Nonimmunosuppressive chemotherapy: EM011-treated mice mount normal T-cell responses to an acute lymphocytic choriomeningitis virus infection

Development of 9-(N-arylmethylamino) congeners of noscapine: the microtubule targeting drugs for the management of breast cancer

Noscapine is a natural lead molecule with anticancer activity at a higher concentrations. So, there is an urge for the development of more potent derivatives of noscapine. In this study, we have approached for development of 9-N-arylmethylamino derivatives of noscapine that kills cancer cells without affecting the normal cells. They were designed by substituting N-aryl methyl pharmacophore at the C-9 position and screened out top-ranked three derivatives 13a-c using molecular docking. Further, their theoretical free energy of binding with tubulin was calculated followed by chemical synthesis and experimental validation. In vitro antiproliferative activity of noscapine and its 9-N-arylmethylamino derivatives (13a-c) was carried out using MCF-7 (a triple receptors positive) and MDA-MB-231 (a triple receptor negative) breast cancer cell lines. Further, cytotoxicity to normal cells was examined using human embryonic kidney cells (HEK cells). Inhibition to cell cycle progression and induction of apoptosis was monitored using FACS. The binding of noscapine and 13a-c with tubulin was examined using fluorescence quenching assay. The 9-N-arylmethylamino derivatives of noscapine (13a-c) were found to inhibit the proliferation of cancer cells at a much lower concentration (IC50 values range between 9.1 to 47.3 µM) compared to noscapine (IC50 value is 45.8-59.3 µM). Surprisingly, the proliferation of HEK cells was not inhibited even at a concentration of 100 µM (cytotoxicity is < 5%). These derivatives induced apoptosis by arresting cells at G2/M-phase and also bind to tubulin. The 9-(N-arylmethylamino) noscapinoids have the potential to be a novel therapeutic agent for the treatment of breast cancer.

Supplementary Information

The online version contains supplementary material available at 10.1007/s13205-022-03445-3.

Comparison of in Vascular Bioreactors and In Vivo Models of Degradation and Cellular Response of Mg-Zn-Mn Stents

Traditional in vitro evaluation criteria of magnesium (Mg)-based stents cannot reflect the degradation process in vivo, due to the interdependence and interference between biodegradable properties and bioenvironment. The current direct and indirect evaluation approaches of in vitro biocompatibility do not have a hydrodynamic environment and vascular biological structure existing in vivo. Herein, we designed a vascular bioreactor to provide an ex vivo culture environment for vessels, which reveals the degradation behavior of Mg-Zn-Mn stent and the effect of its degradation on cells. We reported that rabbit carotid arteries could maintain native morphology and viability in the bioreactor under the best condition within a flow rate of 5.4 mL min^-1 and a culture time of one week. With this culture condition, Mg-Zn-Mn stents were implanted into the arteries in the bioreactors and compared with in vivo rabbit models. The arteries maintained cell survival in the bioreactor, but the cell attachment was absent on the stent struts, associated with a fast degradation. Conversely, the stents achieved a rapid and complete endothelialization in vivo for two weeks. This study could provide a correlation and difference of the degradation behavior and cellular response to the degradation of Mg-based stent between ex vivo and in vivo approaches.

Progress Toward the Development of Noscapine and Derivatives as Anticancer Agents

Many nitrogen-moiety containing alkaloids derived from plant origins are bioactive and play a significant role in human health and emerging medicine. Noscapine, a phthalideisoquinoline alkaloid derived from Papaver somniferum, has been used as a cough suppressant since the mid 1950s, illustrating a good safety profile. Noscapine has since been discovered to arrest cells at mitosis, albeit with moderately weak activity. Immunofluorescence staining of microtubules after 24 h of noscapine exposure at 20 μM elucidated chromosomal abnormalities and the inability of chromosomes to complete congression to the equatorial plane for proper mitotic separation ( Proc. Natl. Acad. Sci. U. S. A. 1998 , 95 , 1601 - 1606 ). A number of noscapine analogues possessing various modifications have been described within the literature and have shown significantly improved antiprolific profiles for a large variety of cancer cell lines. Several semisynthetic antimitotic alkaloids are emerging as possible candidates as novel anticancer therapies. This perspective discusses the advancing understanding of noscapine and related analogues in the fight against malignant disease.

Rational design, synthesis and biological evaluations of amino-noscapine: a high affinity tubulin-binding noscapinoid

Noscapine and its derivatives are important microtubule-interfering agents shown to have potent anti-tumor activity. The binding free energies (ΔG (bind)) of noscapinoids computed using linear interaction energy (LIE) method with a surface generalized Born (SGB) continuum solvation model were in agreement with the experimental ΔG (bind) with average root mean square error of 0.082 kcal/mol. This LIE-SGB model guided us in designing a novel derivative of noscapine, amino-noscapine [(S)-3-((R)-9-amino-4-methoxy-6-methyl-5,6,7,8-tetrahydro [1, 3] dioxolo[4,5-g]isoquinolin-5-yl)-6,7-dimethoxy isobenzo-furan-1(3H)-one] that has higher tubulin binding activity (predicted ΔG (bind) = -6.438 kcal/mol and experimental ΔG (bind) = -6.628 kcal/mol) than noscapine, but does not significantly change the total extent of the tubulin subunit/polymer ratio. The modes of interaction of amino-noscapine with the binding pocket of tubulin involved three hydrogen bonds and are distinct compared to noscapine which involved only one hydrogen bond. Also the patterns of non-bonded interactions are albeit different between both the lignads. The 'blind docking' approach (docking of ligand with different binding sites of a protein and their evaluations) as well as the reasonable accuracy of calculating ΔG (bind) using LIE-SGB model constitutes the first evidence that this class of compounds binds to tubulin at a site overlapping with colchicine-binding site or close to it. Our results revealed that amino-noscapine has better anti-tumor activity than noscapine.

Synergistic antimicrotubule therapy for prostate cancer

Prostate cancer has been widely viewed as a chemoresistant neoplasm. Perhaps, the most prevalent antimicrotubule strategy involves docetaxel administration at its maximum-tolerated dose (MTD). Although the goal is to obtain total eradication of cancer cells, debilitating toxicities are presented by docetaxel therapy, including myelosuppression, immunosuppression, gastrointestinal toxicity and peripheral neuropathy. In addition, solubility limitations necessitate infusion of high-doses intravenously once or twice a week followed by a rest period, which allows recovery of normal proliferating cells to counter-balance efficacy. An emerging notion is that more of a toxic drug at its MTD is not necessarily better. It is likely that combinatorial antimicrotubule therapy with drugs occupying different sites on tubulin may enhance efficacy while reducing toxicity. Here we show that bromonoscapine (EM011), a microtubule-modulating noscapine analog, displays synergism with docetaxel as seen by cell viability and proliferation assays. Cell-cycle data demonstrated that lower dose-levels of docetaxel (25nM) in combination with EM011 caused an additive increase in proapoptotic activity. Since docetaxel alone caused severe mitotic arrest followed by mitotic slippage and endoreduplication, we strategized a sequential treatment regime that involved initial pretreatment with docetaxel followed by addition of EM011 to maximize mitotic arrest and subsequent apoptosis. In vivo studies with docetaxel and EM011 in combination showed a marked inhibition of tumor growth compared to docetaxel or EM011 as single-agents. Our studies suggest the potential usefulness of EM011 in the clinic to enhance docetaxel activity. This would reduce toxicity, thus improving the quality of life of docetaxel-treated patients.

Potent anti-inflammatory activity of novel microtubule-modulating brominated noscapine analogs

Noscapine, a plant-derived, non-toxic, over-the-counter antitussive alkaloid has tubulin-binding properties. Based upon the structural resemblance of noscapine to colchicine, a tubulin-binding anti-inflammatory drug, noscapine and its semi-synthetic brominated analogs were examined for in vitro anti-inflammatory activity. Brominated noscapine analogs were found to inhibit cytokine and chemokine release from macrophage cell lines but did not affect cell viability. Brominated noscapine analogs demonstrated anti-inflammatory properties in both TLR- and non-TLR induced in vitro innate immune pathway inflammation models, mimicking septic and sterile infection respectively. In addition, electron microscopy and immunoblotting data indicated that these analogs induced robust autophagy in human macrophages. This study is the first report to identify brominated noscapines as innate immune pathway anti-inflammatory molecules.

EM011 activates a survivin-dependent apoptotic program in human non-small cell lung cancer cells

Background

Lung cancer remains a leading cause of cancer death among both men and women in the United States. Treatment modalities available for this malignancy are inadequate and thus new drugs with improved pharmacological profiles and superior therapeutic indices are being continually explored. Noscapinoids constitute an emerging class of anticancer agents that bind tubulin but do not significantly alter the monomer/polymer ratio of tubulin. EM011, a rationally-designed member of this class of non-toxic agents, is more potent than the lead molecule, noscapine.

Results

Here we report that EM011 inhibited proliferation of a comprehensive panel of lung cancer cells with IC₅₀'s ranging from 4-50 μM. In A549 human non-small cell lung cancer cells, the antiproliferative activity was mediated through blockage of cell-cycle progression by induction of a transient but robust mitotic arrest accompanied by activation of the spindle assembly checkpoint. The mitotically-arrested A549 cells then override the activated mitotic checkpoint and aberrantly exit mitosis without cytokinesis resulting in pseudo G1-like multinucleated cells that either succumb directly to apoptosis or continue another round of the cell-cycle. The accumulated enormous DNA perhaps acts as genotoxic stress to trigger cell death. EM011-induced apoptotic cell death in A549 cells was associated with a decrease of the Bcl2/BAX ratio, activation of caspase-3 and cleavage of PARP. Furthermore, EM011 induced downregulation of survivin expression over time of treatment. Abrogation of survivin led to an increase of cell death whereas, overexpression caused decreased apoptosis.

Conclusion

These in vitro data suggest that EM011 mediates antiproliferative and proapoptotic activity in non-small cell A549 lung cancer cells by impeding cell-cycle progression and attenuating antiapoptotic signaling circuitries (viz. Bcl2, survivin). The study provides evidence for the potential usefulness of EM011 in chemotherapy of lung cancer.