Suppression of KLF5 basal expression in oral carcinoma-derived cells through three intact CREB1-binding sites in the silencer region.

OBJECTIVES: Krüppel-like factor (KLF)5, which is overexpressed in carcinomas such as oral cancer, inhibits epidermal differentiation. KLF5 induces dedifferentiation of carcinoma cells, which effectuates carcinoma progression; nevertheless, the regulatory mechanism affecting the transcription of the KLF5 gene remains ambiguous. METHODS: Transcriptional activity of the KLF5 silencer, specifically the 425-bp region (425-region), was examined using reporter assays. An additional analysis was conducted to assess the impact of the minimal essential region (MER) of KLF5 on its basal expression. The affinity of cAMP responsive element binding protein 1 (CREB1) for three potential CREB1-binding sites in the 425-region was analyzed using DNA pull-down and quantitative chromatin immunoprecipitation assays. Reporter assays employing a human oral squamous carcinoma cell line, HSC2, transfected with small interfering RNA or complementary DNA for CREB1, were performed to investigate the effect of CREB1 binding sites on MER activity. RESULTS: The 425-region exhibited no transcriptional activity and suppressed MER transcriptional activity. This region encodes three putative CREB1-binding sites, and CREB1 demonstrated equal binding affinity for all three sites. The deletion of each of these binding sites reduced CREB1 precipitation and enhanced MER activity. Endogenous CREB1 knockdown and overexpression elevated and reduced MER activity, respectively, at the intact sites. Conversely, site deletion hampered and improved MER activity upon CREB1 knockdown and overexpression, respectively. CONCLUSIONS: Suppression of KLF5 basal expression via CREB1 binding to the 425-region requires all three CREB1-binding sites to remain intact in oral carcinoma cells. Consequently, deletion of the CREB1-binding site relieves suppression of KLF5 basal expression.

High mobility group AT-hook 2 regulates osteoblast differentiation and facial bone development.

The mutation and deletion of high mobility group AT-hook 2 (Hmga2) gene exhibit skeletal malformation, but almost nothing is known about the mechanism. This study examined morphological anomaly of facial bone in Hmga2-/- mice and osteoblast differentiation of pre-osteoblast MC3T3-E1 cells with Hmga2 gene knockout (A2KO). Hmga2-/- mice showed the size reduction of anterior frontal part of facial bones. Hmga2 protein and mRNA were expressed in mesenchymal cells at ossification area of nasal bone. A2KO cells differentiation into osteoblasts after reaching the proliferation plateau was strongly suppressed by alizarin red and alkaline phosphatase staining analyses. Expression of osteoblast-related genes, especially Osterix, was down-regulated in A2KO cells. These results demonstrate a close association of Hmga2 with osteoblast differentiation of mesenchymal cells and bone growth. Although future studies are needed, the present study suggests an involvement of Hmga2 in osteoblast-genesis and bone growth.

Domain structures of mucosa-associated lymphoid tissue lymphoma translocation 1 protein for nuclear localization in oral carcinoma cells and the proliferation inhibition.

Mucosa-associated lymphoid tissue lymphoma translocation 1 protein (MALT1) consisting of death domain, Ig-like domains and caspase-like domain is expressed in nucleus of oral carcinoma cells, and loss of the expression closely associates with disease progression and stimulates proliferation of the cells. However, nothing is known about the molecular backgrounds. In this study, eight constructs with different domain constitution of human MALT1 and six constructs were transiently and stably transfected into oral carcinoma cell lines, respectively. The immunoblot analysis showed that constructs containing caspase-like domain was expressed in nucleus and the domain-deleted constructs in cytoplasm. Immunocytochemistry of stably transfected HSC2 oral carcinoma cells confirmed the caspase-like domain-dependent nuclear localization. Involvement of domains in proliferation of stably transfected HSC2 cells was quantified by the real-time and conventional colorimetric assays. In contrast to suppression of the proliferation by full-length wild-type MALT1, any domain-deleted constructs enhanced the proliferation. Death domain construct without caspase-like domain suppressed the proliferation when it was localized in nucleus by ligating with the nuclear localization signal. These results demonstrate that nuclear localization of MALT1 in oral carcinoma cells depends on the presence of caspase-like domain and that death domain nuclear entity is responsible for MALT1 inhibition of oral carcinoma cell proliferation. Nuclear localization of death domain led by caspase-like domain may suppress oral carcinoma progression.