Abstract

The beta-globin genes were among the first human genes to be cloned. This led to expectations that hemoglobinopathy diseases such as sickle cell anemia and beta-thalassemia would be among the first diseases to be treated by gene therapy. And yet, nearly ten years after the first gene therapy protocol was approved and after a total of 200 therapeutic protocols have been submitted, no hemoglobinopathy patient has been treated with gene replacement therapy. This is largely due to technical problems involving the gene therapy vectors to be used for the hemoglobinopathies. One of these problems is that consistent, long-lasting, high-level expression has yet to be attained in pre-clinical systems. Evidence indicates that this problem is, at least in part, due to an inability of current vectors to efficiently create a transcriptionally active or """"""""open"""""""" chromatin structure surrounding the integrated vector. The normal beta-globin genes, in the context of the beta-globin gene locus, are able to efficiently perform this process in erythroid cells. Our long term goals are to study the processes by which the normal locus is able to open chromatin structure in an erythroid- specific fashion and to then apply these findings to help develop new gene therapy vectors which are able to independently open chromatin structure wherever they insert into the human genome. We are attacking these problems on four fronts. First we will continue to characterize a 101bp element from HS4 of the beta-globin LCR which is able to locally open chromatin structure in erythroid cells. Our current data implicates the transcription factors NF-E2, GATA-1 and Sp1 in this process. GATA-1 seems to be particularly important in this process. In our second aim we will perform structural studies on this factor gain insight the mechanisms by which it is able to reorganize chromatin structure. In our third aim we will continue our efforts to locate the boundaries of the domain of open chromatin structure which forms around the globin gene locus. Finally, we will continue to test the ability of chromatin structure-determining elements (i.e., HS4 HSFE, chicken beta-globin boundary element, HS3 core, HS2 enhancer) alone and in combination to yield position-independent, high-level, non-silencing expression. These experiments provide a comprehensive approach to understanding the regulation of beta-globin locus chromatin structure and potential applications to development of gene therapy strategies.

  Funding Agency

Agency
National Institute of Health (NIH)
Institute
National Heart, Lung, and Blood Institute (NHLBI)
Type
Research Project (R01)
Project #
2R01HL052243-05
Application #
2752389
Study Section
Hematology Subcommittee 2 (HEM)
Project Start
1994-12-01
Project End
2002-07-31
Budget Start
1999-08-10
Budget End
2000-07-31
Support Year
5
Fiscal Year
1999
Total Cost
Indirect Cost

  Institution

Name
Dartmouth College
Department
Internal Medicine/Medicine
Type
Schools of Medicine
DUNS #
041027822
City
Hanover
State
NH
Country
United States
Zip Code
03755

  Publications

Boosalis, Michael S; Castaneda, Serguei A; Trudel, Marie et al. (2011) Novel therapeutic candidates, identified by molecular modeling, induce ?-globin gene expression in vivo. Blood Cells Mol Dis 47:107-16
Mabaera, Rodwell; West, Rachel J; Conine, Sarah J et al. (2008) A cell stress signaling model of fetal hemoglobin induction: what doesn't kill red blood cells may make them stronger. Exp Hematol 36:1057-72
Layon, Michael E; Ackley, Catherine J; West, Rachel J et al. (2007) Expression of GATA-1 in a non-hematopoietic cell line induces beta-globin locus control region chromatin structure remodeling and an erythroid pattern of gene expression. J Mol Biol 366:737-44
Mabaera, Rodwell; Richardson, Christine A; Johnson, Kristin et al. (2007) Developmental- and differentiation-specific patterns of human gamma- and beta-globin promoter DNA methylation. Blood 110:1343-52
Ermentrout, R Mitchell; Layon, Michael E; Ackley, Catherine J et al. (2006) The effects of lead and cadmium on GATA-1 regulated erythroid gene expression. Blood Cells Mol Dis 37:164-72
Mankidy, Rishikesh; Faller, Douglas V; Mabaera, Rodwell et al. (2006) Short-chain fatty acids induce gamma-globin gene expression by displacement of a HDAC3-NCoR repressor complex. Blood 108:3179-86
Nemeth, Michael J; Lowrey, Christopher H (2004) An Erythroid-Specific Chromatin Opening Element Increases beta-Globin Gene Expression from Integrated Retroviral Gene Transfer Vectors. Gene Ther Mol Biol 8:475-486
Kitareewan, Sutisak; Pitha-Rowe, Ian; Sekula, David et al. (2002) UBE1L is a retinoid target that triggers PML/RARalpha degradation and apoptosis in acute promyelocytic leukemia. Proc Natl Acad Sci U S A 99:3806-11
Nemeth, M J; Bodine, D M; Garrett, L J et al. (2001) An erythroid-specific chromatin opening element reorganizes beta-globin promoter chromatin structure and augments gene expression. Blood Cells Mol Dis 27:767-80
Goodwin, A J; McInerney, J M; Glander, M A et al. (2001) In vivo formation of a human beta-globin locus control region core element requires binding sites for multiple factors including GATA-1, NF-E2, erythroid Kruppel-like factor, and Sp1. J Biol Chem 276:26883-92

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