SUMMARY Background The eukaryotic cell cycle begins with a burst of Cdk phosphorylation. In budding yeast, several Cdk substrates are preferentially phosphorylated at the G1/S transition rather than later in the cell cycle when Cdk activity levels are high. These early Cdk substrates include signaling proteins in the pheromone response pathway. Two such proteins, Ste5 and Ste20, are phosphorylated only when Cdk is associated with the G1/S cyclins Cln1 and Cln2, and not G1, S, or M cyclins. The basis of this cyclin specificity is unknown. Results Here we show that Ste5 and Ste20 have recognition sequences, or “docking” sites, for the G1/S cyclins. These docking sites, which are distinct from Clb5/cyclin A-binding “RxL” motifs, bind preferentially to Cln2. They strongly enhance Cln2-driven phosphorylation of each substrate in vivo, and function largely independent of position and distance to the Cdk sites. We exploited this functional independence to re-wire a Cdk regulatory circuit in a way that changes the target of Cdk inhibition in the pheromone response pathway. Furthermore, we uncover functionally active Cln2 docking motifs in several other Cdk substrates. The docking motifs drive cyclin-specific phosphorylation, and the cyclin preference can be switched by using a distinct motif. Conclusions Our findings indicate that some Cdk substrates are intrinsically capable of being phosphorylated by several different cyclin-Cdk forms, but they are inefficiently phosphorylated in vivo without a cyclin-specific docking site. Docking interactions may play a prevalent but previously unappreciated role in driving phosphorylation of select Cdk substrates preferentially at the G1/S transition.
Summary Background Eukaryotic cell division is driven by cyclin-dependent kinases (CDKs). Distinct cyclin-CDK complexes are specialized to drive different cell cycle events, though the molecular foundations for these specializations are only partly understood. In budding yeast, the decision to begin a new cell cycle is regulated by three G1 cyclins (Cln1–Cln3). Recent studies revealed that some CDK substrates contain a novel docking motif that is specifically recognized by Cln1 and Cln2, and not by Cln3 or later S- or M-phase cyclins, but the responsible cyclin interface was unknown. Results Here, to explore the role of this new docking mechanism in the cell cycle, we first show that it is conserved in a distinct cyclin subtype (Ccn1). Then, we exploit phylogenetic variation to identify cyclin mutations that disrupt docking. These mutations disrupt binding to multiple substrates as well as the ability to use docking sites to promote efficient, multi-site phosphorylation of substrates in vitro. In cells where the Cln2 docking function is blocked, we observed reductions in the polarized morphogenesis of daughter buds and reduced ability to fully phosphorylate the G1/S transcriptional repressor Whi5. Furthermore, disruption of Cln2 docking perturbs the coordination between cell size and division, such that the G1/S transition is delayed. Conclusions The findings point to a novel substrate interaction interface on cyclins, with patterns of conservation and divergence that relate to functional distinctions among cyclin subtypes. Furthermore, this docking function helps ensure full phosphorylation of substrates with multiple phosphorylation sites, and this contributes to punctual cell cycle entry.
Summary Eukaryotic cell division is often regulated by extracellular signals. In budding yeast, signaling from mating pheromones arrests the cell cycle in G1 phase [1]. This arrest requires the protein Far1 [2], which is thought to antagonize the G1/S transition by acting as a Cdk inhibitor (CKI) [3, 4], although the mechanisms remain unresolved [5]. Recent studies found that G1/S cyclins (Cln1 and Cln2) recognize Cdk substrates via specific docking motifs, which promote substrate phosphorylation in vivo [6, 7]. Here, we show that these docking interactions are inhibited by pheromone signaling, and that this inhibition requires Far1. Moreover, Far1 mutants that cannot inhibit docking are defective at cell cycle arrest. Consistent with this arrest function, Far1 outcompetes substrates for association with G1/S cyclins in vivo, and it is present in large excess over G1/S cyclins during the pre-commitment period where pheromone can impose G1 arrest. Finally, a comparison of substrates that do and do not require docking suggests that Far1 acts as a multi-mode inhibitor that antagonizes both kinase activity and substrate recognition by Cln1/2-Cdk complexes. Our findings uncover a novel mechanism of Cdk regulation by external signals, and shed new light on Far1 function to provide a revised view of cell cycle arrest in this model system.
Comprehensive Analysis of G1 Cyclin Docking Motif Sequences that Control CDK Regulatory Potency In Vivo
Cyclin-dependent kinases (CDKs) control the ordered series of events during eukaryotic cell division. The stage at which individual CDK substrates are phosphorylated can be dictated by cyclin-specific docking motifs. In budding yeast, substrates with Leu/Pro-rich (LP) docking motifs are recognized by Cln1/2 cyclins in late G1 phase, yet the key sequence features of these motifs and the conservation of this mechanism were unknown. Here we comprehensively analyzed LP motif requirements in vivo by combining a competitive growth assay with mutational scanning and deep sequencing. We quantified the impact of all single-residue replacements in five different LP motifs, using six distinct G1 cyclins from diverse fungi including medical and agricultural pathogens. The results reveal the basis for variations in potency among wild-type motifs, and allow derivation of a quantitative matrix that predicts the potency of other candidate motifs. In one protein, Whi5, we found overlapping LP and phosphorylation motifs with partly redundant effects. In another protein, the CDK inhibitor Sic1, we found that its LP motif is inherently weak due to unfavorable residues at key positions, and this imposes a beneficial delay in its phosphorylation and degradation. The overall results provide a general method for surveying viable docking motif sequences and quantifying their potency in vivo, and they reveal how variations in LP motif potency can tune the strength and timing of CDK regulation..
Relapsed/refractory DLBCL remains an incurable disease, and single-agent therapies typically show low response rates and/or transient clinical responses. Oncogenic MYD88 mutations occur in ~25% of DLBCL and drive constitutive NFkB activation, promoting proliferation and survival. Despite its role in tumor biology, targeting MYD88MT by inhibiting or degrading IRAK4 alone, a key component of the MYD88 complex, does not drive significant antitumor activity in preclinical models. One potential reason is the frequent redundant NFkB pathway activation by co-mutations, highlighting the need for combination therapies to effectively target the NFkB pathway in DLBCL. To address this challenge, we have developed IRAKIMiDs, heterobifunctional degraders that simultaneously degrade both IRAK4 and IMiD substrates, as a rational therapeutic combination in a single molecule. IRAKIMiDs show increased antitumor activity in vitro and in vivo in MYD88MT cells as compared to IMiD or IRAK4-targeting alone, highlighting suggesting their potential as single agents in R/R DLBCL.Our lead IRAKIMiD, KT-413, is a potent degrader of IRAK4 (DC50 6nM) and IMiD substrates (Ikaros/Aiolos DC50 2nM), inducing rapid and potent cell killing in vitro and complete and sustained tumor regressions in vivo in MYD88MT models of DLBCL. This activity is superior to the IMiD CC-220, which has similar activity against IMiD substrates (Ikaros/Aiolos DC50 1 nM), supporting the synergistic role of IRAK4 degradation in the context of IMiD biology. We show here that the combined activity of these 2 mechanisms drives a synergistic effect on NFkB and IRF4 signaling with greater downstream effect on NFkB and type 1 interferon (IFN) signaling and cell cycle gene expression than either mechanism alone. In THP1 cells engineered with NFkB and IRF4 reporters, KT-413 but not CC-220 inhibits TLR-stimulated NFkB and IRF4 transcription, supporting a role for IRAK4 but not IMiDs in MYD88-driven survival and proliferation signals. IMiDs have previously been shown to modulate type1 IFN signaling through downregulation of IRF4. We propose that simultaneous targeting of both NFkB and type 1 IFN signaling with KT-413 drives synergistic cell killing in MYD88MT cells. In MYD88MT OCI-Ly10 cells, KT-413 leads to greater IRF4 downregulation, increased type 1 IFN signaling, and preferential downregulation of NFkB pathway and cell cycle transcripts when compared to CC-220. These data support the hypothesis that the synergistic activity of targeting IRAK4 and IMiD substrates by KT-413 in MYD88MT DLBCL is a result of dual targeting of NFkB and IRF4/Type1 IFN through degradation of both IRAK4 and IMiD substrates,driving significantly greater cell killing as compared to either mechanism alone, supporting the potential for the first single agent targeted therapy in MYD88MT DLBCL. KT-413 is on track for initiation of a Phase 1 trial in B cell lymphoma in 2H 2021. Citation Format: Christine R. Klaus, Scott F. Rusin, Kirti Sharma, Samyabrata Bhaduri, Matthew M. Weiss, Alice A. McDonald, Michele F. Mayo, Duncan Walker, Rahul Karnik. Mechanisms underlying synergistic activity in MYD88MTDLBCL of KT-413, a targeted degrader of IRAK4 and IMiD substrate [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2021; 2021 Apr 10-15 and May 17-21. Philadelphia (PA): AACR; Cancer Res 2021;81(13_Suppl):Abstract nr LB118.
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