Novel quantitative autophagy analysis by organelle flow cytometry after cell sonication.

Autophagy is a dynamic process of bulk degradation of cellular proteins and organelles in lysosomes. Current methods of autophagy measurement include microscopy-based counting of autophagic vacuoles (AVs) in cells. We have developed a novel method to quantitatively analyze individual AVs using flow cytometry. This method, OFACS (organelle flow after cell sonication), takes advantage of efficient cell disruption with a brief sonication, generating cell homogenates with fluorescently labeled AVs that retain their integrity as confirmed with light and electron microscopy analysis. These AVs could be detected directly in the sonicated cell homogenates on a flow cytometer as a distinct population of expected organelle size on a cytometry plot. Treatment of cells with inhibitors of autophagic flux, such as chloroquine or lysosomal protease inhibitors, increased the number of particles in this population under autophagy inducing conditions, while inhibition of autophagy induction with 3-methyladenine or knockdown of ATG proteins prevented this accumulation. This assay can be easily performed in a high-throughput format and opens up previously unexplored avenues for autophagy analysis.

Targeting activated Akt with GDC-0068, a novel selective Akt inhibitor that is efficacious in multiple tumor models.

PURPOSE: We describe the preclinical pharmacology and antitumor activity of GDC-0068, a novel highly selective ATP-competitive pan-Akt inhibitor currently in clinical trials for the treatment of human cancers. EXPERIMENTAL DESIGN: The effect of GDC-0068 on Akt signaling was characterized using specific biomarkers of the Akt pathway, and response to GDC-0068 was evaluated in human cancer cell lines and xenograft models with various genetic backgrounds, either as a single agent or in combination with chemotherapeutic agents. RESULTS: GDC-0068 blocked Akt signaling both in cultured human cancer cell lines and in tumor xenograft models as evidenced by dose-dependent decrease in phosphorylation of downstream targets. Inhibition of Akt activity by GDC-0068 resulted in blockade of cell-cycle progression and reduced viability of cancer cell lines. Markers of Akt activation, including high-basal phospho-Akt levels, PTEN loss, and PIK3CA kinase domain mutations, correlate with sensitivity to GDC-0068. Isogenic PTEN knockout also sensitized MCF10A cells to GDC-0068. In multiple tumor xenograft models, oral administration of GDC-0068 resulted in antitumor activity ranging from tumor growth delay to regression. Consistent with the role of Akt in a survival pathway, GDC-0068 also enhanced antitumor activity of classic chemotherapeutic agents. CONCLUSIONS: GDC-0068 is a highly selective, orally bioavailable Akt kinase inhibitor that shows pharmacodynamic inhibition of Akt signaling and robust antitumor activity in human cancer cells in vitro and in vivo. Our preclinical data provide a strong mechanistic rationale to evaluate GDC-0068 in cancers with activated Akt signaling.

mTOR kinase inhibitor potentiates apoptosis of PI3K and MEK inhibitors in diagnostically defined subpopulations.

The mammalian target of rapamycin (mTOR) is a central node in a complex signaling network that is regulated by several pathways deregulated in human cancers, including the PI3K/Akt and MAPK pathways. Targeting mTOR therefore presents an opportunity for therapeutic intervention. However, mTOR inhibition with rapamycin analogs or kinase inhibitors reduces cell growth but does not induce apoptosis, and the clinical benefit of rapamycin analogs has been modest. In this study we show that mTOR kinase inhibitors can potentiate apoptosis when used in combination with upstream targeted agents such as PI3K and MEK inhibitors. This increased apoptosis is dependent on genetic background, and correlates with active growth factor survival pathways. In PI3K mutant tumors, mTOR inhibition leads to partial reactivation of Akt which allows cells to survive, whereas in KRAS mutant tumors, this same reactivation of Akt occurs but is not required for cell survival. These data suggest the use of selected rational combinations of mTOR kinase inhibitors with other targeted inhibitors in specific tumor genotypes to achieve the maximal cytotoxic response by inhibiting two nodes in the activated signaling network.

Autophagy, an Achilles' heel AKTing against cancer?

Akt has emerged as an attractive cancer therapeutic target with a central role in cell survival, growth, proliferation and metabolism.A key to the clinical success of Akt inhibitors is the maximal possible antitumor efficacy achievable without intolerable side effects. In our recent work, we show that although Akt inhibition does not always induce a clear apoptotic response, autophagy is a more readily detectable response to pan-Akt knockdown or selective small molecule inhibitors of the PI3K/Akt pathway. Autophagy isa catabolic process of bulk lysosomal degradation and recycling of cytoplasmic material and organelles, which can provide a temporary survival mechanism for cells under stress conditions, but can also make cells vulnerable to several forms of cell death under specific circumstances. We hypothesize that autophagy induced by Akt inhibition may sensitize tumor cells to agents targeting the later steps of this lysosomal degradation process. Indeed, agents that interfere with the lysosomal degradation function could precipitate cell death when combined with Akt inhibition and promote complete tumor remissions in preclinical models. These findings suggest that manipulating the autophagic response may be a promising strategy to increase the therapeutic efficacy of Akt inhibitors.

Akt inhibition promotes autophagy and sensitizes PTEN-null tumors to lysosomotropic agents.

Although Akt is known as a survival kinase, inhibitors of the phosphatidylinositol 3-kinase (PI3K)-Akt pathway do not always induce substantial apoptosis. We show that silencing Akt1 alone, or any combination of Akt isoforms, can suppress the growth of tumors established from phosphatase and tensin homologue-null human cancer cells. Although these findings indicate that Akt is essential for tumor maintenance, most tumors eventually rebound. Akt knockdown or inactivation with small molecule inhibitors did not induce significant apoptosis but rather markedly increased autophagy. Further treatment with the lysosomotropic agent chloroquine caused accumulation of abnormal autophagolysosomes and reactive oxygen species, leading to accelerated cell death in vitro and complete tumor remission in vivo. Cell death was also promoted when Akt inhibition was combined with the vacuolar H(+)-adenosine triphosphatase inhibitor bafilomycin A1 or with cathepsin inhibition. These results suggest that blocking lysosomal degradation can be detrimental to cancer cell survival when autophagy is activated, providing rationale for a new therapeutic approach to enhancing the anticancer efficacy of PI3K-Akt pathway inhibition.