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1. Synergistic reduction in interfacial flexibility of TREM2 ^R47H and ApoE4 may underlie AD pathology

   https://doi.org/10.1002/alz.70120  

   Lietzke, Emma E; Saeb, David; Aldrich, Emma C; Bruce, Kimberley D; Sprenger, Kayla G (April 2025, Alzheimer's & Dementia)

   Abstract BACKGROUNDThe strongest genetic drivers of late‐onset Alzheimer's disease (AD) are apolipoprotein E4 (ApoE4) and TREM2^R47H. Despite their critical roles, the mechanisms underlying their interactions remain poorly understood. METHODSWe conducted microsecond‐long molecular dynamics simulations of TREM2‐ApoE complexes, including TREM2^R47H, validating our findings through comparison with published experimental data on TREM2‐ApoE binding interactions. RESULTSOur simulations reveal TREM2^WTcan sample an “open” CDR2 conformation, challenging the prevailing notion that this conformation is pathogenic. TREM2^WTexhibits greater flexibility, accessing diverse CDR2 conformations, while rigidity in TREM2^R47H’s CDR2 may explain its reduced ligand‐binding properties. ApoE2 facilitates dynamic reconfiguration of TREM2‐ApoE2 complexes, which is absent with ApoE4. TREM2^R47Hand ApoE4 mutually rigidify each other, suppressing interfacial flexibility. DISCUSSIONOur findings suggest mechanisms underlying ApoE2's neuroprotective functions, ApoE4's pathogenicity, and the synergistic effects of ApoE4 and TREM2^R47Hin AD. TREM2^WT’s flexibility and reconfiguration with ApoE2 may support microglial activation, while rigidity in TREM2^R47H‐ApoE4 interactions may drive pathogenic signaling. HighlightsTREM2^WTsamples diverse CDR2 conformations, challenging prior assumptions that an “open” CDR2 state is solely pathogenic.ApoE2 promotes dynamic reconfiguration of TREM2‐ApoE2 complexes, preserving TREM2^WT's flexibility.ApoE4's hinge forms a unique binding pocket that enhances TREM2 binding.The TREM2^R47H‐ApoE4 complex exhibits mutual rigidity, suppressing CDR2 and hinge flexibility. 

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2. IgStrand: A universal residue numbering scheme for the immunoglobulin-fold (Ig-fold) to study Ig-proteomes and Ig-interactomes

   https://doi.org/10.1371/journal.pcbi.1012813  

   Tawfeeq, Caesar; Wang, Jiyao; Khaniya, Umesh; Madej, Thomas; Song, James; Abrol, Ravinder; Youkharibache, Philippe (April 2025, PLOS Computational Biology)

   Friedberg, Iddo (Ed.)

   The Immunoglobulin fold (Ig-fold) is found in proteins from all domains of life and represents the most populous fold in the human genome, with current estimates ranging from 2 to 3% of protein coding regions. That proportion is much higher in the surfaceome where Ig and Ig-like domains orchestrate cell-cell recognition, adhesion and signaling. The ability of Ig-domains to reliably fold and self-assemble through highly specific interfaces represents a remarkable property of these domains, making them key elements of molecular interaction systems: the immune system, the nervous system, the vascular system and the muscular system. We define a universal residue numbering scheme, common to all domains sharing the Ig-fold in order to study the wide spectrum of Ig-domain variants constituting the Ig-proteome and Ig-Ig interactomes at the heart of thesesystems. The “IgStrand numbering scheme” enables the identification of Ig structural proteomes and interactomes in and between any species, and comparative structural, functional, and evolutionary analyses. We review how Ig-domains are classified today as topological and structural variants and highlight the“Ig-fold irreducible structural signature”shared by all of them. The IgStrand numbering scheme lays the foundation for the systematic annotation of structural proteomes by detecting and accurately labeling Ig-, Ig-like and Ig-extended domains in proteins, which are poorly annotated in current databases and opens the door to accurate machine learning. Importantly, it sheds light on the robustIg protein folding algorithmused by nature to form beta sandwich supersecondary structures. The numbering scheme powers an algorithm implemented in the interactive structural analysis software iCn3D to systematically recognize Ig-domains, annotate them and perform detailed analyses comparing any domain sharing the Ig-fold in sequence, topology and structure, regardless of their diverse topologies or origin. The scheme provides a robust fold detection and labeling mechanism that reveals unsuspected structural homologies among protein structures beyond currently identified Ig- and Ig-like domain variants. Indeed, multiple folds classified independently contain a common structural signature, in particular jelly-rolls. Examples of folds that harbor an “Ig-extended” architecture are given. Applications in protein engineering around the Ig-architecture are straightforward based on the universal numbering. 

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3. Conformational heterogeneity in the dGsw purine riboswitch: role of Mg²⁺ and 2’-dG in aptamer folding

   https://doi.org/10.1261/rna.080274.124  

   Chaudhury, Susmit Narayan; Ding, Erdong; Jespersen, Nathan Edward; Onuchic, Jose N; Sanbonmatsu, Karissa Y (February 2025, RNA)

   Recent advancements in RNA structural biology have focused on unraveling the complexities of non-coding mRNA elements like riboswitches. These cis-acting regulatory regions undergo structural changes in response to specific cellular metabolites, leading to up or downregulation of downstream genes. The purine riboswitch family regulates many prokaryotic genes involved in purine degradation and biosynthesis. They feature an aptamer domain organized around a 3-way helical junction, where ligand encapsulation occurs at the junctional core. In our study, we chemically probed the aptamer domain of the 2’-dG-sensing purine riboswitch from Mesoplasma florum (dGsw) under various solution conditions to understand how Mg²⁺ and 2’-dG influence riboswitch folding. Here, we find that efficient 2’-dG binding strongly depends on Mg²⁺, indicating that Mg²⁺ is essential for priming dGsw for ligand interactions. We identified a previously undescribed sequence in the 5’ tail of dGsw that is complementary to a conserved helix. The inclusion of this region in a construct led to intramolecular competition between the alternate helix, Palt, and P1. Mutational analysis confirmed that 5’ flanking end of the aptamer domain forms an alternate helix in the absence of ligand. Molecular dynamics simulations revealed that this alternative conformation is stable. This helix may, therefore, facilitate the formation of an anti-terminator helix by opening the 3-way junction surrounding the 2’-dG binding site. Our study further establishes the importance of a closed terminal P1 helix conformation for metabolite binding and suggests that the delicate interplay between P1 and Palt may fine-tune downstream gene regulation. These insights offer a new perspective on riboswitch structure and enhance our understanding of the role that a conformational ensemble plays in riboswitch activity and regulation. 

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4. The algebraic extended atom-type graph-based model for precise ligand–receptor binding affinity prediction

   https://doi.org/10.1186/s13321-025-00955-z  

   Mukta, Farjana Tasnim; Rana, Md Masud; Meyer, Avery; Ellingson, Sally; Nguyen, Duc D (December 2025, Journal of Cheminformatics)

   Abstract Accurate prediction of ligand-receptor binding affinity is crucial in structure-based drug design, significantly impacting the development of effective drugs. Recent advances in machine learning (ML)–based scoring functions have improved these predictions, yet challenges remain in modeling complex molecular interactions. This study introduces the AGL-EAT-Score, a scoring function that integrates extended atom-type multiscale weighted colored subgraphs with algebraic graph theory. This approach leverages the eigenvalues and eigenvectors of graph Laplacian and adjacency matrices to capture high-level details of specific atom pairwise interactions. Evaluated against benchmark datasets such as CASF-2016, CASF-2013, and the Cathepsin S dataset, the AGL-EAT-Score demonstrates notable accuracy, outperforming existing traditional and ML-based methods. The model’s strength lies in its comprehensive similarity analysis, examining protein sequence, ligand structure, and binding site similarities, thus ensuring minimal bias and over-representation in the training sets. The use of extended atom types in graph coloring enhances the model’s capability to capture the intricacies of protein-ligand interactions. The AGL-EAT-Score marks a significant advancement in drug design, offering a tool that could potentially refine and accelerate the drug discovery process. Scientific Contribution The AGL-EAT-Score presents an algebraic graph-based framework that predicts ligand-receptor binding affinity by constructing multiscale weighted colored subgraphs from the 3D structure of protein-ligand complexes. It improves prediction accuracy by modeling interactions between extended atom types, addressing challenges like dataset bias and over-representation. Benchmark evaluations demonstrate that AGL-EAT-Score outperforms existing methods, offering a robust and systematic tool for structure-based drug design. 

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5. Identification of preferred multimodal ligand‐binding regions on IgG1 F _C using nuclear magnetic resonance and molecular dynamics simulations

   https://doi.org/10.1002/bit.27611  

   Gudhka, Ronak_B; Bilodeau, Camille_L; McCallum, Scott_A; McCoy, Mark_A; Roush, David_J; Snyder, Mark_A; Cramer, Steven_M (November 2020, Biotechnology and Bioengineering)

   Abstract In this study, the binding of multimodal chromatographic ligands to the IgG1 F_Cdomain were studied using nuclear magnetic resonance and molecular dynamics simulations. Nuclear magnetic resonance experiments carried out with chromatographic ligands and a perdeuterated¹⁵N‐labeled F_Cdomain indicated that while single‐mode ion exchange ligands interacted very weakly throughout the F_Csurface, multimodal ligands containing negatively charged and aromatic moieties interacted with specific clusters of residues with relatively high affinity, forming distinct binding regions on the F_C. The multimodal ligand‐binding sites on the F_Cwere concentrated in the hinge region and near the interface of the C_H2 and C_H3 domains. Furthermore, the multimodal binding sites were primarily composed of positively charged, polar, and aliphatic residues in these regions, with histidine residues exhibiting some of the strongest binding affinities with the multimodal ligand. Interestingly, comparison of protein surface property data with ligand interaction sites indicated that the patch analysis on F_Ccorroborated molecular‐level binding information obtained from the nuclear magnetic resonance experiments. Finally, molecular dynamics simulation results were shown to be qualitatively consistent with the nuclear magnetic resonance results and to provide further insights into the binding mechanisms. An important contribution to multimodal ligand‐F_Cbinding in these preferred regions was shown to be electrostatic interactions and π–π stacking of surface‐exposed histidines with the ligands. This combined biophysical and simulation approach has provided a deeper molecular‐level understanding of multimodal ligand–F_Cinteractions and sets the stage for future analyses of even more complex biotherapeutics. 

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