Radioprotective gene therapy.

Control of cancer by irradiation therapy alone or in conjunction with combination chemotherapy is often limited by organ specific toxicity. Ionizing irradiation toxicity is initiated by damage to normal tissue near the tumor target and within the transit volume of radiotherapy beams. Irradiation-induced cellular, tissue, and organ damage is mediated by acute effects, which can be dose limiting. A latent period follows recovery from the acute reaction, then chronic irradiation fibrosis (late effects) pose a second cause of organ failure. We have developed the technology for radioprotective gene therapy using the transgene for the antioxidant manganese superoxide dismutase, delivered to specific target organs (lung, esophagus, oral cavity, oropharynx, and bladder) using gene transfer vectors including plasmid/liposomes (PL) and adenovirus. Irradiation protection by MnSOD transgene overexpression at the cellular level has been demonstrated to be localized to the mitochondrial membrane. Using MnSOD transgene constructs lacking the mitochondrial localization leader sequence, and in other experiments attaching this localization signal to otherwise non-radioprotective cytoplasmic Cu/ZnSOD, mitochondrial localization has been demonstrated to be critical to protection. Organ specific injection of MnSOD-PL prior to irradiation demonstrates transgene expression for 48-72 hours, and an associated decrease in ionizing irradiation-induced expression of inflammatory cytokine mRNA and protein. Significant reduction of organ specific tissue injury has been demonstrated in several organ systems in rodent models. Application of MnSOD-PL gene therapy in the setting of fractionated chemo-radiotherapy is being tested in clinical trials for prevention of esophagitis during treatment of non-small cell carcinoma of the lung, and in prevention of mucositis during combination therapy of carcinomas of the head and neck. Encouraging results in pre-clinical models suggest that radioprotective gene therapy may facilitate dose escalation protocols to allow increases in the therapeutic ratio of cancer radiotherapy.

Modulation of radiation-induced cytokine elevation associated with esophagitis and esophageal stricture by manganese superoxide dismutase-plasmid/liposome (SOD2-PL) gene therapy.

Radiation of the esophagus of C3H/HeNsd mice with 35 or 37 Gy of 6 MV X rays induces significantly increased RNA transcription for interleukin 1 (Il1), tumor necrosis factor alpha (Tnf), interferon gamma inducing factor (Ifngr), and interferon gamma (Ifng). These elevations are associated with DNA damage that is detectable by a comet assay of explanted esophageal cells, apoptosis of the esophageal basal lining layer cells in situ, and micro-ulceration leading to dehydration and death. The histopathology and time sequence of events are comparable to the esophagitis in humans that is associated with chemoradiotherapy of non-small cell lung carcinoma (NSCLC). Intraesophageal injection of clinical-grade manganese superoxide dismutase-plasmid/liposome (SOD2-PL) 24 h prior to irradiation produced an increase in SOD2 biochemical activity in explanted esophagus. An equivalent therapeutic plasmid weight of 10 microgram ALP plasmid in the same 500 microliter of liposomes, correlated to around 52-60% of alkaline phosphatase-positive cells in the squamous layer of the esophagus at 24 h. Administration of SOD2-PL prior to irradiation mediated a significant decrease in induction of cytokine mRNA by radiation and decreased apoptosis of squamous lining cells, micro-ulceration, and esophagitis. Groups of mice receiving 35 or 37 Gy esophageal irradiation by a technique protecting the lungs and treating only the central mediastinal area were followed to assess the long-term effects of radiation. SOD2-PL-treated irradiated mice demonstrated a significant decrease in esophageal wall thickness at day 100 compared to irradiated controls. Mice with orthotopic thoracic tumors composed of 32D-v-abl cells that received intraesophageal SOD2-PL treatment showed transgenic mRNA in the esophagus at 24 h, but no detectable human SOD2 transgene mRNA in explanted tumors by nested RT-PCR. These data provide support for translation of this strategy of SOD2-PL gene therapy to studies leading to a clinical trial in fractionated irradiation to decrease the acute and chronic side effects of radiation-induced damage to the esophagus.

Intratracheal injection of manganese superoxide dismutase (MnSOD) plasmid/liposomes protects normal lung but not orthotopic tumors from irradiation.

To determine whether intratracheal (IT) lung protective manganese superoxide-plasmid/liposomes (MnSOD-PL) complex provided 'bystander' protection of thoracic tumors, mice with orthotopic Lewis lung carcinoma-bacterial beta-galactosidase gene (3LL-LacZ) were studied. There was no significant difference in irradiation survival of 3LL-LacZ cells irradiated, then cocultured with MnSOD-PL-treated compared with control lung cells (D0 2.022 and 2.153, respectively), or when irradiation was delivered 24 h after coculture (D0 0.934 and 0.907, respectively). Tumor-bearing control mice showed 50% survival at 18 days and 10% survival at 21 days. Mice receiving liposomes with no insert or LacZ-PL complex plus 18 Gy had 50% survival at 22 days, and a 20% and 30% survival at day 50, respectively. Mice receiving MnSOD-PL complex followed by 18 Gy showed prolonged survival of 45% at 50 days after irradiation (P < 0.001). Nested RT-PCR assay for the human MnSOD transgene demonstrated expression at 24 h in normal lung, but not in orthotopic tumors. Decreased irradiation induction of TGF-beta1, TGF-beta2, TGF-beta3, MIF, TNF-alpha, and IL-1 at 24 h was detected in lungs, but not orthotopic tumors from MnSOD-PL-injected mice (P < 0.001). Thus, pulmonary radioprotective MnSOD-PL therapy does not provide detectable 'bystander' protection to thoracic tumors.

Manganese superoxide dismutase-plasmid/liposome (MnSOD-PL) administration protects mice from esophagitis associated with fractionated radiation.

Intraesophageal administration of manganese superoxide dismutase-plasmid/liposome (MnSOD-PL) prior to single fraction radiation has been shown to protect mice from lethal esophagitis. In our study, C3H/HeNsd mice received fractionated radiation in two protocols: (i) 18 Gy daily for four days with MnSOD-PL administration 24 hr prior to the first and third fraction, or (ii) 12 Gy daily for six days with MnSOD-PL 24 hr prior to the first, third, and fifth fraction. Control radiated mice received either no liposomes only or LacZ (bacterial beta-galactosidase gene)-plasmid/liposome (LacZ-PL) by the same schedules. We measured thiol depletion and lipid peroxidation (LP) in whole esophagus and tested the effectiveness of a new plasmid, hemagglutinin (HA) epitope-tagged MnSOD (HA-MnSOD). In fractionation protocols, mice receiving MnSOD-PL, but not LacZ-PL (200 microl of plasmid/liposomes containing 200 microg of plasmid DNA), showed a significant reduction in morbidity, decreased weight loss, and improved survival. Four and seven days after 37 Gy single fraction radiation, the esophagus demonstrated a significant increase in peroxidized lipids and reduction in overall antioxidant levels, reduced thiols, and decreased glutathione (GSH). These reductions were modulated by MnSOD-PL administration. The HA-MnSOD plasmid product was detected in the basal layers of the esophageal epithelium 24 hr after administration and provided significant radiation protection compared to glutathione peroxidase-plasmid/liposome (GPX-PL), or liposomes containing MnSOD protein, vitamin E, co-enzyme Q10, or 21-aminosteroid. Thus, MnSOD-PL administration significantly improved tolerance to fractionated radiation and modulated radiation effects on levels of GSH and lipid peroxidation (LP). These studies provide further support for translation of MnSOD-PL treatment into human esophageal radiation protection.

Cell phenotype specific kinetics of expression of intratracheally injected manganese superoxide dismutase-plasmid/liposomes (MnSOD-PL) during lung radioprotective gene therapy.

Intratracheal (IT) injection of manganese superoxide dismutase-plasmid/liposome (MnSOD-PL) complexes prior to whole lung irradiation of C57BL/6J mice provides significant protection from acute and chronic irradiation damage. We determined the duration of increased MnSOD biochemical activity and differential expression of a hemagglutinin (HA) epitope-tagged MnSOD transgene. HA-MnSOD-PL was IT injected at doses of 0-1000 microg, and mice were killed 1,2,3 or 4 days later. Other groups of mice were irradiated to 20 Gy to the pulmonary cavity 24 h after injection and killed at the same time points as non-irradiated mice. Both non-irradiated and irradiated groups of mice showed increased MnSOD biochemical activity with plasmid dose that plateaued at 100 microg of MnSOD plasmid DNA. In control mice, MnSOD biochemical activity decreased at 2, 3 or 4 days after injection. In irradiated mice, MnSOD biochemical activity decreased at day 2 but increased on days 3 and 4. HA-MnSOD expression decreased in broncheoalveolar macrophages and alveolar type-II cells 3 days after injection in non-irradiated and irradiated mice, but remained elevated in endothelial and epithelial cells past 4 days. The data provide a rationale for every second-day administration of intrapulmonary MnSOD-PL in clinical trials of radioprotective gene therapy. This should be sufficient to provide radioprotection during radiation treatments.