Abstract: Polynucleotides encoding DADD protein are also disclosed, along with vectors, host cells, and methods of making DADD protein. Methods of identifying inhibitors of DADD death domain binding and inhibitors identified by such methods are also disclosed.

Abstract: The present invention relates to the three dimensional solution structure of the N-terminal domain of TNFR-1 associated death domain protein (“N-TRADD”), as well as the identification and characterization of a C-TRAF2 binding active site of N-TRADD. Also provided for by the present invention are methods of utilizing the three dimensional structures for the design and selection of potent and selective inhibitors of TNF signaling pathways.

Abstract: The invention provides isolated protein kinase polypeptides homologous to Kinase Suppressor of Ras (KSR), and the isolated nucleic acid molecules that encode these polypeptides. The novel polypeptides and nucleic acid molecules of the invention are termed KSR-2. The invention also provides genetically engineered expression vectors, host cells, and transgenic animals comprising the novel nucleic acid molecules of the invention. The invention additionally provides antisense and RNAi molecules to the nucleic acid molecules of the invention. The invention further provides inhibitors, activators, and antibodies capable of binding to the protein kinase polypeptides of the invention. The invention also provides for the regulation of Cot/Tp12-mediated cellular functions, such as ERK and NF-&kgr;B activation, as well as IL-8 production, through the use of the nucleic acid and protein kinase polypeptide molecules of the invention.

Abstract: The invention relates to compositions and methods comprising lymphotoxin-beta receptor (LT&bgr;R) modulators, which activate or inhibit LT&bgr;R signaling. LT&bgr;R modulators are useful for treating lymphocyte mediated immunological diseases and cancer, and more particularly, for regulating mitochondrial-mediated apoptosis. This invention relates to soluble forms of the LT&bgr;R complex proteins that act as LT&bgr;R activating or inhibiting agents. This invention also relates to the use of soluble molecules, directed against either the LT&bgr;R, its ligands, LIGHT and LT&bgr;1&agr;2, or its intracellular binding partners, that function to regulate LT&bgr;R signaling. A novel screening method for selecting soluble receptors, antibodies and other agents that modulate LT&bgr;R signaling is provided.

Abstract: The present invention relates to the three dimensional solution structure of receptor interacting protein dead domain (RIP DD), as well as the identification and characterization of various binding active sites of RIP DD. Also provided for by the present invention are methods of utilizing the three dimensional structure for the design and selection of potent and selective inhibitors of TNF signaling pathways.

Abstract: Novel IL-1-R intracellular ligand proteins are disclosed. Polynucleotides encoding the IL-1-R intracellular ligand protein are also disclosed, along with vectors, host cells, and methods of making the IL-1-R intracellular ligand protein. Pharmaceutical compositions containing the IL-1-R intracellular ligand protein, methods of treating inflammatory conditions, and methods of inhibiting IL-1-R intracellular domain binding are also disclosed. Methods of identifying inhibitors of IL-1-R intracellular domain binding and inhibitors identified by such methods are also disclosed.

Abstract: Novel TNF receptor death domain (“TNF-R1-DD”) ligand proteins are disclosed. Polynucleotides encoding the TNF-R1-DD ligand protein are also disclosed, along with vectors, host cells, and methods of making the TNF-R1-DD ligand protein. Pharmaceutical compositions containing the TNF-R1-DD ligand protein, methods of treating inflammatory conditions, and methods of inhibiting TNF-R death domain binding are also disclosed. Methods of identifying inhibitors of TNF-R death domain binding and inhibitors identified by such methods are also disclosed.

Abstract: The present invention relates to the three dimensional solution structure of the N-terminal domain of TNFR-1 associated death domain protein (“N-TRADD”), as well as the identification and characterization of a C-TRAF2 binding active site of N-TRADD. Also provided for by the present invention are methods of utilizing the three dimensional structures for the design and selection of potent and selective inhibitors of TNF signaling pathways.

Abstract: The present invention relates to the three dimensional solution structure of tumor necrosis factor receptor 1 death domain (TNFR-1 DD), as well as the identification and characterization of various binding active sites of TNFR-1 DD. Also provided for by the present invention are methods of utilizing the three dimensional structure for the design and selection of potent and selective inhibitors of TNF signaling pathways.

Abstract: Novel TNF receptor death domain (“TNF-R1-DD”) ligand proteins are disclosed. Polynucleotides encoding the TNF-R1-DD ligand protein are also disclosed, along with vectors, host cells, and methods of making the TNF-R1-DD ligand protein. Pharmaceutical compositions containing the TNF-R1-DD ligand protein, methods of treating inflammatory conditions, and methods of inhibiting TNF-R death domain binding are also disclosed. Methods of identifying inhibitors of TNF-R death domain binding and inhibitors identified by such methods are also disclosed.

Abstract: Novel IL-1-R intracellular ligand proteins are disclosed. Polynucleotides encoding the IL-1-R intracellular ligand protein are also disclosed, along with vectors, host cells, and methods of making the IL-1-R intracellular ligand protein. Pharmaceutical compositions containing the IL-1-R intracellular ligand protein, methods of treating inflammatory conditions, and methods of inhibiting IL-1-R intracellular domain binding are also disclosed. Methods of identifying inhibitors of IL-1-R intracellular domain binding and inhibitors identified by such methods are also disclosed.

Abstract: Novel IL-1-R intracellular ligand proteins are disclosed. Polynucleotides encoding the IL-1-R intracellular ligand protein are also disclosed, along with vectors, host cells, and methods of making the IL-1-R intracellular ligand protein. Pharmaceutical compositions containing the IL-1-R intracellular ligand protein, methods of treating inflammatory conditions, and methods of inhibiting IL-1-R intracellular domain binding are also disclosed. Methods of identifying inhibitors of IL-1-R intracellular domain binding and inhibitors identified by such methods are also disclosed.

Abstract: Novel TNF receptor death domain ("TNF-R1-DD") ligand proteins are disclosed. Polynucleotides encoding the TNF-R1-DD ligand protein are also disclosed, along with vectors, host cells, and methods of making the TNF-R1-DD ligand protein. Pharmaceutical compositions containing the TNF-R1-DD ligand protein, methods of treating inflammatory conditions, and methods of inhibiting TNF-R death domain binding are also disclosed. Methods of identifying inhibitors of TNF-R death domain binding and inhibitors identified by such methods are also disclosed.

Abstract: Novel TNF receptor death domain ("TNF-R1-DD") ligand proteins are disclosed. Polynucleotides encoding the TNF-R1-DD ligand protein are also disclosed, along with vectors, host cells, and methods of making the TNF-R1-DD ligand protein. Pharmaceutical compositions containing the TNF-R1-DD ligand protein, methods of treating inflammatory conditions, and methods of inhibiting TNF-R death domain binding are also disclosed. Methods of identifying inhibitors of TNF-R death domain binding and inhibitors identified by such methods are also disclosed.

Abstract: Novel TNF receptor death domain ("TNF-R1-DD") ligand proteins are disclosed. Polynucleotides encoding the TNF-R1-DD ligand protein are also disclosed, along with vectors, host cells, and methods of making the TNF-R1-DD ligand protein. Pharmaceutical compositions containing the TNF-R1-DD ligand protein, methods of treating inflammatory conditions, and methods of inhibiting TNF-R death domain binding are also disclosed. Methods of identifying inhibitors of TNF-R death domain binding and inhibitors identified by such methods are also disclosed.

Abstract: Novel TNF receptor death domain ("TNF-R1-DD") ligand proteins are disclosed. Polynucleotides encoding the TNF-R1-DD ligand protein are also disclosed, along with vectors, host cells, and methods of making the TNF-R1-DD ligand protein. Pharmaceutical compositions containing the TNF-R1-DD ligand protein, methods of treating inflammatory conditions, and methods of inhibiting TNF-R death domain binding are also disclosed. Methods of identifying inhibitors of TNF-R death domain binding and inhibitors identified by such methods are also disclosed.

Abstract: Novel TNF receptor death domain ("TNF-R1-DD") ligand proteins are disclosed. Polynucleotides encoding the TNF-R1-DD ligand protein are also disclosed, along with vectors, host cells, and methods of making the TNF-R1-DD ligand protein. Pharmaceutical compositions containing the TNF-R1-DD ligand protein, methods of treating inflammatory conditions, and methods of inhibiting TNF-R death domain binding are also disclosed. Methods of identifying inhibitors of TNF-R death domain binding and inhibitors identified by such methods are also disclosed.

Abstract: Novel TNF receptor death domain ("TNF-R1-DD") ligand proteins are disclosed. Polynucleotides encoding the TNF-R1-DD ligand protein are also disclosed, along with vectors, host cells, and methods of making the TNF-R1-DD ligand protein. Pharmaceutical compositions containing the TNF-R1-DD ligand protein, methods of treating inflammatory conditions, and methods of inhibiting TNF-R death domain binding are also disclosed. Methods of identifying inhibitors of TNF-R death domain binding and inhibitors identified by such methods are also disclosed.

Abstract: Novel IL-1-R intracellular ligand proteins are disclosed. Polynucleotides encoding the IL-1-R intracellular ligand protein are also disclosed, along with vectors, host cells, and methods of making the IL-1-R intracellular ligand protein. Pharmaceutical compositions containing the IL-1-R intracellular ligand protein, methods of treating inflammatory conditions, and methods of inhibiting IL-1-R intracellular domain binding are also disclosed. Methods of identifying inhibitors of IL-1-R intracellular domain binding and inhibitors identified by such methods are also disclosed.

Abstract: Novel IL-1-R intracellular ligand proteins are disclosed. Polynucleotides encoding the IL-1-R intracellular ligand protein are also disclosed, along with vectors, host cells, and methods of making the IL-1-R intracellular ligand protein. Pharmaceutical compositions containing the IL-1-R intracellular ligand protein, methods of treating inflammatory conditions, and methods of inhibiting IL-1-R intracellular domain binding are also disclosed. Methods of identifying inhibitors of IL-1-R intracellular domain binding and inhibitors identified by such methods are also disclosed.