Funded Research Projects

Permanent URI for this collectionhttps://hdl.handle.net/20.500.14641/189

An index of publicly funded research projects conducted by Texas A&M affiliated researchers.

Browse

Now showing 1 - 2 of 2

Regulating Niche of Periodontium Mesenchymal Stem Cells under the Physiological Condition
Biomedical Sciences; TAMHSC; https://hdl.handle.net/20.500.14641/366; DHHS-NIH-National Institute of Dental and Craniofacial Research
Regulating niche of periodontium mesenchymal stem cells under the physiological condition The periodontium is composed of cementum, alveolar bone and periodontal ligament (PDL) in between. Their physiological turnover was known to be supported by stem cell populations1, 2. Based on mostly in vitro approaches, the periodontal stem cells (PDLSC) were isolated from human molar PDL3. Despite of that, in vivo location and identification of the periodontium stem cells remain largely unknown. Periodontium regeneration during or after periodontitis is a most challenging issue despite of various treatment strategies being designed. The regeneration capability difference strongly suggests that periodontium stem cells behave differentially under physiological or pathological conditions. Activity of stem cells was known to be regulated by the niche they are residing in. Various niche signals interplay which each other and keep stem cells in a dynamic balance4, 5. Despite of tremendous progress of the niche studies for other stem cell populations, the in vivo niche of periodontium stem cells has never been studied. To address above challenges, it is therefore imperative to find out the in vivo identity of the periodontium mesenchymal stem cells (MSCs) and to learn their niche organization. Based on our preliminary experiments, Gli1+ cells are identified as the MSCs for adult periodontium tissue. The Gli1+ cells are exclusively surrounding the neurovascular bundle and are more enriched in the apical region of the PDL space. These Gli1+ cells are negative for lineage differentiation or classical MSC markers. They give rise to the PDL, cementum, alveolar bone and apical root pulp during physiological turnover. Blockage of canonical Wnt signaling leads to failure of Gli1+ stem cells activation and severe periodontal tissue loss. With these preliminary findings, comprehensive investigation is proposed for investigating the in vivo properties and regulating niche of Gli1+ periodontium MSCs under physiological condition. The hypothesis is that Gli1+ MSCs are the dominant stem cell population within the periodontium and are regulated by a negative feedback loop within the periodontium. Canonical Wnt signaling pathway activates and maintains periodontium MSCs. Sclerostin ligand secreted from the cementum and alveolar bone negatively regulates the Gli1+ stem cell activities. Interplays between the two opposing signals keep the periodontium MSCs in a dynamic balance.
The Roles of Fam20c (dmp4) In Odontogenesis and Osteogenesis
Biomedical Sciences; TAMHSC; https://hdl.handle.net/20.500.14641/645; National Institutes of Health
DESCRIPTION (provided by applicant): This research proposal focuses on the biological roles of FAM20C (also known as Dentin Matrix Protein 4, DMP4) in the formation of dentin, cementum, enamel and bone. Our recent studies have established that this novel molecule plays crucial roles in odontogenesis and osteogenesis. We have discovered that the inactivation of Fam20C in mice leads to: 1) significant defects in the dentin, cementum, enamel and bone; 2) a decreased serum level of phosphorus in contrast to an elevated serum level of fibroblast growth factor 23 (FGF23); 3) loss of normal morphology of odontoblasts and ameloblasts; and 4) reduced expression of the differentiation markers for odontoblasts and osteoblasts [including dentin matrix protein 1 (DMP1), a differentiation/mineralization marker]. In vitro studies revealed that recombinant FAM20C promotes the differentiation of preosteoblasts and increases the expression of DMP1, while shRNA knockdown of FAM20C leads to a remarkable reduction of DMP1 and elevation of FGF23 in multiple osteogenic cell lines. Our preliminary data led us to believe that the inactivation of Fam20C prevents cells from differentiating into mature odontogenic/osteogenic cells and leads to hypophosphatemia. The combined results of cell differentiation failure and lower serum phosphate level cause defects in the teeth and bones of Fam20C-deficient mice. The following three Specific Aims are proposed to test the central hypothesis that FAM20C promotes the differentiation of cells forming mineralized tissues and regulates phosphate homeostasis via the mediation of FGF23: (1) To evaluate the molecular pathogenesis of FAM20C-associated disorders in mice and humans by analyzing the specific effects of FAM20C inactivation on odontoblasts, cementoblasts, osteoblasts and ameloblasts, and by examining whether the expression of a normal human FAM20C transgene can rescue the mouse Fam20C-deficient defects and if expressing a mutant mouse Fam20C transgene mimicking a human FAM20C mutation can recapitulate the phenotype identified in some human patients; (2) To determine if FAM20C is involved in biomineralization via the FGF23-mediated regulation of phosphate homeostasis by analyzing double Fam20C- and Fgf23-null mice, injecting anti-FGF23 antibodies and administering a high-phosphate diet in the Fam20C-deficient mice; and (3) To determine if FAM20C regulates DMP1 in dentinogenesis and osteogenesis by examining if expressing the Dmp1 transgene can rescue the dentin and bone defects in the Fam20C-deficient mice, and by analyzing the in vitro effects of adding or expressing DMP1 on Fam20C-deficient cell lines. The proposed studies, which are a necessary step in understanding how FAM20C functions in odontogenesis and osteogenesis, will contribute new insights into the molecular basis for genetic and metabolic disorders that affect the craniofacial complex and the axial skeleton.

Browse

Browsing Funded Research Projects by Subject "Biomedical Sciences"