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BACKGROUND: The epididymis is important for sperm maturation and without its proper development, male infertility will result. Biomechanical properties of tissues/organs play key roles during their morphogenesis, including the Wolffian duct. It is hypothesized that structural/bulk stiffness of the capsule and mesenchyme/extracellular matrix that surround the duct is a major biomechanical property that regulates Wolffian duct morphogenesis. These data will provide key information as to the mechanisms that regulate the development of this important organ. OBJECTIVES: To measure the structural/bulk stiffness in Pascals (force/area) of the capsule and the capsule and mesenchyme together that surrounds the Wolffian duct during the development. To examine the relative membrane tension of mesenchymal cells during the Wolffian duct development. Since Ptk7 was previously shown to regulate ECM integrity and Wolffian duct elongation and coiling, the hypothesis that Ptk7 regulates structural/bulk stiffness and mesenchymal cell membrane tension was tested. MATERIALS AND METHODS: Atomic force microscopy and a microsquisher compression apparatus were used to measure the structural stiffness. Biomechanical properties within the membranes of cells within the capsule and mesenchyme were examined using a membrane-tension fluorescent probe. RESULTS AND DISCUSSION: The structural stiffness (Pascals) of the capsule and underlying mesenchyme was relatively constant during development, with a significant increase in the capsule at the later stages. However, this increase may reflect the ECM and associated mesenchyme being close to the capsule because the coiling of the duct pushed or compressed them into that space. Keeping the capsule and mesenchyme/ECM at constant stiffness would ensure that the duct will continue to coil under similar biomechanical forces throughout the development. Cells within the capsule and mesenchyme at different Wolffian duct regions during the development had varying degrees of membrane lipid tension. It is hypothesized that the dynamic changes ensure the duct is kept at a constant stiffness regardless of any external forces. Loss of Ptk7 resulted in an increase in stiffness at E18.5, which was presumable due to the loss of integrity of the ECM within the mesenchyme. CONCLUSION: Biomechanical properties of the capsule and the mesenchyme/extracellular matrix that surround the Wolffian duct play an important role toward Wolffian duct morphogenesis, thereby allowing for the proper development of the epididymis and subsequent male fertility.
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Introduction: Reduced brain energy metabolism, mTOR dysregulation, and extracellular amyloid-ß oligomer (xcAßO) buildup characterize AD; how they collectively promote neurodegeneration is poorly understood. We previously reported that xcAßOs inhibit N utrient-induced M itochondrial A ctivity (NiMA) in cultured neurons. We now report NiMA disruption in vivo . Methods: Brain energy metabolism and oxygen consumption were recorded in APP SAA/+ mice using two-photon fluorescence lifetime imaging and multiparametric photoacoustic microscopy. Results: NiMA is inhibited in APP SAA/+ mice before other defects are detected in these amyloid-ß-producing animals that do not overexpress APP or contain foreign DNA inserts into genomic DNA. GSK3ß signals through mTORC1 to regulate NiMA independently of mitochondrial biogenesis. Inhibition of GSK3ß with lithium or TWS119 stimulates NiMA in cultured human neurons, and mitochondrial activity and oxygen consumption in APP SAA mice. Conclusion: NiMA disruption in vivo occurs before histopathological changes and cognitive decline in APP SAA mice, and may represent an early stage in human AD.