Akt Pathway Inhibitors.

Cancer is a devastating disease that has plagued humans from ancient times to this day. After decades of slow research progress, promising drug development, and the identification of new targets, the war on cancer was launched, in 1972. The P13K/Akt pathway is a growth-regulating cellular signaling pathway, which in many human cancers is over-activated. Studies have demonstrated that a decrease in Akt activity by Akt inhibitors is associated with a reduction in tumor cell proliferation. There have been several promising drug candidates that have been studied, including but not limited to ipatasertib (RG7440), 1; afuresertib (GSK2110183), 2; uprosertib (GSK2141795), 3; capivasertib (AZD5363), 4; which reportedly bind to the ATP active site and inhibit Akt activity, thus exerting cytotoxic and antiproliferative activities against human cancer cells. For most of the compounds discussed in this review, data from preclinical studies in various cancers suggest a mechanistic basis involving hyperactivated Akt signaling. Allosteric inhibitors are also known to alter the activity of kinases. Perifosine (KRX- 0401), 5, an alkylphospholipid, is known as the first allosteric Akt inhibitor to enter clinical development and is mechanistically characterized as a PH-domain dependent inhibitor, non-competitive with ATP. This results in a reduction in Akt enzymatic and cellular activities. Other small molecule (MK- 2206, 6, PHT-427, Akti-1/2) inhibitors with a similar mechanism of action, alter Akt activity through the suppression of cell growth mediated by the inhibition of Akt membrane localization and subsequent activation. The natural product solenopsin has been identified as an inhibitor of Akt. A few promising solenopsin derivatives have emerged through pharmacophore modeling, energy-based calculations, and property predictions.

Akt Pathway Inhibition of the Solenopsin Analog, 2-Dodecylsulfanyl-1,-4,-5,-6-tetrahydropyrimidine.

BACKGROUND/AIM: The P13K/Akt signaling pathway is a growth-regulating cellular pathway that is constitutively activated in a variety of human cancers. In previous studies, we reported that a solenopsin analog, compound B (MU-06-SC-608-7), shows inhibitory effects on Akt phosphorylation at a key activation site, as well as on proliferation of tumorigenic cells at sub-micromolar concentrations. The purpose of this study was to evaluate the effect of compound B on downstream effectors of Akt kinase, phosphorylation of Akt at a second activation site, Akt kinase activity in vitro, tumorigenic cell viability and other signaling pathways. MATERIALS AND METHODS: Western blot analyses were performed using WBras1 epithelial and H2009 human carcinoma cells and cell viability assays were performed on H2009 cells. In vitro Akt kinase assays were performed using a commercially available kit. RESULTS: Compound B decreased the phosphorylation of Akt at the Thr308 activation site and key downstream effectors of Akt kinase, but did not directly inhibit Akt kinase. Substantial decreases in cell viability were observed at concentrations above 5 µM. No effect was seen on ERK or JNK pathways. CONCLUSION: The results earmark this compound for further studies as a potential targeted cancer therapy.

Modulator of the PI3K/Akt oncogenic pathway affects mTOR complex 2 in human adenocarcinoma cells.

Chaetoglobosin K (ChK) is a natural product that has been shown to promote F-actin capping, inhibit growth, arrest cell cycle G2 phase, and induce apoptosis. ChK also has been shown to downregulate two important kinases involved in oncogenic pathways, Akt and JNK. This report investigates how ChK is involved in the receptor tyrosine kinase pathway (RTK/PI3K/mTORC2/Akt) to the centrally located protein kinase, Akt. Studies have reported that ChK does not inhibit PI3K comparable to wortmannin and does not affect PDK1 activation. PDK1 is responsible for phosphorylation on Akt T308, while mTORC2 phosphorylates Akt S473. Yet, Akt's two activation sites, T308 and S473, are known to be affected by ChK treatment. It was our hypothesis that ChK acts on the mTORC2 complex to inhibit the phosphorylation seen at Akt S473. This inhibition at mTORC2 should decrease phosphorylation at both these proteins, Akt and mTORC2 complex, compared to a known mTOR specific inhibitor, Torin1. Human lung adenocarcinoma H1299 and H2009 cells were treated with IGF-1 or calyculin A to increase phosphorylation at complex mTORC2 and Akt. Pretreatment with ChK was able to significantly decrease phosphorylation at Akt S473 similarly to Torin1 with either IGF-1 or calyculin A treatment. Moreover, the autophosphorylation site on complex mTORC2, S2481, was also significantly reduced with ChK pretreatment, similar to Torin1. This is the first report to illustrate that ChK has a significant effect at mTORC2 S2481 and Akt S473 comparable to Torin1, indicating that it may be a mTOR inhibitor.

Discovery and biological activity of computer-assisted drug designed Akt pathway inhibitors.

The P13K/Akt pathway is a growth-regulating cellular signaling pathway that is over-activated in numerous human cancers. A novel series of Akt pathway inhibitors were identified using iterative pharmacophore modeling, energy-based calculations, and property predictions of known Akt inhibitors. Inhibitory effects on activation of Akt and growth of human neoplastic cells are reported. Results show variable inhibitory effects of three selected compounds on Akt phosphorylation at a key activation site, and on proliferation of tumorigenic cells. We identify one lead compound with potent inhibitory activity on both human carcinoma cell proliferation and Akt activation.