Cdc2 activation in fission yeast depends on Mcs6 and Csk1, two partially redundant Cdk-activating kinases (CAKs)

Cyclin-dependent kinases (Cdks) are fully active only when phosphorylated by a Cdk-activating kinase (CAK) [1]. Metazoan CAK is itself a Cdk, Cdk7, whereas the CAK of Saccharomyces cerevisiae is a distinct enzyme unrelated to Cdks [1]. The Mcs6-Mcs2 complex of Schizosaccharomyces pombe is a putative CAK related to the metazoan enzyme [2] [3]. Although the loss of Mcs6 is lethal, it results in a phenotype that is inconsistent with a failure to activate Cdc2, the major Cdk in S. pombe [3]. We therefore tested the ability of Csk1, a putative regulator of Mcs6 [4], to activate Cdk-cyclin complexes in vitro. Csk1 activated both the monomeric and the Mcs2-bound forms of Mcs6. Surprisingly, Csk1 also activated Cdc2 in complexes with either Cdc13 or Cig2 cyclins. When a double mutant carrying a csk1 deletion and a temperature-sensitive mcs6 allele was incubated at the restrictive temperature, Cdc2 was not activated and the cells underwent a cell division arrest prior to mitosis. Cdc2-cyclin complexes isolated from the arrested cells could be activated in vitro by recombinant CAK, whereas complexes from wild-type cells or either of the single mutants were refractory to activation. Thus, fission yeast contains two partially redundant CAKs: the Mcs6-Mcs2 complex and Csk1. Inactivation of both CAKs is necessary and sufficient to prevent Cdc2 activation and cause a cell-cycle arrest. Mcs6, which is essential, may therefore have required functions other than Cdk activation.     

Fission yeast Csk1 is a CAK-activating kinase (CAKAK).

Cell cycle progression is dependent on the sequential activity of cyclin-dependent kinases (CDKs). For full activity, CDKs require an activating phosphorylation of a conserved residue (corresponding to Thr160 in human CDK2) carried out by the CDK-activating kinase (CAK). Two distinct CAK kinases have been described: in budding yeast Saccharomyces cerevisiae, the Cak1/Civ1 kinase is responsible for CAK activity. In several other species including human, Xenopus, Drosophila and fission yeast Schizosaccharomyces pombe, CAK has been identified as a complex homologous to CDK7-cyclin H (Mcs6-Mcs2 in fission yeast). Here we identify the fission yeast Csk1 kinase as an in vivo activating kinase of the Mcs6-Mcs2 CAK defining Csk1 as a CAK-activating kinase (CAKAK).     

Activation of ubiquitin ligase SCF(Skp2) by Cks1: insights from hydrogen exchange mass spectrometry

Skp2 is the substrate recognition subunit of the multi-subunit ubiquitin ligase SCF(Skp2). It consists of an N-terminal F-box domain that binds to the Skp1 subunit and thereby tethers it to the SCF catalytic core, and an elongated C-terminal domain comprising ten Leucine-rich repeats (LRR) that binds the substrate. A small accessory protein, Cks1, is required for SCF(Skp2) to target certain substrates, including the Cyclin-dependent kinase inhibitor p27. Here we have used hydrogen/deuterium exchange monitored by mass spectrometry to investigate the mode of action of Cks1 on SCF(Skp2). We show that complex formation between Cks1 and Skp2 causes conformational changes in both proteins in regions distant from the respective binding sites. We find that Skp2 interacts with a localised region of Cks1 but the interaction causes a global change in the hydrogen exchange behaviour of Cks1. Also, whilst Cks1 binds to the most C-terminal LRRs of the elongated Skp2 molecule, the interaction induces conformational changes at the distant N-terminal LRRs, close to the F-box motif. Further, binding of Cks1 to Skp2 significantly stabilises the interaction between Skp2 and Skp1. The results reveal that the C-terminal substrate recognition region of Skp2 is coupled to the N-terminal Skp1-binding region and thereby to the SCF catalytic core; this result adds to the model proposed previously that, whilst the principal function of the F-box protein is to recruit the substrate, an additional function may be to help position the substrate in an optimal way within the SCF complex to enable efficient ubiquitin transfer.     

Skp1p and the F-box protein Rcy1p form a non-SCF complex involved in recycling of the SNARE Snc1p in yeast

Skp1p-cullin-F-box protein (SCF) complexes are ubiquitin-ligases composed of a core complex including Skp1p, Cdc53p, Hrt1p, the E2 enzyme Cdc34p, and one of multiple F-box proteins which are thought to provide substrate specificity to the complex. Here we show that the F-box protein Rcy1p is required for recycling of the v-SNARE Snc1p in Saccharomyces cerevisiae. Rcy1p localized to areas of polarized growth, and this polarized localization required its CAAX box and an intact actin cytoskeleton. Rcy1p interacted with Skp1p in vivo in an F-box-dependent manner, and both deletion of its F box and loss of Skp1p function impaired recycling. In contrast, cells deficient in Cdc53p, Hrt1p, or Cdc34p did not exhibit recycling defects. Unlike the case for F-box proteins that are known to participate in SCF complexes, degradation of Rcy1p required neither its F box nor functional 26S proteasomes or other SCF core subunits. Importantly, Skp1p was the only major partner that copurified with Rcy1p. Our results thus suggest that a complex composed of Rcy1p and Skp1p but not other SCF components may play a direct role in recycling of internalized proteins.     

HeLa细胞中Skp2的表达调控p21WAFCIP1稳定性

泛素 蛋白酶体抑制剂MG 132处理的HeLa和SaoS 2细胞中 ,低表达的p2 1WAF CIP1受泛素 蛋白酶体通路调控 .为探讨肿瘤细胞中高表达的E3连接酶底物结合亚基 Skp2和低表达的p2 1WAF CIP1之间的关系 ,在HeLa细胞中转染Skp2的反义寡核苷酸后 ,p2 1表达水平明显升高 .同时 ,相对于转染空载体和Skp2ΔF(Skp2的F box缺失突变体 )的真核表达载体 ,转染全长Skp2的HeLa细胞中 ,p2 1表达水平显著下降 ,说明肿瘤细胞中Skp2调节p2 1的稳定性 ,并且这种调控作用依赖于Skp2蛋白中的F box结构 .免疫荧光结果表明 ,Skp2和p2 1共定位于细胞核 ,这为两者间的相互作用提供了前提 ;体内相互免疫共沉淀结果表明 ,p2 1和其它SCFSkp2 的底物一样与Skp2直接结合 ,并且它们之间的结合区不在F box结构域 ,这一结果在体外的GST pulldown实验中得到验证     

p27(Kip1) ubiquitination and degradation is regulated by the SCF(Skp2) complex through phosphorylated Thr187 in p27.

Many tumorigenic processes affect cell-cycle progression by their effects on the levels of the cyclin-dependent kinase inhibitor p27(Kip1) [1,2]. The phosphorylation- and ubiquitination-dependent proteolysis of p27 is implicated in control of the G1-S transition in the cell cycle [3-6]. To determine the factors that control p27 stability, we established a cell-free extract assay that recapitulates the degradation of p27. Phosphorylation of p27 at Thr187 was essential for its degradation. Degradation was also dependent on SCF(Skp2), a protein complex implicated in targeting phosphorylated proteins for ubiquitination [7-10]. Immunodepletion of components of the complex - Cul-1, Skp1, or Skp2 - from the extract abolished p27 degradation, while addition of purified SCF(Skp2) to Skp2- depleted extract restored the capacity to degrade p27. A specific association was observed between Skp2 and a p27 carboxy-terminal peptide containing phosphorylated Thr187, but not between Skp2 and the non-phosphorylated peptide. Skp2-dependent associations between Skp1 or Cul-1 and the p27 phosphopeptide were also detected. Isolated SCF(Skp2) contained an E3 ubiquitin ligase activity towards p27. Our data thus suggest that SCF(Skp2) specifically targets p27 for degradation during cell-cycle progression.     

Identification of Elongin C and Skp1 sequences that determine Cullin selection

The multiprotein von Hippel-Lindau (VHL) tumor suppressor and Skp1-Cul1-F-box protein (SCF) complexes belong to families of structurally related E3 ubiquitin ligases. In the VHL ubiquitin ligase, the VHL protein serves as the substrate recognition subunit, which is linked by the adaptor protein Elongin C to a heterodimeric Cul2/Rbx1 module that activates ubiquitylation of target proteins by the E2 ubiquitin-conjugating enzyme Ubc5. In SCF ubiquitin ligases, F-box proteins serve as substrate recognition subunits, which are linked by the Elongin C-like adaptor protein Skp1 to a Cul1/Rbx1 module that activates ubiquitylation of target proteins, in most cases by the E2 Cdc34. In this report, we investigate the functions of the Elongin C and Skp1 proteins in reconstitution of VHL and SCF ubiquitin ligases. We identify Elongin C and Skp1 structural elements responsible for selective interaction with their cognate Cullin/Rbx1 modules. In addition, using altered specificity Elongin C and F-box protein mutants, we investigate models for the mechanism underlying E2 selection by VHL and SCF ubiquitin ligases. Our findings provide evidence that E2 selection by VHL and SCF ubiquitin ligases is determined not solely by the Cullin/Rbx1 module, the target protein, or the integrity of the substrate recognition subunit but by yet to be elucidated features of these macromolecular complexes.     

A negatively charged amino acid in Skp2 is required for Skp2-Cks1 interaction and ubiquitination of p27Kip1

Proteolysis of cyclin-dependent kinase inhibitor p27 occurs predominantly in the late G1 phase of the cell cycle through a ubiquitin-mediated protein degradation pathway. Ubiquitination of p27 requires the SCFSkp2 ubiquitin ligase and Skp2 F-box binding protein Cks1. The mechanisms by which Skp2 recognizes Cks1 to ubiquitylate p27 remain obscure. Here we show that Asp-331 in the carboxyl terminus of Skp2 is required for its association with Cks1 and ubiquitination of p27. Mutation of Asp-331 to Ala disrupts the interaction between Skp2 and Cks1. Although Asp-331 mutation negates the ability of the Skp1-Cullin-F-box protein (SCF) complex to ubiquitylate p27, such a mutation has no effect on Skp2 self-ubiquitination. A conservative change from Asp to Glu at position 331 of Skp2 does not affect Skp2-Cks1 interaction. Our results revealed a unique requirement for a negatively charged residue in the carboxyl-terminal region of Skp2 in recognition of Cks1 and ubiquitination of p27.     

Molecular dynamics simulations elucidate the mode of protein recognition by Skp1 and the F‐box domain in the SCF complex

Polyubiquitination of the target protein by a ubiquitin transferring machinery is key to various cellular processes. E3 ligase Skp1‐Cul1‐F‐box (SCF) is one such complex which plays crucial role in substrate recognition and transfer of the ubiquitin molecule. Previous computational studies have focused on S‐phase kinase‐associated protein 2 (Skp2), cullin, and RING‐finger proteins of this complex, but the roles of the adapter protein Skp1 and F‐box domain of Skp2 have not been determined. Using sub‐microsecond molecular dynamics simulations of full‐length Skp1, unbound Skp2, Skp2‐Cks1 (Cks1: Cyclin‐dependent kinases regulatory subunit 1), Skp1‐Skp2, and Skp1‐Skp2‐Cks1 complexes, we have elucidated the function of Skp1 and the F‐box domain of Skp2. We found that the L₁₆ loop of Skp1_, which was deleted in previous X‐ray crystallography studies, can offer additional stability to the ternary complex via its interactions with the C‐terminal tail of Skp2. Moreover, Skp1 helices H6, H7, and H8 display vivid conformational flexibility when not bound to Skp2, suggesting that these helices can recognize and lock the F‐box proteins. Furthermore, we observed that the F‐box domain could rotate (5°–129°), and that the binding partner determined the degree of conformational flexibility. Finally, Skp1 and Skp2 were found to execute a domain motion in Skp1‐Skp2 and Skp1‐Skp2‐Cks1 complexes that could decrease the distance between ubiquitination site of the substrate and the ubiquitin molecule by 3 nm. Thus, we propose that both the F‐box domain of Skp2 and Skp1‐Skp2 domain motions displaying preferential conformational control can together facilitate polyubiquitination of a wide variety of substrates. Proteins 2016; 84:159–171. © 2015 Wiley Periodicals, Inc.     

Cyclin-dependent kinases phosphorylate human Cdt1 and induce its degradation

Eukaryotic cells tightly control DNA replication so that replication origins fire only once during S phase within the same cell cycle. Cell cycle-regulated degradation of the replication licensing factor Cdt1 plays important roles in preventing more than one round of DNA replication per cell cycle. We have previously shown that the SCF(Skp2)-mediated ubiquitination pathway plays an important role in Cdt1 degradation. In this study, we demonstrate that human Cdt1 is a substrate of Cdk2 and Cdk4 both in vivo and in vitro. Overexpression of cyclin-dependent kinase inhibitors such as p21 and p27 dramatically suppresses the phosphorylation of Cdt1, disrupts the interaction of Cdt1 with the F-box protein Skp2, and blocks the degradation of Cdt1. Further analysis reveals that Cdt1 interacts with cyclin/cyclin-dependent kinase (Cdk) complexes through a cyclin/Cdk binding consensus site, located at the N terminus of Cdt1. A Cdt1 mutant carrying four amino acid substitutions at the Cdk binding site dramatically reduces associations with cyclin/Cdk complexes. This mutant is not phosphorylated, fails to bind Skp2 and is more stable than wild-type Cdt1. These data suggest that cyclin/Cdk-mediated Cdt1 phosphorylation is required for the association of Cdt1 with the SCF(Skp2) ubiquitin ligase and thus is important for the cell cycle dependent degradation of Cdt1 in mammalian cells.     

A new function of Skp1 in the mitotic exit of budding yeast Saccharomyces cerevisiae

We previously reported that Skp1, a component of the Skp1-Cullin-F-box protein (SCF) complex essential for the timely degradation of cell cycle proteins by ubiquitination, physically interacts with Bfa1, which is a key negative regulator of the mitotic exit network (MEN) in response to diverse checkpoint-activating stresses in budding yeast. In this study, we initially investigated whether the interaction of Skp1 and Bfa1 is involved in the regulation of the Bfa1 protein level during the cell cycle, especially by mediating its degradation. However, the profile of the Bfa1 protein did not change during the cell cycle in skp1-11, which is a SKP1 mutant allele in which the function of Skp1 as a part of SCF is completely impaired, thus indicating that Skp1 does not affect the degradation of Bfa1. On the other hand, we found that the skp1-12 mutant allele, previously reported to block G2-M transition, showed defects in mitotic exit and cytokinesis. The skp1-12 mutant allele also revealed a specific genetic interaction with Deltabfa1. Bfa1 interacted with Skp1 via its 184 C-terminal residues (Bfa1-D8) that are responsible for its function in mitotic exit. In addition, the interaction between Bfa1 and the Skp1-12 mutant protein was stronger than that of Bfa1 and the wild type Skp1. We suggest a novel function of Skp1 in mitotic exit and cytokinesis, independent of its function as a part of the SCF complex. The interaction of Skp1 and Bfa1 may contribute to the function of Skp1 in the mitotic exit.     

Schizosaccharomyces pombe Mop1-Mcs2 is related to mammalian CAK.

The cyclin-dependent kinase (CDK)-activating kinase, CAK, from mammals and amphibians consists of MO15/CDK7 and cyclin H, a complex which has been identified also as a RNA polymerase II C-terminal domain (CTD) kinase. While the Schizosaccharomyces pombe cdc2 gene product also requires an activating phosphorylation, the enzyme responsible has not been identified. We have isolated an essential S.pombe gene, mop1, whose product is closely related to MO15 and to Saccharomyces cerevisiae Kin28. The functional similarity of Mop1 and MO15 is reflected in the ability of MO15 to rescue a mop1 null allele. This suggests that Mop1 would be a CDK, and indeed Mop1 associates with a previously characterized cyclin H-related cyclin Mcs2 of S.pombe. Also, Mop1 and Mcs2 can associate with the heterologous partners human cyclin H and MO15, respectively. Moreover, the rescue of a temperature-sensitive mcs2 strain by expression of mop1+ demonstrates a genetic interaction between mop1 and mcs2. In a functional assay, immunoprecipitated Mop1-Mcs2 acts both as an RNA polymerase II CTD kinase and as a CAK. The CAK activity of Mop1-Mcs2 distinguishes it from the related CDK-cyclin pair Kin28-Ccl1 from S.cerevisiae, and supports the notion that Mop1-Mcs2 may represent a homolog of MO15-cyclin H in S.pombe with apparent dual roles as a RNA polymerase CTD kinase and as a CAK.     

Skp1 stabilizes the conformation of F-box proteins

The SCF ubiquitin ligase complex consists of four components, Skp1, Cul1, ROC1/Rbx1, and a variable subunit F-box protein, which serves as a receptor for target proteins. The F-box proteins consist of an N-terminal ∼40 amino acid F-box domain that binds to Skp1 and the C-terminal substrate-binding domain. We have reported previously that Fbs1 and Fbs2 are N-linked glycoprotein-specific F-box proteins. In addition, other three F-box proteins, Fbg3, Fbg4, and Fbg5, show high homology to Fbs1 and Fbs2, but their functions remain largely unknown. Here we report that Skp1 assists in correct folding of exogenously expressed F-box proteins. Fbs2 as well as Fbg3, Fbg4, and Fbg5 proteins formed SCF complexes but did not bind to N-glycoproteins when exogenously expressed alone. However, co-expression of Fbs2 and Fbg5 with Skp1 facilitated their binding to glycoproteins that reacted with ConA. Furthermore, Skp1 increased the cellular concentrations of F-box proteins by preventing aggregate formation. These observations suggest that Skp1 plays an important role in stabilizing the conformation of these F-box proteins, which increases their expression levels and substrate-binding.     

The cell-cycle regulatory protein Cks1 is required for SCF(Skp2)-mediated ubiquitinylation of p27

The cyclin-dependent kinase (CDK) inhibitor p27 is degraded in late G1 phase by the ubiquitin pathway, allowing CDK activity to drive cells into S phase. Ubiquitinylation of p27 requires its phosphorylation at Thr 187 (refs 3, 4) and subsequent recognition by S-phase kinase associated protein 2 (Skp2; refs 5-8), a member of the F-box family of proteins that associates with Skp1, Cul-1 and ROC1/Rbx1 to form an SCF ubiquitin ligase complex. However, in vitro ligation of p27 to ubiquitin could not be reconstituted by known purified components of the SCFSkp2 complex. Here we show that the missing factor is CDK subunit 1 (Cks1), which belongs to the highly conserved Suc1/Cks family of proteins that bind to some CDKs and phosphorylated proteins and are essential for cell-cycle progression. Human Cks1, but not other members of the family, reconstitutes ubiquitin ligation of p27 in a completely purified system, binds to Skp2 and greatly increases binding of T187-phosphorylated p27 to Skp2. Our results represent the first evidence that an SCF complex requires an accessory protein for activity as well as for binding to its phosphorylated substrate.     

Specificity of Cdk activation in vivo by the two Caks Mcs6 and Csk1 in fission yeast

Activating phosphorylation of cyclin-dependent kinases (Cdks) is mediated by at least two structurally distinct types of Cdk-activating kinases (Caks): the trimeric Cdk7-cyclin H-Mat1 complex in metazoans and the single-subunit Cak1 in budding yeast. Fission yeast has both Cak types: Mcs6 is a Cdk7 ortholog and Csk1 a single-subunit kinase. Both phosphorylate Cdks in vitro and rescue a thermosensitive budding yeast CAK1 strain. However, this apparent redundancy is not observed in fission yeast in vivo. We have identified mutants that exhibit phenotypes attributable to defects in either Mcs6-activating phosphorylation or in Cdc2-activating phosphorylation. Mcs6, human Cdk7 and budding yeast Cak1 were all active as Caks for Cdc2 when expressed in fission yeast. Although Csk1 could activate Mcs6, it was unable to activate Cdc2. Biochemical experiments supported these genetic results: budding yeast Cak1 could bind and phosphorylate Cdc2 from fission yeast lysates, whereas fission yeast Csk1 could not. These results indicate that Mcs6 is the direct activator of Cdc2, and Csk1 only activates Mcs6. This demonstrates in vivo specificity in Cdk activation by Caks.     

Skp2 contains a novel cyclin A binding domain that directly protects cyclin A from inhibition by p27Kip1

Skp2 is well known as the F-box protein of the SCF(Skp2) x Roc1 complex targeting p27 for ubiquitylation. Skp2 also forms complexes with cyclin A, which is particularly abundant in cancer cells due to frequent Skp2 overexpression, but the mechanism and significance of this interaction remain unknown. Here, we report that Skp2-cyclin A interaction is mediated by novel interaction sequences on both Skp2 and cyclin A, distinguishing it from the well known RXL-hydrophobic patch interaction between cyclins and cyclin-binding proteins. Furthermore, a short peptide derived from the mapped cyclin A binding sequences of Skp2 can block Skp2-cyclin A interaction but not p27-cyclin A interaction, whereas a previously identified RXL peptide can block p27-cyclin A interaction but not Skp2-cyclin A interaction. Functionally, Skp2-cyclin A interaction is separable from Skp2 ability to mediate p27 ubiquitylation. Rather, Skp2-cyclin A interaction serves to directly protect cyclin A-Cdk2 from inhibition by p27 through competitive binding. Finally, we show that disruption of cyclin A binding with point mutations in the cyclin A binding domain of Skp2 compromises the ability of overexpressed Skp2 to counter cell cycle arrest by a p53/p21-mediated cell cycle checkpoint without affecting its ability to cause degradation of cellular p27 and p21. These findings reveal a new functional mechanism of Skp2 and a new regulatory mechanism of cyclin A.     

Structure of a conserved dimerization domain within the F-box protein Fbxo7 and the PI31 proteasome inhibitor

F-box proteins are the substrate-recognition components of the Skp1-Cul1-F box protein (SCF) E3 ubiquitin ligases. Here we report a structural relationship between Fbxo7, a component of the SCF(Fbxo7) E3 ligase, and the proteasome inhibitor PI31. SCF(Fbxo7) is known to catalyze the ubiquitination of hepatoma-up-regulated protein (HURP) and the inhibitor of apoptosis (IAP) protein but also functions as an activator of cyclin D-Cdk6 complexes. We identify PI31 as an Fbxo7.Skp1 binding partner and show that this interaction requires an N-terminal domain present in both proteins that we term the FP (Fbxo7/PI31) domain. The crystal structure of the PI31 FP domain reveals a novel alpha/beta-fold. Biophysical and mutational analyses are used to map regions of the PI31 FP domain mediating homodimerization and required for heterodimerization with Fbxo7.Skp1. Equivalent mutations in Fbxo7 ablate interaction with PI31 and also block Fbxo7 homodimerization. Knockdown of Fbxo7 does not affect PI31 levels arguing against PI31 being a substrate for SCF(Fbxo7). We present a model for FP domain-mediated dimerization of SCF(Fbxo7) and PI31.