The MAPK (Mitogen-Activated Protein Kinase) pathway is one
of the primordial signaling systems that nature has used in several
permutations to accomplish an amazing variety of tasks. It exists in all
eukaryotes, and controls such fundamental cellular processes as Proliferation,
Differentiation, Survival and Apoptosis. Mammalian MAPK can be divided into
four groups based on their structure and function: ERKs (Extracellular
signal-Regulated Kinases), p38MAPKs, JNKs (c-Jun NH2-terminal Kinases) and ERK5
(Extracellular signal-Regulated Kinase-5) or BMK. Activation of these MAPKs
occurs through a cascade of upstream kinases; a MAPKKK (MAPK Kinase Kinase)
first phosphorylates a dual-specificity protein kinase MAPKK (MAPK Kinase),
which in turn phosphorylates the MAPK. This set-up provides not only for signal
amplification, but, maybe even more importantly, for additional regulatory
interfaces that allow the kinetics, duration and amplitude of the activity to
be precisely tuned. ERK, a member of the MAPK family, have been established as
major participants in the regulation of cell growth and differentiation, but
when improperly activated contribute to malignant transformation. ERK1 and 2
form a central component in the MAPK cascade. The MAPK/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. The specific components of the cascade
vary greatly among different stimuli, but the architecture of the pathway
usually includes a set of adaptors like SHC, GRB2 (Growth Factor Receptor Bound
protein-2), Crk, etc. linking the receptor to a GEF (Guanine nucleotide
Exchange Factor) like SOS (Son of Sevenless), C3G, etc. transducing the signal
to small GTP binding proteins (Ras, Rap1), which in turn activate the core unit
of the cascade composed of a MAPKKK (Raf), a MAPKK (MEK1/2 (MAPK/ERK
Kinase-1/2)) and MAPK (ERK). An activated ERK dimer can regulate targets in the
cytosol and also translocate to the nucleus where it phosphorylates a variety
of transcription factors regulating gene expression (Ref.1 & 2).
GPCRs constitute a superfamily of Plasma membrane receptors.
Members of this family include receptors for many Hormones, Neurotransmitters,
Chemokines and Calcium ion, as well as sensory receptors for various odors, and
bitter and sweet tastes. GPCR play an important role in activation of ERKs.
Stimulation of the GN-AlphaI (Guanine Nucleotide Binding Protein-Alpha
Inhibiting Activity Polypeptide)-coupled Neuropeptide Y1 and GN-AlphaQ (Guanine
Nucleotide-Binding Protein-Alpha-Q) -coupled Muscarinic M1 Acetylcholine
Receptors lead to the activation of ERK. When the GPCR becomes activated, it
leads to the exchange of GDP for GTP on the GN-Alpha subunit. Upon activation,
GN-AlphaI or GN-AlphaQ 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 activate PI3K
(Phosphatidylinositide-3 Kinase) and c-Src and modulate their activity through
stimulation of Ras under the influence of many extracellular factors. Rac is
also a key downstream target/effector of PI3K. A new mechanism have been
identified that regulates MEK1-ERK interactions and is dependent on Rac and PAK
(p21-Activated Kinase). Besides GN-Alpha subunit, GN-Beta Gamma complex can
also lead to activation of ERK. GN-Beta and GN-Gamma subunits when activated
separate from GN-alpha subunit and it further activates PKC (Protein Kinase-C)
via PLC-Beta (Phospholipase-C-Beta). PLC-Beta converts PIP2
(Phosphatidylinositol 4,5-bisphosphate) to DAG (Diacylglycerol), which
activates PKC. PKC once formed can activate ERKs via Ras, Raf and MEKs. PKC
also activates Src-PYK2 (Proline-Rich Tyrosine Kinase-2) complex which
activates GRB2, which is also involved in ERK activation (Ref.3 & 4).
The canonical ERK MAPK cascade is also stimulated upon the
binding of extracellular Growth factors to their respective transmembrane RTKs
(Receptor Tyrosine Kinases). 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-SOS
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 kinase MEK. MEK binds and
restricts inactive ERK to the cytosol. The MEK and ERK complex dissociates when
MEK is activated and phosphorylates ERK. The ERK may then dimerize and this
dimerization is apparently required for ERK to translocate into the nucleus by
an active functions. Growth Factors may also activate ERK through PLC-Gamma and
PKC. Integrins also play an important role in regulating the efficiency of the
RTK/Ras/ERK pathway. Integrin regulation occurs at three (or more) different
loci within the ERK pathway. First, in some cell systems, Integrin engagement
with ligands enhances the activation and autophosphorylation of the RTKs.
Secondly, Integrin engagement enhances the efficiency of the cytoplasmic
cascade comprising Raf1, MEK and ERK. Finally, Integrin engagement is necessary
for trafficking of activated ERK from the cytoplasm to the nucleus. 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 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. The non-receptor tyrosine
kinase PYK2 appears to function at a point of convergence of Integrins and
certain GPCR signaling cascades. PYK2 acts with Src to link GN-AlphaI- and
GN-AlphaQ-coupled receptors with GRB2 and SOS to activate the ERK signalling
pathway (Ref. 5 & 6).
TCR (T-Cell Receptor)-CD3 complex also plays an important
role in regulating ERK pathways in T-Cells. VHR is particularly interesting
from a TCR signalling point of view because it accumulates at the T-Cell/APC
(Antigen-Presenting-Cell) contact site, where it is phosphorylated at Tyr-138
by ZAP70 (Zeta-Chain-Associated Protein Kinase). This phosphorylation is
required for VHR to inhibit the ERK MAPKs, giving ZAP70 an unanticipated
control over MAPK dephosphorylation, in addition to its role as upstream
activator of the Ras/Raf/MEK pathway. Other negative regulators of ERK pathway
include PP2A (Protein Phosphatase-2A) and MKPs (MAPK Phosphatase). PP2A
inhibits ERK pathway by dephosphorylating MEKs and is involved in the control
of many cellular functions including metabolism, transcription, translation,
RNA splicing, DNA replication, cell cycle progression, transformation, and
apoptosis. 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. In unstimulated cells KSR is mainly cytoplasmic but translocates
to the Plasma membrane after growth factor stimulation, thus targeting MEK and
ERK to the plasma membrane. 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 (Ref.5, 7 & 8).
ERK once activated can either translocate to the nucleus to
phosphorylate and activate transcription factors, while other pools of
activated ERK phosphorylate a number of cytoplasmic targets. Cytosolic
substrates for ERK include several pathway components involved in ERK negative
feedback regulation. Multiple residues on SOS are phosphorylated by ERK
following growth factor stimulation. SOS phosphorylation destabilizes the
SOS-GRB2 complex, eliminating SOS recruitment to the plasma membrane and
interfering with Ras activation of the ERK pathway. Negative feedback by ERK
also occurs through direct phosphorylation of the EGF (Epidermal Growth Factor)
receptor at Thr669. Finally, ERKs have also been demonstrated to negatively
regulate themselves by phosphorylating MKPs (MAP Kinase Phosphatases) , which
reduces the degradation of these phosphatases through the Ubiquitin-directed
Proteasome complex. ERK also activate MNKs (MAPK-Interacting Kinases) by
phosphorylation at Thr197 and Thr202. MNKs upregulate eIF4E (eukaryotic
initiation factor-4E) through phosphorylation at Ser209 and play an important
role in translation or they may also phosphorylate PLA2 (Phospholipase-A2).
ERK1 and ERK2 regulate transcription indirectly by phosphorylating the RSKs (90
kDa Ribosomal protein S6 Kinases). 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. p90RSK also play an important role in cell survival by
phosphorylating BAD (Bcl2-Antagonist of Cell Death). Another important
cytoplasmic target of ERK is IKK-Alpha (I-KappaB Kinase-Alpha). IKK-Alpha
phosphorylates I-KappaB-Alpha, which leads to ubiquitination and then leads to
the degradation of I-KappaB-Alpha by the Proteosome, resulting in the
translocation of NF-KappaB to the nucleus. In the nucleus it 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 (Ref.9, 10 & 11).
Upon phosphorylation, nuclear translocation of ERK1 and ERK2
is critical for both gene expression and DNA replication induced by growth
factors. In the nucleus, ERK phosphorylates an array of targets, including
transcription factors and a family of RSK-related kinases, the MSKs (Mitogen-
and Stress-activated protein Kinases). MSKs phosphorylate and activate the AP1
component ATF1 (Activating Transcription Factor-1) at Ser63, and may be more
important in vivo than RSKs in CREB phosphorylation at the activating Ser133.
MSKs were also found to phosphorylate Histone H3 at Ser10 and Ser28, and the
HMG14 (High-Mobility-Group protein-14) at Ser6, facilitating the rapid
induction of immediate early genes following mitogenic stimulation. Probably
the best-characterized transcription factor substrates of ERKs are TCFs
(Ternary Complex Factors), including Elk1, which is directly phosphorylated by
ERK1 and ERK2 at multiple sites, including the activating Ser383. Upon complex
formation with SRF, phosphorylated TCFs transcriptionally activate the numerous
Mitogen-inducible genes regulated by SREs (Serum Response Elements). TCFs Sap1
and Sap2 are also phosphorylated by ERK, as are other Ets family members.
Another direct target of ERK is the product of proto-oncogene c-Myc, a
short-lived transcription factor involved in multiple aspects of growth
control. Following phosphorylation at Thr58 and Ser62 within its
transactivation domain, Myc activates transcription as a heterodimeric partner
with Max. ERK can also phosphorylate CREB directly as well as AP1 components
c-Jun and c-Fos. ERK1/2 also phosphorylates MLCK (Myosin Light Polypeptide
Kinase), Capn (Calpain), Pax6 (Paxillin-6) and FAK that play important role in
Cytoskeletal rearrangement. Other ERK targets include STAT1/3 (Signal
Transducer and Activator of Transcription-1/3) and ESR (Estrogen Receptor). Finally,
it can be concluded that ERKs are involved in the regulation of important
neuronal functions, including neuronal plasticity in normal and pathological
conditions. The kinetics and localization of ERK are intrinsically linked, in
that the duration of ERK activation dictates its subcellular
compartmentalization and/or trafficking. The latter, in turn, dictates whether
ERK-expressing cells would enter a program of cell death, survival or
differentiation. With aberrations in the ERK cascade implicated in a high
proportion of human cancers, many emerging therapies target proteins in the
pathway. As these candidate therapies against ERK signaling components undergo
development and enter trials, reagents that monitor their targets' inhibition
are critical for future success (Ref.12, 13 & 14).
References:
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Mitogen-activated protein kinases in apoptosis
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PubMed ID: 16517979
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