Synthesis and anticancer cell potential of steroidal 16,17-seco-16,17a-dinitriles: identification of a selective inhibitor of hormone-independent breast cancer cells.

We report the synthesis of steroidal 16,17-seco-16,17a-dinitriles and investigate their antitumor cell properties. Compounds were evaluated for anticancer potential by in vitro antiproliferation studies, molecular docking and virtual screening. Several compounds inhibit the growth of breast and prostate cancer cell lines (MCF-7, MDA-MB-231 and PC3), and/or cervical cancer cells (HeLa). Supporting this, molecular docking predicts that steroidal 16,17-seco-16,17a-dinitriles could bind with high affinity to multiple molecular targets of breast and prostate cancer treatment (aromatase, estrogen receptor α, androgen receptor and 17α-hydroxylase) facilitated by D-seco flexibility and nitrile-mediated contacts. Thus, 16,17-seco-16,17a-dinitriles may be useful for the design of inhibitors of multiple steroidogenesis pathways. Strikingly, 10, a 1,4-dien-3-on derivative, displayed selective submicromolar antiproliferative activity against hormone-dependent (MCF-7) and -independent (MDA-MB-231) breast cancer cells (IC50 0.52, 0.11µM, respectively). Ligand-based 3D similarity searches suggest AKR1C, 17ß-HSD and/or 3ß-HSD subfamilies as responsible for this antiproliferative activity, while fast molecular docking identified AKR1C and ERß as potential binders-both targets in the treatment of hormone-independent breast cancers.

Anticancer activity of novel steroidal 6-substituted 4-en-3-one D-seco dinitriles.

Steroidal 16,17-seco-16,17a-dinitriles possessing 4-ene-3,6-dione (3), 6-methylene-4-en-3-one (5), (6E)-hydroxyimino-4-en-3ß-ol (9) or (6E)-hydroxyimino-4-en-3-one (10) moiety were synthesized starting from 3ß-acetoxy-16,17-secoandrost-4-ene-16,17a-dinitrile (1). Antiproliferative activity of the newly synthesized compounds, as well as previously synthesized 3-oxo-16,17-secoandrosta-1,4-diene-16,17a-dinitrile (VII), was tested in vitro. Compound 9 displayed submicromolar antiproliferative activity against human cervical carcinoma (HeLa) cells (IC50 0.48 µM), and compounds 3 and 10 expressed strong inhibitory potential against HeLa cells (IC50 4.31 µM and 2.64 µM, respectively). Also, compound 10 was effective in inhibiting estrogen hormone-independent (MDA-MB-231) cells (IC50 2.78 µM). All tested compounds had no influence on the proliferation of healthy cells (MRC-5). Since MDA-MB-231 breast cancer cells and HeLa cervical cancer cells were most sensitive to treatment by 16,17-seco-16,17a-dinitriles, apoptosis induction after treatment by compounds 3, VII, 9 and 10 was studied in these cells, to reveal the mechanism underlying cell growth inhibition. All tested compounds significantly induced apoptosis in both treated cell lines, which was evident from results obtained by a double AO-EB staining test and quantified by counting cells with apoptotic morphology after staining with Giemsa dye. Among all tested substances, (6E)-hydroxyimino-4-en-3-one derivative 10 expressed the most proapoptotic activity.

Addition of vasopressin synthetic analogue [V(4)Q(5)]dDAVP to standard chemotherapy enhances tumour growth inhibition and impairs metastatic spread in aggressive breast tumour models.

[V(4)Q(5)]dDAVP is a novel 2nd generation vasopressin analogue with robust antitumour activity against metastatic breast cancer. We recently reported that, by acting on vasopressin V2r membrane receptor present in tumour cells and microvascular endothelium, [V(4)Q(5)]dDAVP inhibits angiogenesis and metastatic progression of the disease without overt toxicity. Despite chemotherapy remaining as a primary therapeutic option for aggressive breast cancer, its use is limited by low selectivity and associated adverse effects. In this regard, we evaluated potential combinational benefits by adding [V(4)Q(5)]dDAVP to standard-of-care chemotherapy. In vitro, combination of [V(4)Q(5)]dDAVP with sub-IC50 concentrations of paclitaxel or carmustine resulted in a cooperative inhibition of breast cancer cell growth in comparison to single-agent therapy. In vivo antitumour efficacy of [V(4)Q(5)]dDAVP addition to chemotherapy was first evaluated using the triple-negative MDA-MB-231 breast cancer xenograft model. Tumour-bearing mice were treated with i.v. injections of [V(4)Q(5)]dDAVP (0.3 µg/kg, thrice weekly) in combination with weekly cycles of paclitaxel (10 mg/kg i.p.). After 6 weeks of treatment, combination regimen resulted in greater tumour growth inhibition compared to monotherapy. [V(4)Q(5)]dDAVP addition was also associated with reduction of local aggressiveness, and impairment of tumour invasion and infiltration of the skin. Benefits of combined therapy were confirmed in the hormone-independent and metastatic F3II breast cancer model by combining [V(4)Q(5)]dDAVP with carmustine (25 mg/kg i.p.). Interestingly, [V(4)Q(5)]dDAVP plus cytotoxic agents severely impaired colony forming ability of tumour cells and inhibited breast cancer metastasis to lung. The present study shows that [V(4)Q(5)]dDAVP may complement conventional chemotherapy by modulating metastatic progression and early stages of microtumour establishment, and thus supports further preclinical testing of the compound for the management of aggressive breast cancer.