Depot-specific and hypercaloric diet-induced effects on the osteoblast and adipocyte differentiation potential of adipose-derived stromal cells.

Adipose-derived stromal cells (ADSCs) can be differentiated in vitro into several mesenchyme-derived cell types. We had previously described depot-specific differences in the adipocyte differentiation of ADSCs, and consequently we hypothesized that there may also be depot-specific differences in osteoblast differentiation of ADSCs. For this study, the osteoblast differentiation potential of rat subcutaneous ADSCs (scADSCs) and perirenal visceral ADSCs (pvADSCs) was compared. Osteoblast differentiation media (OM) induced markers of the osteoblastic phenotype in scADSCs, but not in pvADSCs. ADSCs harvested from rats with diet-induced visceral obesity (DIO) exhibited reduced osteoinduction, compared to lean controls, but adipocyte differentiation was not affected. Expression of the pro-osteogenic transcription factor Msx2 was significantly higher in naïve scADSCs from lean and DIO rats than in pvADSCs. Our findings indicate that ADSCs from different anatomical sites are uniquely pre-programmed in vivo in a depot-specific manner, and that diet-induced metabolic disturbances translate into reduced osteoblast differentiation of ADSCs.

Cytotoxicity and cell death pathways invoked by two new rhodium-ferrocene complexes in benign and malignant prostatic cell lines.

BACKGROUND: Apoptotic propensity is currently viewed as an important parameter in drug-induced toxicity. But other cell death pathways exist e.g. micronucleation, intermitotic cell death, abnormal nuclear morphology and necrosis. This investigation explores the onset of apoptosis and abnormal morphology in response to 3 drugs i.e. Cisplatin, a novel Ferrocene (fctfa) and a novel Rhodium-Ferrocene [Rh(fctfa)(cod)] complex. MATERIALS AND METHODS: A pair of prostate cell lines from normal human prostate epithelium (1542N) and malignant human prostate epithelium (1542T) were exposed to increasing concentrations of the drugs for 24 hours, double-stained with FITC-Annexin V and with Propidium Iodide and analysed by dual parameter flow cytometry to quantitate viable cells in quadrant I, early apoptotic cells in quadrant IV and late apoptotic/necrotic cells in quadrant III. Apoptosis was also scored by microscopy after Acridine Orange staining, by Western blots for caspase 3 induction and for caspase 8 induction using a colorimetric assay. RESULTS: The toxicity of Cisplatin and the Ferrocene and Rhodium-Ferrocene complexes was found to be 0.9-1.3 microM; 4.1-4.5 microM and 10.1-13.2 microM, respectively. Apoptotic propensity scored after 24 hours was found to be dose-dependent and in the range of 7-19% for Cisplatin and 1-4.1% for the Ferrocene and Rhodium-Ferrocene complexes. Cisplatin produces a distinct apoptotic response followed by a necrotic response, whereas the Ferrocene and the Rhodium-Ferrocene complexes produce a massive necrotic reaction in the region of 3-19% and very little if any apoptosis. Absence of apoptosis was corroborated by lack of caspase 3 activation, absence of typical apoptotic morphology and by lack of caspase 8 activation. CONCLUSION: The 3 drugs Cisplatin, the novel Ferrocene and the novel Rhodium-Ferrocene complexes show similar toxicities in the 1-10 micro-molar range in prostate cell lines. However the drugs differ significantly in the activation of death pathways. While Cisplatin predominantly induces apoptosis documented by morphology, Annexin V staining and caspase 8 activation, the Ferrocene and Rhodium-Ferrocene complexes induce late necrosis and abnormal nuclear morphology. Unlike Cisplatin-treated cells which enter apoptosis and necrosis sequentially, the 2 Ferrocene drugs invoke direct entry of cells into late necrosis without first entering the early apoptotic compartment.