Abstract: The present invention is based, at least in part, on novel, unimolecular STAT3 oligonucleotide decoys exhibiting increased in vivo stability as compared to previously known decoys which are effective in inhibiting STAT3 when administered systemically. The invention is also based on pharmaceutical compositions comprising these unimolecular decoys, and methods for using these decoys in the treatment of cancer.

Abstract: The present invention is based, at least in part, on novel, unimolecular STAT3 oligonucleotide decoys exhibiting increased in vivo stability as compared to previously known decoys which are effective in inhibiting STAT3 when administered systemically.

Abstract: The present invention relates to HPV-positive as well as HPV-negative screening platforms that are highly serum-dependent, for use as HNSCC models. These HNSCC models die reproducibly in serum-deprived conditions and the introduction of driver mutations (or increased levels of the WT gene) confers enhanced cell survival and proliferation under serum deprivation. These platforms have the major advantages of allowing functional screening of mutations in relevant HNSCC models (HPV-positive and HPV-negative). In addition to oncogene screening, this model can also be used in drug discovery. Specifically, cells expressing mutations that confer increased survival can then be screened against panels of therapeutic agents to determine if the mutation(s) can predict the optimal treatment for patients whose tumors harbor the mutation(s).

Abstract: The present invention is based, at least in part, on novel, unimolecular STAT3 oligonucleotide decoys exhibiting increased in vivo stability as compared to previously known decoys which are effective in inhibiting STAT3 when administered systemically. The invention is also based on pharmaceutical compositions comprising these unimolecular decoys, and methods for using these decoys in the treatment of cancer.

Abstract: The present invention relates to HPV-positive as well as HPV-negative screening platforms that are highly serum-dependent, for use as HNSCC models. These HNSCC models die reproducibly in serum-deprived conditions and the introduction of driver mutations (or increased levels of the WT gene) confers enhanced cell survival and proliferation under serum deprivation. These platforms have the major advantages of allowing functional screening of mutations in relevant HNSCC models (HPV-positive and HPV-negative). In addition to oncogene screening, this model can also be used in drug discovery. Specifically, cells expressing mutations that confer increased survival can then be screened against panels of therapeutic agents to determine if the mutation(s) can predict the optimal treatment for patients whose tumors harbor the mutation(s).

Abstract: The present invention is based, at least in part, on novel, unimolecular STAT3 oligonucleotide decoys exhibiting increased in vivo stability as compared to previously known decoys which are effective in inhibiting STAT3 when administered systemically. The invention is also based on pharmaceutical compositions comprising these unimolecular decoys, and methods for using these decoys in the treatment of cancer.

Abstract: The present invention is based, at least in part, on novel, unimolecular STAT3 oligonucleotide decoys exhibiting increased in vivo stability as compared to previously known decoys which are effective in inhibiting STAT3 when administered systemically. The invention is also based on pharmaceutical compositions comprising these unimolecular decoys, and methods for using these decoys in the treatment of cancer.

Abstract: The present invention is based, at least in part, on novel, unimolecular STAT3 oligonucleotide decoys exhibiting increased in vivo stability as compared to previously known decoys which are effective in inhibiting STAT3 when administered systemically. The invention is also based on pharmaceutical compositions comprising these unimolecular decoys, and methods for using these decoys in the treatment of cancer.

Abstract: The present invention is based, at least in part, on novel, unimolecular STAT3 oligonucleotide decoys exhibiting increased in vivo stability as compared to previously known decoys which are effective in inhibiting STAT3 when administered systemically. The invention is also based on pharmaceutical compositions comprising these unimolecular decoys, and methods for using these decoys in the treatment of cancer.

Abstract: A nucleic acid is provided comprising an expression cassette which includes transcription control sequences of a member of a class of Pol III-transcribed genes in which no transcribed portion of the Pol III gene is required for transcription of the gene. In the expression cassette, the transcribed 5? hairpin structure of the Pol III gene is deleted. The transcription control sequences are operably linked to a sequence of an EGFR gene in an antisense orientation suitable for decreasing expression of EGFR in the cell when transcribed. Lastly, a method for decreasing expression of EGFR in cells is provided that includes the step of contacting target cells either parenterally or directly into the tumor or tissue adjacent to the tumor cells with the nucleic acid of the present invention.

Abstract: A nucleic acid is provided comprising an expression cassette which includes transcription control sequences of a member of a class of Pol III-transcribed genes in which no transcribed portion of the Pol III gene is required for transcription of the gene. In the expression cassette, the transcribed 5′ hairpin structure of the Pol III gene is deleted. The transcription control sequences are operably linked to a sequence of an EGFR gene in an antisense orientation suitable for decreasing expression of EGFR in the cell when transcribed. A pharmaceutical composition including the nucleic acid is also provided. The pharmaceutical composition may include cationic liposomes, preferably DC-Chol/DOPE liposomes with which the nucleic acid is complexed. Lastly, a method for decreasing expression of EGFR in cells is provided that includes the step of contacting target cells with the nucleic acid of the present invention.