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1 vulatory period when the oocyte reenters the meiotic cell cycle.
2 id gametes relies on the specially regulated meiotic cell cycle.
3 cells begin to make the transition into the meiotic cell cycle.
4 ep that reinforces the decision to enter the meiotic cell cycle.
5 in the oocyte relieves the inhibition of the meiotic cell cycle.
6 zing hormone (LH) surge and reentry into the meiotic cell cycle.
7 es from most animals arrest twice during the meiotic cell cycle.
8 uired for the proper progression through the meiotic cell cycle.
9 PTPN13 is involved in the regulation of the meiotic cell cycle.
10 absence of the other cyclins, can drive the meiotic cell cycle.
11 lays an important role in the control of the meiotic cell cycle.
12 ome segregation phases, a key feature of the meiotic cell cycle.
13 ggest that local transposition occurs in the meiotic cell cycle.
14 d-1, which itself promotes commitment to the meiotic cell cycle.
15 e progression of male germ cells through the meiotic cell cycle.
16 thway that specifically regulates the female meiotic cell cycle.
17 in testis and is thought to function in the meiotic cell cycle.
18 on of MAP kinase and advances entry into the meiotic cell cycle.
19 links polyadenylation to the control of the meiotic cell cycle.
20 e transcriptional states through mitotic and meiotic cell cycles.
21 ferential origin activity in the mitotic and meiotic cell cycles.
22 G2/M-phase transition during the mitotic and meiotic cell cycles.
24 nsive analysis of the genes required for the meiotic cell cycle and identifies three factors importan
25 tubule perturbation occurs as they enter the meiotic cell cycle and in G(2) if cells are already unde
26 A1 in germ cells, its expression during the meiotic cell cycle and its associated kinase subunits ha
28 normally transition from the mitotic to the meiotic cell cycle and that it dramatically changes the
29 st meiosisthe switch between the mitotic and meiotic cell cycles and a later step during meiosis invo
30 his arrest, leading to the resumption of the meiotic cell cycles and maturation of the oocyte into a
32 hase of meiosis I (MI) and resumption of the meiotic cell cycles, and leads to the formation of a mat
33 ctivation of stored mRNAs, resumption of the meiotic cell cycles, and maturation of the oocyte into a
34 nts is not simply a secondary consequence of meiotic cell-cycle arrest, as spermatid differentiation
36 2 poly(A) polymerase enhances entry into the meiotic cell cycle at least in part by activating GLD-1
37 in the meiotic checkpoint that regulates the meiotic cell cycle, but not the translation of gurken mR
38 tion to functioning as key regulators of the meiotic cell cycle, cooperate in the translational activ
40 ersal cell cycle kinase required for mitotic/meiotic cell cycle entry and its activity needs to decli
41 Some mad2Delta cells have a misregulation of meiotic cell cycle events and undergo a single aberrant
42 ay essential regulatory roles in mitotic and meiotic cell cycle events, mediate CLH-3 activation.
43 e of these genes may expand our knowledge on meiotic cell cycle, fertilization, chromatin remodeling,
44 llele to drive germ-line stem cells into the meiotic cell cycle, followed by chemical inhibition of t
45 is indispensable for oocyte reentry into the meiotic cell cycle, for the synthesis of the extracellul
46 teins, each of which promotes entry into the meiotic cell cycle: GLD-1 is a STAR/Quaking translationa
48 hether germ cells are regulated to enter the meiotic cell cycle (i.e., mitosis-meiosis decision) and
51 : ameiotic1 (am1), required to establish the meiotic cell cycle in maize; absence of first division (
56 tterning implies that the progression of the meiotic cell cycle is coordinated with the regulation of
60 heir sterility results from an arrest in the meiotic cell cycle of spermatocytes, which we now identi
61 parallel developmental sequences during the meiotic cell cycle: one for premeiotic S phase and the o
62 enpH did not affect spindle organization and meiotic cell cycle progression after germinal vesicle br
65 for spermatogenesis, as null mutations block meiotic cell cycle progression and result in a complete
66 henotypes as mutations in can, blocking both meiotic cell cycle progression and spermatid differentia
68 ways early (aly) gene coordinately regulates meiotic cell cycle progression and terminal differentiat
69 mRNAs (cyclin B1, c-Mos, D7, and B9) during meiotic cell cycle progression but not for the synthesis
72 ng mammalian female meiosis, we investigated meiotic cell cycle progression in murine oocytes from XO
73 f maternal mRNA translation is essential for meiotic cell cycle progression in oocytes of the frog Xe
74 which are then recruited to ribosomes during meiotic cell cycle progression in response to progestero
79 meiotic cell cycle progression, thus linking meiotic cell cycle progression to cellular differentiati
81 SIS (TAM), is known for its positive role in meiotic cell cycle progression, but its function in othe
82 aevis, including faster and more synchronous meiotic cell cycle progression, less seasonal variabilit
83 enes, as well as several genes important for meiotic cell cycle progression, thus linking meiotic cel
84 cific genes, and several genes important for meiotic cell cycle progression, thus linking meiotic div
97 on of G(2)/M phase transition in mitotic and meiotic cell cycles requires activation by phosphorylati
99 ted the potential for known effectors of the meiotic cell cycle to activate the translation of the FG
101 lves Drosophila ATR and Chk2 coordinates the meiotic cell cycle with signaling events that establish
102 point that may serve to coordinate the male meiotic cell cycle with the spermatid differentiation pr
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