- Research article
- Open Access
Quantitative framework for ordered degradation of APC/C substrates
© Lu et al. 2015
- Received: 14 July 2015
- Accepted: 23 October 2015
- Published: 16 November 2015
During cell-cycle progression, substrates of a single master regulatory enzyme can be modified in a specific order. Here, we used experimental and computational approaches to dissect the quantitative mechanisms underlying the ordered degradation of the substrates of the ubiquitin ligase APC/CCdc20, a key regulator of chromosome segregation in mitosis.
We show experimentally that the rate of catalysis varies with different substrates of APC/CCdc20. Using a computational model based on multi-step ubiquitination, we then show how changes in the interaction between a single substrate and APC/CCdc20 can alter the timing of degradation onset relative to APC/CCdc20 activation, while ensuring a fast degradation rate. Degradation timing and dynamics depend on substrate affinity for the enzyme as well as the catalytic rate at which the substrate is modified. When two substrates share the same pool of APC/CCdc20, their relative enzyme affinities and rates of catalysis influence the partitioning of APC/CCdc20 among substrates, resulting in substrate competition. Depending on how APC/CCdc20 is partitioned among its substrates, competition can have minor or major effects on the degradation of certain substrates. We show experimentally that increased expression of the early APC/CCdc20 substrate Clb5 does not delay the degradation of the later substrate securin, arguing against a role for competition with Clb5 in establishing securin degradation timing.
The degradation timing of APC/CCdc20 substrates depends on the multi-step nature of ubiquitination, differences in substrate-APC/CCdc20 interactions, and competition among substrates. Our studies provide a conceptual framework for understanding how ordered modification can be established among substrates of the same regulatory enzyme, and facilitate our understanding of how precise temporal control is achieved by a small number of master regulators to ensure a successful cell division cycle.
- Cell cycle
Progression through the cell cycle is accompanied by dramatic changes in cellular content and behavior, and involves a large number of proteins and processes. These changes are orchestrated by a small number of master regulators, including the cyclin-dependent kinases (Cdks) and the anaphase-promoting complex/cyclosome (APC/C). Each Cdk or APC/C isoform has a large number of substrates, and the substrates of each isoform are modified in a specific order that leads to sequential substrate activation or inactivation. This ordering of substrate modification allows a small number of master regulators to carry out their functions over a large time window with high temporal resolution, enabling precise and robust control of the numerous processes underlying cell cycle progression [1, 2].
The APC/C is an E3 ubiquitin ligase that drives mitotic progression by promoting timely degradation of key regulatory proteins . In early mitosis, the APC/C associates with its activator subunit Cdc20 and promotes degradation of the S cyclin, cyclin A (in mammals) or Clb5 (in yeast), followed by securin several minutes later [4–6]. Securin degradation then unleashes separase to promote sister-chromatid separation. APC/CCdc20 also initiates the degradation of M cyclin, cyclin B (in mammals) or Clb2 (in yeast), around the same time as securin [5, 6]. The activator Cdc20 is then replaced by a second activator, Cdh1, and APC/CCdh1 promotes complete degradation of M cyclin, followed by polo-like kinase 1, Aurora A, and other substrates, to complete mitosis and cytokinesis and drive progression into G1 [1, 2].
The APC/C, as a multi-subunit RING-domain E3 ubiquitin ligase, acts as a platform that brings together a substrate and an E2 charged with ubiquitin, thereby catalyzing ubiquitin transfer from the E2 to the substrate (Additional file 1: Figure S1A) [3, 7, 8]. Specific substrates generally bind with sufficient affinity that they remain bound during multiple ubiquitin transfer reactions, resulting in processive substrate modification [9, 10]. Ubiquitins can be added to multiple lysine residues on the substrate, or can be added to pre-attached ubiquitins to build a polyubiquitin chain. These chains are recognized by the proteasome, leading to substrate degradation .
The activator Cdc20 or Cdh1 recruits substrate to the APC/C by interacting with short linear sequence motifs or degrons, such as the D box and KEN box [3, 8, 12]. In addition to recruiting substrates, the activator subunit induces a conformational change in the APC/C core, thereby enhancing E2 binding and the rate of ubiquitin transfer [13, 14]. Interestingly, the D box and KEN box of substrates contribute to this activation process. When substrates are directly fused to the APC/C core, thus bypassing the need of the D box and the KEN box for the recruitment of substrates to the APC/C, the presence of these degron motifs still increases the ability of the activator to promote ubiquitin transfer . Thus, substrate degrons could potentially influence both the affinity for the APC/C and the catalytic rate of ubiquitin transfer.
APC/CCdc20 activation depends on the expression of Cdc20 and phosphorylation of core APC/C subunits [15, 16]. Complete APC/CCdc20 activation also requires inactivation of the spindle assembly checkpoint (SAC), which monitors proper attachment of sister chromatids to the spindle [17, 18]. In mammalian cells, cyclin A is degraded when the SAC is on, while securin degradation begins when the SAC is turned off, resulting in their sequential degradation [4, 19]. In the budding yeast Saccharomyces cerevisiae, we recently showed that the SAC is turned off earlier than securin degradation, and the different timing of Clb5 and securin degradation is due to several other mechanisms (Additional file 1: Figure S1B-E) . In addition to its canonical D box, yeast Clb5 has an ABBA motif that mediates an extra interaction with Cdc20. Clb5 also interacts with Cdk1 in a complex with the phosphate-binding accessory subunit, Cks1. Cdk1-Cks1 binds directly to phosphorylated APC/C core subunits  and can thus bridge Clb5 to APC/C. These mechanisms make Clb5 an excellent APC/CCdc20 substrate, and Clb5 is the first substrate to be degraded when APC/CCdc20 becomes active . Similar mechanisms promote cyclin A degradation in the presence of an active SAC in mammalian cells [20–22]. Yeast securin degradation, on the other hand, is delayed by Cdk1 phosphorylation near its D box and KEN box, and lags behind Clb5. When all these differences are eliminated, the degradation of Clb5 and securin occurs around the same time .
In our previous single-cell studies, differences in the degradation timing of different substrates (calculated as the time when 50 % of the substrate is degraded) were accompanied by relatively minor differences in their rates of degradation. For example, Clb5 is degraded six minutes earlier than securin, while the difference in their apparent half-life is less than 1.5 min (Additional file 1: Figure S1F) . Thus, the overall timing of substrate degradation may be determined primarily by the timing of degradation onset. If true, this leads to an interesting question: if the mechanisms mentioned above make one substrate better than another, how do these mechanisms change the timing of degradation onset while having a relatively small effect on the rate of degradation? In other words, why don’t later substrates begin to be degraded as soon as APC/CCdc20 becomes active?
In the current work, we show that differences in degradation onset indeed account for a major part of the overall differences in degradation timing for Clb5 and securin, and we explore how this differential onset is achieved. We first show that the ABBA motif of Clb5 increases the catalytic rate of ubiquitin transfer when Clb5 is bound to APC/CCdc20, confirming that different substrates can be modified at different rates. We then build computational models that capture the interaction between the substrate and APC/CCdc20, and we use these models to test the effects of substrate-specific changes in binding affinity and catalytic rate. In a one-substrate system lacking competition among different substrates, a multi-step ubiquitination process can produce a robust delay in substrate degradation relative to APC/CCdc20 activation, while maintaining a rapid degradation rate like that we observed in the cell. In a two-substrate system with a limited amount of APC/CCdc20, competition can further influence the timing of degradation by limiting the amount of APC/C available for each substrate. The degradation timing of substrates is thus determined collectively by substrate-APC/CCdc20 interactions and APC/CCdc20 partitioning among substrates, both of which are influenced by differences in kinetic parameters among substrates. We then show experimentally that increasing the amount of Clb5 does not significantly delay the degradation of securin, arguing that competition with Clb5 is not a major determinant of securin degradation timing in the cell. Finally, we use a modified one-substrate model to show that processivity in substrate ubiquitination is related to but not entirely predictive of degradation timing.
Substrates of APC/CCdc20 have different times of degradation onset
In our previous work, we established a single-cell assay to track the degradation dynamics of APC/CCdc20 substrates in the budding yeast Saccharomyces cerevisiae. We tagged each substrate with green fluorescent protein (GFP) to follow its change in concentration over time. In the same strain, we also tagged the spindle-pole body (SPB) component Spc42 with mCherry. The SPB is seen as one dot in G1 and S phase, and separates into two dots at the onset of mitosis. At the metaphase-anaphase transition, the spindle begins to elongate and the two SPB dots move quickly away from each other. These two SPB events serve as single-cell timing references that allow us to align and compare GFP-tagged substrate degradation dynamics in different cells, either from the same strain or with different GFP-tagged substrates .
Previously, we estimated degradation timing by using the time point when 50 % of the GFP-tagged substrate was degraded. Here, we re-processed our previously published data to determine the timing of degradation onset. For each single-cell GFP trace, we smoothed and normalized the curve and calculated its first derivative (Additional file 1: Figure S2A). The minimum of the smoothed first derivative curve corresponds to the fastest declining point on the GFP trace during substrate degradation (Additional file 1: Figure S2A; yellow dots). Working backwards in time from that point, we identified the latest time point at which the smoothed first derivative was close to zero, which we used as our estimate of the time of degradation onset (Additional file 1: Figure S2A, B; green dots).
For all the substrates we analyzed, differences in substrate degradation timing were accompanied by significant differences in the timing of degradation onset (Additional file 1: Figure S3). Most relevant for this work are three substrates: Clb5, securin-2A, and Clb5-2A. The degradation onset of securin-2A, in which the inhibitory Cdk phosphorylation sites are mutated (T27A, S71A), begins an average of four min after Clb5 (Additional file 1: Figure S3A, Student's t-test, p-value <0.001). We focused on securin-2A instead of securin because these Cdk phosphorylation sites establish a positive feedback loop in securin degradation that could complicate our computational modeling . Clb5-2A, in which the ABBA motif is mutated (I102A and Y103A), begins to be degraded three min later than wild-type Clb5 (Additional file 1: Figure S3B, Student's t-test, p-value <0.001). Since the ABBA motif allows Clb5 to compete with spindle assembly checkpoint (SAC) proteins for Cdc20 binding [6, 20], it is possible that the delay in Clb5-2A degradation relative to wild-type Clb5 is due to weak remaining SAC activity that does not inhibit Clb5 degradation. However, when we disable the SAC by deleting its key effector protein Mad2, Clb5-2A degradation is delayed relative to Clb5 to the same extent as it is in wild-type cells (Additional file 1: Fig S3C, D). Therefore, we attribute the delay in Clb5-2A degradation to a change in the Clb5-2A-APC/CCdc20 interaction that is independent of the SAC.
The onset of Clb5 degradation indicates the time at which the SAC is turned off and APC/CCdc20 first becomes active . Thus, other substrates, such as Clb5-2A and securin-2A, are degraded several minutes after APC/CCdc20 becomes active. It is worth noting that in the strain where Clb5-2A degradation was monitored, wild-type Clb5 is deleted and there are no known APC/CCdc20 substrates that are better than Clb5-2A (Additional file 1: Figure S1C-E). Nevertheless, Clb5-2A degradation is delayed even though the timing of APC/CCdc20 activation should remain the same.
Clb5 ABBA motif increases the catalytic rate of Clb5 ubiquitination
A simple dynamic model for APC/CCdc20-mediated substrate ubiquitination and degradation
The initial concentration of the free substrate was set at 200 nM, based on previous estimates of Clb5 concentration in the cell . We fixed the rate of APC/CCdc20 accumulation p A at 0.06 nM/sec, based on estimates of Cdc20 concentration obtained by single-cell analysis of GFP-tagged Cdc20 (Additional file 1: Figure S5). The degradation rate constant e was fixed at 1,000/sec, ensuring that substrate was degraded as soon as it was modified with four ubiquitins. All other parameters were varied across a range of values. We varied the substrate ubiquitination and dissociation rate constants k c and k d from 10−3/sec to 103/sec, based in part on previous enzymatic reaction results in vitro [9, 14, 25]. Substrate association rate constant k a varied from 10−4/(nM sec) to 10/(nM sec) (that is, 105 to 1010/[M sec]). Note that k a should be similar for different substrates as it is mostly determined by rates of random collisions, but we still analyzed a range of k a values to gain insights about the system.
We evaluated our model at 25 values for k c and k d and six values for k a , all evenly distributed on a log scale, so that each k c and k d value was changed by a factor of 1.8, and k a changed by a factor of 10, as compared to its immediate neighbors. For each set of parameters, we calculated the dynamics of substrate concentration over a period of 50 min, which is similar to the duration of a movie for experimental analysis (Fig. 2b).
Delay in degradation onset and fast degradation rate are opposing constraints
Deubiquitination helps establish a delay at a cost to degradation rate
The ubiquitination state of a protein is determined by the relative rates of ubiquitination and deubiquitination. We thus analyzed the role of deubiquitination in our model by incorporating a deubiquitination reaction for all substrates with ubiquitins attached, bound to APC/CCdc20 or not. This led to an increase in the delay of degradation onset but also reduced the degradation rate, and was not essential to reproduce the experimentally observed delayed substrate degradation onset (Fig. 3d). We also tried allowing deubiquitination only for free substrates, only for APC/CCdc20-bound substrates, or only for substrates with one ubiquitin attached , and obtained similar results (Additional file 1: Figure S6).
Varying the dissociation rate constant k d influences degradation timing when free APC/CCdc20 is available
To measure the change in T95 that results from a small change in k c , we calculated the relative decrease in T95 following an increase in k c by a factor of 1.8 (Fig. 4b, left panel), starting with every k c -k d combination (Fig. 4b, middle panel). Increasing k c decreased T95 significantly throughout the parameter space, except in the region where degradation occurs extremely fast due to large k c .
Similarly, we calculated the relative decrease in T95 after a decrease in k d by a factor of 1.8 (Fig. 4b, right panel). Decreasing k d caused a significant decrease in T95 primarily in the area where free APC/CCdc20 is available (Fig. 4c; see also Additional file 1: Figure S7). In the lower left parameter region where varying k d does not significantly influence T95, all APC/CCdc20 molecules are occupied by substrate, ubiquitination occurs at the maximum rate, and varying k d does not significantly change the amount of substrate-bound APC/CCdc20.
A model system with two substrates sharing the same pool of APC/CCdc20 readily generates differences in degradation onset
Since the amount of Cdc20 is not in large excess over substrates in vivo (Additional file 1: Figure S5), competition among substrates for APC/CCdc20 is possible. To understand how competition might influence substrate degradation timing, we analyzed a model with two substrates, C and S, that are based on the yeast substrates Clb5 and securin-2A. The two substrates start at the same concentration and interact with the same pool of APC/CCdc20. The only difference is that C is a better substrate than S, either by having: (1) a smaller dissociation rate constant k d,C that is 1/10 the k d,S of S; or (2) a larger catalytic rate constant k c,C that is 10-fold greater than the k c,S of S.
We then analyzed the differences in degradation rate (Td) between C and S (Figs. 5b and 6b). C generally had a higher degradation rate than S (TdC/TdS < 1), whether its affinity for APC/CCdc20 was higher (Fig. 5b) or its rate of catalysis was higher (Fig. 6b), which is consistent with our previous observation that the rate of Clb5 degradation in vivo is slightly higher than that of securin-2A (Additional file 1: Figure S1F) . Only one parameter region did not generate this result: when C had higher affinity for APC/CCdc20, the degradation rate of C was slower than that of S at some low values of k d,S and k c,S (Fig. 5b; yellow and orange region, TdC/TdS > 1).
Substrate competition could delay degradation by decreasing available APC/CCdc20
We next explored in more detail how two different substrates influence each other’s degradation timing and rate, by comparing degradation of S in a two-substrate system to that in a one-substrate system with the same parameter values. We reasoned that in parameter regions where C has little effect on S degradation, the timing and rate of S degradation are determined primarily by its interaction with APC/CCdc20 as in a one-substrate system, and all the properties of a one-substrate system apply.
We first analyzed the two-substrate system in which C binds APC/CCdc20 with ten-fold higher affinity than S (k d,C is 1/10 k d,S ), as described above. We calculated the relative increase in the T95 of S following the addition of C to the system, compared to S being the only substrate. In one parameter region, the addition of C significantly delayed the degradation of S (Fig. 5c; left and middle panel, red region). Under these conditions, C competitively inhibits S degradation by occupying a large amount of APC/CCdc20, thereby reducing the amount of APC/CCdc20 available to S (Fig. 5d). In the other parameter regions, k d,S is sufficiently large to allow more free APC/CCdc20 in the one-substrate system (see Fig. 4c), and the additional C in the system occupies only a small fraction of APC/CCdc20. This helps buffer against the effect of adding C to the system, and C does not delay S degradation significantly (Fig. 5c; right panel).
Interestingly, C did not have a significant impact on S in our alternate two-substrate system in which C is 10-fold more efficiently ubiquitinated once bound to APC/CCdc20. Addition of C to this system had very little effect on the degradation of S in the entire parameter region (Fig. 6c). In this scenario, when C is bound to APC/CCdc20, the substrate either dissociates or is rapidly ubiquitinated and destroyed. This short life-time of the C-APC/CCdc20 complex results in a very small population of C-bound APC/CCdc20 (Fig. 6d). Thus, C does not sequester APC/CCdc20 away from S and has little influence on S degradation, and the delayed degradation of S is primarily established by the parameters of its interaction with the APC/CCdc20 as in the one-substrate system. Interestingly, in some parameter regions in this scenario, S is more efficient in occupying APC/CCdc20 and can delay degradation of C (Fig. 6c; left panel).
The two-substrate systems we analyzed are both extreme cases. In reality, Clb5 could be better than securin-2A due to relatively small improvements in both k d and k c . For instance, our biochemical studies showed that the ABBA motif of Clb5 can increase its k c (Fig. 1), and others have shown that the ABBA motif of cyclin A can decrease its k d . Other APC/C-interacting motifs are also likely to have similar effects on both k d and k c . These parameters influence both the substrate-APC/CCdc20 interaction and the effect of competition for limited amounts of APC/CCdc20. For the Clb5-2A mutant that lacks the ABBA motif, the delayed degradation onset compared to Clb5 might be a combined result of being a less efficient APC/CCdc20 substrate and possibly less efficient in competing with other substrates for APC/CCdc20 binding.
Similar conclusions are reached in models with constant APC/CCdc20 activity
Clb5 does not significantly delay securin degradation
Processivity is determined by a subset of the factors that determine degradation timing and dynamics
A key feature of the APC/CCdc20 system is the multi-step ubiquitination process. A substrate that takes longer to acquire enough ubiquitins for efficient degradation, either due to lower affinity binding to APC/CCdc20 or a slower rate of ubiquitination once it is bound, will take longer to initiate degradation. If two substrates differ only in their catalytic rate of ubiquitin transfer, they will have different timing of degradation onset (in both one- and two-substrate systems). If two substrates differ only in their binding affinity for APC/CCdc20, then each substrate by itself (in a one-substrate system) may not have dramatically different degradation onset timing. However, when the two substrates share the same pool of APC/CCdc20, the substrate with tighter binding affinity might sequester APC/CCdc20 away from the other substrate to delay its degradation. As a result, regardless of whether substrates differ in their k c or k d , they are very likely to have different times of degradation onset. Ordered substrate degradation is therefore likely to be the default output of the APC/C ubiquitination system.
It is important to emphasize that competition among substrates is not necessary for delayed substrate degradation relative to APC/CCdc20 activation. The impact of competition depends on how APC/CCdc20 is partitioned among its substrates, which is determined by the relative concentrations of APC/CCdc20 and all of its substrates, and the relative strengths of substrate-specific kinetic parameters. These parameters are not readily determined inside the cell, and so the effect of competition in vivo is difficult to predict. Nevertheless, it is possible to gain some insight by testing the effects of small perturbations in substrate concentrations within a physiologically relevant range. We showed, for example, that an extra copy of Clb5 has no effect on the timing of securin degradation, suggesting that competition from Clb5 does not delay securin degradation. However, Clb5 and securin are not the only substrates in the cell that compete for APC/CCdc20 binding. A complete understanding of competition in this system will require more extensive experiments that take all substrates into account.
Previous work unveiled multiple mechanisms that influence substrate degradation timing, such as the ABBA motif and Cdk1/Cks1 binding of Clb5, as well as the phosphorylation of securin. However, it is not clear which parameters these mechanisms actually influence. An obvious and very likely possibility is that many of these mechanisms simply change the affinity of a substrate for APC/CCdc20, which can have an impact on the timing of degradation. Our experimental and modeling work also point to a less intuitive possibility: changes in substrate binding to APC/CCdc20 can affect catalytic rate. Here, we showed that the ABBA motif increases k c for Clb5 by nearly two-fold. Similarly, in previous work, we showed that binding of the D box and KEN box of substrates to the activator subunit helps promote catalytic function . These results raise the interesting possibility that APC/CCdc20 substrate binding and catalytic stimulation are intrinsically coupled, such that degrons enhance both affinity and catalysis. One potential explanation is that binding of additional degron motifs to the activator reduces the flexibility of disordered substrate regions flanking the binding sites, thereby reducing unproductive substrate orientations and allowing more efficient ubiquitin transfer. In addition, substrate-activator binding might help orient the activator to enhance the efficiency of E2 binding, and different substrates might be more or less effective in doing this.
A more complete understanding of the system requires knowledge of real rate constants in vivo, which are not well characterized. Catalytic rates measured in APC/C reactions in vitro are very low and seem unlikely to be reflective of real rates in vivo; for example, we recently observed that the catalytic rate constant of ubiquitin transfer with APC/CCdh1 is roughly 0.001/sec with the E2 Ubc4, using a securin-Apc10 fusion protein as substrate ; this rate is likely to be lower than actual rates because it was measured with methylated ubiquitin. We are similarly uncertain about the affinity of substrates for the APC/C. The apparent KM for sea urchin cyclin B with APC/CCdh1 is 63 nM , and an equilibrium dissociation constant kD in the range of 100 nM to 1 μM is a reasonable estimate for a substrate with two short linear degrons. If we assume that APC/C-substrate association is simply diffusion-limited, then the association rate constant k a would be roughly 0.0001 ~ 0.001/(nM sec) (i.e., 105 ~ 106/(M sec)). If the kD is 100 nM to 1 μM, then we might predict a dissociation rate constant k d of 0.01 ~ 1/sec.
All of these values fall within the parameter space we studied. However, it is inappropriate to directly map these estimates on our parameter space, as the models greatly simplify the real system in several respects. For example, we assumed linearly increasing or constant APC/CCdc20 levels, while APC/CCdc20 activation dynamics in vivo could be much more complex. In addition, we considered only single ubiquitin chain formation, we did not explicitly model activator and E2 binding to APC/CCdc20, and we assumed the same rate constants for all steps. It is also important to note that our experiments measure the degradation of substrate, which is a combined result of ubiquitination and proteasomal degradation. Since the mutants we analyzed specifically perturb the substrate-APC/CCdc20 interaction, we focused on the ubiquitination process. It is possible, however, that substrate-specific differences in proteasomal degradation also contribute to the dynamics of substrate degradation.
By constructing simple models and scanning a broad range of reasonable parameters, our goal was not to reproduce precisely the behavior of substrates in the cell, but rather to obtain useful general insights into the key factors that determine the sequential modification of APC/C targets during progression through mitosis. Our conclusions are far from comprehensive and definitive, but we hope that they will motivate and serve as a primer for future investigations. It is likely that similar principles will help us understand the sequential phosphorylation and dephosphorylation of protein kinase targets during the cell cycle. Cdk1 substrates, for example, often have multiple phosphorylation sites, and ordered substrate phosphorylation is likely to depend on variations in docking motifs that confer differences in specificity (defined as k cat /KM) . Similarly, the sequential dephosphorylation of yeast Cdk1 substrates in late mitosis is thought to be a combinatorial result of Cdk1 specificity and specificity of the phosphatase Cdc14 [29, 30]. Our work also emphasizes the connection and distinction between the two dynamic properties that are critical in the control of cell division: timing and rate, which we find are determined by the same sets of parameters but favor opposing trends of parameter values. Thus, for example, a deubiquitination reaction in our system facilitates the delay in degradation onset but also compromises the rate of degradation. These findings raise interesting questions about the strategies cells use to optimize both the timing and rate of cellular events, and how cellular circuits evolve under these constraints.
Our goal in this work was to develop a quantitative framework to help us understand our experimental observations that: (1) different APC/CCdc20 substrates begin to be degraded at different times; (2) some substrates do not start to decline until the APC/CCdc20 has been active for several minutes; (3) once degradation begins, substrates are degraded within several minutes; and (4) earlier substrates degrade at a rate slightly faster than later substrates. A simple multi-step ubiquitination model is sufficient to recapitulate what we observe in vivo. Our modeling shows that delayed degradation onset and fast degradation rates are opposing constraints in the system. Our models also show that, at fixed substrate and APC/CCdc20 concentrations, substrate degradation dynamics can be determined by a combination of substrate-APC/CCdc20 interactions (as in the one-substrate model), and competition among substrates (as in the two-substrate model). Varying parameters, such as k c and k d , influences both substrate-APC/CCdc20 interactions and the competition among substrates, and thus results in changes in the onset and rate of degradation.
Yeast strain construction
All yeast strains were haploid derivatives of the W303 strain. Fluorescent protein tagging, gene replacement, and deletion of genes at their endogenous loci were performed using standard PCR-based homologous recombination [31–34], while preserving the endogenous promoters. Addition of Clb5-GFP to the genome was done using an integration plasmid at the genomic URA3 locus , with its endogenous promoter, and selected for single-copy integration by PCR and fluorescence intensity.
All images were taken with a spinning-disk confocal microscope at the UCSF Nikon Imaging Center with a 60x/1.4 NA oil immersion objective, under the control of Micromanager . The microscope is a Nikon Ti-E inverted microscope equipped with a Yokogawa CSU-22 scanner unit and a Photometrics Evolve EMCCD camera. Illumination was provided by a 50 mW 491 nm laser and a 50 mW 561 nm laser. Imaging sessions were generally 1 h long, with 30-sec time intervals. Z-stacks were taken across 4 μm of distance with 0.5 μm steps for each time point and each channel. Exposure times for mCherry and GFP channels were below 100 ms for each Z slice. All yeast cultures were grown and imaged at 30 °C. Prior to imaging, yeast cells were grown in synthetic complete media with 2 % glucose (SD) for 24 h with serial dilution to maintain OD below 0.4. For imaging, cells were mounted on a 1.5 % agarose pad made with SD media, and allowed to continue proliferating on the slide for 40–60 min in a 30 °C incubator prior to imaging.
To quantify GFP intensity at each time point, we first used ImageJ (http://imagej.nih.gov/ij/)  and its plugin Image5D (http://rsb.info.nih.gov/ij/plugins/image5d.html) to average across each z-stack and flatten it to 2D. GFP intensity was then quantified using MATLAB (The MathWorks Inc.) code previously developed in the Tang lab . Since all of the APC/C substrates we studied were localized to the nucleus, we took the brightest square of 5×5 pixels in the cell as an estimate of the protein. Timing of SPB events was determined based on the temporal 3D positions of the SPB using the mCherry images . SPB separation was defined as the time point when one SPB split into two, and spindle elongation was defined as the time point when two SPBs began to move rapidly away from each other.
The time point of substrate degradation onset in each cell was defined as when GFP intensity started to drop on a smoothed trace of a degradation event (Additional file 1: Figure S2). Determination of the time of degradation onset, or the level of GFP at a certain time point, was carried out with previously developed MATLAB code . Statistical analysis and plotting were carried out in MATLAB and Python [39, 40].
To measure levels of Cdc20, GFP-Cdc20, and Clb5-GFP (Additional file 1: Figure S5), log-phase cells were arrested in alpha-factor for 4 h at room temperature and released by washing. Samples were taken at various time points after release, and cells were lysed by bead-beating in lysis buffer (50 mM HEPES [pH 8.0], 150 mM NaCl, 1 % NP40, 50 mM beta-glycerophosphate, 50 mM NaF, 1 mM DTT, 1 μg/ml leupeptin, 1 μg/ml pepstatin, 1 μg/ml aprotinin, 1 mM PMSF, 10 % glycerol, 0.63 mg/ml benzamidine, and 5 mM EDTA). Lysates were analyzed by western blotting with anti-Cdc20 (yC-20/sc-6731, Santa Cruz Biotechnology, Santa Cruz, CA, USA).
Ubiquitination assays in vitro
For analysis of APC/C activity with fusion substrates (Fig. 1) , Clb5-Apc10 fusion substrates were translated in vitro with TnT Quick Coupled Transcription/Translation Systems (Promega, Madison, WI, USA) in the presence of 35S-methionine. APC/C was purified from lysates of CDC16-TAP cdh1∆ doc1∆ W303 strains by affinity chromatography with IgG beads . E1 (Uba1-6His) was expressed in yeast and purified using ubiquitin agarose . E2 (Ubc4-6His) was expressed in E. coli and purified by metal-affinity chromatography . Cdc20 was tagged with an N-terminal ZZ tag and TEV cleavage site and produced with TnT Quick Coupled Transcription/Translation Systems (Promega, Madison, WI, USA), followed by purification on IgG beads and TEV cleavage of the ZZ tag . E2 charging was performed in the presence of E1 (Uba1, 300 nM), E2 (Ubc4, 36 μM or varying concentrations), methyl-ubiquitin (Boston Biochem, Cambridge, MA, USA; 150 μM), and ATP (1 mM) in buffer containing 20 mM Hepes pH 7.4, 150 mM NaCl, 0.1 % Nonidet P-40, 1 mM MgCl2 at 23 °C for 20 min. Purified APC/C on IgG beads was incubated with fusion substrates at 23 °C for 30 min, and unbound substrate was washed away. Purified Cdc20 was then added, and reactions were initiated by mixing the Cdc20-APC/C-fusion substrate mixture with E2 charging mixture. After 20 min at 23 °C, reaction products were separated by SDS-PAGE and visualized with a Molecular Dynamics PhosphorImager. The data were analyzed using the software Prism (GraphPad).
Changes in the concentration of molecular species were determined by ordinary differential equations (Additional file 1: Figure S4). For each set of parameters, the simulation ran for 3,000 time steps corresponding to 3,000 seconds, with concentrations of every molecular species calculated at each time point. Using the dynamics of each substrate, we determined the quantity of interest, such as Td or T95. To cover a large parameter space, we carried out the simulation for 25 values of k c and k d ranging from 10−3/sec to 103/sec equally spaced on a log scale, and six values of k a ranging from 10−4/(nM sec) to 10/(nM sec). All dynamic simulations, data analysis, and plotting were carried out in Python with custom written code [39, 40, 43].
We thank Mike Chevalier and Raj Bhatnagar for their critical input in computational modeling; Kurt Thorn and DeLaine Larsen at the UCSF Nikon Imaging Center for their help with microscopy; and Mike Chevalier, Matilde Galli, Xili Liu, Laura Rosen, Chia Wu, and Xiaojing Yang for comments on the manuscript. We also thank everyone in the Morgan Lab for inspiring discussions. This work was supported by funding from the National Institute of General Medical Sciences (R01-GM097115 and R37-GM053270).
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- Pines J. Mitosis: a matter of getting rid of the right protein at the right time. Trends Cell Biol. 2006;16:55–63.View ArticlePubMedGoogle Scholar
- Sullivan M, Morgan DO. Finishing mitosis, one step at a time. Nat Rev Mol Cell Biol. 2007;8:894–903.View ArticlePubMedGoogle Scholar
- Primorac I, Musacchio A. Panta rhei: the APC/C at steady state. J Cell Biol. 2013;201:177–89.PubMed CentralView ArticlePubMedGoogle Scholar
- den Elzen N, Pines J. Cyclin A is destroyed in prometaphase and can delay chromosome alignment and anaphase. J Cell Biol. 2001;153:121–36.View ArticleGoogle Scholar
- Hagting A, Den Elzen N, Vodermaier HC, Waizenegger IC, Peters JM, Pines J. Human securin proteolysis is controlled by the spindle checkpoint and reveals when the APC/C switches from activation by Cdc20 to Cdh1. J Cell Biol. 2002;157:1125–37.PubMed CentralView ArticlePubMedGoogle Scholar
- Lu D, Hsiao JY, Davey NE, Van Voorhis VA, Foster SA, Tang C, et al. Multiple mechanisms determine the order of APC/C substrate degradation in mitosis. J Cell Biol. 2014;207:23–39.PubMed CentralView ArticlePubMedGoogle Scholar
- Barford D. Structure, function and mechanism of the anaphase promoting complex (APC/C). Q Rev Biophys. 2011;44:153–90.View ArticlePubMedGoogle Scholar
- Chang L, Barford D. Insights into the anaphase-promoting complex: a molecular machine that regulates mitosis. Curr Opin Struct Biol. 2014;29:1–9.View ArticlePubMedGoogle Scholar
- Carroll CW, Morgan DO. The Doc1 subunit is a processivity factor for the anaphase-promoting complex. Nat Cell Biol. 2002;4:880–7.View ArticlePubMedGoogle Scholar
- Rape M, Reddy SK, Kirschner MW. The processivity of multiubiquitination by the APC determines the order of substrate degradation. Cell. 2006;124:89–103.View ArticlePubMedGoogle Scholar
- Glickman MH, Ciechanover A. The ubiquitin-proteasome proteolytic pathway: destruction for the sake of construction. Physiol Rev. 2002;82:373–428.View ArticlePubMedGoogle Scholar
- He J, Chao WC, Zhang Z, Yang J, Cronin N, Barford D. Insights into degron recognition by APC/C coactivators from the structure of an Acm1-Cdh1 complex. Mol Cell. 2013;50:649–60.PubMed CentralView ArticlePubMedGoogle Scholar
- Chang L, Zhang Z, Yang J, McLaughlin SH, Barford D. Molecular architecture and mechanism of the anaphase-promoting complex. Nature. 2014;513:388–93.PubMed CentralView ArticlePubMedGoogle Scholar
- Van Voorhis VA, Morgan DO. Activation of the APC/C ubiquitin ligase by enhanced E2 efficiency. Curr Biol. 2014;24:1556–62.PubMed CentralView ArticlePubMedGoogle Scholar
- Rudner AD, Murray AW. Phosphorylation by Cdc28 activates the Cdc20-dependent activity of the anaphase-promoting complex. J Cell Biol. 2000;149:1377–90.PubMed CentralView ArticlePubMedGoogle Scholar
- Kraft C, Herzog F, Gieffers C, Mechtler K, Hagting A, Pines J, et al. Mitotic regulation of the human anaphase-promoting complex by phosphorylation. EMBO J. 2003;22:6598–609.PubMed CentralView ArticlePubMedGoogle Scholar
- Musacchio A, Salmon ED. The spindle-assembly checkpoint in space and time. Nat Rev Mol Cell Biol. 2007;8:379–93.View ArticlePubMedGoogle Scholar
- Lara-Gonzalez P, Westhorpe FG, Taylor SS. The spindle assembly checkpoint. Curr Biol. 2012;22:R966–80.View ArticlePubMedGoogle Scholar
- Geley S, Kramer E, Gieffers C, Gannon J, Peters JM, Hunt T. Anaphase-promoting complex/cyclosome-dependent proteolysis of human cyclin A starts at the beginning of mitosis and is not subject to the spindle assembly checkpoint. J Cell Biol. 2001;153:137–48.PubMed CentralView ArticlePubMedGoogle Scholar
- Di Fiore B, Davey NE, Hagting A, Izawa D, Mansfeld J, Gibson TJ, et al. The ABBA motif binds APC/C activators and is shared by APC/C substrates and regulators. Dev Cell. 2015;32:358–72.View ArticlePubMedGoogle Scholar
- Di Fiore B, Pines J. How cyclin A destruction escapes the spindle assembly checkpoint. J Cell Biol. 2010;190:501–9.PubMed CentralView ArticlePubMedGoogle Scholar
- Wolthuis R, Clay-Farrace L, van Zon W, Yekezare M, Koop L, Ogink J, et al. Cdc20 and Cks direct the spindle checkpoint-independent destruction of cyclin A. Mol Cell. 2008;30:290–302.View ArticlePubMedGoogle Scholar
- Holt LJ, Krutchinsky AN, Morgan DO. Positive feedback sharpens the anaphase switch. Nature. 2008;454:353–7.PubMed CentralView ArticlePubMedGoogle Scholar
- Ghaemmaghami S, Huh WK, Bower K, Howson RW, Belle A, Dephoure N, et al. Global analysis of protein expression in yeast. Nature. 2003;425:737–41.View ArticlePubMedGoogle Scholar
- Carroll CW, Morgan DO. Enzymology of the anaphase-promoting complex. Meth Enzymol. 2005;398:219–30.View ArticlePubMedGoogle Scholar
- Schaefer JB, Morgan DO. Protein-linked ubiquitin chain structure restricts activity of deubiquitinating enzymes. J Biol Chem. 2011;286:45186–96.PubMed CentralView ArticlePubMedGoogle Scholar
- Schwob E, Nasmyth K. CLB5 and CLB6, a new pair of B cyclins involved in DNA replication in Saccharomyces cerevisiae. Genes Dev. 1993;7:1160–75.View ArticlePubMedGoogle Scholar
- Kõivomägi M, Ord M, Iofik A, Valk E, Venta R, Faustova I, et al. Multisite phosphorylation networks as signal processors for Cdk1. Nat Struct Mol Biol. 2013;20:1415–24.View ArticlePubMedGoogle Scholar
- Bouchoux C, Uhlmann F. A quantitative model for ordered Cdk substrate dephosphorylation during mitotic exit. Cell. 2011;147:803–14.View ArticlePubMedGoogle Scholar
- Uhlmann F, Bouchoux C, Lopez-Aviles S. A quantitative model for cyclin-dependent kinase control of the cell cycle: revisited. Philos Trans R Soc Lond B Biol Sci. 2011;366:3572–83.PubMed CentralView ArticlePubMedGoogle Scholar
- Baudin A, Ozier-Kalogeropoulos O, Denouel A, Lacroute F, Cullin C. A simple and efficient method for direct gene deletion in Saccharomyces cerevisiae. Nucleic Acids Res. 1993;21:3329–30.PubMed CentralView ArticlePubMedGoogle Scholar
- Goldstein AL, McCusker JH. Three new dominant drug resistance cassettes for gene disruption in Saccharomyces cerevisiae. Yeast. 1999;15:1541–53.View ArticlePubMedGoogle Scholar
- Jansen G, Wu C, Schade B, Thomas DY, Whiteway M. Drag&Drop cloning in yeast. Gene. 2005;344:43–51.View ArticlePubMedGoogle Scholar
- Longtine MS, McKenzie A, Demarini DJ, Shah NG, Wach A, Brachat A, et al. Additional modules for versatile and economical PCR-based gene deletion and modification in Saccharomyces cerevisiae. Yeast. 1998;14:953–61.View ArticlePubMedGoogle Scholar
- Sikorski RS, Hieter P. A system of shuttle vectors and yeast host strains designed for efficient manipulation of DNA in Saccharomyces cerevisiae. Genetics. 1989;122:19–27.PubMed CentralPubMedGoogle Scholar
- Edelstein A, Amodaj N, Hoover K, Vale R, Stuurman N. Computer control of microscopes using microManager. Current Protocols in Molecular Biology. 2010;92:14.20.1-14.20-17.Google Scholar
- Schneider CA, Rasband WS, Eliceiri KW. NIH Image to ImageJ: 25 years of image analysis. Nat Methods. 2012;9:671–5.View ArticlePubMedGoogle Scholar
- Yang X, Lau KY, Sevim V, Tang C. Design principles of the yeast g1/s switch. PLoS Biol. 2013;11:e1001673.PubMed CentralView ArticlePubMedGoogle Scholar
- Hunter JD. Matplotlib: A 2D graphics environment. Comput Sci Eng. 2007;9:90–5.View ArticleGoogle Scholar
- Oliphant TE. Python for scientific computing. Comput Sci Eng. 2007;9:10–20.View ArticleGoogle Scholar
- Rodrigo-Brenni MC, Morgan DO. Sequential E2s drive polyubiquitin chain assembly on APC targets. Cell. 2007;130:127–39.View ArticlePubMedGoogle Scholar
- Foster SA, Morgan DO. The APC/C subunit Mnd2/Apc15 promotes Cdc20 autoubiquitination and spindle assembly checkpoint inactivation. Mol Cell. 2012;47:921–32.PubMed CentralView ArticlePubMedGoogle Scholar
- Alted F, Vilata I, Prater S, Mas V, Hedley T, Valentino A, et al. PyTables: Hierarchical Datasets in Python. http://www.pytables.org. 2002.