Intracellular signaling cascades are the main routes of
communication between the Plasma membrane and regulatory targets in various
intracellular compartments. Sequential activation of Kinases is a common
mechanism of signal transduction in many cellular processes. During the past
decade, several related intracellular signaling cascades have been elucidated,
which are collectively known as MAPK (Mitogen-Activated Protein Kinase)
signaling cascades. The MAPKs are a group of protein Serine/threonine Kinases
that are activated in response to a variety of extracellular stimuli and
mediate signal transduction from the cell surface to the nucleus. In
combination with several other signaling pathways, they can differentially
alter phosphorylation status of numerous proteins, including Transcription
Factors, Cytoskeletal proteins, Kinases and other Enzymes, and greatly
influence Gene Expression, Metabolism, Cell Division, Cell Morphology and Cell
Survival. Furthermore, epigenetic aberrations of these enzymes or of the
signaling cascades that regulate them have been implicated in a variety of
human diseases including Cancer, Inflammation and Cardiovascular disease. There
are four major groups of MAPKs in mammalian cells—the ERKs (Extracellular signal-Regulated
Kinases), the p38MAPKs, the JNKs (c-Jun NH2-terminal Kinases) and the ERK5
(Extracellular signal-Regulated Kinase-5) or BMK cascades. These MAPKs are
activated by dual phosphorylation at the tripeptide motif Thr-Xaa-Tyr. The
sequence of this tripeptide motif is different in each group of MAPKs: ERK
(Thr-Glu-Tyr); p38 (Thr-Gly-Tyr); and JNK (Thr-Pro-Tyr). Each MAPK pathway
contains a three-tiered kinase cascade comprising a MAPKKK/MAP3K/MEKK/MKKK (MAP
Kinase Kinase Kinase), a MAPKK/MAP2K/MEK/MKK (MAP Kinase Kinase) and the MAPK.
This three-tier module mediates ultrasensitive switch-like responses to
stimuli. Frequently, a MAPKKKK, MAP4K or MKKKK (MAPKKK Kinase) activates the
MAPKKK. The MAPKKKs then phosphorylates a dual-specificity protein kinase
MAPKK, which in turn phosphorylates the MAPK (Ref.1 & 2).
ERK, the most widely studied MAPK cascade, have been
established as a major participant in the regulation of cell growth and
differentiation, but when improperly activated contribute to malignant
transformation. ERK1 and ERK2 form the central component in the ERK cascade.
The ERK signaling cascade is activated by a wide variety of receptors involved
in growth and differentiation including GPCRs (G-Protein Coupled Receptors),
RTKs (Receptor Tyrosine Kinases), Integrins, and Ion Channels. A general
activation scheme involves the activation of RTKs by Growth Factors, such as
EGF (Epidermal Growth Factor). The subsequent auto-phosphorylation of the
cytoplasmic tails of the receptor on tyrosine leads to the tyrosine
phosphorylation of the adapter protein SHC. SHC can then recruit the GRB2
(Growth Factor Receptor Bound Protein-2)-SOS (Son of Sevenless protein) complex
to the membrane via the SH2 domain of GRB2 binding to the phosphotyrosine on
SHC. SOS, a GEF for Ras, can then exchange the GDP bound to Ras to GTP. Once
Ras binds GTP, it can then recruit the Serine/threonine kinase Raf to the
membrane. When Raf translocate to the membrane, it becomes activated and then
phosphorylates the dual specificity kinases MKK1 and MKK2. The activated MKKs
phosphorylate ERK1/ERK2 on Threonine183 and Tyrosine185 (at the TEY motif)
(Ref.3). GPCR also play an important role in activation of ERKs. When the GPCR
becomes activated by Ligands such as Neurotransmitters, Cytokines etc., it
leads to the exchange of GDP for GTP on the GN-Alpha (Guanine
Nucleotide-Binding Protein-Alpha) subunit. Upon activation, GN-AlphaI (Guanine
Nucleotide-Binding Protein-Alpha-I) or GN-AlphaQ (Guanine Nucleotide-Binding
Protein-Alpha-Q) subunits are separated from GN-Beta (Guanine
Nucleotide-Binding Protein-Beta) and GN-Gamma (Guanine Nucleotide-Binding
Protein-Gamma) subunits and are converted to their GTP bound states that
exhibit distinctive regulatory features on the nine tmACs (Transmembrane
Adenylate Cyclases) in order to regulate intracellular cAMP (Cyclic Adenosine
3',5'-monophosphate) levels. cAMP activate Rap1A (Ras-Related Protein-1A) and
Rap1B (Ras-Related Protein Rap1B) through EPAC (Exchange Protein Activated by
cAMP)-dependent pathway. cAMP activates cAMP-GEFI (cAMP-Regulated Guanine
Nucleotide Exchange Factor-I)/EPAC1 and cAMP-GEFII (cAMP-Regulated Guanine
Nucleotide Exchange Factor-II)/EPAC2 that in turn activate Rap1A and Rap1B,
respectively. Rap1A and Rap1B then forms an active complex with BRaf (v-Raf
Murine Sarcoma Viral Oncogene Homolog-B1) for MEK1/2 activation finally
resulting in ERK1/2 activation. cAMP may also activate PKA (Protein Kinase-A),
which may further activate Rap and thus BRaf. On the other hand, PKA also inactivates
C-Raf. GN-Alpha also directly activates PLC (Phospholipase-C) which further
activates PKC (Protein Kinase-C) via DAG (Diacylglycerol). PKC further
activates Raf and thus ERK. A new mechanism has recently been identified that
regulates MEK1-ERK interactions and is dependent on Rac and PAK (p21-Activated
Kinase). Integrins also play an important role in regulating the efficiency of
the RTK/Ras/ERK pathway. FAK (Focal Adhesion Kinase) is a major nonreceptor
tyrosine kinase activated after Integrin-mediated adhesion to ECM
(Extracellular Matrix) proteins such as FN (Fibronectin). Interaction between
FAK and the cytoplasmic tail of Beta1 Integrins results in autophosphorylation
of FAK tyrosine 397 (FAK pY397) that can lead to stimulation of a cell-signaling
cascade that ultimately activates the Ras/MAPK/ERK pathway. In addition to FAK,
members of the Src family of nonreceptor protein-tyrosine kinases also
associate with Focal Adhesions and are involved in Integrin signaling.
Interestingly, Src and FAK appear to function in association with each other as
a result of the binding of the Src SH2 domain to an autophosphorylation site of
FAK. Src then phosphorylates additional sites on FAK. Tyrosine phosphorylation
of FAK creates binding sites for the SH2 domains of other downstream signaling
molecules, including PI3K (Phosphatidylinositol 3-Kinase) and Rac. A key target
of Rac is the protein-serine/threonine kinase PAK. Rac and CDC42 (Cell Division
Cycle-42) can synergize with Raf to promote activation of the ERKs through
mechanisms involving PAK1 phosphorylation of the MEK1 proline-rich sequence and
PAK3 phosphorylation of Raf1. PAK3 can phosphorylate Raf1, enhancing Raf1
activation. Raf1 finally activates ERK1/2 via MEK1/2. ERK once activated
translocates to the nucleus to phosphorylate and activate several nuclear
targets. The major target of activated ERKs is RSK (90 kDa Ribosomal protein S6
Kinase). Active RSKs appear to play a major role in transcriptional regulation,
translocating to the nucleus and phosphorylating such factors as the product of
proto-oncogene c-Fos at Ser362, SRF (Serum Response Factor) at Ser103, and CREB
(Cyclic AMP Response Element-Binding protein) at Ser133. ERK also translocates
to the nucleus to phosphorylate transcription factor Elk1 (on Serine383 and
Serine389). Another important target of ERK is NF-KappaB (Nuclear
Factor-KappaB), which binds to its consensus sequence (5'-GGGACTTTC-3') and
positively regulates the transcription of genes involved in immune and
inflammatory responses, cell growth control, and apoptosis. Other nuclear
targets of ERK include the MSKs (Mitogen- and Stress-activated protein
Kinases), CREB, c-Myc, HSF1 (Heat-Shock Factor-1), Paxillin and many more
transcription factors (Ref.4, 5 & 6).
Recently, another related kinase, ERK3, a nuclear protein
kinase, has been cloned and is reported to exhibit about 50% homology to
ERK1/ERK2 within its catalytic domain. However, it does not phosphorylate any
typical ERK substrates. The phosphorylation site motif in the activation loop
of ERK3 has a single phosphorylation site located at Serine189. Another member
of ERK family is the ERK5 that contains at least ten consensus sites for MAPK
phosphorylation and may be associated with keeping ERK5 in high active state.
ERK5 can be activated by proliferative stimuli such as EGF, Serum,
Lysophosphatidic acid, Neurotrophins and Phorbol ester, as well as by stress
stimuli such as Sorbitol, H2O2, and UV irradiation. WNK1 (WNK Lysine deficient
protein Kinase-1) is required for activation of ERK5 by EGF. MEK5 (MAPK/ERK
Kinase-5) and MEKK2/3 (MAP/ERK Kinase Kinase-2/3) acts as upstream regulators
of ERK5. The known ERK5 substrates include the MEF2 (Myocyte Enhance Factor-2)
family members, MEF2A, C and D, and the ETS-like transcription factor SAP1A
(Signaling lymphocytic Activation molecule associated Protein-1A) (Ref.7 &
8).
The second most widely studied MAPK cascade is the JNK/SAPK
(Stress Activated Protein Kinase). The JNKs/ SAPKs are encoded by at least
three genes: SAPK-Alpha/JNK2, SAPK-Beta/JNK3, and SAPK-Gamma/JNK1. This cascade
is activated following exposure to UV radiation, Heat shock, or Inflammatory
Cytokines. Directly upstream of JNK, at the MAPKK level, there are two dual
specificity kinases that phosphorylate and activate JNK at Serine and threonine
residues. These kinases are MKK4 (MAPK Kinase-4), and MKK7 (MAPK Kinase-4).
These proteins are activated, in turn, by the upstream MAP3K: MEKKs (MAPK/ERK
Kinase Kinases), MLK2/3 (Mixed Lineage Kinase-2/3), TAK1 (TGF-Beta-Activated Kinase-1),
TPL2 (Tumor Progression Locus-2), ZPK (Zipper Protein Kinase), and ASK1
(Apoptosis Signal-regulating Kinase-1). Some other MAP3Ks have also been
identified, whose functions are not known. These included MAP3K6, MLK1 (Mixed
Lineage Kinase-1) and LZK (Leucine Zipper-bearing Kinase). The Rho family GTPases, CDC42 and Rac initiate a cascade leading to JNK/SAPK, presumably by
binding and activating the protein kinase PAK, a kinase that phosphorylates and
promotes activation of MEKK1. CDC42 can also be activated by GPCR. Stimulation
of GPCRs coupled to the GN-AlphaS subunit of trimeric G-proteins, induces
production of cAMP and activation of PKA. Activation of PKA enhances the
activity of CDC42 and thus plays an important role in activation of JNKs. The
activation of JNK by Cytokine receptors appears to be mediated by the TRAF (TNF
Receptor-Associated Factor) group of Adaptor proteins. Activation of the TNFR
(Tumor necrosis Factor Receptor) leads to recruitment of TRAF2 (TNF
Receptor-Associated Factor-2), which is required for JNK activation. This
Adaptor protein (TRADD (Tumor Necrosis Factor Receptor-1-Associated Death
Domain Protein), RIP (Receptor-Interacting Protein), Daxx) has been reported to
bind MEKK1 and ASK1. The activated JNK/SAPKs translocate to the nucleus where
they phosphorylate transcription factors such as c-Jun, c-Fos, DPC4 (Deleted in
Pancreatic Carcinoma 4), p53, ATF2 (Activating Transcription Factor-2), NFAT4
(Nuclear Factor of Activated T-Cell-4), NFAT1 (Nuclear Factor of Activated T-Cell-1),
STAT1 (Signal Transducers and Activators of Transcription-1), HSF1, SHC and
Bcl2 (B-Cell CLL/Lymphoma-2). JNK-regulated transcription factors help to
regulate gene expression in response to a variety of cellular stimuli,
including stress events, Growth Factors and Cytokines. Activation of the JNK
signaling cascade generally results in Apoptosis, although it has also been
shown to promote cell survival under certain conditions and has important roles
in determining cell fate during metazoan development as well as involvement in
tumorigenesis and inflammation (Ref.9, 10 & 11).
The p38 kinase is most well-characterized member of the MAP
kinase family. It shares about 50% homology with the ERKs. Four p38 MAPKs have
been cloned so far in higher eukaryotes: p38-Alpha/XMpk2/CSBP,
p38-Beta/p38-Beta22, p38-Gamma/SAPK3/ERK6, and p38-Delta/SAPK4. The mammalian
p38 MAPK families are activated by cellular stress including UV irradiation,
Heat shock, High osmotic stress, Lipopolysaccharide, Protein synthesis inhibitors,
Proinflammatory Cytokines (such as IL-1 (Interleukin-1) and TNF-Alpha (Tumor
Necrosis Factor-Alpha)) and certain Mitogens. The upstream MAPK cascade in p38
activation includes MAPKKKs such as ASK1, MEKK1, MEKK 4, MLK2 and 3, DLK (Dual
Leucine Zipper Kinase), TPL2 (Tumor Progression Locus-2), TAK1 and TAO1/TAO2,
which phosphorylate and activate MKK3 and MKK6, which in turn phosphorylate and
activate p38. Proinflammatory cytokines such as IL and TNF are the main
stimulator of p38. IL-1 signaling is known to involve PI3K, p38MAPK and ERK.
After IL-1 is bound to its receptor IL-1R (IL-1 Receptor), a complex is formed
between the Type-1 Receptor and the receptor accessory protein. The cytosolic
proteins MyD88 (Myeloid Differentiation primary response gene-88) and TollIP
(Toll-Interacting Protein) are recruited to this complex, where they function
as adaptors, recruiting IRAK1 (IL-1 Receptor-Associated Kinase-1) in turn.
IRAK1, a serine-threonine kinase, activates and recruits TRAF6 (TNF
Receptor-Associated Factors-6) to the IL-1 receptor complex. Eventually,
phosphorylated IRAK is ubiquitinated and degraded. TRAF6 signals through the
TAB1 (TAK1 Binding Protein-1)/TAK1 (TGF-Beta-Activating Kinase-1) kinases to
activate MKKs, which further activates p38MAPK (Ref.12). TNF also stimulate p38
signaling. Binding of TNFR1 to TNF-Alpha results in conformational changes in
the receptor’s intracellular domain, resulting in rapid recruitment of several
cytoplasmic death domain–containing adapter proteins via homophilic interaction
with the death domain of the receptor. The first adaptor recruited to the
clustered receptor is the TNFR–associated protein with death domain, which
functions as a docking protein for several signaling molecules, such as FADD
(Fas-Associated protein with Death Domain), TRADD, Daxx, TRAF2 and RIP. RIP
associates with TRAF2 to generate MEKK4 and ASK1. Both MEKK4 and ASK1 activates
p38MAPKs by activating MKK3 and MKK6. Besides, p38 can also be activated by
GPCRs and numerous physical and chemical stresses, including hormones, UV
irradiation, ischemia, osmotic shock and heat shock. G-proteins activate p38
via PKA or PKC, whereas stress activates p38 via Rac and CDC42. Following its
activation, p38 translocates to the nucleus and phosphoryates ATF2. Another
known target of p38 is MAPKAPK2 (MAPK-Activated Protein Kinase-2) that is
involved in the phosphorylation and activation of heat-shock proteins. Other
transcription factors affected by the p38 family include STAT1 (Signal
Transducers and Activators of Transcription-1), Max/Myc complexes, Elk1 and
CREB through the activation of MSK1 (Mitogen- and Stress-Activated Kinase-1).
The p38 subfamily is also involved in affecting Cell Motility, Transcription
and Chromatin Remodeling. Other substrates of the p38 signaling pathway include
CHOP (C/EBP-Homologous Protein) for regulation of gene expression, as well as
MNK1 (MAPK-Interacting Kinase-1). p38 MAPK is a crucial mediator in the
NF-kappaB-dependent gene activation induced by TNF (Ref.13, 14 & 15).
The mammalian MAPK signaling system employ scaffold
proteins, in part, to organize the MAPK signaling components into functional
MAPK modules, thereby enabling the efficient activation of specific MAPK
pathways. The ERK scaffold protein KSR (Kinase Suppressor of Ras) binds ERK,
its direct activator MEK and Raf. A second targeting protein, p14, targets ERK2
to an endosomal location through its interaction with MP1 (MAPKK1-Interacting
Protein-1), an adaptor protein that binds MEK and ERK. In addition, MEKK1 (MAP/ERK
Kinase Kinase-1) can serve both as a scaffold and as MAPKKK, interacting
specifically with MAPKK and MAPK. Multidomain protein Posh (Plenty of SH3s)
acts as a scaffold for the JNK pathway. Posh binds MLKs both in vivo and in
vitro, and complexes with MKKs 4 and 7 and with JNKs. The JNK MAPK modules are
also regulated by a JIP1 (JNK Interacting Protein-1), JIP2 (JNK Interacting
Protein-2), JIP3 (JNK Interacting Protein-3), JIP4 (JNK Interacting Protein-4),
Beta-Arrestin-2, Filamin and CrkII. There is increasing evidence that the three
well-characterized members of the MAPK family, ERK1/2, JNK/SAPK and p38 play an
important role in regulation of proliferation in mammalian cells by sharing
substrate and cross-cascade interaction. MAPK pathways are involved in many
pathological conditions, including cancer and other diseases. Therefore, a
better understanding of the relationship between MAP kinase signal transduction
system and the regulation of cell proliferation is essential for the rational
design of novel pharmacotherapeutic approaches (Ref.16 & 17).
References:
1. Wada T, Penninger JM.
Mitogen-activated protein kinases in apoptosis
regulation.
Oncogene. 2004 Apr 12;23(16):2838-49.
PubMed ID: 15077147
2. Panka DJ, Atkins MB, Mier JW.
Targeting the mitogen-activated protein kinase pathway in
the treatment of malignant melanoma.
Clin Cancer Res. 2006 Apr 1;12(7 Pt 2):2371s-2375s.
PubMed ID: 16609061
3. Subramaniam S, Unsicker K.
Extracellular signal-regulated kinase as an inducer of
non-apoptotic neuronal death.
Neuroscience. 2006;138(4):1055-65. Epub 2006 Jan 25.
PubMed ID: 16442236
4. Osmond RI, Sheehan A, Borowicz R, Barnett E, Harvey G,
Turner C, Brown A, Crouch MF, Dyer AR.
GPCR screening via ERK 1/2: a novel platform for
screening G protein-coupled receptors.
J Biomol Screen. 2005 Oct;10(7):730-7.
PubMed ID: 16129779
5. Ginnan R, Guikema BJ, Singer HA, Jourd'heuil D.
PKC{delta} mediates activation of ERK1/2 and induction of
iNOS by Interleukin-1{beta} in Vascular Smooth Muscle Cells.
Am J Physiol Cell Physiol. 2006 Jan 25;
PubMed ID: 16436473
6. Chuderland D, Seger R.
Protein-protein interactions in the regulation of the
extracellular signal-regulated kinase.
Mol Biotechnol. 2005 Jan;29(1):57-74.
PubMed ID: 15668520
7. Wang X, Tournier C.
Regulation of cellular functions by the ERK5 signalling
pathway.
Cell Signal. 2006 Jun;18(6):753-60.
PubMed ID: 16376520
8. Ranganathan A, Pearson GW, Chrestensen CA, Sturgill TW,
Cobb MH.
The MAP kinase ERK5 binds to and phosphorylates p90 RSK.
Arch Biochem Biophys. 2006 May 15;449(1-2):8-16. Epub 2006
Mar 13.
PubMed ID: 16626623
9. Yang Q, Kim YS, Lin Y, Lewis J, Neckers L, Liu ZG.
Tumour necrosis factor receptor 1 mediates endoplasmic
reticulum stress-induced activation of the MAP kinase JNK.
EMBO Rep. 2006 May 5;
PubMed ID: 16680093
10. Yamauchi J, Miyamoto Y, Kokubu H, Nishii H, Okamoto M,
Sugawara Y, Hirasawa A, Tsujimoto G, Itoh H.
Endothelin suppresses cell migration via the JNK
signaling pathway in a manner dependent upon Src kinase, Rac1, and Cdc42.
FEBS Lett. 2002 Sep 11;527(1-3):284-8.
PubMed ID: 12220675
11. Heasley LE, Han SY.
JNK Regulation of Oncogenesis.
Mol Cells. 2006 Apr 30;21(2):167-73.
PubMed ID: 16682809
12. Mittelstadt PR, Salvador JM, Fornace AJ Jr, Ashwell JD.
Activating p38 MAPK: new tricks for an old kinase.
Cell Cycle. 2005 Sep;4(9):1189-92.
PubMed ID: 16103752
13. Vergarajauregui S, San Miguel A, Puertollano R.
Activation of p38 Mitogen-Activated Protein Kinase
Promotes Epidermal Growth Factor Receptor Internalization.
Traffic. 2006 Jun;7(6):686-98.
PubMed ID: 16683917
14. Kaur R, Liu X, Gjoerup O, Zhang A, Yuan X, Balk SP,
Schneider MC, Lu ML.
Activation of p21-activated kinase 6 by MAP kinase kinase
6 and p38 MAP kinase.
J Biol Chem. 2005 Feb 4;280(5):3323-30.
PubMed ID: 15550393
15. Lokuta MA, Huttenlocher A.
TNF-alpha promotes a stop signal that inhibits neutrophil
polarization and migration via a p38 MAPK pathway.
J Leukoc Biol. 2005 Jul;78(1):210-9.
PubMed ID: 15845648
16. Kortum RL, Costanzo DL, Haferbier J, Schreiner SJ,
Razidlo GL, Wu MH, Volle DJ, Mori T, Sakaue H, Chaika NV, Chaika OV, Lewis RE.
The molecular scaffold kinase suppressor of Ras 1 (KSR1)
regulates adipogenesis.
Mol Cell Biol. 2005 Sep;25(17):7592-604.
PubMed ID: 16107706
17. Moulin N, Widmann C.
Islet-brain (IB)/JNK-interacting proteins (JIPs): future
targets for the treatment of neurodegenerative diseases?
Curr Neurovasc Res. 2004 Apr;1(2):111-27.
PubMed ID: 16185188
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