Gammaretrovirus-mediated correction of SCID-X1 is associated with skewed vector integration site distribution in vivo
Kerstin Schwarzwaelder, … , Adrian J. Thrasher, Christof von Kalle
Kerstin Schwarzwaelder, … , Adrian J. Thrasher, Christof von Kalle
Published August 1, 2007
Citation Information: J Clin Invest. 2007;117(8):2241-2249. https://doi.org/10.1172/JCI31661.
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Research Article

Gammaretrovirus-mediated correction of SCID-X1 is associated with skewed vector integration site distribution in vivo

Abstract

We treated 10 children with X-linked SCID (SCID-X1) using gammaretrovirus-mediated gene transfer. Those with sufficient follow-up were found to have recovered substantial immunity in the absence of any serious adverse events up to 5 years after treatment. To determine the influence of vector integration on lymphoid reconstitution, we compared retroviral integration sites (RISs) from peripheral blood CD3+ T lymphocytes of 5 patients taken between 9 and 30 months after transplantation with transduced CD34+ progenitor cells derived from 1 further patient and 1 healthy donor. Integration occurred preferentially in gene regions on either side of transcription start sites, was clustered, and correlated with the expression level in CD34+ progenitors during transduction. In contrast to those in CD34+ cells, RISs recovered from engrafted CD3+ T cells were significantly overrepresented within or near genes encoding proteins with kinase or transferase activity or involved in phosphorus metabolism. Although gross patterns of gene expression were unchanged in transduced cells, the divergence of RIS target frequency between transduced progenitor cells and post-thymic T lymphocytes indicates that vector integration influences cell survival, engraftment, or proliferation.

Authors

Kerstin Schwarzwaelder, Steven J. Howe, Manfred Schmidt, Martijn H. Brugman, Annette Deichmann, Hanno Glimm, Sonja Schmidt, Claudia Prinz, Manuela Wissler, Douglas J.S. King, Fang Zhang, Kathryn L. Parsley, Kimberly C. Gilmour, Joanna Sinclair, Jinhua Bayford, Rachel Peraj, Karin Pike-Overzet, Frank J.T. Staal, Dick de Ridder, Christine Kinnon, Ulrich Abel, Gerard Wagemaker, H. Bobby Gaspar, Adrian J. Thrasher, Christof von Kalle

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Figure 2

Genomic distribution of RISs.

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Genomic distribution of RISs. (A) The relationship of chromosome size, n...
(A) The relationship of chromosome size, number of known genes, and RIS frequency. Values for chromosome lengths are shown as a percentage of the total genome size. Values for gene density are shown as a percentage of all genes from the genome. Values of RISs are shown as a percentage of RISs from the corresponding fraction. White bars, autosome length, which was counted twice to allow for the diploid status of hematopoietic cells (X and Y chromosomes were counted once only); light gray bars, gene density of each chromosome; medium gray bars, RISs detected in CD34+ cells from a healthy donor; dark gray bars, RISs detected in pretransplant CD34+ cells from Pt6; black bars, RIS detected in patients’ engrafted cells. (B and C) RISs location related to RefSeq genes. All mappable insertions detected in different fractions are shown as a percentage of all insertions derived from the corresponding fraction. Medium gray bars, RISs derived from transduced CD34+ cells of a healthy donor; dark gray bars, RISs derived from transduced preengraftment CD34+ cells from Pt6; black bars, RISs derived from patients’ engrafted cells. RefSeq gene, RISs in gene region. (B) RISs distribution 10 kbp up- and downstream of TSSs. Up, upstream of TSSs. (C) RISs in and near gene coding regions. RISs locations inside genes are expressed as the percentage of the overall length of each individual vector targeted gene. –5 kbp, all RISs located 5 kbp upstream of TSSs; +5 kbp, all RISs located 5 kbp downstream of RefSeq genes; Down, downstream of RefSeq genes.