The Experts below are selected from a list of 261 Experts worldwide ranked by ideXlab platform
Robert Roskoski - One of the best experts on this subject based on the ideXlab platform.
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Targeting ERK1/2 protein-serine/threonine Kinases in human cancers.
Pharmacological Research, 2019Co-Authors: Robert RoskoskiAbstract:Abstract ERK1 and ERK2 are key protein Kinases that contribute to the Ras-Raf-MEK-ERK MAP kinase signalling module. This pathway participates in the control of numerous processes including apoptosis, cell proliferation, the immune response, nervous system function, and RNA synthesis and processing. MEK1/2 activate human ERK1/2 by first catalyzing the phosphorylation of Y204/187 and then T202/185, both residues of which occur within the activation segment. The phosphorylation of both residues is required for enzyme activation. The only Raf substrates are MEK1/2 and the only MEK1/2 substrates are ERK1/2. In contrast, ERK1/2 catalyze the phosphorylation of many cytoplasmic and nuclear substrates including transcription factors and regulatory molecules. The linear MAP kinase pathway branches extensively at the ERK1/2 node. ERK1/2 are proline-directed Kinases that preferentially catalyze the phosphorylation of substrates containing a PxS/TP sequence. The dephosphorylation and inactivation of ERK1/2 is catalyzed by dual specificity phosphatases, protein-tyrosine specific phosphatases, and protein-serine/threonine phosphatases. The combined functions of Kinases and phosphatases make the overall process reversible. To provide an idea of the complexities involved in these reactions, somatic cell cycle progression involves the strict timing of more than 32,000 phosphorylation and dephosphorylation events as determined by mass spectrometry. The MAP kinase cascade is perhaps the most important oncogenic driver of human cancers and the blockade of this signalling module by targeted inhibitors is an important anti-tumor strategy. Although numerous cancers are driven by MAP kinase pathway activation, thus far the only orally effective approved drugs that target this signaling module are used for the treatment of BRAF-mutant melanomas. The best treatments include the combination of B-Raf and MEK inhibitors (dabrafenib and trametinib, encorafenib and binimetinib, vemurafenib and cobimetanib). However, resistance to these antagonists occurs within one year and additional treatment options are necessary. Owing to the large variety of malignancies that are driven by dysregulation of the MAP kinase pathway, additional tumor types should be amenable to MAP kinase pathway inhibitor therapy. In addition to new B-Raf and MEK inhibitors, the addition of ERK inhibitors should prove helpful. Ulixertinib, MK-8353, and GDC-0994 are orally effective, potent, and specific inhibitors of ERK1/2 that are in early clinical trials for the treatment of various advanced/metastatic solid tumors. These agents are effective against cell lines that are resistant to B-Raf and MEK1/2 inhibitor therapy. Although MK-8353 does not directly inhibit MEK1/2, it decreases the phosphorylation of ERK1/2 as well as the phosphorylation of RSK, an ERK1/2 substrate. The decrease in RSK phosphorylation appears to be a result of ERK inhibition and the decrease in ERK1/2 phosphorylation is related to the inability of MEK to catalyze the phosphorylation of the ERK–MK-8353 complex; these decreases characterize the ERK dual mechanism inhibition paradigm. Additional work will be required to determine whether ERK inhibitors will be successful in the clinic and are able to forestall the development of drug resistance of the MAP kinase pathway.
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Targeting oncogenic Raf protein-serine/threonine Kinases in human cancers.
Pharmacological Research, 2018Co-Authors: Robert RoskoskiAbstract:The Ras-Raf-MEK-ERK signal transduction cascade is arguably the most important oncogenic pathway in human cancers. Ras-GTP promotes the formation of active homodimers or heterodimers of A-Raf, B-Raf, and C-Raf by an intricate process. These enzymes are protein-serine/threonine Kinases that catalyze the phosphorylation and activation of MEK1 and MEK2 which, in turn, catalyze the phosphorylation and activation of ERK1 and ERK2. The latter catalyze the regulatory phosphorylation of dozens of cytosolic and nuclear proteins. The X-ray crystal structure of B-Raf-MEK1 depicts a face-to-face dimer with interacting activation segments; B-Raf is in an active conformation and MEK1 is in an inactive conformation. Besides the four traditional components in the Ras-Raf-MEK-ERK signaling module, scaffolding proteins such as Kinase Suppressor of Ras (KSR1/2) play an important role in this signaling cascade by functioning as a scaffold protein. RAS mutations occur in about 30% of all human cancers. Moreover, BRAFV600E mutations occur in about 8% of all cancers making this the most prevalent oncogenic protein kinase. Vemurafenib and dabrafenib are B-RafV600E inhibitors that were approved for the treatment of melanomas bearing the V600E mutation. Coupling MEK1/2 inhibitors with B-Raf inhibitors is more effective in treating such melanomas and dual therapy is now the standard of care. Vemurafenib and cobimetanib, dabrafenib and trametinib, and encorafenib plus binimetinib are the FDA-approved combinations for the treatment of BRAFV600E melanomas. Although such mutations occur in other neoplasms including thyroid, colorectal, and non-small cell lung cancers, these agents are not as effective in treating these non-melanoma neoplasms. Vemurafenib and dabrafenib produce the paradoxical activation of the MAP kinase pathway in wild type BRAF cells. The precise mechanism for this activation is unclear, but drug-induced Raf activating side-to-side dimerization appears to be an essential step. Although 63%-76% of all people with advanced melanoma with the BRAF V600E mutation derive clinical benefit from combination therapy, median progression-free survival lasts only about nine months and 90% of patients develop resistance within one year. The various secondary resistance mechanisms include NRAS or KRAS mutations (20%), BRAF splice variants (16%), BRAFV600E/K amplifications (13%), MEK1/2 mutations (7%), and non-MAP kinase pathway alterations (11%). Vemurafenib and dabrafenib bind to an inactive form of B-Raf (αC-helixout and DFG-Din) and are classified as type I½ inhibitors. LY3009120 and lifirafenib, which are in the early drug-development stage, bind to a different inactive form of B-Raf (DFG-Dout) and are classified as type II inhibitors. Besides targeting B-Raf and MEK protein Kinases, immunotherapies that include ipilimumab, pembrolizumab, and nivolumab have been FDA-approved for the treatment of melanomas. Current clinical trials are underway to determine the optimal usage of targeted and immunotherapies.
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ERK1/2 MAP Kinases: Structure, function, and regulation
Pharmacological Research, 2012Co-Authors: Robert RoskoskiAbstract:ERK1 and ERK2 are related protein-serine/threonine Kinases that participate in the Ras-Raf-MEK-ERK signal transduction cascade. This cascade participates in the regulation of a large variety of processes including cell adhesion, cell cycle progression, cell migration, cell survival, differentiation, metabolism, proliferation, and transcription. MEK1/2 catalyze the phosphorylation of human ERK1/2 at Tyr204/187 and then Thr202/185. The phosphorylation of both tyrosine and threonine is required for enzyme activation. Whereas the Raf kinase and MEK families have narrow substrate specificity, ERK1/2 catalyze the phosphorylation of hundreds of cytoplasmic and nuclear substrates including regulatory molecules and transcription factors. ERK1/2 are proline-directed Kinases that preferentially catalyze the phosphorylation of substrates containing a Pro-Xxx-Ser/Thr-Pro sequence. Besides this primary structure requirement, many ERK1/2 substrates possess a D-docking site, an F-docking site, or both. A variety of scaffold proteins including KSR1/2, IQGAP1, MP1, β-Arrestin1/2 participate in the regulation of the ERK1/2 MAP kinase cascade. The regulatory dephosphorylation of ERK1/2 is mediated by protein-tyrosine specific phosphatases, protein-serine/threonine phosphatases, and dual specificity phosphatases. The combination of Kinases and phosphatases make the overall process reversible. The ERK1/2 catalyzed phosphorylation of nuclear transcription factors including those of Ets, Elk, and c-Fos represents an important function and requires the translocation of ERK1/2 into the nucleus by active and passive processes involving the nuclear pore. These transcription factors participate in the immediate early gene response. The activity of the Ras-Raf-MEK-ERK cascade is increased in about one-third of all human cancers, and inhibition of components of this cascade by targeted inhibitors represents an important anti-tumor strategy. Thus far, however, only inhibition of mutant B-Raf (Val600Glu) has been found to be therapeutically efficacious. © 2012 Elsevier Ltd. All rights reserved.
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raf protein serine threonine Kinases structure and regulation
Biochemical and Biophysical Research Communications, 2010Co-Authors: Robert RoskoskiAbstract:A-RAF, B-RAF, and C-RAF are a family of three protein-serine/threonine Kinases that participate in the RAS-RAF-MEK-ERK signal transduction cascade. This cascade participates in the regulation of a large variety of processes including apoptosis, cell cycle progression, differentiation, proliferation, and transformation to the cancerous state. RAS mutations occur in 15–30% of all human cancers, and B-RAF mutations occur in 30–60% of melanomas, 30–50% of thyroid cancers, and 5–20% of colorectal cancers. Activation of the RAF Kinases requires their interaction with RAS-GTP along with dephosphorylation and also phosphorylation by SRC family protein-tyrosine Kinases and other protein-serine/threonine Kinases. The formation of unique side-to-side RAF dimers is required for full kinase activity. RAF kinase inhibitors are effective in blocking MEK1/2 and ERK1/2 activation in cells containing the oncogenic B-RAF Val600Glu activating mutation. RAF kinase inhibitors lead to the paradoxical increase in RAF kinase activity in cells containing wild-type B-RAF and wild-type or activated mutant RAS. C-RAF plays a key role in this paradoxical increase in downstream MEK-ERK activation.
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RAF protein-serine/threonine Kinases: Structure and regulation
Biochemical and Biophysical Research Communications, 2010Co-Authors: Robert RoskoskiAbstract:A-RAF, B-RAF, and C-RAF are a family of three protein-serine/threonine Kinases that participate in the RAS-RAF-MEK-ERK signal transduction cascade. This cascade participates in the regulation of a large variety of processes including apoptosis, cell cycle progression, differentiation, proliferation, and transformation to the cancerous state. RAS mutations occur in 15–30% of all human cancers, and B-RAF mutations occur in 30–60% of melanomas, 30–50% of thyroid cancers, and 5–20% of colorectal cancers. Activation of the RAF Kinases requires their interaction with RAS-GTP along with dephosphorylation and also phosphorylation by SRC family protein-tyrosine Kinases and other protein-serine/threonine Kinases. The formation of unique side-to-side RAF dimers is required for full kinase activity. RAF kinase inhibitors are effective in blocking MEK1/2 and ERK1/2 activation in cells containing the oncogenic B-RAF Val600Glu activating mutation. RAF kinase inhibitors lead to the paradoxical increase in RAF kinase activity in cells containing wild-type B-RAF and wild-type or activated mutant RAS. C-RAF plays a key role in this paradoxical increase in downstream MEK-ERK activation.
E. Van Obberghen - One of the best experts on this subject based on the ideXlab platform.
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Modulation of insulin action
Diabetologia, 2004Co-Authors: Luciano Pirola, A M Johnston, E. Van ObberghenAbstract:Insulin is a key hormone regulating the control of metabolism and the maintenance of normoglycaemia and normolipidaemia. Insulin acts by binding to its cell surface receptor, thus activating the receptor's intrinsic tyrosine kinase activity, resulting in receptor autophosphorylation and phosphorylation of several substrates. Tyrosine phosphorylated residues on the receptor itself and on subsequently bound receptor substrates provide docking sites for downstream signalling molecules, including adapters, protein serine/threonine Kinases, phosphoinositide Kinases and exchange factors. Collectively, those molecules orchestrate the numerous insulin-mediated physiological responses. A clear picture is emerging of the way in which insulin elicits several intracellular signalling pathways to mediate its physiologic functions. A further challenge, being pursued by several laboratories, is to understand the molecular mechanisms that underlie insulin action at the peripheral level, deregulation of which ultimately leads to hyperglycaemia and Type 2 diabetes. We review how circulating factors such as insulin itself, TNF-alpha, interleukins, fatty acids and glycation products influence insulin action through insulin signalling molecules themselves or through other pathways ultimately impinging on the insulin-signalling pathway. Understanding how the mechanism by which molecular insulin action is modulated by these factors will potentially provide new targets for pharmacological agents, to enable the control of altered glucose and lipid metabolism and diabetes.
Joseph R Testa - One of the best experts on this subject based on the ideXlab platform.
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akt2 a putative oncogene encoding a member of a subfamily of protein serine threonine Kinases is amplified in human ovarian carcinomas
Proceedings of the National Academy of Sciences of the United States of America, 1992Co-Authors: Jin Quan Cheng, Andrew K Godwin, Alfonso Bellacosa, Takahiro Taguchi, Thomas F Franke, Thomas C Hamilton, Philip N Tsichlis, Joseph R TestaAbstract:We isolated cDNA clones containing the entire coding region of the putative oncogene AKT2. Sequence analysis and in vitro translation demonstrated that AKT2 encodes a 56-kDa protein with homology to serine/threonine Kinases; moreover, this protein contains a Src homology 2-like domain. AKT2 was shown to be amplified and overexpressed in 2 of 8 ovarian carcinoma cell lines and 2 of 15 primary ovarian tumors. AKT2 was mapped to chromosome region 19q13.1-q13.2 by fluorescence in situ hybridization. In the two ovarian carcinoma cell lines exhibiting amplification of AKT2, the amplified sequences were localized within homogeneously staining regions. We conclude that AKT2 belongs to a distinct subfamily of protein-serine/threonine Kinases containing Src homology 2-like domains and that alterations of AKT2 may contribute to the pathogenesis of ovarian carcinomas.
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AKT2, a putative oncogene encoding a member of a subfamily of protein-serine/threonine Kinases, is amplified in human ovarian carcinomas.
Proceedings of the National Academy of Sciences of the United States of America, 1992Co-Authors: Jin Quan Cheng, Andrew K Godwin, Alfonso Bellacosa, Takahiro Taguchi, Thomas F Franke, Thomas C Hamilton, Philip N Tsichlis, Joseph R TestaAbstract:We isolated cDNA clones containing the entire coding region of the putative oncogene AKT2. Sequence analysis and in vitro translation demonstrated that AKT2 encodes a 56-kDa protein with homology to serine/threonine Kinases; moreover, this protein contains a Src homology 2-like domain. AKT2 was shown to be amplified and overexpressed in 2 of 8 ovarian carcinoma cell lines and 2 of 15 primary ovarian tumors. AKT2 was mapped to chromosome region 19q13.1-q13.2 by fluorescence in situ hybridization. In the two ovarian carcinoma cell lines exhibiting amplification of AKT2, the amplified sequences were localized within homogeneously staining regions. We conclude that AKT2 belongs to a distinct subfamily of protein-serine/threonine Kinases containing Src homology 2-like domains and that alterations of AKT2 may contribute to the pathogenesis of ovarian carcinomas.
Luciano Pirola - One of the best experts on this subject based on the ideXlab platform.
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Modulation of insulin action
Diabetologia, 2004Co-Authors: Luciano Pirola, A M Johnston, E. Van ObberghenAbstract:Insulin is a key hormone regulating the control of metabolism and the maintenance of normoglycaemia and normolipidaemia. Insulin acts by binding to its cell surface receptor, thus activating the receptor’s intrinsic tyrosine kinase activity, resulting in receptor autophosphorylation and phosphorylation of several substrates. Tyrosine phosphorylated residues on the receptor itself and on subsequently bound receptor substrates provide docking sites for downstream signalling molecules, including adapters, protein serine/threonine Kinases, phosphoinositide Kinases and exchange factors. Collectively, those molecules orchestrate the numerous insulin-mediated physiological responses.
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Modulation of insulin action
Diabetologia, 2004Co-Authors: Luciano Pirola, A M Johnston, E. Van ObberghenAbstract:Insulin is a key hormone regulating the control of metabolism and the maintenance of normoglycaemia and normolipidaemia. Insulin acts by binding to its cell surface receptor, thus activating the receptor's intrinsic tyrosine kinase activity, resulting in receptor autophosphorylation and phosphorylation of several substrates. Tyrosine phosphorylated residues on the receptor itself and on subsequently bound receptor substrates provide docking sites for downstream signalling molecules, including adapters, protein serine/threonine Kinases, phosphoinositide Kinases and exchange factors. Collectively, those molecules orchestrate the numerous insulin-mediated physiological responses. A clear picture is emerging of the way in which insulin elicits several intracellular signalling pathways to mediate its physiologic functions. A further challenge, being pursued by several laboratories, is to understand the molecular mechanisms that underlie insulin action at the peripheral level, deregulation of which ultimately leads to hyperglycaemia and Type 2 diabetes. We review how circulating factors such as insulin itself, TNF-alpha, interleukins, fatty acids and glycation products influence insulin action through insulin signalling molecules themselves or through other pathways ultimately impinging on the insulin-signalling pathway. Understanding how the mechanism by which molecular insulin action is modulated by these factors will potentially provide new targets for pharmacological agents, to enable the control of altered glucose and lipid metabolism and diabetes.
A M Johnston - One of the best experts on this subject based on the ideXlab platform.
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Modulation of insulin action
Diabetologia, 2004Co-Authors: Luciano Pirola, A M Johnston, E. Van ObberghenAbstract:Insulin is a key hormone regulating the control of metabolism and the maintenance of normoglycaemia and normolipidaemia. Insulin acts by binding to its cell surface receptor, thus activating the receptor’s intrinsic tyrosine kinase activity, resulting in receptor autophosphorylation and phosphorylation of several substrates. Tyrosine phosphorylated residues on the receptor itself and on subsequently bound receptor substrates provide docking sites for downstream signalling molecules, including adapters, protein serine/threonine Kinases, phosphoinositide Kinases and exchange factors. Collectively, those molecules orchestrate the numerous insulin-mediated physiological responses.
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Modulation of insulin action
Diabetologia, 2004Co-Authors: Luciano Pirola, A M Johnston, E. Van ObberghenAbstract:Insulin is a key hormone regulating the control of metabolism and the maintenance of normoglycaemia and normolipidaemia. Insulin acts by binding to its cell surface receptor, thus activating the receptor's intrinsic tyrosine kinase activity, resulting in receptor autophosphorylation and phosphorylation of several substrates. Tyrosine phosphorylated residues on the receptor itself and on subsequently bound receptor substrates provide docking sites for downstream signalling molecules, including adapters, protein serine/threonine Kinases, phosphoinositide Kinases and exchange factors. Collectively, those molecules orchestrate the numerous insulin-mediated physiological responses. A clear picture is emerging of the way in which insulin elicits several intracellular signalling pathways to mediate its physiologic functions. A further challenge, being pursued by several laboratories, is to understand the molecular mechanisms that underlie insulin action at the peripheral level, deregulation of which ultimately leads to hyperglycaemia and Type 2 diabetes. We review how circulating factors such as insulin itself, TNF-alpha, interleukins, fatty acids and glycation products influence insulin action through insulin signalling molecules themselves or through other pathways ultimately impinging on the insulin-signalling pathway. Understanding how the mechanism by which molecular insulin action is modulated by these factors will potentially provide new targets for pharmacological agents, to enable the control of altered glucose and lipid metabolism and diabetes.
