Poly(ADP-ribose) polymerase-1 (PARP-1) contributes to the barrier function of a vertebrate chromatin insulator.

The prototypic chromatin insulator cHS4 has proven effective in reducing silencing chromosomal position effects in a variety of settings. Most of this barrier insulator activity has been mapped to a 250-bp core region, as well as to several proteins that bind this region. However, recent studies from our laboratory demonstrated that an extended 400-bp core region of the cHS4 element is necessary to achieve full barrier insulator activity when used as a single copy in the context of recombinant gammaretroviral and lentiviral vectors. In this study, electrophoretic gel mobility shift assays revealed specific DNA-protein binding activities associated with the distal portion of this extended core region. Affinity purification and tandem mass spectrometry studies led to the identification of one of these proteins as poly(ADP-ribose) polymerase-1 (PARP-1). The identity of this binding activity as PARP-1 was subsequently verified by a variety of biochemical studies in vitro and by chromatin immunoprecipitation studies in vivo. Functional studies with gammaretroviral reporter vectors in cell lines and primary mouse bone marrow progenitor cultures showed that cHS4 barrier activity was abrogated upon mutation of the putative PARP-1-binding site or upon treatment with a PARP inhibitor, respectively. The barrier activity of the cHS4 element was also found to be abrogated in studies using bone marrow from Parp1-null mice. Taken together, this study demonstrates that binding of PARP-1 plays a key functional role in the barrier activity of the extended cHS4 insulator core element.

Extended core sequences from the cHS4 insulator are necessary for protecting retroviral vectors from silencing position effects.

The prototypic chromatin insulator cHS4 has proven effective at reducing repressive chromosomal position effects on retroviral vector expression. We report here studies designed to identify the minimal chicken hypersensitive site-4 (cHS4) sequences necessary for this activity. Using a gammaretroviral reporter vector and expression analysis in cell lines and primary mouse hematopoietic progenitor colonies, we found that a 250-bp core fragment reported to contain most of the cHS4 insulating activity failed to prevent silencing when used alone, although some barrier activity was observed when this fragment was combined with a 790-bp, but not 596-bp, spacer. Similar studies showed that four copies of a 90-bp fragment containing the cHS4 enhancer-blocking activity actually repressed vector green fluorescent protein (GFP) expression. In contrast, a 400-bp fragment containing the 250-bp core plus 3' flanking sequences protected vector expression to the same degree as the full-length 1.2-kb fragment. The 400-bp fragment activity was confirmed in a lentiviral vector expressing human beta-globin in murine erythroid leukemia (MEL) cells. Taken together, these studies indicate that the insulating activity of the 250-bp cHS4 core can be influenced by distance, and identify an extended core element that confers full barrier activity in the setting of two different classes of retroviral vectors.

Integration bias of gammaretrovirus vectors following transduction and growth of primary mouse hematopoietic progenitor cells with and without selection.

The recent recognition that recombinant retrovirus vectors can induce oncogenic transformation has stimulated much interest in the pattern of vector integration sites. We report here on the integration pattern of a gammaretrovirus reporter vector following transduction and ex vivo culture of primary mouse bone marrow progenitor cells in the absence and presence of drug selection. Using a novel method of cloning junction fragments, we observed no bias for integrations within genes, but did observe a bias for integrations within gene-dense regions and especially near transcriptional start sites of highly active genes, similar to previous reports in other cell types. We also document a novel bias for integrations within or near a class of genes that encode nuclear-localized proteins. We found that drug selection resulted in an increase in the frequency of recovered integration events that were located within the beginning of genes, integration events that were located in less gene-dense regions, and integration events that were oriented in an antisense direction relative to flanking gene transcription. Taken together, these studies provide new insights into the nature of retrovirus vector integration patterns in primary cells and demonstrate that selection based on vector expression can bias the integration site repertoire.

Topological constraints governing the use of the chicken HS4 chromatin insulator in oncoretrovirus vectors.

The expression of integrated oncoretrovirus vectors is subject to the inhibitory effects of surrounding chromatin. A previous report from our laboratory indicated that such position effects can be overcome by flanking a reporter vector with the cHS4 chromatin insulator. To characterize this activity more thoroughly, we switched the promoter-gene combinations in the reporter vector and analyzed expression of these vectors flanked with the cHS4 fragment in both orientations following bone marrow transduction and transplantation in mice. The results indicate that the cHS4 fragment can function in both orientations and can insulate both the virus long-terminal-repeat (LTR) promoter and an internal phosphoglycerate kinase (Pgk) promoter. However, insulation of the LTR promoter diminished when the orientation of the cHS4 fragment placed the CTCF-binding core element immediately proximal to the U3 region, suggesting a minimal distance requirement. Moreover, placement of the cHS4 fragment in the U3 region of the 3' LTR dramatically decreased the level of expression from an internal Pgk promoter, presumably by blocking interaction with the 3' LTR enhancer. Finally, sorting studies suggest that the severity of position effects or autonomous promoter silencing increases as transduced progenitors differentiate into mature progeny. These findings have direct implications for the use of chromatin insulators such as cHS4 in oncoretrovirus vectors.