest a multistep model for gene activation; localization away from centromeric heterochromatin is required to achieve general hyperacetylation and an open chromatin structure of the locus, whereas a mechanism involving LCR/promoter histone H3 hyperacetylation is required for high-level transcription of the β-globin genes.

Nuclear localization and histone acetylation: a pathway for chromatin opening and transcriptional activation of the human beta-globin locus

We have investigated the mechanism, structural correlates, and cis-acting elements involved in chromatin opening and gene activation, using the human beta-globin locus as a model. Full transcriptional activity of the human beta-globin locus requires the locus control region (LCR), composed of a series of nuclease hypersensitive sites located upstream of this globin gene cluster. Our previous analysis of naturally occurring and targeted LCR deletions revealed that chromatin opening and transcriptional activity in the endogenous beta-globin locus are dissociable and dependent on distinct cis-acting elements. We now report that general histone H3/H4 acetylation and relocation of the locus away from centromeric heterochromatin in the interphase nucleus are correlated and do not require the LCR. In contrast, LCR-dependent promoter activation is associated with localized histone H3 hyperacetylation at the LCR and the transcribed beta-globin-promoter and gene. On the basis of these results, we suggest a multistep model for gene activation; localization away from centromeric heterochromatin is required to achieve general hyperacetylation and an open chromatin structure of the locus, whereas a mechanism involving LCR/promoter histone H3 hyperacetylation is required for high-level transcription of the beta-globin genes.

Beta-globin gene switching and DNase I sensitivity of the endogenous beta-globin locus in mice do not require the locus control region

We have generated mice with a targeted deletion of the beta-globin locus control region (LCR). Mice homozygous for the deletion die early in embryogenesis but can be rescued with a YAC containing the human beta-globin locus. After germline passage, deletion of the LCR leads to a severe reduction in expression of all mouse beta-like globin genes, but no alteration in the developmental specificity of expression. Furthermore, a DNase I-sensitive "open" chromatin conformation of the locus is established and maintained. Thus, the dominant role of the LCR in the native locus is to confer high-level transcription, and elements elsewhere in the locus are sufficient to establish and maintain an open conformation and to confer developmentally regulated globin gene expression.

Intergenic transcription and developmental remodeling of chromatin subdomains in the human beta-globin locus

Gene activation requires chromatin remodeling complexes, which hyperacetylate histones and enable factor access; however, the targeting mechanisms leading to the establishment and maintenance of large, hyperacetylated DNase-sensitive chromatin domains are unknown. Recent work has shown that histone acetyltransferases are associated with RNA-pol II complexes, suggesting that transcription of chromatin plays a role in chromatin modification. Here we show the human beta-globin locus is divided into three differentially activated chromatin subdomains. Large transcripts precisely delineate the active domains at key cell cycle points associated with chromatin transitions and remodeling. We identify an element that initiates these transcripts, located in a region required for chromatin activation. The results suggest that intergenic transcription is required for chromatin remodeling of chromosomal domains.

An olfactory receptor gene is located in the extended human beta-globin gene cluster and is expressed in erythroid cells

An olfactory receptor gene was identified near the 3' breakpoint of a naturally occurring deletion (HPFH-1) in the human beta-globin gene cluster on chromosome 11p15.5. The gene encodes an amino acid sequence that is 40 to 51% identical to that of a set of olfactory receptors that have only recently been identified as a distinct family of receptors. There are two orthologous genes in the mouse that encode amino acid sequences that are 73 and 71% identical, respectively, to that encoded by the human gene. This olfactory receptor gene is expressed at the RNA level in human and murine erythroid cells at all stages of development. This aberrant expression is probably due to the location of the gene in the transcriptionally active chromatin domain of the extended beta-globin gene cluster in erythroid cells.

The protein CTCF is required for the enhancer blocking activity of vertebrate insulators

An insulator is a DNA sequence that can act as a barrier to the influences of neighboring cis-acting elements, preventing gene activation, for example, when located between an enhancer and a promoter. We have identified a 42 bp fragment of the chicken beta-globin insulator that is both necessary and sufficient for enhancer blocking activity in human cells. We show that this sequence is the binding site for CTCF, a previously identified eleven-zinc finger DNA-binding protein that is highly conserved in vertebrates. CTCF sites are present in all of the vertebrate enhancer-blocking elements we have examined. We suggest that directional enhancer blocking by CTCF is a conserved component of gene regulation in vertebrates.