Novel agents for pancreatic ductal adenocarcinoma: emerging therapeutics and future directions

Because the efficacy of classic PDAC cytotoxic agents is limited, novel formulations of classic agents or drugs targeting the desmoplastic and hypoxic environment were developed. A randomized phase III study NAPOLI-1 added nanoliposome irinotecan prior to 5-FU/leucovorin (LV) in MPC, and the results showed that the objective response rate (ORR) and median OS were significantly improved compared with those in patients in the 5-FU/LV arm (mOS: 6.1 vs 4.2 months, P = 0.012) [26]. An oral prodrug of 5-FU, S-1, was verified as non-inferior, even superior, and was well tolerated compared with gemcitabine among resected PC patients from Asia in the JASPAC-01 study (HR = 0.57, 95% CI 0.44–0.72, P < 0.0001) [27]. This study was launched in 33 hospitals in Japan, and the proportion of male patients younger than 65 years old with a performance status (PS) of 0 was relatively larger in the S-1 group than in the gemcitabine group (male 57 vs 54%, < 65 years old 41 vs 39%, PS 0 70 vs 67%). Another oral prodrug of 5-FU, capecitabine, in combination with gemcitabine as adjuvant therapy among resected PC patients from Europe, showed a significantly better median OS than gemcitabine alone (28 vs 22.5 months, P = 0.032) [28]. The 5-year survival was 28.8% in patients treated with capecitabine plus gemcitabine in the ESPAC-4 trial compared with 44.1% in the S-1 group of the JASPAC-01 trial. The large survival benefit difference between the two trials might because the JASPAC trial included patients with a better risk, such as a lower R1 resection rate (13 vs 60%), a lower proportion of CA19–9 levels exceeding the upper normal limit (26 vs 32%), and a higher proportion of N0 patients (37% vs 20%) and PS0 patients (69 vs 42%). Oral prodrugs of 5-FU are considered new standard treatment for patients with resectable PC after surgery despite racial differences. Global multicenter phase III studies are needed to further confirm racial differences and possibly the underlying mechanism, indicating a possible breakthrough for Asia PDAC patients. Evofosfamide is a prodrug that selectively targets tumor cells under hypoxic conditions and results in the release of a strong alkylating agent, dibromoisophosphoramide mustard. A phase II trial of evofosfamide demonstrated a 2.4-month longer PFS for unresectable PDAC than in those treated with gemcitabine alone (P = 0.005) [29]. Based on the encouraging result of the phase II study, the phase III MAESTRO randomized trial of evofosfamide and gemcitabine as first-line therapy was recently completed (NCT01746979), showing an improved OS compared with gemcitabine alone (mOS, 8.7 vs 7.6 months, P = 0.059). However, because patients from Asia achieved a longer OS than other races, further confirmation of subgroup analysis could be a breakthrough for Asia PDAC patients.

KRAS mediates signal transduction between membrane growth factor receptors and downstream pathways, such as PI3K/AKT/mTOR and RAS/RAF/MEK/ERK, which all contribute to tumor growth, progression, and metastasis [30]. Efforts have been made to target KRAS, but all have failed, such as the use of the farnesyltransferase inhibitor R115777 and tipifarnib [31, 32]. However, a new approach to target KRAS through engineered exosomes carrying short interfering RNA or short hairpin RNA specific to oncogenic Kras ^G12D was recently discovered in a PC mouse model and proved to be associated with increased OS [33]. The use of engineered exosomes and interfering RNA offered a potential prospective for even more accurate transportation for precision treatment. Chu et al. found that KRAS-integrin-linked kinase (ILK) allows PC cells to regulate KRAS expression, and the inhibition of ILK blocked KRAS-driven epithelial-to-mesenchymal transition (EMT) as well as growth factor-stimulated KRAS expression. Thus, ILK inhibitors may be a viable therapeutic strategy for PDAC [34].

Other therapeutic strategies were mainly developed targeting the downstream effectors MEK, PI3K/AKT, and ERK. The PI3K-AKT-mTOR signaling pathway regulates cell metabolism, cell cycle, protein synthesis, and apoptosis. The PI3K inhibitor LY294002 can inhibit cancer cell growth and suppress angiogenesis [35]. Drug combinations targeting multiple pathways might achieve a certain clinical benefit. However, the potent and highly selective MEK1/2 inhibitor selumetinib plus the PI3K/AKT inhibitor MK-2206 did not show a survival benefit but increased adverse events compared with mFOLFOX alone in gemcitabine-refractory MPC patients (Fig. 1) [36]. It is possible that the toxicity effects of two or more kinase inhibitors overlapped, and 45% of the patients in the experimental arm experienced toxicity-related treatment delays and dose reduction. Refametinib is an orally active, non-competitive MEK kinase inhibitor with high affinity to MEK 1/2. A continuous dosing regimen maximized refametinib-induced tumor growth inhibition. The half-life of refametinib was approximately 10–20 h after dosing on day 1, which was significantly longer than 8.3 h of selumetinib. Refametinib is generally well tolerated compared with selumetinib because grade 3–4 rash, and hematologic toxicity were observed more often in selumetinib users. The highly selective MEK1/2 inhibitor refametinib showed a promising ORR (ORR 23%; mOS, 8.9 months), similar to previously reported trametinib and gemcitabine (ORR 22%; mOS, 8.4 months) in advanced pancreatic cancer (APC) patients with detectable KRAS mutations (Fig. 2) [37, 38]. Because it showed a trend toward improved outcomes in APC patients without KRAS mutations (ORR 48%; mOS, 18.2 months), refametinib in combination with gemcitabine is especially encouraged when patients harbored KRAS mutations. MEK inhibitors showed disappointing efficacy as single agents because they often block the Ras-MARK pathway and activate PI3K together. The compromised efficacy might be due to the existence of resistance cells imposed by the MEK inhibitor and intratumoral heterogeneity [39]. A phase I study combining the PI3K inhibitor buparlisib with sonidegib or mFOLFOX6 was recently completed (NCT01571024). Moreover, cell cycle checkpoint inhibitors have been emerging in recent years and have showed considerable efficacy in reducing PC growth in preclinical study [40]. A phase II study of the PI3K/mTOR/DNA-PK inhibitor LY3023414 and CDK inhibitor abemaciclib is currently recruiting, and the results of this combination are awaited (NCT02981342, Table 1). Targeting the downstream effectors of KRAS mutation showed mediocre results, and more effort should be devoted to new approaches for targeting KRAS.

The mutations of tumor suppressor genes are more randomized and diverse; thus, it is very difficult to develop target therapy directly. SGT-53 is a complex of cationic liposome that could efficaciously deliver the p53 cDNA to the tumor cells. A phase II trial of SGT-53 and gemcitabine/nab-paclitaxel for MPC is ongoing (NCT02340117). Drugs targeting SMAD4 and CDKN2A are still under development.

Notch activation triggers pancreatic nestin (+) precursor cells to accumulate and metaplastic ductal epithelium to expand. By expanding undifferentiated precursor cells, it also mediates TGF-α, which induces epithelial differentiation. A phase II study of the Notch pathway inhibitor RO4929097 was launched among MPC patients as second- or third-line treatment, and it showed a cytostatic effect rather than cell death as monotherapy [41]. A phase I study of MK0752 added to gemcitabine hydrochloride as first-line treatment in late-stage PDAC has been completed (NCT01098344). The Notch2/Notch3 antagonist tarextumab reduced the tumor-initiating cell frequency in patient-derived xenograft tumors [42]. The ALPINE trial, which studied the addition of tarextumab to nab-paclitaxel and gemcitabine, was recently completed (NCT01647828). Ponnurangam et al. found that quinomycin significantly inhibited tumor growth in nude mice, coupled with the reduction of CSC markers and Notch signaling proteins [43]. Because unwanted gastrointestinal toxicity was associated with γ-secretase inhibitors (GSIs), chemopreventive natural agents, such as curcumin, sulphoraphane, and genistein, might serve as potential Notch inhibitors while easing the toxicity [44, 45].

The JAK family consists of JAK1, JAK2, JAK3, and TYK2, which play critical roles in hematopoiesis [46]. STAT3 is essential for disease progression in a PDAC mouse model harboring KRAS mutation [47]. High-throughput gene expression analysis found evidence of the JAK-STAT pathway in PDAC. Because phosphorylation of STAT transcription factors relies on the activation of JAK receptors, especially JAK2/STAT3, preclinical studies showed that the efficacy of JAK2 inhibitors could be predicated by phosphorylated STAT3 [47]. JAK/STAT together is related to inflammatory reaction and drives tumor progression [48, 49]. A double-blind, phase II study of the JAK1/JAK2 inhibitor ruxolitinib in combination with capecitabine for selected MPC patients with high levels of serum C-reactive protein levels showed prolonged survival and good tolerance [50]. The JANUS 1 trial is a phase III study of ruxolitinib and capecitabine as second-line therapy for MPC, but it was terminated because the results of planned interim analysis demonstrated futility (NCT02117479). Napabucasin—a STAT3 inhibitor—showed promising anti-cancer effects, as 52% of MPC patients achieved a ≥ 24-week disease control rate (DCR) in a phase Ib study (NCT02231723). A phase III study of napabucasin combined with nab-paclitaxel and gemcitabine for MPC is currently recruiting (NCT02993731).