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Thesis
Peer Reviewed

Insights into the Role of a Disordered N-Terminus in the Functional Regulation of CLK1 Kinase

UC San Diego Electronic Theses and Dissertations (2021)

SR proteins are a family of splicing factors that plays important roles in regulating alternative splicing. The function of SR proteins is heavily regulated by the extent of phosphorylation of its C-terminal RS domain. Cdc-2 like kinases (CLKs) are known to hyper-phosphorylate the RS domains and control the splicing functions of SR proteins. CLKs have a folded kinase domain and an N-terminus that is predicted to be disordered. The N-terminus plays vital roles in regulating the function of CLK1 in various aspects. The studies presented here elucidate how the N-terminus modulates three different aspects of CLK1 function: sub-cellular localization, self-association to form oligomers, and substrate phosphorylation. Although prior studies had shown that the N-terminus was important for modulating the nuclear import of CLK1, the mechanism for this change in subcellular localization had largely been uninvestigated. Here, we show that CLK1 lacks a short, classical Nuclear Localization Sequence (NLS), indicating that the nuclear import is not mediated by the classical importin / system. Instead, we show that CLK1 enters the nucleus by forming a complex with its physiological substrate SRSF1, an SR protein prototype, in the cytoplasm and transportin SR-2 (TRN-SR2) imports the kinase-substrate complex into the nucleus. Previous studies from our laboratory had shown that the N-terminus induces oligomerization of CLK1, which helps the kinase select its physiological substrates over non-physiological ones. The nature of the interactions underlying this oligomerization was investigated and our results show that CLK1 oligomerization is driven not only by self-association of the N-terminus (N-N interactions) but also by interactions between the N-terminus and the kinase domain (N-K interactions). While interactions between the N-termini are mediated solely by aromatic residues, interactions between the N-terminus and kinase domain are electrostatic in nature. Lastly, we also investigated the role of the N-terminus in regulating SRSF1 hyper-phosphorylation. Our results show a strong correlation between CLK1 quaternary structure and substrate phosphorylation activity. While substrate binding affinity is solely regulated by the length of the N-terminus, the velocity of hyper-phosphorylation is tightly regulated by the quaternary structure of CLK1 oligomers. Our studies demonstrate that the N-terminus of CLK1 is highly versatile. It is important not only for recognizing a broad range of RS domains for essential SR protein hyper-phosphorylation but also for CLK1 nuclear localization through substrate “piggybacking.”

Cover page: Insights into the Role of a Disordered N-Terminus in the Functional Regulation of CLK1 Kinase

Article
Peer Reviewed

Mobilization of a splicing factor through a nuclear kinase-kinase complex.

UC San Diego Previously Published Works (2018)

The splicing of mRNA is dependent on serine-arginine (SR) proteins that are mobilized from membrane-free, nuclear speckles to the nucleoplasm by the Cdc2-like kinases (CLKs). This movement is critical for SR protein-dependent assembly of the macromolecular spliceosome. Although CLK1 facilitates such trafficking through the phosphorylation of serine-proline dipeptides in the prototype SR protein SRSF1, an unrelated enzyme known as SR protein kinase 1 (SRPK1) performs the same function but does not efficiently modify these dipeptides in SRSF1. We now show that the ability of SRPK1 to mobilize SRSF1 from speckles to the nucleoplasm is dependent on active CLK1. Diffusion from speckles is promoted by the formation of an SRPK1-CLK1 complex that facilitates dissociation of SRSF1 from CLK1 and enhances the phosphorylation of several serine-proline dipeptides in this SR protein. Down-regulation of either kinase blocks EGF-stimulated mobilization of nuclear SRSF1. These findings establish a signaling pathway that connects SRPKs to SR protein activation through the associated CLK family of kinases.

Cover page: Mobilization of a splicing factor through a nuclear kinase-kinase complex.

Article
Peer Reviewed

Disordered protein interactions for an ordered cellular transition: Cdc2-like kinase 1 is transported to the nucleus via its Ser–Arg protein substrate

UC San Diego Previously Published Works (2019)

Serine-arginine (SR) proteins are essential splicing factors that promote numerous steps associated with mRNA processing and whose biological function is tightly regulated through multi-site phosphorylation. In the nucleus, the cdc2-like kinases (CLKs) phosphorylate SR proteins on their intrinsically disordered Arg-Ser (RS) domains, mobilizing them from storage speckles to the splicing machinery. The CLKs have disordered N termini that bind tightly to RS domains, enhancing SR protein phosphorylation. The N termini also promote nuclear localization of CLKs, but their transport mechanism is presently unknown. To explore cytoplasmic-nuclear transitions, several classical nuclear localization sequences in the N terminus of the CLK1 isoform were identified, but their mutation had no effect on subcellular localization. Rather, we found that CLK1 amplifies its presence in the nucleus by forming a stable complex with the SR protein substrate and appropriating its NLS for transport. These findings indicate that, along with their well-established roles in mRNA splicing, SR proteins use disordered protein-protein interactions to carry their kinase regulator from the cytoplasm to the nucleus.

Cover page: Disordered protein interactions for an ordered cellular transition: Cdc2-like kinase 1 is transported to the nucleus via its Ser–Arg protein substrate

Article
Peer Reviewed

Molecular interactions connecting the function of the serine-arginine–rich protein SRSF1 to protein phosphatase 1

UC San Diego Previously Published Works (2018)

Splicing generates many mRNA strands from a single precursor mRNA, expanding the proteome and enhancing intracellular diversity. Both initial assembly and activation of the spliceosome require an essential family of splicing factors called serine-arginine (SR) proteins. Protein phosphatase 1 (PP1) regulates the SR proteins by controlling phosphorylation of a C-terminal arginine-serine-rich (RS) domain. These modifications are vital for the subcellular localization and mRNA splicing function of the SR protein. Although PP1 has been shown to dephosphorylate the prototype SR protein splicing factor 1 (SRSF1), the molecular nature of this interaction is not understood. Here, using NMR spectroscopy, we identified two electrostatic residues in helix α2 and a hydrophobic residue in helix α1 in the RNA recognition motif 1 (RRM1) of SRSF1 that constitute a binding surface for PP1. Substitution of these residues dissociated SRSF1 from PP1 and enhanced phosphatase activity, reducing phosphorylation in the RS domain. These effects lead to shifts in alternative splicing patterns that parallel increases in SRSF1 diffusion from speckles to the nucleoplasm brought on by regiospecific decreases in RS domain phosphorylation. Overall, these findings establish a molecular and biological connection between PP1-targeted amino acids in an RRM with the phosphorylation state and mRNA-processing function of an SR protein.

Cover page: Molecular interactions connecting the function of the serine-arginine–rich protein SRSF1 to protein phosphatase 1

Article
Peer Reviewed

Redirecting SR Protein Nuclear Trafficking through an Allosteric Platform

UC San Diego Previously Published Works (2017)

Although phosphorylation directs serine-arginine (SR) proteins from nuclear storage speckles to the nucleoplasm for splicing function, dephosphorylation paradoxically induces similar movement, raising the question of how such chemical modifications are balanced in these essential splicing factors. In this new study, we investigated the interaction of protein phosphatase 1 (PP1) with the SR protein splicing factor (SRSF1) to understand the foundation of these opposing effects in the nucleus. We found that RNA recognition motif 1 (RRM1) in SRSF1 binds PP1 and represses its catalytic function through an allosteric mechanism. Disruption of RRM1-PP1 interactions reduces the phosphorylation status of the RS domain in vitro and in cells, redirecting SRSF1 in the nucleus. The data imply that an allosteric SR protein-phosphatase platform balances phosphorylation levels in a "goldilocks" region for the proper subnuclear storage of an SR protein splicing factor.

Cover page: Redirecting SR Protein Nuclear Trafficking through an Allosteric Platform

Article
Peer Reviewed

Intra-domain Cross-talk Regulates Serine-arginine Protein Kinase 1-dependent Phosphorylation and Splicing Function of Transformer 2β1*

UC San Diego Previously Published Works (2015)

Transformer 2β1 (Tra2β1) is a splicing effector protein composed of a core RNA recognition motif flanked by two arginine-serine-rich (RS) domains, RS1 and RS2. Although Tra2β1-dependent splicing is regulated by phosphorylation, very little is known about how protein kinases phosphorylate these two RS domains. We now show that the serine-arginine protein kinase-1 (SRPK1) is a regulator of Tra2β1 and promotes exon inclusion in the survival motor neuron gene 2 (SMN2). To understand how SRPK1 phosphorylates this splicing factor, we performed mass spectrometric and kinetic experiments. We found that SRPK1 specifically phosphorylates 21 serines in RS1, a process facilitated by a docking groove in the kinase domain. Although SRPK1 readily phosphorylates RS2 in a splice variant lacking the N-terminal RS domain (Tra2β3), RS1 blocks phosphorylation of these serines in the full-length Tra2β1. Thus, RS2 serves two new functions. First, RS2 positively regulates binding of the central RNA recognition motif to an exonic splicing enhancer sequence, a phenomenon reversed by SRPK1 phosphorylation on RS1. Second, RS2 enhances ligand exchange in the SRPK1 active site allowing highly efficient Tra2β1 phosphorylation. These studies demonstrate that SRPK1 is a regulator of Tra2β1 splicing function and that the individual RS domains engage in considerable cross-talk, assuming novel functions with regard to RNA binding, splicing, and SRPK1 catalysis.

Cover page: Intra-domain Cross-talk Regulates Serine-arginine Protein Kinase 1-dependent Phosphorylation and Splicing Function of Transformer 2β1*

Article
Peer Reviewed

Nuclear protein kinase CLK1 uses a non-traditional docking mechanism to select physiological substrates.

UC San Diego Previously Published Works (2015)

Phosphorylation-dependent cell communication requires enzymes that specifically recognize key proteins in a sea of similar, competing substrates. The protein kinases achieve this goal by utilizing docking grooves in the kinase domain or heterologous protein adaptors to reduce 'off pathway' targeting. We now provide evidence that the nuclear protein kinase CLK1 (cell division cycle2-like kinase 1) important for splicing regulation departs from these classic paradigms by using a novel self-association mechanism. The disordered N-terminus of CLK1 induces oligomerization, a necessary event for targeting its physiological substrates the SR protein (splicing factor containing a C-terminal RS domain) family of splicing factors. Increasing the CLK1 concentration enhances phosphorylation of the splicing regulator SRSF1 (SR protein splicing factor 1) compared with the general substrate myelin basic protein (MBP). In contrast, removal of the N-terminus or dilution of CLK1 induces monomer formation and reverses this specificity. CLK1 self-association also occurs in the nucleus, is induced by the N-terminus and is important for localization of the kinase in sub-nuclear compartments known as speckles. These findings present a new picture of substrate recognition for a protein kinase in which an intrinsically disordered domain is used to capture physiological targets with similar disordered domains in a large oligomeric complex while discriminating against non-physiological targets.

Cover page: Nuclear protein kinase CLK1 uses a non-traditional docking mechanism to select physiological substrates.

Article
Peer Reviewed

Release of SR Proteins from CLK1 by SRPK1: A Symbiotic Kinase System for Phosphorylation Control of Pre-mRNA Splicing

UC Irvine Previously Published Works (2016)

Phosphorylation has been generally thought to activate the SR family of splicing factors for efficient splice-site recognition, but this idea is incompatible with an early observation that overexpression of an SR protein kinase, such as the CDC2-like kinase 1 (CLK1), weakens splice-site selection. Here, we report that CLK1 binds SR proteins but lacks the mechanism to release phosphorylated SR proteins, thus functionally inactivating the splicing factors. Interestingly, CLK1 overcomes this dilemma through a symbiotic relationship with the serine-arginine protein kinase 1 (SRPK1). We show that SRPK1 interacts with an RS-like domain in the N terminus of CLK1 to facilitate the release of phosphorylated SR proteins, which then promotes efficient splice-site recognition and subsequent spliceosome assembly. These findings reveal an unprecedented signaling mechanism by which two protein kinases fulfill separate catalytic features that are normally encoded in single kinases to institute phosphorylation control of pre-mRNA splicing in the nucleus.

Article
Peer Reviewed

Release of SR Proteins from CLK1 by SRPK1: A Symbiotic Kinase System for Phosphorylation Control of Pre-mRNA Splicing.

UC Irvine Previously Published Works (2016)

Phosphorylation has been generally thought to activate the SR family of splicing factors for efficient splice-site recognition, but this idea is incompatible with an early observation that overexpression of an SR protein kinase, such as the CDC2-like kinase 1 (CLK1), weakens splice-site selection. Here, we report that CLK1 binds SR proteins but lacks the mechanism to release phosphorylated SR proteins, thus functionally inactivating the splicing factors. Interestingly, CLK1 overcomes this dilemma through a symbiotic relationship with the serine-arginine protein kinase 1 (SRPK1). We show that SRPK1 interacts with an RS-like domain in the N terminus of CLK1 to facilitate the release of phosphorylated SR proteins, which then promotes efficient splice-site recognition and subsequent spliceosome assembly. These findings reveal an unprecedented signaling mechanism by which two protein kinases fulfill separate catalytic features that are normally encoded in single kinases to institute phosphorylation control of pre-mRNA splicing in the nucleus.

Article
Peer Reviewed

Directional Phosphorylation and Nuclear Transport of the Splicing Factor SRSF1 Is Regulated by an RNA Recognition Motif

UC San Diego Previously Published Works (2016)

Multisite phosphorylation is required for the biological function of serine-arginine (SR) proteins, a family of essential regulators of mRNA splicing. These modifications are catalyzed by serine-arginine protein kinases (SRPKs) that phosphorylate numerous serines in arginine-serine-rich (RS) domains of SR proteins using a directional, C-to-N-terminal mechanism. The present studies explore how SRPKs govern this highly biased phosphorylation reaction and investigate biological roles of the observed directional phosphorylation mechanism. Using NMR spectroscopy with two separately expressed domains of SRSF1, we showed that several residues in the RNA-binding motif 2 interact with the N-terminal region of the RS domain (RS1). These contacts provide a structural framework that balances the activities of SRPK1 and the protein phosphatase PP1, thereby regulating the phosphoryl content of the RS domain. Disruption of the implicated intramolecular RNA-binding motif 2-RS domain interaction impairs both the directional phosphorylation mechanism and the nuclear translocation of SRSF1 demonstrating that the intrinsic phosphorylation bias is obligatory for SR protein biological function.

Cover page: Directional Phosphorylation and Nuclear Transport of the Splicing Factor SRSF1 Is Regulated by an RNA Recognition Motif