|
Figure 1.
Greatwall regulates Cdc25. (A) Depletion of Greatwall from cycling extracts prevents Cdc25 activation and mitotic entry. Mock-depleted control extracts enter M phase within 80 min, as shown by M phase–specific upshifts of Cdc25 and Greatwall, the loss of the inhibitory Tyr15 phosphorylation of Cdc2, and the rapid degradation of cyclin B. Greatwall-depleted extracts fail to enter mitosis as judged by all of these criteria; similar experiments published previously (Yu et al., 2006) show that the block to mitotic entry continues for at least 60 min beyond the latest time point shown here. (B) Maintenance of mitotic phosphorylations on Cdc25C in CSF extracts requires Greatwall but not Plx1 or Cdc2 activity. Removal of Plx1 by immunodepletion and/or inhibition of Cdc2 activity by 250 μM roscovitine have no detectable impact on Cdc25C mobility (groups of Plx1Δ/−Ros and MockΔ/+Ros). Depletion of Greatwall completely eliminates the migration shift of Cdc25C (groups of Plx1Δ/GwlΔ and GwlΔ). The electrophoretic mobility of Greatwall itself is unaffected by Plx1 depletion, but roscovitine appears to cause the removal of some phosphorylations on Greatwall; this effect is only partial because Greatwall's migration is still significantly retarded (the arrow at left indicates the mobility of fully dephosphorylated Greatwall during interphase). (C) Premature mitotic entry induced by active Greatwall. Freshly made cycling extracts were incubated at 23°C starting at t = 0. Untreated cycling extracts enter mitosis at 70 min. Addition at 20 min of excess (five times the endogenous level) active wild-type Greatwall [Gwl(BV)] purified from OA-treated Sf9 cells promotes premature mitotic entry at t = 30 min, as indicated by the mobility shifts of Cdc25C and endogenous (endo) Greatwall and the dephosphorylation of Tyr15 of Cdc2. Within 20 min of mitotic entry, the extracts exit mitosis (note the degradation of cyclins A1 and B1), indicating that excess active Greatwall does not block mitotic exit. Addition of an even larger excess (7.5 times the endogenous level) of kinase-dead Greatwall (G41S) does not accelerate mitotic entry. Throughout this article, the relative amounts of recombinant and endogenous proteins were determined by Coomassie Blue staining (data not shown); the intensities of the exogenous Greatwall bands on the Western blots in B–D are distorted by the immunoglobulin Z domain in these recombinant proteins as well as some nonlinearity in the relationship between the protein amount and Western blot signal intensity (see Supplementary Figure S1E). The interaction between the Z domain and secondary antibodies accounts for ∼50% of the total signal on Western blots (Supplementary Figure S1E). (D) Greatwall purified from OA-treated Sf9 cells is less active than endogenous Greatwall. CSF egg extracts were subjected to Greatwall depletion or mock depletion (see Yu et al., 2006 for details). Greatwall-depleted egg extract was then supplemented with various amounts of mock-depleted CSF egg extract or with active purified Greatwall. Extracts were prepared for analysis 30 min after supplementation. Purified Greatwall preparations have only about one-third the activity of endogenous mitotic Greatwall in maintaining the M phase status of the extracts.
|
|
Figure 2.
Active Greatwall induces oocyte maturation in the absence of progesterone in a protein synthesis–dependent manner. (A) Oocytes were injected with active (WT) or kinase-dead (KD) Greatwall protein. Control oocytes were stimulated by progesterone (Pg). In some cases as indicated, cycloheximide (CHX) was added 1 h before Greatwall injection or progesterone addition. The graph shows the time course of germinal vesicle breakdown (GVBD). Photographs illustrate the external morphology of Greatwall-injected oocytes (Gwl) or progesterone-stimulated oocytes (Pg). (B) Oocytes were homogenized at GVBD, or 7 h after injection or stimulation when GVBD did not occur. Lysates were immunoblotted with the indicated antibodies. Cyclin B1 is expressed at a low level in immature oocytes and its synthesis is stimulated during meiotic maturation; Cyclin B2 migrates as a doublet when MPF is inactive and as a single band when MPF is active (Karaiskou et al., 2004).
|
|
Figure 3.
Greatwall can influence Cdc25 phosphorylation independent of MPF activity. (A) Greatwall promotes mitotic entry in the presence of the Cdc2 inhibitor roscovitine (Ros). Cycling extracts were incubated at 23°C (starting at t = 0) for 30 min before the addition of 250 μM Ros as indicated. Excess active Greatwall (5×) or an equal volume of buffer was added 10 min later. Extracts were processed every 10 min thereafter for Western blot analysis and Histone H1 kinase assay. (B) Greatwall promotes Cdc25 phosphorylation in the absence of MPF. To eliminate MPF activity, CSF extracts were first induced into interphase (at t = 0) by adding CaCl2 to a final concentration of 0.5 mM and then incubated at 23°C for 15 min. Cycloheximide (CHX) was then added (100 μg/ml final concentration) to inhibit protein synthesis as indicated. After another 15 min, exogenous cyclin B was supplemented to the indicated groups. At t = 40 min, active Greatwall was added as shown, and samples were collected every 10 min and processed for immunoblotting. In untreated control extracts, mitotic entry occurs at ∼120 min after CaCl2 addition (data not shown). Note that in the presence of active Greatwall, extracts enter mitosis prematurely at 50–60 min when cyclin B concentrations are low. In addition, a partial mobility shift of Cdc25 occurs at this time even when cyclin B is undetectable and (as shown in Figure 6 below) H1 kinase activity is extremely low due to CHX.
|
|
Figure 4.
Plx1 is not required for Greatwall-induced mitotic entry. Cycling extracts were subjected to mock depletion or Plx1 depletion, and then incubated starting at t = 0 for 40 min at 23°C. The extract was then supplemented with buffer (PBS) or with WT or KD Greatwall purified from OA-treated Sf9 cells. One-microliter aliquots of extracts were subsequently collected every 10 min for immunoblot analysis. As expected, Plx1 depletion causes a defect in mitotic entry. However, Plx1 depletion does not interfere with Greatwall-induced mitotic entry even though Cdc25C does not obtain its full complement of M phase phosphorylations.
|
|
Figure 5.
The MAPK pathway is not critical for Greatwall-induced activation of Cdc25. The involvement of the MAPK pathway in Greatwall-induced mitotic entry was tested in interphase extracts released from CSF arrest by the addition of CaCl2 at t = 0. Extracts were then incubated at 23°C for 30 min before U0126 was supplemented to a final concentration of 400 μM as shown. After 10 min of incubation, excess active Greatwall was added as indicated. Immunoblot analysis reveals that U0126 shuts down signaling through the MAPK pathway, but does not interfere with Greatwall's ability to induce Cdc25 phosphorylation and precocious mitotic entry.
|
|
Figure 6.
Greatwall induces the phosphorylation of Cdc25 by several mitotic kinases. Interphase extract was prepared by addition of CaCl2 to CSF extract a t = 0 and incubated at 23°C for 20 min. The extract was then supplemented with the MEK inhibitor U0126 (400 μM) and/or the protein synthesis inhibitor CHX (100 μM) or DMSO, followed by another 20-min incubation at 23°C. Extracts were then subjected to Plx1 depletion or mock depletion as indicated. One-microliter aliquots were collected immediately after the depletion and every 10 min thereafter for immunoblotting and H1 kinase assay.
|
|
Figure 7.
Greatwall overrides the effect of the PKA activator 8-Br-cAMP. Addition of 8-Br-cAMP (40 μM final concentration) effectively blocks mitotic entry in control cycling extracts; Cdc25 remains unphosphorylated, whereas inhibitory Tyr15 phosphorylations accumulate on Cdc2. The addition of excess (five times the endogenous level) active Greatwall at t = 40 min overcomes this effect of 8-Br-cAMP. In controls, the drug does not increase phosphorylation at the S287 residue of Cdc25C; the mechanism by which 8-Br-cAMP blocks mitotic entry remains unknown. The inset shows the result of a similar experiment that emphasizes the existence of Cdc25 species of retarded mobility that retain substantial Ser287 phosphorylation.
|
|
Figure 8.
OA overcomes the Greatwall depletion phenotype in cycling extracts. (A) Mock-depleted or Greatwall-depleted cycling extracts were incubated at 23°C for 40 min before supplementation with 100 or 400 nM OA in DMSO or with an equal volume of DMSO alone (0). One-microliter aliquots were collected every 10 min thereafter and processed for immunoblotting. (B) OA rescues the Plx1 depletion phenotype in cycling extracts. Mock-depleted or Plx1-depleted cycling extracts were incubated at 23°C for 40 min before supplementation with 400 nM OA or DMSO.
|
|
Supplemental Figure S1. Characterization of Greatwall’s mitosis-inducing activity. (A) Coomassie blue staining of WT and KD (G41S) Greatwall purified from OA-treated Sf9 cells. The difference in mobilities probably reflects the absence of autophosphorylation in KD Greatwall. (B) CSF egg extracts were induced into interphase by adding CaCl2 to 0.5 mM. 40 min later, various amounts of Greatwall
(WT or KD, both purified from OA-treated Sf9 cells) was added. Although 3 times the endogenous level of WT active Greatwall is sufficient to induce premature mitotic entry, the addition of up to 18 times the endogenous level of KD Greatwall has no such mitosis-promoting effect. Note that in extracts that do not enter M phase (1x WT Greatwall and all KD Greatwall concentrations), Greatwall proteins become dephosphorylated. In controls without added Greatwall, M phase entry is at ~120 min (data not shown). (C) Greatwall purified from OA-treated Sf9 cells (+OA) promotes precocious mitotic entry in interphase extracts, while Greatwall purified from cells without OA treatment (-OA) does not. (D) Greatwall protein expressed in OA-treated Sf9 cells is not fully phosphorylated. WT or KD Greatwall kinase purifed from OA-treated Sf9 cells was added to CSF extracts and incubated at 23°C. Samples were analyzed by immunoblotting at the indicated time points. WT Greatwall’s mobility becomes retarded mobility after 30 min incubation, suggesting that additional phosphorylations are added to the protein in the CSF (M phase) extract. The mobility of KD Greatwall is also retarded, but to a more limited extent, probably reflecting the defective autophosphorylation of this protein. (E) Left panel: Coomassie Blue staining of Greatwall proteins purified from Sf9 cells and bovine serum albumin (BSA) standards. The Greatwall (Gwl) sample in the first lane has no epitope tag (it was originally expressed as a His6/Myc tagged protein, but the tag was cleaved off by TEV protease). The protein in the Z-Gwl lane is Greatwall tagged with the immunoglobulin Z domain and a His tag; this is the protein added

exogenously to extracts or oocytes in the experiments shown in all other figures. Right panel: Western blot results obtained with the same purified Greatwall proteins. Note that addition of the Z domain produces more than a 2-fold increase in signal intensity. In addition, comparison of the results using 5 ng and 25 ng of these proteins shows a greater than 5-fold increase in the signal, indicating that the Western blot signal is not completely linear with respect to protein amount.
|
|
Supplemental Figure S2. The Mos-MAPK pathway is not required for Greatwall activation during oocyte maturation. Oocytes were injected (mo) or not (u) with an antisense morpholino directed against c-mos mRNA as described by Dupre et al. (2002). One hour later (t=0), progesterone was added, and oocytes were collected and homogenized either at 120 min after progesterone addition, during GVBD, or at the indicated times after GVBD. eGVBD: first pigment rearrangement detected at the animal pole (15 min before GVBD); GVBD: well-defined white spot. Homogenates were immunoblotted with antibodies against Greatwall (Gwl), Mos, phospho-MAP kinase (pMAPK) or Cyclin B2. Note that the morpholino abolishes signaling through the MAPK cascade (Mos is not synthesized and MAPK does not acquire its activating phosphorylations), yet oocyte maturation and the activation of Greatwall occur normally.
|
|
Supplemental Figure S3. Greatwall-induced mitotic entry does not require the MAPK cascade in cycling extracts. The involvement of the MAPK pathway in Greatwall-induced mitotic entry was tested in freshly-made cycling extracts to which U0126 was added at t=30 min as indicated. Active Greatwall (5 times the endogenous level) was added 10 min later. U0126 does not interfere with the precocious mitotic entry caused by active Greatwall.
|
|
Supplemental Figure S4. Greatwall does not function uniquely by regulating the S287 phosphorylation of Cdc25 nor through Calmodulin kinase II. Addition of the CaMKII inhibitor 281-309 to a final
concentration of 400 μM causes precocious mitotic entry in cycling extracts in the presence of endogenous Greatwall but does not allow Greatwall-depleted extracts to enter mitosis. Consistent with the well-established function of CaMKII in mitotic exit (Lorca et al., 1993; Rauh et al., 2005), the inhibitor-treated control extract remains in M phase as judged by Cdc25 and Greatwall phosphorylations. It is surprising that cyclin B is substantially degraded in the same extract; this may reflect the action of recently-discovered pathways that can degrade Emi2 (a factor critical for CSF arrest) in the absence of CaMKII (Rauh et al., 2005).
|