Cellular dissolution at hypha- and spore-mineral interfaces revealing unrecognized mechanisms and scales of fungal weathering

The nacre structure consists of laminated interlocked mineral platelets separated by nanoscale organic layers. Here, the role of close proximity of mineral to the proteins on mechanical behavior of the protein is investigated through steered molecular dynamics simulations. Our simulations indicate that energy required for unfolding protein in the proximity of mineral aragonite is several times higher than that for isolated protein in the absence of the mineral. Here, we present details of specific mechanisms which result in higher energy for protein unfolding in the proximity of mineral. At the early stage of pulling, peaks in the load-displacement (LD) plot at mineral proximity are quantitatively correlated to the interaction energy between atoms involved in the latching phenomenon of amino acid side chain to aragonite surface. Water plays an important role during mineral and protein interaction and water molecules closer to the mineral surface are highly oriented and remain rigidly attached as the protein strand is pulled. Also, the high magnitude of load for a given displacement originates from attractive interactions between the protein, protein-bound water, and mineral. This study provides an insight into mineral-protein interactions that are predominant in biological nanocomposites and also provides guidelines towards design of biomimetic nanocomposites.

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Advanced Solid State NMR Techniques for the Investigation of the Organic-Mineral Interfaces in Biomaterials

MRS Proceedings ◽

10.1557/proc-1236-ss08-02 ◽

2009 ◽

Vol 1236 ◽

Author(s):

Danielle Laurencin ◽

Gilles Guerrero ◽

Julien Amalric ◽

Christian Bonhomme ◽

Christel Gervais ◽

...

Keyword(s):

Solid State ◽

Solid State Nmr ◽

Calcium Phosphates ◽

Titanium Implants ◽

Phosphonic Acids ◽

Oh Groups ◽

Organic Mineral ◽

Nmr Techniques ◽

Mineral Interfaces ◽

Interface Structures

AbstractHigh resolution solid state NMR experiments were carried out on several compounds, to see how this technique can now be used to investigate in detail the surface structure of different biomaterials. First, because the surface of titanium implants can be functionalized by phosphonic acids, for instance to prevent bacterial adhesion,17O NMR experiments were performed on model TiO2 surfaces functionalized by 17O enriched phosphonic acids, to look at the mode of grafting of these coupling agents. Results bring clear evidence of the formation of Ti-O-P bridges and of the presence of residual P=O and P-OH groups. Second, given that calcium phosphates are widely present in biological hard tissues and synthetic biomaterials, 43Ca correlation experiments were performed on 43Ca enriched materials (hydroxyapatite and calcium benzoate), to see how the proximities between this nucleus and neighbouring atoms can be analyzed. Results show that both Ca…C and Ca…H proximities can be evidenced, and could thus help elucidate interface structures. All in all, these studies should pave the way to future investigations of biomaterials, and in particular of the structure of organic-inorganic interfaces.

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Oxo-iron clusters in a bacterial iron-trafficking protein: new roles for a conserved motif

Biochemical Journal ◽

10.1042/bj20031283 ◽

2003 ◽

Vol 376 (1) ◽

pp. 35-41 ◽

Cited By ~ 36

Author(s):

Haizhong ZHU ◽

Dmitriy ALEXEEV ◽

Dominic J. B. HUNTER ◽

Dominic J. CAMPOPIANO ◽

Peter J. SADLER

Keyword(s):

Iron Acquisition ◽

Ion Binding ◽

Binding Motif ◽

Iron Cluster ◽

X Ray ◽

Iron Trafficking ◽

Organic Mineral ◽

Unit Cells ◽

Independent Molecules ◽

Mineral Interfaces

We report a set of three 1.8–1.9 Å resolution X-ray crystal structures of Neisseria gonorrhoeae Fbp (ferric-ion binding protein): (i) open-cleft apo-Fbp containing bound phosphate, (ii) open-cleft mono-Fe Fbp capped by nitrilotriacetate, and (iii) open-cleft trinuclear oxo-iron Fbp, the first structure of an iron-cluster adduct of a transferrin. The nine independent molecules in the unit cells provide ‘snapshots’ of the versatile dynamic structural roles of the conserved dityrosyl iron-binding motif (Tyr195-Tyr196) which control the capture and, possibly, processing of iron. These findings have implications for understanding bacterial iron acquisition and dissimilation, and organic/mineral interfaces.

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Adsorption mechanisms of microcystin variant conformations at water–mineral interfaces: A molecular modeling investigation

Journal of Colloid and Interface Science ◽

10.1016/j.jcis.2016.07.016 ◽

2016 ◽

Vol 480 ◽

pp. 166-174 ◽

Cited By ~ 9

Author(s):

Amy L. Pochodylo ◽

Thalia G. Aoki ◽

Ludmilla Aristilde

Keyword(s):

Molecular Modeling ◽

Adsorption Mechanisms ◽

Mineral Interfaces

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ELEMENTARY REACTIONS IN POLYNUCLEAR IONS AND AQUEOUS?MINERAL INTERFACES: A NEW GEOLOGY

10.2172/1115419 ◽

2012 ◽

Author(s):

James R. Rustad

Keyword(s):

Elementary Reactions ◽

Mineral Interfaces

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Dynamic feldspar alteration governed by single self-evolved fluid system

10.21203/rs.3.rs-61362/v1 ◽

2020 ◽

Author(s):

Gan Duan ◽

Joel Brugger ◽

Rahul Ram ◽

Yan Xing ◽

Barbara Etschmann

Keyword(s):

Hydrothermal Fluid ◽

Large Scale ◽

Reaction System ◽

Ore Deposits ◽

Fluid Mixing ◽

Fluid System ◽

Mineral Reaction ◽

Hydrothermal Processes ◽

Copper Gold ◽

Mineral Interfaces

Abstract The evolution of hydrothermal fluids during metasomatic and/or hydrothermal processes is responsible for the formation of ore deposits and associated alteration. In systems with well-developed breccia and fractures, mineral reactions are largely driven by decompression boiling, fluid cooling or external fluid mixing, but in less permeable rocks, elements exchanges occur at fluid-mineral interfaces, resulting in a self-evolved fluid-mineral reaction system. However, the dynamic fluid evolution leading to large-scale (km) alteration remains poorly understood. We observed experimentally that the sequential sodic and potassic alterations associated with mineralization in large ore deposits, in particular Iron Oxide Copper Gold (IOCG) deposits, can occur via a single self-evolved, originally Na-only, hydrothermal fluid, driven by a positive feedback between equilibrium and kinetic factors. Albite formed first upon reaction of sanidine ((K,Na)AlSi3O8) with a NaCl fluid at 600˚C, 2 kbar. However, with increasing reaction time, some of the initially formed albite was in-turn replaced by K-feldspar (KAlSi3O8). Fluorine accelerated the process, resulting in nearly complete back-replacement of albite within 1 day. These experiments demonstrate that potassic alteration can be induced by Na-rich fluids, and pervasive sequential sodic and potassic alterations do not necessarily reflect near-equilibrium, externally-driven changes in fluid alkali contents.

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Three-Dimensional and Microstructural Fingerprinting of Gold Nanoparticles at Fluid-Mineral Interfaces

American Mineralogist ◽

10.2138/am-2021-7696 ◽

2021 ◽

Vol 106 (1) ◽

pp. 97-104

Author(s):

Haoyang Zhou ◽

Richard Wirth ◽

Sarah A. Gleeson ◽

Anja Schreiber ◽

Sathish Mayanna

Keyword(s):

Gold Nanoparticles ◽

Focused Ion Beam ◽

Ion Beam ◽

Three Dimensional ◽

Heteroepitaxial Growth ◽

Extrinsic Factors ◽

Thermodynamic Conditions ◽

World Class ◽

Mineral Interfaces ◽

Lattice Planes

Abstract Recent studies have identified gold nanoparticles in ores in a range of deposit types, but little is known about their formation processes. In this contribution, gold-bearing magnetite from the well-documented, world-class Beiya Au deposit, China, was investigated in terms of microstructure and crystallography at the nanoscale. We present the first three-dimensional (3D) focused ion beam/scanning electron microscopy (FIB/SEM) tomography of the distribution of gold nanoparticles in nanopores in the low-Si magnetite. The porous low-Si magnetite, which overprints an earlier generation of silician magnetite, was formed by a coupled dissolution-reprecipitation reaction (CDRR). The extrinsic changes in thermodynamic conditions (e.g., S content and temperature) of the hydrothermal fluids resulted in the CDRR in magnetite and the disequilibrium of Au-Bi melts. The gold nanoparticles crystallized from Au-supersaturated fluids originating from the disequilibrium of Au-Bi melts and grew in two ways depending on the intrinsic crystal structure and pore textures: (1) heteroepitaxial growth utilizing the (111) lattice planes of magnetite, and (2) randomly oriented nucleation and growth. Therefore, this study unravels how intrinsic and extrinsic factors drove the formation of gold nanoparticles at fluid-mineral interfaces.

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