Background: Trophoblast invasion is regulated by trophoblast-decidual cell interaction. Results: HtrA1 and HtrA3 expression is up-regulated in decidualization stimuli-treated endometrial cells, which suppresses HtrA4-mediated trophoblast invasion by degradation of HtrA4. Conclusion: Physical and functional interaction between trophoblastic HtrA4 and decidual HtrA1 and HtrA3 regulates trophoblast invasion. Significance: This study reveals a novel trophoblast-decidual cell interaction in control of trophoblast invasion.
Hutchinson–Gilford progeria syndrome (HGPS) is a rare laminopathy that produces a mutant form of prelamin A, known as Progerin, resulting in premature aging. HGPS cells show morphological abnormalities of the nuclear membrane, reduced cell proliferation rates, accumulation of reactive oxygen species (ROS), and expression of senescence markers. Lysophosphatidic acid (LPA) is a growth factor‐like lipid mediator that regulates various physiological functions via activating multiple LPA G protein‐coupled receptors. Here, we study the roles of LPA and LPA receptors in premature aging. We report that the protein level of LPA3 was highly downregulated through internalization and the lysosomal degradation pathway in Progerin‐transfected HEK293 cells. By treating Progerin HEK293 cells with an LPA3 agonist (OMPT, 1‐Oleoyl‐2‐O‐methyl‐rac‐glycerophosphothionate) and performing shRNA knockdown of the Lpa3r transcript in these cells, we showed that LPA3 activation increased expression levels of antioxidant enzymes, consequently inhibiting ROS accumulation and ameliorating cell senescence. LPA3 was shown to be downregulated in HGPS patient fibroblasts through the lysosomal pathway, and it was shown to be crucial for ameliorating ROS accumulation and cell senescence in fibroblasts. Moreover, in a zebrafish model, LPA3 deficiency was sufficient to cause premature aging phenotypes in multiple organs, as well as a shorter lifespan. Taken together, these findings identify the decline of LPA3 as a key contributor to the premature aging phenotypes of HGPS cells and zebrafish.
Aryl hydrocarbon receptor (AHR) signaling has been suggested to play roles in various physiological functions independent of its xenobiotic activity, including cell cycle regulation, immune response, and embryonic development. Several endogenous ligands were also identified by high-throughput screening techniques. However, the mechanism by which these molecules mediate AHR signaling in certain functions is still elusive. In this study, we investigated the possible pathway through which AHR and its endogenous ligands regulate neural development. We first identified two neuroactive steroids, 3α,5α-tetrahydrocorticosterone and 3α,5β-tetrahydrocorticosterone (5α-and 5β-THB), as novel AHR endogenous ligands through the use of an ultrasensitive dioxin-like compound bioassay and liquid chromatography-electrospray ionization-tandem mass spectrometry (LC-ESI-MS). We then treated zebrafish embryos with 5α-and 5β-THB, which enhance the expression of neurogenesis marker HuC. Furthermore, 5α-and 5β-THB both enhanced the expression of myelinating glial cell markers, sex determining region Y-box 10 (Sox10), and myelin-associated proteins myelin basic protein (Mbp) and improved the mobility of zebrafish larvae via the Ahr2 pathway. These results indicated that AHR mediates zebrafish neurogenesis and gliogenesis, especially the differentiation of oligodendrocyte or Schwann cells. Additionally, we showed that these molecules may induce neuroblastoma (NB) cell differentiation suggesting therapeutic potential of 5α-and 5β-THB in NB treatment. In summary, our results reveal that 5α-and 5β-THB are endogenous ligands of AHR and have therapeutic potential for NB treatment. By the interaction with THB, AHR signaling regulates various aspects of neural development.
Tau pathology is instrumental in the gradual loss of neuronal functions and cognitive decline in tauopathies, including Alzheimer’s disease (AD). Earlier reports showed that adenosine metabolism is abnormal in the brain of AD patients while consequences remained ill-defined. Herein, we aimed at investigating whether manipulation of adenosine tone would impact Tau pathology, associated molecular alterations and subsequent neurodegeneration. We demonstrated that treatment with an inhibitor (J4) of equilibrative nucleoside transporter 1 (ENT1) exerted beneficial effects in a mouse model of Tauopathy. Treatment with J4 not only reduced Tau hyperphosphorylation but also rescued memory deficits, mitochondrial dysfunction, synaptic loss, and abnormal expression of immune-related gene signatures. These beneficial effects were particularly ascribed to the ability of J4 to suppress the overactivation of AMPK (an energy reduction sensor), suggesting that normalization of energy dysfunction mitigates neuronal dysfunctions in Tauopathy. Collectively, these data highlight that targeting adenosine metabolism is a novel strategy for tauopathies.
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