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Inhibition of Xenopus oocyte meiotic maturation by catalytically inactive protein kinase A. , Schmitt A., Proc Natl Acad Sci U S A. April 2, 2002; 99 (7): 4361-6.
A new role for Mos in Xenopus oocyte maturation: targeting Myt1 independently of MAPK. , Peter M., Development. May 1, 2002; 129 (9): 2129-39.
A novel regulatory element determines the timing of Mos mRNA translation during Xenopus oocyte maturation. , Charlesworth A ., EMBO J. June 3, 2002; 21 (11): 2798-806.
Mos is not required for the initiation of meiotic maturation in Xenopus oocytes. , Dupré A ., EMBO J. August 1, 2002; 21 (15): 4026-36.
Xenopus H-RasV12 promotes entry into meiotic M phase and cdc2 activation independently of Mos and p42( MAPK). , Dupré A ., Oncogene. September 19, 2002; 21 (42): 6425-33.
Dissection of c- MOS degron. , Sheng J., EMBO J. November 15, 2002; 21 (22): 6061-71.
Discrimination of the roles of MPF and MAP kinase in morphological changes that occur during oocyte maturation. , Kotani T., Dev Biol. December 15, 2002; 252 (2): 271-86.
DIF-1, an anti-tumor substance found in Dictyostelium discoideum, inhibits progesterone-induced oocyte maturation in Xenopus laevis. , Kubohara Y., Eur J Pharmacol. January 24, 2003; 460 (2-3): 93-8.
Biphasic activation of Aurora-A kinase during the meiosis I- meiosis II transition in Xenopus oocytes. , Ma C., Mol Cell Biol. March 1, 2003; 23 (5): 1703-16.
XGef is a CPEB-interacting protein involved in Xenopus oocyte maturation. , Reverte CG., Dev Biol. March 15, 2003; 255 (2): 383-98.
Expression of cell-cycle regulators during Xenopus oogenesis. , Furuno N ., Gene Expr Patterns. May 1, 2003; 3 (2): 165-8.
Cdc2- cyclin B triggers H3 kinase activation of Aurora-A in Xenopus oocytes. , Maton G., J Biol Chem. June 13, 2003; 278 (24): 21439-49.
Involvement of Xenopus Pumilio in the translational regulation that is specific to cyclin B1 mRNA during oocyte maturation. , Nakahata S., Mech Dev. August 1, 2003; 120 (8): 865-80.
Regulation of the G2/M transition in oocytes of xenopus tropicalis. , Stanford JS., Dev Biol. August 15, 2003; 260 (2): 438-48.
A positive-feedback-based bistable 'memory module' that governs a cell fate decision. , Xiong W., Nature. November 27, 2003; 426 (6965): 460-5.
Spindle checkpoint proteins Mad1 and Mad2 are required for cytostatic factor-mediated metaphase arrest. , Tunquist BJ., J Cell Biol. December 22, 2003; 163 (6): 1231-42.
Progesterone and insulin stimulation of CPEB-dependent polyadenylation is regulated by Aurora A and glycogen synthase kinase-3. , Sarkissian M., Genes Dev. January 1, 2004; 18 (1): 48-61.
Oocyte maturation in Xenopus laevis is blocked by the hormonal herbicide, 2,4-dichlorophenoxy acetic acid. , Stebbins-Boaz B., Mol Reprod Dev. February 1, 2004; 67 (2): 233-42.
Ca(2+)(cyt) negatively regulates the initiation of oocyte maturation. , Sun L., J Cell Biol. April 1, 2004; 165 (1): 63-75.
Polo-like kinase confers MPF autoamplification competence to growing Xenopus oocytes. , Karaiskou A., Development. April 1, 2004; 131 (7): 1543-52.
CK2 beta, which inhibits Mos function, binds to a discrete domain in the N-terminus of Mos. , Lieberman SL., Dev Biol. April 15, 2004; 268 (2): 271-9.
Cytoplasmic polyadenylation element (CPE)- and CPE-binding protein ( CPEB)-independent mechanisms regulate early class maternal mRNA translational activation in Xenopus oocytes. , Charlesworth A ., J Biol Chem. April 23, 2004; 279 (17): 17650-9.
Contribution of JNK, Mek, Mos and PI-3K signaling to GVBD in Xenopus oocytes. , Mood K., Cell Signal. May 1, 2004; 16 (5): 631-42.
XCdh1 is involved in progesterone-induced oocyte maturation. , Papin C., Dev Biol. August 1, 2004; 272 (1): 66-75.
Emi1-mediated M-phase arrest in Xenopus eggs is distinct from cytostatic factor arrest. , Ohsumi K., Proc Natl Acad Sci U S A. August 24, 2004; 101 (34): 12531-6.
Potential role of protein tyrosine phosphatase nonreceptor type 13 in the control of oocyte meiotic maturation. , Nedachi T., Development. October 1, 2004; 131 (20): 4987-98.
XGef mediates early CPEB phosphorylation during Xenopus oocyte meiotic maturation. , Martínez SE., Mol Biol Cell. March 1, 2005; 16 (3): 1152-64.
The distinct stage-specific effects of 2-(p-amylcinnamoyl)amino-4-chlorobenzoic acid on the activation of MAP kinase and Cdc2 kinase in Xenopus oocyte maturation. , Islam A., Cell Signal. April 1, 2005; 17 (4): 507-23.
Phosphorylation of maskin by Aurora-A participates in the control of sequential protein synthesis during Xenopus laevis oocyte maturation. , Pascreau G., J Biol Chem. April 8, 2005; 280 (14): 13415-23.
p90Rsk is not involved in cytostatic factor arrest in mouse oocytes. , Dumont J., J Cell Biol. April 25, 2005; 169 (2): 227-31.
Differential roles of p39Mos-Xp42Mpk1 cascade proteins on Raf1 phosphorylation and spindle morphogenesis in Xenopus oocytes. , Bodart JF., Dev Biol. July 15, 2005; 283 (2): 373-83.
Differential phosphorylation controls Maskin association with eukaryotic translation initiation factor 4E and localization on the mitotic apparatus. , Barnard DC ., Mol Cell Biol. September 1, 2005; 25 (17): 7605-15.
Oocyte extracts for the study of meiotic M-M transition. , Ohsumi K., Methods Mol Biol. January 1, 2006; 322 445-58.
Redundant pathways for Cdc2 activation in Xenopus oocyte: either cyclin B or Mos synthesis. , Haccard O ., EMBO Rep. March 1, 2006; 7 (3): 321-5.
Oncogenic Met receptor induces cell-cycle progression in Xenopus oocytes independent of direct Grb2 and Shc binding or Mos synthesis, but requires phosphatidylinositol 3-kinase and Raf signaling. , Mood K., J Cell Physiol. April 1, 2006; 207 (1): 271-85.
Intracellular acidification delays hormonal G2/M transition and inhibits G2/M transition triggered by thiophosphorylated MAPK in Xenopus oocytes. , Sellier C., J Cell Biochem. May 15, 2006; 98 (2): 287-300.
CUG-BP binds to RNA substrates and recruits PARN deadenylase. , Moraes KC., RNA. June 1, 2006; 12 (6): 1084-91.
B-Raf and C-Raf are required for Ras-stimulated p42 MAP kinase activation in Xenopus egg extracts. , Yue J., Oncogene. June 1, 2006; 25 (23): 3307-15.
Musashi regulates the temporal order of mRNA translation during Xenopus oocyte maturation. , Charlesworth A ., EMBO J. June 21, 2006; 25 (12): 2792-801.
Mechanistic studies of the mitotic activation of Mos. , Yue J., Mol Cell Biol. July 1, 2006; 26 (14): 5300-9.
Metaphase arrest by cyclin E- Cdk2 requires the spindle-checkpoint kinase Mps1. , Grimison B., Curr Biol. October 10, 2006; 16 (19): 1968-73.
Paxillin regulates steroid-triggered meiotic resumption in oocytes by enhancing an all-or-none positive feedback kinase loop. , Rasar M., J Biol Chem. December 22, 2006; 281 (51): 39455-64.
The hormonal herbicide, 2,4-dichlorophenoxyacetic acid, inhibits Xenopus oocyte maturation by targeting translational and post-translational mechanisms. , LaChapelle AM., Reprod Toxicol. January 1, 2007; 23 (1): 20-31.
MAPK interacts with XGef and is required for CPEB activation during meiosis in Xenopus oocytes. , Keady BT., J Cell Sci. March 15, 2007; 120 (Pt 6): 1093-103.
Hermes RNA-binding protein targets RNAs-encoding proteins involved in meiotic maturation, early cleavage, and germline development. , Song HW., Differentiation. July 1, 2007; 75 (6): 519-28.
Involvement of Mos-MEK- MAPK pathway in cytostatic factor (CSF) arrest in eggs of the parthenogenetic insect, Athalia rosae. , Yamamoto DS., Mech Dev. January 1, 2008; 125 (11-12): 996-1008.
Identification of novel and known ovary-specific genes including ZP2, in a marsupial, the stripe-faced dunnart. , Au PC., Mol Reprod Dev. February 1, 2008; 75 (2): 318-25.
Roles of Greatwall kinase in the regulation of cdc25 phosphatase. , Zhao Y., Mol Biol Cell. April 1, 2008; 19 (4): 1317-27.
Mos 3' UTR regulatory differences underlie species-specific temporal patterns of Mos mRNA cytoplasmic polyadenylation and translational recruitment during oocyte maturation. , Prasad CK., Mol Reprod Dev. August 1, 2008; 75 (8): 1258-68.
Activation of the progesterone-signaling pathway by methyl-beta-cyclodextrin or steroid in Xenopus laevis oocytes involves release of 45-kDa Galphas. , Sadler SE., Dev Biol. October 1, 2008; 322 (1): 199-207.