Quantitative determination of ion distributions in bacterial lipopolysaccharide membranes by grazing-incidence X-ray fluorescence

Schneck, Emanuel; Schubert, Thomas; Konovalov, Oleg; Quinn, Bonnie; Gutsmann, Thomas; Brandenburg, Klaus; Oliveira, Rafael G.; Pink, David A.; Tanaka, Motomu

doi:10.1073/pnas.0913737107

Cited by 116 publications

(145 citation statements)

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“…When Ca 2+ ions are present, the Ptm is essentially unbound and exhibits a distribution between~9 and~16 nm. This result is in accord with predictions [36] relating to the MIC of P. aeruginosa and recently confirmed [53][54][55][56] employing grazing-incidence X-ray scattering to investigate monolayers of LPS taken from the outer membranes of Salmonella enterica and P. aeruginosa. Figure 4A for a (65:35) membrane and the Na + (black, f) and Ptm (black, g) distributions for a (75:25) membrane.…”

Section: Mathematical Modeling and Computer Simulationsupporting

confidence: 87%

“…The intent of representing some of the ions by a Debye screening length, -κ 1 , was so that we could carry out our simulations using a screened potential to avoid having to model infinite-range interactions using standard techniques, such as the Ewald approach [39]. We have successfully used and discussed this approach elsewhere [36,[53][54][55][56], where the value of κ = 0.5 nm 1 was also used. Briefly, the criterion for choosing κ is related to maximizing the region of space in which the ions are represented as discrete charges and not described by the continuum (meanfield) theory, while keeping the simulation time within an acceptable value.…”

Section: Mathematical Modeling and Computer Simulationmentioning

confidence: 99%

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Interaction of protamine with gram‐negative bacteria membranes: possible alternative mechanisms of internalization in Escherichia coli, Salmonella typhimurium and Pseudomonas aeruginosa

Pink

Hasan

Quinn

et al. 2014

Journal of Peptide Science

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This study was concerned with the interaction between the cationic antimicrobial peptide, protamine (Ptm) and the cytoplasmic membranes of the gram-negative bacteria Escherichia coli, Salmonella typhimurium and Pseudomonas aeruginosa. The objective of the study was to explain the observed paradox of internalization without permanent disruption of the cell envelope. We carried out Monte Carlo computer simulation of Ptm in an aqueous environment in the presence of~100 mM NaCl and model membranes consisting of either (65:35) or (75:25) PE:PG molar ratios. The (75:25) model, representative of the gram-negative cytoplasmic membrane, showed that the Ptm center of mass remained at least 7 nm from the membrane surface leading to the prediction that Ptm would not internalize via disruption of the inner membrane.By using immunoelectron microscopy of Ptm-treated cells, we showed that Ptm internalization to the cytoplasm took place rapidly in the presence or absence of the outer envelope. Ultrastructural examination revealed no obvious morphological changes to cells that were treated with subinhibitory or bactericidal levels of Ptm. Reconstituted phospholipid bilayers were constructed and were unperturbed by Ptm treatment over a wide range of concentrations and applied transmembrane voltages. We conclude that in the cases of the cell envelopes of E. coli, S. typhimurium and P. aeruginosa, Ptm internalized by means independent of the phospholipid bilayer, most likely mediated by one or more membrane proteins such as cation-selective barrel-like proteins. Work is currently underway to test this hypothesis.

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Section: Mathematical Modeling and Computer Simulationsupporting

confidence: 87%

Section: Mathematical Modeling and Computer Simulationmentioning

confidence: 99%

Interaction of protamine with gram‐negative bacteria membranes: possible alternative mechanisms of internalization in Escherichia coli, Salmonella typhimurium and Pseudomonas aeruginosa

Pink

Hasan

Quinn

et al. 2014

Journal of Peptide Science

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“…1, we safely neglected the depth dependence of the fluorescence attenuation, because in the present study the target elements are confined in nanometric layers. For a given incident angle θ, Φ(θ, z) follows from the interfacial scattering length density (SLD) profile and can be computed from a suitable slab model representation of the SLD via the phase-correct summation of all reflected and transmitted partial waves (23), as has been described previously (14). As shown in the inset of Fig.…”

Section: Resultsmentioning

confidence: 99%

“…The angle-dependent fluorescence intensity thus contains information on the interfacial element distribution (7). This principle has been exploited for the study of interfacial phenomena involving solid, liquid, and gas phases (8)(9)(10)(11)(12)(13)(14)(15)(16). High resolution perpendicular to the interface is implied by SWXF experiments in Bragg reflection configuration, in which case planar, nanometric multilayers are used to create strongly modulated standing waves above the terminal surface close to the Bragg condition (9,10).…”

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confidence: 99%

Atom-scale depth localization of biologically important chemical elements in molecular layers

Schneck

Scoppola

Drnec

et al. 2016

Proc. Natl. Acad. Sci. U.S.A.

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In nature, biomolecules are often organized as functional thin layers in interfacial architectures, the most prominent examples being biological membranes. Biomolecular layers play also important roles in context with biotechnological surfaces, for instance, when they are the result of adsorption processes. For the understanding of many biological or biotechnologically relevant phenomena, detailed structural insight into the involved biomolecular layers is required. Here, we use standing-wave X-ray fluorescence (SWXF) to localize chemical elements in solid-supported lipid and protein layers with near-Ångstrom precision. The technique complements traditional specular reflectometry experiments that merely yield the layers' global density profiles. While earlier work mostly focused on relatively heavy elements, typically metal ions, we show that it is also possible to determine the position of the comparatively light elements S and P, which are found in the most abundant classes of biomolecules and are therefore particularly important. With that, we overcome the need of artificial heavy atom labels, the main obstacle to a broader application of high-resolution SWXF in the fields of biology and soft matter. This work may thus constitute the basis for the label-free, element-specific structural investigation of complex biomolecular layers and biological surfaces.surfaces | interfaces | lipid membranes | protein adsorption | X-ray scattering N anometric biomolecular layers in interfacial geometries are key components of biological matter. Biological membranes, for example, are 2D molecular structures composed mainly of lipids and proteins in an aqueous environment (1, 2). Interfacial biomolecular layers are also important from a biotechnological perspective, where surfaces are often designed to selectively promote or prevent the adsorption of bio(macro)molecules from solution (3). To investigate the diverse behavior of biomolecules at interfaces, well-defined planar model systems of biological and biotechnologically relevant interfaces have been established (4, 5). Processes involving biomolecules at interfaces are typically accompanied by a spatial reorganization of molecules, changes in molecular conformations, or the adsorption of molecules in a chemically heterogeneous environment (6). Structural insight on the nanometer scale is therefore of paramount importance.X-ray and neutron scattering are uniquely suited for the structural investigation of biomolecular systems. Specular reflectometry reveals matter density profiles perpendicular to a planar interface. However, it is generally difficult to elucidate molecular conformations and elemental distributions from such "global" density profiles. In contrast, standing-wave X-ray fluorescence (SWXF) allows determining element-specific density profiles across an interface. The SWXF technique is based on the elementcharacteristic fluorescence induced by a standing X-ray wave. The latter is formed by interference of the incident and reflected waves and its shape depends o...

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“…The binding of Ca 2ϩ and Mg 2ϩ to the negatively charged surface lipopolysaccharides (LPS) in Gram-negative bacteria generates ionic cross bridges, which exert a stabilizing effect on the outer cell membrane (41)(42)(43)(44). Notwithstanding variations in the cell wall/membrane makeup and structure between Gram-positive and Gram-negative bacteria (45), we considered whether the formation of Ca 2ϩ -mediated cross bridges in the Gram-positive bacterium C. beijerinckii might partly contribute to the effects of Ca 2ϩ on ABE fermentation.…”

Section: Discussionmentioning

confidence: 99%

Use of Proteomic Analysis To Elucidate the Role of Calcium in Acetone-Butanol-Ethanol Fermentation by Clostridium beijerinckii NCIMB 8052

Han

Ujor

Lai

et al. 2013

Appl Environ Microbiol

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c Calcium carbonate increases growth, substrate utilization, and acetone-butanol-ethanol (ABE) fermentation by Clostridium beijerinckii NCIMB 8052. Toward an understanding of the basis for these pleiotropic effects, we profiled changes in the C. beijerinckii NCIMB 8052 proteome that occur in response to the addition of CaCO 3 . We observed increases in the levels of different heat shock proteins (GrpE and DnaK), sugar transporters, and proteins involved in DNA synthesis, repair, recombination, and replication. We also noted significant decreases in the levels of proteins involved in metabolism, nucleic acid stabilization, sporulation, oxidative and antibiotic stress responses, and signal transduction. We determined that CaCO 3 enhances ABE fermentation due to both its buffering effects and its ability to influence key cellular processes, such as sugar transport, butanol tolerance, and solventogenesis. Moreover, activity assays in vitro for select solventogenic enzymes revealed that part of the underpinning for the CaCO 3 -mediated increase in the level of ABE fermentation stems from the enhanced activity of these catalysts in the presence of Ca 2؉ . Collectively, these proteomic and biochemical studies provide new insights into the multifactorial basis for the stimulation of ABE fermentation and butanol tolerance in the presence of CaCO 3 . Growing concerns over increased emissions of greenhouse gases from the combustion of fossil fuels and the global energy crisis have recently spawned extensive research into renewable energy. As a result, there is a resurgent interest in butanol as an alternative fuel, due mainly to its higher energy content than ethanol and its compatibility with gasoline, with the latter trait making it more compatible with existing pipelines for distribution (1, 2). However, the cost of butanol production, which currently relies on petroleum feedstock, is not favorable compared to gasoline (3). Although acetone-butanol-ethanol (ABE) fermentation with solventogenic Clostridium species holds promise as a potentially cheaper means of butanol production, low yields and productivity due to butanol toxicity to the fermenting cells have hampered the commercialization of biobutanol (4, 5).To increase yield and productivity, fermentation broth additives such as acetate (6, 7) and calcium carbonate (3, 8, 9) have been successfully utilized. During ABE fermentation by solventogenic Clostridium species, CaCO 3 has been shown to stimulate sugar utilization, butanol production, and butanol tolerance (3,8,9). For example, during Clostridium acetobutylicum fermentation, the addition of 8 g/liter butanol (to mimic solvent intolerance) limited xylose utilization to 30 g/liter (from a starting concentration of 60 g/liter); however, upon the addition of CaCO 3 (10 g/liter), xylose utilization increased to 43 g/liter (8). Similarly, when ABE fermentation was conducted in an iron-deficient medium, which modifies carbon and electron flow to favor early butanol accumulation, the xylose utilization by C. acetobutyl...

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Quantitative determination of ion distributions in bacterial lipopolysaccharide membranes by grazing-incidence X-ray fluorescence

Cited by 116 publications

References 38 publications

Interaction of protamine with gram‐negative bacteria membranes: possible alternative mechanisms of internalization in Escherichia coli, Salmonella typhimurium and Pseudomonas aeruginosa

Interaction of protamine with gram‐negative bacteria membranes: possible alternative mechanisms of internalization in Escherichia coli, Salmonella typhimurium and Pseudomonas aeruginosa

Atom-scale depth localization of biologically important chemical elements in molecular layers

Use of Proteomic Analysis To Elucidate the Role of Calcium in Acetone-Butanol-Ethanol Fermentation by Clostridium beijerinckii NCIMB 8052

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