Abstract: The present invention provides a DNA molecule comprising a radiation responsive enhancer-promoter operatively linked to an encoding region that encodes at least one polypeptide. An encoding region can comprise a single encoding sequence for a polypeptide or two or more encoding sequences encoding DNA binding, activation or repression domains of a transcription factor. Processes for regulating polypeptide expression and inhibiting tumor growth using such DNA molecules are also provided.

Abstract: A method for identifying a molecule that binds an irradiated tumor in a subject and molecules identified thereby. The method includes the steps of: (a) exposing a tumor to ionizing radiation; (b) administering to a subject a library of diverse molecules; and (c) isolating from the tumor one or more molecules of the library of diverse molecules, whereby a molecule that binds an irradiated tumor is identified. Also provided are therapeutic and diagnostic methods using targeting ligands that bind an irradiated tumor.

Abstract: The identification of radiation-inducible genes by isolating RNA from irradiated cell cultures and then hybridizing the isolated RNA to nucleic acid sequences from an organism of interest (e.g. mammals such as mice and human beings); a method for x-ray guided drug delivery using a targeting ligand that specifically recognizes a radiation-inducible RNA target molecule; and magnetic dispersion of an active agent, such as the dispersion of a genetic construct within a tumor.

Abstract: A halogen-labeled gene therapy construct that includes halogen-labeled nucleic acids, methods for preparing a halogenated gene therapy construct, and methods for in vivo imaging of the same. Also provided are methods for non-invasive drug detection in a subject using a labeled antibody that recognizes a heterologous antigen conjugated to, encoded by, or otherwise associated with the drug.

Abstract: A method for increasing radiosensitivity of a tumor in a subject via administration of a VEGF-R2 inhibitor to a tumor in a subject. Also provided are methods for delaying tumor growth and for inhibiting tumor blood vessel growth via administration of a VEGF-R2 inhibitor.

Abstract: The present invention provides a DNA molecule comprising a radiation responsive enhancer-promoter operatively linked to an encoding region that encodes at least one polypeptide. An encoding region can comprise a single encoding sequence for a polypeptide or two or more encoding sequences encoding DNA binding, activation or repression domains of a transcription factor. Processes for regulating polypeptide expression and inhibiting tumor growth using such DNA molecules are also provided.

Abstract: A method for identifying a molecule that binds an irradiated tumor in a subject and molecules identified thereby. The method includes the steps of: (a) exposing a tumor to ionizing radiation; (b) administering to a subject a library of diverse molecules; and (c) isolating from the tumor one or more molecules of the library of diverse molecules, whereby a molecule that binds an irradiated tumor is identified. Also provided are therapeutic and diagnostic methods using targeting ligands that bind an irradiated tumor.

Abstract: A signaling pathway is identified that involves the activation of phospholipase A2 and protein kinase C in human cells, which in turn confers x-ray induction of the tumor necrosis factor &agr; (TNF) gene. Inhibition of phospholipase A2 abolishes radiation-mediated arachidonate production, as well as the subsequent activation of protein kinase C and TNF gene expression. These phospholipase A2 inhibitors may be used to ameliorate the adverse-effects of radiotherapy associated with TNF production.

Abstract: The present invention provides a DNA molecule comprising a radiation responsive enhancer-promoter operatively linked to an encoding region that encodes at least one polypeptide. An encoding region can comprise a single encoding sequence for a polypeptide or two or more encoding sequences encoding DNA binding, activation or repression domains of a transcription factor. Processes for regulating polypeptide expression and inhibiting tumor growth using such DNA molecules are also provided.

Abstract: A method of delivering an active agent to a target tissue, particularly neoplastic tissue, vascular anomaly or tumor tissue, in a vertebrate subject. The method includes the steps of exposing the target tissue to ionizing radiation; and administering a delivery vehicle to the vertebrate subject before, after, during, or combinations thereof, exposing the target tissue to the ionizing radiation. The delivery vehicle includes the active agent and delivers the agent to the target tissue. Exemplary delivery vehicles include platelets; leukocytes; proteins or peptides which bind activated platelets; antibodies which bind activated platelets; microspheres coated with proteins or peptides which bind activated platelets; liposomes conjugated to platelets, leukocytes, proteins or peptides which bind activated platelets, or antibodies which bind activated platelets; and combinations thereof.

Abstract: The present invention provides a DNA molecule comprising a radiation responsive enhancer-promoter operatively linked to an encoding region that encodes at least one polypeptide. An encoding region can comprise a single encoding sequence for a polypeptide or two or more encoding sequences encoding DNA binding, activation or repression domains of a transcription factor. Processes for regulating polypeptide expression and inhibiting tumor growth using such DNA molecules are also provided.

Abstract: Disclosed are a variety of compositions and methods for use in specifically targeting the L-selectin or preferably, the E-selectin marker following its cell surface induction, e.g., using ionizing radiation, in tumor vasculature endothelial cells. The compositions and methods described are suitable for use in the delivery of selected agents to tumor vasculature, as may be used in the diagnosis aid therapy of solid tumors.

Abstract: This invention relates to genetic constructs which comprise an enhancer-promoter region which is responsive to radiation, and at least one structural gene whose expression is controlled by the enhancer-promoter. This invention also relates to methods of destroying, altering, or inactivating cells in target tissue by delivering the genetic constructs to the cells of the tissues and inducing expression of the structural gene or genes in the construct by exposing the tissues to ionizing radiation. This invention is useful for treating patients with cancer, clotting disorders, myocardial infarction, and other diseases for which target tissues can be identified and for which gene expression of the construct within the target tissues can alleviate the disease or disorder.

Abstract: The present invention provides a DNA molecule comprising a radiation responsive enhancer-promoter operatively linked to an encoding region that encodes at least one polypeptide. An encoding region can comprise a single encoding sequence for a polypeptide or two or more encoding sequences encoding DNA binding, activation or repression domains of a transcription factor. Processes for regulating polypeptide expression and inhibiting tumor growth using such DNA molecules are also provided.

Abstract: Treatment of cells with ionizing radiation is associated with the production of arachidonic acid. Inhibition of phospholipase A2 abolishes radiation-mediated arachidonate production, protein kinase C induction and tumor necrosis factor gene expression. The addition of inhibitors of lipoxygenase, such as ketoconazole, prior to irradiation reduces the expression of of tumor necrosis factor while maintaining the expression of other radiation inducible genes, such as Egr-1 and c-jun. In contrast, indomethacin, an inhibitor of cyclooxygenase, enhanced the expression of tumor necrosis factor as well as other radiation inducible genes. The results show that lipoxygenase inhibitors are useful in the treatment of radiation-induced mucositis, dermatitis, pneumonitis, proctitis, and esophagitis. which may be due to the production of cytokines such as TNF.

Abstract: This invention relates to genetic constructs which comprise an enhancer-promoter region which is responsive to radiation, and at least one structural gene whose expression is controlled by the enhancer-promoter. This invention also relates to methods of destroying, altering, or inactivating cells in target tissue by delivering the genetic constructs to the cells of the tissues and inducing expression of the structural gene or genes in the construct by exposing the tissues to ionizing radiation. This invention is useful for treating patients with cancer, clotting disorders, myocardial infarction, and other diseases for which target tissues can be identified and for which gene expression of the construct within the target tissues can alleviate the disease or disorder.