Mutations in RAS oncogenes occur inâ??~â??30% of human cancers, with KRAS being the most frequently altered isoform. RAS proteins comprise a conserved GTPase domain and a C-terminal lipid-modified tail that is unique to each isoform. The GTPase domain is a â??switchâ?? that regulates multiple signaling cascades that drive cell growth and proliferation when activated by binding GTP, and the signal is terminated by GTP hydrolysis. Oncogenic RAS mutations disrupt the GTPase cycle, leading to accumulation of the activated GTP-bound state and promoting proliferation. RAS is a key target in oncology, however it lacks classic druggable pockets and has been extremely challenging to target. RAS signaling has thus been targeted indirectly, by harnessing key downstream effectors as well as upstream regulators, or disrupting the proper membrane localization required for signaling, by inhibiting either lipid modification or â??carrierâ?? proteins. As a small (20Â*kDa) protein with multiple conformers in dynamic equilibrium, RAS is an excellent candidate for NMR-driven characterization and screening for direct inhibitors. Several molecules have been discovered that bind RAS and stabilize shallow pockets through conformational selection, and recent compounds have achieved substantial improvements in affinity. NMR-derived insight into targeting the RAS-membrane interface has revealed a new strategy to enhance the potency of small molecules, while another approach has been development of peptidyl inhibitors that bind through large interfaces rather than deep pockets. Remarkable progress has been made with mutation-specific covalent inhibitors that target the thiol of a G12C mutant, and these are now in clinical trials. Here we review the history of RAS inhibitor development and highlight the utility of NMR and integrated biophysical approaches in RAS drug discovery.
The past, present, and future of 1.26 T2
From The DNP-NMR Blog:
The past, present, and future of 1.26 T2
This article is not directly related to DNP-NMR spectroscopy but offers some very valuable insight how to optimize acquisition parameters.
Rovnyak, David. “The Past, Present, and Future of 1.26 T2.” Concepts in Magnetic Resonance Part A 47A, no. 2 (March 2018): e21473.
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04-01-2020 03:54 PM
[NMR paper] Biomolecular NMR: Past and future.
Biomolecular NMR: Past and future.
Related Articles Biomolecular NMR: Past and future.
Arch Biochem Biophys. 2017 May 08;:
Authors: Markley JL, Westler WM
Abstract
The editors of this special volume suggested this topic, presumably because of the perspective lent by our combined >90-year association with biomolecular NMR. What follows is our personal experience with the evolution of the field, which we hope will illustrate the trajectory of change over the years. As for the future, one can confidently predict that it will involve...
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05-13-2017 02:08 PM
On the present and future of dissolution-DNP
From The DNP-NMR Blog:
On the present and future of dissolution-DNP
Ardenkjaer-Larsen, J.H., On the present and future of dissolution-DNP. J Magn Reson, 2016. 264: p. 3-12.
http://www.ncbi.nlm.nih.gov/pubmed/26920825
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04-22-2016 08:45 PM
Past and Future Solid-State NMR Spectroscopy Studies at the Convergence Point between Biology and Materials Research
From The DNP-NMR Blog:
Past and Future Solid-State NMR Spectroscopy Studies at the Convergence Point between Biology and Materials Research
With DNP becoming an important technique in the material science community it is good to take a look every now and then at the progress that the field of solid-state NMR spectroscopy is making in the area of material science.
Goobes, G., Past and Future Solid-State NMR Spectroscopy Studies at the Convergence Point between Biology and Materials Research. Israel Journal of Chemistry, 2014. 54(1-2): p. 113-124.
...
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08-01-2014 06:21 PM
[NMR paper] Present and future of NMR for RNA-protein complexes: A perspective of integrated structural biology.
Present and future of NMR for RNA-protein complexes: A perspective of integrated structural biology.
Related Articles Present and future of NMR for RNA-protein complexes: A perspective of integrated structural biology.
J Magn Reson. 2014 Apr;241:126-36
Authors: Carlomagno T
Abstract
Nucleic acids are gaining enormous importance as key molecules in almost all biological processes. Most nucleic acids do not act in isolation but are generally associated with proteins to form high-molecular-weight nucleoprotein complexes. In this perspective...
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03-25-2014 11:49 AM
[NMR paper] Chemical exchange in biomacromolecules: Past, present, and future
Chemical exchange in biomacromolecules: Past, present, and future
Publication date: April 2014
Source:Journal of Magnetic Resonance, Volume 241</br>
Author(s): Arthur G. Palmer III</br>
The perspective reviews quantitative investigations of chemical exchange phenomena in proteins and other biological macromolecules using NMR spectroscopy, particularly relaxation dispersion methods. The emphasis is on techniques and applications that quantify the populations, interconversion kinetics, and structural features of sparsely populated conformational states in equilibrium...
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03-22-2014 01:28 AM
Present and future of NMR for RNA–protein complexes: A perspective of integrated structural biology
Present and future of NMR for RNA–protein complexes: A perspective of integrated structural biology
Publication date: April 2014
Source:Journal of Magnetic Resonance, Volume 241</br>
Author(s): Teresa Carlomagno</br>
Nucleic acids are gaining enormous importance as key molecules in almost all biological processes. Most nucleic acids do not act in isolation but are generally associated with proteins to form high-molecular-weight nucleoprotein complexes. In this perspective article I focus on the structural studies of supra-molecular ribonucleoprotein (RNP) assemblies...
NMR in integrated biophysical drug discovery for RAS: past, present, and future
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