The natural product wortmannin and its derivative LY294002 are pan-Class I inhibitors [68,69]. As aforementioned, Akt-mediated activation of the PI3K pathway has been associated with chemo and radioresistance in NSCLC [37]. Even though both compounds were able to increase chemo- and radiosensitivity in NSCLC and SCLC cell lines [37,70,71], they are considered too toxic for human use and have not reached the clinical stage.

PX-866 is also a pan-Class I inhibitor that has the ability to bind PI3K irreversibly [72]. Ihle et al. reported the ability of PX-866 to demonstrate antitumor activity in vivo against a variety of cancer cell lines [72,73]. Interestingly, cancer cell lines harboring PIK3CA mutations or PTEN loss appeared to be more sensitive to PX-866 [67]. The major toxicity reported was hyperglycemia and decreased glucose tolerance which could be overcome when treated with the antidiabetic agent pioglitazone [74]. In mouse models of oncogenic KRAS-induced lung cancer, PX-866 was able to halt PI3K-induced bronchioalveolar stem cell expansion [75]. The agent is about to enter a Phase I study to determine the maximally tolerated dose (MTD) in combination with docetaxel in patients with solid tumors and a Phase II study to determine the efficacy of PX-866 in combination with docetaxel in patients with NSCLC or Squamous Cell Carcinoma of the Head and Neck (SCCHN) [76] (Table 1).

GDC-0941 is a pan-Class I inhibitor that derives from the pyridofuropyrimidine scaffold and shows high oral availability [77]. It is quickly absorbed and has moderate to long half-life as was shown in a Phase I study [78]. It has already entered clinical trials in patients with solid tumors, with three out of 19 patients showing some level of antitumor activity, and grade 3 headache and pleural effusion to be the dose limiting toxicities (DLTs) observed [79]. The compound will soon enter a Phase I study in combination with paclitaxel and carboplatin (with or without bevacizumab) or pemetrexed, cisplatin, and bevacizumab in patients with advanced NSCLC [80] and in combination with the EGFR inhibitor erlotinib in patients with advanced solid tumors [81]. A Phase II study has already been designed to evaluate the safety and efficacy of GDC-0941 in combination with carboplatin-paclitaxel or carboplatin-paclitaxel and bevacizumab in patients with previously untreated advanced or recurrent NSCLC [82]. (Table 1)

XL-147 (SAR245408) is a pan-Class I inhibitor with long half-life and prolonged absorption. In a Phase I study in patients with solid tumors treated orally once a day with XL-147, thirteen patients remained on trial for more than 16 weeks and one patient with NSCLC showed partial response (PR) by RECIST criteria. The compound demonstrated reduction in PI3K and MEK/ERK pathway signaling and prolonged stable disease. Grade 3 rash and grade 4 arterial thrombosis were the serious adverse events (SAEs) observed in the trial, with skin rash to be the most common drug-related toxicity [83]. Currently, the entity is in a Phase I study in combination with paclitaxel and carboplatin in adults with solid tumors including NSCLC patients [84] (Table 1) and has already completed a Phase I study in combination with the EGFR inhibitor erlotinib in patients with solid tumors in which 8 patients with NSCLC were enrolled. The combination of XL-147 and erlotinib was well tolerated (rash, nausea, diarrhea, fatigue and vomiting were the most frequently observed toxicities) in dose levels up to 400 mg XL147 and 150 mg erlotinib daily and showed parallel inhibition of PI3K and EGFR signaling [85].

NVP-BKM120 is a highly specific, orally available pan-Class I PI3K inhibitor that has already completed a Phase I dose-escalation study in patients with advanced malignancies. In this study, thirty-five patients were enrolled and orally treated with NVP-BKM120 daily. The MTD was set at 100 mg/day. The most frequent drug-related adverse events were rash, hyperglycemia, diarrhea, anorexia, and mood alteration. Seven of 35 patients remained in the study for over 8 months and the entity was able to present preliminary antiproliferative activity [86]. The combination of NVP-BKM120 with the mTOR inhibitor rapamycin resulted in synergistic growth inhibition in NSCLC cell lines. Moreover, NVP-BKM120 when combined with the mTOR inhibitor RAD001 (Everolimus), managed to inhibit the growth of lung cancer cells in vitro and also in murine lung cancer xenograft models [87]. Currently, NVP-BKM120 is in a Phase I study with the EGFR inhibitor gefitinib in patients with advanced NSCLC particularly enriched with patients harboring alterations of the PI3K pathway and overexpress EGFR [88] and also in a Phase I/II trial with the EGFR inhibitor erlotinib in patients previously sensitive to erlotinib [89]. NVP-BKM120 is undergoing a Phase II study with docetaxel or docetaxel and pemetrexed in patients with metastatic NSCLC [90] and a Phase I study in combination with the mTOR inhibitor everolimus in patients with advanced solid tumors [91]. Lastly, a Phase II study of NVP-BKM120 is currently being conducted in patients with PIK3CA activating mutations [92] (Table 1).

Chemical compounds that have the ability to inhibit both mTOR and the p110 catalytic subunits are termed dual PI3K- mTOR inhibitors. These inhibitors have the possible advantage of multi-blocking the PI3K pathway, even though it is still unclear if they can effectively inhibit all p110 isoforms and mTORC1- mTORC2 in doses tolerable for clinical use.

NVP-BEZ235 is an imidazo-quinoline derivative, orally available, that belongs to the family of dual PI3K-mTOR inhibitors [93,94]. It was the first entity of this class to enter Phase I studies in patients with advanced solid tumors (many patients with breast cancer were enrolled) in which NVP-BEZ235 showed efficacy and anti-tumor activity [95]. NVP-BEZ235 was able to achieve a decrease in cell proliferation and G1 cell cycle arrest in a variety of cancer cell lines and halt further tumor growth in xenograft models of these cancer types [31,93,96,97]. Compared to mTORC1 inhibitor rapamycin, NVP-BEZ235 was more efficient in blocking tumor cell growth [98]. Moreover, NVP-BEZ235 was able to show anti-tumor efficacy in vitro and in vivo and also increase radiosensitivity in KRAS-mutant NSCLC cell lines [96]. Another study with genetically engineered mice demonstrated that even though the compound, as single-agent, failed to inhibit murine KRAS-mutant lung tumors, when combined with a MEK inhibitor (ARRY-142886) resulted in tumor shrinkage [31]. In the same study, NVP-BEZ235 was highly effective at shrinking a murine lung adenocarcinoma with a somatic mutation in the p110α kinase domain (H1047R) [31]. These results led to the assumption that lung cancer tumors harboring PIK3CA mutations could benefit from the inhibition of PI3K signaling and the combination of both PI3K and MEK inhibitors might show efficacy in KRAS-mutant lung cancers [31]. Sos ML et al. using a panel of NSCLC cell lines, confirmed that tumors with activating mutations in RTKs present high dependence on PI3K signaling and mutations in the RAS/RAF pathway is strongly correlated with MAPK signaling [99]. In another study, EGFR-mutant NSCLC models did not respond to single-agent NVP-BEZ235, but when combined with a MEK inhibitor (AZD6244), tumor regression could be observed suggesting the key role of simultaneous PI3K and MEK inhibition in lung cancers with EGFR mutations [100].

XL-765 (SAR245409) is another dual PI3K-mTOR inhibitor that recently completed a Phase I dose-escalation study in patients with advanced solid tumors. The compound was orally administered and well tolerated with elevated hepatic enzymes, with nausea and diarrhea being the most frequent drug-related adverse events (AEs). No partial responses were observed, but five of 36 patients presented stable disease, one of them with NSCLC. Evidence of 60% to 90% pathway inhibition was found in hair and skin [101]. The combination of XL-765 with the EGFR inhibitor erlotinib was tested in a Phase I study in 21 patients with advanced solid tumors, including 14 patients with NSCLC. The combination was well tolerated in doses up to 50 mg XL-765 and 100 mg erlotinib with skin and subcutaneous tissue disorders (including rash) and diarrhea to be the most commonly observed treatment-related adverse events (AEs) and showed satisfactory dual PI3K and EGFR signaling inhibition [102].

Another dual PI3K-mTOR inhibitor PI-103, a pyridinylfuranopyrimidine compound, was able to induce apoptosis in NSCLC cell lines with resistance to EGFR inhibitor gefitinib [103]. Cell lines harboring activating mutations of the PIK3CA gene were more sensitive than wild-type PIK3CA cancer cell lines [103]. Moreover, PI-103 increased sensitivity to radiation in tumor cells in vitro [104] and caused vascular normalization in murine xenograft models in vivo [105]. The entity is still under clinical evaluation.

Akt inhibitors are chemical agents based on staurosporine and derivatives that have the ability to block the serine/threonine kinase Akt, crucial component of the PI3K pathway [106,107]. However, preclinical data suggest that parallel inhibition of both Akt1 and Akt2 could result in peripheral insulin resistance and drug-induced, dose-dependent hyperglycemia and hyperinsulinemia [108]. In several studies using mouse models, Akt inhibitors have been implicated for causing hyperglycemia [109,110], supporting the hypothesis of having a key role in insulin signaling and glucose homeostasis. Therefore, concerns have been raised for possible limitation in the therapeutic applications of Akt inhibitors due to metabolic toxicities.

MK-2206 is an orally administered pan-AKT kinase inhibitor presenting high selectivity for Akt. Preclinical data demonstrated the ability of MK-2206 to inhibit cancer cell proliferation when combined with cytotoxic agents (such as docetaxel, doxorubicin, gemcitabine, 5-FU and carboplatin) or targeted therapeutic agents (such as erlotinib or lapatinib) [111]. In a Phase I study, thirty-three patients with solid tumors were treated with MK-2206, establishing the MTD at 60 mg. One patient with pancreatic adenocarcinoma presented 60% reduction in cancer antigen 19-9 levels and 23% tumor shrinkage. Skin rash, nausea, pruritus, hyperglycemia and diarrhea were the most commonly observed adverse events [112]. Currently, a dose-escalation Phase I study of MK-2206 combined with the EGFR-TKI gefitinib is being conducted in patients with NSCLC, particularly enriched with patients harboring EGFR mutations [113]. Also, a Phase II study of MK-2206 and the EGFR inhibitor erlotinib is currently recruiting patients with NSCLC who have progressed after previous response to erlotinib, in order to assess the safety of the drug combination [114] (Table 1). Other Akt inhibitors such as A-443654 and GSK690693 are currently under clinical evaluation [109,115].

Compounds targeting the mTOR pathway can be grouped into two main subtypes: the allosteric mTOR inhibitors (like rapamycin and its derivatives) and the ATP-competitive mTOR inhibitors.

Rapamycin (sirolimus, Rapamune^®), a macrolide isolated from Streptomyces hygroscopicus, is an allosteric inhibitor of the mTORC1 complex (but not mTORC2) with antifungal, immunosuppressive and antiproliferative activity [116]. Even though the anti-tumor efficacy of rapamycin is well documented both in vitro and in vivo, it is still not entirely understood. By reducing the levels of cyclins (especially cyclin D) and increase the levels of cyclin-dependent kinase inhibitors p21^cip1 and p27^kip1, rapamycin blocks G1 cell cycle progression [117,118,119,120]. The compound presents also anti-angiogenic properties by inhibiting endothelial cell proliferation, reducing the levels of produced vascular endothelial growth factor (VEGF) and reducing the response of endothelial cells to VEGF via mTOR inhibition [121,122,123]. There are preclinical data suggesting compounds’ ability to block the growth of human NSCLC cells and inhibit the growth of a Ras-induced NSCLC tumor and alveolar epithelial neoplasia [124,125,126]. The combination of rapamycin and docetaxel was found to synergistically inhibit the growth of lung cancer cells [127] and also the addition of rapamycin to PI3K inhibitors LY294002 and NVP-BKM120 resulted in synergistic act against NSCLC specimens [128], suggesting the possible efficacy of using rapamycin in combination with chemotherapy or other targeted agents in the treatment of lung cancer. However, the unfavorable pharmacological properties of rapamycin have promoted the discovery and development of rapamycin analogues suitable for clinical use, such as everolimus (RAD001), temsirolimus (CCI-779) and deforolimus (AP23573).

CCI-779 (temsirolimus) is an orally available rapamycin analogue with significant antiproliferative activity against a variety of human cancer types including SCLC [129]. Ohara et al. recently reported the ability of temsirolimus to inhibit tumor cell proliferation in NSCLC cell lines in a dose-dependent manner [130]. In a Phase I dose-escalation study, CCI-779 was i.v. administered in 63 patients with solid tumors. One patient with NSCLC had a confirmed partial response (PR) maintained for 12.7 months, three out of 63 patients had unconfirmed PRs and in two patients stable disease was observed for over 24 weeks. The most frequent drug-related toxicities were fatigue, mucositis and nausea and the maximally tolerated dose was 15 mg/m² for heavily pretreated patients and 19 mg/m² for patients with minimal prior treatment [131]. In another Phase I trial, patients with advanced solid tumors were orally treated with CCI-779 and the MTD was set at 75 mg. Elevated liver enzymes and rash were the dose-limiting toxicities observed in the study, and mucositis, rash and asthenia the most commonly identified drug-related adverse events [132]. Temsirolimus was also administered in 87 patients with extensive-stage SCLC in remission after induction chemotherapy. The overall median progression-free survival (PFS) time was 2.2 months and the median overall survival (OS) time was 8 months. Only one patient experienced a PR and six patients achieved disease stabilization, thus temsirolimus failed to prolong PFS in stable or responding patients with extensive-stage SCLC after induction chemotherapy [133]. Fifty-five patients with advanced NSCLC received CCI-779 i.v. at a dose of 25 mg/week in a Phase II study. Four patients had confirmed PR and SD maintained for 8 weeks or more was observed in fourteen patients. Dyspnea, fatigue, hyperglycemia, hypoxia, nausea and rash were the most frequent drug-related adverse events reported [134]. In a Phase I dose-escalation study, CCI-779 was tested in combination with the EGFR inhibitor EKB-569 in 48 patients with advanced solid tumors. The MTD was established at 30 mg on days 1–3 and 15–17 in a 28-day cycle for temsirolimus and 35 mg daily for EKB-569. The most common grade 3/4 toxicities observed were diarrhea, dehydration, and nausea-vomiting. Four out of 48 patients had a partial response and 15 patients showed stable disease [135]. Currently, CCI-779 is undergoing numerous clinical studies either as a single agent or in combination with cytotoxic agents (such as pemetrexed, vinorelbine and docetaxel) in patients with lung cancer [136,137,138] (Table 1).

RAD001 (everolimus) is an orally available rapamycin derivative that has already been approved in Europe as an immunosuppressive agent to prevent rejection in adult cardiac and renal transplant patients [139,140]. RAD001 showed significant antitumor activity in cancer cell lines and xenograft models of various cancer types including lung cancer [141,142,143,144,145]. Everolimus has the ability to bind with high affinity to FKB12, the intracellular receptor for mTOR, form a complex that interacts with mTOR and consequently halt downstream signaling [143].

RAD001 was evaluated in a Phase II nonrandomized study comparing NSCLC patients with two or fewer prior lines of chemotherapy, one platinum-based (arm 1) to those who failed second line chemotherapy in combination with an EGFR inhibitor (arm 2). Eighty-five patients (42 in arm 1 and 43 in arm 2) were enrolled and treated with Everolimus at a dose of 10 mg/day until progression disease or unacceptable toxicity. The overall response rate (ORR) was 4.7% and the overall disease control rate was 47.1%. The median progression-free survival (PFS) was 2.6 months in arm 1 and 2.7 months in arm 2. The most commonly observed toxicities were fatigue, dyspnea, stomatitis, anorexia, anemia and thrombocytopenia [146].

In a Phase I trial, RAD001 was orally administered in combination with the EGFR inhibitor gefitinib in patients with advanced NSCLC. Ten patients were enrolled in this study and the maximum tolerated dose of everolimus was set at 5 mg/day when coadministered with 250 mg gefitinib daily. At this dosage, the combination of RAD001 and gefitinib had only mild to moderate toxicities. When everolimus was administered at a higher dose, two dose-limiting toxicities were observed (grade 5 hypotension and grade 3 stomatitis). Among the eight evaluated patients, only two confirmed partial responses (PRs) were identified [147]. The combination of everolimus and gefitinib was also evaluated in a Phase II study in which 62 NSCLC patients participated. The patients were stratified into two cohorts based on whether they had been previously treated with cisplatin or carboplatin and docetaxel or pemetrexed (arm 2) or if they had received no prior treatment (arm 1). Only in 8 out of 62 patients, PRs were identified, thus the overall response rate was 13%. The median time to progression was 4 months and the median overall survival was 12 months, 27 months in arm 1 and 11 months in arm 2. Even though the combination was well tolerated with only mild to moderate toxicities, the partial response rate observed did not meet the predefined response to justify further investigation [148].

Campone et al. conducted a Phase I study of everolimus and paclitaxel weekly administered in patients with solid tumors. Sixteen patients were enrolled, eleven of whom achieved disease stabilization. The main DLT observed in this study was myelosuppression [149].

Twenty-four patients with advanced NSCLC and progression after platinum-based chemotherapy were enrolled in a Phase I study of RAD001 in combination with docetaxel. The DLTs were fever with grade 3/4 neutropenia, grade 3 fatigue and grade 3 mucositis. Among 21 patients evaluated, one patient with lung adenocarcinoma had a PR and 10 patients achieved disease stabilization. The recommended Phase II doses for the combination are 60 mg/m² for docetaxel and 5 mg daily for everolimus [150].

The combination of everolimus and pemetrexed was also tested in a Phase I dose-escalation study in patients with NSCLC who progressed after one prior treatment. Forty-three patients were enrolled and in 5 of them, PR was identified. Everolimus 5 mg daily or 50 mg weekly in combination with the standard regimen of pemetrexed, was well tolerated and the most common grade 3/4 adverse events observed were neutropenia, dyspnea and thrombocytopenia [151].

Everolimus and the EGFR inhibitor erlotinib were administered in patients with advanced NSCLC previously treated with chemotherapy in a Phase I trial. Sixty-one patients were enrolled in the study and the drug-combination was well tolerated with mucositis, rash, diarrhea, vomiting and neutropenia to be the DLTs observed. One patient had complete response (CR), three patients had PR and 17 patients presented stable disease [152]. The combination was further tested in a Phase II study in which 133 patients participated. Even though the combination arm of everolimus plus erlotinib had 11% better disease control rate (DCR) at 3 months than the single-agent erlotinib arm, it did not meet the prespecified threshold for a Phase III study [153].

In a Phase I clinical study, RAD001 will be tested in patients with operable NSCLC [154]. In another Phase I study, the combination of everolimus and carboplatin-paclitaxel with or without bevacizumab is being evaluated in patients with NSCLC [155] (Table 1).

In SCLC cell lines RAD001 were able to inhibit cell growth in vitro and also in xenograft models of SCLC [156,157]. Moreover, SCLC cell lines exhibiting overactivation of the Akt/mTOR signaling were shown to be more sensitive to RAD001 treatment, suggesting the possible key role of inhibiting mTOR in patients with SCLC [156]. In a Phase II study, 10 mg everolimus were administered daily to 40 previously treated patients with SCLC after progression. In 35 evaluated patients, one had PR, and in eight patients disease stabilization was identified. The disease control rate at 6 weeks was 26%, the median time to progression was 1.3 months and the median survival was 6.7 months. Thrombocytopenia, neutropenia, infection, pneumonitis, fatigue, elevated transaminases, diarrhea and acute renal failure were the grade 3 adverse events observed. Even though the entity was well tolerated in this study, it had only moderate efficacy in pre-treated patients with relapsed SCLC [158].

Preclinical data suggest that everolimus and the EGFR inhibitor erlotinib have synergistic effect in atypical bronchial carcinoids (AC) and large cell neuroendocrine lung carcinomas (LCNEC), indicating the clinical importance of EGFR and mTOR as therapeutic targets in bronchial neuroendocrine tumors [159]. A Phase II study of everolimus with paclitaxel and carboplatin as first line treatment in patients with advanced large cell lung cancer with neuroendocrine differentiation is being conducted [160] (Table 1).

Currently, everolimus is in a Phase I study in combination with paclitaxel in patients with relapsed or refractory SCLC [161] and recently a dose-escalation Phase I study of everolimus in combination with carboplatin and etoposide in patients with SCLC or other advanced malignancies was terminated due to increased number of toxicities observed in the trial [162]. The combination of everolimus and cisplatin-etoposide is being evaluated in a Phase I trial in non-previously-treated patients with extensive-stage SCLC [163] (Table 1).

Drug-related pulmonary toxicity has been described for mTOR inhibitors in several studies and has been reported to be as high as 25% to 36% with typical radiographic findings, including lung consolidation and nonspecific areas of ground glass attenuation [164,165]. Patients with mTOR pneumonitis can be asymptomatic or have only mild symptoms, thus careful monitoring is required and treatment with mTOR inhibitors can often be continued.

AP23573 (ridaforolimus) is a rapamycin analogue and a small molecule mTOR inhibitor. The compound has shown significant antiproliferative activity in various human cancer cell lines and murine xenografts, as a single agent or in combination with cytotoxic or targeted agents [166,167]. In a Phase I study, ridaforolimus was administered to 13 Japanese patients with advanced solid tumors, and was well tolerated up to a dose of 40 mg. The most common adverse events identified were stomatitis, hypertriglyceridemia and proteinuria. In this study, one patient with NSCLC experienced PR [168]. In another dose-escalation Phase I study, thirty-two patients with advanced tumors received AP23573 intravenously daily for 5 days every 2 weeks in a 28-day cycle. The entity was well tolerated and the maximum-tolerated dose (MTD) was 18.75 mg/d. One patient with NSCLC had PR [169].

Up to date, a Phase II study of AP23573 in NSCLC patients with KRAS-mutations is ongoing [170] and a Phase I study of AP23573 combined with cetuximab in patients with NSCLC, head and neck cancer and colon cancer [171] (Table 1).

ATP competitive mTOR inhibitors have the ability of blocking both mTORC1 and mTORC2 complex producing a more significant antitumor activity compared to rapamycin derivatives [172].

AZD8055 is an ATP competitive mTOR inhibitor that has already completed a Phase I study in patients with solid tumors and lymphomas. Forty-nine patients were treated with AZD8055 and the most frequently observed drug-related adverse events were increased transaminases and fatigue. The maximum tolerated dose was set at 90 mg. Even though seven patients had stable disease maintained for over 4 months, no responses by RECIST criteria were identified [173]. Preclinical data suggest that AZD8055 and the MEK inhibitor selumetinib have synergistic antitumor efficacy in murine xenograft models of human lung adenocarcinomas [174]. Other ATP competitive mTOR inhibitors such as KU-0063794, WYE-354, WYE-132, OXA-01 are currently under clinical research in patients with solid tumors including lung cancer patients.