Glioma is one of the most common primary malignant tumors of the central nervous system accounting for approximately 40% of all intracranial tumors. Temozolomide is a conventional chemotherapy drug for adjuvant treatment of patients with high-risk gliomas, including grade II to grade IV. Our bioinformatic analysis of The Cancer Genome Atlas and Chinese Glioma Genome Atlas datasets and immunoblotting assay show that SLC12A2 gene and its encoded Na+-K+-2Cl− cotransporter isoform 1 (NKCC1) protein are abundantly expressed in grade II–IV gliomas. NKCC1 regulates cell volume and intracellular Cl− concentration, which promotes glioma cell migration, resistance to temozolomide, and tumor-related epilepsy in experimental glioma models. Using mouse syngeneic glioma models with intracranial transplantation of two different glioma cell lines (GL26 and SB28), we show that NKCC1 protein in glioma tumor cells as well as in tumor-associated reactive astrocytes was significantly upregulated in response to temozolomide monotherapy. Combination therapy of temozolomide with the potent NKCC1 inhibitor bumetanide reduced tumor proliferation, potentiated the cytotoxic effects of temozolomide, decreased tumor-associated reactive astrogliosis, and restored astrocytic GLT-1 and GLAST glutamate transporter expression. The combinatorial therapy also led to suppressed tumor growth and prolonged survival of mice bearing GL26 glioma cells. Taken together, these results demonstrate that NKCC1 protein plays multifaceted roles in the pathogenesis of glioma tumors and presents as a therapeutic target for reducing temozolomide-mediated resistance and tumor-associated astrogliosis.
We previously identified an up-regulation of specific Wnt proteins in the cholangiocyte compartment during cholestatic liver injury and found that mice lacking Wnt secretion from hepatocytes and cholangiocytes showed fewer proliferating cholangiocytes and high mortality in response to a 3,5-diethoxycarbonyl-1,4-dihydrocollidine (DDC) diet, a murine model of primary sclerosing cholangitis. In vitro studies demonstrated that Wnt7b, one of the Wnts upregulated during cholestasis, induces proliferation of cholangiocytes in an autocrine manner and increases secretion of proinflammatory cytokines. We hypothesized that loss of Wnt7b may exacerbate some of the complications of cholangiopathies by decreasing the ability of bile ducts to induce repair. Wnt7b-flox mice were bred with Krt19-cre mice to deplete Wnt7b expression in only cholangiocytes (CC) or with albumin-Cre mice to delete Wnt7b expression in both hepatocytes and cholangiocytes (HC + CC). These mice were placed on a DDC diet for 1 month then killed for evaluation. Contrary to our expectations, we found that mice lacking Wnt7b from CC and HC + CC compartments had improved biliary injury, decreased cellular senescence, and lesser bile acid accumulation after DDC exposure compared to controls, along with decreased expression of inflammatory cytokines. Although Wnt7b knockout (KO) resulted in fewer proliferating cholangiocytes, CC and HC + CC KO mice on a DDC diet also had more hepatocytes expressing cholangiocyte markers compared to wild-type mice on a DDC diet, indicating that Wnt7b suppression promotes hepatocyte reprogramming. Conclusion: Wnt7b induces a proproliferative proinflammatory program in cholangiocytes, and its loss is compensated for by conversion of hepatocytes to a biliary phenotype during cholestatic injury. (Hepatology Communications 2021;0:1-16).
Striatal dopamine (DA) neurotransmission is critical for an array of reward-related behaviors and goal-directed motor control. In rodents, 95% of striatal neurons are GABAergic medium spiny neurons (MSNs) that have been traditionally segregated into two subpopulations based on the expression of stimulatory DA D1-like receptors versus inhibitory D2-like receptors. However, emerging evidence suggests that striatal cell composition is anatomically and functionally more heterogenous than previously appreciated. The presence of MSNs that co-express multiple DA receptors offers a means to more accurately understand this heterogeneity. To dissect the precise nature of MSN heterogeneity, here we used multiplex RNAscope to identify expression of three predominantly expressed DA receptors in the striatum: DA D1 (D1R), D2 (D2R), and D3 (D3R) receptors. We report heterogenous subpopulations of MSNs that are distinctly distributed across the dorsal-ventral and rostral-caudal axes of the adult mouse striatum. These subpopulations include MSNs that co-express D1R and D2R (D1/2R), D1R and D3R (D1/3R), and D2R and D3R (D2/3R). Overall, our characterization of distinct MSN subpopulations informs our understanding of region-specific striatal cell heterogeneity.
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