Pancratistatin induces apoptosis in clinical leukemia samples with minimal effect on non-cancerous peripheral blood mononuclear cells

Chemotherapy for acute myeloid leukemia, despite earnest attempts, has not significantly changed in the last 30 years. Treatment continues to be based on the cytotoxic chemotherapies of anthracyclines and cytarabine. The natural compound, pancratistatin, extracted from the Hymenocallis littoralis, has broad-range efficacy against several cancer cell lines at 1 μM, with minimal effect on non-cancerous cell lines of the same origin [1, 2]. Pancratistatin treatment causes phosphatidyl-serine flipping, caspase-3 activation, generation of reactive oxygen species (ROS), and loss of mitochondrial membrane potential, which leads to apoptosis in cultured T-cell (Jurkat) leukemia cells [3]. Although pancratistatin is a non-genotoxic drug, its target has not yet been elucidated [3, 4]. The efficacy of pancratistatin in inducing apoptosis selectively in cultured (commercial) cancer cell lines is well established, though its effect on leukemia cells obtained from patients has not been tested. In this study, clinical leukemia and non-cancerous peripheral blood mononuclear cells (ncPBMCs) were treated with pancratistatin to determine its selectivity and efficacy to induce apoptosis ex vivo. Activity of pancratistatin was compared to that of the widely used chemotherapeutic, paclitaxel, against cancer cells. Peripheral blood samples from patients with a diagnosis of acute myeloid leukemia (AML; n = 11), acute lymphoid leukemia (ALL; n = 1), chronic myelogenous leukemia (CML; n = 1), chronic myelomonocytic leukemia (CMML; n = 1) and Mantle cell lymphoma (n = 1) were obtained. The majority of samples were taken at diagnosis, that is, in chemo-näive patients. Of the 15 patients, 5 did not go into remission with induction chemotherapy. The median duration of remission was 3 months. Our pre-clinical results demonstrate that pancratistatin is effective against all types of leukemia tested and does not induce apoptosis in non-cancerous mononuclear cells.

We report the novel finding that pancratistatin has selective apoptosis-inducing activity ex vivo at a low dose in a random sampling (n = 15) of patient-obtained leukemias. In contrast, pancratistatin has no effect on non-cancerous peripheral blood mononuclear cells (n = 8). Cellular subtypes in the PBMC samples may have differing sensitivities to pancratistatin and separation of these populations is needed to clarify this point, but requires much greater numbers. However, our results indicate that PBMCs collected from healthy volunteers of various ages were unaffected by pancratistatin. It is therefore unlikely that pancratistatin is toxic to a particular subtype of non-cancerous PBMC samples. The efficacy and selectivity of pancratistatin against clinical leukemia is based on 2 characteristic features of apoptosis, viz. nuclear morphology and lipid rearrangement within the plasma membrane. Our results suggest that pancratistatin could be a novel way to treat leukemia and may not cause adverse effects common to intravenous chemotherapy [5]. Paclitaxel has been used to treat many types of cancer, including leukemia, for over a decade; but it causes harsh side effects often associated with chemotherapy [6]. In contrast, pancratistatin is more effective against cancer cells than paclitaxel and has no significant effect on non-cancerous PBMC samples.

The mechanism of action and biochemical target of pancratistatin is currently being studied. Due to its broad-range effectiveness, we hypothesize that pancratistatin may selectively target cancer cell mitochondria, as opposed to a specific kinase or signalling protein. We have previously shown that pancratistatin causes mitochondrial membrane potential collapse and permeabilization, leading to reactive oxygen species (ROS) generation, cytochrome c leakage, caspase-3 activation, and apoptosis [1, 3, 7]. Recent reports indicate that some leukemia cells have increased basal levels of ROS, suggesting increased susceptibility to oxidative stress, which can lead to mitochondrial permeabilization and subsequent apoptosis [8]. It has also been reported that cancer cell mitochondria are dysfunctional and more susceptible to attack compared to non-cancerous cell mitochondria, which presents an opportunity for the development of new chemotherapeutics, especially for leukemia [9]. Liu et al.[10] reported that Lycorine, also an Amaryllidaceae alkaloid, induces caspase-dependent apoptosis in leukemia cells by down regulating the anti-apoptotic protein, Mcl-1. It is possible that pancratistatin is also targeting a protein that regulates the balance of apoptosis/survival, which could explain the broad-range efficacy of this compound against cancer cells in vitro. This is supported by our evaluation of pancratistatin on patient-obtained leukemia cells ex vivo at a low dose (1 μM).

Our results show that pancratistatin is an effective and selective anti-cancer agent with potential for advancement to clinical trials [11]. Targeted therapies are the holy grail of systemic cancer therapy; the ideal drug should kill cancer cells without harming non-cancerous cells. This is an exciting development in the treatment of AML, for which treatment regimens used over the last 30 years have not significantly improved survival.