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1. Quantitative entropy–enthalpy compensation in intraprotein interactions from model compound data

   https://doi.org/10.1002/pro.5013  

   Redvanly, Thomas W; Pielak, Gary J (June 2024, Protein Science)

   Abstract Many small globular proteins exist in only two states—the physiologically relevant folded state and an inactive unfolded state. The active state is stabilized by numerous weak attractive contacts, including hydrogen bonds, other polar interactions, and the hydrophobic effect. Knowledge of these interactions is key to understanding the fundamental equilibrium thermodynamics of protein folding and stability. We focus on one such interaction, that between amide and aromatic groups. We provide a statistically convincing case for quantitative, linear entropy–enthalpy compensation in forming aromatic–amide interactions using published model compound transfer‐free energy data. 

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2. Structural Rearrangement of the AT1 Receptor Modulated by Membrane Thickness and Tension

   https://doi.org/10.1021/acs.jpcb.4c03325  

   Poudel, Bharat; Vanegas, Juan M (October 2024, The Journal of Physical Chemistry B)

   Membrane-embedded mechanosensitive (MS) proteins, including ion channels and G-protein coupled receptors (GPCRs), are essential for the transduction of external mechanical stimuli into biological signals. The angiotensin II type 1 (AT1) receptor plays many important roles in cardiovascular regulation and is associated with diseases such as hypertension and congestive heart failure. The membrane-mediated activation of the AT1 receptor is not well understood, despite this being one of the most widely studied GPCRs within the context of biased agonism. Here, we use extensive molecular dynamics (MD) simulations to characterize the effect of the local membrane environment on the activation of the AT1 receptor. We show that membrane thickness plays an important role in the stability of active and inactive states of the receptor, as well as the dynamic interchange between states. Furthermore, our simulation results show that membrane tension is effective in driving large-scale structural changes in the inactive state such as the outward movement of transmembrane helix 6 to stabilize intermediate active-like conformations. We conclude by comparing our simulation observations with AlphaFold 2 predictions, as a proxy to experimental structures, to provide a framework for how membrane mediated stimuli can facilitate activation of the AT1 receptor through the β-arrestin signaling pathway. 

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3. Coupling of conformational dynamics and inhibitor binding in the phosphodiesterase‐5 family

   https://doi.org/10.1002/pro.4720  

   Tripathi, Shubhandra; Cote, Rick H.; Vashisth, Harish (July 2023, Protein Science)

   Abstract Phosphodiesterase‐5 (PDE5) is responsible for regulating the concentration of the second messenger molecule cGMP by hydrolyzing it into 5′‐GMP. PDE5 is implicated in erectile dysfunction and cardiovascular diseases. The substrate binding site in the catalytic domain of PDE5 is surrounded by several dynamic structural motifs (including the α14 helix, M‐loop, and H‐loop) that are known to switch between inactive and active conformational states via currently unresolved structural intermediates. We evaluated the conformational dynamics of these structural motifs in the apo state and upon binding of an allosteric inhibitor (evodiamine) oravanafil, a competitive inhibitor. We employed enhanced sampling‐based replica exchange solute scaling (REST2) method, principal component analysis (PCA), time‐lagged independent component analysis (tICA), molecular dynamics (MD) simulations, and well‐tempered metadynamics simulations to probe the conformational changes in these structural motifs. Our results support a regulatory mechanism for PDE5, where the α14 helix alternates between an inward (lower activity) conformation and an outward (higher activity) conformation that is accompanied by the folding/unfolding of the α8′ and α8″ helices of the H‐loop. When the allosteric inhibitor evodiamine is bound to PDE5, the inward (inactive) state of the α14 helix is preferred, thus preventing substrate access to the catalytic site. In contrast, competitive inhibitors of PDE5 block catalysis by occupying the active site accompanied by stabilization of the outward conformation of the α14 helix. Defining the conformational dynamics underlying regulation of PDE5 activation will be helpful in rational design of next‐generation small molecules modulators of PDE5 activity. 

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4. Exploring the activation mechanism of metabotropic glutamate receptor 2

   https://doi.org/10.1073/pnas.2401079121  

   Zhu, Xiaohong; Luo, Mengqi; An, Ke; Shi, Danfeng; Hou, Tingjun; Warshel, Arieh; Bai, Chen (May 2024, Proceedings of the National Academy of Sciences)

   Homomeric dimerization of metabotropic glutamate receptors (mGlus) is essential for the modulation of their functions and represents a promising avenue for the development of novel therapeutic approaches to address central nervous system diseases. Yet, the scarcity of detailed molecular and energetic data on mGlu2 impedes our in-depth comprehension of their activation process. Here, we employ computational simulation methods to elucidate the activation process and key events associated with the mGlu2, including a detailed analysis of its conformational transitions, the binding of agonists, G_iprotein coupling, and the guanosine diphosphate (GDP) release. Our results demonstrate that the activation of mGlu2 is a stepwise process and several energy barriers need to be overcome. Moreover, we also identify the rate-determining step of the mGlu2’s transition from the agonist-bound state to its active state. From the perspective of free-energy analysis, we find that the conformational dynamics of mGlu2’s subunit follow coupled rather than discrete, independent actions. Asymmetric dimerization is critical for receptor activation. Our calculation results are consistent with the observation of cross-linking and fluorescent-labeled blot experiments, thus illustrating the reliability of our calculations. Besides, we also identify potential key residues in the G_iprotein binding position on mGlu2, mGlu2 dimer’s TM6–TM6 interface, and Gi α5 helix by the change of energy barriers after mutation. The implications of our findings could lead to a more comprehensive grasp of class C G protein-coupled receptor activation. 

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5. Membrane mediated mechanical stimuli produces distinct active-like states in the AT1 receptor

   https://doi.org/10.1038/s41467-023-40433-4  

   Poudel, Bharat; Rajeshwar T, Rajitha; Vanegas, Juan M. (August 2023, Nature Communications)

   Abstract The Angiotensin II Type 1 (AT1) receptor is one of the most widely studied GPCRs within the context of biased signaling. While the AT1 receptor is activated by agonists such as the peptide AngII, it can also be activated by mechanical stimuli such as membrane stretch or shear in the absence of a ligand. Despite the importance of mechanical activation of the AT1 receptor in biological processes such as vasoconstriction, little is known about the structural changes induced by external physical stimuli mediated by the surrounding lipid membrane. Here, we present a systematic simulation study that characterizes the activation of the AT1 receptor under various membrane environments and mechanical stimuli. We show that stability of the active state is highly sensitive to membrane thickness and tension. Structural comparison of membrane-mediated vs. agonist-induced activation shows that the AT1 receptor has distinct active conformations. This is supported by multi-microsecond free energy calculations that show unique landscapes for the inactive and various active states. Our modeling results provide structural insights into the mechanical activation of the AT1 receptor and how it may produce different functional outcomes within the framework of biased agonism. 

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