MINIREVIEW
Signaling by the Germinal Center Kinase Family of Protein Kinases*

John M. KyriakisDagger

From the Diabetes Research Laboratory, Massachusetts General Hospital and the Department of Medicine, Harvard Medical School, Charlestown, Massachusetts 02129

    INTRODUCTION
Top
Introduction
References

Mammalian mitogen-activated protein kinase (MAPK)1 pathways regulate an extensive range of cellular processes including gene transcription, cytoskeletal organization, metabolite homeostasis, cell growth, and apoptosis. At the physiologic level, MAPK pathways are likely to be critical to the pathogenesis of a number of important clinical conditions including oncogenesis, diabetes, ischemic injury, arthritis, and septic shock. MAPK pathways have been widely conserved in eukaryotic cell evolution. At the heart of these pathways are so-called "core signaling modules" consisting of the MAPKs, which are activated by concomitant Tyr and Thr phosphorylation catalyzed by members of the MAPK/extracellular signal-regulated kinase (ERK) kinase (MEK) family. MEKs, in turn, are activated by Ser/Thr phosphorylation catalyzed by protein kinases of several families collectively termed MAPK kinase kinases (MAP3Ks) (reviewed in Refs. 1-3).

Mammalian cells possess at least six MAPK families, three of which have been characterized in some detail: the ERKs, the stress-activated protein kinases (SAPKs, also referred to as Jun N-terminal kinases or JNKs) and the p38s (1, 2). The ERK pathway is a major downstream target of the Ras proto-oncoprotein and has been reviewed extensively elsewhere (2, 4). The SAPKs and p38s are, in most instances, poorly activated by mitogens and are instead potently and preferentially activated by a variety of environmental stresses (ionizing radiation, heat shock, oxidative stress, osmotic shock), inflammatory mediators of the TNF family (TNF, interleukin-1, CD40L, etc.), and the vascular responses to ischemia, reperfusion, and hypertension and associated humoral factors (angiotensin II, endothelin) (1). The SAPKs and p38s activate several transcription factors, most notably activator protein-1 (reviewed in Refs. 1 and 5).

The SAPKs are activated by at least two MEKs, SAPK/ERK-kinase-1 (also called MAPK kinase (MKK)-4) and MKK7. The p38s are also activated by at least two MEKs, MKK3 and MKK6 (6-10). The MAP3Ks upstream of the SAPKs and p38s are structurally divergent and differ widely in the spectrum of MEKs that they can activate in vivo and in vitro. Of these, only MEK kinase 1 (MEKK1) and mixed lineage kinases (MLK) 2 and 3 are demonstrably SAPK pathway-specific (11-20) (reviewed in Ref. 1).

Although considerable progress has been made in the identification of the molecular components and regulatory relationships of which MAPK core signaling modules are composed, much less is known of how core signaling modules are linked to events at the cell surface. A bewildering array of potential upstream activating proteins has been implicated in the regulation of MAP3Ks, ranging from Ras superfamily GTPases to additional protein kinases and adapter proteins coupled to cytokine receptors. In particular the SAPKs and p38s can be activated in vivo by Rac1, Cdc42Hs, and V12 Chp, members of the Rho subgroup of Ras family GTPases (21-24). Most, but not all, Rac and Cdc42 effectors possess a Cdc42/Rac interaction and binding (CRIB) domain (25, 26). Of note, p21-activated kinases (PAKs) possess CRIB motifs and are activated upon binding GTP-Rac1 or -Cdc42Hs (27). Several MAP3Ks upstream of the SAPKs and p38s, including MEKK-1 and -4 and MLK-2 and -3, can also bind GTP-Rac1 and/or -Cdc42Hs.

Recently, protein Ser/Thr kinases related to human germinal center kinase (GCK) have emerged as important potential players in the regulation of stress-activated MAPK core signaling pathways. This review will discuss what is known about the GCKs and their roles in MAPK pathway regulation.

    The kGCK Family: Structural Features of Group I and II Enzymes

Eleven mammalian protein kinases related to GCK have been cloned. In addition, there are Drosophila, Caenorhabditis elegans, and Dictyostelium homologues as well as two Saccharomyces cerevisiae genes with defined phenotypes. All GCK homologues possess N-terminal kinase domains that are distantly related to those of the PAKs and extensive C-terminal regulatory domains (CTDs) (30-44) (Fig. 1). The distant homology between PAK and GCK kinase domains has led to the grouping of these kinases into a single family. However, GCKs do not possess CRIB motifs and do not bind Rho GTPases; moreover, the PAKs have C-terminal kinase domains (27). Based on these strong differences, GCKs should be considered a distinct protein kinase family.


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Fig. 1.   Domain topology of mammalian group I GCKs. Kinase domains are indicated in red; the CTD boundaries are indicated with the bracket. Within the CTDs, PEST domains are in green, putative SH3 binding sites are in blue, the Leu-rich domains are in yellow, and the conserved CT extensions implicated in TRAF binding are in purple. The sequences of the putative SH3 binding sites are indicated. Numbers indicate the amino acid positions of the various domains.

GCKs can be subdivided into two broad groups based on their structural and functional properties. Group I GCKs are closely related to GCK itself and include GCK, GCK-related (GCKR), GCK-like kinase (GLK), hematopoietic progenitor kinase-1 (HPK1), Nck-interacting kinase (NIK, not to be confused with NF-kappa B-inducing kinase, also called NIK), and Drosophila Misshapen. These enzymes have been shown to activate selectively the SAPKs (30-35, 41). The C. elegans GCK MIG-15, an ortholog of NIK, is also a group I GCK (Fig. 1).

The C-terminal domains of all group I GCKs include at least two proline/glutamic acid/serine/threonine (PEST) motifs and at least two polyproline consensus binding sites for proteins containing Src homology (SH)-3 domains (30-35, 41). Most significantly, however, all of the group I kinases possess a highly conserved ~350-aa C-terminal region divided into two domains: a hydrophobic, leucine-rich domain and a 140-150-aa stretch, the C-terminal (CT) region (Fig. 1) (30-35, 41). The leucine residues in the Leu-rich domains are not organized into leucine zippers nor are these domains sufficiently hydrophobic for membrane insertion (Fig. 1) (30-35). GCK, GCKR, and GLK are all activated in vivo by TNF, and their CTDs along with that of HPK1 are quite homologous. Similarity to the CT motif of NIK, although apparent, is less dramatic (30-32, 44). Studies of GCK and GCKR indicate that this domain is required for binding proteins of the TNF receptor-associated factor (TRAF) family and, possibly, for gating the binding of MAP3Ks (45).2

Group II GCKs (Ste20-like oxidant stress-activated kinase-1 (SOK1), kinase responsive to stress (Krs)-1, mammalian sterile twenty-like-1 (MST1)/Krs2, mammalian sterile twenty-like-3 (MST3), lymphocyte-oriented kinase (LOK), severin kinase, Sps1p, and Cdc15p) are structurally more similar to S. cerevisiae Sps1p than to group I kinases (36-40, 42-44). These enzymes are less well understood, and the mammalian kinases do not activate any of the known MAPK pathways. Although group II GCKs share substantial catalytic domain homology with group I GCKs, their CTDs differ significantly from those of the group I enzymes.

    Functional Properties of Group I GCKs: SAPK Activation via Binding and Regulation of MAP3Ks

Although GCK is expressed in all tissues examined, in B lymphocytic follicular tissue it is restricted largely to the germinal center and not the surrounding mantle zone (30). Germinal centers are regions of B follicular tissue wherein B lymphocyte differentiation and selection, including Ig class switching, occurs. These processes are driven by ligands of the TNF family including CD40L, CD30L, and TNF itself (47, 48). That cytokines of the TNF family can potently activate the SAPKs suggested that GCK might relay signals from these ligands to the SAPKs. Indeed, GCK is a potent and selective activator of the SAPK pathway (45, 46). Upon overexpression, GCK does not activate p38, the ERKs, or NF-kappa B. The other group I GCKs manifest a similar selectivity for the SAPKs (31-35, 45, 46). Activation of the SAPKs by coexpressed GCK itself and by other group I GCKs occurs in the absence of external ligand, and the kinases are enzymatically constitutively active when overexpressed (30-35, 45). This contrasts with the PAKs, which must be activated by mutation or coexpression with active forms of Rac1 or Cdc42 (27). These results suggest that group I GCKs are activated either by dissociation of an inhibitor present in limiting concentrations or by oligomerization. Both of these processes could be overcome by overexpression.

The conserved CTDs are likely the site of group I GCK regulation and effector recognition. Expression of the free GCK and NIK CTDs (but not those of HPK1 or GCKR) results in substantial activation of coexpressed SAPK (33, 44), supporting the idea that the overexpressed CTDs either stoichiometrically titer out GCK inhibitors or nucleate the formation of GCK aggregates that foster SAPK activation. The first hints to the mechanism of action of mammalian group I GCK homologues came with the finding that these kinases could associate in vivo with MAP3Ks. HPK1 can bind both MEKK1 and MLK3. These interactions require the HPK1 CTD (31, 32). It is conceivable that both of these MAP3Ks are HPK1 targets, inasmuch as kinase-inactive mutants of MEKK1 and MLK3 can effectively block HPK1 activation of the SAPKs. The HPK1-MLK3 interaction has been mapped to the C-terminal two of four SH3 binding motifs in the HPK1 CTD (Fig. 1). These interact with the MLK3 SH3 domain (31, 32).

NIK was isolated based on its association with the SH2/SH3 adapter Nck (33). The NIK CTD contains two SH3 binding domains, both of which can mediate the interaction with Nck (33). Extracellular activators of NIK are unknown; however, an attractive possibility is that the Nck-NIK interaction may serve to couple NIK to receptor or non-receptor Tyr kinases.

NIK can interact in vivo with MEKK1. The Leu-rich domain (aa 948-1233) is required for MEKK1 binding (33). aa 1-719 of MEKK1 mediate the binding to NIK. Kinase-inactive MEKK1 can inhibit NIK activation of the SAPK pathway, suggesting that MEKK1 is a physiologic target of NIK (33).

GCK can bind either endogenous or coexpressed, recombinant MEKK1. This interaction can be reproduced in vitro using purified GCK and MEKK1. As with HPK1 and NIK, the interaction requires the GCK CTD (46). We have also observed an in vivo interaction between MLK3 and GCK; however, MLK2, which is structurally quite similar to MLK3, does not bind GCK.3 MEKK1 binds GCK through an acid-rich domain on the MEKK1 polypeptide, aa 817-1221, which is clearly distinct from the domain of MEKK1 that binds NIK (33, 46). Expression of this GCK binding domain of MEKK1 effectively blocks GCK activation of coexpressed SAPK, indicating that MEKK1 is a true GCK target (33, 46). In contrast to the results with NIK and HPK, the GCK CTD interacts with MEKK1 much more stably than does full-length GCK, and kinase-inactive GCK barely interacts with MEKK1 at all (32, 33, 46). Thus activation of the kinase activity of GCK may facilitate both MEKK1 binding and turnover.

The Leu-rich and CT regions are conserved among the group I GCKs that can bind MEKK1 (and MLK3), suggesting that these domains might form a common MAP3K binding site. Indeed, it is the SH3 binding site at the N terminus of the HPK1 Leu-rich domain that binds MLK3. By contrast, the characteristics of the binding of NIK and GCK to MEKK1 appear to be divergent. Deletion of its Leu-rich domain inhibits NIK binding to aa 1-719 of MEKK1 (33). Conversely, aa 1-719 MEKK1 are apparently dispensable for GCK binding (46); and deletion of the GCK CT actually prevents the binding of GCK to MEKK1, whereas subsequent deletion of the Leu-rich domain restores binding. MEKK1 binding is again lost upon deletion of the C-terminal PEST domain (PEST3) of the GCK CTD, suggesting that PEST3 of the GCK CTD may contain a binding site for MEKK1 aa 817-1221 (46). The results from NIK suggest that group I GCK Leu-rich domains may contain MEKK1 binding sites that target MEKK1 aa 1-719, a domain not yet tested for binding to GCK. Thus group I GCKs may possess multiple MEKK1 contact points within and outside of the Leu-rich domains. The Leu-rich domain of GCK (and perhaps those of GCKR, GLK, and HPK1) appears also to inhibit MEKK1 binding and may include structural motifs that negatively regulate MEKK1 binding. In this regard, it is noteworthy that the GCK, GCKR, GLK, and HPK1 Leu-rich domains are ~75-100 aa longer than that of NIK. GCK/GCKR/HPK1 or GLK activation, perhaps initiated by regulatory proteins binding the CT (46), may reverse this inhibition.

    Interaction of GCK and Rab8

A yeast two-hybrid screen employing the monomeric GTPase Rab8 as a bait demonstrated that GCK CTD could bind Rab8 in vivo. This binding is apparently GTP-dependent inasmuch as GTPase-deficient forms of Rab8 strongly interact in vivo with GCK, whereas Rab8 mutants that cannot bind guanine nucleotides or exchange GDP for GTP do not associate in vivo with GCK (49). Rab family GTPases are members of the Ras superfamily and have been implicated in the regulation of vesicular trafficking. Rab8 regulates traffic between the trans-Golgi and the plasma membrane (50). Thus GCK may play an effector role in Rab8-regulated vesicle movement, or alternatively, Rab8 may target GCK to substrate proteins associated with the cytosolic leaflets of vesicle membranes destined for fusion with the plasma membrane.

    SH3-binding Sites of Group I GCKs and Their Interactions with SH3 Adapter Proteins

The SH3-binding sites of the CTDs of group I GCKs are likely to be important in the regulation and function of these proteins in vivo. GCK, GCKR, GLK, and HPK1 each have one SH3 binding site site in their conserved Leu-rich regions (30-32, 34, 35). These SH3-binding sites may serve in effector binding; thus, the C-terminal Leu-rich domain SH3-binding site of HPK1 interacts with the MLK3 SH3 domain (31) (see above).

In addition, both HPK1 and NIK can interact with SH3 domain-containing adapter proteins that couple to Tyr kinases (33, 51). These interactions may allow for the recruitment of these GCKs to the membrane. Thus, NIK was cloned as an interactor with Nck, an adapter protein that couples receptor Tyr kinases to cytoskeletal and cell shape changes (33, 52). Interestingly, the Drosophila and C. elegans orthologs of NIK, Misshapen, and MIG-15, respectively, have been implicated in the regulation of embryogenic functions that involve cell elongation and migration (41) (see below). NIK and its orthologs may regulate cellular and developmental processes that involve changes in cell motility and morphology.

HPK1 not only interacts in vivo with MLK3, but it also binds the SH2/SH3 domain-containing adapter protein Grb2 (51). Grb2 is known for its ability to interact constitutively with mSOS, a Ras guanine nucleotide-exchange factor. Mitogen-induced receptor Tyr kinase autophosphorylation causes Grb2-mSOS to bind to Tyr(P) residues on the activated receptors. mSOS is thereby recruited to membranes where it can activate Ras (reviewed in Refs. 2 and 4). The C-terminal SH3 domain of Grb2 binds preferentially to the N-terminal two SH3-binding sites of HPK1 (51). As with the Grb2-mSOS interaction, the Grb2-HPK1 interaction is not altered by mitogen stimulation. However, epidermal growth factor treatment does stimulate the translocation of the Grb2-HPK1 complex to the autophosphorylated epidermal growth factor receptor at the membrane. These findings raise the intriguing possibility that membrane translocation of group I GCKs can be regulated by Tyr kinases (Fig. 2).


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Fig. 2.   Model for the regulation and function of group I GCKs. GCKs are recruited to the membrane by either receptor Tyr kinases (indicated as RTK in the figure) or activated components of TNFR family receptors (exemplified by TNFR shown here). Recruitment is followed by activation of the kinase activity of GCK. Stimuli that recruit the GCKs to the membrane may also recruit to the membrane-specific GCK MAP3K targets. GCK-MAP3K binding and MAP3K activation occur thereafter as discussed in the text. Tyr-P, phosphotyrosine.


    GCK and GCKR as Effectors for TRAFs

Three group I GCKs, GCK, GCKR, and GLK, are activated in vivo by TNF and appear to be elements in TNF signaling pathways that activate the SAPKs (34, 35, 45). The TNF family comprises a large group of related inflammatory mediators that bind to a group of related receptors to initiate responses that are critical to acquired and innate immunity, as well as to the pathogenesis of a number of important clinical conditions including arthritis, sepsis, inflammatory bowel disease, and type 2 diabetes mellitus (reviewed in Ref. 53).

TNF binds to one of two receptors, the 55-kDa TNF receptor (TNFR)-1/CD120a or the 75-kDa TNFR2/CD120b. Neither TNFR possesses intrinsic enzymatic activity. TNFRs homotrimerize upon binding ligand, an event that triggers the recruitment of downstream effectors. The intracellular extension of TNFR1 contains a death domain that binds, in a TNF-dependent manner, TNFR-associated death domain protein (TRADD), which, in turn, recruits TRAF2 (reviewed in Ref. 53).

TRAF2 is one of six known mammalian members of the TRAF family, each of which consists of C-terminal conserved TRAF domains, central zinc finger repeats, and with the exception of TRAF1, an N-terminal RING finger domain. The RING finger is critical for TRAF2 signaling to downstream effectors. The TRAF domains mediate the binding of TRAF proteins to their upstream activators and downstream targets. Transient overexpression of TRAF2, -5, and -6 can activate the SAPKs (reviewed in Ref. 53).

GCK and GCKR are important effectors for TRAF2 (35, 45, 46). Antisense constructs of GCKR can block SAPK activation of TNF but not activation of NF-kappa B. In addition, expression of TRAF2, but not TRAF2 mutants wherein the RING domain has been deleted, activates GCKR and the SAPKs in vivo, and expression of antisense constructs of GCKR in 293 cells can inhibit activation of the SAPKs by TRAF2 (35).

GCK and GCKR can both physically associate in vivo with the TRAF domains of TRAF2 (46).2 GCK can also associate in vivo with TRAF6.3 The CT extensions (Fig. 1) are required for the binding of GCK and GCKR to TRAF2 (46).2 In the case of GCK, the N-terminal PEST motif is also necessary for GCK binding (46). There is striking conservation among the CT motifs of the GCK, GCKR, GLK, and HPK1 CTDs (30-32, 34, 35), suggesting that a subset of the group I GCKs may be TRAF targets. It is also noteworthy that the CT region of GCK is required for binding to MEKK1 (46). Thus one function of TRAFs may be to regulate the interactions between TNF/cytokine-activated GCKs and their effectors.

    Genetic Studies of Group I GCKs: Signaling by Misshapen

Recent studies of the Drosophila dorsal closure signaling pathway lend credence to the idea that group I GCKs couple receptors (notably TNFR family receptors) to MAP3Ks. Dorsal closure occurs late in Drosophila embryogenesis and is precipitated by cell migrations and shape changes that position and eventually fuse the lateral epidermal primordia over the aminoserosa. Dorsal closure requires basket, the Drosophila homologue of SAPK, hemipterous, a homologue of MKK7, and Drosophila Jun, Djun. This Drosophila SAPK pathway induces expression of decapentaplegic, a transforming growth factor-beta homologue that ultimately controls the tissue reorganization characteristic of dorsal closure (reviewed in Ref. 54).

The Misshapen polypeptide is strikingly similar to NIK, both within and outside of the catalytic domain. Deletion of misshapen is lethal and results in dorsal closure defects similar to those arising from defects in basket (41). Ectopic expression of misshapen rescues the dorsal closure defects of mutant or null embryos. Transient expression of misshapen in mammalian cells results in activation of coexpressed SAPK indicating that Misshapen may signal to Basket. Consistent with this, a significant percentage of either doubly heterozygous misshapen-/+, basket-/+ or misshapen-/+, hemipterous-/+ flies exhibits a dorsal open phenotype, with the severity of the phenotype correlating well with the strength of the basket or hemipterous allele. Moreover, constitutively active Djun rescues not only the basket phenotype but the misshapen phenotype as well when expressed in the corresponding mutant embryos (41).

Skolnik and colleagues4 have recently identified a Drosophila TRAF homologue that binds Misshapen in vitro. Like mutations in misshapen, mutations in the Drosophila TRAF also give rise to dorsal closure defects; however, placement of the Drosophila TRAF upstream of Misshapen awaits further epistasis studies.

mig-15 encodes a C. elegans GCK that is also remarkably similar structurally to NIK and Misshapen. mig-15 mutants have a variety of developmental defects including abrogated Q-neuroblast migration and muscle arm targeting (41).

    Group II GCKs: Activation by Extreme Environmental Stresses

No known effectors have been identified for mammalian group II GCKs. Like group I GCKs, group II kinases are essentially ubiquitously expressed (with one exception, LOK, which is selectively expressed in lymphocytes) and possess significant basal activity when immunoprecipitated from endogenous sources or when overexpressed (36-39, 43, 44). However, Krs1, MST1/Krs2, and SOK1 can be activated substantially in vivo by different environmental stresses. Krs1 and MST1/Krs2 are activated by extreme heat shock and high concentrations of arsenite, staurosporine, and okadaic acid (37, 38). MST1/Krs2 can also be activated in vitro by phosphatase 2A (37, 38). Thus these two group II GCKs may be activated by both phosphorylation and dephosphorylation. SOK1, as its name implies, is strongly activated by oxidative stress. SOK1 is also activated by ischemic injury and depletion of the cellular ATP pool. In all cases, SOK1 activation appears to require the generation of reactive oxygen intermediates as well as elevated levels of cytosolic free Ca2+ (36, 55).5 Stimuli that recruit LOK and MST3 are unknown (39, 40). Certain group II GCKs display enzymologic properties that may yield clues as to the mechanisms of regulation of kinases of the GCK family. Thus, SOK1 and MST3 autoactivate upon autophosphorylation in vitro, and both SOK1 and MST1/Krs2 spontaneously homodimerize in vivo (36, 37, 39, 55). These results suggest that oligomerization and autophosphorylation may play a role in GCK family kinase activation.

    Conclusions and Perspectives

The GCKs represent an emerging family of protein kinases that regulate eukaryotic stress responses. How might the available findings be combined into a general model suitable for further experimental testing? Fig. 2 illustrates one way in which group I GCKs might mediate activation of MAPKs. In this model activated receptor Tyr kinases (through SH2/SH3 adapters) or cytokine receptors (through TRAFs) trigger the translocation of GCKs to membrane-associated receptor complexes. This translocation may initiate activation of GCKs (perhaps by oligomerization or disinhibition) and bring GCKs into close apposition with membrane-associated MAP3Ks, thereby promoting MAP3K binding and activation. Many MAP3Ks including MEKK1 (an effector for GCK, NIK, and HPK1) and MLK3 (an HPK1 effector) themselves display a reversible, stimulus-induced membrane translocation, which is required for activation (1-4, 28, 29). Differential and selective signal-induced MAP3K and GCK translocation would permit the specific activation of discrete pools of MAP3Ks by specific GCKs. Clearly further study of this interesting family of protein kinases will be important to our understanding of how MAPK core signaling modules are coupled to their activators.

    ACKNOWLEDGEMENTS

I thank Edward Skolnik and Melanie Cobb for providing results prior to publication and John Kehrl and Thomas Force for collaborations and for providing results prior to publication.

    Note Added in Proof

A portion of the studies of a Drosophila TRAF cited in the text as "E. Skolnik, personal communication" (Footnote 4) is now published (Liu, H., Su, Y.-C., Becker, E., Treisman, J., and Skolnik, E. Y. (1999) Curr. Biol. 9, 101-104).

    FOOTNOTES

* This minireview will be reprinted in the 1999 Minireview Compendium, which will be available in December, 1999. Work in the author's laboratory is supported by United States Public Health Service Grant GM46577 and a basic science grant from the Arthritis Foundation.

Dagger To whom correspondence should be addressed: Diabetes Research Laboratory, Massachusetts General Hospital East, 149 13th St., Charlestown, MA 02129. Tel.: 617-726-9451; Fax: 617-726-9452; E-mail: kyriakis{at}helix.mgh.harvard.edu.

2 J. Kehrl, personal communication.

3 J. M. Kyriakis and T. Yuasa, unpublished observations.

4 E. Skolnik, personal communication.

5 T. Force, personal communication.

    ABBREVIATIONS

The abbreviations used are: MAPK, mitogen-activated protein kinase; aa, amino acid(s); CD, cluster of differentiation; Cdc, cell division cycle; CRIB, Cdc42/Rac interaction and binding; CT, GCK C-terminal extension of CTD; CTD, C-terminal regulatory domain; ERK, extracellular signal-regulated kinase; GCK, germinal center kinase; GCKR, GCK-related; GLK, GCK-like kinase; HPK1, hematopoietic progenitor kinase-1; Krs, kinase responsive to stress; LOK, lymphocyte-oriented kinase; MAP3K, MAPK kinase kinase; MEK, MAPK/ERK kinase; MKK, MAPK kinase; MEKK, MEK kinase; MLK, mixed lineage kinase; MST, mammalian sterile twenty-like; NIK, Nck-interacting kinase (not to be confused with NF-kappa B-inducing kinase, also called NIK); NF-kappa B, nuclear factor-kappa B; PAK, p21-activated kinase; PEST, Pro/Glu/Ser/Thr-rich; RING, really interesting new gene; SAPK, stress-activated protein kinase; SH, Src homology; SOK, Ste20-like oxidant stress response kinase; SPS, sporulation-specific; TNF, tumor necrosis factor; TNFR, TNF receptor; TRAF, TNFR-associated factor.

    REFERENCES
Top
Introduction
References
  1. Kyriakis, J. M., and Avruch, J. (1996) J. Biol. Chem. 271, 24313-24316[Free Full Text]
  2. Marshall, C. J. (1995) Cell 80, 179-185[Medline] [Order article via Infotrieve]
  3. Herskowitz, I. (1995) Cell 80, 187-197[Medline] [Order article via Infotrieve]
  4. Avruch, J., Zhang, X.-f., and Kyriakis, J. M. (1994) Trends Biochem. Sci. 19, 279-283[CrossRef][Medline] [Order article via Infotrieve]
  5. Karin, M., Liu, Z.-g., and Zandi, E. (1997) Curr. Opin. Cell Biol. 9, 240-246[CrossRef][Medline] [Order article via Infotrieve]
  6. Sánchez, I., Hughes, R. T., Mayer, B. J., Yee, K., Woodgett, J. R., Avruch, J., Kyriakis, J. M., and Zon, L. I. (1994) Nature 372, 794-798[Medline] [Order article via Infotrieve]
  7. Dérijard, B., Raingeaud, J., Barrett, T., Wu, L.-H., Han, J., Ulevitch, R. J., and Davis, R. J. (1995) Science 267, 682-685[Medline] [Order article via Infotrieve]
  8. Tournier, C., Whitmarsh, A. J., Cavanagh, J., Barrett, T., and Davis, R. J. (1997) Proc. Natl. Acad. Sci. U. S. A. 94, 7337-7342[Abstract/Free Full Text]
  9. Holland, P. M., Suzanne, M., Campbell, J. S., Noselli, S., and Cooper, J. A. (1997) J. Biol. Chem. 272, 24994-24998[Abstract/Free Full Text]
  10. Raingeaud, J., Whitmarsh, A. J., Barett, T., Dérijard, B., and Davis, R. J. (1996) Mol. Cell. Biol. 16, 1247-1255[Abstract]
  11. Yan, M., Dai, T., Deak, J. C., Kyriakis, J. M., Zon, L. I., Woodgett, J. R., and Templeton, D. J. (1994) Nature 372, 798-800[Medline] [Order article via Infotrieve]
  12. Xu, S., Robbins, D. J., Christerson, L. B., English, J. M., Vanderbilt, C., and Cobb, M. H. (1996) Proc. Natl. Acad. Sci. U. S. A. 93, 5291-5295[Abstract/Free Full Text]
  13. Rana, A., Gallo, K., Godowski, P., Hirai, S.-i., Ohno, S., Zon, L. I., Kyriakis, J. M., and Avruch, J. (1996) J. Biol. Chem. 271, 19025-19028[Abstract/Free Full Text]
  14. Hirai, S.-i., Katoh, M., Terada, M., Kyriakis, J. M., Zon, L. I., Rana, A., Avruch, J., and Ohno, S. (1997) J. Biol. Chem. 272, 15167-15173[Abstract/Free Full Text]
  15. Blank, J. L., Gerwins, P., Elliot, E. M., Sather, S., and Johnson, G. L. (1996) J. Biol. Chem. 271, 5361-5368[Abstract/Free Full Text]
  16. Salmerón, A., Ahmad, T. B., Carlile, G. W., Pappin, D., Narsimhan, R. P., and Ley, S. C. (1996) EMBO J. 15, 817-826[Abstract]
  17. Ichijo, H., Nishida, E., Irie, K., ten Dijke, P., Saitoh, M., Moriguchi, T., Takagi, M., Matsumoto, K., Miyazono, K., and Gotoh, Y. (1997) Science 275, 90-94[Abstract/Free Full Text]
  18. Gerwins, P., Blank, J. L., and Johnson, G. L. (1997) J. Biol. Chem. 272, 8288-8295[Abstract/Free Full Text]
  19. Takekawa, M., Posas, F., and Saito, H. (1997) EMBO J. 16, 4973-4982[Abstract/Free Full Text]
  20. Moriguchi, T., Kuroyanagi, N., Yamaguchi, K., Gotoh, Y., Irie, K., Kano, T., Shirakabe, K., Muro, Y., Shibuya, H., Matsumoto, K., Nishida, E., and Hagiwara, M. (1996) J. Biol. Chem. 271, 13675-13679[Abstract/Free Full Text]
  21. Coso, O. A., Chiarello, M., Yu, J.-C., Teramoto, H., Crespo, P., Xu, N., Miki, T., and Gutkind, J. S. (1995) Cell 81, 1137-1146[Medline] [Order article via Infotrieve]
  22. Minden, A., Lin, A., Claret, F.-X., Abo, A., and Karin, M. (1995) Cell 81, 1147-1157[Medline] [Order article via Infotrieve]
  23. Bagrodia, S., Dérijard, B., Davis, R. J., and Cerione, R. A. (1995) J. Biol. Chem. 270, 27995-27998[Abstract/Free Full Text]
  24. Aronheim, A., Broder, Y. C., Cohen, A., Fritsch, A., Belisle, B., and Abo, A. (1998) Curr. Biol. 8, 1125-1128[Medline] [Order article via Infotrieve]
  25. Burbelo, P. D., Drechsel, D., and Hall, A. (1995) J. Biol. Chem. 270, 29071-29074[Abstract/Free Full Text]
  26. Tapon, N., Nagata, K., Lamarche, N., and Hall, A. (1998) EMBO J. 17, 1395-1404[Abstract/Free Full Text]
  27. Sells, M. A., and Chernoff, J. (1997) Trends Cell Biol. 7, 162-167[CrossRef]
  28. Fanger, G. R., Johnson, N. L., and Johnson, G. L. (1997) EMBO J. 16, 4961-4972[Abstract/Free Full Text]
  29. Nagata, K., Puls, A., Futter, C., Aspenstrom, P., Schaefer, E., Nakata, T., Hirokawa, N., and Hall, A. (1998) EMBO J. 17, 149-158[Abstract/Free Full Text]
  30. Katz, P., Whalen, G., and Kehrl, J. H. (1994) J. Biol. Chem. 269, 16802-16809[Abstract/Free Full Text]
  31. Kiefer, F., Tibbles, L. A., Anafi, M., Janssen, A., Zanke, B. W., Lassam, N., Pawson, T., Woodgett, J. R., and Iscove, N. R. (1996) EMBO J. 15, 7013-7025[Abstract]
  32. Hu, M. C.-T., Qiu, W. R., Wang, X., Meyer, C. F., and Tan, T.-H. (1996) Genes Dev. 10, 2251-2264[Abstract]
  33. Su, Y.-C., Han, J., Xu, S., Cobb, M., and Skolnik, E. Y. (1997) EMBO J. 16, 1279-1290[Abstract/Free Full Text]
  34. Diener, K., Wang, X. S., Chen, C., Meyer, C. F., Keesler, G., Zukowski, M., Tan, T.-H., and Yao, Z. (1997) Proc. Natl. Acad. Sci. U. S. A. 94, 9687-9692[Abstract/Free Full Text]
  35. Shi, C.-S., and Kehrl, J. H. (1997) J. Biol. Chem. 272, 32102-32107[Abstract/Free Full Text]
  36. Pombo, C. M., Bonventre, J. V., Molnár, A., Kyriakis, J., and Force, T. (1996) EMBO J. 15, 4537-4546[Abstract]
  37. Creasy, C. L., Ambrose, D. M., and Chernoff, J. (1996) J. Biol. Chem. 271, 21049-21053[Abstract/Free Full Text]
  38. Taylor, L. K., Wang, H.-C., and Erikson, R. L. (1996) Proc. Natl. Acad. Sci. U. S. A. 93, 10099-10104[Abstract/Free Full Text]
  39. Schinkmann, K., and Blenis, J. (1997) J. Biol. Chem. 272, 28695-28703[Abstract/Free Full Text]
  40. Kuramochi, S., Moriguchi, T., Kuida, K., Endo, J., Semba, K., Nishida, E., and Karasuyama, H. (1997) J. Biol. Chem. 272, 22679-22684[Abstract/Free Full Text]
  41. Su, Y.-C., Treisman, J. E., and Skolnik, E. Y. (1998) Genes Dev. 12, 2371-2380[Abstract/Free Full Text]
  42. Eichinger, L., Bähler, M., Dietz, M., Eckerskorn, C., and Schleicher, M. (1998) J. Biol. Chem. 273, 12952-12959[Abstract/Free Full Text]
  43. Freisen, H., Lunz, R., Doyle, S., and Segall, J. (1994) Genes Dev. 8, 2162-2175[Abstract]
  44. Phillipsen, P., and Schweitzer, B. (1991) Yeast 7, 265-273[Medline] [Order article via Infotrieve]
  45. Pombo, C. M., Kehrl, J. H., Sánchez, I., Katz, P., Avruch, J., Zon, L. I., Woodgett, J. R., Force, T., and Kyriakis, J. M. (1995) Nature 377, 750-754[CrossRef][Medline] [Order article via Infotrieve]
  46. Yuasa, T., Ohno, S., Kehrl, J. H., and Kyriakis, J. M. (1998) J. Biol. Chem. 273, 22681-22692[Abstract/Free Full Text]
  47. Cerutti, A., Schaffer, A., Shah, S., Zan, H., Liou, H.-C., Goodwin, R. G., and Casali, P. (1998) Immunity 9, 247-256[Medline] [Order article via Infotrieve]
  48. Matsumoto, M., Mariathasan, S., Nahm, M. H., Baranyay, F., Peschon, J. J., and Chaplin, D. D. (1996) Science 271, 1289-1291[Abstract]
  49. Ren, M., Zeng, J., De Lemos-Chiarandini, C., Rosenfeld, M., Adesnik, M., and Sabatini, D. D. (1996) Proc. Natl. Acad. Sci. U. S. A. 93, 5151-5155[Abstract/Free Full Text]
  50. Nuoffer, C., and Balch, W. E. (1994) Annu. Rev. Biochem. 63, 949-990[CrossRef][Medline] [Order article via Infotrieve]
  51. Anafi, M., Kiefer, F., Gish, G. D., Mbamalu, G., Iscove, N. N., and Pawson, T. (1997) J. Biol. Chem. 272, 27804-27811[Abstract/Free Full Text]
  52. Lu, W., Katz, S., Gupta, R., and Mayer, B. J. (1997) Curr. Biol. 7, 85-94[Medline] [Order article via Infotrieve]
  53. Arch, R. H., Gedrich, R. W., and Thompson, C. B. (1998) Genes Dev. 12, 2821-2830[Free Full Text]
  54. Ip, Y. T., and Davis, R. J. (1998) Curr. Opin. Cell Biol. 10, 205-219[CrossRef][Medline] [Order article via Infotrieve]
  55. Pombo, C. M., Tsujita, T., Kyriakis, J. M., Bonventre, J. V., and Force, T. (1997) J. Biol. Chem. 272, 29372-29379[Abstract/Free Full Text]


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