Differential biological effects of dehydroepiandrosterone (DHEA) between mouse (B16F10) and human melanoma (BLM) cell lines.

Dehydroepiandrosterone (DHEA) is a weak androgen and had been shown to have anti-cancer, anti-adipogenic and anti-inflammatory effects on mouse and other rodent models, but not on humans, suggesting a systemic level difference between mouse and human. Our previous study on DHEA biological functions involving a variety of cell lines, suggested that the functional differences between mouse and human existed even at the cellular level. Hence, using mouse and human melanoma cell models, in-vitro effects of DHEA on cell growth, mechanism of cell death and mechanism of DHEA action were studied. Results indicated a differential biological effects of DHEA between mouse and human melanoma cell lines. These in-vitro studies also suggested that the differential biological effects observed between these two cell lines could be due to the difference in the way DHEA was processed or metabolized inside the cell.

In-vitro rescue and recovery studies of human melanoma (BLM) cell growth, adhesion and migration functions after treatment with progesterone.

Treatment of human melanoma (BLM) cells for 48 hrs with progesterone resulted in a significant inhibition of cell growth. The mechanism of growth inhibition was due to autophagy and this action of progesterone was not mediated through progesterone receptor. As cells were floating during treatment, adhesion assay was performed, which showed complete loss of adhesion. When cells were allowed to recover after treatment by culturing in growth medium without progesterone, there was recovery in cell growth. Preliminary experiments on adhesion and recovery cell growth prompted us to suppress autophagic lysosomal degradation with 3-methyladenine (3-MA), which resulted in partial rescue of cell growth, adhesion and migration functions. The above experimental design gave rise to two experimental groups viz., progesterone treated and 3-MA rescued. Since, recovery studies also showed improvement in cell growth, progesterone treated and 3-MA rescued groups were allowed to recover on their own for first 48 hrs and then a second 48 hrs. Comparison of in-vitro cell growth, adhesion and migration functions of progesterone treated, 3-MA rescued and recovered human melanoma cells revealed that the recovery of 3-MA rescued cells was better than the recovery of progesterone treated cells in terms of cell growth and adhesion functions. These in-vitro experiments not only provided the scientific basis for epidemiological findings that menstruating females were better protected in melanoma, but also showed the potential of progesterone to act as an anti-cancer agent for melanoma treatment.

In vitro effect of progesterone on human melanoma (BLM) cell growth.

Epidemiological data suggest there is a female sex advantage in melanoma skin cancer. Female sex hormones have been attributed to this protection. There has been no experimental evidence to link female sex hormones directly with melanoma protection until our recently published work on mouse melanoma (B16F10) cells. Our recently published work showed that progesterone significantly inhibited mouse melanoma cell growth in vitro. This study was extended to human melanoma (BLM) cells. Research work revealed that progesterone inhibited human melanoma cell growth also in vitro. The mechanism of inhibition was due to autophagy and this effect of progesterone was not mediated through progesterone receptor.

Delta-4-androstene-3,17-dione binds androgen receptor, promotes myogenesis in vitro, and increases serum testosterone levels, fat-free mass, and muscle strength in hypogonadal men.

Previous studies of Delta 4-androstene-3,17-dione (4-androstenedione) administration in men have not demonstrated sustained increments in testosterone levels, fat-free mass (FFM), and muscle strength, and failure to demonstrate androstenedione's androgenic/anabolic effects has stifled efforts to regulate its sales. To determine whether 4-androstenedione has androgenic/anabolic properties, we evaluated its association with androgen receptor (AR) and its effects on myogenesis in vitro. Additionally, we studied the effects of a high dose of 4-androstenedione on testosterone levels, FFM, and muscle strength in hypogonadal men. We determined the dissociation constant (K(d)) for 4-androstenedione using fluorescence anisotropy measurement of competitive displacement of fluorescent androgen from AR ligand-binding domain. AR nuclear translocation and myogenic activity of androstenedione were evaluated in mesenchymal, pluripotent C3H10T1/2 cells, in which androgens stimulate myogenesis through an AR pathway. We determined effects of a high dose of androstenedione (500 mg thrice daily) given for 12 wk on FFM, muscle strength, and hormone levels in nine healthy, hypogonadal men. 4-Androstenedione competitively displaced fluorescent androgen from AR ligand-binding domain with a lower affinity than dihydrotestosterone (K(d), 648 +/- 21 and 10 +/- 0.4 nm, respectively). In C3H10T1/2 cells, 4-androstenedione caused nuclear translocation of AR and stimulated myogenesis, as indicated by a dose-dependent increase in myosin heavy chain II+ myotube area and up-regulation of MyoD protein. Stimulatory effects of 4-androstenedione on myosin heavy chain II+ myotubes and myogenic determination factor expression were attenuated by bicalutamide, an AR antagonist. Administration of 1500 mg 4-androstenedione daily to hypogonadal men significantly increased serum androstenedione, total and free testosterone, estradiol, and estrone levels and suppressed SHBG and high-density lipoprotein cholesterol levels. 4-androstenedione administration was associated with significant gains in FFM (+1.7 +/- 0.5 kg; P = 0.012) and muscle strength in bench press (+4.3 +/- 3.1 kg; P = 0.006) and leg press exercises (+18.8 +/- 17.3 kg; P = 0.045). 4-androstenedione is an androgen that binds AR, induces AR nuclear translocation, and promotes myogenesis in vitro, with substantially lower potency than dihydrotestosterone. 4-androstenedione administration in high doses to hypogonadal men increases testosterone levels, FFM, and muscle strength, although at the dose tested, the anabolic effects in hypogonadal men are likely because of its conversion to testosterone.

Effect of mutational inactivation of tyrosine kinase activity on BCR/ABL-induced abnormalities in cell growth and adhesion in human hematopoietic progenitors.

Chronic myelogenous leukemia (CML) results from transformation of a primitive hematopoietic cell by the BCR/ABL gene. The specific BCR/ABL signaling mechanisms responsible for transformation of primitive human hematopoietic cells are not well defined. Previous studies have suggested that constitutively activated tyrosine kinase activity plays an important role for in abnormal proliferation of CML progenitors but has not clearly defined its role in abnormal adhesion and migration. We established a human progenitor model of CML by ectopic expression of BCR/ABL in normal CD34+ cells using retrovirus-mediated gene transfer. CD34+ cells expressing BCR/ABL demonstrated several features characteristic of primary CML progenitors including increased proliferation in committed and primitive progenitor culture, reduced adhesion to fibronectin, and reduced chemotaxis to stroma-derived factor-1alpha. We expressed a kinase-inactive BCR/ABL gene to directly investigate the role of kinase activity in abnormal progenitor function. Abnormalities in proliferation were completely reversed, whereas defects in adhesion and migration were significantly improved but not completely reversed in cells expressing a kinase-inactive BCR/ABL. Furthermore, the BCR/ABL kinase inhibitor imatinib mesylate markedly inhibited proliferation of BCR/ABL-expressing progenitors but did not fully correct the adhesion and migration defects. Expression of BCR/ABL genes with deletions of either the COOH-terminal actin binding or proline-rich domains resulted in enhanced adhesion and chemotaxis compared with wild-type BCR/ABL but did not affect progenitor proliferation. We conclude that abnormal kinase activity is essential for abnormal proliferation and survival of CML progenitors but that abnormal adhesion and migration result from both kinase-dependent and -independent mechanisms.