Abstract: In some aspects, the disclosure provides methods of modulating the level of proteasome inhibitor resistance of a cell, the methods comprising manipulating the level of expression or activity of a subunit of the 19S proteasome in the cell. In some aspects, cells in which the level of a 19S subunit is modulated, e.g., reduced, are provided. In some aspects, methods of identifying agents that reduce proteasome inhibitor resistance are provided. In some aspects, methods of classifying cancers according to predicted proteasome inhibitor resistance are provided. In some aspects, methods of killing or inhibiting proliferation of cancer cells, e.g., proteasome inhibitor resistant cancer cells, are provided. In some aspects, methods of treating cancer, e.g., proteasome inhibitor resistant cancer, are provided.

Abstract: It has been established that exposure to cytotoxic doses of HSP90 inhibitor is broadly immunosuppressive, whereas continuous exposure to low-dosages of the same inhibitor exerts anti-tumor activity. The anti-tumor activity is mediated by the host immune system. Compositions and methods for continuous, low-dose exposure to HSP90 inhibitors in combination with one or more immunostimulatory agents for the treatment of cancer are described. Typically, the HSP90 inhibitor is administered in an amount that is between 1% and 20% of the clinically-determined maximum tolerate dose. The immunostimulatory agent can be administered simultaneously with the HSP90 inhibitor, or at some time before or after the HSP90 inhibitor. Compositions including a sub-toxic dose of HSP90 inhibitor in combination with an immunostimulatory agent in an amount effective to treat cancer are also provided.

Abstract: In some aspects, the disclosure provides methods of modulating the level of proteasome inhibitor resistance of a cell, the methods comprising manipulating the level of expression or activity of a subunit of the 19S proteasome in the cell. In some aspects, cells in which the level of a 19S subunit is modulated, e.g., reduced, are provided. In some aspects, methods of identifying agents that reduce proteasome inhibitor resistance are provided. In some aspects, methods of classifying cancers according to predicted proteasome inhibitor resistance are provided. In some aspects, methods of killing or inhibiting proliferation of cancer cells, e.g., proteasome inhibitor resistant cancer cells, are provided. In some aspects, methods of treating cancer, e.g., proteasome inhibitor resistant cancer, are provided.

Abstract: In some aspects, the disclosure provides methods of modulating the level of proteasome inhibitor resistance of a cell, the methods comprising manipulating the level of expression or activity of a subunit of the 19S proteasome in the cell. In some aspects, cells in which the level of a 19S subunit is modulated, e.g., reduced, are provided. In some aspects, methods of identifying agents that reduce proteasome inhibitor resistance are provided. In some aspects, methods of classifying cancers according to predicted proteasome inhibitor resistance are provided. In some aspects, methods of killing or inhibiting proliferation of cancer cells, e.g., proteasome inhibitor resistant cancer cells, are provided. In some aspects, methods of treating cancer, e.g., proteasome inhibitor resistant cancer, are provided.

Abstract: In some aspects, the invention relates to Heat Shock Protein-1 (HSF1) gene and HSF1 gene products. In some aspects, the invention provides methods of tumor diagnosis, prognosis, treatment-specific prediction, or treatment selection, the methods comprising assessing the level of HSF1 expression or HSF1 activation in a sample obtained from the tumor. In some aspects, the invention relates to the discovery that increased HSF1 expression and increased HSF1 activation correlate with poor outcome in cancer, e.g., breast cancer.

Abstract: In some aspects, the invention relates to Heat Shock Protein-1 (HSF1) gene and HSF1 gene products in tumor stroma. In some aspects, the invention provides methods of tumor prognosis, treatment-specific prediction, or treatment selection, the methods comprising measuring the level of HSF1 expression or HSF1 activation in a sample obtained from the tumor that comprises tumor-associated stromal cells. In some aspects, the invention relates to the discovery that increased HSF1 expression and increased HSF1 activation in tumor-associated stromal cells correlate with poor outcome in cancer. In some embodiments, the methods comprise measuring HSF1 expression or activation specifically in tumor-associated stromal cells. In some embodiments, the methods comprise measuring HSF1 expression or activation specifically in tumor-associated stromal cells and specifically in cancer cells. In some embodiments HSF1 expression or activation is measured using an antibody that specifically binds to HSF1.

Abstract: In some aspects, the invention relates to Heat Shock Protein-1 (HSF1) gene and HSF1 gene products. In some aspects, the invention provides methods of tumor diagnosis, prognosis, treatment-specific prediction, or treatment selection, the methods comprising assessing the level of HSF1 expression or HSF1 activation in a sample obtained from the tumor. In some aspects, the invention relates to the discovery that increased HSF1 expression and increased HSF1 activation correlate with poor outcome in cancer, e.g., breast cancer. In some aspects, the invention relates to the HSF1 cancer program genes, HSF1 cancer signature set genes, subsets thereof, and uses in tumor diagnosis, prognosis, treatment-specific prediction, treatment selection, or drug discovery, among others.

Abstract: In some aspects, the invention relates to Heat Shock Protein-1 (HSF1) gene and HSF1 gene products. In some aspects, the invention provides methods of tumor diagnosis, prognosis, treatment-specific prediction, or treatment selection, the methods comprising assessing the level of HSF1 expression or HSF1 activation in a sample obtained from the tumor. In some aspects, the invention relates to the discovery that increased HSF1 expression and increased HSF1 activation correlate with poor outcome in cancer, e.g., breast cancer.