Improvement of mouse beta-thalassemia by electrotransfer of erythropoietin cDNA.

OBJECTIVE: A new intramuscular DNA electrotransfer method for erythropoietin (EPO) expression was evaluated in the natural mouse model of human beta-thalassemia (Hbb-thal1) in terms of its ability to reverse the anemia and improve the thalassemic features of erythrocytes. MATERIALS AND METHODS: Intramuscular injection of small amounts of a plasmid encoding mouse EPO, immediately followed by controlled electric pulses, was used. RESULTS: This procedure induced very high hematocrit levels in beta-thalassemic mice compared to nonelectrotransferred mice. The hematocrit increase was dose dependent, still increased 4 months after injection of plasmid DNA, and associated with a high transgenic EPO blood level in all mice (up to 2500 mU/mL of plasma). EPO gene electrotransfer not only led to a long-lasting and dose-dependent increase in the hematocrit but also to a 100% increase in the lifespan of erythrocytes of thalassemic mice. This was related to a nearly complete reestablishment of alpha/beta globin chain balance, as demonstrated by a marked decrease in unpaired alpha globin chain. Eight months after the first electrotransfer of pCMV-mEPO plasmid, reinjection of the same construct raised the hematocrit to a level close to that observed following the first electrotransfer. CONCLUSION: This is the first description of the use of plasmid DNA to achieve long-term improvement in a mouse model of a human genetic disorder.

Efficient DNA electrotransfer into tumors.

DNA transfer to tumor cells of antiproliferative genes or of genes coding for immunomodulatory or antiangiogenic products is a promising approach for cancer therapy. However, intratumoral injection of plasmid DNA either naked or associated to chemical vectors results in a low level of gene expression. Recently, electrically mediated gene transfer has been described to strongly increase foreign gene expression in various tissues. We confirm and extend these observations using long duration electric pulses for several murine and human tumor models, using a reporter gene encoding for luciferase. After plasmid intratumoral injection, eight electric pulses of 20-ms duration were delivered at a frequency of 1 Hz through two flat parallel stainless steel electrodes placed at each side of the tumor. Optimal gene transfer was obtained using a voltage-to-distance ratio comprising between 400 and 600 V/cm. Two days after electrotransfer, we obtained a 10- to 1200-fold increase in gene expression over the naked DNA injection alone, leading to the expression of 0.6 to 300 ng luciferase per tumor. Moreover, histological results using beta-Gal reporter gene injected in H1299 tumor indicate that electrotransfer leads to a substantial increase in the percentage of beta-Gal positive cells. These results confirm the wide potential of electrotransfer for gene therapy in cancer.

Stellar (n,gamma) cross section of 62Ni.

The 62Ni(n,gamma)63Ni(t(1/2)=100+/-2 yr) reaction plays an important role in the control of the flow path of the slow neutron-capture (s) nucleosynthesis process. We have measured for the first time the total cross section of this reaction for a quasi-Maxwellian (kT=25 keV) neutron flux. The measurement was performed by fast-neutron activation, combined with accelerator mass spectrometry to detect directly the 63Ni product nuclei. The experimental value of 28.4+/-2.8 mb, fairly consistent with a recent calculation, affects the calculated net yield of 62Ni itself and the whole distribution of nuclei with 62

Erythropoietin secretion and physiological effect in mouse after intramuscular plasmid DNA electrotransfer.

BACKGROUND: Direct intramuscular plasmid DNA injection has recently been proposed for erythropoietin therapy, as an alternative to either systemic injection of recombinant erythropoietin or the use of viral vectors for erythropoietin gene transfer. However, direct intramuscular plasmid injection has so far been hampered by low efficiency and high interindividual variability. METHOD: We explored the use of a new method termed 'intramuscular electrotransfer' for erythropoietin gene expression in the mouse. This method is based on intramuscular plasmid injection followed by application of appropriate electric pulses. RESULTS: Intramuscular plasmid electrotransfer in mouse leg led to an increase of approximately 10- to 100-fold in circulating murine erythropoietin level, as compared to naked DNA alone. Using electrotransfer, as little as 1 microgram of an erythropoietin encoding plasmid was sufficient to induce an increase in mouse hematocrit, from 47% up to 80%. This hematocrit increase was stable for at least two months. Moreover, interindividual hematocrit variability was markedly reduced by electrotransfer, as compared with naked DNA injection. CONCLUSION: In vivo electrotransfer appears to be a convenient method for obtaining high erythropoietin expression in mice, and it could also be used for the expression of other secreted therapeutic proteins.

Dimeric erythropoietin fusion protein with enhanced erythropoietic activity in vitro and in vivo.

High doses of recombinant human erythropoietin (rhEpo) are required for the treatment of chronic anemia. Thus, it is clear that therapy for chronic anemia would greatly benefit from an erythropoietin derivative with increased erythropoietic activity rather than the native endogenous hormone. In this report, the activity of a human Epo-Epo dimer protein, obtained by recombinant technology, is described and compared with its Epo monomer counterpart produced under identical conditions. Although monomer Epo and dimer Epo-Epo had similar pharmacokinetics in normal mice, the increase in hematocrit value was greater with the dimer than with the monomer. Moreover, in clonogenic assays using CD34(+) human hematopoietic cells, the human dimer induced a 3- to 4-fold-greater proliferation of erythroid cells than the monomer. Controlled secretion of dimeric erythropoietin was achieved in beta-thalassemic mice by in vivo intramuscular electrotransfer of a mouse Epo-Epo plasmid containing the tetO element and of a plasmid encoding the tetracycline controlled transactivator tTA. Administration of tetracycline completely inhibited the expression of the mEpo dimer. On tetracycline withdrawal, expression of the Epo-Epo dimer resumed, thereby resulting in a large and sustained hematocrit increase in beta-thalassemic mice. No immunologic response against the dimer was apparent in mice because the duration of the hematocrit increase was similar to that observed with the monomeric form of mouse erythropoietin. (Blood. 2001;97:3776-3782)

Oxygen tension and a pharmacological switch in the regulation of transgene expression for gene therapy.

BACKGROUND: The combination of physiologically and pharmacologically controlled elements may provide a means to ensure both the regulation and the safety of transgene expression--two major goals in gene therapy. METHODS: A two-gene modulation system was developed that uses the following three levels of control: (i) the hypoxia-responsive element directing the transcription of the tetracycline-controlled transactivator (tTA); (ii) part of the oxygen-degradation domain limiting the production of tTA in normoxia; and (iii) the tetracycline switch of the transactivator activity (the tet-off system). RESULTS: This triple-control system allowed high expression of the gene of interest (luciferase or erythropoietin) by transfected cells upon hypoxia and low expression under normoxia or in the presence of tetracycline. This control of transgene expression was also obtained in mouse tumors. CONCLUSIONS: This multiple-control system is of interest for spatially restricting transgene expression into hypoxic tumors, and for finely adjusting the expression level of a therapeutic protein to the oxygen supply in medical applications such as neoangiogenesis or the erythropoietin-mediated treatment of anemia.

High-level protein secretion into blood circulation after electric pulse-mediated gene transfer into skeletal muscle.

Numerous diseases are linked to the absence or insufficient concentration of a specific plasma protein. Gene transfer is an appealing strategy for correction of such diseases. We report high and sustained plasma secretion of human secreted alkaline phosphatase and of human Factor IX by skeletal muscle of mice. This was obtained by delivering square-wave unipolar electric pulses of low field strength (200 V/cm) and long duration (20 ms) to skeletal muscle previously injected with plasmid DNA encoding for the secreted protein. This intramuscular electrotransfer method allows 30- to 150-fold increase in reporter protein secretion, compared to simple plasmid DNA injection. This increase allows one to obtain values of up to 2200 ng/ml of a reporter circulating protein. Moreover, this high level of secretion remains stable for several months.