Sequences Flanking Hypersensitive Sites of the β-Globin Locus Control Region Are Required for Synergistic Enhancement

Molete, Joseph M.; Petrykowska, Hanna M.; Bouhassira, Eric E.; Feng, Yue; Miller, Webb; Hardison, Ross C.

doi:10.1128/mcb.21.9.2969-2980.2001

Cited by 46 publications

(41 citation statements)

References 48 publications

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“…18 If the LCR forms a holocomplex then it follows that disruption of some portion of the structure could lead to disruption of the entire structure. This model is supported by transfection studies of constructs with different HS combinations 13,19,20 and by deletion studies of human LCR HS core regions in human ␤-globin yeast artificial chromosome (YAC) transgenic mice. 18,[21][22][23] In YAC transgenic mice, deletion of individual human HS cores (HS2, HS3, or HS4) results in severe reduction of all ␤-like globin gene expression and failure to form the remaining HSs, 21,24,25 suggesting that LCR HSs are mutually interdependent for their formation.…”

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confidence: 78%

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Deletion of the core region of 5′ HS2 of the mouse β-globin locus control region reveals a distinct effect in comparison with human β-globin transgenes

Bulger

Bender

et al. 2006

Blood

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The ␤-globin locus control region (LCR) is a large DNA element that is required for high-level expression of ␤-like globin genes from the endogenous mouse locus or in transgenic mice carrying the human ␤-globin locus. The LCR encompasses 6 DNaseI hypersensitive sites (HSs) that bind transcription factors. These HSs each contain a core of a few hundred base pairs (bp) that has most of the functional activity and exhibits high interspecies sequence homology. Adjoining the cores are 500-to 1000-bp "flanks" with weaker functional activity and lower interspecies homology. Studies of human ␤-globin transgenes and of the endogenous murine locus show that deletion of an entire HS (core plus flanks) moderately suppresses expression. However, human transgenes in which only individual HS core regions were deleted showed drastic loss of expression accompanied by changes in chromatin structure. To address these disparate results, we have deleted the core region of 5HS2 from the endogenous murine ␤-LCR. The phenotype was similar to that of the larger 5HS2 deletion, with no apparent disruption of chromatin structure. These results demonstrate that the greater severity of HS core deletions in comparison to full HS deletions is not a general property of the ␤-LCR. IntroductionLocus control regions (LCRs) are specialized tissue-specific DNA regulatory elements that are functionally defined by their ability to improve position independence and copy number dependence of linked genes in transgenic mice. The ␤-globin LCR was the first identified and has been the most heavily studied. Other LCRs have been identified that are postulated to be important in regulating genes at their endogenous locations. [1][2][3] However, it is unclear whether regulatory activities demonstrated in transgenic studies are relevant for LCRs in their endogenous loci.The human and mouse ␤-globin loci are highly homologous. Both have a series of ␤-like globin genes that are activated in erythroid cells at different developmental stages (reviewed in Stamatoyannopoulos et al 4 ). The human ␤-globin LCR is a group of hypersensitive sites (HSs) located 6 to 22 kb upstream of the embryonic ⑀-globin gene. 5,6 The murine ␤-globin LCR is very similar to the human ␤-globin LCR in its structure, sequence, and activity 7 (Figure 1). The human LCR has been studied predominantly as transgenes in mice or cells, whereas the murine LCR has been predominantly studied by targeted mutation in its endogenous location. Deletion of the murine ␤-globin LCR showed that it is required for high-level expression of all the linked ␤-like globin genes, but developmental timing of gene expression and the chromatin structure of the remaining locus was unaffected by the LCR deletion. 8,9 Each HS contains a very highly conserved core fragment that is 200-to 400-bp long and less conserved but recognizably homologous sequences of roughly 500 to 1000 bp flanking the core ( Figure 1B). The cores from the major HS contain transcription factor binding sites that are generally similar between HSs....

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confidence: 78%

“…The flanking sequences do form minor DNaseI HSs and carry limited transcriptional activation activities. 13 Two models can be delineated for how the multiple LCR HSs interact to regulate gene expression. An additive model proposes that each 5Ј HS contributes independently in an additive manner to LCR activity.…”

Section: Introductionmentioning

confidence: 99%

Deletion of the core region of 5′ HS2 of the mouse β-globin locus control region reveals a distinct effect in comparison with human β-globin transgenes

Bulger

Bender

et al. 2006

Blood

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“…Deletion of individual HSs of the endogenous ␤-globin locus control region yielded incremental decreases in ␤-globin expression, consistent with a mechanism involving additivity (46,47). In contrast, deletion of HSs from the intact ␤-globin locus within a yeast artificial chromosome (48,49) and transfection experiments (50,51) reveal synergism between the HSs.…”

Section: Distinct Preferences For Gata-1 and Gata-2 Occupancy Of Chromentioning

confidence: 90%

Dynamic GATA Factor Interplay at a Multicomponent Regulatory Region of the GATA-2 Locus

Martowicz

Grass

Boyer

et al. 2005

Journal of Biological Chemistry

105

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Given the simplicity of the DNA sequence that mediates binding of GATA transcription factors, GATA motifs reside throughout chromosomal DNA. However, chromatin immunoprecipitation analysis has revealed that GATA-1 discriminates exquisitely among these sites. GATA-2 selectively occupies the ؊2.8-kilobase (kb) region of the GATA-2 locus in the active state despite there being numerous GATA motifs throughout the locus. The GATA-1-mediated displacement of GATA-2 is tightly coupled to repression of GATA-2 transcription. We have used high resolution chromatin immunoprecipitation to show that GATA-1 and GATA-2 occupy two additional regions, ؊3.9 and ؊1.8 kb of the GATA-2 locus. GATA-1 and GATA-2 had distinct preferences for occupancy at these regions, with GATA-1 and GATA-2 occupancy highest at the ؊3.9-and ؊1.8-kb regions, respectively. Activation of an estrogen receptor fusion to GATA-1 (ER-GATA-1) induced similar kinetics of ER-GATA-1 occupancy and GATA-2 displacement at the sites. In the transcriptionally active state, DNase I hypersensitive sites (HSs) were detected at the ؊3.9-and ؊1.8-kb regions, with a weak HS at the ؊2.8-kb region. Whereas ER-GATA-1-instigated repression abolished the ؊1.8-kb HS, the ؊3.9-kb HS persisted in the repressed state. Transient transfection analysis provided evidence that the ؊3.9-kb region functions distinctly from the ؊2.8-and ؊1.8-kb regions. We propose that GATA-2 transcription is regulated via the collective actions of complexes assembled at the ؊2.8-and ؊1.8-kb regions, which share similar properties, and through a qualitatively distinct activity of the ؊3.9-kb complex.

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“…Globin transcriptional control elements have been extensively studied, 27,28 without conclusively defining what minimal segments and what combination thereof are best suited to generate a miniature ␤-globin transcription unit. The relative roles of the locus control region and of other genetic elements spanning the human ␤-globin locus and its chromatin domain in regulating globin gene expression remain controversial.…”

Section: Discussionmentioning

confidence: 99%

A novel murine model of Cooley anemia and its rescue by lentiviral-mediated human β-globin gene transfer

Rivella

May

Chadburn

et al. 2003

Blood

211

220

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Patients affected by ␤-thalassemia major require lifelong transfusions because of insufficient or absent production of the ␤ chain of hemoglobin (Hb). A minority of patients are cured by allogeneic bone marrow transplantation. In the most severe of the hitherto available mouse models of ␤-thalassemia, a model for human ␤-thalassemia intermedia, we previously demonstrated that globin gene transfer in bone marrow cells is curative, stably raising Hb levels from 8.0-8.5 to 11.0-12.0 g/dL in long-term chimeras. To fully assess the therapeutic potential of gene therapy in the context of a lethal anemia, we now have created an adult model of ␤ 0 -thalassemia major. In this novel model, mice engrafted with ␤-globin-null (Hbb th3/th3 ) fetal liver cells succumb to ineffective erythropoiesis within 60 days. These mice rapidly develop severe anemia (2-4 g/dL), massive splenomegaly, extramedullary hematopoiesis (EMH), and hepatic iron overload. Remarkably, most mice (11 of 13) treated by lentivirus-mediated globin gene transfer were rescued. Long-term chimeras with an average 1.0-2. IntroductionThe ␤-thalassemias are caused by more than 200 mutations that lead to decreased or absent production of the ␤ chain of hemoglobin (Hb). 1-3 Most of the mutations are point mutations in the ␤-globin gene that either decrease the level of transcription or mRNA stability or lead to nonfunctional mRNA, as is the case in nonsense and frameshift mutations. Other mutations include deletions in the ␤-globin gene, as well as rare deletions located distally to the ␤-globin gene itself. 1,3,4 There is a large spectrum in the severity of the disease found in homozygotes and compound heterozygotes. Patients affected by ␤-thalassemia intermedia do not require chronic transfusion therapy in the first years of life, but they often worsen over time, eventually developing hypersplenism, osteopenia, extramedullary hematopoiesis (EMH), and iron overload. Some patients eventually require splenectomy and blood transfusions. In patients with ␤-thalassemia major, or Cooley anemia, the absent or extremely reduced production of the ␤ chain of Hb causes severe ineffective erythropoiesis, massive erythroid hyperplasia in the bone marrow and extramedullary sites, and hemolysis. The ensuing iron overload can lead to endocrine deficiencies, cirrhosis, and cardiac failure. In the absence of lifelong transfusions, the disease is lethal. 5 Current disease management consists of prenatal diagnosis, transfusion therapy, or allogeneic bone marrow transplantation. 1,3,4 Only the latter is curative, but this option is limited to a minority of patients for whom a histocompatible donor can be identified.New approaches aimed at ameliorating the condition of patients with severe ␤-thalassemia are greatly needed. Genetic approaches based on the transfer of a regulated human ␤-globin gene in autologous hematopoietic stem cells (HSCs) represent an attractive potential treatment. 6 Their implementation has been hampered by the difficulty of appropriately regulating expression o...

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Sequences Flanking Hypersensitive Sites of the β-Globin Locus Control Region Are Required for Synergistic Enhancement

Cited by 46 publications

References 48 publications

Deletion of the core region of 5′ HS2 of the mouse β-globin locus control region reveals a distinct effect in comparison with human β-globin transgenes

Deletion of the core region of 5′ HS2 of the mouse β-globin locus control region reveals a distinct effect in comparison with human β-globin transgenes

Dynamic GATA Factor Interplay at a Multicomponent Regulatory Region of the GATA-2 Locus

A novel murine model of Cooley anemia and its rescue by lentiviral-mediated human β-globin gene transfer

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