Dissociation of Akt1 from its negative regulator JIP1 is mediated through the ASK1-MEK-JNK signal transduction pathway during metabolic oxidative stress: a negative feedback loop

doi:10.1083/jcb.200502070

Published 5 July 2005. doi:10.1083/jcb.200502070
The Rockefeller University Press, 0021-9525 $8.00
JCB, Volume 170, Number 1, 61-72

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Dissociation of Akt1 from its negative regulator JIP1 is mediated through the ASK1–MEK–JNK signal transduction pathway during metabolic oxidative stress

: a negative feedback loop

Jae J. Song and Yong J. Lee

Department of Surgery and Pharmacology, University of Pittsburgh, Pittsburgh, PA 15213

Correspondence to Yong J. Lee: leeyj{at}msx.upmc.edu

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Abstract
Introduction
Results
Discussion
Materials and methods
References

We have previously observed that metabolic oxidative stress–induceddeath domain–associated protein (Daxx) trafficking ismediated by the ASK1–SEK1–JNK1–HIPK1 signaltransduction pathway. The relocalized Daxx from the nucleusto the cytoplasm during glucose deprivation participates ina positive regulatory feedback loop by binding to apoptosissignal–regulating kinase (ASK) 1. In this study, we reportthat Akt1 is involved in a negative regulatory feedback loopduring glucose deprivation. Akt1 interacts with c-Jun NH₂-terminalkinase (JNK)–interacting protein (JIP) 1, and Akt1 catalyticactivity is inhibited. The JNK2-mediated phosphorylation ofJIP1 results in the dissociation of Akt1 from JIP1 and subsequentlyrestores Akt1 enzyme activity. Concomitantly, Akt1 interactswith stress-activated protein kinase/extracellular signal–regulatedkinase (SEK) 1 (also known as MKK4) and inhibits SEK1 activity.Knockdown of SEK1 leads to the inhibition of JNK activation,JIP1–JNK2 binding, and the dissociation of Akt1 from JIP1during glucose deprivation. Knockdown of JIP1 also leads tothe inhibition of JNK activation, whereas the knockdown of Akt1promotes JNK activation during glucose deprivation. Altogether,our data demonstrate that Akt1 participates in a negative regulatoryfeedback loop by interacting with the JIP1 scaffold protein.

Abbreviations used in this paper: ASK1, apoptosis signal–regulatingkinase 1; Daxx, death domain–associated protein; DLK,dual zipper-bearing kinase; JIP1, JNK-interacting protein 1;JNK, c-Jun NH₂-terminal kinase; MLK, mixed lineage protein kinase;MOI, multiplicity of infection; SEK1, stress-activated proteinkinase/extracellular signal–regulated kinase1; si, smallinterference.

Introduction

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Abstract
Introduction
Results
Discussion
Materials and methods
References

We have previously observed that glucose deprivation increasesthe intracellular levels of hydroperoxide and glutathione disulfide(Lee et al., 1998). The increased steady-state levels of hydroperoxideand glutathione disulfide are sensed through thioredoxin andglutaredoxin and subsequently activate the apoptosis signal–regulatingkinase (ASK) 1–MEK–MAPK–HIPK1 signal transductionpathway (Song et al., 2002; Song and Lee, 2003a,b,c). The activatedHIPK1 phosphorylates the death domain–associated protein(Daxx), leading to the relocalization of Daxx from the nucleusto the cytoplasm (Song and Lee, 2004). The translocated Daxxbinds to ASK1 and subsequently leads to ASK1 oligomerization(Song and Lee, 2003a). The association of Daxx with ASK1 mayfunction as a positive feedback regulator to maintain/promoteASK1–MEK–MAPK signal transduction through ASK1 oligomerization(Song and Lee, 2004). Unlike Daxx, CDC25A phosphatase and mouseGST Mu 1-1 physically associate with ASK1 and inhibit its oligomerizationas well as its activity (Cho et al., 2001; Zou et al., 2001).

Biological regulatory systems usually have switchlike properties.Positive and negative feedback loops may produce bistable systemsunder stress conditions. Bistability can result from the combinedeffects of positive and negative regulators. Thus, we hypothesizedthat glucose deprivation elicits both positive and negativeregulatory signaling pathways. As mentioned previously, Daxx-mediatedASK1 oligomerization may act as a positive feedback loop forASK1–MEK–MAPK signal transduction by maintaining/promotingASK1 activity. However, a fundamental question that remainsunanswered is how glucose deprivation–induced ASK1–MEK–MAPKsignal transduction can be negatively controlled. In this study,we postulated that Akt1 acts as a negative regulator. A previousstudy has shown that Akt interacts with ASK1 and negativelyregulates ASK1 by phosphorylating ASK1 on Ser-83 residue (Kim et al., 2001).Park et al. (2002) also observed that Akt phosphorylatesstress-activated protein kinase/extracellular signal–regulatedkinase (SEK)1 on Ser-78 residue, resulting in the inhibitionof SEK1 enzyme activity. It is well known that the Akt familyof Ser/Thr-directed protein kinases (Akt1–3) are importantmediators of cell survival in response to growth factors, includinginsulin and insulin-like growth factor I (Bellacosa et al., 1998;Datta et al., 1999; Lawlor and Alessi, 2001; Leinninger et al., 2004).Akt is activated by phosphoinositide-dependentkinases 1 and 2 through phosphorylation at Thr-308 and Ser-473residues (Alessi et al., 1997; Toker and Newton, 2000). A numberof proapoptotic proteins have been identified as direct Aktsubstrates, including Forkhead transcription factors, caspase-9,glycogen synthase kinase 3, and Bad (Cross et al., 1995; Datta et al., 1997;del Peso et al., 1997; Cardone et al., 1998; Pap and Cooper, 1998;Brunet et al., 1999; Kops et al., 1999; Hetman et al., 2000).The proapoptotic function of these moleculesis suppressed upon phosphorylation by Akt. Recently, Kim et al. (2002)reported an interaction between Akt1 and c-Jun NH₂-terminalkinase (JNK)–interacting protein (JIP) 1. The Akt1–JIP1interaction is decreased concomitantly with an increase in anassociation between JIP1 and JNK (Kim et al., 2002). Based onthat previous study, we hypothesized that JIP1 negatively regulatesAkt1 by means of protein–protein interactions. The glucosedeprivation–induced dissociation of Akt1 from JIP1 leadsto the restoration of Akt1 enzyme activity.

JIP1 is a scaffold protein that integrates both positive andnegative regulators of JNK. JIP1 assembles JNK, MKK7, and mixedlineage protein kinase (MLK) proteins on different regions ofJIP1 and facilitates the JNK signaling pathway (Whitmarsh et al., 1998,2001). A JNK negative regulator, MAPK phosphatase-7,also binds to JIP1 and inhibits JNK activation by dephosphorylatingJNK (Willoughby et al., 2003). A recent study revealed thatthe recruitment of JNK to JIP1 and the phosphorylation of JIP1by JNK are prerequisites for activation of the JNK module (Nihalani et al., 2003).On the other hand, JNK activity can be antagonizedby Akt kinase activity in numerous cellular systems (Levresse et al., 2000;Kim et al., 2002; Barthwal et al., 2003; Aikin et al., 2004),and this cross talk may underlie many of theprosurvival effects of Akt.

In this study, we have demonstrated that JIP1–Akt1 playsan important role in the negative feedback loop during glucosedeprivation. Glucose deprivation–induced JNK2 activationresults in the phosphorylation of JIP1, which leads to the restorationof Akt1 activity by dissociating Akt1 from JIP1. Subsequently,Akt1 inhibits the glucose deprivation–induced ASK1–SEK1–JNK2signal transduction pathway.

Results

Top
Abstract
Introduction
Results
Discussion
Materials and methods
References

Interaction between Akt1 and JIP1
A previous study has shown that Akt1 binds to JIP1, which isa JNK pathway scaffold protein (Kim et al., 2002). We hypothesizedthat JIP1 acts as a negative regulator of Akt1 and that JIP1–Akt1interaction results in the inhibition of Akt1 catalytic activity.Metabolic oxidative stress may dissociate Akt1 from JIP1, therebyrestoring Akt1 enzyme activity. To test the hypothesis, whichwas the first step in this study, we examined whether endogenousJIP1 associates with endogenous Akt1 and inhibits the enzymaticactivity of Akt1 and whether metabolic oxidative stress dissociatesAkt1 from JIP1, thereby restoring Akt1 enzyme activity. DU-145cells were exposed to glucose-free medium for various times(10–120 min). Cells were lysed and immunoprecipitatedwith anti-Akt1 antibody followed by immunoblotting with anti-JIP1antibody, or Akt1 enzyme activity was measured by using an immunecomplex kinase assay. Fig. 1 A shows that endogenous Akt1 interactedwith endogenous JIP1 (lane 2). However, Akt1 dissociated fromJIP1 within 2 h during glucose deprivation (Fig. 1 A, lane 6).Fig. 1 A also shows that Akt1 phosphorylated an Akt-specificsubstrate, Bad (lane 6). These results suggest that Akt1 interactswith JIP1 and that Akt1 catalytic activity is inhibited. Thedissociation of Akt1 from JIP1 restores Akt1 enzyme activity,and the role of JIP1 in Akt1 catalytic activity was furtherexamined by the knockdown of JIP1 expression. Unlike pSilencercontrol plasmid–transfected cells, pSilencer–shortinterference (si)JIP1 stably transfected siJIP1#2 cells containeda low level of JIP1 (Fig. 1 B) and promoted Akt1 enzyme activity(Fig. 1 C). In contrast, when JIP1 was overexpressed, more JIP1associated with Akt1, and the phosphorylation of Bad on Ser-136was inhibited (Fig. 1 D, lanes 4–6). The inhibition ofBad phosphorylation was dependent on the level of JIP1 expression(Fig. 1 D). These results suggest that the interaction betweenAkt1 and JIP1 leads to the inhibition of Akt1 activity. Mostinteresting, the overexpression of JIP1 led to apoptosis, asshown by cell surface blebbing and the formation of apoptoticbodies (Fig. 1 E). These observations were consistent with poly(ADP-ribose) polymerase cleavage (Fig. 1 F), which is the hallmarkfeature of apoptosis, and with TUNEL assay (not depicted). Fig. 1F also shows that procaspase-9, the precursor form of caspase-9,was cleaved and activated in JIP1-overexpressing cells. Apoptosiswas dependent on the level of JIP1 expression.

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Figure 1. Role of JIP1 in Akt activity in DU-145 cells. (A) Cells were exposed to glucose-free medium for various times (10–120 min). Cells were lysed, and lysates were immunoprecipitated (IP) with anti–mouse Akt1 antibody. Immunoprecipitates were analyzed for the interaction of JIP1 with Akt1 (with anti-JIP1 antibody) and Akt1 catalytic activity in vitro using GST-Bad protein as a substrate (top). GST-Bad, phosphorylated GST-Bad, or Akt1 was detected with anti-Bad, anti–phospho–Ser-136–Bad, or anti–rabbit Akt1 antibody, respectively. Cell lysates (bottom) were immunoblotted with anti-JIP1, anti-phospho–Ser-473–Akt1, anti-Akt1, or antiactin antibody. (B) Immunoblot of JIP1 expression in control vector transfected (pSilencer) or pSilencer-siJIP1 stably transfected (siJIP1#1–3) single cell clones from DU-145 cells. Lysates containing equal amounts of protein (20 µg) were separated by SDS-PAGE and were immunoblotted with anti-JIP1 antibody. (C) Control plasmid or pSilencer-siJIP1 stably transfected siJIP1#2 cells were lysed, and lysates were immunoprecipitated with anti–mouse Akt1 antibody. Akt1 catalytic activity in vitro was determined by using GST-Bad protein as a substrate (top). GST-Bad, phosphorylated GST-Bad, or Akt1 was detected with anti-Bad, anti–phospho–Ser-136–Bad, or anti–rabbit Akt1 antibody, respectively. Cell lysates (bottom) were immunoblotted with anti–phospho–Ser-473–Akt1, anti-JIP1, or antiactin antibody. (D) Cells were infected with adenoviral vector containing Flag-tagged JIP1 cDNA (Ad.Flag-JIP1) at various multiplicity of infections (MOIs; 2–50). After 48 h of infection, cells were lysed, and lysates were immunoprecipitated with anti–mouse Akt antibody. Immunoprecipitates were analyzed for Akt catalytic activity and JIP1 binding using immunoprecipitated Akt as described in Fig. 1 A (top). The presence of JIP1 or actin in the lysates was verified by immunoblotting (bottom). (E and F) Cells were infected with Ad.EGFP and/or Ad.Flag-JIP1 at various MOIs (10–200). After 48 h of infection, morphology was evaluated with a phase-contrast microscope (E), or cell lysates were immunoblotted with anti-PARP, anti–caspase-9, anti-JIP1, or antiactin antibody (F).

It is well known that Akt1 is activated by phosphoinositide-dependentkinase 1 through phosphorylation at the Thr-308 and Ser-473residues (Alessi et al., 1997). Fig. 2 (A and B) shows thatAkt1 phosphorylated on Thr-308 and that Ser-473 binds to JIP1.To determine whether both residues play an important role inthe interaction between Akt1 and JIP1, site-directed mutagenesiswas used to create point mutations in one or both residues,converting them to Ala residues (Thr-308A, Ser-473A, and Thr-308A+ Ser-473A). Fig. 2 (C and D) clearly demonstrates that thereis no difference between wild-type Akt1 and mutant-type Akt1sin terms of binding to JIP1. These results indicate that thephosphorylation of these residues is not essential for the bindingof Akt1 to JIP1.

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Figure 2. Phosphorylation of Akt on Thr-308 and Ser-473 and its role in the association of Akt1 with JIP1. (A and B) DU-145 cells were infected with adenoviral vector containing HA-tagged Akt1 (Ad.HA-Akt1) and/or Ad.Flag-JIP1 at an MOI of 10. After 48 h of infection, cells were lysed. Lysates were immunoprecipitated with anti-HA antibody or anti-Flag antibody. Immunoprecipitated proteins and lysates were separated by SDS-PAGE and were immunoblotted with anti–phospho–Thr-308–Akt, anti–phospho–Ser-473–Akt, anti-Flag, anti-HA, or antiactin antibody. (C and D) DU-145 cells were transfected with pHA-Akt1 (wild type), pHA-Akt1 (Thr-308A), pHA-Akt1 (Ser-473A), or pHA-Akt1 (Thr-308A + Ser-473A) plasmids and were infected with Ad.Flag-JIP1 at an MOI of 10. After 48 h of incubation, cells were lysed. Cell lysates were immunoprecipitated with anti-HA antibody (C) or anti-Flag antibody (D) and were immunoblotted with anti-Flag or anti-HA antibody (top). The presence of Flag-JIP1 or HA-Akt1 in the lysates was verified by immunoblotting with anti-Flag antibody or anti-HA antibody, respectively (bottom).

Effect of glucose deprivation on JIP1–Akt1 or JIP1–JNK1/2 interaction
To investigate whether metabolic oxidative stress dissociatesAkt1 from JIP1, DU-145 cells were infected with Ad.Flag-JIP1and Ad.HA-Akt1. Cells were then exposed to glucose-free mediumfor various times, and the interaction between the two moleculeswas examined by immunoprecipitation. Fig. 3 A shows that Akt1dissociated from JIP1 within 2 h during glucose deprivation.We further examined whether our findings could be generalizedto other JIPs. Unlike JIP1, there was no interaction betweenAkt1 and JIP3 (Fig. 3 B) or JIP2 (not depicted), regardlessof the glucose concentration of the medium. Next, we examinedthe mechanism by which Akt1 dissociates from JIP1 during glucosedeprivation. We hypothesized that JNK is involved in this process.As a first step, we investigated the interaction between JIP1and JNK1/2 during glucose deprivation. Fig. 3 (C and D) showsthat the binding affinity of JNK2 to JIP1, but not that of JNK1to JIP1, was enhanced during glucose deprivation.

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Figure 3. Effect of glucose deprivation on Akt1–JIP1/3 interaction or JIP1–JNK1/2 interaction. DU-145 cells were coinfected with Ad.HA-Akt1 and Ad.Flag-JIP1 (A) or Flag-tagged JIP3 (Ad.Flag-JIP3; B) at an MOI of 10. DU-145 cells were coinfected with Ad.Flag-JIP1 and Ad.His-JNK1 (C) or Ad.HA-JNK2 (D) at an MOI of 10. After 48 h of infection, cells were exposed to glucose-free medium for various times. (A and B) Cell lysates were immunoprecipitated with anti-HA antibody and were immunoblotted with anti-Flag or anti-HA antibody (top). The presence of Flag-JIP1, Flag-JIP3, phospho-Akt, or actin in the lysates was verified by immunoblotting (bottom). (C and D) Lysates were immunoprecipitated with anti-His/anti-HA antibody and were immunoblotted with anti-Flag or anti-His/anti-HA antibody (top). The presence of Flag-JIP1 in the lysates was verified by immunoblotting (bottom).

Phosphorylation of JIP1 on Thr-103 is responsible for the dissociation of Akt1 from JIP1 during glucose deprivation
Previously, Nihalani et al. (2003) reported that JNK is involvedin the Thr-103 phosphorylation of JIP1, leading to the dissociationof dual zipper-bearing kinase (DLK) from JIP1. JNK recruitmentto JIP1 is related to the decreased affinity of JIP1 and DLK(Nihalani et al., 2001). We postulated that metabolic oxidativestress-induced JNK2 activation promotes the interaction betweenJNK2 and JIP1 and leads to the phosphorylation of JIP1 on Thr-103,thereby causing the dissociation of Akt1 from JIP1. To examinethis possibility, we used site-directed mutagenesis to createa point mutation at residue Thr-103 (Thr $->$ Ala) of JIP1 and measuredthe effect on the dissociation of Akt1 from JIP1 during glucosedeprivation. Data from immune complex kinase assays show thatthe glucose deprivation–induced phosphorylation of JIP1by JNK2 was diminished in Thr-103A mutant-type JIP1 (Fig. 4A). Unlike wild-type JIP1, the interaction between Akt1 andThr-103A mutant-type JIP1 was maintained during glucose deprivation(Figs. 3 A and 4 B). These data suggest that JNK2 binds to JIP1and phosphorylates JIP1 on the Thr-103 residue during glucosedeprivation. The phosphorylation of JIP1 on Thr-103 leads tothe dissociation of Akt1 from JIP1.

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Figure 4. Phosphorylation of JIP1 on Thr-103 and its role in the dissociation of JIP1 from Akt1 during glucose deprivation. (A) DU-145 cells were infected with Ad.HA-JNK2 at an MOI of 10. After 48 h of infection, cells were exposed to glucose-free medium for 1 h and lysed. Cell lysates were immunoprecipitated with anti-HA antibody. To examine which amino acid residue of JIP1 can be phosphorylated by JNK2, 0.5 µg GST-JIP1 (wild type) or GST-JIP1–Thr-103A (mutant type) was incubated with immunoprecipitated HA-JNK2 in kinase buffer containing 100 µCi/ml ${gamma}$ -[³²P]ATP at 30°C for 1 h. Phosphorylated proteins were resolved by SDS-PAGE and were analyzed by autoradiography. The presence of GST-JIP1 and HA-JNK2 in the kinase buffer was verified by immunoblotting with anti-JIP1 antibody and anti-HA antibody, respectively (top). The presence of HA-JNK2 in the lysates was verified by immunoblotting with anti-HA antibody (bottom). (B) DU-145 cells were transfected with pFlag-JIP1–Thr-103A and infected with Ad.HA-Akt1. After 48 h of incubation, cells were exposed to glucose-free medium for various times (1–4 h). Lysates were immunoprecipitated with anti-HA antibody and were immunoblotted with anti-Flag or anti-HA antibody (top). The presence of Flag-JIP1–Thr-103A in the lysates was verified by immunoblotting with anti-Flag antibody (bottom).

JNK2–JIP1 interaction and JNK2-mediated phosphorylation of JIP1
Fleming et al. (2000) reported that phosphorylation of Thr-183and Tyr-185 residues is required for the full activation ofJNK2. We hypothesized that phosphorylation of both residuesduring glucose deprivation is essential for JNK2–JIP1interaction and the phosphorylation of JIP1. To test this possibility,Thr-183 and Tyr-185 were replaced with Ala (Thr-183A) and phenylalanine(Y185F), respectively. Fig. 5 A shows that glucose deprivationincreased the interaction between JIP1 and Thr-183A mutant-typeJNK2. Fig. 5 B also shows that Y185F mutant increased its bindingto JIP1 during glucose deprivation. However, the total amountof JIP1 bound to the Y185F mutant-type JNK2 is much less (Fig. 5C). Data from densitometer tracings revealed that the ratioof the relative intensity of JIP1/JNK2 of wild type is similarto that of Thr-183A. However, the ratio of the relative intensityof JIP1/JNK2 of Y185F is only 35% of the wild-type value. Thesedata suggest that the phosphorylation of Tyr-185 residue, butnot that of Thr-183 residue, facilitates the binding of JNK2to JIP1. We further investigated whether the phosphorylationof both JNK2 residues is required for the JNK2-mediated phosphorylationof JIP1. Data from an immune complex kinase assay shows thatJIP1 was phosphorylated by only wild-type JNK2 during glucosedeprivation, but not by either Thr-183A or Y185F mutant-typeJNK2 (Fig. 5 D). These results suggest that phosphorylationof both the Thr-183 and Tyr-185 residues is necessary for fullactivation of the JNK2 enzyme.

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Figure 5. Role of Thr-183 and Tyr-185 residues of JNK2 in glucose deprivation–induced JNK2–JIP1 interaction or JIP1 phosphorylation. DU-145 cells were coinfected with Ad.Flag-JIP1 and adenoviral vector containing HA-tagged wild-type JNK2 (Ad.HA-JNK2-wt), Thr-183A mutant-type JNK2 (Ad.HA-JNK2–Thr-183A), or Y185F mutant-type JNK2 (Ad.HA-JNK2-Y185F) at an MOI of 10. After 48 h of infection, cells were exposed to glucose-free medium for various times (A and B) or for 60 min (C and D) and were lysed. (A–C) Lysates were immunoprecipitated with anti-HA antibody and were immunoblotted with anti-Flag or anti-HA antibody (top). The presence of Flag-JIP1 in the lysates was verified by immunoblotting with anti-Flag antibody (bottom). (D) Cell lysates were immunoprecipitated with anti-HA antibody. To examine which types of JNK2 can phosphorylate JIP1, 0.5 µg GST-JIP1 was incubated with immunoprecipitated HA-JNK2 in kinase buffer containing 100 µCi/ml ${gamma}$ -[³²P]ATP at 30°C for 1 h. Phosphorylated proteins were resolved by SDS-PAGE and were analyzed by autoradiography. The presence of GST-JIP1 and HA-JNK2 in the kinase buffer was verified by immunoblotting with anti-JIP1 antibody and anti-HA antibody, respectively (top). The presence of HA-JNK2 in the lysates was verified by immunoblotting with anti-HA antibody (bottom).

Role of SEK1 in JNK2 activation, JIP1–JNK2 interaction, and Akt1–JIP1 binding
We previously observed that glucose deprivation activates theASK1–SEK1–JNK pathway (Song et al., 2002). To examinewhether glucose deprivation–activated SEK1 plays a rolein the interaction between JIP1 and JNK and in the dissociationof Akt1 from JIP1, we attempted to silence SEK1 expression byusing short hairpin RNAs. DU-145 cells were stably transfectedwith either pSilencer control plasmid or pSilencer-siSEK1 vector.We selected several stable transfectants, as described in Materialsand methods. We chose three transfectant clones (pSilencer,siSEK1#1, and siSEK1#2) for further studies (Fig. 6). Fig. 6A shows that the expression of SEK1 was effectively reducedin the siSEK1#2 transfectant. To examine the role of SEK1 inthe activation of JNK, pSilencer and siSEK1#2 transfectantswere exposed to glucose-free medium for various times (Fig. 6B) or for 60 min (Fig. 6 C). Fig. 6 (B and C) shows that theglucose deprivation–induced activation of JNK and thephosphorylation of p46 and p54 was suppressed in the siSEK1#2transfectant. Relatively less suppression was observed in thesiSEK1#1 transfectant (unpublished data). We further examinedwhether the knockdown of SEK1 mRNA and protein suppresses theinteraction between JIP1 and JNK2 during glucose deprivation.Fig. 7 A shows that the binding of JNK2 to JIP1 increased duringglucose deprivation in the pSilencer transfectant. However,this binding was markedly inhibited in the siSEK1#2 transfectant(Fig. 7, B and C). We also observed that glucose deprivation–inducedJNK activation, the dissociation of Akt1 from JIP1, and therestoration of Akt1 activity were delayed in siSEK1#2 cellsin comparison with pSilencer control vector–transfectedcells (Fig. 7, E and D). These data suggest that SEK1 playsan important role in JNK2 activation, the binding of JNK2 toJIP1, and the subsequent dissociation of Akt1 from JIP1.

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Figure 6. Glucose deprivation–induced JNK activation in control plasmid (pSilencer) or pSilencer-siSEK1 stably transfected DU-145 cells. (A) Immunoblot of SEK1 expression in control vector–transfected (pSilencer) or pSilencer-siSEK1 stably transfected (siSEK1#1 and siSEK1#2) single cell clones from DU-145 cells. Lysates containing equal amounts of protein (20 µg) were separated by SDS-PAGE and were immunoblotted with anti-SEK1 antibody. Control, untransfected cells. (B and C) Control plasmid or pSilencer-siSEK1 stably transfected cells were exposed to glucose-free medium for various times (10–120 min; B) or for 60 min (C). After incubating, cells were harvested, and Western blot analysis was performed with anti–ACTIVE JNK, anti-JNK2, or antiactin antibody as the loading control.

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Figure 7. Role of SEK1 in the interaction between JIP1 and JNK2/Akt1 during glucose deprivation. Control plasmid (pSilencer) or pSilencer-siSEK1 stably transfected (siSEK1#2) cells were coinfected with Ad.Flag-JIP1 and adenoviral vector containing HA-tagged JNK2 (Ad.HA-JNK2) or Ad.HA-Akt1 at an MOI of 10. After 48 h of infection, cells were exposed to glucose-free medium for various times (A, B, D, and E) or for 60 min (C) and were lysed. Lysates were immunoprecipitated with anti-HA antibody and were immunoblotted with anti-Flag or anti-HA antibody (A–E). Akt1 catalytic activity in vitro was determined by using GST-Bad protein as a substrate (D and E). GST-Bad or phosphorylated GST-Bad was detected with anti-Bad or anti–phospho–Ser-136–Bad antibody, respectively (top). Flag-JIP1, phosphorylated JNK, JNK2, or actin in the lysates was verified by immunoblotting with anti-Flag, anti–ACTIVE JNK, anti-JNK2, or antiactin antibody, respectively (bottom).

Glucose deprivation–induced interaction between Akt1 and SEK1
A previous study has shown that Akt binds to SEK1 and subsequentlyinhibits SEK1 activity by phosphorylating mouse SEK1 on Ser-78residue (Park et al., 2002). We postulated that the glucosedeprivation–induced dissociation of Akt1 from JIP1 leadsto the increased binding of Akt1 to SEK1. The interaction betweenAkt1 and SEK1 results in the inhibition of SEK1 enzyme activity.To test this hypothesis, we first examined Akt1–SEK1 bindingduring glucose deprivation. Fig. 8 (A and B) shows that bindingof Akt1 to SEK1 gradually increased as a function of time duringglucose deprivation without changes in the intracellular levelof Akt1. We then investigated whether Akt1, which dissociatesfrom JIP1 during glucose deprivation, is the Akt1 that interactswith SEK1. Fig. 8 (C and D) shows that endogenous Akt1 associatedwith endogenous SEK1 during glucose deprivation for 2 h andphosphorylated human SEK1 on Ser-80 residue. As shown previouslyin Fig. 4 B, Akt1 binds to JIP1 before glucose deprivation.However, Akt1 does not dissociate from the JIP1–Thr-103Amutant protein during glucose deprivation. This indicates thatJIP1 is responsible for the dissociation of Akt1 from JIP1 duringglucose deprivation. If it is true that the dissociation ofAkt1 from JIP1 causes an increase in the interaction betweenAkt1 and SEK1, then that interaction should likewise be diminishedby the overexpression of JIP1–Thr-103A mutant protein.Fig. 8 E shows that glucose deprivation–induced Akt1–SEK1interaction was suppressed by overexpressing mutant-type JIP1–Thr-103Abut not wild-type JIP1. These results suggest that Akt1, whichhas been dissociated from JIP1, interacts with SEK1. To examinewhether the interaction between Akt1 and SEK1 inhibits the catalyticactivity of SEK1, cells were coinfected with Ad.His-SEK1 andeither Ad.HA-Akt1 wild type or Ad.HA-Akt1 mutant type (a dominantnegative form carrying a point mutation that ablates the kinaseactivity by replacing Lys-179 residue with Met). Data from immunecomplex kinase assays show that GST-JNK1 was phosphorylatedby His-SEK1 in cells that were deprived of glucose for 1 h (Fig. 8F). This phosphorylation was reduced during 4 h of glucosedeprivation in Ad.HA-Akt1 (wild type)–infected cells,but not in Ad.HA-Akt1–infected cells (Fig. 8 F). Altogether,these results suggest that the enzymatic activity of SEK1 isinhibited by its binding to Akt1 after several hours of glucosedeprivation, resulting from activation of the negative feedbackloop.

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Figure 8. Interaction between SEK1 and Akt1 and its role in SEK1 enzyme activity during glucose deprivation. DU-145 cells were coinfected with adenoviral vector containing His-tagged SEK1 (Ad.His-SEK1) and Ad.HA-Akt1 at an MOI of 10 (A, B, E, and F) and were transiently transfected with pFlag-JIP1-wt (wild type) or pFlag-JIP1–Thr-103A (mutant type; E). (A and B) After 48 h of incubation, cells were exposed to glucose-free medium for various times (1–4 h) and were lysed. Cell lysates were immunoprecipitated with anti-HA antibody (A) or anti-His antibody (B) and were immunoblotted with anti-His or anti-HA antibody (top). The presence of His-SEK1, Akt, or phospho-Akt in the lysates was verified by immunoblotting (bottom). (C and D) DU-145 cells were exposed to glucose-free medium for 1 or 2 h and were lysed. Lysates were immunoprecipitated with anti–mouse Akt antibody. (C) Immunoprecipitates were analyzed for SEK1 binding with anti-SEK1 or anti–rabbit Akt antibody (top). The presence of SEK1 and Akt in the lysates was verified by immunoblotting (bottom). (D) Immunoprecipitates were examined for the phosphorylation of SEK1 (Ser-80) by Akt. 0.5 µg GST-SEK1 was incubated with immunoprecipitated Akt in kinase buffer containing ATP at 30°C for 1 h. Phosphorylated proteins were resolved by SDS-PAGE and were analyzed by immunoblotting with anti–phospho-SEK1 (Ser-80) antibody. The presence of GST-SEK1 or Akt in the immunoprecipitate was verified by immunoblotting with anti-SEK1 antibody or anti–rabbit Akt antibody, respectively (top). The presence of Akt, phospho-SEK1, or SEK1 in the lysates was verified by immunoblotting (bottom). (E) After 48 h of incubation, cells were exposed to glucose-free medium for 4 h and were lysed. Lysates were immunoprecipitated with anti-His antibody and were immunoblotted with anti-HA or anti-His antibody (top). The presence of HA-Akt1, Flag-JIP1 wild type, or Flag-JIP1–Thr-103A in the lysates was verified by immunoblotting (bottom). (F) DU-145 cells were coinfected with Ad.His-SEK1 and Ad.HA-Akt1 wild type (wt) or Ad.HA-Akt1 dominant negative mutant type (DN) at an MOI of 10. After 48 h of incubation, cells were exposed to glucose-free medium for 1 or 4 h and were lysed. Lysates were immunoprecipitated with anti-His antibody. To examine the catalytic activity of SEK1, 0.5 µg GST-JNK1 was incubated with immunoprecipitated His-SEK1 in kinase buffer containing ATP at 30°C for 1 h. Phosphorylated proteins were resolved by SDS-PAGE and were analyzed by immunoblotting with anti–ACTIVE JNK antibody. The presence of GST-JNK1, His-SEK1, or HA-Akt1 in the immunoprecipitates was verified by immunoblotting (top). The presence of HA-Akt1 (wt, DN) or His-SEK1 in the lysates was verified by immunoblotting (bottom).

Role of JIP1 in glucose deprivation–induced JNK activation
To examine whether JIP1 plays an important role in JNK activationduring glucose deprivation, pSilencer control plasmid–transfectedcells or pSilencer-siJIP1 stably transfected siJIP1#2 cellswere exposed to glucose-free medium for various times (Fig. 9A) or for 60 min (Fig. 9 B). Fig. 9 shows that glucose deprivation–inducedJNK activation was suppressed in siJIP1#2 cells. Because JIP1was a knockdown, but not a knockout, in siJIP1#2 cells, basallevels of activated JNK was still observed. The activation ofJNK was restored by overexpressing JIP1 in siJIP1#2 cells (Fig. 9A, right).

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Figure 9. Glucose deprivation–induced JNK activation in control plasmid (pSilencer), pSilencer-siJIP1 stably transfected siJIP1#2, or Ad.Flag-JIP1–infected siJIP1#2 cells. Cells were exposed to glucose-free medium for various times (10–120 min; A) or for 60 min (B). Cell lysates were immunoblotted with anti–ACTIVE JNK, anti-JNK2, anti-JIP1, or antiactin antibody.

Negative regulator role of Akt1 in glucose deprivation–induced JNK activation
Our studies have revealed that Akt1 acts as a negative regulatorfor the ASK1–SEK1–JNK pathway during glucose deprivation.To confirm our observations, cells were transfected with Akt1or mock siRNA. Fig. 10 A shows that the expression of Akt1 waseffectively inhibited by siAkt1. Glucose deprivation–inducedJNK activation (Fig. 10, B and C) and cytotoxicity (Fig. 10D) were promoted in siAkt1-transfected cells. To exclude off-targeteffects of the siAkt construct, siAkt1-transfected cells wereinfected with Ad.HA-Akt1. Fig. 10 (C and D) shows that the overexpressionof Akt1 in siAkt1-transfected cells suppressed glucose deprivation–inducedJNK activation and cytotoxicity. These results suggest thatAkt1 acts as a negative regulator for the ASK1–SEK1–JNKpathway during glucose deprivation.

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Figure 10. Role of Akt1 in glucose deprivation–induced JNK activation and morphological damage. (A and B) DU-145 cells were transfected with Akt1 siRNA or mock siRNA and were incubated for 36 h. (A) Akt1 protein expression was assessed by immunoblotting with anti-Akt1 antibody. (B) Cells were exposed to glucose-free medium for various times (10–120 min). Cell lysates were immunoblotted with anti–ACTIVE JNK, anti-JNK2, or antiactin antibody. (C and D) DU-145 cells were transfected with Akt1 or mock siRNA. After 24 of incubation, cells were infected with Ad.EGFP or Ad.HA-Akt1 at an MOI of 10. After 24 h of infection, cells were exposed to glucose-free medium for 60 min (C) or for 24 h (D). (C) Cell lysates were immunoblotted with anti–ACTIVE JNK, anti-JNK2, anti-Akt1, or antiactin antibody. (D) Morphology was evaluated with a phase-contrast microscope.

	Discussion

Top Abstract Introduction Results Discussion Materials and methods References

The cellular functions of scaffolding proteins are to maintainthe specificity of signaling pathways and catalyze the activationof pathway components (Burack and Shaw, 2000). The JIP familyof scaffolding proteins associate with MAPK, MAPK kinase, andMAPK kinase kinase and create a functional signaling moduleto control the specificity of signal transduction (Morrison and Davis, 2003).JIP1 scaffold facilitates JNK activation inan MLK-MKK7–dependent manner (Dickens et al., 1997; Whitmarsh et al., 1998;Yasuda et al., 1999; Kelkar et al., 2000). JIP3mediates JNK signaling by interacting with ASK1, MEKK1, andSEK1 (Ito et al., 1999; Matsuura et al., 2002). JIP2 has beenproposed to regulate p38 signaling modules (Schoorlemmer and Goldfarb, 2001;Matsuura et al., 2002). Most interesting, JIP1and 2 interact and form homo- and heterooligomeric complexeswith components of the JNK signaling pathway and facilitatesignal transduction (Yasuda et al., 1999). However, our studiesreveal that JIP1 also acts as a negative regulator (Fig. 1).Data from immune complex kinase assays show that JIP1 bindsto Akt1 and inhibits Akt1 enzymatic activity (Fig. 1). Our observationssomewhat contradicted a recent report (Kim et al., 2003) thatJIP1 activates Akt1. We can only speculate that this discrepancyis a result of differences in analytical methods (immunoblottingassay vs immune complex kinase assay) because our data clearlydemonstrate that immunoblotting with phosphospecific Akt antibodiesdoes not truly reflect the catalytic activity of Akt. Data fromimmunoblot assays illustrate that phosphorylated (active form)Akt1 binds to JIP1; however, data from immune complex kinaseassays demonstrate that the enzymatic activity of Akt1 is suppressedby binding with JIP1 (Figs. 1 and 2).

The present studies reveal that JNK2-dependent JIP1 phosphorylationon Thr-103 regulates JIP1–Akt1 binding (Fig. 4). Theseresults are consistent with a previous study that demonstratedthat the JNK-mediated phosphorylation of JIP1 on Thr-103 isessential for regulating the binding of DLK to JIP1 (Nihalani et al., 2003).The dissociation of DLK from JIP1 results inDLK oligomerization, autophosphorylation, and, ultimately, inmodule activation (Nihalani et al., 2003). However, unlike DLK,phosphorylated Akt1 (active form) binds to JIP1 and is inactivated,whereas its dissociation from JIP1 results in the restorationof activity (Figs. 1–3). Akt1 then binds to SEK1 and negativelyregulates SEK1 by phosphorylating Ser-80 residue (Park et al., 2002;Fig. 8). A previous study also revealed that Akt negativelyregulates ASK1 by phosphorylating Ser-83 residue (Kim et al., 2001)and preventing oligomerization (unpublished data). Altogether,the Akt-mediated inhibition of SEK1 and/or ASK1 may act as anegative regulatory feedback loop for the ASK1–MEK–MAPKsignal transduction pathway. Moreover, recent studies have demonstratedthat during glucose deprivation, Akt phosphorylates and activatesARK5, which is a member of the AMP-activated protein kinasefamily (Suzuki et al., 2003a, 2004a). Activated ARK5 phosphorylatesataxia-telangiectasia mutated, a tumor suppressor, leading tothe activation of p53 by phosphorylation (Suzuki et al., 2003a).The activation of ARK5, which is triggered by Akt during glucosedeprivation, suppresses caspase activation and prevents celldeath (Suzuki et al., 2003b, 2004b). It is possible that Akt-activatedARK5 is involved in the negative regulatory feedback loop forthe ASK1–MEK–MAPK signal transduction pathway. Thispossibility needs to be investigated.

It was well known that HSP90 binds to Akt, and the inhibitionof this Akt–HSP90 interaction by HSP90 inhibitors leadsto the dephosphorylation and inactivation of Akt (Basso et al., 2002;Sato et al., 2000). Protein phosphatase 2A or proteinphosphatase 1 may play an important role in the regulation ofAkt dephosphorylation (Sato et al., 2000; Xu et al., 2003).In this study, we did not observe any significant reductionof the level of Akt1 phosphorylation during glucose deprivation(Fig. 3 A). Thus, HSP90 is not likely involved in the regulatoryfeedback loop for the ASK1–MEK–MAPK signal transductionpathway during glucose deprivation.

Previous studies have shown that JNK is activated by dual phosphorylationon the tripeptide motif Thr-X-Tyr, where X is any amino acid(Payne et al., 1991; Lawler et al., 1998). Two MAPK kinases,MKK4 and MKK7, synergistically activate JNK (Lawler et al., 1998;Ito et al., 1999; Matsuura et al., 2002; Kishimoto et al., 2003).MKK4 prefers Tyr-185 residue, and MKK7 prefers Thr-183residue (Lawler et al., 1998; Fleming et al., 2000). Our datademonstrate that the full activation of JNK requires the phosphorylationof both residues (Fig. 5 D). However, the phosphorylation ofJNK2 on Tyr-185 is a prerequisite for the recruitment of JNK2to JIP1 (Fig. 5). Most interesting, the knockdown of SEK1 (MKK4)mRNA and protein by siRNA for SEK1 during glucose deprivationleads to the inhibition of JNK activation, JIP1–JNK2 binding,and the dissociation of Akt1 from JIP1 (Figs. 6 and 7). Theseresults suggest that SEK1-mediated JNK2 phosphorylation is necessaryfor the restoration of Akt1 enzyme activity. As mentioned inthe Introduction, JIP1 specifically scaffolds JNK, MKK7, andmembers of the MLK family. In contrast, the ASK1–SEK1–JNK-signalingmodule preferentially interacts with JIP3 (Matsuura et al., 2002).Altogether, we postulate that two scaffolding proteins,JIP1 and 3, have a cross talk that leads to the regulation ofthe ASK1–SEK1–JNK signal during glucose deprivation.Glucose deprivation rapidly increases the interaction betweenASK1 and JIP3, and the consequently activated ASK1 phosphorylatesSEK1 on the Thr-261 residue. The activated SEK1 dissociatesfrom JIP3 and phosphorylates JNK2 on the Tyr-185 residue. PhosphorylatedJNK2 binds to JIP1, and the phosphorylation of the JNK2 Thr-183residue occurs. Activated JNK2 phosphorylates JIP1 on the Thr-103residue and leads to the dissociation of Akt1 from JIP1. DissociatedAkt1 binds to SEK1 and ASK1 and inhibits their enzyme activityby phosphorylating SEK1 on the Ser-80 residue and ASK1 on theSer-83 residue. Although JIP3 and 1 are structurally distinct,we believe that cross talk takes place between these two scaffoldingproteins. Obviously, further studies are necessary to understandthe role of scaffolding proteins in the glucose deprivation–inducednegative feedback loop. Our model will provide a framework forfuture studies.

Materials and methods

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Abstract
Introduction
Results
Discussion
Materials and methods
References

Cell culture
Human prostate adenocarcinoma DU-145 cells were cultured inDME with 10% FBS (HyClone) and 26 mM sodium bicarbonate formonolayer cell culture. The cells were maintained in a humidifiedatmosphere containing 5% CO₂ and air at 37°C.

Reagents and antibodies
Polyclonal anti-SEK1, anti–phospho–Thr-308–Akt,anti–phospho–Ser-473–Akt, anti-Akt, anti-Bad,and anti–phospho–Ser-136–Bad were purchasedfrom Cell Signaling, and anti–ACTIVE JNK was purchasedfrom Promega. mAbs were purchased from the following companies:anti-JIP1 from Santa Cruz Biotechnology, Inc.; antiactin fromICN; anti-HA (clone 3F10) from Roche Diagnostics; anti-Flag(clone M2; mouse) from Sigma-Aldrich; and anti-His (penta-His;mouse) from QIAGEN.

Site-directed mutagenesis
The QuickChange Site-Directed Mutagenesis Kit (Stratagene) wasused to make point mutations in Akt1, JNK2, or JIP1 protein.One Thr residue in Akt1 (Thr-308 Akt1) was replaced with Ala(Thr-308A Akt1). Sense primer (5'-GGTGCCACTATGAAGGCATTCTGCGGAACGC-3')and antisense oligonucleotides (5'-GCGTTCCGCAGAATGCCTTCATAGTGGCACC-3')were used for site-directed mutagenesis. For the mutation ofanother phosphorylation site of Akt1, Ser-473 residue was changedto Ala. Sense (5'-TCCCCCAGTTCGCCTACTCAGCCAGTG-3') and antisenseprimer oligonucleotides (5'-CACTGGCTGAGTAGGCGAACTGGGGGA-3')were used for site-directed mutagenesis. One Thr residue inJNK2 (183 JNK2) was replaced with Ala (Thr-183A). Sense (5'-CCAACTTTATGATGGCTCCCTATGTGGTG-3')and antisense primer oligonucleotides (5'-CACCACATAGGGAGCCATCATAAAGTTGG-3')were used for site-directed mutagenesis. One Tyr residue inJNK2 (185 JNK2) was replaced with Phe (Y185F). Sense (5'-CTTTATGATGACTCCCTTTGTGGTGACACGGTAC-3')and antisense primer oligonucleotides (5'-GTACCGTGTCACCACAAAGGGAGTCATCATAAAG-3')were used for site-directed mutagenesis. One Thr residue inJIP1 (103 JIP1) was replaced with Ala (Thr-103A). Sense primer(5'-GGCAGGTGACGCTCCGGGCGCCG-3') and antisense oligonucleotides(5'-CGGCGCCCGGAGCGTCACCTGCC-3') were used for site-directedmutagenesis. PCR reaction was prepared by adding 5 µlof 10x reaction buffer, 20 ng of double-stranded (ds) DNA template(pAdlox-HA-JNK2), 125 ng of each sense primer, 125 ng of eachantisense primer, 1 µl deoxyribonucleotide triphosphatemix, double-distilled water to a final volume of 50 µl,and 1 µl Pfu Turbo DNA polymerase (2.5 U/µl). PCRwas performed with 14 cycles (95°C for 30 s; 58°C for1 min; 68°C for 7 min) with initial incubation at 95°Cfor 30 s. After temperature cycling, the reaction was placedon ice for 2 min to cool the reaction. After PCR, 1 µlDpnI restriction enzyme (10 U/µl) was added directly toeach amplification reaction and incubated at 37°C for 1h to digest the parental supercoiled dsDNA. The DpnI-treateddsDNA was transformed into Epicurian Coli XL1-blue supercompetentcells. Colonies were selected, and each plasmid (pAdlox-HA-JNK2,pAdlox-HA-Akt1, and pAdlox-JIP1) was sequenced using primer(5'-GGATGCTAACTTATGTCAGG-3' for JNK2; 5'-CGAGAGCGCGTGTTCTCCGAG-3'for Akt1 308 and 473; and 5'-CATGACATCAGCCTGGAGGAG-3' for JIP1)to confirm mutation.

RNA interference by siRNA of SEK1 or Akt1
To stably express siRNA for long-term knockdown, pSilencer 2.1-U6hygro vector (Ambion) was used for clonal cell lines. The insertsfor hairpin siRNA into pSilencer were prepared by annealingtwo oligonucleotides. For human SEK1 siRNA, the top strand sequencewas 5'-GATCCACGCAAAGCACTGAAGTTGTTCAAGAGACAACTTCAGTGCTTTGCGTTTTTTTGGAAA-3',and the bottom strand sequence was 5'-AGCTTTTCCAAAAAAACGCAAAGCACTGAAGTTGTCTCTTGAACAACTTCAGTGC-TTTGCGTG-3'.The annealed insert was cloned into pSilencer 2.1-U6 hygro digestedwith BamH I and HindIII. The correct structure of pSilencer2.1-U6 hygro–SEK1 was confirmed by nucleotide sequencing.The resultant plasmid, pSilencer-SEK1, was transfected intoDU-145 cells, and 250 µg/ml hygromycin B–resistantcell clones were isolated. The interference of SEK1 proteinexpression was confirmed by immunoblot using anti-SEK1 antibody.

To down-regulate Akt1, Akt1 siRNA (Santa Cruz Biotechnology,Inc.) was used. Cells were transfected with Akt1 siRNA and wereincubated for 36 h. The interference of Akt1 protein expressionwas confirmed by immunoblotting using anti-Akt1 antibody (UpstateBiotechnology).

In vivo binding of Akt1 and JIP1 (or JIP3)
To examine the interaction between Akt1 and JIP1/3, DU-145 cellsin 100-mm culture plates were coinfected with the adenovirusof HA-tagged Akt1 (Ad.HA-Akt1) and Flag-tagged JIP1 (Ad.Flag-JIP1)or Flag-tagged JIP3 (Ad.Flag-JIP3). For immunoprecipitation,cells were lysed in buffer containing 150 mM NaCl, 20 mM Tris-HCl,pH 7.5, 10 mM EDTA, 1% Triton X-100, 1% deoxycholate, 1 mM PMSF,80 µM aprotinin, and 2 mM leupeptin, and the lysates wereincubated with 0.5 µg of rat anti-HA antibody for 2 h.After the addition of protein G agarose, the lysates were incubatedfor an additional 2 h. The beads were washed three times withthe lysis buffer, separated by SDS-PAGE, and immunoblotted withmouse anti-Flag or rat anti-HA antibodies. The proteins weredetected with the enhanced chemiluminescence reaction.

Shuttle vector construction
Adlox-HA-Akt1 was produced by inserting a HindIII–EcoRIfragment from pCMV6- HA-Akt1 into HindIII–EcoRI-cut pAdloxshuttle vector. pCMV5-Flag-JIP1 was provided by R. Davis (Universityof Massachusetts Medical School, Amherst, MA). pAdlox-Flag-JIP1having Flag tagged at their NH₂-terminal and restriction enzymerecognition sites at the flanking sides (5', HindIII; 3', XbaI)was produced by PCR using pcMV5-Flag-JIP1 as a template. Thesense primer was 5'-TAATAAGCTTGCGGAGCGAGAGAGCGGCCTG-3', andthe antisense primer was 5'-GCCGTCTAGACTACTCCAAGTAGATATCTTC-3'.PCR was performed for 30 cycles (94°C for 30 s, 55°Cfor 30 s, and 68°C for 2 min 30 s) with an initial incubationat 94°C for 1 min. For JIP1 (or JIP1–Thr-103A) proteinpurification, a PCR product of mouse JIP1 having restrictionenzyme sites at the flanking sides (5', EcoRI; 3', SalI) wasproduced using pcDNA3-T7-JIP1 (pAdlox-JIP1 Thr-103A) as a template.The sense primer was 5'-TAATGAATTCGCGGAGCGAGAGAGCGGCCTG-3',and the antisense primer was 5'-GCCAGTCGACCTACTCCAAGTAGATATCTTCTG-3'.pGEX-4T-1-JIP1 (or JIP1–Thr-103A) was made by insertingan EcoRI–SalI fragment from JIP1 (or JIP1 Thr-103A) PCRproduct into EcoRI–SalI-cut pGEX-4T-1 (Amersham Biosciences).pGEX-4T-1-JIP1 (or JIP1–Thr-103A) was transformed intoJM109, and JIP1 (JIP1–Thr-103A) expression was confirmedby anti-JIP1 (Cell Signaling). GST-JIP1 (or JIP1–Thr-103A)was purified by using glutathione Sepharose 4B column (AmershamBiosciences). pcDNA3-Flag-JIP3 was provided by K. Yoshioka (KanazawaUniversity, Kanazawa, Japan). pAdlox-Flag-JIP3 having Flag taggedat their NH₂-terminal and restriction enzyme recognition sitesat the flanking sides (5', SphI; 3', AccI) was produced by PCRusing pcDNA3-Flag-JIP3 as a template. The sense primer was 5'-CTGCGCATGCTGATGGACTACAAAGACGATGACGACAAGCT-3',and the antisense primer was 5'-CATCTAGTCGACTCACTCAGGGGTGTAGGACACCTGCC-3'.pcDNA3.1-His C-SEK1 was made by inserting the BamHI fragmentfrom pEBG-SEK1. Adlox-His-SEK1 was made by inserting the SpeI–XbaIfragment from pcDNA3.1-His C-SEK1 into SpeI–XbaI-cut pAdloxshuttle vector. pLNCX-HA p54 JNK2 ${alpha}$ were provided by L.E. Heasley(University of Colorado Health Sciences Center, Denver, CO).pLNCX-HA p54 JNK2 ${alpha}$ were digested with HindIII–ClaI, andtheir fragments were subcloned into HindIII–AccI-digestedpAdlox.

Adenoviral vector construction
All recombinant adenoviruses were constructed by using the Cre-loxrecombination system (Hardy et al., 1997). The selective cellline CRE8 has a ß-actin–based expression cassettedriving a Cre recombinase gene with an NH₂-terminal nuclearlocalization signal stably integrated into 293 cells. Transfectionswere done by using Lipofectamine Reagent (Invitrogen). 5 x 10⁵cells were split into a 6-well plate 1 d before transfection.For the production of recombinant adenovirus, 2 µg SfiI-digestedAdlox/HA-Akt1, Adlox/Flag-JIP1, Adlox/Flag-JIP3, His-SEK1, HA-JNK2,and HA-JNK2 (Thr-183A and Y185F) and 2 µg of ${psi}$ 5 viral genomicDNA were cotransfected into CRE8 cells. The recombinant adenoviruseswere generated by intermolecular homologous recombination betweenthe shuttle vector and ${psi}$ 5 viral DNA. A new virus has an intactpackaging site and carries a recombinant gene. Plaques wereharvested, analyzed, and purified. The insertion of each componentto adenovirus was confirmed by Western blot analysis after theinfection of corresponding recombinant adenovirus into DU-145cells.

Immune complex kinase assay
For the immune complex kinase assay, DU-145 cells were infectedwith Ad.HA-Akt1/Ad.Flag-JIP1 at a multiplicity of infection(MOI) of 10. After 48 h of infection, cells were lysed in abuffer solution containing 20 mM Tris-HCl, pH 7.5, 150 mM NaCl,5 mM EGTA, 10 mM NaF, 1% Triton X-100, 0.5% deoxycholate, 2mM DTT, 1 mM sodium orthovanadate, 1 mM PMSF, and protein inhibitorcocktail solution (Sigma-Aldrich). Cell extracts were clarifiedby centrifugation, and the supernatants were immunoprecipitatedwith rat anti-HA antibody (3F10; Roche Diagnostics) or mouseanti-Flag antibody (Sigma-Aldrich) and protein G agarose (SantaCruz Biotechnology, Inc.). The beads were washed twice witha solution containing 150 mM NaCl, 20 mM Tris-HCl, pH 7.5, 5mM EGTA, 2 mM DTT, 1 mM sodium orthovanadate, 1 mM PMSF, andprotein inhibitor cocktail solution, were washed once with thekinase buffer solution, and were subjected to kinase assays.To examine whether the JIP1-bound Akt1has a catalytic activity,GST-tagged fusion Bad protein (Santa Cruz Biotechnology, Inc.)was used as a substrate of Akt1. 1 µg Bad was incubatedwith immunoprecipitated HA-Akt1 or Flag-JIP1–HA-Akt1 complexin kinase buffer containing 20 mM Tris-HCl, pH 7.5, 20 mM MgCl₂,1 mM sodium orthovanadate, 2 mM DTT, and 20 µM ATP at30°C for 1 h. Finally, the reaction was stopped by adding2x Laemmli buffer. Phosphorylated proteins were resolved bySDS-PAGE and were analyzed by immunoblotting by using anti–phospho-Bad(Ser-136) antibody (Cell Signaling). For in vitro kinase assayof JIP1 phosphorylation by JNK2, DU-145 cells were infectedwith various types of Ad.HA-JNK2 (wild type, Thr-183A, and Y185F)at an MOI of 10. After 48 h of infection, cells were incubatedin glucose-free medium for 1 h and were lysed in a buffer solutioncontaining 20 mM Tris-HCl, pH 7.5, 150 mM NaCl, 5 mM EGTA, 10mM NaF, 1% Triton X-100, 0.5% deoxycholate, 0.1% SDS, 2 mM DTT,1 mM sodium orthovanadate, 1 mM PMSF, and protein inhibitorcocktail solution (Sigma-Aldrich). Cell extracts were clarifiedby centrifugation, and the supernatants were immunoprecipitatedwith rat anti-HA antibody and protein G agarose. The beads werewashed three times with the same solution as the beads above,were washed once with the kinase buffer solution, and were subjectedto kinase assays. 0.5 µg GST-JIP1 or GST-JIP1 (Thr-103A)was incubated with various immunoprecipitated types of HA-JNK2in kinase buffer containing 20 mM Tris-HCl, pH 7.5, 20 mM MgCl₂,1 mM sodium orthovanadate, 2 mM DTT, 20 µM ATP, and 100µCi/ml ${gamma}$ -[³²P]ATP at 30°C for 1 h. Finally, the reactionwas stopped by adding 2x Laemmli buffer. Phosphorylated proteinswere resolved by SDS-PAGE and were analyzed by autoradiography.

Immunoblot analysis
Cell lysates were subjected to electrophoresis on 10% polyacrylamidegels containing SDS under reducing conditions, and the proteinsin the gels were transferred onto a polyvinylidine difluoridemembrane. The membranes were incubated with 7% (wt/vol) skimmilk in PBST (PBS containing 0.1% [vol/vol] Tween 20) and werereacted with primary antibodies. After washing three times withPBST, the membranes were incubated with HRP-conjugated anti-IgG.The proteins were then detected with the ECL reagent.

Acknowledgments

This work was supported by the National Cancer Institute (grantsCA95191 and CA96989), the Elsa U. Pardee Foundation, the PittsburghFoundation, and the Department of Defense prostate program fund(grant PC020530).

Submitted: 10 February 2005

Accepted: 1 June 2005

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