MC1R signaling through the cAMP-CREB/ATF-1 and ERK-NFκB pathways accelerates G1/S transition promoting breast cancer progression.

MC1R, a G-protein coupled receptor, triggers ultraviolet light-induced melanin synthesis and DNA repair in melanocytes and is implicated in the pathogenesis of melanoma. Although widely expressed in different tissue types, its function in non-cutaneous tissue is relatively unknown. Herein, we demonstrate that disruptive MC1R variants associated with melanomagenesis are less frequently found in patients with several cancers. Further exploration revealed that breast cancer tissue shows a significantly higher MC1R expression than normal breast tissue, and knocking down MC1R significantly reduced cell proliferation in vitro and in vivo. Mechanistically, MC1R signaling through the MC1R-cAMP-CREB/ATF-1 and MC1R-ERK-NFκB axes accelerated the G1-S transition in breast cancer cells. Our results revealed a new association between MC1R and breast cancer, which could be potentially targeted therapeutically. Moreover, our results suggest that MC1R-enhancing/activating therapies should be used cautiously, as they might be pro-tumorigenic in certain contexts.

The quantity and distribution of biofilm growth of Escherichia coli strain ATCC 9723 depends on the carbon/energy source.

Escherichia coli strain 15 (ATCC 9723) formed robust biofilms of two distinct forms on glass tubes. In rich, low-osmolarity medium, the biofilms were restricted to the air/liquid interface, resulting in rings attached to the glass. As it was not evident that these biofilms extended across the liquid surface, we termed them 'ring' rather than 'pellicle' biofilms. In minimal medium supplemented with a non-fermentable substrate as the carbon/energy source, we observed either robust ring biofilms or little biofilm of any type, depending on the substrate. In contrast, fermentable substrates (sugars and sugar derivatives) supported robust biofilms covering most of the solid/liquid interface, which we termed 'tube-covering biofilms'. Maximal biofilm growth was observed when the sugar was a relatively poor substrate, supporting slow growth and known to cause minimal dephosphorylation of regulatory protein Enzyme IIAGlucose of the phosphotransferase system. Compounds found to be inhibitors of biofilm growth, such as lactate, caused a shift from tube-covering to ring form at low concentration and complete loss of biofilm growth at high when added to minimal medium supplemented with a fermentable substrate. Exogenous cAMP activated biofilm growth under all conditions tested, leading to more intense ring or tube-covering biofilms and/or to a shift from ring to tube-covering form.