Browsing by Author "Nguyen, Andrew V."

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    The loss of STAT3 in mature osteoclasts has detrimental effects on bone structure
    (Public Library of Science, 2020-07-30) Davidson, Rebecca K.; Himes, Evan R.; Takigawa, Shinya; Chen, Andy; Horn, M. Ryne; Meijome, Tomas; Wallace, Joseph M.; Kacena, Melissa A.; Yokota, Hiroki; Nguyen, Andrew V.; Li, Jiliang; Biology, School of Science
    Signal Transducer and Activator of Transcription 3 (STAT3) has recently been shown to be involved in bone development and has been implicated in bone diseases, such as Job’s Syndrome. Bone growth and changes have been known for many years to differ between sexes with male bones tending to have higher bone mass than female bones and older females tending to lose bone mass at faster rates than older males. Previous studies using conditional knock mice with Stat3 specifically deleted from the osteoblasts showed both sexes exhibited decreased bone mineral density (BMD) and strength. Using the Cre-Lox system with Cathepsin K promotor driving Cre to target the deletion of the Stat3 gene in mature osteoclasts (STAT3-cKO mice), we observed that 8-week old STAT3-cKO female femurs exhibited significantly lower BMD and bone mineral content (BMC) compared to littermate control (CN) females. There were no differences in BMD and BMC observed between male knock-out and male CN femurs. However, micro-computed tomography (μCT) analysis showed that both male and female STAT3-cKO mice had significant decreases in bone volume/tissue volume (BV/TV). Bone histomorphometry analysis of the distal femur, further revealed a decrease in bone formation rate and mineralizing surface/bone surface (MS/BS) with a significant decrease in osteoclast surface in female, but not male, STAT3-cKO mice. Profiling gene expression in an osteoclastic cell line with a knockdown of STAT3 showed an upregulation of a number of genes that are directly regulated by estrogen receptors. These data collectively suggest that regulation of STAT3 differs in male and female osteoclasts and that inactivation of STAT3 in osteoclasts affects bone turnover more in females than males, demonstrating the complicated nature of STAT3 signaling pathways in osteoclastogenesis. Drugs targeting the STAT3 pathway may be used for treatment of diseases such as Job’s Syndrome and osteoporosis.
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    Loss of STAT3 in osteoblasts has detrimental and sexually dimorphic effects on skeletal development
    (Public Library of Science, 2024-12-17) Davidson, Rebecca K.; Corry, Kylie; Orlofsky, Amos; Li, Ping; Russell, Caleb E.; Zhang, Amy; Moraes de Lima Perini, Mariana; Priddy, Carlie N.; Nguyen, Andrew V.; Li, Jiliang; Biology, School of Science
    Studies with genetically modified mice have implicated the transcriptional regulator STAT3 as a key modulator of bone development. STAT3-OKO knockout mouse lines were generated in two genetic backgrounds, pure C57BL/6 (STAT3-OKO-BL) and mixed C57BL/6, CD1 (STAT3-OKO-M). Both lines exhibited defective postnatal bone development resulting in reduced body weight and shortened femurs that displayed low bone mineral density as well as cortical widening and thinning in the diaphyseal region. Remarkably, each of these defects displayed sexual dimorphism that was dependent on genetic background: the phenotype was entirely male-specific in STAT3-OKO-M but not in STAT3-OKO-BL, in which defects were similar in both sexes. However, both lines exhibited a male-specific bone defect in mineralization, and also in bone mechanical properties related to bone quality, such as yield stress and ultimate stress. On the other hand, bone mechanical properties such as ultimate force, that may reflect density and macrostructure rather than bone quality, showed male-specific defects only in STAT3-OKO-M. These findings suggest that STAT3 may regulate multiple sex-dependent mechanisms in bone development that control either mineralization or bone accrual, and that the sex-dependence of at least some of these mechanisms is affected by genetic background. Finally, we used CRISPR/Cas9 to generate STAT3-deficient preosteoblastic cells from immortalized wild-type bone marrow stem cells and showed that the defective osteoblastic differentiation of STAT3-ablated cells was associated with reduced gene expression of Wnt3a and Wnt5a, consistent with other studies that identify Wnt signaling pathways as potential effector mechanisms for STAT3-mediated regulation of bone development.