Inhibition of mTOR kinase by AZD8055 can antagonize chemotherapy-induced cell death through autophagy induction and down-regulation of p62/sequestosome 1.

AZD8055 is an ATP-competitive inhibitor of mammalian target of rapamycin (mTOR) that forms two multiprotein complexes, mTORC1 and mTORC2, and negatively regulates autophagy. We demonstrate that AZD8055 stimulates and potentiates chemotherapy-mediated autophagy, as shown by LC3I-II conversion and down-regulation of the ubiquitin-binding protein p62/sequestosome 1. AZD8055-induced autophagy was pro-survival as shown by its ability to attenuate cell death and DNA damage (p-H2AX), and to enhance clonogenic survival by cytotoxic chemotherapy. Autophagy inhibition by siRNA against Beclin 1 or LC3B, or by chloroquine, partially reversed the cytoprotective effect of AZD8055 that was independent of cell cycle inhibition. The pro-survival role of autophagy was confirmed using ectopic expression of Beclin 1 that conferred cytoprotection. To determine whether autophagy-mediated down-regulation of p62/sequestosome 1 contributes to its pro-survival role, we generated p62 knockdown cells using shRNA that showed protection from chemotherapy-induced cell death and DNA damage. We also overexpressed wild-type (wt) p62 that promoted chemotherapy-induced cell death, whereas mutated p62 at functional domains (PB1, UBA) failed to do so. The ability of ectopic wt p62 to promote cell death was blocked by AZD8055. AZD8055 was shown to inhibit phosphorylation of the autophagy-initiating kinase ULK1 at Ser(757) and inhibited known targets of mTORC1 (p-mTOR Ser(2448), p70S6K, p-S6, p4EBP1) and mTORC2 (p-mTOR Ser(2481), p-AKT Ser(473)). Knockdown of mTOR, but not Raptor or Rictor, reduced p-ULK1 at Ser(757) and enhanced chemotherapy-induced autophagy that resulted in a similar cytoprotective effect as shown for AZD8055. In conclusion, AZD8055 inhibits mTOR kinase and ULK1 phosphorylation to induce autophagy whose pro-survival effect is due, in part, to down-regulation of p62.

Plasma from chronic liver disease subjects exhibit differential ability to generate thrombin.

Liver fibrosis in chronic liver disease (CLD) results in complex alterations in procoagulant and anticoagulant proteins. Although an elevated international normalized ratio (INR) is a prominent feature of progressive fibrosis, the utility of the INR to accurately reflect the net effect of these changes on the coagulation system is uncertain. In subjects with CLD, elevated INRs have been observed in both bleeding and thrombotic complications, suggesting limitations of the INR in characterizing the coagulation status. Unlike the INR, which is preferentially sensitive to the extrinsic pathway, the direct measurement of thrombin generation better captures the global coagulation cascade. We conducted a pilot study measuring the INR, chromogenic factor X and thrombin generation in CLD subjects and compared them with control subjects and subjects on warfarin anticoagulation. We observed a large interquartile range in thrombin generation among compensated CLD subjects across a narrow INR range, suggesting that the INR is a suboptimal surrogate measure of thrombin generation in CLD subjects.

A case of thrombotic microangiopathy/microangiopathies.

We report a case of Streptococcus pneumonia sepsis-associated disseminated intravascular coagulation (DIC) with features of acute renal failure and microvascular thrombosis characterized by skin purpura and bilateral foot necrosis. The persistence of laboratory features of microangiopathic hemolytic anemia despite aggressive correction of DIC-associated coagulopathy suggests the possibility of an additional concomitant microangiopathic process. Here, we discuss the management and diagnostic approach, particularly highlighting the difficulties in making a definitive diagnosis. Although unconfirmed, our differentials include the concomitant process of sepsis-induced DIC occurring together with an indeterminate form of plasmapheresis and plasma exchange-responsive thrombotic microangiopathy, processes which are previously believed to be mutually exclusive.

Venous thromboembolism in cirrhosis.

The cirrhosis population represents a unique subset of patients who are at risk for both bleeding and developing venous thromboembolic events (VTEs). It has been commonly misunderstood that these patients are naturally protected from thrombosis by deficiencies in coagulation factors. As a result, the cirrhosis population is often falsely perceived to be "autoanticoagulated." However, the concept of "autoanticoagulation" conferring protection from thrombosis is a misnomer. While patients with cirrhosis may have a bleeding predisposition, not uncommonly they also experience thrombotic events. The concern for this increased bleeding risk often makes anticoagulation a difficult choice. Prophylactic and therapeutic management of VTE in patients with cirrhosis is a difficult clinical problem with the lack of clear established guidelines. The elucidation of laboratory and/or clinical predictors of VTE will be useful in this setting. This review serves to examine VTE and the use of anticoagulation in the cirrhosis population.

Autophagy modulation for cancer therapy.

Autophagy is a homeostatic and catabolic process that enables the sequestration and lysosomal degradation of cytoplasmic organelles and proteins that is important for the maintenance of genomic stability and cell survival. Beclin 1 (+/- ) gene knockout mice are tumor prone, indicating a tumor suppressor role for autophagy. Autophagy is also mechanism of stress tolerance that maintains cell viability and can lead to tumor dormancy, progression, and therapeutic resistance. Many anticancer drugs induce cytotoxic stress that can activate pro-survival autophagy. In some contexts, excessive or prolonged autophagy can lead to tumor cell death. Inhibition of cytoprotective autophagy by genetic or pharmacological means has been shown to enhance anticancer drug-induced cell death, suggesting a novel therapeutic strategy. Studies are ongoing to define optimal strategies to modulate autophagy for cancer prevention and therapy, and to exploit it as a target for anticancer drug discovery.

The role of autophagy in cancer: therapeutic implications.

Autophagy is a homeostatic, catabolic degradation process whereby cellular proteins and organelles are engulfed by autophagosomes, digested in lysosomes, and recycled to sustain cellular metabolism. Autophagy has dual roles in cancer, acting as both a tumor suppressor by preventing the accumulation of damaged proteins and organelles and as a mechanism of cell survival that can promote the growth of established tumors. Tumor cells activate autophagy in response to cellular stress and/or increased metabolic demands related to rapid cell proliferation. Autophagy-related stress tolerance can enable cell survival by maintaining energy production that can lead to tumor growth and therapeutic resistance. As shown in preclinical models, inhibition of autophagy restored chemosensitivity and enhanced tumor cell death. These results established autophagy as a therapeutic target and led to multiple early phase clinical trials in humans to evaluate autophagy inhibition using hydroxychloroquine in combination with chemotherapy or targeted agents. Targeting autophagy in cancer will provide new opportunities for drug development, because more potent and specific inhibitors of autophagy are needed. The role of autophagy and its regulation in cancer cells continues to emerge, and studies aim to define optimal strategies to modulate autophagy for therapeutic advantage.