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1. Water content modulation enables selective ion transport in 2D MXene membranes

   https://doi.org/10.1073/pnas.2501017122  

   Zhu, Yaguang; Xiong, Qinsi; Jeon, Woo Cheol; Blum, Monika; Camino, Fernando; Schatz, George C; Hatzell, Kelsey B (July 2025, Proceedings of the National Academy of Sciences)

   Separation membranes are critical for a range of processes, including but not limited to water desalination, chemical and fuel production, and recycling and recovery applications. Fundamentally, there are intrinsic trade-offs between permeability and selectivity. Local water organization and content can impact membrane structure (short- and long-range) in laminar transition metal carbide (MXene) membranes and impact selective ion permeation. Intercalation of chaotropic cesium (Cs ${}^{+}$) ions within the layers reduces the water content in the membrane and at the surface which cannot be found in the intercalation of other ions. Additionally, 3D imaging using focused ion beam scanning electron microscopy showed fewer defects in the Cs-MXene membrane, due to reduced local water content, leading to more efficient ion sieving. X-ray diffraction and density functional theory calculations on the nanochannel structure demonstrated that the chaotropic ion results in the smallest nanochannel size and induces a stronger resistance to water-induced nanochannel swelling. With a narrower nanochannel, the Cs-MXene membrane limits ion transport pathways, resulting in more selective transport of lithium over other metal cations, as evidenced in both experiment and molecular dynamics simulations. Our findings highlight the potential for controlling the structural organization of 2D MXene membranes to enable on-demand transport of ions for diverse applications. 

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2. Metal ions induced secondary structure rearrangements: mechanically interlocked lasso vs. unthreaded branched-cyclic topoisomers

   https://doi.org/10.1039/c8an00138c  

   Jeanne Dit Fouque, Kevin; Moreno, Javier; Hegemann, Julian D.; Zirah, Séverine; Rebuffat, Sylvie; Fernandez-Lima, Francisco (January 2018, The Analyst)

   Metal ions can play a significant role in a variety of important functions in protein systems including cofactor for catalysis, protein folding, assembly, structural stability and conformational change. In the present work, we examined the influence of alkali (Na, K and Cs), alkaline earth (Mg and Ca) and transition (Co, Ni and Zn) metal ions on the conformational space and analytical separation of mechanically interlocked lasso peptides. Syanodin I, sphingonodin I, caulonodin III and microcin J25, selected as models of lasso peptides, and their respective branched-cyclic topoisomers were submitted to native nESI trapped ion mobility spectrometry-mass spectrometry (TIMS-MS). The high mobility resolving power of TIMS permitted to group conformational families regardless of the metal ion. The lower diversity of conformational families for syanodin I as compared to the other lasso peptides supports that syanodin I probably forms tighter binding interactions with metal ions limiting their conformational space in the gas-phase. Conversely, the higher diversity of conformational families for the branched-cyclic topologies further supports that the metal ions probably interact with a higher number of electronegative groups arising from the fully unconstraint C-terminal part. A correlation between the lengths of the loop and the C-terminal tail with the conformational space of lasso peptides becomes apparent upon addition of metal ions. It was shown that the threaded C-terminal region in lasso peptides allows only for distinct interactions of the metal ion with either residues in the loop or tail region. This limits the size of the interacting region and apparently leads to a bias of metal ion binding in either the loop or tail region, depending whichever section is larger in the respective lasso peptide. For branched-cyclic peptides, the non-restricted C-terminal tail allows metal coordination by residues throughout this region, which can result in gas-phase structures that are sometimes even more compact than the lasso peptides. The high TIMS resolution also resulted in the separation of almost all lasso and branched-cyclic topoisomer metal ions ( r ∼ 2.1 on average). It is also shown that the metal incorporation ( e.g. , doubly cesiated species) can lead to the formation of a simplified IMS pattern (or preferential conformers), which results in baseline analytical separation and discrimination between lasso and branched-cyclic topologies using TIMS-MS. 

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3. Strategies to Improve Electrical and Ionic Conductivities of Metal–Organic Frameworks

   https://doi.org/10.1080/02603594.2019.1704738  

   Gordillo, Monica A.; Saha, Sourav (January 2020, Comments on Inorganic Chemistry)

   Owing to their highly ordered crystalline structures and ease of introducing different electroactive meta ions and ligands, metal–organic frameworks (MOFs) have emerged as promising electrical and ion conducting materials. In this minireview, we highlighted recent advances in guest-induced electronic and ionic conductivity of MOFs, which are otherwise insulators or poor conductors. Examples of conductivity enhancement upon guest-induced framework oxidation or reduction, π-donor/acceptor stack formation, crosslinking of coordinatively unsaturated nodes, and binding of mobile Li+ and Mg2+ with the MOFs are discussed. 

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4. mebipred : identifying metal-binding potential in protein sequence

   https://doi.org/10.1093/bioinformatics/btac358  

   Aptekmann, A A; Buongiorno, J; Giovannelli, D; Glamoclija, M; Ferreiro, D U; Bromberg, Y (July 2022, Bioinformatics)

   Cowen, Lenore (Ed.)

   Abstract Motivationmetal-binding proteins have a central role in maintaining life processes. Nearly one-third of known protein structures contain metal ions that are used for a variety of needs, such as catalysis, DNA/RNA binding, protein structure stability, etc. Identifying metal-binding proteins is thus crucial for understanding the mechanisms of cellular activity. However, experimental annotation of protein metal-binding potential is severely lacking, while computational techniques are often imprecise and of limited applicability. Resultswe developed a novel machine learning-based method, mebipred, for identifying metal-binding proteins from sequence-derived features. This method is over 80% accurate in recognizing proteins that bind metal ion-containing ligands; the specific identity of 11 ubiquitously present metal ions can also be annotated. mebipred is reference-free, i.e. no sequence alignments are involved, and is thus faster than alignment-based methods; it is also more accurate than other sequence-based prediction methods. Additionally, mebipred can identify protein metal-binding capabilities from short sequence stretches, e.g. translated sequencing reads, and, thus, may be useful for the annotation of metal requirements of metagenomic samples. We performed an analysis of available microbiome data and found that ocean, hot spring sediments and soil microbiomes use a more diverse set of metals than human host-related ones. For human microbiomes, physiological conditions explain the observed metal preferences. Similarly, subtle changes in ocean sample ion concentration affect the abundance of relevant metal-binding proteins. These results highlight mebipred’s utility in analyzing microbiome metal requirements. Availability and implementationmebipred is available as a web server at services.bromberglab.org/mebipred and as a standalone package at https://pypi.org/project/mymetal/. Supplementary informationSupplementary data are available at Bioinformatics online. 

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5. Halide-assisted metal ion reduction: emergent effects of dilute chloride, bromide, and iodide in nanoparticle synthesis

   https://doi.org/10.1039/C9NR04647J  

   King, Melissa E.; Kent, Isabella A.; Personick, Michelle L. (August 2019, Nanoscale)

   Understanding the competing effects of growth-directing additives, such as halide ions, on particle formation in solution phase metal nanoparticle syntheses is an ongoing challenge. Further, trace halide impurities are known to have a drastic impact on particle morphology as well as reproducibility. Herein, we employ a “halide-free” platform as an analogue to commonly used halide-containing surfactants and metal precursors to isolate and study the effects of micromolar concentrations of halide ions (chloride, bromide, and iodide) on the rate of metal ion reduction. In the absence of competing halides from precursors and surfactants, we observe a catalytic effect of low concentrations of halide ions on the rate of metal ion reduction, an influence which is fundamentally different from the previously reported role of halides in metal nanoparticle growth. We propose that this halide-assisted metal ion reduction proceeds via the formation of a halide bridge which facilitates the adsorption of the metal precursor to a growing nanoparticle and, subsequently, electron transfer from the particle surface. We then demonstrate that this process is operative not only in the well-controlled “halide-free” platform, but also in syntheses involving high concentrations of halide-containing surfactants as well as metal precursors with halide ligands. Importantly, this study shows that halide-assisted metal ion reduction can be extended to bimetallic systems and provides a handle for the directed differential control of metal ion reduction in one-pot co-reduction syntheses. 

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