Speciation and Quantitative Mapping of Metal Species in Microbial Biofilms Using Scanning Transmission X-ray Microscopy

Dynes, James J.; Tyliszczak, Tolek; Araki, Tohru; Lawrence, John R.; Swerhone, G. D. W.; Leppard, Gary G.; Hitchcock, Adam P.

doi:10.1021/es0513638

Cited by 128 publications

(142 citation statements)

References 48 publications

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“…Synchrotron-based scanning transmission X-ray spectromicroscopy (STXM) enables the study of the minerals and organic functional group chemistry of hydrated samples with high spatial and spectral resolutions (<40 nm and <0.1 eV, respectively). STXM has proven to be a useful tool for studying both organics and metals in biofilms and biominerals, as demonstrated by work on Mn-oxidizing bacteria (Pecher et al, 2003;Toner et al, 2005), microbial calcification (Benzerara et al, 2004(Benzerara et al, , 2006, and river biofilms (Lawrence et al, 2003;Dynes et al, 2006). We performed synthesis experiments to simulate the postulated mineralization pathway, and used STXM-based carbon and iron near edge Xray absorption fine structure (NEXAFS) spectroscopy to observe the progression of polymer-iron interactions during the course of mineral formation.…”

Section: Introductionmentioning

confidence: 99%

Iron oxyhydroxide mineralization on microbial extracellular polysaccharides

Chan

Fakra

Edwards

et al. 2009

Geochimica et Cosmochimica Acta

341

259

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Iron biominerals can form in neutral pH microaerophilic environments where microbes both catalyze iron oxidation and create polymers that localize mineral precipitation. In order to classify the microbial polymers that influence FeOOH mineralogy, we studied the organic and mineral components of biominerals using scanning transmission X-ray microscopy (STXM), micro X-ray fluorescence (lXRF) microscopy, and high-resolution transmission electron microscopy (HRTEM). We focused on iron microbial mat samples from a creek and abandoned mine; these samples are dominated by iron oxyhydroxide-coated structures with sheath, stalk, and filament morphologies. In addition, we characterized the mineralized products of an iron-oxidizing, stalk-forming bacterial culture isolated from the mine. In both natural and cultured samples, microbial polymers were found to be acidic polysaccharides with carboxyl functional groups, strongly spatially correlated with iron oxyhydroxide distribution patterns. Organic fibrils collect FeOOH and control its recrystallization, in some cases resulting in oriented crystals with high aspect ratios. The impact of polymers is particularly pronounced as the materials age. Synthesis experiments designed to mimic the biomineralization processes show that the polysaccharide carboxyl groups bind dissolved iron strongly but release it as mineralization proceeds. Our results suggest that carboxyl groups of acidic polysaccharides are produced by different microorganisms to create a wide range of iron oxyhydroxide biomineral structures. The intimate and potentially long-term association controls the crystal growth, phase, and reactivity of iron oxyhydroxide nanoparticles in natural systems.

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Section: Introductionmentioning

confidence: 99%

Iron oxyhydroxide mineralization on microbial extracellular polysaccharides

Chan

Fakra

Edwards

et al. 2009

Geochimica et Cosmochimica Acta

341

259

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“…[4][5][6][7][8][9][10][11] Better understanding of damage mechanisms and more accurate determinations of damage rates for polymers are not only important to the areas mentioned above, but also to the field of soft X-ray spectromicroscopy, which is increasingly being applied to organic materials [12][13][14][15] and biological samples. 14,16,17 A complete bibliography of soft X-ray spectromicroscopy has recently been published in association with a recent review of polymer applications 15 and updates can be obtained from http://unicorn. mcmaster.ca/xrm-biblio/xrm_bib.html.…”

Section: Introductionmentioning

confidence: 99%

Quantitative Evaluation of Radiation Damage to Polyethylene Terephthalate by Soft X-rays and High-energy Electrons

et al. 2009

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The chemical changes and absolute rates in radiation damage to polyethylene terephthalate (PET) caused by soft X-rays and energetic electrons have been measured using a scanning transmission X-ray microscope (STXM). Electron beam damage at two different dose rates and a range of doses was performed in an 80 keV transmission electron microscope (TEM). The STXM beam was used to create damage patterns with systematically varied doses of monochromatic soft X-rays on an adjacent piece of the same PET sample. NEXAFS spectroscopy at the C 1s and O 1s edges was used to study the chemistry of the radiation damage and to determine quantitative critical doses for PET damage by both types of radiation. The spectral changes were similar for damage by electrons and X-rays, indicating the radiation chemistry is dominated by secondary processes, not the primary event. The critical dose for chemical changes determined from C 1s spectral features is 4.2(6) × 10 8 Gy and was the same for soft X-rays and electrons within measurement uncertainties. The critical dose for specific damage processes (as defined by changes in several different, bond-specific spectral features) was found to be similar in the C 1s region and was comparable between C 1s and O 1s edges for electron beam damage. There were statistically different critical doses for soft X-ray damage as probed by changes in O 1s spectral features related to carbonyl and ester bonds.

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“…Quantitative component maps of the major biomacromolecules (proteins, lipids, and polysaccharides) as well as CO 3 2Ϫ , K ϩ , and CHX, were derived by fitting the image sequences at each pixel to the spectra of the reference compounds that had been placed on an absolute linear absorbance scale using the singular value decomposition procedure (38). Absolute linear absorbance is the optical density (OD) per unit path length of a pure material of a defined density, where the absorbance (A), also called OD, is given by the equation A ϭ OD ϭ Ϫln(I/Io), where I is the transmitted intensity and Io is the incident intensity, and it is established by adjusting the intensity scale of the reference spectrum to that of the computed elemental response outside the structured near-edge region (41). The lower and upper limits of the gray scale indicated in the component maps are a measure of the component thickness in nm.…”

Section: Methodsmentioning

confidence: 99%

“…The lower and upper limits of the gray scale indicated in the component maps are a measure of the component thickness in nm. The reliability and methodology used to quantitatively map the major biomacromolecules in biofilm cells have been described in detail elsewhere (19,23,41). The reference compounds used were protein (human serum albumin), lipid (1,2-dipalmitoyl-sn-glycero-3-phosphocholine), polysaccharide (xanthan gum), carbonate (calcite), K (K 2 CO 3 with CO 3 derived from Ca carbonate subtracted) (20,22), and chlorhexidine dihydrochloride (CHX).…”

Section: Methodsmentioning

confidence: 99%

Microscopic and Spectroscopic Analyses of Chlorhexidine Tolerance in Delftia acidovorans Biofilms

Rema

Lawrence

Dynes

et al. 2014

Antimicrob Agents Chemother

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The physicochemical responses of Delftia acidovorans biofilms exposed to the commonly used antimicrobial chlorhexidine (CHX) were examined in this study. A CHX-sensitive mutant (MIC, 1.0 g ml ؊1 ) was derived from a CHX-tolerant (MIC, 15.0 g ml ؊1 ) D. acidovorans parent strain using transposon mutagenesis. D. acidovorans mutant (MT51) and wild-type (WT15) strain biofilms were cultivated in flow cells and then treated with CHX at sub-MIC and inhibitory concentrations and examined by confocal laser scanning microscopy (CLSM), scanning transmission X-ray microscopy (STXM), and infrared (IR) spectroscopy. Specific morphological, structural, and chemical compositional differences between the CHX-treated and -untreated biofilms of both strains were observed. Apart from architectural differences, CLSM revealed a negative effect of CHX on biofilm thickness in the CHX-sensitive MT51 biofilms relative to those of the WT15 strain. STXM analyses showed that the WT15 biofilms contained two morphochemical cell variants, whereas only one type was detected in the MT51 biofilms. The cells in the MT51 biofilms bioaccumulated CHX to a similar extent as one of the cell types found in the WT15 biofilms, whereas the other cell type in the WT15 biofilms did not bioaccumulate CHX. STXM and IR spectral analyses revealed that CHX-sensitive MT51 cells accumulated the highest levels of CHX. Pretreating biofilms with EDTA promoted the accumulation of CHX in all cells. Thus, it is suggested that a subpopulation of cells that do not accumulate CHX appear to be responsible for greater CHX resistance in D. acidovorans WT15 biofilm in conjunction with the possible involvement of bacterial membrane stability.

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Speciation and Quantitative Mapping of Metal Species in Microbial Biofilms Using Scanning Transmission X-ray Microscopy

Cited by 128 publications

References 48 publications

Iron oxyhydroxide mineralization on microbial extracellular polysaccharides

Iron oxyhydroxide mineralization on microbial extracellular polysaccharides

Quantitative Evaluation of Radiation Damage to Polyethylene Terephthalate by Soft X-rays and High-energy Electrons

Microscopic and Spectroscopic Analyses of Chlorhexidine Tolerance in Delftia acidovorans Biofilms

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