Mutation of a barrier insulator in the human ankyrin-1 gene is associated with hereditary spherocytosis
Patrick G. Gallagher, … , Lisa J. Garrett, David M. Bodine
Patrick G. Gallagher, … , Lisa J. Garrett, David M. Bodine
Published November 22, 2010
Citation Information: J Clin Invest. 2010;120(12):4453-4465. https://doi.org/10.1172/JCI42240.
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Research Article

Mutation of a barrier insulator in the human ankyrin-1 gene is associated with hereditary spherocytosis

Abstract

Defects of the ankyrin-1 gene are the most common cause in humans of hereditary spherocytosis, an inherited anemia that affects patients of all ethnic groups. In some kindreds, linked –108/–153 nucleotide substitutions have been found in the upstream region of the ankyrin gene promoter that is active in erythroid cells. In vivo, the ankyrin erythroid promoter and its upstream region direct position-independent, uniform expression, a property of barrier insulators. Using human erythroid cell lines and primary cells and transgenic mice, here we have demonstrated that a region upstream of the erythroid promoter is a barrier insulator in vivo in erythroid cells. The region exhibited both functional and structural characteristics of a barrier, including prevention of gene silencing in an in vivo functional assay, appropriate chromatin configuration, and occupancy by barrier-associated proteins. Fragments with the –108/–153 spherocytosis-associated mutations failed to function as barrier insulators in vivo and demonstrated perturbations in barrier-associated chromatin configuration. In transgenic mice, flanking a mutant –108/–153 ankyrin gene promoter with the well-characterized chicken HS4 barrier insulator restored position-independent, uniform expression at levels comparable to wild-type. These data indicate that an upstream region of the ankyrin-1 erythroid promoter acts as a barrier insulator and identify disruption of the barrier element as a potential pathogenetic mechanism of human disease.

Authors

Patrick G. Gallagher, Laurie A. Steiner, Robert I. Liem, Ashley N. Owen, Amanda P. Cline, Nancy E. Seidel, Lisa J. Garrett, David M. Bodine

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Figure 4

Quantitative ChIP analyses of chromatin architecture in the ankyrin-1 5′HS region.

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Quantitative ChIP analyses of chromatin architecture in the ankyrin-1 5′...
ChIP studies examining posttranslational histone modifications around the 5′HS region. (A) Left panel: ChIP with antibodies against diacetylated histone H3 (DiAcH3) and tetraacetylated histone H4 (TetraAcH4) and K562 chromatin. Middle panel: ChIP with antibodies against H3K4me1, H3K4me2, and H3K4me3. HS2 of the β-globin locus (93) was included as a positive control (+C), and a region of hsSat2 (94) was included as a negative control (–C). Right panel: The region and primers utilized in ChIP. (B) ChIP analyses with K562 cells (left) and primary erythroid cells (right). Top 2 rows: ChIP with antibodies against DiAcH3 and H3K4me2. Third row and left panel of fourth row: ChIP with antibodies against H3K27me3 and H3K9me3. For H3K27me3, a region of the HoxB7 gene was included as a positive control, and a region of the β-actin promoter was included as negative control. For H3K9me3, a region of hsSat2, repeat F1-X72636, was included as a positive control, and a region of the actin promoter was included as negative control. Bottom right panels: The region and primers utilized in ChIP.