R. Nakamori scite author profile

The nuclear receptor, peroxisome proliferator-activated receptor c (PPARc), recognizes various synthetic and endogenous ligands by the ligand-binding domain. Fattyacid metabolites reportedly activate PPARc through conformational changes of the X loop. Here, we report that serotonin metabolites act as endogenous agonists for PPARc to regulate macrophage function and adipogenesis by directly binding to helix H12. A cyclooxygenase inhibitor, indomethacin, is a mimetic agonist of these metabolites. Crystallographic analyses revealed that an indole acetate functions as a common moiety for the recognition by the sub-pocket near helix H12. Intriguingly, a serotonin metabolite and a fatty-acid metabolite each bind to distinct sub-pockets, and the PPARc antagonist, T0070907, blocked the fatty-acid agonism, but not that of the serotonin metabolites. Mutational analyses on receptor-mediated transcription and coactivator binding revealed that each metabolite individually uses coregulator and/or heterodimer interfaces in a ligand-type-specific manner. Furthermore, the inhibition of the serotonin metabolism reduced the expression of the endogenous PPARc-target gene. Collectively, these results suggest a novel agonism, in which PPARc functions as a multiple sensor in response to distinct metabolites.

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A secreted decoy of InR antagonizes insulin/IGF signaling to restrict body growth in Drosophila

Okamoto¹,

Nakamori²,

Murai³

et al. 2013

Genes Dev.

106

105

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Members of the insulin peptide family have conserved roles in the regulation of growth and metabolism in a wide variety of metazoans. Drosophila insulin-like peptides (Dilps) promote tissue growth through the single insulin-like receptor (InR). Despite the important role of Dilps in nutrient-dependent growth control, the molecular mechanism that regulates the activity of circulating Dilps is not well understood. Here, we report the function of a novel secreted decoy of InR (SDR) as a negative regulator of insulin signaling. SDR is predominantly expressed in glia and is secreted into the hemolymph. Larvae lacking SDR grow at a faster rate, thereby increasing adult body size. Conversely, overexpression of SDR reduces body growth non-cell-autonomously. SDR is structurally similar to the extracellular domain of InR and interacts with several Dilps in vitro independent of Imp-L2, the ortholog of the mammalian insulin-like growth factor-binding protein 7 (IGFBP7). We further demonstrate that SDR is constantly secreted into the hemolymph independent of nutritional status and is essential for adjusting insulin signaling under adverse food conditions. We propose that Drosophila uses a secreted decoy to fine-tune systemic growth against fluctuations of circulating insulin levels.

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Interactions between cytoskeletal components during myoplasm rearrangement in ascidian eggs

et al. 1999

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Ooplasmic segregation in ascidian eggs consists of two phases of cytoplasmic movement, the first phase is mediated by the microfilament system and the second is mediated by the microtubule system. Recently, two novel proteins, p58 and myoplasmin-C1, which are localized to the myoplasm, were suggested to have important roles in muscle differentiation. In order to analyze the molecular mechanisms underlying ooplasmic segregation, the interactions between actin, tubulin, p58 and myoplasmin-C1 were examined. During the first segregation, microtubule meshwork in the unfertilized egg disappeared. At the second segregation, a novel structure of the microtubules that extended from the sperm aster and localized in the cortical region of the myoplasm was found. Moreover, uniform distribution of the cortical actin filament was observed at the second segregation. During the course of myoplasm rearrangement, p58 and myoplasmin-C1 are colocalized and can form a molecular complex in vitro. This complex of p58 and myoplasmin-C1 is a good candidate for a cytoskeletal component of the myoplasm, and is likely to be involved in the correct distribution of cytoplasmic determinants.

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Calcium-induced Mechanical Change in the Neck Domain Alters the Activity of Plant Myosin XI

Tominaga

Kojima

Yokota

et al. 2012

Journal of Biological Chemistry

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Background: Cytoplasmic streaming driven by myosin XI is inhibited by Ca2+ in plant cells.Results: The neck length and step size of a single myosin XI molecule decreased through Ca2+-induced calmodulin dissociation.Conclusion: Plant myosin XI is regulated by Ca2+ through dissociation of calmodulin, a different manner of regulation than for vertebrate myosin V.Significance: Ca2+ affects the mechanical properties of myosin XI.

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R. Nakamori

The nuclear receptor PPARγ individually responds to serotonin- and fatty acid-metabolites

A secreted decoy of InR antagonizes insulin/IGF signaling to restrict body growth in Drosophila

Interactions between cytoskeletal components during myoplasm rearrangement in ascidian eggs

Calcium-induced Mechanical Change in the Neck Domain Alters the Activity of Plant Myosin XI

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