Tight metal binding by humic acids and its role in biomineralization †

Davies, Geoffrey; Fataftah, Amjad; Cherkasskiy, Aleksandr; Ghabbour, Elham A.; Radwan, Amal; Jansen, Susan A.; Kolla, Santha; Paciolla, Mark D.; Sein, Lawrence T.; Buermann, Wolfgang; Balasubramanian, Mahalingam; Budnick, J. I.; Xing, Baoshan

doi:10.1039/a703145i

Cited by 176 publications

(168 citation statements)

References 34 publications

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“…2,3,[26][27][28] The TNB model fragment used in our simulations contains three carboxylic groups, three carbonyl groups, two phenolic groups, two amine groups, and four other R-OH alcohol groups and has a total molecular weight of 753 Da. [38][39][40] The size, composition, molecular weight, degree of aromaticity, and total charge density of this model are in good agreement with available experimental characterization of NOM 26,27,29 , the results of computer assisted 3-D structure elucidation, 42 and stochastic biogeochemical modeling. 33 The composition of the TNB model is also quite close to the composition of Suwannee River NOM, which is often used experimentally.…”

Section: Computational Methods and Detailssupporting

confidence: 80%

“…37 Despite the well recognized uncertainties of the NOM composition and structure, such methods have been successfully used over the last decade to investigate NOM in molecular-scale detail. [38][39][40][41][42][43][44][45][46][47] The TNB (Temple-Northeastern-Birmingham) model of an NOM molecular fragment [38][39][40] used in our work provides a good structural and compositional analog of the Suwannee River NOM commonly used in experimental studies. [43][44][45] Carboxylic groups are the most important interaction sites for metal binding to these molecules, as they are for many other organic and bioorganic molecules.…”

Section: Introductionmentioning

confidence: 99%

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Metal Cation Complexation with Natural Organic Matter in Aqueous Solutions: Molecular Dynamics Simulations and Potentials of Mean Force

Iskrenova-Tchoukova¹,

Kalinichev²,

2010

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Natural organic matter (NOM, or humic substance) has a known tendency to form colloidal aggregates in aqueous environments, with the composition and concentration of cationic species in solution, pH, temperature, and the composition of the NOM itself playing important roles. Strong interaction of carboxylic groups of NOM with dissolved metal cations is thought to be the leading chemical interaction in NOM supramolecular aggregation.Computational molecular dynamics (MD) study of the interactions of Na + , Mg 2+ , and Ca 2+ with the carboxylic groups of a model NOM fragment and acetate anions in aqueous solutions provides new quantitative insight into the structure, energetics, and dynamics of the interactions of carboxylic groups with metal cations, their association and the effects of cations on the colloidal aggregation of NOM molecules. Potentials of mean force and the equilibrium constants describing overall ion association and the distribution of metal cations between contact ion pairs and solvent separated ions pairs were computed from free MD simulations and restrained umbrella sampling calculations. The results provide insight into the local structural environments of metal-carboxylate association and the dynamics of exchange among these sites. All three cations prefer contact ion pair to solvent separated ion pair coordination, and Na + and Ca 2+ show a strong preference for bidentate contact ion pair formation. The average residence time of a Ca 2+ ion in a contact ion pair with the carboxylic groups is of the order of 0.5 ns, whereas the corresponding residence time of a Na + ion is only between 0.02 and 0.05 ns. The average residence times of a Ca 2+ ion in a bidentate coordinated contact ion pair vs. a monodentate coordinated contact ion pair are about 0.5 ns and about 0.08 ns, respectively. On the 10-ns time scale of our simulations, aggregation of the NOM molecules occurs in the presence of Ca 2+ but not Na + or Mg 2+ . These results agree with previous experimental observations and are explained 3 by both Ca 2+ ion-bridging between NOM molecules and decreased repulsion between the NOM molecules due to the reduced net charge of the NOM-metal complexes. Simulations on a larger scale are needed to further explore the relative importance of the different aggregation mechanisms and the stability of NOM aggregates.4

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Section: Computational Methods and Detailssupporting

confidence: 80%

Section: Introductionmentioning

confidence: 99%

Metal Cation Complexation with Natural Organic Matter in Aqueous Solutions: Molecular Dynamics Simulations and Potentials of Mean Force

Iskrenova-Tchoukova¹,

Kalinichev²,

2010

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“…Dose-dependent responses were also observed in an acute iron toxicity study (Whittaker et al, 2002). Because it was believed that the absorption of HA from the intestine is poor (1-5%) (Islam et al, 2005) and the binding between Fe and HA is tight (Davies et al, 1997), we hypothesised that the HA-Fe complex would be absorbed poorly from the intestine. Contrary to this hypothesis, the Fe concentration in the large intestinal content of HA rats remained at the control level and did not follow the relative increment of Fe concentration of the diets, suggesting that the efficiency of iron absorption from the intestine increased with the dose of HA (Fig.…”

Section: Ironmentioning

confidence: 79%

“…An explanation for the different effects of FA and HA on iron homeostasis may be that the binding of Fe to HA is much tighter than to FA (Davies et al, 1997). This is why HA did not provide iron either to the liver or to the other investigated organs.…”

Section: Acta Veterinaria Hungarica 65 2017mentioning

confidence: 92%

Effect of fulvic and humic acids on iron and manganese homeostasis in rats

Szabó

Vucskits²,

Berta

et al. 2017

Acta Veterinaria Hungarica

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The objective of this study was to investigate the effects of fulvic acid (FA) and humic acid (HA) as the two main compounds of humic substances, separately on Fe and Mn homeostasis. Seventy-two male Wistar rats were randomly divided into 9 experimental groups. The control diet (AIN-93G formula) and diets supplemented with 0.1%, 0.2%, 0.4% and 0.8% HA or FA were fed for 26 days. Fe and Mn concentrations of the large intestinal content, liver, kidney, femur and hair were determined. No significant differences were observed in the production parameters. The effects of FA and HA on iron homeostasis were significantly different. FA proved to be a good iron source, and slightly increased the iron content of liver and kidney, but -up to a dietary iron level of 52.7 mg/kg -it did not influence the efficiency of iron absorption. Above a dietary iron level of 52.7 mg/kg down-regulation of Fe absorption can be assumed. HA significantly stimulated the iron uptake and there was no down-regulation of Fe absorption up to 0.8% dietary HA supplementation level (61.5 mg Fe/kg diet). In the HA groups the iron content of the liver and kidney decreased significantly, suggesting that in spite of the better Fe absorption, the HA-Fe complex does not provide iron to the investigated organs. Neither FA nor HA supplementation influenced the Fe content of the femur and hair and slightly decreased the Mn concentration in the large intestinal content. This effect was significant (with a 22.7% Mn concentration decrease) only at the HA supplementation rate of 0.8%. Neither FA nor HA influenced significantly the Mn concentrations of the liver, kidney and femur. The Mn concentration of the hair in rats receiving FA-or HA-supplemented diets was higher than in the control rats; however, this result needs further confirmation.

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“…This and other recent publications (e.g., Davies et al 1997;Manceau et al 1996;Sery et al 1996;Hesterberg et al 1997) that describe the use of EXAFS/XANES to probe the state of heavy metals in soils, sediments and minerals, demonstrate the enormous, unrealized potential of these methods in environmental research. In this article, we will demonstrate, using soil contaminated with Cu as an example, how information about the chemical state of a metal and its bonding geometry can be obtained via the application of state-of-the-art instrumentation and analysis techniques.…”

mentioning

confidence: 99%

Studies of Cu(II) in soil by X-ray absorption spectroscopy

Frenkel¹,

Korshin²

2001

Can. J. Soil. Sci.

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Frenkel, A. I. and Korshin, G. V. 2001. Studies of Cu(II) in soil by X-ray absorption spectroscopy. Can. J. Soil Sci. 81: 271-276. Based on original data for copper, this paper evaluates the use and advantages of X-ray absorption fine structure (XAFS) in studies of heavy metals in soils. The structural parameters of the Cu 2+ target were quantified for soil exposed to copper and the same soil eluted with 0.1 M HCl. Experimental data were obtained using synchrotron sources of second and third generations. X-ray absorption near edge structure (XANES) indicated that the copper in both samples is likely to be predominantly bound by oxygen-containing functional groups. Extended X-ray absorption fine structure (EXAFS) analysis showed that the equatorial Cu-O distances were similar to those seen for Cu 2+ -humic complexes in aqueous solutions, but the axial distances for both samples were longer than in water. In the axial direction, this may indicate a type of ligation dissimilar to that in solutions. The magnitude of the mean square deviation of the axial Cu-O distance in the 0.1 M HCl eluted sample indicated a stronger bond compared with that in the sample containing both extractable and tightly bound copper. The results indicate that careful examination of structural data for sequentially eluted soils in combination with the development of new radiation sources to improve the sensitivity and quality of the data are likely to improve insight into the nature of interactions between heavy metals and soil.Key words: Soil, copper, humic, speciation, extended X-ray absorption fine structure, X-ray absorption near edge structure Mots clés: Sol, cuivre, humique, espèces chimiques, EXAFS, XANES X-Ray Absorption Fine Structure spectroscopy is an advanced structural technique based on the use of high intensity synchrotron radiation to measure the X-ray absorption coefficient of a material as a function of the X-ray energy. The interpretation of XAFS spectra provides quantitative information regarding the short-range atomic structure around the target element in the sample.The fine structure in the XAFS spectrum originates from the oscillatory nature of the wave function of the photoelectron ejected from the target atom in the photoabsorption process. The fine structure in the absorption coefficient starts at ca. 40 eV and extends ca. 1000 eV past the absorption edge. For these energies, single and multiple scatterings of the photoelectron by its nearest neighbors define the behavior of the X-ray absorption coefficient, which, due to its nature, contains the information about the identity and coordination numbers of the surrounding atoms, as well as about relevant distances and their disorders. The method of XAFS, which studies the absorption coefficient in the discussed range of energies, is called Extended X-Ray Absorption Fine Structure (EXAFS). The X-ray absorption near edge structure (XANES) spectroscopy is an allied but independent method that examines the data in the energy region from the Fermi level up to 40 eV past t...

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Tight metal binding by humic acids and its role in biomineralization †

Cited by 176 publications

References 34 publications

Metal Cation Complexation with Natural Organic Matter in Aqueous Solutions: Molecular Dynamics Simulations and Potentials of Mean Force

Metal Cation Complexation with Natural Organic Matter in Aqueous Solutions: Molecular Dynamics Simulations and Potentials of Mean Force

Effect of fulvic and humic acids on iron and manganese homeostasis in rats

Studies of Cu(II) in soil by X-ray absorption spectroscopy

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