Comparison of anti-inflammatory mechanisms between doxofylline and theophylline in human monocytes.

BACKGROUND: Methylxanthines are important pharmacological agents in the treatment of asthma and of chronic obstructive pulmonary diseases. The present study was designed to compare the ability of doxofylline and theophylline to modulate inflammatory pathways in human monocytes. METHODS: Monocytes isolated from healthy anonymous human buffy coats were treated with doxofylline or theophylline in the presence of phorbol 12-myristate 13-acetate (PMA) or lipopolysaccharide (LPS), and their phenotype, the oxidative burst, cytokine expression and release, cAMP production, and protein kinase C (PKC) activity were evaluated. RESULTS: Doxofylline and theophylline did not have overlapping effects on human monocytes. While sharing some common characteristics, they differed significantly in their selectivity. Theophylline affected LPS- above PMA-induced cellular responsivity, while doxofylline behaved in the opposite manner. Furthermore, when testing PKC activity, we found an inhibitory effect of doxofylline but not of theophylline, at equimolar doses. CONCLUSIONS: In conclusion, our data support the growing hypothesis that doxofylline does not have a superimposable mechanism of action compared to theophylline, and this may both explain some differences in the risk/benefit ratio and may direct studies to tailor therapy for patients.

Bitter taste receptor (TAS2R) 46 in human skeletal muscle: expression and activity.

Bitter taste receptors are involved not only in taste perception but in various physiological functions as their anatomical location is not restricted to the gustatory system. We previously demonstrated expression and activity of the subtype hTAS2R46 in human airway smooth muscle and broncho-epithelial cells, and here we show its expression and functionality in human skeletal muscle cells. Three different cellular models were used: micro-dissected human skeletal tissues, human myoblasts/myotubes and human skeletal muscle cells differentiated from urine stem cells of healthy donors. We used qPCR, immunohistochemistry and immunofluorescence analysis to evaluate gene and protein hTAS2R46 expression. In order to explore receptor activity, cells were incubated with the specific bitter ligands absinthin and 3ß-hydroxydihydrocostunolide, and calcium oscillation and relaxation were evaluated by calcium imaging and collagen assay, respectively, after a cholinergic stimulus. We show, for the first time, experimentally the presence and functionality of a type 2 bitter receptor in human skeletal muscle cells. Given the tendentially protective role of the bitter receptors starting from the oral cavity and following also in the other ectopic sites, and given its expression already at the myoblast level, we hypothesize that the bitter receptor can play an important role in the development, maintenance and in the protection of muscle tissue functions.

Characterization of a functional Ca2+ toolkit in urine-derived stem cells and derived skeletal muscle cells.

Muscular diseases are characterized by a wide genetic diversity and the Ca2+-signalling machinery is often perturbed. Its characterization is therefore pivotal and requires appropriate cellular models. Muscle biopsies are the best approach but are invasive for the patient and difficult to justify if the biopsy is not for diagnostic purposes. To circumvent this, interest is mounting in urine-derived stem cells that can be differentiated into skeletal muscle cells. In the present study, we isolated stem cells from urine (USC) samples of healthy donors and differentiated them by MyoD lentiviral vector transduction into skeletal muscle cells (USC-SkMC). As expected, USCs and USC-SkMCs are characterized by a radically different pattern of expression of stem and skeletal muscle markers. Characterization of cells in the present manuscript focused on Ca2+-signalling. Undifferentiated and differentiated cells differed in the expression of key proteins involved in Ca2+-homeostasis and also displayed different Ca2+-responses to external stimuli, confirming that during differentiation there was a transition from a non-excitable to an excitable phenotype. In USCs, the main mechanism of calcium entry was IP3 dependent, suggesting a major involvement of receptor-operated Ca2+ entry. Indeed, U-73122 (a PLC inhibitor) significantly inhibited the Ca2+increase triggered by ATP both in calcium and calcium-free conditions. In USC-SkMCs both store- and receptor-operated calcium entry were active. Furthermore, a caffeine challenge led to Ca2+ release both in the presence or absence of extracellular calcium, which was inhibited by ryanodine, suggesting the presence and functionality of ryanodine receptors in USC-SkMCs. Lastly, the voltage-operated calcium channels are operative in USC-SkMCs, unlike in USCs, since stimulation with high concentration of KCl induced a significant calcium transient, partially reversed by verapamil. Our data therefore support the use of skeletal muscle cells derived from USCs as an easily amenable tool to investigate Ca2+-homeostasis, in particular in those (neuro)muscular diseases that lack valid alternative models.