TMSB10, a potential prognosis prediction biomarker, promotes the invasion and angiogenesis of gastric cancer.

BACKGROUND AND AIM: The thymosin beta 10 (TMSB10) was originally identified from the thymus, which plays a key role in the development of many cancers. However, the underlying molecular mechanisms of TMSB10 involved in GC have not been understood. METHODS: We sought to determine the expression of TMSB10 in human GC tissues and illustrate whether it is correlated with the clinical pathologic characteristics and prognosis in GC patients. Its roles and potential mechanisms in regulating tumor growth, invasion, and angiogenesis were evaluated by TMSB10 knockdown/overexpression of GC cells in vitro and ex vivo. RESULTS: Marked overexpression of TMSB10 protein expression was observed in GC cells and tissues, which was associated with the advanced tumor stage and lymph nodes (LN) metastasis of GC patients. Furthermore, prognostic analysis showed that GC patients with high TMSB10 expression had a remarkably shorter survival and acted as an important factor for predicting poor overall survival in GC patients. Moreover, TMSB10 overexpression promoted, while TMSB10 knockdown the proliferation, EMT process, and angiogenesis of GC cells. CONCLUSION: The study highlights that TMSB10 may hold promise as potential prognosis prediction biomarker for the diagnosis of GC and a potential therapeutic target, which will facilitate the development of a novel therapeutic strategy against GC.

Repair of experimental alveolar bone defects by tissue-engineered bone.

Alveolar bone resorption caused by periodontal diseases remains a difficult clinical problem to treat. Our purpose here was to develop protocols for repairing experimental horizontal alveolar bone defects. The procedure entailed isolating bone marrow stromal cells (BMSC). They were expanded and induced in vitro into osteogenic cells in a defined medium. Induced BMSCs were mixed with calcium alginate to form a gel form of cell-scaffold construct for developing engineered bone. A horizontal alveolar bone defect was created in 15 mongrel dogs, which was 5 mm high on each of two buccal sides at the location of mandibular premolar 3, 4, and molar 1. Without bias, the animals were separated into the following groups: (1) cell-scaffold construct as the experimental group; (2) calcium alginate alone as the control group A; (3) untreated as the control group B. Block sections of the defects were collected at 4, 12, and 24 weeks postsurgery, respectively, and processed for gross and histological observation as well as x-ray examination. The results showed that in vitro induced BMSCs exhibited an osteogenic phenotype. Histologically, bone nodule structure was observed in the tissue of the experimental group at 4 weeks postsurgery and the engineered bone became more mature after 12 weeks, which was similar to normal bone. At 12 weeks postsurgery, the height of repaired alveolar bone reached 2.43 +/- 0.93 mm, 0.98 +/- 0.87 mm, 0.78 +/- 0.75 mm for the experimental group, control groups A and B, respectively, with a significant difference between the experimental and control groups (p < 0.01). The average level of buccal alveolar ridge in experimental group, control groups A and B reached 48.59%, 19.74%, and 15.76% of the height of normal alveolus, respectively, with a significant difference between the experimental group and two control groups (p < 0.01). We thus conclude that BMSCs can be induced to become osteogenic and can be used as seed cells to engineer bone tissue and repair experimental alveolar bone defects.

Fluoride down-regulates the expression of matrix metalloproteinase-20 in human fetal tooth ameloblast-lineage cells in vitro.

Fluoride is associated with a decrease in the incidence of dental caries, but excessive fluoride intake during tooth enamel formation can result in enamel fluorosis. Fluorosed enamel has increased porosity, which has been related to a delay in the removal of amelogenin proteins as the enamel matures. This delay in protein removal suggests that fluoride may affect either the amount or the activity of enamel matrix proteinases. In this study, we investigated the role of fluoride in the synthesis and secretion of matrix metalloproteinase-20 (MMP-20), the proteinase primarily responsible for the initial hydrolysis of amelogenin during the secretory stage of enamel formation. Cultured human fetus tooth organ ameloblast-lineage cells were exposed to 10 microM fluoride and analyzed for synthesis of MMP-20. Immunoblotting showed that 10 microM NaF down-regulated the synthesis of MMP-20 by 21% compared with control cells, but did not alter the amount of amelogenin or kalikrein-4 (KLK-4) synthesized by the cells. Real-time polymerase chain reaction (PCR) showed that 10 microM NaF down-regulated MMP-20 mRNA expression to 28% of the levels found in the non-treated cells. These in vitro results suggest that fluoride can alter the expression of MMP-20 by ameloblasts, resulting in a disturbance of the balance between MMP-20 and its substrate that may contribute to the retention of amelogenins in the formation of fluorosed enamel.

Differentiation of human ameloblast-lineage cells in vitro.

Previous studies have shown that ameloblast-like cells can be selectively cultured from the enamel organ in a serum-free medium with low calcium concentrations. The purpose of this study was to further characterize this culture system to identify differentiated ameloblast-lineage cells. Tooth organs from 19-24-wk-old fetal cadavers were either frozen and cryosectioned for immunostaining, or digested in collagenase/dispase for cell culture. The cells were grown in keratinocyte media supplemented with 0.05 mM calcium, and characterized by morphology and immunofluorescence. Epithelial clones with two distinct morphologies, including smaller cobblestone-shaped cells and larger (5-15 times in size) rounded cells, began to form between day 8 and day 12 after culture. The cobblestone-shaped cells continued to proliferate in culture, while the larger cells proliferated slowly or not at all. These larger cells formed filopodia, usually had two or more nuclei and a radiating cytoplasm at the cell margin, and were more abundant with increasing time in culture. Both cell types stained for cytokeratin 14, and the larger cells appeared more differentiated, showing stronger staining for amelogenin and ameloblastin. Immunofluorescence of the tooth bud sections showed staining for these matrix proteins as ameloblasts differentiated from the inner enamel epithelium. These results show the successful culture of differentiating ameloblast-lineage cells, and lay a foundation for use of these cells to further understand ameloblast biology with application to tooth enamel tissue engineering.

[Ectopic osteogenic ability of BMSCs on various scaffold materials in nude mice].

PURPOSE: To explore the ectopic osteogenic abilities of bone marrow stromal cells (BMSCs) on different scaffold materials in nude mice. METHODS: Canine BMSCs in vitro cultured were seeded at the density of 1x10(6)cells/cm(2) onto scaffolds of freeze-dried demineralized bone matrix (fdDBM), tricalcium phosphate (TCP), 200microm coralline hydroxyapatite (CH200) and 500microm coralline hydroxyapatite (CH500). The cell adherence and growth on the materials were examined by SEM and H&E staining after 4 to 7 days of in vitro culturing. To observe the ectopic osteogenic capacity, four 10mmx5mmx2mm cell/scaffold complexes (fdDBM, TCP, CH200, CH500) and a blank control scaffold (fdDBM only) were implanted subcutaneously into each of athymic mice (n=8). The implants were harvested after 9 weeks and H&E stained. Newly formed trabecular bone volume (TBV) was measured by IMAGER-PRO PLUS software, and statistical analysis was performed by ANOVA with SAS software. RESULTS: Canine BMSCs adhered to all 4 types of scaffolds and spread well in their pores 7-8 days after seeding. Athymic subcutaneous ectopic osteogenesis were observed in all the specimens of TCP, CH200, CH500 but were observed only in 75% of BMSCs/fdDBM and 25% of fdDBM. The TCP group showed significant higher TBV percentage (28.2%+/-2.86) than CH200 group (24.1%+/-4.12) and CH500 group (18.1%+/-4.66) (P<0.01). CONCLUSIONS: BMSCs adhered to all 4 scaffolds. When combined with BMSCs, TCP exhibited the greatest osteogenic potential, which indicates that it might be an excellent scaffold material in the field of bone tissue engineering. Supported by National 973 Project (G1999054300) and National Natural Science Foundation of China(30271426).