Abstract: A Beclin 1-targeting stapled peptide and a pharmaceutical composition. The stapled peptide includes an amino acid sequence at least 66.7% identical to amino acid residues 191-205 of Beclin 1, an amino acid residue E195 and an amino acid residue N202 in the stapled peptide are connected by a hydrocarbon staple to stabilize the ?-helical structure of the stapled peptide. The hydrocarbon staple is located at a position in the stapled peptide closer to the Beclin1 coiled coil domain-stapled peptide binding interface, which can enhance the binding affinity of the stapled peptide to Beclin 1 by 10-30 fold. Compared to other autophagy inducers like rapamycin and Tat-Beclin 1 peptide, the optimized stapled peptide shows the unique profile of not only inducing autophagy but also significantly enhancing the endolysosomal degradation of cell surface oncogenic receptors EGFR and HER2 in HER2-positive cancer cells.

Abstract: The present invention relates to a Beclin 1-UVRAG complex structure which reveals a tightly packed coiled coil assembly with Beclin 1 and UVRAG residues complementing each other to form a stable dimeric complex. This potent physical interaction is critical for UVRAG-dependent EGFR degradation but less critical for autophagy. Targeting the Beclin 1 coiled coil domain with rationally designed stapled peptides leads to enhanced autophagy activity and EGFR degradation in non-small cell lung cancer (NSCLC) cell lines, suggesting translational value for these compounds.

Abstract: The present invention relates to a Beclin 1-UVRAG complex structure which reveals a tightly packed coiled coil assembly with Beclin 1 and UVRAG residues complementing each other to form a stable dimeric complex. This potent physical interaction is critical for UVRAG-dependent EGFR degradation but less critical for autophagy. Targeting the Beclin 1 coiled coil domain with rationally designed stapled peptides leads to enhanced autophagy activity and EGFR degradation in non-small cell lung cancer (NSCLC) cell lines, suggesting translational value for these compounds.

Abstract: The present invention relates to a Beclin1-UVRAG complex structure which reveals a tightly packed coiled coil assembly with Beclin 1 and UVRAG residues complementing each other to form a stable dimeric complex. This potent physical interaction is critical for UVRAG-dependent EGFR degradation but less critical for autophagy. Targeting the Beclin coiled coil domain with rationally designed stapled peptides leads to enhanced autophagy activity and EGFR degradation in non-small cell lung cancer (NSCLC) cell lines, suggesting translational value for these compounds.

Abstract: The invention is directed to constitutively active Stat proteins and methods for their preparation. The modified Stat proteins have at least one cysteine residue which may interact with the corresponding cysteine residue on another modified Stat protein to form a dimer. The constitutively active Stat proteins are capable of binding to DNA and activating transcription in the absence of tyrosine phosphorylation. Cell lines expressing the modified Stat protein exhibit a transformed phenotype and are capable of forming tumors in nude mice. Methods are describe utilizing the modified Stat proteins of the invention in the absence and presence of tyrosine phosphorylation in identifying agents capable of modulating Stat protein dimerization, transcriptional activity, and cellular transformation in vitro and in vivo. The invention is also directed to polynucleotides encoding modified, constitutively active Stat proteins.

Abstract: The present invention provides a crystal of the core portion of the STAT protein in dimeric form with an 18-mer duplex DNA that contains a binding site for the STAT-dimer. The crystal is of sufficient quality to perform X-ray crystallographic studies. Methods of preparing the crystals are include in the invention. The present invention further discloses the three-dimensional structure of the crystal. The present invention also provides methods of using the structural information in drug discovery and drug development.