Thermodynamics of nucleotide and non-ATP-competitive inhibitor binding to MEK1 by circular dichroism and isothermal titration calorimetry

MEK1 is a member of the MAPK signal transduction pathway that responds to growth factors and cytokines. A wealth of information about the enzymatic activity of MEK1, its domain functions, and inhibitor action is available; however, the thermodynamic properties of the interaction between MEK1 and ligands, such as nucleotides and non-ATP-competitive inhibitors, have not been reported. This study describes the thermodynamic parameters for the binding interactions of MEK1, nucleotides, and non-ATP-competitive inhibitor complexes using temperature-dependent circular dichroism (TdCD) and isothermal titration calorimetry (ITC). Non-phosphorylated MEK1 (npMEK1) has a high affinity for both AMP-PNP and ADP (Kd approximately 2microM). The binding is enthalpically favored and Mg-dependent. The active, phosphorylated form of MEK1 (pMEK1) bound nucleotides with a similar high affinity (Kd approximately 2muM) and had a thermodynamic profile and Mg-dependence similar to that of the non-phosphorylated form. The non-ATP-competitive MEK1 inhibitors, U0126 and PD0325901, showed no preference for npMEK1 and pMEK1 by TdCD. TdCD results also showed that these inhibitors are more potent in the presence of the nucleotide than in its absence. The ternary complex, MEK1.PD0325901.nucleotide, showed synergistic binding as evidenced by a large, non-additive shift in the midpoint of the protein unfolding transition (Tm). This was apparent for both npMEK1 and pMEK1 using either ADP or AMP-PNP. ITC binding studies confirmed the synergistic binding effect. The ITC-determined affinity of nucleotide (AMP-PNP, ADP) binding to the npMEK1.PD0325901 complex was enhanced nearly 5-fold compared to nucleotide binding to npMEK1 alone. In addition, the affinity of PD0325901 binding to npMEK1.nucleotide complexes was increased nearly 10-fold relative to the affinity of PD0325901 for npMEK1 alone. These are the first thermodynamic binding studies that characterize the affinity of the allosteric non-ATP-competitive inhibitors U0126 and PD0325901 with and without the nucleotide. The results indicate these allosteric inhibitors have a dynamic range in the type of MEK1 activation states and nucleotide complexes that they can bind.     

RAF associates with phosphorylated nuclear BubR1 during endoreduplication induced by JAK inhibition

The role of JAK signaling in cell cycle transit and maintenance of genomic stability was determined in HL-60 human myeloblastic leukemia cells. We have previously reported that a pan-JAK inhibitor caused ERK-dependent endoreduplication. In the current study we find that JAK inhibition caused nuclear re-localization of RAF-1, which could be inhibited by RAF inhibitor GW5074. GW5074 also inhibited JAK inhibitor-induced appearance of nuclear phosphorylated RAF-1(pS621RAF) and MEK, and it inhibited the JAK inhibitor-induced co-immunoprecipitation of nuclear RAF-1 and MEK. JAK inhibition also increased nuclear BubR1 phosphorylation, which was diminished by RAF inhibitor GW5074. RAF-1 and BubR1 in the nucleus co-immunoprecipitated; and GW5074 eliminated this. Furthermore, inhibiting RAF with GW5074 blocked the pan-JAK inhibitor-induced endoreduplication. These data thus show that JAK inhibition causes nuclear re-localization and phosphorylation of RAF and MEK where RAF binds BubR1 with ensuing nuclear RAF-dependent BubR1 phosphorylation. Inhibiting RAF inhibited this and endoreduplication. The results suggest that there is a JAK/RAF/MEK/BubR1 axis that can regulate genomic stability. In this hypothetical model JAK suppresses RAF/MEK phosphorylation and nuclear re-localization, but JAK inhibition induces the phosphorylations and re-localization with association of RAF and phosphorylated BubR1 in the nucleus leading to endoreduplication.     

Role of RAF/MEK/ERK pathway,p‐STAT‐3 and Mcl‐1 in sorafenib activity in human pancreatic cancer cell lines

Sorafenib is a multikinase inhibitor that has shown promising therapeutic results in different tumor histotypes, both as a single agent or in combination with other treatments. We analyzed the in vitro activity of sorafenib in pancreatic cancer, one of the most lethal and chemo‐radio‐resistant tumors, using four human pancreatic cancer cell lines (t3m4, Capan 1, Capan 2, and MiaPaca 2), characterized by different K‐ras gene status and RAF/MEK/ERK profile. Sorafenib exerted a strong anti‐proliferative effect independently of RAS/RAF/MEK/ERK and induced various degrees of apoptosis in the cell lines. The mechanisms involved were explored in detail in t3m4 and Capan 1, in which sorafenib induced the highest and lowest levels of apoptosis, respectively. In t3m4, the RAF/AKT/STAT‐3 rather than the RAF/MEK/ERK pathway was involved, whereas in Capan 1 cells there was a strong decrease in pMEK and pERK which was not accompanied by an important reduction in RAF, AKT, and STAT‐3 proteins or in their phosphorylation. Moreover, U0126‐induced MEK inhibition did not induce apoptosis in any cell line, reinforcing the hypothesis of a MEK/ERK‐independent mechanism of sorafenib activity. Mcl‐1 appears to play a crucial role in sorafenib‐induced apoptosis. In fact, both protein and mRNA were downregulated in t3m4 and upregulated in Capan 1, in which siRNA‐induced silencing resulted in the same level of apoptosis as observed in t3m4. Our results show that sorafenib exerts anti‐proliferative and pro‐apoptotic activity in pancreatic cancer cells. Used singly or in combination with other drugs, it could therefore represent valid treatment for pancreatic cancer. J. Cell. Physiol. 220: 214–221, 2009. © 2009 Wiley‐Liss, Inc.     

RAF associates with phosphorylated nuclear BubR1 during endoreduplication induced by JAK inhibition

The role of JAK signaling in cell cycle transit and maintenance of genomic stability was determined in HL-60 human myeloblastic leukemia cells. We have previously reported that a pan-JAK inhibitor caused ERK-dependent endoreduplication. In the current study we find that JAK inhibition caused nuclear re-localization of RAF-1, which could be inhibited by RAF inhibitor GW5074. GW5074 also inhibited JAK inhibitor-induced appearance of nuclear phosphorylated RAF-1(pS621RAF) and MEK, and it inhibited the JAK inhibitor-induced co-immunoprecipitation of nuclear RAF-1 and MEK. JAK inhibition also increased nuclear BubR1 phosphorylation, which was diminished by RAF inhibitor GW5074. RAF-1 and BubR1 in the nucleus co-immunoprecipitated; and GW5074 eliminated this. Furthermore, inhibiting RAF with GW5074 blocked the pan-JAK inhibitor-induced endoreduplication. These data thus show that JAK inhibition causes nuclear re-localization and phosphorylation of RAF and MEK where RAF binds BubR1 with ensuing nuclear RAF-dependent BubR1 phosphorylation. Inhibiting RAF inhibited this and endoreduplication. The results suggest that there is a JAK/RAF/MEK/BubR1 axis that can regulate genomic stability. In this hypothetical model JAK suppresses RAF/MEK phosphorylation and nuclear re-localization, but JAK inhibition induces the phosphorylations and re-localization with association of RAF and phosphorylated BubR1 in the nucleus leading to endoreduplication.Key words: endoreduplication, JAK, genomic instability, MAPK, HL-60 cells     

Expression and purification of phosphorylated and non-phosphorylated human MEK1

Kinases exist in either a high or low activity form depending on the phosphorylation state of the activating lip. These two different forms of the same kinase may adopt different conformations that affect not only activity but also inhibitor binding and the ability to crystallize the protein. Therefore, isolation of homogenous preparations of the phosphorylated and non-phosphorylated versions of a kinase is critical for accurate biophysical measurements of activity, stability and ligand binding as well as for protein crystallization. The aim of the present study is the expression, purification and characterization of recombinant human MEK1 protein in both the activated and low-activity states. A baculovirus co-expression system was developed for obtaining high levels of activated, phosphorylated human MEK1 kinase. High-Five cells were co-infected with human MEK1 virus and Raf-BXB, an untagged constitutively active version of Raf which is the activating kinase for MEK1. Unphosphorylated MEK1 was generated by treating MEK1 isolated from High-Five baculovirus expression with lambda-phosphatase. The proteins were characterized by SDS-PAGE, LC-MS, Western blotting, enzymatic activity, and circular dichroism. Previous reports of MEK1 expression and purification yielded lower levels of protein and purity. The yield using High-Five cells was 5mg/L for phosphorylated MEK1 and 10mg/L for unphosphorylated MEK1. For phosphorylated MEK1, the specific activity was 3530U/mg, the IC(50) values for the non-specific kinase inhibitors K252a and K252b were 8 and 47nM, respectively, and the IC(50) for the MEK1 non-ATP competitive inhibitor, PD0325901, was 43nM.     

The RAS Effector RIN1 Directly Competes with RAF and Is Regulated by 14-3-3 Proteins

Activation of RAS proteins can lead to multiple outcomes by virtue of regulated signal traffic through alternate effector pathways. We demonstrate that the RAS effector protein RIN1 binds to activated RAS with an affinity (K(d), 22 nM) similar to that observed for RAF1. At concentrations close to their equilibrium dissociation constant values, RIN1 and RAF1 compete directly for RAS binding. RIN1 was also observed to inhibit cellular transformation by activated mutant RAS. This distinguishes RIN1 from other RAS effectors, which are transformation enhancing. Blockade of transformation was mediated by the RAS binding domain but required membrane localization. RIN1 recognizes endogenous RAS following transient activation by epidermal growth factor, and a portion of RIN1 fractionates to the cell membrane in a manner consistent with a reversible interaction. RIN1 also binds to 14-3-3 proteins through a sequence including serine 351. Mutation of this residue abolished the 14-3-3 binding capacity of RIN1 and led to more efficient blockade of RAS-mediated transformation. The mutant protein, RIN1(S351A), showed a shift in localization to the plasma membrane. Serine 351 is a substrate for protein kinase D (PKD [also known as PKCmu]) in vitro and in vivo. These data suggest that the normal localization and function of RIN1, as well as its ability to compete with RAF, are regulated in part by 14-3-3 binding, which in turn is controlled by PKD phosphorylation.     

Retinoic acid causes MEK-dependent RAF phosphorylation through RARα plus RXR activation in HL-60 cells

Retinoic acid (RA) is known to cause the myeloid differentiation of HL-60 human myeloblastic leukemia cells in a process requiring MEK-dependent ERK2 activation. This RA-induced ERK2 activation appears after approximately 4 h and persists until the cells are differentiated and G0 arrested (Yen et al, 1998). This motivates the question of whether RA also activated RAF as part of a typical RAF/MEK/MAPK cascade. Retinoic acid is shown here to also increase the phosphorylation of RAF, but in an unusual way. Surprisingly, increased RAF phosphorylation is first detectable after 12 to 24 hours by phosphorylation-induced retardation of polyacrylamide gel electrophoretic mobility. The RA-induced increased RAF phosphorylation is still apparent after 72 hours of treatment when most cells are differentiated and G0 arrested. There is a progressive dose-response relationship with 10(-8), 10(-7), and 10(-6) M RA. The RA-induced RAF phosphorylation corresponds to increased in vitro kinase activity. Inhibition of MEK with a PD98059 dose which inhibits ERK2 phosphorylation and subsequent cell differentiation also inhibits RAF phosphorylation. RA-induced MEK-dependent RAF phosphorylation is not due to changes in the amount of cellular MEK. The induced RAF phosphorylation, as well as anteceding ERK2 activation, depends on ligand-induced activation of both an RARalpha receptor and an RXR receptor. This and the slow kinetics of activation suggest a need for prior RA-induced gene expression. In summary, RA induces a MEK-dependent prolonged RAF activation, whose slow onset occurs after ERK2 activation but still well before cell cycle arrest and cell differentiation. The RA-induced increased RAF phosphorylation thus differs from typical mitogenic growth factor signaling, features that may contribute to cell cycle arrest and differentiation instead of division as the cellular outcome.     

Substrate phosphorylation specificity of the human c-kit receptor tyrosine kinase.

The chimeric EK-receptor (EK-R), consisting of the epidermal growth factor receptor (EGF-R) extracellular binding domain and p145c-kit cytoplasmic signal-generating sequences, was fully functional in forming high and low affinity EGF binding sites and in ligand-regulated receptor and substrate phosphorylation activities. Relative to EGF-R, EK-R activation stimulated kit-characteristic phosphorylation of human 293 fibroblast substrate polypeptides. Transient coexpression of EK-R with candidate substrates resulted in ligand-induced phosphorylation of phospholipase C gamma and guanosine triphosphatase-activating polypeptide. The RAF-1 serine/threonine kinase was shown to be associated with activated EK-R, but no tyrosine phosphorylation could be detected. The faithfulness of EK-R substrate phosphorylation specificity was confirmed with stem cell factor-stimulated p145c-kit.     

Mitogen-activated protein kinase kinase 1 (MEK1) stabilizes MyoD through direct phosphorylation at tyrosine 156 during myogenic differentiation

Previously, we reported that mitogen-activated protein kinase kinase 1 (MEK1) activated in the mid-stage of skeletal muscle differentiation promotes myogenic differentiation. To elucidate the molecular mechanism, we investigated an activity of MEK1 for MyoD. Activated MEK1 associates with MyoD in the nucleus of differentiating myoblasts. In vitro kinase assay using active MEK1, a (32)P-labeled protein band corresponding to GST-MyoD was observed but not to mutant GST-MyoD-Y156F. Tyrosine phosphorylation of endogenous MyoD was detected with a specific anti-pMyoD-Y156 antibody; however, this response was blocked by PD184352, a MEK-specific inhibitor. These results indicate that activated MEK1 phosphorylates the MyoD-Y156 residue directly. Interestingly, the protein level of mutant MyoD-Y156F decreased compared with that of wild type but was recovered in the presence of lactacystin, a proteasome inhibitor. The protein level of MyoD-Y156E, which mimics phosphorylation at Tyr-156, was above that of wild type, indicating that the phosphorylation protects MyoD from the ubiquitin proteasome-mediated degradation. In addition, the low protein level of MyoD-Y156F was recovered over that of wild type by an additional mutation at Leu-164, a critical binding residue of MAFbx/AT-1, a Skp, Cullin, F-box (SCF) E3-ubiquitin ligase. The amount of MyoD co-precipitated with MAFbx/AT-1 also was reduced in the presence of active MEK1. Thus, these results suggested that the phosphorylation probably interrupts the binding of MAFbx/AT-1 to MyoD and thereby increases its stability. Collectively, our results suggest that MEK1 activated in differentiating myoblasts stimulates muscle differentiation by phosphorylating MyoD-Y156, which results in MyoD stabilization.     

Negative regulation of MAPKK by phosphorylation of a conserved serine residue equivalent to Ser212 of MEK1

The MAPKKs MEK1 and MEK2 are activated by phosphorylation, but little is known about how these enzymes are inactivated. Here, we show that MEK1 is phosphorylated in vivo at Ser(212), a residue conserved among all MAPKK family members. Mutation of Ser(212) to alanine enhanced the basal activity of MEK1, whereas the phosphomimetic aspartate mutation completely suppressed the activation of both wild-type MEK1 and the constitutively activated MEK1(S218D/S222D) mutant. Phosphorylation of Ser(212) did not interfere with activating phosphorylation of MEK1 at Ser(218)/Ser(222) or with binding to ERK2 substrate. Importantly, mimicking phosphorylation of the equivalent Ser(212) residue of the yeast MAPKKs Pbs2p and Ste7p similarly abrogated their biological function. Our findings suggest that Ser(212) phosphorylation represents an evolutionarily conserved mechanism involved in the negative regulation of MAPKKs.     

MEK kinase 3 directly activates MKK6 and MKK7, specific activators of the p38 and c-Jun NH2-terminal kinases.

Mitogen-activated protein kinase (MAPK)/extracellular signal-regulated kinase kinase kinase 3 (MEKK3) activates the c-Jun NH2-terminal kinase (JNK) pathway, although no substrates for MEKK3 have been identified. We have examined the regulation by MEKK3 of MAPK kinase 7 (MKK7) and MKK6, two novel MAPK kinases specific for JNK and p38, respectively. Coexpression of MKK7 with MEKK3 in COS-7 cells enhanced MKK7 autophosphorylation and its ability to activate recombinant JNK1 in vitro. MKK6 autophosphorylation and in vitro activation of p38alpha were also observed following coexpression of MKK6 with MEKK3. MEKK2, a closely related homologue of MEKK3, also activated MKK7 and MKK6 in COS-7 cells. Importantly, immunoprecipitates of either MEKK3 or MEKK2 directly activated recombinant MKK7 and MKK6 in vitro. These data identify MEKK3 as a MAPK kinase kinase specific for MKK7 and MKK6 in the JNK and p38 pathways. We have also examined whether MEKK3 or MEKK2 activates p38 in intact cells using MAPK-activated protein kinase-2 (MAPKAPK2) as an affinity ligand and substrate. Anisomycin, sorbitol, or the expression of MEKK3 in HEK293 cells enhanced MAPKAPK2 phosphorylation, whereas MEKK2 was less effective. Furthermore, MAPKAPK2 phosphorylation induced by MEKK3 or cellular stress was abolished by the p38 inhibitor SB-203580, suggesting that MEKK3 is coupled to p38 activation in intact cells.     

A Phos‐tag SDS‐PAGE method that effectively uses phosphoproteomic data for profiling the phosphorylation dynamics of MEK1

MEK1, an essential component of the mitogen‐activated protein kinase (MAPK) pathway, is phosphorylated during activation of the pathway; 12 phosphorylation sites have been identified in human MEK1 by MS‐based phosphoproteomic methods. By using Phos‐tag SDS‐PAGE, we found that multiple variants of MEK1 with different phosphorylation states are constitutively present in typical human cells. The Phos‐tag‐based strategy, which makes effective use of existing information on the location of phosphorylation sites, permits quantitative time‐course profiling of MEK1 phosphospecies in their respective phosphorylation states. By subsequent immunoblotting with an anti‐HaloTag antibody, we analyzed a HaloTag‐fused MEK1 protein and 12 potential phosphorylation‐site‐directed mutants of the protein transiently expressed in HEK 293 cells. This strategy revealed that MEK1 is constitutively and mainly phosphorylated at the Thr‐292, Ser‐298, Thr‐386, and Thr‐388 residues in vivo, and that combinations of phosphorylations at these four residues produce at least six phosphorylated variants of MEK1. Like the levels of phosphorylation of the Ser‐218 and Ser‐222 residues by RAF1, which have been well studied, the phosphorylation statuses of Thr‐292, Ser‐298, Thr‐386, and Thr‐388 residues vary widely during activation and deactivation of the MAPK pathway. Furthermore, we demonstrated inhibitor‐specific profiling of MEK1 phosphospecies by using three MEK inhibitors: TAK‐733, PD98059, and U0126.     

Enzyme kinetics and binding studies on inhibitors of MEK protein kinase

Inhibition of the protein kinase, MEK1, is a potential approach for the treatment of cancer. Inhibitors may act by prevention of activation (PoA), which involves interfering with phosphorylation of nonactivated MEK1 by the upstream kinase, B-RAF. Modulation also may occur by inhibition of catalysis (IoC) during phosphorylation of the downstream substrate, ERK2, by activated MEK1. Here, five MEK inhibitors are characterized in terms of binding affinity, PoA, and IoC. The compounds are a butadiene (U-0126), an N-alkoxy amide (CI-1040), two CI-1040 analogues (an anthranilic acid and an N-alkyl amide), and a cyanoquinoline. Some compounds give different mechanisms of inhibition (ATP-competitive, noncompetitive, or uncompetitive) in PoA compared to IoC or show a change in potency between the assays. The inhibitors also exhibit different shifts in potency when either PoA or IoC is compared with binding to nonactivated MEK. The inhibitor potency ranking, therefore, is dependent upon the assay format. When the ATP concentration equals K m, IoC IC 50 increases in the order CI-1040 approximately cyanoquinoline < anthranilic acid approximately U-0126 < alkyl amide. Conversely, the K d from nonactivated MEK1 for four of the compounds varies between more than 6-fold lower and over 18-fold higher than this IC 50, with U-0126 having the lowest K d and CI-1040 having the highest. In PoA when the ATP concentration equals K m, U-0126 has the lowest IC 50, becoming more potent than CI-1040, the cyanoquinoline, and the anthranilic acid. These observations have implications for understanding structure-activity relationships of MEK inhibitors and illustrate how assays can be designed to favor different compounds.     

RAF1-activated MEK1 is found on the Golgi apparatus in late prophase and is required for Golgi complex fragmentation in mitosis

Amitotically activated mitogen-activated protein kinase 1 (MEK1) fragments the pericentriolar Golgi stacks in mammalian cells. We show that activated MEK1 is found on the Golgi apparatus in late prophase. The fragmented and dispersed Golgi membranes in prometaphase and later stages of mitosis do not contain activated MEK1. MEK1-dependent Golgi complex fragmentation is through activation by RAF1 and not MEK1 kinase 1. We propose that a RAF1-dependent activation of MEK1 and its presence on the Golgi apparatus in late prophase is required for Golgi complex fragmentation.     

A novel SND1-BRAF fusion confers resistance to c-Met inhibitor PF-04217903 in GTL16 cells though MAPK activation

Targeting cancers with amplified or abnormally activated c-Met (hepatocyte growth factor receptor) may have therapeutic benefit based on nonclinical and emerging clinical findings. However, the eventual emergence of drug resistant tumors motivates the pre-emptive identification of potential mechanisms of clinical resistance. We rendered a MET amplified gastric cancer cell line, GTL16, resistant to c-Met inhibition with prolonged exposure to a c-Met inhibitor, PF-04217903 (METi). Characterization of surviving cells identified an amplified chromosomal rearrangement between 7q32 and 7q34 which overexpresses a constitutively active SND1-BRAF fusion protein. In the resistant clones, hyperactivation of the downstream MAPK pathway via SND1-BRAF conferred resistance to c-Met receptor tyrosine kinase inhibition. Combination treatment with METi and a RAF inhibitor, PF-04880594 (RAFi) inhibited ERK activation and circumvented resistance to either single agent. Alternatively, treatment with a MEK inhibitor, PD-0325901 (MEKi) alone effectively blocked ERK phosphorylation and inhibited cell growth. Our results suggest that combination of a c-Met tyrosine kinase inhibitor with a BRAF or a MEK inhibitor may be effective in treating resistant tumors that use activated BRAF to escape suppression of c-Met signaling.     

p66shc inhibits pro-survival epidermal growth factor receptor/ERK signaling during severe oxidative stress in mouse renal proximal tubule cells

The fully executed epidermal growth factor receptor (EGFR)/Ras/MEK/ERK pathway serves a pro-survival role in renal epithelia under moderate oxidative stress. We and others have demonstrated that during severe oxidative stress, however, the activated EGFR is disconnected from ERK activation in cultured renal proximal tubule cells and also in renal proximal tubules after ischemia/reperfusion injury, resulting in necrotic death. Studies have shown that the tyrosine-phosphorylated p46/52 isoforms of the ShcA family of adaptor proteins connect the activated EGFR to activation of Ras and ERK, whereas the p66(shc) isoform can inhibit this p46/52(shc) function. Here, we determined that severe oxidative stress (after a brief period of activation) terminates activation of the Ras/MEK/ERK pathway, which coincides with ERK/JNK-dependent Ser(36) phosphorylation of p66(shc). Isoform-specific knockdown of p66(shc) or mutation of Ser(36) to Ala, but not to Asp, attenuated severe oxidative stress-mediated ERK inhibition and cell death in vitro. Also, severe oxidative stress (unlike ligand stimulation and moderate oxidative stress, both of which support survival) increased binding of p66(shc) to the activated EGFR and Grb2. This binding dissociated the SOS1 adaptor protein from the EGFR-recruited signaling complex, leading to termination of Ras/MEK/ERK activation. Notably, Ser(36) phosphorylation of p66(shc) and its increased binding to the EGFR also occurred in the kidney after ischemia/reperfusion injury in vivo. At the same time, SOS1 binding to the EGFR declined, similar to the in vitro findings. Thus, the mechanism we propose in vitro offers a means to ameliorate oxidative stress-induced cell injury by either inhibiting Ser(36) phosphorylation of p66(shc) or knocking down p66(shc) expression in vivo.     

CRAF autophosphorylation of serine 621 is required to prevent its proteasome-mediated degradation

The CRAF protein kinase regulates proliferative, differentiation, and survival signals from activated RAS proteins to downstream effectors, most often by inducing MEK/ERK activation. A well-established model of CRAF regulation involves RAS-mediated translocation of CRAF to the plasma membrane, where it is activated by a series of events including phosphorylation. Here we have discovered a new mode of regulation that occurs prior to this step. By creating a kinase-defective version of CRAF in mice or by use of the RAF inhibitor sorafenib, we show that CRAF must first undergo autophosphorylation of serine 621 (S621). Autophosphorylation occurs in cis, does not involve MEK/ERK activation, and is essential to ensure the correct folding and stability of the protein. In the absence of S621 phosphorylation, CRAF is degraded by the proteasome by mechanisms that do not uniquely rely on the E3 ubiquitin ligase CHIP.     

Autophosphorylation and protein kinase C phosphorylation of the epidermal growth factor receptor. Effect on tyrosine kinase activity and ligand binding affinity

The effect of autophosphorylation and protein kinase C-catalyzed phosphorylation on the tyrosine-protein kinase activity and ligand binding affinity of the epidermal growth factor (EGF) receptor has been studied. Kinetic parameters for the phosphorylation by the receptor kinase of synthetic peptide substrates having sequences related to the 3 in vitro receptor autophosphorylation sites (tyrosine residues 1173 (P1), 1148 (P2), and 1068 (P3)) were measured. The Km of peptide P1 (residues 1164-1176) was significantly lower than that for peptides P2 (residues 1141-1151) or P3 (residues 1059-1072). The tyrosine residue 1173 was also the most rapidly autophosphorylated in purified receptor preparations, consistent with previous observations for the receptor in intact cells (Downward, J., Parker, P., and Waterfield, M. D. (1984) Nature 311, 483-485). Variation in the extent of receptor autophosphorylation from 0.1 to 2.8 mol of phosphate/mol of receptor did not influence kinase activity or EGF binding affinity either for purified receptor or receptor in membrane preparations. Phosphorylation of the EGF receptor by protein kinase C was shown to cause a 3-fold decrease in the affinity of purified EGF receptor for EGF and to reduce the receptor kinase activity. In membrane preparations, phosphorylation of the EGF receptor by protein kinase C resulted in conversion of high affinity EGF binding sites to a low affinity state. This suggests that activation of protein kinase C by certain growth promoting agents and tumor promoters is directly responsible for modulation of the affinity of the EGF receptor for its ligand EGF. The regulation of the EGF receptor function by protein kinase C is discussed.