Magnetic resonance imaging and characterization of spontaneous lesions in a transgenic mouse model of tuberous sclerosis as a model for endothelial cell-based transgene delivery.

Tuberous sclerosis (TSC) is an autosomal dominant genetic disorder characterized by abnormalities in cellular migration, proliferation, and differentiation in many tissues. Benign hamartomas develop in multiple organs, believed to be caused by somatic mutation in addition to germ line mutation to cause loss of both alleles of either the TSC1 or TSC2 tumor suppressor gene, with resultant dysregulated growth due to loss of hamartin or tuberin function, respectively. This study focuses on detecting spontaneous lesions in a knockout mouse model of TSC2 by magnetic resonance imaging (MRI) and exploring the efficiency of introducing gene products into lesions, using transduced endothelial cells as gene vehicles. MRI was shown to be effective in detecting spontaneous lesions in multiple tissues as a means of assessing the prevalence of tumors. Tsc(2+/) heterozygous mice were screened at 12-24 months of age. MRI detected 100% of the renal lesions (cystadenomas, renal cell carcinomas) and 75% of the hepatic lesions (hemangiosarcomas), later identified by histology. Cell-mediated gene delivery was evaluated by immunohistochemical analysis of renal, hepatic, and lung lesions after intravenous delivery of MS1 mouse endothelial cells, transduced to express an enhanced form of green fluorescent protein (EGFP). Preliminary immunohistochemical analysis, using a polyclonal antibody to EGFP and a horseradish peroxidase-diaminobenzidine detection system, revealed these cells throughout liver, kidney, and lung sections from injected animals, organs that are frequently affected in TSC2 patients, as well as within the lesions themselves.

Intravascular delivery of neural stem cell lines to target intracranial and extracranial tumors of neural and non-neural origin.

The remarkable migratory and tumor-tropic capacities of neural stem cells (NSCs and/or neuroprogenitor cells) represent a potentially powerful approach to the treatment of invasive brain tumors, such as malignant gliomas. We have previously shown that whether implanted directly into or at distant sites from an experimental intracranial glioma, NSCs distributed efficiently throughout the main tumor mass and also tracked advancing tumor cells, while stably expressing a reporter transgene. As therapeutic proof-of-concept, NSCs genetically modified to produce the prodrug activating enzyme cytosine deaminase (CD), effected an 80% reduction in the resultant tumor mass, when tumor animals were treated with the systemic prodrug, 5-fluorocytosine. We now extend our findings of the tumor-tropic properties of NSCs (using a well-characterized, clonal NSC line C17.2), by investigating their capacity to target both intracranial and extracranial tumors, when administered into the peripheral vasculature. We furthermore demonstrate their capacity to target extracranial non-neural tumors such as prostate cancer and malignant melanoma. Well-characterized NSC lines (lacZ and/or CD-positive) were injected into the tail vein of adult nude mice with established experimental intracranial and/or subcutaneous flank tumors of neural and non-neural origin. The time course and distribution of NSCs within the tumor and internal organs was assessed in various models. Resulting data suggest that NSCs can localize to various tumor sites when injected via the peripheral vasculature, with little accumulation in normal tissues. Our findings suggest the novel use of intravascularly administered NSCs as an effective delivery vehicle to target and disseminate therapeutic agents to invasive tumors of neural and nonneural origin, both within and outside of the brain.