Your search keyword '"PG, phosphatidyl glycerol"' showing total 7 results

1. Biofilms of the non-tuberculous

Author

Perla, Vega-Dominguez, Eliza, Peterson, Min, Pan, Alessandro, Di Maio, Saumya, Singh, Siva, Umapathy, Deepak K, Saini, Nitin, Baliga, and Apoorva, Bhatt

Subjects

TDM, Trehalose dimycolate, NTMs, Non-tuberculous mycobacteria, Mycobacterium chelonae, Extracellular matrix, biochemical phenomena, metabolism, and nutrition, Lipids, Article, ECM, Extracellular matrix, Biofilms, Non-tuberculous mycobacteria, Raman spectroscopy, SEM, Scanning electron microscopy, eDNA, Extra cellular DNA, FMA, Free mycolic acids, PG, Phosphatidyl glycerol, DEG, Differentially expressed genes

Abstract

Mycobacterium chelonae is an environmental, non-tuberculous mycobacterial species, capable of causing infections in humans. Biofilm formation is a key strategy used by M. chelonae in colonising niches in the environment and in the host. We studied a water-air interface (pellicle) biofilm of M. chelonae using a wide array of approaches to outline the molecular structure and composition of the biofilm. Scanning electron micrographs showed that M. chelonae biofilms produced an extracellular matrix. Using a combination of biochemical analysis, Raman spectroscopy, and fluorescence microscopy, we showed the matrix to consist of proteins, carbohydrates, lipids and eDNA. Glucose was the predominant sugar present in the biofilm matrix, and its relative abundance decreased in late (established) biofilms. RNA-seq analysis of the biofilms showed upregulation of genes involved in redox metabolism. Additionally, genes involved in mycolic acid, other lipid and glyoxylate metabolism were also upregulated in the early biofilms.

Published

2020

2. Lipids in membrane protein structures

Author

Palsdottir, Hildur and Hunte, Carola

Subjects

*DEHYDROGENASES, *ELECTRON paramagnetic resonance, *BIOMOLECULES, *MEMBRANE proteins, *CYTOCHROMES, *VITAMIN B complex

Abstract

This review describes the recent knowledge about tightly bound lipids in membrane protein structures and deduces general principles of the binding interactions. Bound lipids are grouped in annular, nonannular, and integral protein lipids. The importance of lipid binding for vertical positioning and tight integration of proteins in the membrane, for assembly and stabilization of oligomeric and multisubunit complexes, for supercomplexes, as well as their functional roles are pointed out. Lipid binding is stabilized by multiple noncovalent interactions from protein residues to lipid head groups and hydrophobic tails. Based on analysis of lipids with refined head groups in membrane protein structures, distinct motifs were identified for stabilizing interactions between the phosphodiester moieties and side chains of amino acid residues. Differences between binding at the electropositive and electronegative membrane side, as well as a preferential binding to the latter, are observed. A first attempt to identify lipid head group specific binding motifs is made. A newly identified cardiolipin binding site in the yeast cytochrome bc1 complex is described. Assignment of unsaturated lipid chains and evolutionary aspects of lipid binding are discussed. [Copyright &y& Elsevier]

Published

2004

3. Polymer vesicles in vivo: correlations with PEG molecular weight

Author

Photos, Peter J., Bacakova, Lucie, Discher, Bohdana, Bates, Frank S., and Discher, Dennis E.

Subjects

*COATED vesicles, *POLYMERS, *LIPIDS

Abstract

PEG-modified lipid vesicles have already shown considerable utility in delaying vesicle clearance from the circulation. They are, however, limited in their ability to stably integrate high molar ratios of PEG–lipid due to the high curvature and micellar preference of the very large hydrophilic PEG chain. Polymersomes, by contrast, are vesicles composed entirely of PEG-based block copolymer amphiphiles that are not only more proportionately designed, but also have already been shown to considerably broaden the range of vesicle properties (e.g. stability). Here, polymersomes composed of varying length copolymer chains were injected into rats and found to have in vivo circulation times, τ1/2, up to about two-fold longer than PEGylated, or Stealth, liposomes. The dependence of τ1/2 on PEG molecular weight is nonetheless limited by uptake into the liver and spleen—as with liposomes. In vitro incubations of polymersomes in plasma indicate gradual opsonization through plasma protein adsorption, such that, when vesicles are held in an optical trap and presented to a phagocyte, rapid engulfment occurs only after incubation times of similar magnitude to τ1/2. The stealthiness introduced to liposomes through PEGylation is thus extended here with completely synthetic polymersomes. [Copyright &y& Elsevier]

Published

2003

4. Binding of sea anemone pore-forming toxins sticholysins I and II to interfaces—Modulation of conformation and activity, and lipid–protein interaction

Author

Alvarez, Carlos, Casallanovo, Fabio, Shida, Claudio S., Nogueira, Luciana V., Martinez, Diana, Tejuca, Mayra, Pazos, Isabel F., Lanio, Maria E., Menestrina, Gianfranco, Lissi, Eduardo, and Schreier, Shirley

Subjects

*CIRCULAR dichroism, *CARDIOLIPIN

Abstract

Sticholysins I and II (St I and St II) are water-soluble toxins produced by the sea anemone Stichodactyla helianthus. St I and St II bind to biological and model membranes containing sphingomyelin (SM), forming oligomeric pores that lead to leakage of internal contents. Here we describe functional and structural studies of the toxins aiming at the understanding at a molecular level of their mechanism of binding, as well as their effects on membrane permeabilization. St I and St II caused potassium leakage from red blood cells and temperature-dependent hemolysis, the activation energy of the process being lower for the latter toxin. Protein intrinsic fluorescence measurements provided evidence for toxin binding to model membranes composed of 1:1 (mol:mol) egg phosphatidyl choline (ePC):SM. The fluorescence intensity increased and the maximum emission wavelength decreased as a result of binding. The changes were quantitatively different for both toxins. Circular dichroism spectra showed that both St I and St II exhibit a high content of β-sheet structure and that binding to model membranes did not alter the toxin''s conformation to a large extent. Changing the lipid composition by adding 5 mol% of negatively charged phosphatidic acid (PA) or phosphatidyl glycerol (PG) had small, but detectable, effects on protein conformation. The influence of lipid composition on toxin-induced membrane permeabilization was assessed by means of fluorescence measurements of calcein leakage. The effect was larger for ePC:SM bilayers containing 5 mol% of negative curvature-inducing lipids. Electron paramagnetic resonance (EPR) spectra of intercalated fatty acid spin probes carrying the nitroxide moiety at different carbons (5, 7, 12, and 16) evidenced the occurrence of lipid–protein interaction. Upon addition of the toxins, two-component spectra were observed for the probe labeled at C-12. The broader component, corresponding to a population of strongly immobilized spin probes, was ascribed to boundary lipid. The contribution of this component to the total spectrum was larger for St II than for St I. Moreover, it was clearly detectable for the C-12-labeled probe, but it was absent when the label was at C-16, indicating a lack of lipid–protein interaction close to the lipid terminal methyl group. This effect could be either due to the fact that the toxins do not span the whole bilayer thickness or to the formation of a toroidal pore leading to the preferential interaction with acyl chain carbons closer to the phospholipids head groups. [Copyright &y& Elsevier]

Published

2003

5. Enhanced imaging of lipid rich nanoparticles embedded in methylcellulose films for transmission electron microscopy using mixtures of heavy metals

Author

Jalal, Asadi, Sophie, Ferguson, Hussain, Raja, Christian, Hacker, Phedra, Marius, Richard, Ward, Christos, Pliotas, James, Naismith, and John, Lucocq

Subjects

DMPC, dimyristoyl-phosphatidylcholine, DHPC, dihexanoyl phosphatidylcholine, Uranyl acetate, Methylcellulose, Negative Staining, Article, Specimen Handling, Sodium silicotungstate, Microscopy, Electron, Transmission, Negative stain, Metals, Heavy, STA, sodium silicotungstate, Organometallic Compounds, Bicelles, Phospholipids, EM, electron microscopy, PE, phosphatidyl ethanolamine, Membranes, Staining and Labeling, Silicates, UA, uranyl acetate, Nanodiscs, Phosphotungstic Acid, Tungsten Compounds, PTA, phosphotungstic acid, Lipids, MC, methyl cellulose, LRPN, lipid rich nanoparticle, Liposomes, Nanoparticles, CL, Cardiolipin, PG, phosphatidyl glycerol

Abstract

Highlights • Uranyl acetate/tungsten double stains are proposed for imaging lipid rich nanoparticle in TEM. • Combined with methylcellulose embedment, the technique enhances membrane contrast. • The technique works for liposomes, nanodiscs and bicelles. • The double staining should improve quantification of lipid rich nanoparticles., Synthetic and naturally occurring lipid-rich nanoparticles are of wide ranging importance in biomedicine. They include liposomes, bicelles, nanodiscs, exosomes and virus particles. The quantitative study of these particles requires methods for high-resolution visualization of the whole population. One powerful imaging method is cryo-EM of vitrified samples, but this is technically demanding, requires specialized equipment, provides low contrast and does not reveal all particles present in a population. Another approach is classical negative stain-EM, which is more accessible but is difficult to standardize for larger lipidic structures, which are prone to artifacts of structure collapse and contrast variability. A third method uses embedment in methylcellulose films containing uranyl acetate as a contrasting agent. Methylcellulose embedment has been widely used for contrasting and supporting cryosections but only sporadically for visualizing lipid rich vesicular structures such as endosomes and exosomes. Here we present a simple methylcellulose-based method for routine and comprehensive visualization of synthetic lipid rich nanoparticles preparations, such as liposomes, bicelles and nanodiscs. It combines a novel double-staining mixture of uranyl acetate (UA) and tungsten-based electron stains (namely phosphotungstic acid (PTA) or sodium silicotungstate (STA)) with methylcellulose embedment. While the methylcellulose supports the delicate lipid structures during drying, the addition of PTA or STA to UA provides significant enhancement in lipid structure display and contrast as compared to UA alone. This double staining method should aid routine structural evaluation and quantification of lipid rich nanoparticles structures.

Published

2017

6. Biofilms of the non-tuberculous Mycobacterium chelonae form an extracellular matrix and display distinct expression patterns.

Author

Vega-Dominguez P, Peterson E, Pan M, Di Maio A, Singh S, Umapathy S, Saini DK, Baliga N, and Bhatt A

Abstract

Mycobacterium chelonae is an environmental, non-tuberculous mycobacterial species, capable of causing infections in humans. Biofilm formation is a key strategy used by M. chelonae in colonising niches in the environment and in the host. We studied a water-air interface (pellicle) biofilm of M. chelonae using a wide array of approaches to outline the molecular structure and composition of the biofilm. Scanning electron micrographs showed that M. chelonae biofilms produced an extracellular matrix. Using a combination of biochemical analysis, Raman spectroscopy, and fluorescence microscopy, we showed the matrix to consist of proteins, carbohydrates, lipids and eDNA. Glucose was the predominant sugar present in the biofilm matrix, and its relative abundance decreased in late (established) biofilms. RNA-seq analysis of the biofilms showed upregulation of genes involved in redox metabolism. Additionally, genes involved in mycolic acid, other lipid and glyoxylate metabolism were also upregulated in the early biofilms., Competing Interests: The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (© 2020 The Authors.)

Published

2020

7. Natrarchaeobius chitinivorans gen. nov., sp. nov., and Natrarchaeobius halalkaliphilus sp. nov., alkaliphilic, chitin-utilizing haloarchaea from hypersaline alkaline lakes

Author

Ilya V. Kublanov, Jaap S. Sinninghe Damsté, Tatiana V. Khijniak, Nicole J. Bale, Stepan V. Toshchakov, Dimitry Y. Sorokin, Alexander G. Elcheninov, and non-UU output of UU-AW members

Subjects

Salinity, Soda lakes, MGE, monoalkyl glycerol ether, Chitin, DGE, dialkyl glycerol ether, Applied Microbiology and Biotechnology, chemistry.chemical_compound, Natrialba, RNA, Ribosomal, 16S, Natronoarchae, Phylogeny, 0303 health sciences, biology, Pigmentation, Quinones, Hydrogen-Ion Concentration, 6. Clean water, Halophile, PG, phosphatidyl glycerol, Energy source, Water Microbiology, DNA, Bacterial, Euryarchaeota, PE, phosphatidylethanolamine, Microbiology, Article, 03 medical and health sciences, Membrane Lipids, Bacterial Proteins, Species Specificity, Botany, Halopiger, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, 030306 microbiology, Chitinase, Sequence Analysis, DNA, PGP-Me, phosphatidylglycerophosphate methylester, Natrialbaceae, biology.organism_classification, PGP, phosphatidylglycerophosphate, Lakes, chemistry, biology.protein, Haloarchaea, Natrarchaeobius, Natronoarchaea, Genome, Bacterial, Archaea

Abstract

Two groups of alkaliphilic haloarchaea from hypersaline alkaline lakes in Central Asia, Egypt and North America were enriched and isolated in pure culture using chitin as growth substrate. These cultures, termed AArcht, were divided into two groups: group 1 which includes eleven isolates from highly alkaline soda lakes and group 2 which contains a single isolate obtained from the alkaline hypersaline Searles Lake. The colonies of chitin-utilizing natronoarchaea were red-pigmented and surrounded by large zones of chitin hydrolysis. The free cells of both groups were mostly flat nonmotile rods, while the cells that attached to chitin or formed colonies on chitin plates were mostly coccoid. The isolates are obligate aerobic saccharolytic archaea utilizing chitin and chitosane (less actively) as the only sugar polymers as well as a few hexoses as their carbon and energy source. Both groups are extremely halophilic, growing optimally at 3.5–4 M total Na+, but they differ in their pH profiles: the main group 1 isolates are obligately alkaliphilic, while the single group 2 strain (AArcht-SlT) is alkalitolerant. The core archaeal lipids in both groups are dominated by C20–C20 and C20–C25 dialkyl glycerol ethers (DGE) in approximately equal proportion. Phylogenetic analysis indicated that the isolates form an independent genus-level lineage within the family Natrialbaceae with 3 species-level subgroups. The available genomes of the closest cultured relatives of the AArcht strains, belonging to the genera Natrialba and Halopiger, do not encode any chitinase-related genes. On the basis of their unique phenotypic properties and distinct phylogeny, we suggest that the obligate alkaliphilic AArcht isolates (group 1) with an identical phenotype are classified into a new genus and species Natrarchaeobius chitinivorans gen. nov., sp. nov., with strain AArcht4T as the type strain (JCM 32476T = UNIQEM U966T), while the facultatively alkaliphilic strain AArcht-SlT (group 2) — as a new species Natrarchaeobius halalkaliphilus sp. nov. (JCM 32477T = UNIQEM U969T).