The spindle assembly checkpoint inhibits anaphase until all chromosomes have become attached to the mitotic spindle. A complex between the checkpoint proteins Mad1 and Mad2 provides a platform for Mad2:Mad2 dimerization at unattached kinetochores, which enables Mad2 to delay anaphase. Here, we show that mutations in Bub1 and within the Mad1 C‐terminal domain impair the kinetochore localization of Mad1:Mad2 and abrogate checkpoint activity. Artificial kinetochore recruitment of Mad1 in these mutants co‐recruits Mad2; however, the checkpoint remains non‐functional. We identify specific mutations within the C‐terminal head of Mad1 that impair checkpoint activity without affecting the kinetochore localization of Bub1, Mad1 or Mad2. Hence, Mad1 potentially in conjunction with Bub1 has a crucial role in checkpoint signalling in addition to presenting Mad2.
See also: T Kruse et al (January 2014)
This study, published alongside one from the Nilsson laboratory, shows that Mad1 mutants that still recruit Mad2 to kinetochores cannot activate the spindle assembly checkpoint in yeast. Thus, Mad1 has an additional, hitherto unidentified role in this process.
The Mad1 C‐terminus and Bub1 conserved motif 1 are required for kinetochore localization of the Schizosaccharomyces pombe Mad1:Mad2 complex.
The Mad1 C‐terminal “head” is required for checkpoint activity despite being dispensable for Mad1 and Mad2 kinetochore recruitment.
Mad1 is not only the scaffold for presenting Mad2 at kinetochores, but its C‐terminus additionally promotes checkpoint signalling.
Mad1 is part of the spindle assembly checkpoint, a conserved mitotic signalling pathway that protects genome integrity by monitoring chromosome attachment to the mitotic spindle and delaying anaphase until all chromosomes have achieved proper attachment . Mad1 forms a tetrameric complex with the checkpoint protein Mad2 . At unattached kinetochores, Mad1‐bound Mad2 dimerizes with soluble Mad2 to induce binding of the latter to Cdc20 , , an essential co‐activator of the anaphase‐promoting complex/cyclosome (APC/C) . This enables binding of Mad3 (BubR1 in many organisms) to Cdc20 to form the mitotic checkpoint complex (MCC), which is a potent inhibitor of the APC/C , , . In S. pombe, the kinases Ark1 and Mph1, as well as Bub1 and Bub3, are required to bring Mad1:Mad2 to unattached kinetochores . Similar dependencies exist in other organisms . Consistent with the important role of the Mad1:Mad2 complex in initiating Cdc20 inhibition, preventing the Mad1:Mad2 interaction abolishes checkpoint activity , , , . Hence, Mad1 is important to present Mad2 at unattached kinetochores.
Mad1 has approximately 80 kDa; yet, the stretch that binds Mad2 is <20 amino acids long. This raises the question whether the remaining parts only have a structural role. The Mad1 part N‐terminal to the Mad2‐binding site is predicted to form a long coiled‐coil. The structure of the C‐terminal end of this coiled‐coil (α1) together with the Mad2‐binding site bound to Mad2 as well as a C‐terminal helix (α2) indicated that α1 mediates Mad1 dimerization . Another structure of the C‐terminal part following α2 showed another intermolecular coiled‐coil (α3) and a globular head  (see Figs 1A and 4A). The Mad1 C‐terminus has repeatedly been implicated in kinetochore binding , , ; some studies have suggested a role for the N‐terminus , . Budding yeast Mad1 interacts with Bub1, which requires a conserved motif (RLK, Arg‐Leu‐Lys) in the Mad1 α3 helix  and a conserved stretch in Bub1 . This interaction is important for checkpoint activity , and in human cells, the RLK motif is required for kinetochore localization of Mad1 . Overall, these observations indicate that the structured parts of Mad1 are required to bring the Mad1:Mad2 complex to kinetochores to allow checkpoint signalling, potentially through an interaction between Mad1 and Bub1.
Here, we show using fission yeast that the Mad1 C‐terminus promotes checkpoint activity in a way that is independent of its role in bringing the Mad1:Mad2 complex to kinetochores.
Results and Discussion
Mad1‐RLK motif and Bub1‐conserved motif 1 are required for kinetochore localization of Mad1 and checkpoint activity
To assess potential roles of Mad1 apart from Mad2‐binding, we focused on the RLK motif (amino acid (aa) 580–582) within α3 . When we mutated all motif residues to alanine in S. pombe, kinetochore localization of Mad1 and Mad2 was impaired (Fig 1A, C–E), whereas localization to the nuclear envelope stayed intact (Supplementary Fig S1A and D). Checkpoint activity was lost in the Mad1‐RLK/AAA mutant (Fig 1F), although kinetochore localization of Ark1, Bub1, Bub3 and Mad3 was preserved (Fig 1E, Supplementary Fig S1B) and although Mad1‐RLK/AAA was present at normal levels (Fig 1G) and the Mad1:Mad2 interaction was intact (Fig 1H). This suggests that the failure to bring Mad1:Mad2 to kinetochores causes the checkpoint defect. A similar loss of Mad1 localization and checkpoint activity occurred when only the outward‐facing amino acids R and K of the RLK motif were mutated or when the C‐terminus was truncated (Fig 1). The latter supports results from budding yeast . Like RLK/AAA, the RLK/ALA mutation preserved Mad2 interaction, whereas truncation of the C‐terminus led to a gradual loss of this interaction (Fig 1H). Although the Mad1 C‐terminus was necessary for kinetochore binding (Fig 1C and D), it did not seem sufficient (Supplementary Fig S2). In contrast to the C‐terminus, the Mad1 N‐terminus was required for nuclear envelope localization, but was at least partly dispensable for kinetochore localization (Supplementary Fig S2).
The RLK motif has been implicated in binding to Bub1 in budding yeast , , which involves a region of Bub1 that contains the “conserved motif 1” (cm1; ). Indeed, mutation of Bub1‐cm1 phenocopied Mad1‐RLK mutants (Fig 1I–L). Bub1 itself (Fig 1K) as well as Bub3 and Mad3 (Supplementary Fig S1I) still localized to kinetochores, but Mad1 and Mad2 were strongly reduced (Fig 1J and K, Supplementary Fig S1I) and cells lacked checkpoint activity (Fig 1L). We conclude that the C‐terminus of Mad1 (with the RLK motif) and Bub1‐cm1 are involved in recruiting Mad1 to kinetochores and both regions are important for checkpoint function.
The Mad1 RLK motif and Bub1‐cm1 promote checkpoint activity independently of their role in Mad1 kinetochore localization
Since Bub1 and Mad1 have been observed to interact in budding yeast , it is conceivable that Bub1 and Mad1 interact through cm1 and RLK motif and that this interaction is required for Mad1 kinetochore localization and checkpoint activity. Surprisingly, we were unable to detect an interaction between these two proteins when immunoprecipitating either of them from cells with an active checkpoint (Supplementary Fig S3A and B), similar to the situation in human cells . To test whether the loss of checkpoint activity in the Mad1‐RLK/AAA or Bub1‐cm1 mutant (Fig 1F and L) is at all related to the loss of Mad1 from kinetochores, we tested checkpoint activity after artificially recruiting Mad1 to kinetochores through fusion to the kinetochore protein Mis12 (Fig 2). Although the levels of tethered Mad1 at unattached kinetochores were slightly lower than for wild‐type Mad1 (Fig 2E and F), the checkpoint was functional at least in a large fraction of the cells (Fig 2B and D). Tethering of Mad1‐RLK/AAA, however, did not provide checkpoint activity (Fig 2B), even though Mad2 was co‐recruited to the kinetochore at similar levels as in tethered wild‐type Mad1 (Fig 2F). Similarly, artificially recruiting Mad1 in either bub1Δ or bub1‐cm1 cells did not restore the checkpoint (Fig 2D and E). This suggests that Bub1‐cm1 and the Mad1 C‐terminus have an additional role within the spindle assembly checkpoint, apart from recruiting Mad1 and Mad2 to kinetochores.
Mutations in the C‐terminus of Mad1 abolish checkpoint signalling although kinetochore localization of Bub1, Mad1 and Mad2 is intact
If Bub1 and Mad1 have an additional role in the checkpoint, unrelated to Mad1 kinetochore localization, it should be possible to identify separation‐of‐function mutants that preserve kinetochore localization but are deficient in checkpoint signalling. We screened for such mutations in the structured and conserved C‐terminus of Mad1. An initial screen narrowed down the region of interest to the very C‐terminus (Supplementary Fig S4A). We noticed a conserved, negatively charged surface patch on “top” of the Mad1 “head,” which we either mutated (EDD/QNN) or which we removed by truncating the protein before the last α helix (Δhelix) (Fig 3A). Both mutants maintained Mad1 kinetochore localization (Fig 3B and C), but strongly or entirely lost checkpoint activity (Fig 3D), despite being present at similar levels as wild‐type Mad1 (Fig 3E). Both immunoprecipitation (Fig 3F) and co‐recruitment to the kinetochore (Fig 3G, Supplementary Fig S4C) demonstrated that the interaction of Mad1 with Mad2 was largely preserved. In addition, Bub1 still localized to kinetochores (Supplementary Fig S4G). Hence, in these Mad1 mutants Bub1, Mad1 and Mad2 are at kinetochores; yet, checkpoint signalling is strongly impaired.
The C‐terminal part of Mad1 (α3 and head) has been proposed to fold back onto Mad1‐α2 , which would bring the Mad1 head in close vicinity to Mad2. Because Mad1‐bound Mad2 needs to dimerize with additional Mad2 to support checkpoint function , , we suspected that the Mad1 C‐terminal head promotes this dimerization. As in human cells , the Mad2/Mad1 ratio at kinetochores is reduced in a dimerization‐deficient Mad2 mutant (Mad2‐R133A ; Fig 3G), presumably because Mad2 cannot be recruited to the kinetochore through Mad2:Mad2 dimerization, but only through binding to Mad1. In both the Mad1‐EDD/QNN and ‐Δhelix mutant, the Mad2/Mad1 ratio at kinetochores was similar to Mad1 wild‐type cells, and in both mutants, there was less Mad2 relative to Mad1 at kinetochores when the Mad2‐R133A mutant was expressed instead of wild‐type Mad2 (Fig 3G). This strongly indicates that Mad2 dimerization is intact. Similarly, the Mad2/Mad1 ratio after artificially tethering Mad1‐RLK/AAA was more similar to wild‐type than to Mad2‐R133A‐expressing cells (Fig 3H). Hence, the Mad1 C‐terminal head and the RLK motif promote checkpoint function, but seemingly not through facilitating Mad2 dimerization.
Our data indicate that the C‐terminal head of Mad1 has a previously unrecognized role in checkpoint signalling, which is neither related to the requirement for the C‐terminus to bring Mad1 to kinetochores (Fig 1) nor related to the role of Mad1 in recruiting Mad2, either directly or through Mad2:Mad2 dimerization (Figs 2 and 3). Since very similar findings have been made in human cells , this function of Mad1 is probably conserved across eukaryotes. Current models for the spindle assembly checkpoint mainly see Mad1 as a passive platform for presenting Mad2 at kinetochores. Our findings revise this picture and make Mad1 an active player in checkpoint signalling. How the Mad1 C‐terminus promotes checkpoint activity and how Bub1 fits into the picture remains unclear (Fig 4). Our finding that the very C‐terminal Mad1 head is required for checkpoint activity without being required for any of the known Mad1 functions provides a basis to elucidate the molecular mechanism. How the head is arranged with respect to the remainder of the molecule is still unclear (Fig 4). In any case, we suspect that the head, like similar folds in other kinetochore proteins , , , , mediates a protein–protein interaction (Fig 4B). The interacting partner could be Mad2 or another (checkpoint) protein. Although we find Mad2 dimerization apparently intact in the Mad1‐EDD/QNN, Mad1‐Δhelix or Mad1‐RLK/AAA mutant (Fig 3), it remains possible that these regions are involved in promoting the conformational change of Mad2 that is required for binding of free Mad2 to Cdc20 ,  (Fig 4B). It would be interesting to perform cross‐linking experiments to determine which arrangement the Mad1 C‐terminus takes in vivo and which proteins the different regions interact with (Fig 4B).
Materials and Methods
Schizosaccharomyces pombe strains
Strains are listed in Supplementary Table 1. For the amino acid (aa) numbering of Mad1, note that we corrected the annotation of the start codon, which shifted by 13 aa (Supplementary Information). In general, mutants were integrated into the endogenous locus using PCR‐based gene targeting  and replaced the wild‐type allele. P(nmt81)‐(mis12‐)mad1‐(AAA)‐GFP constructs were integrated into the leu1 locus using the pDUAL system , and the endogenous mad1+ gene was deleted. Schizosaccharomyces pombe strains with the following mutations or modifications have been described: nda3‐KM311 , mad1+‐GFP≪kanR, mad2+‐GFP≪kanR, mad3+‐GFP≪kanR, plo1+‐mCherry, ark1+‐GFP , bub1+‐GFP≪kanR , bub3+‐GFP≪kanR , mad1Δ::ura4+ , bub1∆::ura4+ .
For live‐cell imaging, cells were grown at 30°C in either rich medium (YEA) or Edinburgh minimal medium (EMM) containing the necessary supplements. Mad1 constructs expressed from P(nmt81) at the leu1 locus were cultured for 19 h in EMM without thiamine to induce expression, then washed three times with EMM containing 16 μM thiamine and resuspended in EMM containing 16 μM thiamine before shifting to 16°C for imaging.
Live‐cell imaging to assess checkpoint functionality
Live‐cell imaging was performed on a DeltaVision microscope (Applied Precision/GE Healthcare) as previously described .
Quantification of GFP and mCherry signals in the nucleus and at the kinetochore
To determine the intensity of checkpoint protein‐GFP or ‐mCherry signals at the kinetochores, mitotic cells were identified by the appearance of localized Plo1‐mCherry signal at SPBs, or by localized Mad1‐GFP or Mad2‐mCherry signal at kinetochores. In cells expressing constitutive kinetochore‐tethered Mad1 (Mis12‐Mad1) and lacking a fluorescent tag on Plo1 (so that entry into mitosis could not be judged), signals were measured for 50 min before the kinetochores unclustered. The unclustering (Supplementary Fig S2D) indicates that the cell is in mitosis. An area was placed around kinetochores (for checkpoint protein‐GFP or ‐mCherry strains) or SPBs (for Plo1‐mCherry strains; because kinetochores cluster at the SPB in early mitosis, this captures the signal at kinetochores). The GFP or mCherry signal in this area was traced over time. To determine signal intensity at the kinetochore, the total signal intensity per area of a similarly sized region in the nucleoplasm was subtracted from the total signal intensity per area around the kinetochore.
Fluorescence microscopy of asynchronous cell cultures
Images of living cells were acquired with a CoolSnap EZ (Roper) camera using a 63 × /1.4 Plan Apochromat oil objective on a Zeiss AxioImager microscope and were processed with MetaMorph software (Molecular Devices Corporation). Typically, a Z‐stack of about 3 μm thickness, with single planes spaced by 0.3 μm, was acquired and subsequently projected. Shown are sum intensity projections of the Z‐stack for checkpoint proteins and maximum intensity projections of the Z‐stack for Plo1.
Immunoprecipitation was performed as previously described  using rabbit anti‐Mad1  or mouse anti‐GFP (Roche, 11814460001) antibodies and protein A‐coated magnetic beads (Dynabeads, Invitrogen 10002D).
Cell extracts, SDS–PAGE and immunoblotting
Protein extraction was performed as previously described . Mouse anti‐GFP (Roche, 11814460001), rabbit anti‐Mad1 , rabbit anti‐Mad2 , mouse anti‐HA (Roche, 12CA5) or rabbit anti‐Cdc2 (Santa Cruz, SC‐53) were used as primary antibodies. Secondary antibodies were anti‐mouse or anti‐rabbit HRP conjugates (Dianova, 115‐035‐003, 111‐035‐003) and were read out using chemiluminescence.
SHe (Figs 1,2,3, Supplementary Figs S1,2,3,4), KS (Figs 1,2,3, Supplementary Figs S1,2,3,4), HW (Fig 1), ML (Figs 1 and 2, Supplementary Fig S4), NS (Fig 1, Supplementary Figs S1 and 3) and NH (Supplementary Fig S3) designed and performed experiments; SHa devised the project and wrote the manuscript together with SHe and input from all other authors.
Conflict of interest
The authors declare that they have no conflict of interest.
Supplementary Figure 1
Supplementary Figure 2
Supplementary Figure 3
Supplementary Figure 4
Supplementary Table 1
We thank Jan Hasenauer for statistical analysis, Julia Kamenz for valuable suggestions, Katrin Bertram, Holda Anagho, Eva Illgen, Julia Binder, Julia Sauerwald, Alexandra Dudek and Philipp Spät for excellent technical help, Andrei Lupas for advice on coiled‐coil truncations, the Proteome Center of the University of Tübingen for mass spectrometric analysis and Jakob Nilsson and his group for communicating unpublished results. We are grateful for funding by the Max Planck Society; St.H. was additionally supported by the Ernst Schering Foundation.
FundingMax Planck Society
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- © 2014 The Authors.