51 research outputs found
Intra-Domain Cross-Talk Regulates Serine-Arginine Protein Kinase 1-Dependent Phosphorylation and Splicing Function of Transformer 2β1
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
Structure of smAKAP and its regulation by PKA-mediated phosphorylation
The A-kinase anchoring protein (AKAP) smAKAP has three extraordinary features; it is very small, it is anchored directly to membranes by acyl motifs, and it interacts almost exclusively with the type I regulatory subunits (RI) of cAMP-dependent kinase (PKA). Here, we determined the crystal structure of smAKAP's A-kinase binding domain (smAKAP-AKB) in complex with the dimerization/docking (D/D) domain of RIα which reveals an extended hydrophobic interface with unique interaction pockets that drive smAKAP's high specificity for RI-subunits. We also identify a conserved PKA phosphorylation site at Ser66 in the AKB domain which we predict would cause steric clashes and disrupt binding. This correlates with in vivo co-localization and fluorescence polarization studies where Ser66 AKB phosphorylation ablates RI-binding. Hydrogen/deuterium exchange studies confirm that the AKB helix is accessible and dynamic. Furthermore, full-length smAKAP as well as the unbound AKB is predicted to contain a break at the phosphorylation site, and circular dichroism measurements confirm that the AKB domain loses its helicity following phosphorylation. Since the active site of PKA's catalytic subunit does not accommodate α-helices, we predict that the inherent flexibility of the AKB domain enables its phosphorylation by PKA. This represents a novel mechanism, whereby activation of anchored PKA can terminate its binding to smAKAP affecting the regulation of localized cAMP-signaling events. This article is protected by copyright. All rights reserved
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Human p70 Ribosomal S6 Protein Kinase-1 (S6K1): Mechanism of Substrate Catalysis, Activation and Inhibition
S6K1 is a member of the AGC subfamily of serine-threonine protein kinases, whereby catalytic activation requires dual phosphorylation of critical residues in the conserved T-loop (T229) and hydrophobic motif (HM; T389) peptide regions of its catalytic kinase domain (residues 1-398). In addition to its kinase domain, S6K1 contains a C-terminal autoinhibitory domain (AID; residues 399-502), which prevents T-loop and HM phosphorylation and autoinhibition is relieved on multi-site Ser-Thr phosphorylation of the AID (S411, S418, T421, and S424). The fully activated catalytic kinase domain construct, His6-S6K1 alphaII(∆AID)-T389E (activity = 250 nmol/min/mg) was generated by baculovirus-mediated expression and purification from Sf9 insect cells that were coinfected with recombinant baculovirus expressing the catalytic kinase domain of PDK1 [His6-PDK1(∆PH)]. The kinetic mechanism of fully active His6-S6K1 alphaII(∆AID)-T389E for catalyzing phosphorylation of a model peptide substrate (Tide, RRRLSSLRA) was determined. Two-substrate steady-state kinetics and product inhibition patterns indicated a Steady-State Ordered Bi Bi mechanism, while pre-steady state kinetics yielded microscopic rate constants for substrate binding, rapid chemical phosphorylation, and rate-limiting product release. Catalytic trapping experiments confirmed rate-limiting steps involving release of ADP. Pre-steady state kinetic and catalytic trapping experiments showed osmotic pressure to increase the rate of ADP release; and direct binding experiments showed osmotic pressure to correspondingly weaken the enzyme\u27s affinity for both ADP and ATP, indicating a less hydrated conformational form of the free enzyme. We propose that ordered binding of ATP causes partial unfolding of enzyme residues, which unmask the peptide substrate binding epitope. Next, the kinetic mechanism of PDK1 for catalyzing T229 phosphorylation of S6K1 (native and T389E mutant forms) was determined. Surprisingly, we found that His6-PDK1(∆PH) effectively and specifically phosphorylates T229 of His6-S6K1 alphaII(∆AID), regardless of whether a negative charge is localized at residue 389. Steady-state kinetic studies revealed S6K1 alphaII to be a competitive inhibitor of ATP, thereby enforcing an Ordered Bi Bi mechanism whereby ATP must bind first. Kinetic studies further revealed exceptionally slow bimolecular association of S6K1 alphaII substrate to form the productive ternary complex that catalyzes S6K1 alphaII T229 phosphorylation, indicating a high degree of nonproductive binding events. In this regard, the T389E mutant exhibited a two-fold increased efficiency of productive binding over native S6K1 alphaII. Finally, to investigate the regulatory role of C-terminal AID of S6K1, we developed and optimized protocols for efficient AID expression and purification. Consistent with computer predictions, aberrant mobilities in both SDS-PAGE and size-exclusion chromatography, as well as low chemical shift dispersion in 1H-15N HSQC NMR spectra, indicated purified recombinant AID to be largely unfolded. Yet, trans-addition of purified AID effectively inhibited PDK1-catalyzed T-loop phosphorylation of a catalytic kinase domain construct of S6K1. Using an identical purification protocol, similar protein yields of a tetraphospho-mimic mutant AID(D2ED) construct were obtained; and this construct displayed only weak inhibition of PDK1-catalyzed T229 phosphorylation
Kinetic Mechanism of Fully Activated S6K1 Protein Kinase*S⃞
S6K1 is a member of the AGC subfamily of serine-threonine protein kinases,
whereby catalytic activation requires dual phosphorylation of critical
residues in the conserved T-loop (Thr-229) and hydrophobic motif (Thr-389).
Previously, we described production of the fully activated catalytic kinase
domain construct, His6-S6K1αII(ΔAID)-T389E. Now, we
report its kinetic mechanism for catalyzing phosphorylation of a model peptide
substrate (Tide, RRRLSSLRA). First, two-substrate steady-state kinetics and
product inhibition patterns indicated a Steady-State Ordered Bi Bi mechanism,
whereby initial high affinity binding of ATP
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\begin{equation*}(K_{d}^{{\mathrm{ATP}}}=5-6\hspace{1em}{\mu}{\mathrm{M}})\end{equation*}\end{document} was
followed by low affinity binding of Tide
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\begin{equation*}(K_{d}^{{\mathrm{Tide}}}=180\hspace{1em}{\mu}{\mathrm{M}})\end{equation*}\end{document}, and
values of \documentclass[10pt]{article}
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\begin{equation*}K_{m}^{{\mathrm{ATP}}}=5-6\hspace{1em}{\mu}{\mathrm{M}}\end{equation*}\end{document}
and \documentclass[10pt]{article}
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\begin{equation*}K_{m}^{{\mathrm{Tide}}}=4-5\hspace{1em}{\mu}{\mathrm{M}}\end{equation*}\end{document} were
expressed in the active ternary complex. Global curve-fitting analysis of ATP,
Tide, and ADP titrations of pre-steady-state burst kinetics yielded
microscopic rate constants for substrate binding, rapid chemical
phosphorylation, and rate-limiting product release. Catalytic trapping
experiments confirmed rate-limiting steps involving release of ADP.
Pre-steady-state kinetic and catalytic trapping experiments showed osmotic
pressure to increase the rate of ADP release; and direct binding experiments
showed osmotic pressure to correspondingly weaken the affinity of the enzyme
for both ADP and ATP, indicating a less hydrated conformational form of the
free enzyme
Mobilization of a splicing factor through a nuclear kinase-kinase complex.
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
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Evolution of the eukaryotic protein kinases as dynamic molecular switches
Protein kinases have evolved in eukaryotes to be highly dynamic molecular switches that regulate a plethora of biological processes. Two motifs, a dynamic activation segment and a GHI helical subdomain, distinguish the eukaryotic protein kinases (EPKs) from the more primitive eukaryotic-like kinases. The EPKs are themselves highly regulated, typically by phosphorylation, and this allows them to be rapidly turned on and off. The EPKs have a novel hydrophobic architecture that is typically regulated by the dynamic assembly of two hydrophobic spines that is usually mediated by the phosphorylation of an activation loop phosphate. Cyclic AMP-dependent protein kinase (protein kinase A (PKA)) is used as a prototype to exemplify these features of the PKA superfamily. Specificity in PKA signalling is achieved in large part by packaging the enzyme as inactive tetrameric holoenzymes with regulatory subunits that then are localized to macromolecular complexes in close proximity to dedicated substrates by targeting scaffold proteins. In this way, the cell creates discrete foci that most likely represent the physiological environment for cyclic AMP-mediated signalling
Expression, purification, and characterization of a structurally disordered and functional C-terminal autoinhibitory domain (AID) of the 70 kDa 40S ribosomal protein S6 kinase-1 (S6K1)
S6K1 is a member of the AGC subfamily of serine-threonine protein kinases, whereby catalytic activation requires dual phosphorylation of critical residues in the conserved T-loop (T229) and hydrophobic motif (HM; T389) peptide regions of its catalytic kinase domain (residues 1-398). In addition to its kinase domain, S6K1 contains a C-terminal autoinhibitory domain (AID; residues 399-502), which prevents T-loop and HM phosphorylation; and autoinhibition is relieved on multi-site Ser-Thr phosphorylation of the AID (S411, S418, T421, and S424). Interestingly, 66 of the 104 C-terminal AID amino acid residues were computer predicted to exist in structurally disordered peptide regions, begetting interest as to how such dynamics could be coupled to autoregulation. To begin addressing this issue, we developed and optimized protocols for efficient AID expression and purification. Consistent with computer predictions, aberrant mobilities in both SDS-PAGE and size-exclusion chromatography, as well as low chemical shift dispersion in
1
H-
15
N HSQC NMR spectra, indicated purified recombinant AID to be largely unfolded. Yet, trans-addition of purified AID effectively inhibited PDK1-catalyzed T-loop phosphorylation of a catalytic kinase domain construct of S6K1. Using an identical purification protocol, similar protein yields of a tetraphospho-mimic mutant AID(D
2
ED) construct were obtained; and this construct displayed only weak inhibition of PDK1-catalyzed T229 phosphorylation. Purification of the structurally ‘disordered’ and functional C-terminal AID and AID(D
2
ED) constructs will facilitate studies aimed to understand the role of conformational plasticity and protein phosphorylation in modulating autoregulatory domain-domain interactions
Baculovirus-mediated expression, purification, and characterization of a fully activated catalytic kinase domain construct of the 70 kDa 40S ribosomal protein S6 kinase-1 αII isoform (S6K1αII)
S6K1αII is a member of the AGC subfamily of serine–threonine protein kinases, whereby catalytic activation requires dual phosphorylation of critical residues in the conserved T-loop (T229) and hydrophobic motif (HM; T389) regions of its catalytic kinase domain [S6K1αII(ΔAID); deletion of C-terminal autoinhibitory domain residues 399–502]. With regard to mimicking the synergistic effect of full dual site phosphorylation, baculovirus-mediated expression and affinity purification of the His
6-S6K1αII(ΔAID)-T229E,T389E double mutant from Sf9 insect cells yielded enzyme with compromised activity. Higher activity preparations were generated using the Sf9 purified His
6-S6K1αII(ΔAID)-T389E single mutant isoform, which was in vitro phosphorylated by the upstream T229 kinase, PDK1 (∼75
nmol/min/mg). Most significantly, we report that the His
6-S6K1αII(ΔAID)-T389E construct was generated in its most highly active form (250
nmol/min/mg) by baculovirus-mediated expression and purification from Sf9 insect cells that were
coinfected with recombinant baculovirus expressing the catalytic kinase domain of PDK1 [His
6-PDK1(ΔPH)]. Approximately equal amounts of fully activated His
6-S6K1αII(ΔAID)-T389E (5
±
1
mg) and His
6-PDK1(ΔPH) (8
±
2
mg) were His
6 affinity co-purified 60
h after initial coinfection of 200
mL of Sf9 insect cells (2
×
10
6 cells/mL), which were resolved by MonoQ anion exchange chromatography. ESI-TOF mass spectrometry, MonoQ anion exchange chromatography, and kinetic assays showed His
6-PDK1(ΔPH) to phosphorylate T229 to ∼100% after co-expression in Sf9 insect cells as compared to ∼50% under in vitro conditions, raising interest to mechanistic components not fully achieved in the in vitro reaction. Generation of fully activated S6K1 will facilitate more rigorous analysis of its structure and mechanism
Mechanisms of cyclic AMP/protein kinase A- and glucocorticoid-mediated apoptosis using S49 lymphoma cells as a model system.
Cyclic AMP/protein kinase A (cAMP/PKA) and glucocorticoids promote the death of many cell types, including cells of hematopoietic origin. In wild-type (WT) S49 T-lymphoma cells, signaling by cAMP and glucocorticoids converges on the induction of the proapoptotic B-cell lymphoma-family protein Bim to produce mitochondria-dependent apoptosis. Kin(-), a clonal variant of WT S49 cells, lacks PKA catalytic (PKA-Cα) activity and is resistant to cAMP-mediated apoptosis. Using sorbitol density gradient fractionation, we show here that in kin(-) S49 cells PKA-Cα is not only depleted but the residual PKA-Cα mislocalizes to heavier cell fractions and is not phosphorylated at two conserved residues (Ser(338) or Thr(197)). In WT S49 cells, PKA-regulatory subunit I (RI) and Bim coimmunoprecipitate upon treatment with cAMP analogs and forskolin (which increases endogenous cAMP concentrations). By contrast, in kin(-) cells, expression of PKA-RIα and Bim is prominently decreased, and increases in cAMP do not increase Bim expression. Even so, kin(-) cells undergo apoptosis in response to treatment with the glucocorticoid dexamethasone (Dex). In WT cells, glucorticoid-mediated apoptosis involves an increase in Bim, but in kin(-) cells, Dex-promoted cell death appears to occur by a caspase 3-independent apoptosis-inducing factor pathway. Thus, although cAMP/PKA-Cα and PKA-R1α/Bim mediate apoptotic cell death in WT S49 cells, kin(-) cells resist this response because of lower levels of PKA-Cα and PKA-RIα subunits as well as Bim. The findings for Dex-promoted apoptosis imply that these lymphoma cells have adapted to selective pressure that promotes cell death by altering canonical signaling pathways
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