Kang Q , Pomerening JR .

R01GM086526 NIGMS NIH HHS , R01 GM086526 NIGMS NIH HHS , R01 GM086526-03 NIGMS NIH HHS

	FIGURE 1:. Cyclin B translation is attenuated before and during mitosis. (A) Time course of cyclin B levels and H1 kinase activities in cycling extracts. 35S-Met-labeled cyclin was precipitated using p13 agarose; H1 kinase assays were performed to measure CDK1 activity; both were subjected to SDS-PAGE separation and visualized by phosphorimaging. Sperm chromatin was added to extracts; aliquots were taken at various times and stained with DAPI. Sperm chromatin forms nuclei in interphase (60 min is shown as representative), and then nuclei undergo mitosis, as indicated by chromatin condensation and NEB (70 and 80 min). Data were shifted to align the peak H1 kinase activities of all three replicates, with two replicates shifted 2 and 10 min earlier, respectively, excluding the earliest and latest lone time points from the analysis. Quantitated data are plotted as means ± SEM (error bars; N = 3). Bars above micrographs and H1 kinase activities denote time points where NEB was observed. (B, C) Time course of cyclin B levels and H1 kinase activities for cycling extracts treated with DMSO (1%) or MG132 (1 mM; 1% final volume). Data were shifted to align the peak H1 kinase activities of all four replicates, with two replicates shifted 10 and 20 min earlier, respectively, excluding the earliest and latest lone time points from the analysis. Data were analyzed as described in A and plotted as means ± SEM (N = 4). Bars denote time points where NEB was observed. Also see Supplemental Figure S1.
	FIGURE 2:. Inhibiting or prematurely activating CDK1 alters the level of cyclin B synthesis. (A–C) Time course of cyclin B levels (left) and H1 kinase activities (right) for cycling extracts treated with (A) DMSO (1%) and ethanol (0.64%), MG132 (1 mM) and ethanol, or MG132 (1 mM) and roscovitine (0.18 mM); (B) DMSO (1%) and buffer, MG132 (1 mM) and buffer, or MG132 (1 mM) and Δ65XCycB1 (200 nM); (C) CHX (100 μg/ml) added at different time points prior to and during mitosis in cycling egg extract. Data were shifted to align the peak H1 kinase activities of all three replicates, with one replicate shifted 5 min earlier, excluding the earliest and latest lone time points from the analysis. Data were analyzed as described in Figure 1A and plotted as means ± SEM (A, N = 3; B, N = 2; C, N = 3). Bars denote time points where NEB was observed (A–C), and histograms correspond to cyclin levels and H1 kinase activities before and after CHX addition (C); control (no addition), dark gray bars; 30 min addition, light green bars; 40 min addition, light blue bars; 50 min, orange bars; 55 min, light gray bars.
	FIGURE 3:. Polyadenylation of the cyclin B1 mRNA 3′ UTR does not vary with changes in cyclin B1 synthesis during cycling. (A, B) Time course of cyclin B levels (left) and H1 kinase activities (right) for cycling extracts treated with (A) water or 6 or 12 ng/μl in vitro–transcribed cyclin B1 mRNA coding region; (B) DMSO (1%), MG132 (1 mM), 6 ng/μl cyclin B1 mRNA coding region and MG132 (1 mM). For A, data were shifted to align the H1 kinase activity peaks of all three replicates, with two replicates shifted 10 min earlier, excluding the earliest and latest lone time points from the analysis; for B, one replicate was shifted 30 min earlier to align peak H1 kinase activities. Data were analyzed as described in Figure 1A and plotted as means ± SEM; A, N = 3; B, N = 2. Bars denote time points where NEB was observed. (C) Pooled data of cyclin B levels (left) and H1 kinase activities (right) plotted as means ± SEM (N = 3) for results shown in D. Data were shifted to align the H1 kinase activity peaks of all three replicates, with one replicate shifted 15 min earlier, excluding the earliest and latest lone time points from the analysis. (D) 32P-Labeled, in vitro–transcribed cyclin B1 3′ UTR was incubated in cycling extracts treated with either DMSO (1%; left) or the polyadenylation inhibitor cordycepin (1 mM; right). Dot indicates addition of nonpolyadenylated UTR. Aliquots were taken at indicated time points, and total RNAs were purified, separated on denaturing urea PAGE, and visualized by phosphorimaging. H1 kinase activities and cyclin B levels were analyzed as described in Figure 1A. Representative of one of three independent experiments is shown. (E) Pooled data of cyclin B levels (left) and H1 kinase activities (right) plotted as means ± SEM (N = 3) for results shown in F. (F) 32P-Labeled, in vitro–transcribed and polyadenylated Xenopus cyclin B1 3′ UTR incubated in extracts treatment were performed as described in D. Dot indicates addition of in vitro–polyadenylated UTR. Bars denote time points where NEB was observed. Representative of one of three independent experiments is shown. Also see Supplemental Figure S2.
	FIGURE 4:. Cyclin B translational repression is mitosis specific and collaborates with APC function. (A, B) Polyadenylation of cyclin B1 mRNA promotes translation. Water, 12 ng/μl in vitro–transcribed cyclin B1 mRNA coding region, or in vitro–polyadenylated cyclin B1 mRNA coding region were added to cycling extracts arrested in interphase (I) by roscovitine (0.18 mM) and MG132 (1 mM; A) and mitosis (M) by Δ65XCycB1 (67 nM) and MG132 (1 mM; B), respectively, in the presence of 35S-Met. Aliquots were collected at 15-min intervals and analyzed as described in Figure 1A. Cyclin B levels and H1 kinase activities are plotted as means ± SEM (N = 2). Bars denote time points where NEB was observed. (C) Cyclin B is translated in CSF-M extract. CSF-M extracts were treated with DMSO (1%) and buffer, DMSO and Δ65XCycB1 (65 nM), MG132 (1 mM) and buffer, or MG132 (1 mM) and Δ65XCycB1 (65 nM). Samples were collected at 15-min intervals and analyzed as described in Figure 1A. Quantitated data are plotted as means ± SEM (N = 2). Bars denote time points where NEB was observed. (D) Rapid production of cyclin B1 hampers its destruction and causes mitotic arrest. Time course of H1 kinase activities (right) and cyclin B levels (left) for cycling extracts treated with water, 24 or 48 ng/μl cyclin B1 mRNA coding region. Quantitated data are plotted as means ± SEM (N = 2). Bars denote time points where NEB was observed. Also see Supplemental Figures S3 and S4.
	FIGURE 5:. A reduction of cyclin B1 mRNA content in polysome fractions at M phase corresponds to its diminished translation. (A) Luciferase mRNA is poorly translated in mitosis-arrested extract. In vitro–transcribed luciferase mRNA (5 ng/μl) was added to cycling extracts treated with either buffer or Δ65XCycB1 (200 nM). Samples were collected at 15-min intervals in a 96-well plate cooled on ice, and luciferase assays were then performed. H1 kinase activities were analyzed as described in Figure 1A (bottom) and plotted with luciferase signals as means ± SEM (N = 2; top), in cycling egg extract (boxes), and Δ65XCycB1-arrested extract (dots). Data were shifted to align the H1 kinase activity peaks of both replicates, with one replicate shifted 15 min earlier, excluding the earliest and latest lone time points from the analysis. Bars above H1 kinase activities denote time points where NEB was observed. (B) Top, samples of interphase extract and mitotic extract (just prior to NEB) were separated by sucrose gradient centrifugation. Total RNA from 40S, 60S, 80S, and polysome fractions was purified, and the distribution of cyclin B1 mRNA was analyzed by qRT-PCR. Left of the dashed line is defined as nonpolysome fraction (40S, 60S, and 80S) and on its right is defined as the polysome fraction. The percentage cyclin B1 mRNA in each fraction was quantitated and normalized as a percentage of total across all fractions, in duplicate. (B) Bottom, differences in the percentage of cyclin B1 mRNA in nonpolysome and polysome fractions (n − p) between interphase and mitosis is presented as mean ± SEM (N = 3). Also see Supplemental Figure S5.
	FIGURE 6:. Attenuation of cyclin synthesis at M phase yields a CDK1 oscillator with some functional advantages. (A) Schematic of ODE model with constant cyclin synthesis (left); three oscillations of cyclin (gray) and CDK1 activity (black) from ODE model with constant cyclin synthesis (ksynthcycB = 0.2; ksynthcycBoff = 0; right). In this model, APC degrades all cyclin complexed with CDK1 and newly synthesized cyclin monomer. (B) Schematic of ODE model with pulses of cyclin synthesis caused by CDK1 activity repressing cyclin synthesis (left); three oscillations of cyclin (gray) and CDK1 activity (black) from ODE model with pulses of cyclin synthesis (ksynthcycB = 0.33; ksynthcycBoff = 0.2; right). In this model, CDK1 activity is inhibitory toward cyclin synthesis. Note that although the inhibitory leg of APC toward cyclin monomer shown in B is included in this computational model, it effectively disappears because no new cyclin synthesis occurs once APC is active. (C) Cyclin levels (top) and CDK1 activity (bottom) of ODE models with either constant cyclin synthesis (black) or cyclin pulses (gray) during a single oscillation (shown as the third oscillation in the simulation from 150 to 220 min to avoid minor variations in initial transients). (D) Peak cyclin levels (left) and trough cyclin levels (right) generated by ODE models with constant cyclin synthesis (black) or cyclin pulses (gray) as the parameter ksynthcycB (rate of cyclin synthesis) is varied. For consistency, peak and trough values of the limit cycle oscillations were measured. Arrows extending from the abscissa demarcate ksynthcycB values that produce a frequency of CDK1 oscillations representative of that observed in cycling egg extracts (shown in A and B, for constant synthesis and pulse, respectively); horizontal lines toward the ordinate indicate the median value required to produce the oscillations in the constant cyclin synthesis (black) and cyclin pulse (gray) models as shown in A and B, respectively. To generate oscillations in the cyclin pulse model, ksynthcycB values >1.8 were required. (E) Comparison of the sensitivity to changes in cyclin synthesis rate (ksynthcycB) between CDK1 oscillator models with constant or attenuated cyclin synthesis. Black arrow indicates changes in ksynthcycB required for an increase from three to four oscillations over a period of 250 min; gray arrow indicates changes in ksynthcycB required for an increase from four to five oscillations (left). Histogram (right) plotting differences in the average change in oscillation number over a period of 250 min per change in ksynthcycB, showing differences in sensitivity to increasing the oscillation number from three to four (left histogram pair; refer to black arrow in left plot) and from four to five (right histogram pair; refer to gray arrow in left plot).

Azzam, Mechanism of puromycin action: fate of ribosomes after release of nascent protein chains from polysomes. 1973, Pubmed

Azzam, Mechanism of puromycin action: fate of ribosomes after release of nascent protein chains from polysomes. 1973, Pubmed
Baker, Wnt signaling in Xenopus embryos inhibits bmp4 expression and activates neural development. 1999, Pubmed , Xenbase
Ballantyne, A dependent pathway of cytoplasmic polyadenylation reactions linked to cell cycle control by c-mos and CDK1 activation. 1997, Pubmed , Xenbase
Beal, Effect of UV on cleavage of Xenopus laevis. 1975, Pubmed , Xenbase
Beckhelling, Timing of calcium and protein synthesis requirements for the first mitotic cell cycle in fertilised Xenopus eggs. 1999, Pubmed , Xenbase
Belloc, Sequential waves of polyadenylation and deadenylation define a translation circuit that drives meiotic progression. 2008, Pubmed
Blower, Genome-wide analysis demonstrates conserved localization of messenger RNAs to mitotic microtubules. 2007, Pubmed , Xenbase
Bonneau, Involvement of the 24-kDa cap-binding protein in regulation of protein synthesis in mitosis. 1987, Pubmed
Borisuk, Bifurcation analysis of a model of mitotic control in frog eggs. 1998, Pubmed
Busenberg, Mathematical models of the early embryonic cell cycle: the role of MPF activation and cyclin degradation. 1994, Pubmed
Creanor, Patterns of protein synthesis during the cell cycle of the fission yeast Schizosaccharomyces pombe. 1982, Pubmed
Datta, Increased phosphorylation of eukaryotic initiation factor 2alpha at the G2/M boundary in human osteosarcoma cells correlates with deglycosylation of p67 and a decreased rate of protein synthesis. 1999, Pubmed
Drapkin, Analysis of the mitotic exit control system using locked levels of stable mitotic cyclin. 2009, Pubmed
Evans, Cyclin: a protein specified by maternal mRNA in sea urchin eggs that is destroyed at each cleavage division. 1983, Pubmed
Fan, Regulation of protein synthesis in mammalian cells. II. Inhibition of protein synthesis at the level of initiation during mitosis. 1970, Pubmed
Ferrell, Modeling the cell cycle: why do certain circuits oscillate? 2011, Pubmed , Xenbase
Georgi, Timing of events in mitosis. 2002, Pubmed , Xenbase
Gerhart, Cell cycle dynamics of an M-phase-specific cytoplasmic factor in Xenopus laevis oocytes and eggs. 1984, Pubmed , Xenbase
Goldbeter, A minimal cascade model for the mitotic oscillator involving cyclin and cdc2 kinase. 1991, Pubmed
Goldbeter, Arresting the mitotic oscillator and the control of cell proliferation: insights from a cascade model for cdc2 kinase activation. 1996, Pubmed
Groisman, CPEB, maskin, and cyclin B1 mRNA at the mitotic apparatus: implications for local translational control of cell division. 2000, Pubmed , Xenbase
Groisman, Translational control of the embryonic cell cycle. 2002, Pubmed , Xenbase
Hansen, Emi2 at the crossroads: where CSF meets MPF. 2007, Pubmed , Xenbase
Hartley, In vivo regulation of the early embryonic cell cycle in Xenopus. 1996, Pubmed , Xenbase
Isoda, Dynamic regulation of Emi2 by Emi2-bound Cdk1/Plk1/CK1 and PP2A-B56 in meiotic arrest of Xenopus eggs. 2011, Pubmed , Xenbase
Kanki, The cell cycle dependence of protein synthesis during Xenopus laevis development. 1991, Pubmed , Xenbase
Kim, RINGO/cdk1 and CPEB mediate poly(A) tail stabilization and translational regulation by ePAB. 2007, Pubmed , Xenbase
Kim, Measuring CPEB-mediated cytoplasmic polyadenylation-deadenylation in Xenopus laevis oocytes and egg extracts. 2008, Pubmed , Xenbase
Lahav-Baratz, Reversible phosphorylation controls the activity of cyclosome-associated cyclin-ubiquitin ligase. 1995, Pubmed
Le Breton, Translational control during mitosis. 2005, Pubmed
Malureanu, Cdc20 hypomorphic mice fail to counteract de novo synthesis of cyclin B1 in mitosis. 2010, Pubmed
Murray, Cell cycle extracts. 1991, Pubmed
Murray, Cyclin synthesis drives the early embryonic cell cycle. 1989, Pubmed , Xenbase
Norel, A model for the adjustment of the mitotic clock by cyclin and MPF levels. 1991, Pubmed
Novak, Numerical analysis of a comprehensive model of M-phase control in Xenopus oocyte extracts and intact embryos. 1993, Pubmed , Xenbase
Obeyesekere, Mathematical models for the cellular concentrations of cyclin and MPF. 1992, Pubmed
Paillard, Poly(A) metabolism in Xenopus laevis embryos: substrate-specific and default poly(A) nuclease activities are mediated by two distinct complexes. 1996, Pubmed , Xenbase
Pomerening, Systems-level dissection of the cell-cycle oscillator: bypassing positive feedback produces damped oscillations. 2005, Pubmed , Xenbase
PRESCOTT, Synthesis of RNA and protein during mitosis in mammalian tissue culture cells. 1962, Pubmed
Pyronnet, Suppression of cap-dependent translation in mitosis. 2001, Pubmed
Pyronnet, Cell-cycle-dependent translational control. 2001, Pubmed
Salb, Translational inhibition in mitotic HeLa cells. 1965, Pubmed
Sheets, The 3'-untranslated regions of c-mos and cyclin mRNAs stimulate translation by regulating cytoplasmic polyadenylation. 1994, Pubmed , Xenbase
Sible, Mathematical modeling as a tool for investigating cell cycle control networks. 2007, Pubmed , Xenbase
Sivan, Mitotic modulation of translation elongation factor 1 leads to hindered tRNA delivery to ribosomes. 2011, Pubmed
Sivan, Ribosomal slowdown mediates translational arrest during cellular division. 2007, Pubmed
Smythe, Systems for the study of nuclear assembly, DNA replication, and nuclear breakdown in Xenopus laevis egg extracts. 1991, Pubmed , Xenbase
Solomon, Cyclin activation of p34cdc2. 1990, Pubmed , Xenbase
Sonenberg, Regulation of translation initiation in eukaryotes: mechanisms and biological targets. 2009, Pubmed
Spriggs, Translational regulation of gene expression during conditions of cell stress. 2010, Pubmed
Stiffler, Cyclin A and B functions in the early Drosophila embryo. 1999, Pubmed
Tsai, Robust, tunable biological oscillations from interlinked positive and negative feedback loops. 2008, Pubmed , Xenbase
Tyson, Modeling the cell division cycle: cdc2 and cyclin interactions. 1991, Pubmed
Vardy, The Drosophila PNG kinase complex regulates the translation of cyclin B. 2007, Pubmed
Voeltz, A novel embryonic poly(A) binding protein, ePAB, regulates mRNA deadenylation in Xenopus egg extracts. 2001, Pubmed , Xenbase
Wasserman, The cyclic behavior of a cytoplasmic factor controlling nuclear membrane breakdown. 1978, Pubmed , Xenbase
White, Specific regulation by endogenous polyamines of translational initiation of S-adenosylmethionine decarboxylase mRNA in Swiss 3T3 fibroblasts. 1990, Pubmed
Wu, PP1-mediated dephosphorylation of phosphoproteins at mitotic exit is controlled by inhibitor-1 and PP1 phosphorylation. 2009, Pubmed , Xenbase
Wu, A role for Cdc2- and PP2A-mediated regulation of Emi2 in the maintenance of CSF arrest. 2007, Pubmed , Xenbase
Zhao, Comprehensive algorithm for quantitative real-time polymerase chain reaction. 2005, Pubmed