Most patients with lung cancer have a poor prognosis due to genetic alterations and resistance to conventional therapy. The development of novel and more effective drugs is critical to improve the prognosis of patients with both non-small cell lung cancer (NSCLC) and small lung cancer (SCLC). BAK is a key multidomain proapoptotic molecule in the Bcl2 family, which is required for apoptotic cell death. Because BAK is normally an integral outer mitochondrial membrane protein, whereas BAX requires translocation from the cytosol after an apoptotic stimulus, BAK activation may be more tractable. The formation of BAK homo- or heterodimers is an important mechanism in the induction of apoptosis. Bcl-XL and Mcl-1 can bind to BAK, which is presumably in a ?primed? conformation with its BH3 domain exposed, while in apoptosis-induced cells, a BH3-only protein displaces BAK from the anti-apoptotic heterodimer. The free BAK then forms an oligomer that elicits the permeabilization of the mitochondrial outer membrane and the release of cytochrome c leading to apoptosis. The BH3 binding pocket is located between BAK ?2 and ?3, which is an ideal site for the design or screening of BAK activators for the development of potential new anti-cancer agents. We chose the BH3 domain binding pocket (aa75-90) of BAK as a docking site for the screening of small molecules using the UCSF DOCK 6.1 program suite and the NCI chemical library database. We discovered two novel BAK activators (BKA-073 and BKA-758) that exhibit selective apoptotic effect in lung cancer cells as compared to normal human bronchial epithelial cells. Fluorescence polarization assay reveals that BKA-073 and BKA-758 preferentially bind to BAK protein with inhibitory constant (Ki) values at nanomolar levels in vitro but do not bind to other Bcl2 family members (i.e. BAX or Bcl2). The lead compound BKA-758 has potent antitumor activity against lung cancer in xenografts derived from lung cancer cell lines or patient-derived xenograft models. We hypothesize that BKA(s) may specifically activate the proapoptotic function of BAK in tumor cells by specifically targeting its BH3 binding pocket, which leads to suppression of lung cancer. To test this hypothesis, we have identified two specific aims: (1) To determine the mechanism(s) by which BAK agonists (BKAs) activate the proapoptotic function of BAK and induce apoptosis in human lung cancer cells; (2) To determine whether BKA compounds suppress the growth of small lung cancer (SCLC) and non-small cell lung cancer (NSCLC) in vivo. Studies will test the potency of BKAs in patient-derived xenografts, radioresistant lung cancer and genetically engineered lung cancer animal models. Determine whether the ?dynamic BH3 profiling? predicts the antitumor efficacy of BKA compounds in vivo. Based on our proposed studies, it is expected that novel first-in-class BAK agonists as an entirely new class of anti-lung cancer drugs will be developed for lung cancer therapy.
Most patients with lung cancer have a poor prognosis with limited options for effective treatment. Proposed studies will develop new agents and strategies for both small cell lung cancer and non-small cell lung cancer, which will lead to improvement of lung cancer outcome and benefit to public health.
