Added Metal Ions Research Articles

An Investigation into the Anti-Ultraviolet Performance of Natural Tea Pigment

Wool fabric was treated with homemade natural tea pigment to endow anti-ultraviolet property. Research results showed that the anti-ultraviolet performance was improved significantly after treatment and the UPF value was increased with the increasing of the pigment dosage. Adding metal ions can improve anti-ultraviolet performance in varying degrees.

Synthesis of novel triarylamine-based dendrimers with N4,N6-dibutyl-1,3,5-triazine-4,6-diamine probe for electron/energy transfers in H-bonded donor–acceptor–donor triads and as efficient Cu2+ sensors

Two novel highly soluble triarylamine dendrimers TPAD1 and TPAD2 with N4,N6-dibutyl-1,3,5-triazine-4,6-diamine probe were synthesized via normal synthetic routes. Both dendrimers (TPAD1 and TPAD2) form H-bonded donor–acceptor–donor (D–A–D) supramolecular triads TPAD1-PBI-TPAD1 and TPAD2-PBI-TPAD2 with 3,4,9,10-perylene tetra carboxylic diimide derivative (PBI). The presence of multiple H-bonds in the solution state was elucidated by 1H NMR titrations and IR spectral studies. J-aggregations and electron/energy transfers provided by both dendrimers were verified by UV–Vis and photoluminescence (PL) titrations with PBI and the particle sizes of supramolecular triads were calculated by X-ray diffraction (XRD) analysis. Similarly, both dendrimers also showed sensitivities towards Cu2+ in comparison with 19 interfering metal ions, which were evidenced via UV–Vis and PL titraions in both single and dual metal systems. The maximum detection limit of Cu2+ ions was determined to be 20 ppm from PL titrations for both dendrimers, and the 1 : 2 stoichiometry of the complexes formed by both dendrimers (TPAD1-Cu2+ and TPAD2-Cu2+) were calculated by Job plots based on UV–Vis absorption titrations. More importantly, the binding mechanism of the 1,3,5-triazine-4,6-diamine probe of both dendrimers was well characterized by 1H and 13C NMR titrations ([D8]THF : D2O = 2 : 1 in vol.) and supported by the fluorescence reversibility by adding metal ions and PMDTA sequentially.

Controlling the Morphology of Metal-Promoted Higher Ordered Assemblies of Collagen Peptides with Varied Core Lengths

Self-assembling peptides have become an important subclass of next-generation biomaterials. In particular, materials that mimic the properties of collagen have received considerable attention due to the unique properties of natural collagen. Previous peptide-based designs have been successful in generating structures with morphological properties that were primarily determined by the type of self-assembling mechanism. Herein we demonstrate the metal ion-promoted, supramolecular assembly of collagen-based peptide triple helices into distinct morphologies that are controlled by defining the number of Pro-Hyp-Gly repeating units. We synthesized and characterized collagen-based peptides that incorporated either 5, 7, 9, or 11 Pro-Hyp-Gly repeating units. We found that the number of repeating units, and the resulting stability of the collagen triple helix, is intimately linked with the types of assemblies formed. For instance, collagen peptides that did not form a stable triple helix, such as NCoH5, did not participate in supramolecular assembly with added metal ions. Collagen peptides that formed stable triple helices, such as NCoH11, resulted in microsaddle structures with metal-promoted assembly, whereas a highly cross-linked, three-dimensional mesh formed with NCoH7, albeit at a higher metal ion concentration. These data provide evidence that triple helix formation is required for efficient metal-triggered assembly to the observed microstructures.

Structural and Kinetic Studies on Metallo-β-lactamase IMP-1

In an effort to probe for metal binding to metallo-β-lactamase (MβL) IMP-1, the enzyme was overexpressed, purified, and characterized. The resulting enzyme was shown to bind 2 equiv of Zn(II), exhibit significant catalytic activity, and yield EXAFS results similar to crystallographic data previously reported. Rapid kinetic studies showed that IMP-1 does not stabilize a nitrocefin-derived reaction intermediate; rather, the enzyme follows a simple Michaelis mechanism to hydrolyze nitrocefin. Metal-substituted and metal-reconstituted analogues of IMP-1 were prepared by directly adding metal ion stocks to metal-free enzyme, which was generated by dialysis versus EDTA. UV-vis studies on IMP-1 containing 1 equiv of Co(II) showed a strong ligand-to-metal charge transition at 340 nm, and the intensity of this feature increased when the second equivalent of Co(II) was added to the enzyme. EXAFS fits on IMP-1 containing 1 equiv of Co(II) strongly suggest the presence of a metal-metal interaction, and EPR spectra of the IMP-1 containing 1 and 2 equiv of Co(II) are very similar. Taken together, steady-state kinetic and spectroscopic studies suggest that metal binding to metal-free IMP-1 follows a positive-cooperative mode.

Metal-Mediated Tandem Coassembly of Collagen Peptides into Banded Microstructures

The ability to recapitulate the features of natural collagen at the micro- and nanoscale with novel biopolymers has the potential to lead to improved biomaterials. Herein we describe stimuli-responsive collagen-based peptides (IdaCol and HisCol) that together form higher order assemblies in the presence of added metal ions. SEM and TEM imaging of these assemblies revealed microscale petal-like and intertwined fiber morphologies, each with periodic banding on the nanometer scale. The observed banding is consistent with tandem coassembly of alternating IdaCol and HisCol triple helical blocks that may laterally associate either in or out of register to form higher order structures, and mimics the banding found in natural collagen fibers.

Metal ion retention by emulsion liquid membrane coupled to liquid-phase polymer-based retention

The capacity of polyelectrolytes (PELs) to enhance the metal ion retention in a double emulsion system (DES) was studied by diafiltration. Our results indicate that PELs can increase the maximum retention capacity of DES as functional groups of polymer are being saturated. Increase of retention can be explained by interaction between reverse emulsion globules and metal–polymer species formed in solution. Assuming an inert membrane, if the amount of added metal ion is lower than the polymer’s maximum retention capacity, then the retention system behaves as if the polymer was the single retainer element in the filtration cell. For poly(acrylic acid), retention/adsorption and transport/regeneration processes were strongly associated to changes in hydrophilic–lipophilic balance of polymer chains; whereas for poly(vinyl sulfonic acid) and poly(sodium 4-styrensulfonate), these processes were mainly associated to screening of surface charge density of macromolecule in solution.

Metal ion and DNA binding by single-chain PvuII endonuclease: lessons from the linker

Understanding the roles of metal ions in restriction enzymes has been complicated by both the presence of two metal ions in many active sites and their homodimeric structure. Using a single-chain form of the wild-type restriction enzyme PvuII (scWT) in which subunits are fused with a short polypeptide linker (Simoncsits et al. in J. Mol. Biol. 309:89-97, 2001), we have characterized metal ion and DNA binding behavior in one subunit and examined the effects of the linker on dimer behavior. scWT exhibits heteronuclear single quantum coherence NMR spectra similar to those of native wild-type PvuII (WT). For scWT, isothermal titration calorimetry data fit to two Ca(II) sites per subunit with low-millimolar K (d)s. The variant scWT|E68A, in which metal ion binding in one subunit is abolished by mutation, also binds two Ca(II) ions in the WT subunit with low-millimolar K (d)s. When there are no added metal ions, DNA binding affinity for scWT is tenfold stronger than that of the native WT, but tenfold weaker at saturating Ca(II) concentration. In the presence of Ca(II), scWT|E68A binds target DNA similarly to scWT, indicating that high-affinity substrate binding can be carried energetically by one metal-ion-binding subunit. Global analysis of DNA binding data for scWT|E68A suggests that the metal-ion-dependent behaviors observed for WT are reflective of independent subunit behavior. This characterization provides an understanding of subunit contributions in a homodimeric context.

ISOLATION, PURIFICATION, AND CHARACTERIZATION OF THERMOPHILIC T80 ISOENZYME OF XYLOSE ISOMERASE FROM THE XEROPHYTE Cereus pterogonus

A thermostable isoenzyme (T80) of xylose isomerase from the eukaryote xerophyte Cereus pterogonus was purified to homogeneity by precipitation with ammonium sulfate and column chromatography on Dowex-1 ion exchange, with Sephadex G-100 gel filtration, resulting in an approximately 25.55-fold increase in specific activity and a final yield of approximately 17.9%. Certain physiochemical and kinetic properties (Km and Vmax) of the T80 xylose isomerase isoenzyme were investigated. The molecular mass of the purified T80 isoenzyme was 68 kD determined by sodium dodecyl sulfate polyacrylamide gel electrophoresis. Polyclonal antibodies against the purified T80 isoenzyme recognized a single polypeptide band on Western blots. The activation energy required for the thermal denaturation of the isoenzyme was determined to be 61.84 KJ mol−1. The use of differential scanning calorimetry established the melting temperature of the CPXI isoenzyme to be 80°C, but when studied with added metal ions, melting temperature increases to more than the normal. Fluorescence spectroscopy of T80 isoenzymes yielded an emission peak with λem at 320 nm and 340 nm, respectively, confirming the presence of Trp residue in these proteins. Electron paramagnetic resonance (EPR) analysis at liquid nitrogen temperature established the presence of Mn2+ and Co2+ associated with each isoenzyme. These enzyme species exhibited different thermal and pH stabilities compared to their mesophilic counterparts and offered greater efficiency in functioning as a potential alternate catalytic converter of glucose in the production of high-fructose corn syrup (HFCS) for the sweetener industry and for ethanol production.

Adsorption of linear polymers on polyethersulfone membranes: Contribution of divalent counterions on modifying of hydrophilic–lipophilic balance of polyelectrolyte chain

The effect of divalent metal ions on conformational changes, size and hydrophilicity of poly(acrylic acid), PAA, in solution as well as its relation with characteristics of adsorbed polymer layers on polyethersulfone membrane, PESm, were studied and analyzed by several techniques. PAA adsorption on PESm in the presence of divalent metal ions was established to be occurring by an adsorption mechanism promoted by interchain polymer–metal bonds between polymer molecules in solution and pre-adsorbed polymer layers on the surface. Results suggest that changes of hydrophilic–lipophilic balance of polymer chains can be related to adsorption mechanisms of PAA; these changes are consequence of decrease of negative charges on carboxylate groups by coordination of added metal ions and by increase of ionic strength. Besides, the surface and permeability characteristics of adsorbed polymer layers were related to the changes of size, aggregation and conformations of polymer chains in solution as metal ion concentration was increased.

Tick-borne encephalitis: immunological indicators of possible transformation of acute process into chronic disease

Several autoimmune diseases with chronic clinical course are characterized by detection of DNA autoantibodies in patients’ serum, while there are no such IgGs in healthy donors’ blood or in patients with acute clinical course with no evidence of chronization. Tick-borne encephalitis has not been considered this way. Several strict criteria have been applied to show that the DNase activity is an intrinsic property of IgGs from the sera of TBE patients but not from healthy donors. The relative activity of IgGs has been shown to vary extensively from patient to patient, but most of the preparations (91%) had detectable levels of the DNase activity. Polyclonal DNase IgGs were not active in the presence of EDTA or after a dialysis against EDTA, but could be activated by several externally added metal ions, with the level of activity decreasing in the order Mn2+ + Ca2+ ≥ Mn2+ + Mg2+ ≥ Mn2+ ≥ ≥ Mg2+ + Ca2+ ≥ Ca2+ ≥ Mg2+ > Ca2+, while K+ , Na+ , Ni2+, Zn2+, and Cu2+ did not stimulate DNA hydrolysis. Affinity chromatography on DNA-cellulose separated the DNase IgGs into many subfractions with various affinities for DNA and very different levels of the relative activity. Possible reasons for catalytic diversity of polyclonal human Abzs are discussed.

A novel nucleotide kinase encoded by gene 1.7 of bacteriophage T7

Gene 1.7 of bacteriophage T7 confers sensitivity of both phage T7 and its host Escherichia coli to dideoxythymidine (ddT). We have purified the product of gene 1.7, gp1.7. It exists in two forms of molecular weight 22,181 and 17,782. Only the C-terminal half of the protein is required to confer ddT sensitivity. We show that gp1.7 catalyses the phosphorylation of dGMP and dTMP to dGDP and dTDP, respectively, by using either GTP, dGTP or dTTP as the phosphate donor. Either form of gp1.7 exhibit identical kinase activity as compared with wild-type gp1.7 that contains a mixture of both forms. The K(m) of 70 microM and Kcat of 4.3 s(-1) for dTMP are similar to those found for E. coli thymidylate kinase. However, unlike the host enzyme, gp1.7 efficiently catalyses the conversion of the chain-terminating dideoxythymidylate (ddTMP) to ddTDP. This finding explains the sensitivity of phage T7 but not E. coli to exogenous ddT. Gp1.7 is unusual in that it has no sequence homology to any known nucleotide kinase, it has no identifiable nucleotide-binding motif and its activity is independent of added metal ions. When coupled with nucleoside diphosphate kinase, gp1.7 exponentially converts dTMP to dTTP.

A Novel Nucleotide Kinase Encoded by Gene 1.7 of Bacteriophage T7

Gene 1.7 of bacteriophage T7 confers sensitivity of phage T7 to dideoxythymidine (ddT). We have purified the product of gene 1.7 (gp1.7). It exists in two molecular weight forms. Only the C‐terminal half of the protein is required for ddT sensitivity. We show that gp1.7 catalyzes the phosphorylation of dTMP to dTDP with dTTP or dGTP as the phosphate donor. The Km of 70 μM and Vmax of 4.3 M‐1S‐1 are similar to those found for E. coli thymidylate kinase. However, unlike the host enzyme, gp1.7 efficiently catalyzes the conversion of the chain terminating dideoxythymidylate (ddTMP) to ddTDP, thus explaining the sensitivity of phage T7 but not E. coli to exogenous ddT. Gp1.7 has no sequence homology to any known nucleotide kinase, no identifiable nucleotide‐binding motif, and its activity is not dependent on added metal ion. When coupled with nucleoside diphosphosphate kinase, dTMP is exponentially converted to dTTP.

Nano- and Microstructure Fabrication by Using a Three-Component System

Two-component amphiphiles based on hydrogen-bonded complexes between terephthaloylbisalanine (H(2)TBA) and dodecylamine (DA) are able to self-assemble into nano- and microsized superstructures in an aqueous solvent. It is possible to modulate the morphology of these self-assembled superstructures by modifying the composition of the complexes, which can be achieved by changing the molar ratio of the two components or by changing the chirality of H(2)TBA. For example, right-handed microhelical ribbon structures were formed with L-TBA(1.0)DA(2.0), whereas in the case of rac-TBA(1.0)DA(2.0), flat ribbonlike structures were observed. Although L-TBA(1.0)DA(1.0) exhibited entangled fibrous structures, rac-TBA(1.0)DA(1.0) exhibited wire structures. Different ratios of H(2)TBA and DA were self-assembled into fiber-, wire-, and tubulelike superstructures, as well as monoclinic, columnar, and lamellar aggregation patterns. The self-assembled superstructures of TBA(x)DA(y) were significantly changed by adding metal ions. Transition metal (Cd(II), Co(II), and Zn(II)) complexes with L-TBA(x)DA(y) self-assembled into rod-, tubule-, wire-, and platelike superstructures. Metal-ion complexes with rac-TBA(x)DA(y) exhibited different superstructures. Our work suggests that it is possible to fabricate a wide variety of nano- and microsized superstructures by using two- and three-component amphiphiles.

DNA-hydrolyzing activity of IgG antibodies from the sera of patients with tick-borne encephalitis

DNase autoantibodies (Abzs) can be found in the blood of patients with several autoimmune diseases, while the blood of healthy donors or patients with diseases with an insignificant disturbance of the immune status does not contain DNase Abzs. Here we present the first analysis of the DNase Abzs activity in the patients with tick-borne encephalitis (TBE). Several strict criteria have been applied to show that the DNase activity is an intrinsic property of IgGs from the sera of TBE patients but not from healthy donors. The relative activity of IgGs has been shown to vary extensively from patient to patient, but most of the preparations (91%) had detectable levels of the DNase activity. Polyclonal DNase IgGs were not active in the presence of EDTA or after a dialysis against EDTA, but could be activated by several externally added metal ions, with the level of activity decreasing in the order Mn 2+ + Ca 2+ ≥ Mn 2++ Mg 2+ ≥ Mn 2+ ≥ Mg 2+ + Ca 2+ ≥ Co 2+ ≥ Mg 2+ > Ca 2+, while K +, Na +, Ni 2+, Zn 2+, and Cu 2+ did not stimulate DNA hydrolysis. Affinity chromatography on DNA-cellulose separated the DNase IgGs into many subfractions with various affinities for DNA and very different levels of the relative activity. Possible reasons for catalytic diversity of polyclonal human Abzs are discussed.

Effects of Modification of Calcium Hydroxyapatites by Trivalent Metal Ions on the Protein Adsorption Behavior

The effects of modification of calcium hydroxyapatites (Hap; Ca10(PO4)6(OH)2) by trivalent metal ions (Al(III), La(III), and Fe(III)) on protein adsorption behavior were examined using bovine serum albumin (BSA; isoelectric point (iep) = 4.7 and molecular mass (M(s)) = 67,200 Da). The Al(III)-, La(III)-, and Fe(III)-substituted Hap particles were prepared by the coprecipitation method with different atomic ratios, metal/(Ca + metal), abbreviated as X(metal). The particles precipitated at X(metal) = 0 (original-Hap) were rod-like and 10 x 36 nm2 in size. The short, rod-like original-Hap particles were elongated upon adding metal ions up to X(metal) = 0.10, and the extent of the particle growth was in the order of La(III) < Al(III) << Fe(III). The crystallinity of the materials was slightly lowered by increasing X(metal) for all systems. The adsorption isotherms of BSA onto the Al(III)-, La(III)-, and Fe(III)-substituted Hap particles showed the Langmuirian type. The saturated amounts of adsorbed BSA (n(s)(BSA)) values were strongly dependent on X(metal) in each system. The n(s)(BSA) values for the Fe(III)-substituted Hap system were increased with an increase in X(Fe) (X(metal) value of Hap particles substituted with Fe(III)); the n(s)(BSA) value obtained at X(Fe) = 0.10 was 2.7-fold more than that for the original-Hap particle, though those for the La(III) system were decreased to ca. 1/5. On the other hand, the n(s)(BSA) values for the Al(III) system were decreased with substitution of small amounts of Al(III), showing a minimum point at X(Al) = 0.01, but they were increased again at X(Al) over 0.03. Since the concentrations of hetero metal ions dissolved from the particles exhibited extremely low values, the possibility of binder effects of trivalent cations dissolved from the particle surface for adsorbing BSA to trivalent-ion-substituted Hap particles was excluded. The increase of n(s)(BSA) by an increase in X(Fe) was explained by elongation of mean particle length along with the production of surface hydroxo ions, such as Fe(OH)2+ or Fe(OH)2+, to induce the hydrogen bond between the Fe(III)-substituted Hap surface and BSA molecules, though the number of original C sites established by Ca(II) atoms was reduced. In the case of La(III)-substituted Hap particles, the number of original C sites established by Ca(II) atoms was reduced by La(III) substitution but the mean particle length remained almost constant. Furthermore, surface hydroxo La(III) groups were absent. Therefore, the reduction of n(s)(BSA) was explained by both the unaltered mean particle length and their low surface hydrophilicity. The change of n(s)(BSA) values by X(Al) resembled that of the mean particle length. These results implied that both the mean particle length and surface hydrophilicity of Al(III)-, La(III)-, and Fe(III)-substituted Hap particles are determining factors of the adsorption amounts of BSA.

Biochemical and mutagenic analysis of I-CreII reveals distinct but important roles for both the H-N-H and GIY-YIG motifs

Homing endonucleases typically contain one of four conserved catalytic motifs, and other elements that confer tight DNA binding. I-CreII, which catalyzes homing of the Cr.psbA4 intron, is unusual in containing two potential catalytic motifs, H-N-H and GIY-YIG. Previously, we showed that cleavage by I-CreII leaves ends (2-nt 3′ overhangs) that are characteristic of GIY-YIG endonucleases, yet it has a relaxed metal requirement like H-N-H enzymes. Here we show that I-CreII can bind DNA without an added metal ion, and that it binds as a monomer, akin to GIY-YIG enzymes. Moreover, cleavage of supercoiled DNA, and estimates of strand-specific cleavage rates, suggest that I-CreII uses a sequential cleavage mechanism. Alanine substitution of a number of residues in the GIY-YIG motif, however, did not block cleavage activity, although DNA binding was substantially reduced in several variants. Substitution of conserved histidines in the H-N-H motif resulted in variants that did not promote DNA cleavage, but retained high-affinity DNA binding—thus identifying it as the catalytic motif. Unlike the non-specific H-N-H colicins, however; substitution of the conserved asparagine substantially reduced DNA binding (though not the ability to promote cleavage). These results indicate that, in I-CreII, two catalytic motifs have evolved to play important roles in specific DNA binding. The data also indicate that only the H-N-H motif has retained catalytic ability.

The self-assembling and application of inorganic antibacterial material made of natural nanoporous carrier

The inorganic antimicrobial material was inhibited to the microbes with the added metal ion, Zn. The primary wet product carrying 5%–10% zinc ion was generated under the following conditions: temperature was 95 °C, solution zinc concentration was 1.2–2.0 mol/L, and the ratio of Zn solution to zeolite weight was 5: 1. The final stable product was manufactured after baking in an oven for 1–3 h at the temperature of 500–900 °C. The baked material was tested for its disinfection effectiveness and coloring effect when mixed with paint coating. Based on the final batch of tests, the zinc content of this anti-microbial product was further optimized.

Mutual Stimulation of Beta-Amyloid Fibrillogenesis by Clioquinol and Divalent Metals

As reported by some authors, clioquinol (CQ), a 8-hydroxyquinoline derivative, has produced very encouraging results in the treatment of Alzheimer's disease (AD). Its biological effects are most likely ascribed to complexation of specific metal ions, such as copper (II) and zinc (II), critically associated with beta-amyloid (A beta) aggregation/fibrillogenesis and degeneration processes in the brain. The present study was aimed at assessing the in vitro effects of CQ on the aggregation/fibrillogenesis properties of human A beta either alone or complexed with Cu(2+) and Zn(2+). Surprisingly, our data indicated that CQ promoted rather than inhibited the formation of A beta fibrillar aggregates when added metal ions were present. To understand whether the latter effects were related to the peptide amino acid sequence, we also investigated the aggregational profile of rat A beta, which differs from the human homologous for three amino acidic substitutions. Such a sequence alteration drastically reduced the tendency of the peptide to undergo spontaneous aggregation/fibrillization. In the presence of CQ and metals, however, also rat A beta showed a strong propensity to generate fibrillar aggregates. In agreement with the pro-aggregation effects observed in solution, studies with neuroblastoma cells demonstrated an impairment of cell functioning only in the presence of CQ + A beta-metals. Based on the present findings, the literature data on the potential effectiveness of CQ-based chelation therapy in AD should be re-interpreted.

Templateless Synthesis of Polygonal Gold Nanoparticles: An Unsupported and Reusable Catalyst with Superior Activity

AbstractWe report the synthesis of polygonal gold nanoparticles (GNPs) by an in situ reduction technique using ferric ammonium citrate as reducing agent in absence of any surfactant or polymeric template. Transmission electron microscopic analysis and selected area electron diffraction patterns confirmed the formation of well‐crystalline polygonal GNPs grown preferentially along the (111) direction, which is consistent with the results of X‐ray diffractometry analysis. The results of control experiments of HAuCl4 with tri‐ammonium citrate in presence of different externally added metal ions like Fe3+, Ni2+, Cu2+, Zn2+, and Al3+ suggested the ion‐induced growth mechanism in the formation of polygonal GNPs. The purified polygonal GNPs were then successfully used as catalyst in the borohydride reduction of three isomeric nitrophenols and also in the aerobic oxidation of different D‐hexoses (e.g., D‐glucose, D‐mannose, D‐fructose). The catalytic activity of these polygonal GNPs is higher by a factor of 300–1000, depending on the GNP's sample type, in nitrophenol reduction compared to that of spherical GNPs. Similar activity enhancement was also observed in the aerobic oxidation of different D‐hexoses. These polygonal GNPs catalyst are very stable and could be reused several times in the borohydride reduction of nitrophenols without much losing in their virgin catalytic activity.

Damage to lung epithelial cells and lining fluid antioxidant defense by humic acid

Humic acid causes diseases including lung emphysema and fibrosis. Emerging evidence indicates that oxidative stress is involved in humic acid-induced effects. In the present study, we investigated generation of hydroxyl radicals from humic acid, as well as the effects of humic acid to lung epithelial cells and artificial alveolar lining fluid antioxidant mixture. The involvement of iron in humic acid-induced effects was also determined. We found that humic acid (concentration and time dependently) reduced the cell survival, increased caspase-3 activity, depleted GSH and raised lipid peroxidation in epithelial cells. Humic acid reduced antioxidant levels in the lining fluid antioxidant mix, which could be prevented by adding metal ion chelators. These findings suggest that humic acid causes oxidative stress in lung cells and alveolar lining fluid, which is most likely triggered by hydroxyl radicals produced directly from humic acid. Iron is probably involved in humic acid toxicity.