Erythroid-specific expression of ß-globin from Sleeping Beauty-transduced human hematopoietic progenitor cells.

Gene therapy for sickle cell disease will require efficient delivery of a tightly regulated and stably expressed gene product to provide an effective therapy. In this study we utilized the non-viral Sleeping Beauty (SB) transposon system using the SB100X hyperactive transposase to transduce human cord blood CD34(+) cells with DsRed and a hybrid IHK-ß-globin transgene. IHK transduced cells were successfully differentiated into multiple lineages which all showed transgene integration. The mature erythroid cells had an increased ß-globin to γ-globin ratio from 0.66±0.08 to 1.05±0.12 (p=0.05), indicating expression of ß-globin from the integrated SB transgene. IHK-ß-globin mRNA was found in non-erythroid cell types, similar to native ß-globin mRNA that was also expressed at low levels. Additional studies in the hematopoietic K562 cell line confirmed the ability of cHS4 insulator elements to protect DsRed and IHK-ß-globin transgenes from silencing in long-term culture studies. Insulated transgenes had statistically significant improvement in the maintenance of long term expression, while preserving transgene regulation. These results support the use of Sleeping Beauty vectors in carrying an insulated IHK-ß-globin transgene for gene therapy of sickle cell disease.

Proinflammatory phenotype with imbalance of KLF2 and RelA: risk of childhood stroke with sickle cell anemia.

Altered inflammation signaling within the cerebral vasculature may be an important risk factor for stroke in children with sickle cell anemia (SCA). This study examines how differential expression of NFkappaB/p65 (RelA), KLF2, and other transcription factors may act as switches in inflammation signaling leading to observed differences between non-SCA (NS) African Americans and African Americans with SCA who are either at risk (AR) or not at risk (NAR) of childhood stroke based on occurrence of Circle of Willis disease. Clover/Transfac analysis was used to identify overrepresented transcription factor binding motifs on genes associated with inflammation. Transcription factor binding motifs for the NFkappaB family and RFX1 were overrepresented on inflammation signaling gene set analysis. Variations in protein expression were determined by flow cytometry of blood outgrowth endothelial cells (BOECs) from NS, AR, and NAR donors and Western blots of protein extracts from both unstimulated and TNFalpha/IL1beta-stimulated BOECs. BOECs from patients with SCA had more cytoplasmic-derived RelA compared with NS BOECs. Sickle BOECs also had heightened responses to inflammatory stimuli compared with NS BOECs, as shown by increased nuclear RelA, and intracellular adhesion molecule (ICAM) response to TNFalpha/IL1beta stimulation. Multiple control points in RelA signaling were associated with risk of childhood stroke. The ratio of proinflammatory factor RelA to anti-inflammatory factor KLF2 was greater in BOECs from AR donors than NS donors. Group risk of childhood stroke with SCA was greatest among individuals who exhibited increased expression of proinflammatory transcription factors and decreased expression of transcription factors that suppress inflammation.

Blood outgrowth endothelial cell migration and trapping in vivo: a window into gene therapy.

Human blood outgrowth endothelial cells (hBOECs) may be useful delivery cells for gene therapy. hBOECs have high expansion capacity and a stable phenotype. If incorporated into blood vessels, hBOECs could release therapeutic agents directly into the bloodstream. However, little is known about the lodging and homing of hBOECs in vivo. We examined the homing patterns of hBOECs in mice and explored extending cell-based factor VIII (FVIII) gene therapy from mice to larger animals. hBOECs were injected into NOD/SCID mice to determine where they localize, how localization changes over time, and if there were toxic effects on host organs. The presence of hBOECs in mouse organs was determined by quantitative polymerase chain reaction (qPCR) and immunofluorescence microscopy. hBOECs lodged most notably in mouse lungs at 3 h, but by 24 h, no differences were observed among 9 organs. The longevity of hBOECs was assessed up to 7 months in vivo. hBOECs expanded well and then reached a plateau in vivo. hBOECs from older cultures expanded equally well in vivo as younger hBOECs. hBOECs caused no noticeable organ toxicity up to 3 days after injection. When mice were pretreated with antibodies to E-selectin, P-selectin, or anti-alpha4 integrin prior to hBOEC injection, the number of hBOECs in lungs at 3 h was decreased. Preliminary studies that infused hemophilic dogs with autologous canine BOECs that overexpressed FVIII (B-domain deleted) showed improvement in whole blood clotting times (WBCTs). In conclusion, the survivability, expandability, and lack of toxicity of BOECs in vivo indicate that they may be valuable host cells for gene therapy.