We have analyzed the role of glutamate and its receptors (GluRs) in regulating the development of oligodendrocytes. Activation of AMPA-preferring GluRs with selective agonists inhibited proliferation of purified cortical oligodendrocyte progenitor (O-2A) cells cultured with different mitogens, as measured by [3H]thymidine incorporation or bromodeoxyuridine staining. In contrast, activation of GABA or muscarinic receptors did not affect O-2A proliferation. Cell viability and apoptosis assays demonstrated that the inhibition of O-2A proliferation was not attributable to a cytotoxic action of GluR agonists, and was reversible. Activation of GluRs prevented lineage progression from the O-2A (GD3+/nestin+) stage to the prooligodendroblast (O4+) stage, but did not affect O-2A migration. Additional experiments examined the membrane ionic channels mediating these GluR activation effects. We found that proliferating O-2A cells expressed functional delayed rectifier K+ channels, which were absent in pro-oligodendroblasts. GluR agonists and the K+ channel blocker tetraethylammonium (TEA) strongly inhibited delayed rectifier K+ currents in O-2A cells. TEA reproduced the effects of GluR activation on O-2A proliferation and lineage progression in the same concentration range that blocked delayed rectifier K+ currents. These results indicate that glutamate regulates oligodendrogenesis specifically at the O-2A stage by modulating K+ channel activity.
Neural cell development is regulated by membrane ion channel activity. We have previously demonstrated that cell membrane depolarization with veratridine or blockage of K+ channels with tetraethylammonium (TEA) inhibit oligodendrocyte progenitor (OP) proliferation and differentiation (); however the molecular events involved are largely unknown. Here we show that forskolin (FSK) and its derivative dideoxyforskolin (DFSK) block K+ channels in OPs and inhibit cell proliferation. The antiproliferative effects of TEA, FSK, DFSK, and veratridine were attributable to OP cell cycle arrest in G1 phase. In fact, (1) cyclin D accumulation in synchronized OP cells was not affected by K+ channel blockers or veratridine; (2) these agents prevented OP cell proliferation only if present during G1 phase; and (3) G1 blockers, such as rapamycin and deferoxamine, mimicked the anti-proliferative effects of K+ channel blockers. DFSK also prevented OP differentiation, whereas FSK had no effect. Blockage of K+ channels and membrane depolarization also caused accumulation of the cyclin-dependent kinase inhibitors p27(Kip1) and p21(CIP1) in OP cells. The antiproliferative effects of K+ channel blockers and veratridine were still present in OP cells isolated from INK4a-/- mice, lacking the cyclin-dependent kinase inhibitors p16(INK4a) and p19(ARF). Our results demonstrate that blockage of K+ channels and cell depolarization induce G1 arrest in the OP cell cycle through a mechanism that may involve p27(Kip1) and p21(CIP1) and further support the conclusion that OP cell cycle arrest and differentiation are two uncoupled events.
The bladder is a target organ for inorganic arsenic, a carcinogen and common environmental contaminant found in soil and water. Urothelial carcinoma (UC) is the most common type of bladder cancer (BC) that develops into papillary or non-papillary tumors. Papillary tumors are mostly non-muscle invasive (NMIUC), easier treated, and have a better prognosis. Urothelial carcinoma can be molecularly sub-typed as luminal or basal, with papillary tumors generally falling into the luminal category and basal tumors exclusively forming muscle invasive urothelial carcinomas (MIUC). It is unclear why some UCs develop more aggressive basal phenotypes. We hypothesized that chronic arsenic exposure of a papillary luminal bladder cancer would lead to the development of basal characteristics and increase in invasiveness. We treated the human papillary bladder cancer cell line RT4 with 1 µM arsenite (As3+) for twenty passages. Throughout the study, key luminal and basal gene/protein markers in the exposed cells were evaluated and at passage twenty, the cells were injected into athymic mice to evaluate tumor histology and measure protein markers using immunohistochemistry. Our data indicates that chronic As3+- treatment altered cellular morphology and decreased several luminal markers in cell culture. The histology of the tumors generated from the As3+-exposed cells was similar to the parent (non-treated) however, they appeared to be more invasive in the liver and displayed elevated levels of some basal markers. Our study demonstrates that chronic As3+ exposure is able to convert a non-invasive papillary bladder cancer to an invasive form that acquires some basal characteristics.
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