Tyrosine phosphorylation modifies protein kinase C delta-dependent phosphorylation of cardiac troponin I

Our study identifies tyrosine phosphorylation as a novel protein kinase Cdelta (PKCdelta) activation mechanism that modifies PKCdelta-dependent phosphorylation of cardiac troponin I (cTnI), a myofilament regulatory protein. PKCdelta phosphorylates cTnI at Ser23/Ser24 when activated by lipid cofactors; Src phosphorylates PKCdelta at Tyr311 and Tyr332 leading to enhanced PKCdelta autophosphorylation at Thr505 (its activation loop) and PKCdelta-dependent cTnI phosphorylation at both Ser23/Ser24 and Thr144. The Src-dependent acquisition of cTnI-Thr144 kinase activity is abrogated by Y311F or T505A substitutions. Treatment of detergent-extracted single cardiomyocytes with lipid-activated PKCdelta induces depressed tension at submaximum but not maximum [Ca2+] as expected for cTnI-Ser23/Ser24 phosphorylation. Treatment of myocytes with Src-activated PKCdelta leads to depressed maximum tension and cross-bridge kinetics, attributable to a dominant effect of cTnI-Thr144 phosphorylation. Our data implicate PKCdelta-Tyr311/Thr505 phosphorylation as dynamically regulated modifications that alter PKCdelta enzymology and allow for stimulus-specific control of cardiac mechanics during growth factor stimulation and oxidative stress.     

PKCdelta-mediated IRS-1 Ser24 phosphorylation negatively regulates IRS-1 function

The IRS-1 PH and PTB domains are essential for insulin-stimulated IRS-1 Tyr phosphorylation and insulin signaling, while Ser/Thr phosphorylation of IRS-1 disrupts these signaling events. To investigate consensus PKC phosphorylation sites in the PH-PTB domains of human IRS-1, we changed Ser24, Ser58, and Thr191 to Ala (3A) or Glu (3E), to block or mimic phosphorylation, respectively. The 3A mutant abrogated the inhibitory effect of PKCdelta on insulin-stimulated IRS-1 Tyr phosphorylation, while reductions in insulin-stimulated IRS-1 Tyr phosphorylation, cellular proliferation, and Akt activation were observed with the 3E mutant. When single Glu mutants were tested, the Ser24 to Glu mutant had the greatest inhibitory effect on insulin-stimulated IRS-1 Tyr phosphorylation. PKCdelta-mediated IRS-1 Ser24 phosphorylation was confirmed in cells with PKCdelta catalytic domain mutants and by an RNAi method. Mechanistic studies revealed that IRS-1 with Ala and Glu point mutations at Ser24 impaired phosphatidylinositol-4,5-bisphosphate binding. In summary, our data are consistent with the hypothesis that Ser24 is a negative regulatory phosphorylation site in IRS-1.     

Consequences of lysine 72 mutation on the phosphorylation and activation state of cAMP-dependent kinase

General strategies to obtain inactive kinases have utilized mutation of key conserved residues in the kinase core, and the equivalent Lys72 in cAMP-dependent kinase has often been used to generate a "dead" kinase. Here, we have analyzed the consequences of this mutation on kinase structure and function. Mutation of Lys72 to histidine (K72H) generated an inactive enzyme, which was unphosphorylated. Treatment with an exogenous kinase (PDK-1) resulted in a mutant that was phosphorylated only at Thr197 and remained inactive but nevertheless capable of binding ATP. Ser338 in K72H cannot be autophosphorylated, nor can it be phosphorylated in an intermolecular process by active wild type C-subunit. The Lys72 mutant, once phosphorylated on Thr197, can bind with high affinity to the RIalpha subunits. Thus a dead kinase can still act as a scaffold for binding substrates and inhibitors; it is only phosphoryl transfer that is defective. Using a potent inhibitor of C-subunit activity, H-89, Escherichia coli-expressed C-subunit was also obtained in its unphosphorylated state. This protein is able to mature into its active form in the presence of PDK-1 and is able to undergo secondary autophosphorylation on Ser338. Unlike the H-89-treated wild type protein, the mutant protein (K72H) cannot undergo the subsequent cis autophosphorylation following phosphorylation at Thr197. Using these two substrates and mammalian-expressed PDK-1, we can elucidate a possible two-step process for the activation of the C-subunit: initial phosphorylation on the activation loop at Thr197 by PDK-1, or a PDK-1-like enzyme, followed by second cis autophosphorylation step at Ser338.     

Nutrient regulation of PKCepsilon is mediated by leucine, not insulin, in skeletal muscle

Nutrients enhance signaling pathways involved in skeletal muscle growth through an increased rate of protein synthesis. These studies have led to an understanding of the potential role of the mammalian target of rapamycin (mTOR) in this process. However, activation of mTOR cannot account for all the stimulatory effects of nutrients. The purpose of these experiments was to examine the effect of nutrients on the cellular distribution and activation state of novel PKC isoforms (PKCepsilon and PKCdelta) in the gastrocnemius of rats by use of modification state-dependent phosphopeptide-specific antibodies. The phosphorylation of PKCepsilon on the catalytic domain autophosphorylation site (Ser(729)) was elevated during feeding and then returned to basal levels when the feeding period ended. Meal feeding augmented the phosphorylation of the downstream effectors of mTOR, namely S6K1 and 4E-BP1. In contrast, the phosphorylation of PKCdelta on either the catalytic domain autophosphorylation site (Ser(643)) or activation loop site (Thr(505)) was unaffected. Similar results were obtained when animals were given leucine either acutely via gavage or chronically by dietary supplementations. The effect of leucine was not mimicked by injecting animals with insulin but could be induced by gavage with norleucine, a structural analog of leucine that does not increase plasma insulin concentration. Thus rises in insulin secondary to meal intake or leucine gavage are probably not responsible for increased phosphorylation of PKCepsilon in response to meal feeding. Elevating the leucine concentration stimulated the phosphorylation of PKCepsilon in gastrocnemius from perfused hindlimb and caused a shift in the distribution of PKCepsilon from the membrane fraction to the cytosolic fraction. The results indicate that leucine leads to an activation (autophosphorylation) and subcellular redistribution of PKCepsilon, but not PKCdelta, in gastrocnemius both in vivo and in vitro. Furthermore, activation of the mTOR signaling pathway above basal conditions does not appear to be necessary to induce phosphorylation or translocation of PKCepsilon, suggesting that multiple signaling pathways become activated with leucine.     

The kinase activation loop is the key to mixed lineage kinase-3 activation via both autophosphorylation and hematopoietic progenitor kinase 1 phosphorylation

We have demonstrated previously that Cdc42 induced MLK-3 homodimerization leads to both autophosphorylation and activation of MLK-3 and postulated that autophosphorylation is an intermediate step of MLK-3 activation following its dimerization. In this report we sought to refine further the mechanism of MLK-3 activation and study the role of the putative kinase activation loop in MLK-3 activation. First we mutated the three potential phosphorylation sites in MLK-3 putative activation loop to alanine in an effort to abrogate MLK-3 autophosphorylation. Mutant T277A displayed almost no autophosphorylation activity and was nearly nonfunctional; mutant S281A, that displayed a low level of autophosphorylation, only slightly activated its downstream targets, whereas the T278A mutant, that exhibited autophosphorylation comparable to that of the wild type, was almost fully functional. Thus, these residues within the activation loop are critical for MLK-3 autophosphorylation and activation. In addition, when the Thr277 and Ser281 residues were mutated to negatively charged glutamic acid to mimic phosphorylated serine/threonine residues, the resulting mutants were fully functional, implying that these two residues may serve as the autophosphorylation sites. Interestingly, HPK1 also phosphorylated MLK-3 activation loop in vitro, and Ser281 was found to be the major phosphorylation site, indicating that HPK1 also activates MLK-3 via phosphorylation of the kinase activation loop.     

Activation of a GST-tagged AKT2/PKBbeta

The protein kinase AKT is a key regulator for cell growth, cell survival and metabolic insulin action. However, the mechanism of activation of AKT in vivo, which presumably involves membrane recruitment of the kinase, oligomerization, and multiple phosphorylation events, is not fully understood. In the present study, we have expressed and purified dimeric GST-fusion proteins of human protein kinase AKT2 (DeltaPH-AKT2) in milligram quantities via the baculovirus expression system. Treatment of virus-infected insect cells with the phosphatase inhibitor okadaic acid (OA) led to phosphorylation of the two regulatory phosphorylation sites, Thr309 and Ser474, and to activation of the kinase. Likewise, phosphorylation of Thr309 in vitro by recombinant PDK1 or mutation of Thr309 and Ser474 to acidic residues rendered the kinase constitutively active. However, even though the specific activity of our AKT2 was increased 15-fold compared to previous reports, GST-mediated dimerization alone did not lead to an activation of the kinase. Whereas both mutagenesis and phosphorylation led to an increase in the turnover number of the enzyme, only the latter resulted in a marked reduction (20-fold) of the apparent Km value for the exogenous substrate Crosstide, indicating that this widely used mutagenesis only partially mimics phosphorylation. Kinetic analysis of GST-AKT2 demonstrates that phosphorylation of Thr309 in the activation loop of the kinase is largely responsible for the observed reduction in Km and for a subsequent 150-fold increase in the catalytic efficiency (k(cat)/Km) of the enzyme. Highly active AKT2 constructs were used in autophosphorylation reactions in vitro, where inactive AKT2 kinases served as substrates. As a matter of fact, we found evidence for a minor autophosphorylation activity of AKT2 but no significant autophosphorylation of any of the two regulatory sites, Thr309 or Ser474.     

The hydrophobic phosphorylation motif of conventional protein kinase C is regulated by autophosphorylation.

BACKGROUND: A growing number of kinases are now known to be controlled by two phosphorylation switches, one on a loop near the entrance to the active site and a second on the carboxyl terminus. For the protein kinase C (PKC) family of enzymes, phosphorylation at the activation loop is mediated by another kinase but the mechanism for carboxy-terminal phosphorylation is still unclear. The latter switch contains two phosphorylation sites - one on a 'turn' motif and the second on a conserved hydrophobic phosphorylation motif - that are found separately or together in a number of other kinases. RESULTS: Here, we investigated whether the carboxy-terminal phosphorylation sites of a conventional PKC are controlled by autophosphorylation or by another kinase. First, kinetic analyses revealed that a purified construct of the kinase domain of PKC betaII autophosphorylated on the Ser660 residue of the hydrophobic phosphorylation motif in an apparently concentration-independent manner. Second, kinase-inactive mutants of PKC did not incorporate phosphate at either of the carboxy-terminal sites, Thr641 or Ser660, when expressed in COS-7 cells. The inability to incorporate phosphate on the hydrophobic site was unrelated to the phosphorylation state of the other key phosphorylation sites: kinase-inactive mutants with negative charge at Thr641 and/or the activation-loop position were also not phosphorylated in vivo. CONCLUSIONS: PKC betaII autophosphorylates at its conserved carboxy-terminal hydrophobic phosphorylation site by an apparently intramolecular mechanism. Expression studies with kinase-inactive mutants revealed that this mechanism is the only one responsible for phosphorylating this motif in vivo. Thus, conventional PKC autoregulates the carboxy-terminal phosphorylation switch following phosphorylation by another kinase at the activation loop switch.     

Auto‐activation mechanism of the Mycobacterium tuberculosis PknB receptor Ser/Thr kinase

Many Ser/Thr protein kinases are activated by autophosphorylation, but the mechanism of this process has not been defined. We determined the crystal structure of a mutant of the Ser/Thr kinase domain (KD) of the mycobacterial sensor kinase PknB in complex with an ATP competitive inhibitor and discovered features consistent with an activation complex. The complex formed an asymmetric dimer, with the G helix and the ordered activation loop of one KD in contact with the G helix of the other. The activation loop of this putative ‘substrate’ KD was disordered, with the ends positioned at the entrance to the partner KD active site. Single amino‐acid substitutions in the G‐helix interface reduced activation‐loop phosphorylation, and multiple replacements abolished KD phosphorylation and kinase activation. Phosphorylation of an inactive mutant KD was reduced by G‐helix substitutions in both active and inactive KDs, as predicted by the idea that the asymmetric dimer mimics a trans‐autophosphorylation complex. These results support a model in which a structurally and functionally asymmetric, ‘front‐to‐front’ association mediates autophosphorylation of PknB and homologous kinases.     

Protein kinase C delta is phosphorylated on five novel Ser/Thr sites following inducible overexpression in human colorectal cancer cells

Phosphorylation plays an important role in regulation of protein kinase C delta (PKCdelta). To date, three Ser/Thr residues (Thr 505, Ser 643, and Ser 662) and nine tyrosine residues (Tyr 52, Tyr 64, Tyr 155, Tyr 187, Tyr 311, Tyr 332, Tyr 512, Tyr 523, and Tyr 565) have been defined as regulatory phosphorylation sites for this protein (rat PKCdelta numbering). We combined doxycycline-regulated inducible gene expression technology with a hypothesis-driven mass spectrometry approach to study PKCdelta phosphorylation pattern in colorectal cancer cells. We report identification of five novel Ser/Thr phosphorylation sites: Thr 50, Thr 141, Ser 304, Thr 451, and Ser 506 (human PKCdelta numbering) following overexpression of PKCdelta in HCT116 human colon carcinoma cells grown in standard tissue culture conditions. Identification of potential novel phosphorylation sites will affect further functional studies of this protein, and may introduce additional complexity to PKCdelta signaling.     

Regulation of NDR protein kinase by hydrophobic motif phosphorylation mediated by the mammalian Ste20-like kinase MST3

NDR protein kinases are involved in the regulation of cell cycle progression and morphology. NDR1/NDR2 protein kinase is activated by phosphorylation on the activation loop phosphorylation site Ser281/Ser282 and the hydrophobic motif phosphorylation site Thr444/Thr442. Autophosphorylation of NDR is responsible for phosphorylation on Ser281/Ser282, whereas Thr444/Thr442 is targeted by an upstream kinase. Here we show that MST3, a mammalian Ste20-like protein kinase, is able to phosphorylate NDR protein kinase at Thr444/Thr442. In vitro, MST3 selectively phosphorylated Thr442 of NDR2, resulting in a 10-fold stimulation of NDR activity. MOB1A (Mps one binder 1A) protein further increased the activity, leading to a fully active kinase. In vivo, Thr442 phosphorylation after okadaic acid stimulation was potently inhibited by MST3KR, a kinase-dead mutant of MST3. Knockdown of MST3 using short hairpin constructs abolished Thr442 hydrophobic motif phosphorylation of NDR in HEK293F cells. We conclude that activation of NDR is a multistep process involving phosphorylation of the hydrophobic motif site Thr444/2 by MST3, autophosphorylation of Ser281/2, and binding of MOB1A.     

Protein kinase Cepsilon (PKCepsilon) and Src control PKCdelta activation loop phosphorylation in cardiomyocytes

Protein kinase Cdelta (PKCdelta) is unusual among AGC kinases in that it does not require activation loop (Thr(505)) phosphorylation for catalytic competence. Nevertheless, Thr(505) phosphorylation has been implicated as a mechanism that influences PKCdelta activity. This study examines the controls of PKCdelta-Thr(505) phosphorylation in cardiomyocytes. We implicate phosphoinositide-dependent kinase-1 and PKCdelta autophosphorylation in the "priming" maturational PKCdelta-Thr(505) phosphorylation that accompanies de novo enzyme synthesis. In contrast, we show that PKCdelta-Thr(505) phosphorylation dynamically increases in cardiomyocytes treated with phorbol 12-myristate 13-acetate or the alpha(1)-adrenergic receptor agonist norepinephrine via a mechanism that requires novel PKC isoform activity and not phosphoinositide-dependent kinase-1. We used a PKCepsilon overexpression strategy as an initial approach to discriminate two possible novel PKC mechanisms, namely PKCdelta-Thr(505) autophosphorylation and PKCdelta-Thr(505) phosphorylation in trans by PKCepsilon. Our studies show that adenovirus-mediated PKCepsilon overexpression leads to an increase in PKCdelta-Thr(505) phosphorylation. However, this cannot be attributed to an effect of PKCepsilon to function as a direct PKCdelta-Thr(505) kinase, since the PKCepsilon-dependent increase in PKCdelta-Thr(505) phosphorylation is accompanied by (and dependent upon) increased PKCdelta phosphorylation at Tyr(311) and Tyr(332). Further studies implicate Src in this mechanism, showing that 1) PKCepsilon overexpression increases PKCdelta-Thr(505) phosphorylation in cardiomyocytes and Src(+) cells but not in SYF cells (that lack Src, Yes, and Fyn and exhibit a defect in PKCdelta-Tyr(311)/Tyr(332) phosphorylation), and 2) in vitro PKCdelta-Thr(505) autophosphorylation is augmented in assays performed with Src (which promotes PKCdelta-Tyr(311)/Tyr(332) phosphorylation). Collectively, these results identify a novel PKCdelta-Thr(505) autophosphorylation mechanism that is triggered by PKCepsilon overexpression and involves Src-dependent PKCdelta-Tyr(311)/Tyr(332) phosphorylation.     

Human biliverdin reductase, a previously unknown activator of protein kinase C betaII

Human biliverdin reductase (hBVR), a dual specificity kinase (Ser/Thr/Tyr) is, as protein kinase C (PKC) betaII, activated by insulin and free radicals (Miralem, T., Hu, Z., Torno, M. D., Lelli, K. M., and Maines, M. D. (2005) J. Biol. Chem. 280, 17084-17092; Lerner-Marmarosh, N., Shen, J., Torno, M. D., Kravets, A., Hu, Z., and Maines, M. D. (2005) Proc. Natl. Acad. Sci. U. S. A. 102, 7109-7114). Here, by using 293A cells co-transfected with pcDNA3-hBVR and PKC betaII plasmids, we report the co-immunoprecipitation of the proteins and co-purification in the glutathione S-transferase (GST) pulldown assay. hBVR and PKC betaII, but not the reductase and PKC zeta, transphosphorylated in assay systems supportive of activity of only one of the kinases. PKC betaII K371R mutant protein ("kinase-dead") was also a substrate for hBVR. The reductase increased the Vmax but not the apparent Km values of PKC betaII for myelin basic protein; activation was independent of phospholipids and extended to the phosphorylation of S2, a PKC-specific substrate. The increase in substrate phosphorylation was blocked by specific inhibitors of conventional PKCs and attenuated by sihBVR. The effect of the latter could be rescued by subsequent overexpression of hBVR. To a large extent, the activation was a function of the hBVR N-terminal chain of valines and intact ATP-binding site and the cysteine-rich C-terminal segment. The cobalt protoporphyrin-activated hBVR phosphorylated a threonine in a peptide corresponding to the Thr500 in the human PKC betaII activation loop. Neither serine nor threonine residues in peptides corresponding to other phosphorylation sites of the PKC betaII nor PKC zeta activation loop-derived peptides were substrates. The phosphorylation of Thr500 was confirmed by immunoblotting of hBVR.PKC betaII immunocomplex. The potential biological relevance of the hBVR activation of PKC betaII was suggested by the finding that in cells transfected with the PKC betaII, hBVR augmented phorbol myristate acetate-mediated c-fos expression, and infection with sihBVR attenuated the response. Also, in cells overexpressing hBVR and PKC betaII, as well as in untransfected cells, upon treatment with phorbol myristate acetate, the PKC translocated to the plasma membrane and co-localized with hBVR. hBVR activation of PKC betaII underscores its potential function in propagation of signals relayed through PKCs.     

Phosphoregulation of mixed-lineage kinase 1 activity by multiple phosphorylation in the activation loop

Mixed-lineage kinase 1 (MLK1) is a mitogen-activated protein kinase kinase kinase capable of activating the c-Jun NH(2)-terminal kinase (JNK) pathway. Full-length MLK1 has 1104 amino acids and a domain structure identical to MLK2 and MLK3. Immunoblot and mass spectrometry show that MLK1 is threonine (and possibly serine) phosphorylated in or near the activation loop. A kinase-dead mutant is not, consistent with autophosphorylation. Mutation to alanine of any of the four serine or threonine residues in the activation loop reduces both the activity of the recombinant kinase domain and JNK pathway activation driven by full-length MLK1 expressed in mammalian cells. Furthermore, the gel mobility of the mutant MLK1s is closer to that of the kinase-dead than wild type, consistent with reduced phosphorylation. Thr312 is the key residue: MLK1[T312A] retains only basal activity (about 1-2% of wild type), and its gel mobility is indistinguishable from kinase-dead. Thr312 does not suffice, however; phosphorylation of multiple sites is necessary for full activation of MLK1. An activation mechanism consistent with these data involves phosphorylation of multiple sites in the activation loop, with phosphorylation of Thr312 required for full phosphorylation. This mechanism is broadly similar to that previously reported for MLK3 [Leung, I. W., and Lassam, N. (2001) J. Biol. Chem. 276, 1961-1967], but the key residue differs.     

Regulation of protein kinase C delta by phorbol ester, endothelin-1, and platelet-derived growth factor in cardiac myocytes

Protein kinase C (PKC) delta is regulated allosterically by phosphatidylserine and diacylglycerol (which promote its translocation to the membrane) and by phosphorylation of Ser/Thr and Tyr residues. Although phosphorylation on Thr-505/Ser-643/Ser-662 may simply "prime" PKCdelta for activation, it could be regulatory. We examined the regulation of PKCdelta in cardiac myocytes by endothelin-1 (Gq protein-coupled receptor agonist) and platelet-derived growth factor (receptor tyrosine kinase agonist) in comparison with phorbol 12-myristate 13-acetate (PMA). All increased phosphorylation of PKCdelta(Thr-505/Ser-643) and of Tyr residues, although to differing extents. De novo phosphorylation occurred mainly after translocation of PKCdelta to the particulate fraction, and phosphorylations of Thr-505/Ser-643 versus Tyr residues were essentially independent events. Following chromatographic separation of the PKCdelta subspecies, activities were correlated with immunoreactivity profiles of total and phosphorylated forms. In unstimulated cells, approximately 25% of PKCdelta lacked phosphorylation of Thr-505/Ser-643 and displayed minimal activity (assayed in the presence of phosphatidylserine/PMA following chromatography). Endothelin-1 or PMA (10 min) promoted Thr-505/Ser-643 phosphorylation of this pool, and this was associated with an increase in total recoverable PKCdelta activity. Meanwhile, in cells exposed to endothelin-1 or PMA, the overall pool of PKCdelta translocated rapidly (30 s) to the particulate fraction and was phosphorylated on Tyr residues. This was associated with an increase in lipid-independent activity (i.e. the phosphatidylserine/PMA requirement disappeared). For endothelin-1, Tyr phosphorylation of PKCdelta and the increase in phosphatidylserine/PMA-independent activity persisted after PKCdelta retrotranslocated to the soluble fraction. We concluded that, with this physiological agonist, PKCdelta becomes activated in the particulate fraction but retains activity following its retrotranslocation, presumably to phosphorylate substrates elsewhere.     

Substitution of the autophosphorylation site Thr516 with a negatively charged residue confers constitutive activity to mouse 3-phosphoinositide-dependent protein kinase-1 in cells

3-Phosphoinositide-dependent protein kinase-1 (PDK-1)is a serine/threonine kinase that has been found to phosphorylate and activate several members of the AGC protein kinase family including protein kinase B (Akt), p70 S6 kinase, and protein kinase Czeta. However, the mechanism(s) by which PDK-1 is regulated remains unclear. Here we show that mouse PDK-1 (mPDK-1) undergoes autophosphorylation in vitro on both serine and threonine residues. In addition, we have identified Ser(399) and Thr(516) as the major mPDK-1 autophosphorylation sites in vitro. Furthermore, we have found that these two residues, as well as Ser(244) in the activation loop, are phosphorylated in cells and demonstrated that Ser(244) is a major in vivo phosphorylation site. Abolishment of phosphorylation at Ser(244), but not at Ser(399) or Thr(516), led to a significant decrease of mPDK-1 autophosphorylation and kinase activity in vitro, indicating that autophosphorylation at Ser(399) or Thr(516) is not essential for mPDK-1 autokinase activity. However, overexpression of mPDK-1(T516E), but not of mPDK-1(S244E) or mPDK-1(S399D), in Chinese hamster ovary and HEK293 cells was sufficient to induce Akt phosphorylation at Thr(308) to a level similar to that of insulin stimulation. Furthermore, this increase in phosphorylation was independent of the Pleckstrin homology domain of Akt. Taken together, our results suggest that mPDK-1 undergoes autophosphorylation at multiple sites and that this phosphorylation may be essential for PDK-1 to interact with and phosphorylate its downstream substrates in vivo.     

Interleukin-1 stimulated activation of the COT catalytic subunit through the phosphorylation of Thr290 and Ser62

The protein kinase COT/Tpl2 is activated by interleukin-1 (IL-1), TNFalpha and lipopolysaccharide, and its activation by these agonists involves the IkappaB kinase beta (IKKbeta) catalysed phosphorylation of the p105 regulatory subunit. Here, we show that COT activation also requires catalytic subunit phosphorylation, since IL-1beta induced a 5-10-fold activation of a COT mutant unable to bind p105. Activation was paralleled by the phosphorylation of Thr290 and Ser62 and unaffected by the IKKbeta inhibitor PS1145 at concentrations which prevented the degradation of IkappaBalpha. Mutagenesis experiments indicated that COT activation is initiated by Thr290 phosphorylation catalysed by an IL-1-stimulated protein kinase distinct from IKKbeta, while Ser62 phosphorylation is an autophosphorylation event required for maximal activation.     

Mechanism of inhibition of sequestration of protein kinase C alpha/betaII by ceramide. Roles of ceramide-activated protein phosphatases and phosphorylation/dephosphorylation of protein kinase C alpha/betaII on threonine 638/641

Sustained activation of protein kinase C (PKC) isoenzymes alpha and betaII leads to their translocation to a perinuclear region and to the formation of the pericentrion, a PKC-dependent subset of recycling endosomes. In MCF-7 human breast cancer cells, the action of the PKC activator 4beta-phorbol-12-myristate-13-acetate (PMA) evokes ceramide formation, which in turn prevents PKCalpha/betaII translocation to the pericentrion. In this study we investigated the mechanisms by which ceramide negatively regulates this translocation of PKCalpha/betaII. Upon PMA treatment, HEK-293 cells displayed dual phosphorylation of PKCalpha/betaII at carboxyl-terminal sites (Thr-638/641 and Ser-657/660), whereas in MCF-7 cells PKCalpha/betaII were phosphorylated at Ser-657/660 but not Thr-638/641. Inhibition of ceramide synthesis by fumonisin B1 overcame the defect in PKC phosphorylation and restored translocation of PKCalpha/betaII to the pericentrion. To determine the involvement of ceramide-activated protein phosphatases in PKC regulation, we employed small interference RNA to silence individual Ser/Thr protein phosphatases. Knockdown of isoforms alpha or beta of the catalytic subunits of protein phosphatase 1 not only increased phosphorylation of PKCalpha/betaII at Thr-638/641 but also restored PKCbetaII translocation to the pericentrion. Mutagenesis approaches in HEK-293 cells revealed that mutation of either Thr-641 or Ser-660 to Ala in PKCbetaII abolished sequestration of PKC, implying the indispensable roles of phosphorylation of PKCalpha/betaII at those sites for their translocation to the pericentrion. Reciprocally, a point mutation of Thr-641 to Glu, which mimics phosphorylation, in PKCbetaII overcame the inhibitory effects of ceramide on PKC translocation in PMA-stimulated MCF-7 cells. Therefore, the results demonstrate a novel role for carboxyl-terminal phosphorylation of PKCalpha/betaII in the translocation of PKC to the pericentrion, and they disclose specific regulation of PKC autophosphorylation by ceramide through the activation of specific isoforms of protein phosphatase 1.     

Autophosphorylation of threonine 485 in the activation loop is essential for attaining eIF2alpha kinase activity of HRI

In heme deficiency, protein synthesis is inhibited by the activation of the heme-regulated eIF2alpha kinase (HRI) through its multiple autophosphorylation. Autophosphorylation sites in HRI were identified in order to investigate their functions. We found that there were eight major tryptic phosphopeptides of HRI activated in heme deficiency. In this report we focused on the role of autophosphorylation at Thr483 and Thr485 in the activation loop of HRI. Disruption of the autophosphorylation of Thr485, but not Thr483, resulted in a lower autokinase activity and locked Thr485Ala HRI in a hypophosphorylated state. Most importantly, autophosphorylation of Thr485, but not Thr483, was essential for attaining eIF2alpha kinase activity of HRI. In addition, autophosphorylation of Thr485 was necessary for arsenite-induced activation of the eIF2alpha kinase activity of HRI, while autophosphorylation at Thr483 was not required for activation by arsenite. The function of Thr490, another conserved Thr residue in the activation loop of HRI, was also investigated. Mutations of Thr490 to either Ala or Asp resulted in reduced autokinase activity and loss of eIF2alpha kinase activity in heme deficiency or upon arsenite treatment. Since Thr490 was not identified as an autophosphorylated site, it is likely that Thr490 itself might be critical for the catalytic activity of HRI. Importantly, Thr485 was very poorly phosphorylated in Thr490 mutant HRI. Collectively, our results demonstrate that autophosphorylation of Thr485 is essential for the hyperphosphorylation and activation of HRI and is required for the acquisition of the eIF2alpha kinase activity.     

Regulatory mechanism of Dictyostelium myosin light chain kinase A

In this study, we examined the activation mechanism of Dictyostelium myosin light chain kinase A (MLCK-A) using constitutively active Ca2+/calmodulin-dependent protein kinase kinase as a surrogate MLCK-A kinase. MLCK-A was phosphorylated at Thr166 by constitutively active Ca2+/calmodulin-dependent protein kinase kinase, resulting in an approximately 140-fold increase in catalytic activity, using intact Dictyostelium myosin II. Recombinant Dictyostelium myosin II regulatory light chain and Kemptamide were also readily phosphorylated by activated MLCK-A. Mass spectrometry analysis revealed that MLCK-A expressed by Escherichia coli was autophosphorylated at Thr289 and that, subsequent to Thr166 phosphorylation, MLCK-A also underwent a slow rate of autophosphorylation at multiple Ser residues. Using site-directed mutagenesis, we show that autophosphorylation at Thr289 is required for efficient phosphorylation and activation by an upstream kinase. By performing enzyme kinetics analysis on a series of MLCK-A truncation mutants, we found that residues 283-288 function as an autoinhibitory domain and that autoinhibition is fully relieved by Thr166 phosphorylation. Simple removal of this region resulted in a significant increase in the kcat of MLCK-A; however, it did not generate maximum enzymatic activity. Together with the results of our kinetic analysis of the enzymes, these findings demonstrate that Thr166 phosphorylation of MLCK-A by an upstream kinase subsequent to autophosphorylation at Thr289 results in generation of maximum MLCK-A activity through both release of an autoinhibitory domain from its catalytic core and a further increase (15-19-fold) in the kcat of the enzyme.     

Insulin receptor kinase domain autophosphorylation regulates receptor enzymatic function.

We have studied a series of insulin receptor molecules in which the 3 tyrosine residues which undergo autophosphorylation in the kinase domain of the beta-subunit (Tyr1158, Tyr1162, and Tyr1163) were replaced individually, in pairs, or all together with phenylalanine or serine by in vitro mutagenesis. A single-Phe replacement at each of these three positions reduced insulin-stimulated autophosphorylation of solubilized receptor by 45-60% of that observed with wild-type receptor. The double-Phe replacements showed a 60-70% reduction, and substitution of all 3 tyrosine residues with Phe or Ser reduced insulin-stimulated tyrosine autophosphorylation by greater than 80%. Phosphopeptide mapping each mutant revealed that all remaining tyrosine autophosphorylation sites were phosphorylated normally following insulin stimulation, and no new sites appeared. The single-Phe mutants showed insulin-stimulated kinase activity toward a synthetic peptide substrate of 50-75% when compared with wild-type receptor kinase activity. Insulin-stimulated kinase activity was further reduced in the double-Phe mutants and barely detectable in the triple-Phe mutants. In contrast to the wild-type receptor, all of the mutant receptor kinases showed a significant reduction in activation following in vitro insulin-stimulated autophosphorylation. When studied in intact Chinese hamster ovary cells, insulin-stimulated receptor autophosphorylation and tyrosine phosphorylation of the cellular substrate pp185 in the single-Phe and double-Phe mutants was progressively lower with increased tyrosine replacement and did not exceed the basal levels in the triple-Phe mutants. However, all the mutant receptors, including the triple-Phe mutant, retained the ability to undergo insulin-stimulated Ser and Thr phosphorylation. Thus, full activation of the insulin receptor tyrosine kinase is dependent on insulin-stimulated Tris phosphorylation of the kinase domain, and the level of autophosphorylation in the kinase domain provides a mechanism for modulating insulin receptor kinase activity following insulin stimulation. By contrast, insulin stimulation of receptor phosphorylation on Ser and Thr residues by cellular serine/threonine kinases can occur despite markedly reduced tyrosine autophosphorylation.