As shown in Figure 5B, in mir-29a over-expressed cells, the expression of luciferase was dramatically inhibited (P < 0.01). In contrast with inhibition of mir-29a on wild type 3′-UTR of B-Myb, mir-29a cannot inhibit the luciferase expression (P > 0.05), when the binding site of mir-29a in 3′-UTR of B-Myb was mutated. Consistent with this, in MDA-MB-453 cells that over-expressed Mir-29a, protein level of B-Myb decreased (Figure 5C). Consistently in these cells, the downstream effectors of KU-57788 solubility dmso B-Myb such as learn more cyclin A2 and D1 were also down-regulated by Mir-29a over-expression (Figure 5C). On the contrary, in MCF-10A cells with Mir-29a knockdown, the protein level of B-Myb is dramatically up-regulated (Figure 5D).
Consistent with an increased level of B-Myb, in MCF-10A cells, levels of Cyclin A2 and D1 were also up-regulated. All these findings suggested that Mir-29a probably regulates cell growth through B-Myb. Figure 5 B-Myb acts as the downstream effector of mir-29a to regulate cell cycle. A, the scheme of the plasmid construction for the luciferase assay. B, relative luciferase activities of the cells (with or without mir-29a
over-expression) transfected with either wild or Nepicastat price mutant 3′-UTR of B-Myb; n = 5, Mean ± SD. C, protein levels of cyclin A2, cyclin D1 and B-Myb in MDA-MB-453 cells with or without mir-29a over-expression. D, protein levels of cyclin A2, cyclin D1 and B-Myb in MCF-10A cells with or without mir-29a knockdown. Discussion As described earlier, the function of Mir-29a in tumorigenesis and metastasis remains controversial. Muniyappa et al. showed that Mir-29a was down-regulated in invasive lung cancer cells and invasive phenotype of cancer cells could be suppressed by ectopic expression of Mir-29a [23]. Study from Xu et al. mafosfamide also showed that expression level of Mir-29a is significantly lower in various
solid tumors [24]. In contrast, Mir-29a is also shown to be up-regulated in certain leukemia cells [25]. In this study, we focused on the role of Mir-29a in breast cancers cells. We showed that expression level of Mir-29a is down-regulated in various breast cancer cells (Figure 2). This data indicates that Mir-29a expression is probably associated with breast cancer. One piece of evidence to support this hypothesis is that over-expression of Mir-29a in breast cancer cells significantly reduce cancer cell growth rate (Figure 3B). Consistent with this result, knockdown of Mir-29a in normal mammary epithelial cells cause higher cell growth rate (Figure 4B). These data strongly suggested Mir-29a inhibited tumorigeneses through suppression of cell growth. We also showed that the inhibitory effect of Mir-29a to breast cancer cells is probably due to its role in arresting cells in G0/G1 cells (Figure 3C-E and 4C-E). Previous studies showed that Mir-29a is able to suppress the expression of tristetraprolin, which is involved in epithelial-to-mesenchymal transition [17].