Gene transfer in vivo with DNA-liposome complexes: lack of autoimmunity and gonadal localization.

Direct gene transfer into localized arterial segments can be performed in vivo by transfection with DNA-liposome complexes. This technique holds promise for the treatment of human diseases, including malignancy and cardiovascular disorders. We have previously characterized the potential toxicity of this form of treatment in mice in vivo (Stewart et al., 1992). In this report, we examined two issues relevant to long-term expression of foreign recombinant genes: (i) the potential for autoimmune damage to major organs and (ii) DNA localization in gonadal tissue. Autoimmunity and toxicity of allogeneic major histocompatibility (MHC) gene transfer was assessed in mice after induction of an immune response to a recombinant murine class I MHC gene by direct gene transfer in vivo. Histological examination of brain, heart, lung, liver, kidney, spleen, and skeletal muscle revealed no clinically significant immunopathology or organ damage. The toxicity of gene delivery by DNA liposomes was also analyzed in pigs and rabbits in vivo. No histopathology was observed following the introduction of plasmids encoding several different gene products, and analysis of serum following DNA liposome delivery revealed no abnormalities of serum biochemical parameters. The potential for transfer of recombinant DNA into testes and ovary in animals was evaluated by the polymerase chain reaction. Although evidence of recombinant plasmid was consistently observed in transfected, but not untransfected, arterial sites and occasionally in lung, kidney, spleen, and liver, no plasmid DNA was detected in testes or ovary. These studies suggest that uptake of recombinant DNA following direct gene transfer by liposomal transfection in major organs is not associated with autoimmunity, toxicity, or gonadal localization.(ABSTRACT TRUNCATED AT 250 WORDS)

Gene transfer in vivo with DNA-liposome complexes: safety and acute toxicity in mice.

DNA can be introduced into a variety of cell types after formation of liposomal complexes with cationic lipids. In this report, conditions have been established to optimize the production of DNA-liposome complexes that efficiently transfect cells. The safety and toxicity of this method of gene delivery have been assessed after in vivo administration, either by intravenous or direct intratumor injection. Nine to eleven days after intravenous injection, DNA was found primarily in heart and lung tissue by PCR analysis. No abnormalities were evident from histologic examination of tissue, examination of tissue-specific serum enzymes, routine biochemical parameters, or electrocardiographic monitoring. DNA-liposome complexes can therefore be used for the delivery of recombinant genes in vivo with minimal toxicity.

Safety and short-term toxicity of a novel cationic lipid formulation for human gene therapy.

Among the potential nonviral vectors for human gene therapy are DNA-liposome complexes. In a recent clinical study, this delivery system has been utilized. In this report, a novel cationic lipid, dimyristyloxypropyl-3-dimethyl-hydroxyethyl ammonium (DMRIE), has been substituted into the DNA-liposome complex with dioleoyl phosphatidylethanolamine (DOPE), which both improves transfection efficiencies and allows increased doses of DNA to be delivered in vivo. The safety and toxicity of this DNA-liposome complex has been evaluated in two species, mice and pigs. The efficacy of DMRIE/DOPE in inducing an antitumor response in mice after transfer of a foreign MHC has been confirmed. No abnormalities were detected after administration of up to 1,000-fold higher concentrations of DNA and lipid than could be tolerated in vivo previously. Examination of serum biochemical enzymes, pathologic examination of tissue, and analysis of cardiac function in mice and pigs revealed no toxicities related to this treatment. This improved cationic lipid formulation is well-tolerated in vivo and could therefore allow higher dose administration and potentially greater efficiency of gene transfer for gene therapy.

Direct gene transfer for the understanding and treatment of human disease.

Direct gene transfer has been used to develop molecular genetic interventions for acquired diseases in several animal models. Through the use of intravascular catheters or anatomically localized injection of DNA liposome complexes, specific tissues can be transduced with recombinant genes. Several promising applications of this method for the study of vascular biology have been demonstrated by direct gene transfer into arteries in vivo. Delivery, via catheter, of genes that modulate the thrombogenic or proliferative properties of vascular cells may someday provide therapy for stenotic lesions of atherosclerosis or following angioplasty. Cancer is another acquired disorder in which direct gene transfer may improve the efficacy of treatment. Introduction of class I MHC or cytokine genes with antitumor or immunostimulatory effects have demonstrated promise in animal models. Direct transfer of an allogeneic class I MHC gene into tumors in vivo induces a CD8+ CTL response against weak antigens on poorly immunogenic tumors. The efficacy of this antitumor response can be augmented to induce regression of actively growing established tumors. Additional strategies, such as intratumoral delivery of combinations of multiple cytokine and MHC genes, may serve to improve the antitumor response. A clinical gene therapy protocol is underway to analyze the safety and efficacy of DNA liposome-mediated gene transfer in humans. Development of improved gene delivery systems and introduction of recombinant genes into visceral tumors by intravascular catheter will extend the application of direct gene transfer to immunotherapy of malignancies. These clinical trials of direct gene transfer will help to develop new treatment strategies for human diseases.

Allogeneic class I major histocompatibility complex gene transfer in murine neuroblastoma in vivo.

In vivo intratumoral gene transfer of allogeneic class I major histocompatibility complex (MHC) genes augments the immune response against weak tumor antigens. In this study, mice inoculated with the allogeneic MHC molecule (H-2Kb), had transduced-murine neuroblastoma C1300S3 cells showed prolonged survival relative to non-transduced or neo transduced tumors (p < 0.005). Interestingly, direct in vivo gene transfer of H-2Kb plasmid DNA complexed with HVJ-liposomes into S3 tumors was highly efficient, resulting in transduction of 8% of the interstitial cells within the tumor but rarely within tumor cells. Regression of established tumors and prolonged survival occurred in 50% of mice injected with H-2Kb, in contrast to no tumor regression in mice receiving control plasmid (p < 0.005). This study concludes that interstitial cells could serve as an important target of intratumoral gene transfer, and further that HVJ-liposome complexes could be a vehicle for in vivo gene transfer.

Immunotherapy of malignancy by in vivo gene transfer into tumors.

The immune system confers protection against a variety of pathogens and contributes to the surveillance and destruction of neoplastic cells. Several cell types participate in the recognition and lysis of tumors, and appropriate immune stimulation provides therapeutic effects in malignancy. Foreign major histocompatibility complex (MHC) proteins also serve as a potent stimulus to the immune system. In this report, a foreign MHC gene was introduced directly into malignant tumors in vivo in an effort to stimulate tumor rejection. In contrast to previous attempts to induce tumor immunity by cell-mediated gene transfer, the recombinant gene was introduced directly into tumors in vivo. Expression of the murine class I H-2Ks gene within the CT26 mouse colon adenocarcinoma (H-2Kd) or the MCA 106 fibrosarcoma (H-2Kb) induced a cytotoxic T-cell response to H-2Ks and, more importantly, to other antigens present on unmodified tumor cells. This immune response attenuated tumor growth and caused complete tumor regression in many cases. Direct gene transfer in vivo can therefore induce cell-mediated immunity against specific gene products, which provides an immunotherapeutic effect for malignancy, and potentially can be applied to the treatment of cancer and infectious diseases in man.

Generation of therapeutic T-lymphocytes after in vivo tumor transfection with an allogeneic class I major histocompatibility complex gene.

In an effort to enhance the generation of tumor-reactive T-lymphocytes for adoptive immunotherapy, we examined the effects of in vivo transfection of an allogeneic major histocompatibility complex (MHC) class I gene (H-2Ks) of the poorly immunogenic B16BL6 (BL6) melanoma of H-2b origin. Cells from lymph nodes (LNs) draining these tumors after transfection were assessed in adoptive immunotherapy experiments for tumor reactivity after sequential activation with anti-CD3 monoclonal antibody (mAb) followed by culture in interleukin (IL)-2. H-2Ks lipofection of progressively growing BL6 subcutaneous tumors did not reduce tumorigenicity. However, in vivo lipofection of BL6 by intratumor inoculation or admixture of H-2Ks cDNA/liposome complexes and tumor cells prior to inoculation resulted in enhanced development of sensitized T-lymphocytes in the draining LN, which mediated the reduction of the numbers of established 3-day parental lung metastases in six of six experiments. In subsequent studies, in vivo transfection of BL6 with naked H-2Ks cDNA was found to be more effective than lipofection in eliciting sensitized T-cells in the draining LN. Admixture of liposomes alone or control plasmid DNA did not have an adjuvant effect similar to H-2Ks cDNA. Relative tumor transfection efficiency was assessed by an indirect assay with the chloramphenicol acetyltransferase (CAT) reporter gene. BL6 tumors were more efficiently transfected by intratumor inoculation with naked cDNA compared with lipofection. In summary, in vivo allogenization of the poorly immunogenic BL6 tumor resulted in enhanced generation of therapeutic T-cells effective in the treatment of parental tumor.

Direct gene transfer with DNA-liposome complexes in melanoma: expression, biologic activity, and lack of toxicity in humans.

Direct gene transfer offers the potential to introduce DNA encoding therapeutic proteins to treat human disease. Previously, gene transfer in humans has been achieved by a cell-mediated ex vivo approach in which cells from the blood or tissue of patients are genetically modified in the laboratory and subsequently returned to the patient. To determine the feasibility and safety of directly transferring genes into humans, a clinical study was performed. The gene encoding a foreign major histocompatibility complex protein, HLA-B7, was introduced into HLA-B7-negative patients with advanced melanoma by injection of DNA-liposome complexes in an effort to demonstrate gene transfer, document recombinant gene expression, and determine the safety and potential toxicity of this therapy. Six courses of treatment were completed without complications in five HLA-B7-negative patients with stage IV melanoma. Plasmid DNA was detected within biopsies of treated tumor nodules 3-7 days after injection but was not found in the serum at any time by using the polymerase chain reaction. Recombinant HLA-B7 protein was demonstrated in tumor biopsy tissue in all five patients by immunochemistry, and immune responses to HLA-B7 and autologous tumors could be detected. No antibodies to DNA were detected in any patient. One patient demonstrated regression of injected nodules on two independent treatments, which was accompanied by regression at distant sites. These studies demonstrate the feasibility, safety, and therapeutic potential of direct gene transfer in humans.