Pathway: RAF activation
Reactions in pathway: RAF activation :
RAF activation
Mammals have three RAF isoforms, A, B and C, that are activated downstream of RAS and stimulate the MAPK pathway. Although CRAF (also known as RAF-1) was the first identified and remains perhaps the best studied, BRAF is most similar to the RAF expressed in other organisms. Notably, MAPK (ERK) activation is more compromised in BRAF-deficient cells than in CRAF or ARAF deficient cells (Bonner et al, 1985; Mikula et al, 2001, Huser et al, 2001, Mercer et al, 2002; reviewed in Leicht et al, 2007; Matallanas et al, 2011; Cseh et al, 2014). Consistent with its important role in MAPK pathway activation, mutations in the BRAF gene, but not in those for A- or CRAF, are associated with cancer development (Davies et al, 2002; reviewed in Leicht et al, 2007). ARAF and CRAF may have arisen through gene duplication events, and may play additional roles in MAPK-independent signaling (Hindley and Kolch, 2002; Murakami and Morrison, 2001).
Despite divergences in function, all mammalian RAF proteins share three conserved regions (CRs) and each interacts with RAS and MEK proteins, although with different affinities. The N-terminal CR1 contains a RAS-binding domain (RBD) and a cysteine-rich domain (CRD) that mediate interactions with RAS and the phospholipid membrane. CR2 contains inhibitory phosphorylation sites that impact RAS binding and RAF activation, while the C-terminal CR3 contains the bi-lobed kinase domain with its activation loop, and an adjacent upstream "N-terminal acidic motif" -S(S/G)YY in C- and A-RAF,respectively, and SSDD in B-RAF - that is required for RAF activation (Tran et al, 2005; Dhillon et al, 2002; Chong et al, 2001; Cutler et al, 1998; Chong et al, 2003; reviewed in Matallanas et al, 2011).
Regulation of RAF activity involves multiple phosphorylation and dephosphorylation events, intramolecular conformational changes, homo- and heterodimerization between RAF monomers and changes to protein binding partners, including scaffolding proteins which bring pathway members together (reviewed in Matallanas et al, 2011; Cseh et al, 2014). The details of this regulation are not completely known and differ slightly from one RAF isoform to another. Briefly, in the inactive state, RAF phosphorylation on conserved serine residues in CR2 promote an interaction with 14-3-3 dimers, maintaining the kinase in a closed conformation. Upon RAS activation, these sites are dephosphorylated, allowing the RAF CRD and RBD to bind RAS and phospholipids, facilitating membrane recruitment. RAF activation requires homo- or heterodimerization, which promotes autophosphorylation in the activation loop of the receiving monomer. Of the three isoforms, only BRAF is able to initiate this allosteric activation of other RAF monomers (Hu et al, 2013; Heidorn et al, 2010; Garnett et al, 2005). This activity depends on negative charge in the N-terminal acidic region (NtA; S(S/G)YY or SSDD) adjacent to the kinase domain. In BRAF, this region carries permanent negative charge due to the presence of the two aspartate residues in place of the tyrosine residues of A- and CRAF. In addition, unique to BRAF, one of the serine residues of the NtA is constitutively phosphorylated. In A- and CRAF, residues in this region are subject to phosphorylation by activated MEK downstream of RAF activation, establishing a positive feedback loop and allowing activated A- and CRAF monomers to act as transactivators in turn (Hu et al, 2013; reviewed in Cseh et al, 2014). RAF signaling is terminated through dephosphorylation of the NtA region and phosphorylation of the residues that mediate the inhibitory interaction with 14-3-3, promoting a return to the inactive state (reviewed in Matallanas et al, 2011; Cseh et al, 2014).
Despite divergences in function, all mammalian RAF proteins share three conserved regions (CRs) and each interacts with RAS and MEK proteins, although with different affinities. The N-terminal CR1 contains a RAS-binding domain (RBD) and a cysteine-rich domain (CRD) that mediate interactions with RAS and the phospholipid membrane. CR2 contains inhibitory phosphorylation sites that impact RAS binding and RAF activation, while the C-terminal CR3 contains the bi-lobed kinase domain with its activation loop, and an adjacent upstream "N-terminal acidic motif" -S(S/G)YY in C- and A-RAF,respectively, and SSDD in B-RAF - that is required for RAF activation (Tran et al, 2005; Dhillon et al, 2002; Chong et al, 2001; Cutler et al, 1998; Chong et al, 2003; reviewed in Matallanas et al, 2011).
Regulation of RAF activity involves multiple phosphorylation and dephosphorylation events, intramolecular conformational changes, homo- and heterodimerization between RAF monomers and changes to protein binding partners, including scaffolding proteins which bring pathway members together (reviewed in Matallanas et al, 2011; Cseh et al, 2014). The details of this regulation are not completely known and differ slightly from one RAF isoform to another. Briefly, in the inactive state, RAF phosphorylation on conserved serine residues in CR2 promote an interaction with 14-3-3 dimers, maintaining the kinase in a closed conformation. Upon RAS activation, these sites are dephosphorylated, allowing the RAF CRD and RBD to bind RAS and phospholipids, facilitating membrane recruitment. RAF activation requires homo- or heterodimerization, which promotes autophosphorylation in the activation loop of the receiving monomer. Of the three isoforms, only BRAF is able to initiate this allosteric activation of other RAF monomers (Hu et al, 2013; Heidorn et al, 2010; Garnett et al, 2005). This activity depends on negative charge in the N-terminal acidic region (NtA; S(S/G)YY or SSDD) adjacent to the kinase domain. In BRAF, this region carries permanent negative charge due to the presence of the two aspartate residues in place of the tyrosine residues of A- and CRAF. In addition, unique to BRAF, one of the serine residues of the NtA is constitutively phosphorylated. In A- and CRAF, residues in this region are subject to phosphorylation by activated MEK downstream of RAF activation, establishing a positive feedback loop and allowing activated A- and CRAF monomers to act as transactivators in turn (Hu et al, 2013; reviewed in Cseh et al, 2014). RAF signaling is terminated through dephosphorylation of the NtA region and phosphorylation of the residues that mediate the inhibitory interaction with 14-3-3, promoting a return to the inactive state (reviewed in Matallanas et al, 2011; Cseh et al, 2014).
The mitogen activated protein kinases (MAPKs) are a family of conserved protein serine threonine kinases that respond to varied extracellular stimuli to activate intracellular processes including gene expression, metabolism, proliferation, differentiation and apoptosis, among others.
The classic MAPK cascades, including the ERK1/2 pathway, the p38 MAPK pathway, the JNK pathway and the ERK5 pathway are characterized by three tiers of sequentially acting, activating kinases (reviewed in Kryiakis and Avruch, 2012; Cargnello and Roux, 2011). The MAPK kinase kinase kinase (MAPKKK), at the top of the cascade, is phosphorylated on serine and threonine residues in response to external stimuli; this phosphorylation often occurs in the context of an interaction between the MAPKKK protein and a member of the RAS/RHO family of small GTP-binding proteins. Activated MAPKKK proteins in turn phosphorylate the dual-specificity MAPK kinase proteins (MAPKK), which ultimately phosphorylate the MAPK proteins in a conserved Thr-X-Tyr motif in the activation loop.
Less is known about the activation of the atypical families of MAPKs, which include the ERK3/4 signaling cascade, the ERK7 cascade and the NLK cascade. Although the details are not fully worked out, these MAPK proteins don't appear to be phosphorylated downstream of a 3-tiered kinase system as described above (reviewed in Coulombe and Meloche, 2007; Cargnello and Roux, 2011) .
Both conventional and atypical MAPKs are proline-directed serine threonine kinases and, once activated, phosphorylate substrates in the consensus P-X-S/T-P site. Both cytosolic and nuclear targets of MAPK proteins have been identified and upon stimulation, a proportion of the phosphorylated MAPKs relocalize from the cytoplasm to the nucleus. In some cases, nuclear translocation may be accompanied by dimerization, although the relationship between these two events is not fully elaborated (reviewed in Kryiakis and Avruch, 2012; Cargnello and Roux, 2011; Plotnikov et al, 2010).
The classic MAPK cascades, including the ERK1/2 pathway, the p38 MAPK pathway, the JNK pathway and the ERK5 pathway are characterized by three tiers of sequentially acting, activating kinases (reviewed in Kryiakis and Avruch, 2012; Cargnello and Roux, 2011). The MAPK kinase kinase kinase (MAPKKK), at the top of the cascade, is phosphorylated on serine and threonine residues in response to external stimuli; this phosphorylation often occurs in the context of an interaction between the MAPKKK protein and a member of the RAS/RHO family of small GTP-binding proteins. Activated MAPKKK proteins in turn phosphorylate the dual-specificity MAPK kinase proteins (MAPKK), which ultimately phosphorylate the MAPK proteins in a conserved Thr-X-Tyr motif in the activation loop.
Less is known about the activation of the atypical families of MAPKs, which include the ERK3/4 signaling cascade, the ERK7 cascade and the NLK cascade. Although the details are not fully worked out, these MAPK proteins don't appear to be phosphorylated downstream of a 3-tiered kinase system as described above (reviewed in Coulombe and Meloche, 2007; Cargnello and Roux, 2011) .
Both conventional and atypical MAPKs are proline-directed serine threonine kinases and, once activated, phosphorylate substrates in the consensus P-X-S/T-P site. Both cytosolic and nuclear targets of MAPK proteins have been identified and upon stimulation, a proportion of the phosphorylated MAPKs relocalize from the cytoplasm to the nucleus. In some cases, nuclear translocation may be accompanied by dimerization, although the relationship between these two events is not fully elaborated (reviewed in Kryiakis and Avruch, 2012; Cargnello and Roux, 2011; Plotnikov et al, 2010).
Signal transduction is a process in which extracellular signals elicit changes in cell state and activity. Transmembrane receptors sense changes in the cellular environment by binding ligands, such as hormones and growth factors, or reacting to other types of stimuli, such as light. Stimulation of transmembrane receptors leads to their conformational change which propagates the signal to the intracellular environment by activating downstream signaling cascades. Depending on the cellular context, this may impact cellular proliferation, differentiation, and survival. On the organism level, signal transduction regulates overall growth and behavior.
Receptor tyrosine kinases (RTKs) transmit extracellular signals by phosphorylating their protein partners on conserved tyrosine residues. Some of the best studied RTKs are EGFR (reviewed in Avraham and Yarden, 2011), FGFR (reviewed in Eswarakumar et al, 2005), insulin receptor (reviewed in Saltiel and Kahn, 2001), NGF (reviewed in Reichardt, 2006), PDGF (reviewed in Andrae et al, 2008) and VEGF (reviewed in Xie et al, 2004). RTKs frequently activate downstream signaling through RAF/MAP kinases (reviewed in McKay and Morrison, 2007 and Wellbrock et al 2004), AKT (reviewed in Manning and Cantley, 2007) and PLC- gamma (reviewed in Patterson et al, 2005), which ultimately results in changes in gene expression and cellular metabolism.
Receptor serine/threonine kinases of the TGF-beta family, such as TGF-beta receptors (reviewed in Kang et al. 2009) and BMP receptors (reviewed in Miyazono et al. 2009), transmit extracellular signals by phosphorylating regulatory SMAD proteins on conserved serine and threonine residues. This leads to formation of complexes of regulatory SMADs and SMAD4, which translocate to the nucleus where they act as transcription factors.
WNT receptors transmit their signal through beta-catenin. In the absence of ligand, beta-catenin is constitutively degraded in a ubiquitin-dependent manner. WNT receptor stimulation releases beta-catenin from the destruction complex, allowing it to translocate to the nucleus where it acts as a transcriptional regulator (reviewed in MacDonald et al, 2009 and Angers and Moon, 2009). WNT receptors were originally classified as G-protein coupled receptors (GPCRs). Although they are structurally related, GPCRs primarily transmit their signals through G-proteins, which are trimers of alpha, beta and gamma subunits. When a GPCR is activated, it acts as a guanine nucleotide exchange factor, catalyzing GDP to GTP exchange on the G-alpha subunit of the G protein and its dissociation from the gamma-beta heterodimer. The G-alpha subunit regulates the activity of adenylate cyclase, while the gamma-beta heterodimer can activate AKT and PLC signaling (reviewed in Rosenbaum et al. 2009, Oldham and Hamm 2008, Ritter and Hall 2009).
NOTCH receptors are activated by transmembrane ligands expressed on neighboring cells, which results in cleavage of NOTCH receptor and release of its intracellular domain. NOTCH intracellular domain translocates to the nucleus where it acts as a transcription factor (reviewed in Kopan and Ilagan, 2009).
Integrins are activated by extracellular matrix components, such as fibronectin and collagen, leading to conformational change and clustering of integrins on the cell surface. This results in activation of integrin-linked kinase and other cytosolic kinases and, in co-operation with RTK signaling, regulates survival, proliferation and cell shape and adhesion (reviewed in Hehlgans et al, 2007) .
Besides inducing changes in gene expression and cellular metabolism, extracellular signals that trigger the activation of Rho GTP-ases can trigger changes in the organization of cytoskeleton, thereby regulating cell polarity and cell-cell junctions (reviewed in Citi et al, 2011).
Receptor tyrosine kinases (RTKs) transmit extracellular signals by phosphorylating their protein partners on conserved tyrosine residues. Some of the best studied RTKs are EGFR (reviewed in Avraham and Yarden, 2011), FGFR (reviewed in Eswarakumar et al, 2005), insulin receptor (reviewed in Saltiel and Kahn, 2001), NGF (reviewed in Reichardt, 2006), PDGF (reviewed in Andrae et al, 2008) and VEGF (reviewed in Xie et al, 2004). RTKs frequently activate downstream signaling through RAF/MAP kinases (reviewed in McKay and Morrison, 2007 and Wellbrock et al 2004), AKT (reviewed in Manning and Cantley, 2007) and PLC- gamma (reviewed in Patterson et al, 2005), which ultimately results in changes in gene expression and cellular metabolism.
Receptor serine/threonine kinases of the TGF-beta family, such as TGF-beta receptors (reviewed in Kang et al. 2009) and BMP receptors (reviewed in Miyazono et al. 2009), transmit extracellular signals by phosphorylating regulatory SMAD proteins on conserved serine and threonine residues. This leads to formation of complexes of regulatory SMADs and SMAD4, which translocate to the nucleus where they act as transcription factors.
WNT receptors transmit their signal through beta-catenin. In the absence of ligand, beta-catenin is constitutively degraded in a ubiquitin-dependent manner. WNT receptor stimulation releases beta-catenin from the destruction complex, allowing it to translocate to the nucleus where it acts as a transcriptional regulator (reviewed in MacDonald et al, 2009 and Angers and Moon, 2009). WNT receptors were originally classified as G-protein coupled receptors (GPCRs). Although they are structurally related, GPCRs primarily transmit their signals through G-proteins, which are trimers of alpha, beta and gamma subunits. When a GPCR is activated, it acts as a guanine nucleotide exchange factor, catalyzing GDP to GTP exchange on the G-alpha subunit of the G protein and its dissociation from the gamma-beta heterodimer. The G-alpha subunit regulates the activity of adenylate cyclase, while the gamma-beta heterodimer can activate AKT and PLC signaling (reviewed in Rosenbaum et al. 2009, Oldham and Hamm 2008, Ritter and Hall 2009).
NOTCH receptors are activated by transmembrane ligands expressed on neighboring cells, which results in cleavage of NOTCH receptor and release of its intracellular domain. NOTCH intracellular domain translocates to the nucleus where it acts as a transcription factor (reviewed in Kopan and Ilagan, 2009).
Integrins are activated by extracellular matrix components, such as fibronectin and collagen, leading to conformational change and clustering of integrins on the cell surface. This results in activation of integrin-linked kinase and other cytosolic kinases and, in co-operation with RTK signaling, regulates survival, proliferation and cell shape and adhesion (reviewed in Hehlgans et al, 2007) .
Besides inducing changes in gene expression and cellular metabolism, extracellular signals that trigger the activation of Rho GTP-ases can trigger changes in the organization of cytoskeleton, thereby regulating cell polarity and cell-cell junctions (reviewed in Citi et al, 2011).