The homeobox genes Xlim-1 and goosecoid (gsc) are coexpressed in the Spemann organizer and later in the prechordal plate that acts as head organizer. Based on our previous finding that gsc is a possible target gene for Xlim-1, we studied the regulation of gsc transcription by Xlim-1 and other regulatory genes expressed at gastrula stages, by using gsc-luciferase reporter constructs injected into animal explants. A 492-bp upstream region of the gsc promoter responds to Xlim-1/3m, an activated form of Xlim-1, and to a combination of wild-type Xlim-1 and Ldb1, a LIM domain binding protein, supporting the view that gsc is a direct target of Xlim-1. Footprint and electrophoretic mobility shift assays with GST-homeodomain fusion proteins and embryo extracts overexpressing FLAG-tagged full-length proteins showed that the Xlim-1 homeodomain or Xlim-1/Ldb1 complex recognize several TAATXY core elements in the 492-bp upstream region, where XY is TA, TG, CA, or GG. Some of these elements are also bound by the ventral factor PV.1, whereas a TAATCT element did not bind Xlim-1 or PV.1 but did bind the anterior factors Otx2 and Gsc. These proteins modulate the activity of the gsc reporter in animal caps: Otx2 activates the reporter synergistically with Xlim-1 plus Ldb1, whereas Gsc and PV.1 strongly repress reporter activity. We show further, using animal cap assays, that the endogenous gsc gene was synergistically activated by Xlim-1, Ldb1, and Otx2 and that the endogenous otx2 gene was activated by Xlim-1/3m, and this activation was suppressed by the posterior factor Xbra. Based on these data, we propose a model for gene interactions in the specification of dorsoventral and anteroposterior differences in the mesoderm during gastrulation.
Brain microvascular endothelial cells
derived from human induced
pluripotent stem cells (hiPS-BMECs) have been proposed as a new blood–brain
barrier model, but their transport function has not been fully clarified.
Therefore, in this study, we investigated the gene expression and
function of transporters in hiPS-BMECs by means of quantitative reverse
transcription-PCR, in vitro transcellular transport studies, and uptake
experiments. mRNAs encoding ABC and SLC transporters, such as BCRP,
MCT1, CAT1, and GLAST, were highly expressed in hiPS-BMECs. Transcellular
transport studies showed that prazosin, [14C]l-lactate, [3H]l-arginine, and [3H]l-glutamate (substrates of BCRP, MCT1, CAT1, and GLAST, respectively)
were transported asymmetrically across the hiPS-BMEC monolayer. Substrates
of LAT1, OCTN2, CAT1, GLAST, MCT1, and proton-coupled organic cation
(H+/OC) antiporter were taken up by hiPS-BMECs in a time-,
temperature-, and concentration-dependent manner, and the uptakes
were markedly decreased by inhibitors of the corresponding transporter.
These results indicate that hiPS-BMECs express multiple nutrient and
drug transporters.
Background: In Xenopus retinogenesis, p27Xic1, a Xenopus cyclin dependent kinase inhibitor, functions as a cell fate determinant in both gliogenesis and neurogenesis in a context dependent manner. This activity is essential for co-ordination of determination and cell cycle regulation. However, very little is known about the mechanism regulating the context dependent choice between gliogenesis versus neurogenesis.
Critical to the function of mast cells in immune responses including allergy is their production of lipid mediators, among which only omega-6 (ω-6) arachidonate-derived eicosanoids have been well characterized. Here, by employing comprehensive lipidomics, we identify omega-3 (ω-3) fatty acid epoxides as new mast cell-derived lipid mediators and show that they are produced by PAF-AH2, an oxidized-phospholipid-selective phospholipase A2. Genetic or pharmacological deletion of PAF-AH2 reduced the steady-state production of ω-3 epoxides, leading to attenuated mast cell activation and anaphylaxis following FcɛRI cross-linking. Mechanistically, the ω-3 epoxides promote IgE-mediated activation of mast cells by downregulating Srcin1, a Src-inhibitory protein that counteracts FcɛRI signaling, through a pathway involving PPARg. Thus, the PAF-AH2-ω-3 epoxide-Srcin1 axis presents new potential drug targets for allergic diseases.
Ruthenium complex with octahedral geometry serves as a core building block of peptidic molecule construction for protein-guided molecular self-assembly with enhanced sensitivity. The self-assembled nanofibrils selectively capture the lipid rafts of cervical cancer cells and exert mechanical stimuli on raft-associated receptors, leading to inhibition of cancer cell migration and cellular physical damage.
HIGHLIGHTSLipid rafts are promising targets for the precise control of cell response Octahedral Ru-complex-based molecule discriminates target protein for self-assembly Nanofibrils on lipid rafts manipulate cell motility through mechanical force Li et al., Chem 2, 283-298 February 9, 2017 ª 2017 Elsevier Inc. http://dx.
SUMMARYCells modify the migration mechanism in response to their surroundings, which sets the challenge for cancer therapy targeting metastasis through signaling pathways. To cope with the diversity and complexity of molecular self-assembled nanofibrils, we have developed a mechanical approach that captures membrane dynamicity to suppress cancer cell migration and invasion. We designed and synthesized a ruthenium (Ru)-complex-based peptidic molecule that selectively initiates self-assembly into extracellular nanofibrils on lipid rafts of cervical cancer cells by reacting with glycosylphosphatidylinositol-anchored placental alkaline phosphatase (GPI-anchored PLAP). The growing nanofibrils glue the lipid rafts and chain them into large clusters, leading to reinforced focal adhesion suppressing cell migration. The molecular self-assembly constantly exerts mechanical stimuli to raft-associated protein receptors, provoking opposing cell migration against focal adhesion with enhanced motility. The contradictory motions generate a mechanical force transferred through the actin cytoskeleton. When the force increases, the restricted cervical cancer cell is ruptured.
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