Human JIK, a Novel Member of the STE20 Kinase Family That Inhibits JNK and Is Negatively Regulated by Epidermal Growth Factor

doi:10.1074/jbc.274.47.33287

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Human JIK, a Novel Member of the STE20 Kinase Family That Inhibits JNK and Is Negatively Regulated by Epidermal Growth Factor^*

Elena Tassi, Zuzanna Biesova^§, Pier Paolo Di Fiore^¶, J. Silvio Gutkind, and William T. Wong^**

From the Oral and Pharyngeal Cancer Branch, NIDCR, National Institutes of Health, Bethesda, Maryland 20892-4330, the ^§ Institute of Virology, Slovak Academy of Sciences, Dubravska Cesta 9, Bratislava 84246, Slovak Republic, the ^¶ Department of Experimental Oncology, European Institute of Oncology, Milan 20140, Italy, and ^** GenoQuest, Inc., Germantown, Maryland 20874

ABSTRACT

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Mammalian members related to Saccharomyces cerevisiae serine/threonine kinase STE20 can be divided into two subfamilies basedon their structure and function. The PAK subfamily is characterizedby an N-terminal p21-binding domain (also known as CRIB domain),a C-terminal kinase domain, and is regulated by the small GTP-bindingproteins Rac1 and Cdc42Hs. The second group is represented bythe GCK-like members, which contain an N-terminal catalytic domainand lack the p21-binding domain. Some of them have been demonstratedto induce c-Jun N-terminal kinase/stress-activated protein kinase(JNK/SAPK) cascade, while others have been shown to be activatedby a subset of stress conditions or apoptotic agents, althoughlittle is known about their specific function. Here, we have identifieda novel human STE20-related serine/threonine kinase, belongingto the GCK-like subfamily. This kinase does not induce the JNK/SAPKpathway, but, instead, inhibits the basal activity of JNK/SAPK,and diminishes its activation in response to human epidermal growthfactor (EGF). Therefore, we designated this molecule JIK for JNK/SAPK-inhibitorykinase. The inhibition of JNK/SAPK signaling pathway by JIK wasfound to occur between the EGF receptor and the small GTP-bindingproteins Rac1 and Cdc42Hs. In contrast, JIK does not activatenor does it inhibit ERK2, ERK6, p38, or ERK5. Furthermore, JIKkinase activity is not modulated by any exogenous stimuli, but,interestingly, it is dramatically decreased upon EGF receptoractivation. Thus, JIK might represent the first member of theSTE20 kinase family whose activity can be negatively regulatedby tyrosine kinase receptors, and whose downstream targets inhibit,rather than enhance, JNK/SAPKactivation.

INTRODUCTION

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Binding of growth factors, hormones, and cytokines to their receptors regulates intracellular signal transduction pathways,which, in turn, control diverse cellular functions such as metabolism,proliferation, differentiation, programmed cell death, and stressresponses. The biochemical routes mediating these diverse biologicalresponses often involve a series of sequentially organized serine-threonineprotein kinases, known collectively as mitogen-activated proteinkinase (MAPK)¹ cascades (1-3). In mammalian cells, these kinases include p44/42^MAPK also known, respectively, as extracellular signal-regulated kinases1 and 2 (ERK-1 and ERK-2) (4, 5), ERK5 (6), ERK6, alsoknown as SAPK3 (7), c-Jun N-terminal kinases/stress-activatedprotein kinase (JNK/SAPK) (8-11), p38 kinase (11, 12), andSAPK4 (13).

The best studied MAPKs are the ERKs, whose catalytic activity is elevated in response to the binding of ligands to receptortyrosine kinases (i.e. epidermal growth factor receptors) or Gprotein-coupled receptors. The activation occurs after phosphorylationcatalyzed by their upstream protein kinase known as MAPK kinaseor MEK (14-16), which is itself activated by phosphorylation ontwo serine residues by several mammalian serine/threonine kinases,including Raf (17-19), Mos (20), and MEK kinase 1 (MEKK1) (21).In contrast, JNKs/SAPKs are activated in response to stress-inducingsignals, such as osmotic and heat shock, UV light, protein synthesisinhibitors, and proinflammatory cytokines (8-10). It has beenrecently shown that MKK4/SAPKK/JNKK/SEK1 phosphorylates JNK/SAPKat threonine and tyrosine, thus causing its activation (22-24).SEK1 is regulated by phosphorylation by upstream MAPK kinase kinases,which include MEKK1, -2, -3, and -4 (21, 25-28), Tpl-2 (29),and MAPKKK5 (30). However, upstream molecules controlling MEKK1directly are currentlyunknown.

The function of p38 in mammalian cells is unclear, but recent data indicate that it may respond to proinflammatory cytokines(interleukin-1, TNF- $alpha$ , lipopolysaccharide) and environmental stress(osmotic shock) (12, 30-33). Pathways regulating the activityof ERK6 (34), and SAPK4 appear to be similar to those of p38(13), while ERK5, shown to be activated by oxidative stress,may represent a unique redox-sensitive kinase distinct from otherMAPK family members (35, 36).

This unexpected diversity of MAPKs is not unique to mammalian cells. In the budding yeast Saccharomyces cerevisiae, at leastsix MAPK pathways have been identified (37, 38). They regulatediverse biological processes, such as mating and invasive growth,cell wall integrity, and the response to high osmolarity (39-42).Based on epistasis experiments, the S. cerevisiae serine-threoninekinase STE20 was shown to act upstream of the MAPK module consistingof the MAPK kinase kinase STE11, the MAPK kinase STE7, and theMAPKs FUS3/KSS1 in the mating pathway (43-45). Additional S. cerevisiaeSTE20-like kinases have been identified, and include Cla4 (46),which is involved in budding and cytokinesis, and SPS1 (47),a kinase required for late events in sporulation. In fission yeast,the STE20-like kinase Shk1 forms a complex with Cdc42 and a functionalinteraction between Shk1, Cdc42, and Ras1 is required for normalcell morphology and mating (48).

In the last few years, a large number of mammalian kinases closely related to S. cerevisiae STE20 have been identified. Basedon their structure, these mammalian STE20-like kinases can bedivided into two subfamilies (49): the PAK subfamily, containingan N-terminal p21-binding domain (also known as CRIB domain) anda C-terminal kinase domain; and the GCK-like subfamily, whichcontains an N-terminal catalytic domain and lacks the p21-bindingdomain. Recently, it has been shown that PAK comprises a proteinkinase family composed of several PAK isoforms, including therat and mouse p21-activated protein kinases, p65^PAK and mPAK-3 (50, 51), and their human counterparts, hPAK65(hPAK2) (52, 53) and hPAK1 (53, 54), which are all ableto interact with the small p21 GTP-binding proteins Rac1 and Cdc42(50), thereby regulating the activation of JNK/SAPK and p38pathways (55-57).

The second group of kinases comprises a growing number of serine/threonine kinases, including mNIK (58) (Nck-interactingkinase), hKHS (59) (kinase homologous to SPS1/STE20), hGCK (60),hGLK (61) (GCK-like kinase), hHPK1 (62) and mHPK1 (63) (hematopoieticprogenitor kinase-1), hSOK-1 (64) (STE20/oxidant stress responsekinase-1), mLOK (65) (lymphocyte-oriented kinase), hMST1 (66)(mammalian STE20-like kinase-1), hMST2 (67) (mammalian STE20-likekinase-2) and hMST3 (68) (ammalian E20-like kinase-3), and hKRS1and 2 (69) (kinases responsive to stress). In this study, wedescribe the isolation of a novel human serine/threonine kinase,designated JNK/SAPK-inhibitory kinase (JIK), whose kinase domainshares similarity to the GCK-like subfamily of STE20 kinases.Furthermore, its non-catalytic domain shares high homology toa Caenorhabditis elegans putative serine/threonine kinase, namedSULU, of unknown function. Interestingly, we found that this proteindoes not induce JNK/SAPK pathway; rather, its overexpression inCOS7 cells leads to the inhibition of JNK/SAPK activation. Furthermore,EGF negatively regulates JIK activity, and thus it may representthe first member of the STE20-like kinases whose activity is reducedupon stimulation of a cell surfacereceptor.

MATERIALS AND METHODS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Isolation and Characterization of JIK cDNA-- A GST fusion protein containing eps8-SH3 domain (amino acid residues 531-591) was used to screen a pCEV-LAC bacterial expressionlibrary constructed from human embryonic fibroblast M426 mRNAs,as described previously (70). The library was a kind gift fromDr. Toru Miki (71).

Northern Blot Analysis-- DNA probes used for Northern blot analysis were labeled with [ $alpha$ -³²P]dCTP using a random priming kit (Stratagene). The JIK cDNA (nucleotides1100-2800) and the human glyceraldehyde 3'-phosphate dehydrogenasewere random primed (Stratagene), and Northern blot analysis wasperformed on commercial human multiple tissue Northern blots (CLONTECH).Hybridization was performed as recommended by themanufacturer.

Production of Anti-JIK Polyclonal Antibodies-- Two oligonucleotide primers, 5'-CCGCGTGGATCCATGTCAGGTTATAAGCGGATGCGGCG-3' and 5'-TGAATTAAGCTTTCATCTGTAGTCCTCCTTAGGAAAATC-3',corresponding respectively, to amino acids 461-469 and 891-898,were used to amplify the DNA from the non-catalytic region ofJIK (clone 74). The resulting fragment was cloned in frame intothe BamHI and HindIII sites of pGEX-KG vector (Amersham PharmaciaBiotech). GST-JIK fusion protein was purified as described (72)and used to raise polyclonal antibodies inrabbit.

Expression Plasmids-- BamHI-EcoRI cDNA fragments containing either the entire coding sequence of JIK or JIK(A¹⁸¹ F¹⁸³) were amplified and introduced into BglII-EcoRI sites of pCEFLHA or pCEFL AU5 expression vectors. pCEFL is a modified pcDNAIIIexpression vector containing the elongation factor-1 promoterdriving the expression of an in-frame N-terminal tag of nine aminoacids (YPYDVPDYA) or six amino acids (TDFYLK) derived from HAand AU5,respectively.

Mutations were introduced into pBluescriptII SK-JIK by polymerase chain reaction (QuickChange^TM mutagenesis kit; Stratagene) according to the manufacturer'sinstructions and subcloned into the BglII-EcoRI sites of pCEFL-HAand pCEFL-AU5 expression vectors. The mutations were confirmedby automatedsequencing.

The expression vectors for pCDNA3-HA-JNK, pCDNA3-HA-ERK2, pCEFL-HA-p38, pCEFL-HA-ERK5, pCEFL-HA-ERK6, pCEFL-HA-SAPK4, pCEFL-AU5-Rac1QL,pCEFL-AU5-Cdc42QL, pCEFL-AU5-MLK3, and pCEV29-MEKK1 have beenalready described (55, 73).

Cell Cultures and Transfections-- C33A and COS7 cells were grown in Dulbecco's modified Eagle's medium supplemented with 10% (v/v) fetal bovine serum. NIH-3T3cells were grown in Dulbecco's modified Eagle's medium supplementedwith 10% (v/v) calf serum. Transfection of C33A and COS7 cellswas performed by calcium phosphate and DEAE-dextran methods,respectively.

Immunoprecipitation and Autophosphorylation Assay-- Subconfluent COS7 cells were transfected with 10 µg of pCEFL-HA, pCEFL-HA-JIK, or pCEFL-HA-JIK(A¹⁸¹ F¹⁸³). Two days after transfection, the transfectants were washedwith cold PBS and lysed at 4 °C in a buffer containing 20 mM Hepes(pH 7.5), 10 mM EGTA (pH 8), 2.5 mM MgCl₂, 1 mM DTT, 1% NonidetP-40, 40 mM $beta$ -glycerophosphate, 2 mM sodium orthovanadate, 1 mMphenylmethylsulfonyl fluoride, 20 µg/ml aprotinin, and 20 µg/mlleupeptin. The immunoprecipitation procedure and the subsequentkinase assay were performed as described (55). Briefly, theepitope-tagged JIK and JIK(A¹⁸¹ F¹⁸³) were respectively immunoprecipitated from the cleared lysatesby incubation with anti-HA (12CA5) for 1 h at 4 °C. Immunocomplexeswere recovered with the aid of Gamma-Bind Sepharose beads (AmershamPharmacia Biotech) and washed three times with PBS containing1% Nonidet P-40 and 1 mM sodium othovanadate, once with 100 mMTris (pH 7.5) and 0.5 M LiCl, and once with kinase reaction buffer(25 mM Hepes, pH 7.5, 20 mM MgCl₂, 20 mM $beta$ -glycerophosphate, 1mM sodium orthovanadate, 2 mM DTT). JIK activity was determinedby resuspension in 30 µl of kinase reaction buffer containing1 µCi (4500 Ci/mmol) of [ $gamma$ -³²P]ATP per reaction, 20 µM of cold ATP, and 4 µg of myelin basicprotein as substrate. After incubation at 30 °C for 30 min, reactionswere terminated by the addition of 15 µl of 5× Laemmli's buffer.Samples were heated at 95 °C for 5 min, analyzed by SDS electrophoresison 12.5% polyacrylamide gels, and visualized by autoradiography.Parallel anti-HA immunoprecipitates were processed for Westernblot analysis using an anti-JIK-specificantiserum.

MAPK Assays-- Subconfluent COS7 cells were cotransfected with 1 µg of pCDNA3-HA-ERK2, pCEFL-HA-ERK6, pCEFL-HA-p38, pCEFL-HA-SAPK4, pCEFL-HA-ERK5,or pCDNA3-HA-JNK and with 1 µg of pCEFL-AU5, pCEFL-AU5-JIK, orpCEFL-AU5-JIK(A¹⁸¹ F¹⁸³). After 2 days, transfected COS7 cells were cultured overnightin serum-free medium. Cells were left untreated or stimulatedwith 100 ng/ml EGF (Upstate Biotechnology) for 15 min for ERKand JNK, 200 µM H₂O₂ for 20 min for ERK5 (35), or 10 µg/ml anisomycinfor 20 min for p38, ERK6, and SAPK4. Cells were washed with coldPBS and subjected to kinase assay, using 5 µg of GST-ATF2(96)fusion protein or 4 µg of myelin basic protein as substrate, asdescribed in the method for the autophosphorylation assay (55,74). Parallel anti-HA and anti-AU5 immunoprecipitates were processedfor Western blot analysis using, respectively, MAPK- or JIK-specificantisera.

Phosphoamino Acid Analysis-- Phosphoamino acid analysis was performed as described (75). Phosphoproteins were separated by SDS-PAGE, transferred electrophoreticallyto Immobilon P membranes (Millipore), and autoradiographed. Theband of interest was excised from the membrane, and the phosphoproteinwas hydrolyzed in 6 N HCl at 110 °C for 90 min. The hydrolyzedsample was diluted in 1 ml of water, frozen in dry ice, driedby centrifugation under vacuum, and resuspended in 10 µl of watercontaining 2 mg/ml phosphotyrosine, phosphoserine, and phosphothreoninestandard, respectively. 1 µl of the sample was then spotted ontoa cellulose thin layer chromatography plate. Electrophoresis wasperformed in a buffer containing 1% pyridine and 10% acetic acidat 800 V for 75 min. The plates was then air-dried, and the aminoacids were visualized with 0.25% ninhydrin in acetone. Phosphoaminoacids were identified byautoradiography.

Immunoblot Analysis-- Anti-HA, anti-AU5, or anti-JIK immunoprecipitates were analyzed by Western blotting after SDS-PAGE, transferred to ImmobilonP membranes (Millipore), and immunoblotted with the correspondingrabbit antiserum or mouse monoclonal antibody. Immunocomplexeswere visualized by enhanced fluoroluminescence detection (VistraECF, Amersham Pharmacia Biotech) using alkaline phosphatase-linkedgoat anti-rabbit or anti-mouse antisera. Mouse monoclonal antibodies,anti-HA (clone 12CA5) and anti-AU5 were purchased from BABCO.Rabbit polyclonal anti-JNK1, anti-ERK2, and anti-p38 were purchasedfrom Santa Cruz Biotechnology, Inc. Anti-ERK5 was purchased fromStressgen.

RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Eps8 is an SH3 domain-containing protein identified as a substrate for the epidermal growth factor receptor (EGFR) and severalother receptor tyrosine kinases (76). The binding site of eps8on the EGFR was mapped to the juxtamembrane region of this receptor(77). Although several observations suggest that eps8 playsa critical role in mitogenic signaling (76, 78), its cellularfunction is still not clearlyunderstood.

As an approach to identify proteins that can associate physically with eps8, we screened a human embryonic fibroblast M426expression library using the GST SH3 domain of eps8 as a probe(70). Several overlapping cDNA clones were identified, the longestof which, designated clone 74-10, contained a cDNA insert of 2.978kilobase pairs. The complete nucleotide sequence of the clone74-10 (GenBank accession no. AF179867) predicted an 898-aminoacid open reading frame (Fig. 1A) and a molecular mass of 106kDa. Furthermore, the clone 74 contained a consensus Kozak sequence,GCCATC (79), immediately upstream from the putative initiationcodon. GenBank and EMBL data base searches revealed that its N-terminalregion (amino acids 19-284) encompasses a kinase domain includingall 11 subdomains that are characteristic of serine/threoninekinases (80). Sequence comparison with other protein kinasesusing the BLAST program (81) demonstrated that the kinase domainof clone 74 shares sequence homology with members of the STE20-likekinase family, and is most closely related to MST1 and MST2 (57%identity) (66, 67), SOK1 (56% identity) (64), SLK (51% identity)(82), hPAK1 (47% identity) (53, 54), KHS1 (45% identity)(59), and NIK (44% identity) (58). Furthermore, the overallprotein exhibits 63% identity and 76% similarity with a C. elegansserine/threonine kinase of unknown function, designated SULU (Fig.1B). A dendrogram was created to examine the evolutionary relationshipbetween clone 74, designated JIK for Jun kinase-inhibitory kinase(see below), and the other members of the STE20-like kinases.As shown in Fig. 1C, JIK does not belong to any of the STE20-relatedbranches but, together with its C. elegans homolog, it definesan independent subfamily.

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Fig. 1. Deduced amino acid sequence of human JIK and alignment with other proteins containing similar sequence motifs. A, JIK contains an open reading frame of 898 amino acid residues. Numbers refer to the position of the amino acid relative to the first methionine, and the kinase domain is underlined. B, amino acid alignment of JIK kinase domain with the corresponding domains of SULU, hSLK, mNIK, hKHS1, hMST1, hSOK1, and hPAK1. Identical and highly conserved amino acids are shaded. Roman numerals indicate the 11 protein serine/threonine kinase subdomains. C, the dendrogram, representing the degree of homology between the kinase domain of JIK and the corresponding domain of the STE20-like family members, was determined by Pile-Up algorithm of the GCG program.

Although JIK was initially isolated by virtue of its ability to bind to the bacterially expressed SH3 domain of eps8, no interactionbetween eps8 and JIK was observed when JIK was co-expressed inmammalian cells together with eps8, or when lysates from JIK-expressingcells were affinity-purified with bacterially expressed eps8 (datanot shown). Thus, we concluded that JIK binds eps8 in vitro, butthat this is likely to represent a low affinity interaction. Thebiological relevance of such an interaction, as well as whetherJIK can physically associate in vivo to other eps8-related proteins,is under currentinvestigation.

Analysis of the cDNA and Expression of JIK mRNA-- To examine the tissue distribution of JIK, we performed Northern blot analysis to establish the level of JIK mRNA expressionin several human tissues. As shown in Fig. 2, a major distincttranscript of 4.4 kilobase pairs was detected in most tissues.The levels of JIK mRNA are similar in the tissues analyzed, withthe exception of low level expression in the skeletal muscle.Thus, JIK is ubiquitously expressed in a variety of human tissues.

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Fig. 2. Expression of JIK mRNA in human tissues. A multiple tissue Northern blot was hybridized with JIK cDNA probe (upper panel), stripped, and re-hybridized with a human glyceraldehyde 3'-phosphate dehydrogenase probe (lower panel). Each lane represents 2 µg of poly(A)⁺ RNA isolated from the indicated tissues. Molecular size markers are shown on the left in kilobase pairs.

Identification and Characterization of the Human JIK Product-- In order to determine the expression of endogenous JIK protein, total cell lysates from NIH-3T3 and C33A cells were immunoprecipitatedand immunoblotted with a specific anti-JIK serum, raised againstthe non-catalytic region of JIK. This anti-JIK serum recognizeda major ~110 k Da band (Fig. 3, lanes 3 and 4) which was not detectedwhen the same extracts were immunoprecipitated with pre-immuneserum (Fig. 3, lanes 1 and 2). A faint band of higher molecularweight was also detected by the anti-JIK serum (Fig. 3, lanes3 and 4). However, when a variety of cell lines was tested, theintensity of this band did not correlate with that of the majorJIK-immunoreactive species (not shown), nor we observed changesupon overexpression of the JIK cDNA (Fig. 3, lane 6), Thus, thisband is likely not to represent lower mobility forms of JIK, butinstead cross-reacting molecules that are yet to be characterized.To confirm that the JIK cDNA contained the entire coding region,we engineered an expression plasmid encoding the HA epitope (83)in frame with the first codon of JIK open reading frame. Totalcell lysates from transfected C33A cells were immunoprecipitatedusing anti-HA and then examined by immunoblot analysis using anti-JIK.As shown in Fig. 3, a 110-kDa protein, migrating at a similarposition as the endogenous protein, was detected in HA-JIK transfectedcells (lane 6). No bands were detected in the cells transfectedwith the vector alone (Fig. 3, lane 5). These results suggestedthat the longest JIK cDNA clone identified (74-10) contains theentire open reading frame of the JIK gene.

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Fig. 3. Immunoprecipitation and immunoblot analysis of JIK. 5 mg of cell lysates from asynchronously growing NIH-3T3 and C33A cells were immunoprecipitated with polyclonal anti-JIK (lanes 3 and 4) and with preimmune rabbit serum (lanes 1 and 2). 5 mg of cell lysates from C33A cells transfected with vector alone (lane 5) or with HA-tagged JIK (lane 6) were immunoprecipitated with anti-HA antibody. The immunoprecipitants were separated by SDS-PAGE (10%) and, after transferring onto Immobilon P membrane, were immunoblotted with anti-JIK antibody.

Because of the sequence similarity of the putative kinase region of JIK to other serine/threonine kinases, we sought to determinewhether JIK exhibits intrinsic kinase activity. HA-tagged JIKwas transiently transfected in COS7 cells, immunoprecipitatedusing anti-HA antibodies and subjected to immune complex kinaseassay, using myelin basic protein (MBP) as exogenous substrate.As shown in Fig. 4, autophosphorylation of JIK, as well as MBPphosphorylation, were observed in HA-JIK transfected cells (lane2), but not in cells transfected with the vector alone (lane 1).To further confirm that the phosphorylated band at 110 k Da wasindeed HA-JIK, HA immunoprecipitates were blotted with anti-JIKantibodies. As shown in the bottom panel of Fig. 4A, a 110 k Daband was detected in the HA-JIK transfected cells but not in thecells transfected with the vector alone.

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Fig. 4. JIK is an active protein kinase. A, immunocomplex kinase assay of JIK in COS7 cells. Cell lysates from COS7 transfected with vector alone (lane 1) or with pCEFL-HA-JIK or pCEFL-HA-JIK(A¹⁸¹ F¹⁸³) (lanes 2 and 3) were immunoprecipitated with anti-HA antibody. The immunoprecipitates were then split, and one half was subjected to an in vitro kinase assay as described under "Materials and Methods." The second half was used to demonstrate equal protein levels of HA-JIK and HA-JIK (A¹⁸¹ F¹⁸³) immunoblotting with anti-JIK antiserum. B, phosphoamino acid analysis of in vitro phosphorylated JIK. 10 mg of total cell lysates from C33A cells transfected with pCEFL-HA-JIK were immunoprecipitated with anti-HA antibodies, separated by 10% SDS-PAGE, transferred onto Immobilon P membrane, and subjected to autoradiogram. The ³²P-labeled JIK was excised from the membrane and subjected to phosphoamino acid analysis, as described under "Materials and Methods." Position of the phosphoserine (pSer), phosphothreonine (pThr), and phosphotyrosine (pTyr) standards are indicated.

The protein kinase domains of all members of the STE20-related kinases are highly related, containing the characteristic sequenceGTPY/FWMAPE in subdomain VIII that serves as a signature for thisfamily of kinases. As in other protein kinases, the threonineresidue within this sequence may be a site for regulatory phosphorylation(84). As an approach to rule out the presence of a kinase otherthan JIK in the immune complexes responsible for the phosphorylationof JIK and of the exogenously added substrate, we engineered aJIK mutant by substituting the Thr-181 and Tyr-183 with Ala-181and Phe-183, respectively. Although partial activity was stillobserved in JIK(A¹⁸¹ F¹⁸³)-transfected COS7 cells, most likely due to the presence of alternativephosphorylation sites in the JIK molecule, both autophosphorylationand MBP phosphorylation were dramatically decreased despite comparableexpression level of the JIK and JIK(A¹⁸¹ F¹⁸³) proteins (Fig. 4A). These data indicate that JIK is indeed theprotein kinase present in the immune complex responsible for autophosphorylationand for the phosphorylation of the exogenous substrate. Moreover,our observations suggest that JIK (A¹⁸¹F¹⁸³) acts as the catalytically inactive mutant of JIK, which is nolonger able to potently undergo autophosphorylation and dramaticallyphosphorylate MBP, as compared with the wild type JIK.

To further ascertain the nature of the phosphorylated residues in JIK, autophosphorylated JIK was subjected to phosphoaminoacid analysis. As shown in Fig. 4B, autophosphorylated JIK containedboth phosphoserine and phosphothreonine, but not phosphotyrosine.Together, these results suggested that JIK is a serine/threoninekinase.

JIK Is Negatively Regulated by EGF-- Although JIK was enzymatically active when expressed in COS7 cells, we set out to investigate whether a variety of exogenousstimuli, including stress inducing agents such as UV light, NaCl,H₂O₂, TNF $alpha$ , anisomycin or L- $alpha$ Lysophospatidic acid, were modulatingthe catalytic activity of JIK. In this initial search, we foundthat none of these stimuli were able to cause the elevation ofthe kinase activity of JIK (data not shown). We next examinedthe response of JIK upon treatment with human epidermal growthfactor (EGF). AU5-tagged JIK was transiently expressed in COS7cells and its kinase activity was analyzed upon stimulation withEGF at different times. As shown in Fig. 5, JIK enzymatic activitywas still considerably high in response to EGF treatment for 5min, when compared with the level of activation detected in unstimulatedcells. However, JIK kinase activity and its autophosphorylationlevel were found to be potently reduced upon 15 min of EGF stimulation.Interestingly, the blockade of JIK kinase activity elicited byEGF was still detectable upon 20, 25 and 30 min of stimulation(not shown). Moreover, as shown in the bottom panel of Fig. 5,levels of expression of JIK were not affected by these treatments.Thus, taken together, these findings indicate that EGF might negativelyregulate JIK activity.

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Fig. 5. JIK activity is inhibited by EGF. Subconfluent COS7 cells were transiently transfected with 5 µg of pCEFL-HA (control) (lane 1) or pCEFL-HA-JIK (lanes 2-4). The cells were then serum-starved for 12 h and stimulated with EGF (100 ng/ml), as indicated. Cell extracts were subsequently processed for in vitro kinase assay, as described under "Materials and Methods." The data are the mean ± S.E. of three independent experiments, expressed as -fold increase with respect to the vector-transfected cells (control).

JIK Does Not Modulate ERK2, ERK6, p38, SAPK4, and ERK5 Activity-- To investigate whether JIK plays a role in regulating the activity of signaling kinases, in vitro kinase assays were performedusing lysates from cells coexpressing AU5-tagged JIK cDNA togetherwith HA-epitope tagged cDNAs encoding either ERK2, ERK6, p38,SAPK4 or ERK5. The activity of the immunoprecipitated MAPKs wasdetermined by measuring the phosphorylation of MBP for ERK2, ERK6,p38 and ERK5, and GST-ATF2(96) for SAPK4. As shown in Fig. 6a,coexpression of wild type JIK with ERK2 did not cause enhancementof MBP phosphorylation, as compared with the negative control.However, since it has been demonstrated that ERK2 catalytic activityis potently enhanced in response to EGF (85) and since we showedthat JIK kinase activity is dramatically blocked by treatmentwith EGF, we set out to investigate the effect of JIK on ERK2-elicitedstimulation in EGF-treated cells. As shown in Fig. 6A, as comparedwith the control coexpressed with the empty vector, JIK does notinterfere with the activation of ERK2 elicited by EGF.

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Fig. 6. JIK does not activate neither inhibits ERK2, ERK6, p38, SAPK4, and ERK5. A, subconfluent COS7 cells were cotransfected with pCDNA3-HA-ERK2 together with empty vector (control) (lanes 1 and 4), pCEFL-AU5-JIK (lanes 2 and 5), or pCEFL-AU5-JIK(A¹⁸¹ F¹⁸³) (1 µg each), starved overnight and treated with EGF (100 ng/ml, 10 min), as indicated. Lysates were then subjected to in vitro kinase assay, using MBP as substrate. Detection of HA-ERK2, AU5-JIK, and AU5-JIK(A¹⁸¹ F¹⁸³) in the lysates was determined, respectively, after immunoprecipitation with anti-HA and anti-AU5 and immunoblotting with anti-ERK2 and anti-JIK antisera. B-E, Subconfluent COS7 cells were cotransfected with pCEFL-HA-ERK6, pCEFL-HA-p38, pCEFL-HA-SAPK4, or pCEFL-HA-ERK5 (1 µg/plate) together with empty vector (control) (lanes 1 and 4) or pCEFL-AU5-JIK (lanes 3 and 4) (1 µg each). Cells were starved overnight and treated, where indicated, respectively with NaCl (300 mM, 20 min) for the ERK6 assay (B), anisomycin (10 µg/ml, 20 min) for p38 and SAPK4 assays (C and D, respectively) and H₂O₂ (200 µM, 20 min) for ERK5 assay. Lysates were then subjected to in vitro kinase assay, using MBP (B, C, E) or GST-ATF2(96) (D) as exogenous substrates. Detection of HA-tagged form of ERK6, p38, SAPK4, ERK5, and AU5-JIK in the lysates was determined respectively after immunoprecipitation with anti-HA and anti-AU5 and immunoblotting with anti-HA (B, D), anti-p38 (C), or anti-ERK5 (E) and anti-JIK antisera.

Furthermore, we confirmed that JIK was not required to stimulate or modulate the activity of other signaling kinases, suchas ERK6 (Fig. 6B) and SAPK4 (Fig. 6D), despite the activationby their respective agonists. However, in some experiments JIKcaused a minimal inhibitory effect on p38 (Fig. 6C) and ERK5 (Fig.6E), although Western blot analysis confirmed appropriate expressionof each MAPK and JIK. Taken together, these results led us toconclude that, in the model system analyzed, JIK does not activatenor have a significant negative affect on the enzymatic activityof ERK2, ERK6, p38, SAPK4 andERK5.

JIK Inhibits JNK/SAPK in an EGF-, Anisomycin-dependent, but UV-independent Manner by Acting on a Step Upstream from the Small GTPases-- Many members of the STE20-like kinase family have been shown to play a role in the activation of the SAPK/JNK cascade. Therefore,to examine the ability of JIK to affect the SAPK/JNK pathway,we coexpressed AU5-tagged JIK with HA-tagged JNK in COS7 cells.The activity of JNK was determined by immune complex kinase assayusing GST-ATF2(96) as a substrate. Unlike other STE20-like kinases,JIK was unable to activate JNK/SAPK, but, interestingly, JIK wasfound to reduce the basal activity of JNK/SAPK (4.2-fold). Thedecrease in SAPK/JNK activity was not due to variation of JNKexpression since similar levels were detected in all samples analyzed(Fig. 7).

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Fig. 7. JIK inhibits JNK/SAPK activation. A, COS7 cells were transfected with pCDNA3-HA-JNK and with empty vector or with pCEFL AU5-JIK or with pCEFL-AU5-JIK(A¹⁸¹ F¹⁸³) (1 µg each), starved overnight, and left untreated (control) or stimulated with EGF (100 ng/ml, 15 min) (A) or anisomycin (10 µg/ml, 20 min) and UV light (1000 µJ, 2 min) (B), as indicated. Cell extracts were processed to JNK assay, as described under "Materials and Methods." Detection of HA-JNK, AU5-JIK, and AU5-JIK(A¹⁸¹ F¹⁸³) in the lysates was determined after immunoprecipitation, respectively, with anti-HA and anti-AU5 and immunoblotting with anti-JNK1 and anti-JIK antisera. Data represent the mean ± S.E. of four independent experiments, expressed as -fold increase with respect to the vector-transfected cells (control).

Since EGF is known to play a role in inducing JNK/SAPK signaling pathway (55) and we also demonstrated that EGF negativelyregulates JIK kinase activity, we sought to determine whetherJIK plays a role in EGF-mediated JNK activation. Upon coexpressionof HA-JNK with AU5-JIK in COS7 cells, the cells were subsequentlystimulated with 100 ng/ml of EGF for 15 min. It has already beenshown that JNK/SAPK is fully activated upon 15 min of EGF treatmentin COS7 cells (55) and the same time of stimulation is sufficientto cause a dramatic reduction of JIK kinase activity (Fig. 5).Stimulation with EGF for 15 min led to a 2.3-fold increase ofJNK activity, when compared with unstimulated cells (Fig. 7A).In contrast, when coexpressed with JIK, as expected, JNK was onlymarginally activated by EGF. To ascertain that the JIK kinaseactivity was indeed responsible for the JNK/SAPK inhibition, wecoexpressed HA-tagged JNK together with JIK catalytically inactivemutant [AU5-JIK(A¹⁸¹ F¹⁸³)]. In these cells, the basal level of JNK activity was not inhibited,as compared with the level of activation detected in cells coexpressingwild type JIK and JNK. Furthermore, in the presence of the mutatedform of JIK, the EGF-elicited activity of JNK was only slightlylower than in cells transfected with vector alone, most likelydue to the fact that JIK(A¹⁸¹ F¹⁸³) still retains some kinase activity (Fig. 4A). Immunoblot analysisdetected the same level of expression of JNK, JIK and JIK(A¹⁸¹ F¹⁸³) in the samplesanalyzed.

Since it has also been reported that both anisomycin and UV light are potent activators of JNK/SAPK pathway (8-10, 55),we next explored the effect of JIK on JNK/SAPK cascade, upon stimulationwith these two stress-inducing agents. As shown in Fig. 7B, bothanisomycin and UV light caused a potent activation of JNK/SAPKcascade, when compared with the unstimulated cells, as determinedby GST-ATF2(96) phosphorylation. However, the overexpression ofJIK did not significantly affect the activation of JNK/SAPK elicitedby anisomycin or UV light. As shown in the bottom panels, immunoblotanalysis of the immunoprecipitants indicated that the treatmentwith these stimuli did not alter the expression of JIK, JIK (A¹⁸¹F¹⁸³), or JNK.

These observations suggest that JIK might act in a JNK/SAPK-inhibitory pathway, by reducing the basal state of JNK/SAPK activationand partially preventing the response of JNK/SAPK to EGF. In contrast,our data demonstrate that JIK does not modulate the activationof molecules mediating the induction of JNK/SAPK signaling pathwayby chemical and physicalstresses.

It has been recently demonstrated that the constitutively active forms of the small GTP-binding proteins Rac1 and Cdc42 (Rac1QL and Cdc42 QL, respectively) led to a potent stimulation ofthe JNK/SAPK signal transduction pathway (55). Moreover, ithas been also shown that the overexpression of the MAPK kinasekinase 1 (MEKK1) as well as the mixed lineage kinase 3 (MLK3)are sufficient to enhance JNK/SAPK cascade (25, 86). Thus,to further investigate the mechanism whereby JIK inhibits JNKactivation, we sought to determine whether the activation of JNK/SAPKpathway elicited either by Rac1 QL, Cdc42 QL, MLK3, or MEKK1 wasaffected by the overexpression of the wild type form of JIK. Asshown in Fig. 8, JIK was not able to inhibit the activation ofJNK/SAPK signal transduction pathway upon Rac1 QL (Fig. 8A), Cdc42QL (Fig. 8B), MLK3 (Fig. 8C), or MEKK1 (Fig. 8D) induction. Theexpression levels of the immunoprecipitated JNK/SAPK and JIK wereexamined by immunoblot analysis and were confirmed to be presentat comparable amounts in the samples analyzed. These findingsindicate that JIK might exert its inhibitory function by actingon a step upstream from the small GTPases Rac1 and/or Cdc42.

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Fig. 8. JIK does not inhibit JNK/SAPK activation by molecules acting downstream from small GTPases. Subconfluent COS7 cells were cotransfected with 1 µg of pCDNA3-HA-JNK and with 2 µg of empty vector (control) (lanes 1), or 2 µg of pCEFL-AU5 carrying cDNAs for the activated (QL) forms of Rac1 and Cdc42, or pCEFL-AU5-MLK3 or pCEV29-MEKK1 (lanes 2) together with 1 µg of pCEFL-AU5-JIK (lanes 3) or pCEFL-AU5-JIK(A¹⁸¹ F¹⁸³) (lanes 4). Cell extracts were processed as in Fig. 7. The data are representative of three independent experiments.

	DISCUSSION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

In this study we describe the cloning of a novel human serine/threonine kinase, designated JIK (for JNK/SAPK-inhibitory kinase),which was found to be ubiquitously expressed in human tissues.Based on its structure, this novel kinase was determined to belongto the STE20-related family of serine/threonine kinases and, inparticular, to the GCK-like subfamily of STE20 homologs. In itsoverall structure, JIK is highly similar to a putative C. elegansserine/threonine kinase, termed SULU, which has not been yet characterized.Interestingly, the obtained dendrogram, based on the computer-assistedalignment of the catalytic domain of each of the STE20-relatedkinases, showed that JIK, together with its C. elegans homolog,did not belong to any of the known STE20-related branches, butinstead determined an independentsubfamily.

When overexpressed in C33A and COS7 cells, JIK was shown to encode a protein of 110 kDa with autophosphorylating properties.Phosphoamino acid analysis of phospholabeled proteins indicatedthat JIK was indeed a serine/threonine kinase and, when expressedin COS7 cells, JIK was found to be enzymatically active. However,systematic evaluation of physical conditions, ligands, or substancesactivating other members of the STE20 family of kinases revealedthat no exogenous stimuli could result in elevated JIK kinaseactivity. In contrast, we found that EGF receptor stimulationcauses a dramatic decrease in JIK activity. However, EGF did notcause the tyrosine phosphorylation of JIK nor did it promotedthe association of JIK with EGF receptors or other phosphotyrosine-containingproteins (data not shown). Thus, how activation of EGF receptormodulates JIK activity is currently unknown and under investigation.We can nevertheless conclude that JIK may represent the firstSTE20-like kinase that can be negatively regulated after activationof a cell surface receptor, and most likely the first STE20-relatedkinase that responds to growth factors, rather than to stresspathways.

Germinal center kinase (GCK) (64) as well as germinal center kinase-like kinase (GLK) (61), are reported to activate theJNK/SAPK pathway through activation respectively of SEK1 and MEKK1,but unable to activate p38 or ERKs. Another member of STE20-relatedkinase, KHS, is also able to induce the activation of the JNK/SAPKkinase cascade, but not p38 or ERK2 kinases. Mouse and human HPK1have been also shown to induce JNK/SAPK cascade (62, 63),via the SH3-containing mixed lineage kinase MLK-3 and MAPK/ERKkinase 1 (MEKK1), which both in turn activate SEK1 (also calledMKK4 or JNKK) (21, 87). Interestingly, these four kinasesall belong to the same evolutionary branch and function as upstreamactivators of JNK/SAPK pathway, suggesting that they may havedeveloped during evolution to transmit signals to JNK in responseto distinct stimuli. Another STE20-related kinase, NIK (Nck-interactingkinase), was recently shown to activate JNK/SAPK but not ERK2(58). Taken together, these findings indicate that many STE20-relatedkinases are likely to specifically function in the activationof JNK/SAPK pathway. However, the function of many of the othermembers of this family of kinases, such as SOK1, LOK1, SLK, MST1,MST2, and MST3, remains yet to be elucidated. In this regard,the highly divergent structure of these proteins outside theirkinase domain suggests that they probably respond to, and areregulated by, very different cellular elements. Unlike other membersof the GCK-like family that activate JNK/SAPK pathway, JIK wasfound to reduce the basal level of JNK/SAPK activity more than4-fold, whereas kinase-inactive JIK had no demonstrable effect.In addition, the stimulation of JNK in response to EGF treatmentwas partially inhibited by the coexpression of JIK. Moreover,we found that JIK did not significantly reduce anisomycin- orUV-elicited JNK/SAPK activation, thus suggesting that JIK mayrepresent a regulatory member of a novel inhibitory pathway, controllingthe constitutive or the EGF-mediated activation of JNK/SAPK cascade.Interestingly, the JIK kinase activity was required for the inhibitionof JNK/SAPK constitutive activity. However, EGF itself has beenshown to reduce JIK enzymatic activity after 15 min of ligandaddition. Furthermore, upon 10 min of EGF stimulation, JIK wasdemonstrated to be still in its active state (data not shown)and thus was able to block JNK/SAPK basal activation. This mayexplain the EGF-mediated JNK/SAPK partial activation observedwhen wild type JIK wascoexpressed.

A number of molecules have been recently shown to exert a negative effect on the JNK/SAPK signaling pathway. They includeglutathione S-transferase P_i (GSTp), which physically associateswith and inhibits JNK/SAPK (88), JNK-inhibitory protein (JIP-1);which acts as a scaffolding molecule facilitating the activationof JNK/SAPK but preventing its translocation to the nucleus (89);thioredoxin, which binds and inhibits Ask-1, a molecule actingupstream of JNK/SAPK kinase (90); and the G-protein pathwaysuppressor 2 (GSP2), which blocks the activation of JNK/SAPK byTNF- $alpha$ , but whose molecular target is still unknown (91). ForJIK, co-immunoprecipitation experiments failed to demonstratea direct association with JNK/SAPK (data not shown). Furthermore,when we examined the effect of JIK on signaling molecules actingupstream from JNK/SAPK, we found that JIK did not affect the stimulationof JNK/SAPK by the constitutively active form of Rac1 and Cdc42(Rac1 QL and Cdc42 QL, respectively), nor the elevated JNK/SAPKactivity in response to the expression of MEKK1 or MLK3. Thus,these data strongly suggest that the target for the inhibitoryeffect of JIK is likely to reside downstream from the EGF receptor,but upstream from the Rho-related GTPases. Furthermore, the inhibitionof the JNK/SAPK pathway by JIK appears to be specific, as JIKeither did not effect ERK2, SAPK4, and ERK6 function or exertedvery limited inhibitory effect on p38 and ERK5. Nevertheless,in no case JIK caused any increase in the level of activationof these members of the MAPKsuperfamily.

The function(s) of the C-terminal regulatory domain of JIK are yet to be identified. We nevertheless speculate that the JIKregulatory domain might recruit interacting molecules, such asprotein phosphatases, which may trigger the dephosphorylationand inactivation of downstream targets, thereby leading to theinhibition of JNK/SAPK signal transduction pathway. In addition,although the sequence analysis of the C terminus of JIK revealedno known protein-protein interaction motifs, the nature of themolecular targets for JIK in this novel JNK-inhibitory pathwayis still unknown, and under currentinvestigation.

In summary, our data suggest that JIK represents the first member of the STE20 kinase family whose activity can be negativelyregulated by the EGF receptor and whose downstream targets leadto the inhibition, rather than to the enhancement, of JNK/SAPKactivation. Although the molecules mediating the inhibitory activityof JIK are still unknown, they are likely to reside upstream fromthe activation of the small GTPases. Further studies are neededto elucidate how EGF down-regulates JIK activity and, in turn,how JIK inhibits the JNK/SAPKpathway.

ACKNOWLEDGEMENTS

We gratefully acknowledge Dr. Giorgio Scita for helpful discussion, Dr. Donald P. Bottaro for assistance with phosphoaminoacid analysis, and Dr. Toru Miki for providing the human M426cDNAlibrary.

	FOOTNOTES

^* This work was supported in part by the Associazione Italiana Ricerca sul Cancro.The costs of publication of this article weredefrayed in part by the payment of page charges. The article musttherefore be hereby marked "advertisement" in accordance with18 U.S.C. Section 1734 solely to indicate thisfact.

To whom correspondence may be addressed. E-mail: sg39v@nih.gov.

To whom correspondence may be addressed: GenoQuest, Inc., P. O. Box 19, Germantown, MD 20874. E-mail: wwong@genoquest.com.

ABBREVIATIONS

The abbreviations used are: MAPK, mitogen-activated protein kinase; HA, hemagglutinin; PAGE, polyacrylamide gel electrophoresis; EGF, epidermal growth factor; EGFR, epidermal growth factor receptor; JNK, c-Jun N-terminal kinase; MBP, myelin basic protein; PBS, phosphate-buffered saline; TNF- $alpha$ , tumor necrosis factor- $alpha$ ; DTT, dithiothreitol; GST, glutathione S-transferase; MEK, mitogen-activated protein kinase kinase; MEKK, mitogen-activated protein kinase kinase kinase; ERK, extracellular signal-regulated kinase; SAPK, stress-activated protein kinase; JIK, JNK/SAPK-inhibitory kinase.

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Human JIK, a Novel Member of the STE20 Kinase Family That Inhibits JNK and Is Negatively Regulated by Epidermal Growth Factor*

Human JIK, a Novel Member of the STE20 Kinase Family That Inhibits JNK and Is Negatively Regulated by Epidermal Growth Factor^*