Mammalian oocytes are arrested in meiotic prophase by an inhibitory signal from the surrounding somatic cells in the ovarian follicle. In response to luteinizing hormone (LH), which binds to receptors on the somatic cells, the oocyte proceeds to second metaphase, where it can be fertilized. Here we investigate how the somatic cells regulate the prophase-to-metaphase transition in the oocyte, and show that the inhibitory signal from the somatic cells is cGMP. Using FRET-based cyclic nucleotide sensors in follicleenclosed mouse oocytes, we find that cGMP passes through gap junctions into the oocyte, where it inhibits the hydrolysis of cAMP by the phosphodiesterase PDE3A. This inhibition maintains a high concentration of cAMP and thus blocks meiotic progression. LH reverses the inhibitory signal by lowering cGMP levels in the somatic cells (from ~2 μM to ~80 nM at 1 hour after LH stimulation) and by closing gap junctions between the somatic cells. The resulting decrease in oocyte cGMP (from ~1 μM to ~40 nM) relieves the inhibition of PDE3A, increasing its activity by ~5-fold. This causes a decrease in oocyte cAMP (from ~700 nM to ~140 nM), leading to the resumption of meiosis.
The channel kinases TRPM6 and TRPM7 have recently been discovered to play important roles in Mg 2؉ and Ca 2؉ homeostasis, which is critical to both human health and cell viability. However, the molecular basis underlying these channels' unique Mg 2؉ and Ca 2؉ permeability and pH sensitivity remains unknown. Here we have created a series of amino acid substitutions in the putative pore of TRPM7 to evaluate the origin of the permeability of the channel and its regulation by pH. Two mutants of TRPM7, E1047Q and E1052Q, produced dramatic changes in channel properties. The I-V relations of E1052Q and E1047Q were significantly different from WT TRPM7, with the inward currents of 8-and 12-fold larger than TRPM7, respectively. permeation, rendering TRPM7 a monovalent selective channel. In addition, the ability of protons to potentiate inward currents was lost in E1047Q, indicating that E1047 is critical to Ca 2؉ and Mg 2؉ permeability of TRPM7, and its pH sensitivity. Mutation of the corresponding residues in the pore of TRPM6, E1024Q and E1029Q, produced nearly identical changes to the channel properties of TRPM6. Our results indicate that these two glutamates are key determinants of both channels' divalent selectivity and pH sensitivity. These findings reveal the molecular mechanisms underpinning physiological/pathological functions of TRPM6 and TRPM7, and will extend our understanding of the pore structures of TRPM channels.TRPM6 and TRPM7 belong to the TRP channel superfamily (1-5) and are distinguished from other known ion channels by virtue of having both ion channel and protein kinase activities (6 -11). In addition, TRPM6 and TRPM7 uniquely exhibit strong outward rectification, permeation to Ca 2ϩ , Mg 2ϩ , monovalent cations, and a wide array of trace metals (6 -8, 11, 12 (8,20,21,23), whereas TRPM7 is ubiquitously expressed, with highest expression in the kidney and heart (5, 6). In addition to these channels' regulation of Mg 2ϩ homeostasis, several studies have suggested multiple cellular and physiology functions for TRPM7, including anoxic neuronal death (24), cell adhesion and actomyosin contractility (25, 26), and skeletogenesis (27). Although the mechanisms by which TRPM6 and TRPM7 exert their physiological and/or pathological functions are not yet completely understood, it is clear that permeation of Ca 2ϩ and Mg 2ϩ contributes substantially to the known functions of these channels (7, 20 -22, 24, 25, 27). Moreover, a recent study demonstrated that the sensitivity of TRPM7 to external pH may contribute to controlling neurotransmitter release (28). Therefore, it is essential to understand the molecular mechanisms underlying the Ca 2ϩ and Mg 2ϩ permeability of TRPM6 and TRPM7, as well as their sensitivities to changes in pH.The aim of the present study was to identify the amino acid residues that determine Mg 2ϩ and Ca 2ϩ permeation of TRPM6 and TRPM7. We previously demonstrated that external protons significantly enhance TRPM6 and TRPM7 inward currents (11,19) by decreasing the divalent affinity to t...
Voltage sensitive phosphatases (VSPs) are unique proteins in which membrane potential controls enzyme activity. They are comprised of the voltage sensor domain of an ion channel coupled to a lipid phosphatase specific for phosphoinositides, and for ascidian and zebrafish VSPs, the phosphatase activity has been found to be activated by membrane depolarization. The physiological functions of these proteins are unknown, but their expression in testis and embryos suggests a role in fertilization or development. Here we investigate the expression pattern and voltage dependence of VSPs in two frog species, Xenopus laevis and Xenopus tropicalis, that are well suited for experimental studies of these possible functions. X. laevis has two VSP genes (Xl-VSP1 and Xl-VSP2), whereas X. tropicalis has only one gene (Xt-VSP). The highest expression of these genes was observed in testis, ovary, liver, and kidney. Our results show that while Xl-VSP2 activates only at positive membrane potentials outside of the physiological range, Xl-VSP1 and Xt-VSP phosphatase activity is regulated in the voltage range that regulates sperm-egg fusion at fertilization.
CD13/aminopeptidase N (CD13/APN) is a potent regulator of angiogenesis both in vitro and in vivo and transcription of CD13/APN in endothelial cells is induced by angiogenic growth factors via the RAS/MAPK pathway. We have explored the nuclear effectors downstream of this pathway that are responsible for CD13/APN induction. The response to serum/angiogenic growth factors mapped to a 38-bp region of the CD13/APN promoter containing an Ets-core motif that specifically binds a protein complex from nuclear lysates from activated endothelial cells. This motif and the proteins that target it are functionally relevant because mutation of this sequence abrogates CD13/APN transcription. Analysis of endothelial Ets family members showed that Ets-2, and to a lesser extent Ets-1, transactivate CD13/APN promoter activity via the Ets-core motif, whereas Fli, Erg, and NERF are ineffective. We investigated the possibility that the induction of CD13/APN is mediated by phosphorylation of Ets-2 via RAS/MAPK. A phosphorylation-defective Ets-2 mutant, T72A, failed to transactivate CD13/APN, suggesting that Ets-2 phosphorylation is obligatory for CD13/APN induction. To confirm a role for endogenous Ets-2 in CD13/APN expression, we specifically abrogated Ets-2 mRNA and protein by siRNA knockdown that significantly inhibited CD13/APN transcription. Finally, to assess the relevance of Ets-2 in endothelial cell function, we induced endothelial cells containing Ets-2 siRNA oligonucleotides to form capillary networks. Cells containing the Ets-2 inhibitory small interfering RNAs were completely incapable of forming the organized networks characteristic of endothelial morphogenesis. Thus, the phosphorylation of Ets-2 by RAS/MAPK is a prerequisite for CD13/APN endothelial induction and Ets-2 and its targets play essential roles in endothelial cell function.
Summary The mammalian oocyte develops within a complex of somatic cells known as a follicle, within which signals from the somatic cells regulate the oocyte, and signals from the oocyte regulate the somatic cells. Because isolation of the oocyte from the follicle disrupts these communication pathways, oocyte physiology is best studied within an intact follicle. Here we describe methods for quantitative microinjection of follicle-enclosed mouse oocytes, thus allowing the introduction of signaling molecules as well as optical probes into the oocyte within its physiological environment.
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