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Synthesis of Phosphatidylethanolamine Lipids for Model Studies of the Cell MembraneTeye-Kau, John Hayford G 01 December 2021 (has links)
Concerns about global warming have resulted in a surge of research into alternatives to fossil fuels. In recent years, biofuels have gained traction due to their low environmental impact. Biofuel production most commonly employs microorganisms to convert biomass to fuel for industrial and transportation applications. Compounds made in biofuel production, however, are toxic to cell membranes and disrupt their integrity, harming the microorganisms and limiting biofuel yield. A key to overcoming this challenge is understanding how fuels interact with microorganisms’ cell membranes, which perform a host of functions, including transport, cell recognition, transduction, and movement. Phospholipids are the cell membrane’s building blocks and provide the critical matrix to support these vital functions. This research sought to make in-vitro membrane phospholipid models of the bacterium Bacillus subtilis (a biofuel producer candidate), subject them to fuel stress and employ fluorescence techniques to understand how fuels affect membrane integrity.
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Independence and interdependence: signal transduction of two chemosensory receptors important for the regulation of gliding motility in Myxococcus xanthusXu, Qian 27 December 2007 (has links)
The Myxococcus xanthus Dif and Frz chemosensory pathways play important roles in the regulation of gliding motility. The Dif system regulates the production of exopolysaccheride (EPS), which is essential for social motility and fruiting body formation. The Frz pathway controls reversal frequency, which is fundamental for directed movement by this surface-gliding bacterium. In addition, both pathways are involved in the chemotactic response towards several phosphatidylethanolamine (PE) species such that the Dif pathway is required for excitation while the Frz pathway is essential for adaptation. In this study we addressed three crucial questions regarding the signal processing of these two chemosensory pathways by focusing on DifA and FrzCD, the MCP homologs from their respective pathways.
First, the receptor protein in the Dif pathway, DifA, lacks a perisplasmic domain, the typical signal-sensing structure. To examine whether DifA shares similar transmembrane signaling mechanism with typical transmembrane sensor proteins (MCPs and sensor kinases), we constructed a chimeric protein that is composed of the N-terminus of NarX (nitrate sensor kinase) and the C-terminus of DifA. This NarX-DifA chimera restores the DifA functionality (EPS production, agglutination, S-motility and development) to a "difA mutant in a nitrate-dependent manner, suggesting DifA shares a similar transmembrane signaling mechanism with typical MCPs and sensor kinases despite its unorthodox structure.
Second, the M. xanthus chemotaxis is still controversial. It has been argued that the taxis-like response in this slowly gliding bacterium could result from physiological effects of certain chemicals. To study motility regulation by the Frz pathway, we constructed two chimeras between the N-terminus of NarX and C-terminus of FrzCD, which is the receptor protein of the Frz pathway. The two chimeras, NazDF and NazDR, are identical except that NazDR contains a G51R mutation in the otherwise wild-type NarX sensory module. This G51R mutation was shown to reverse the signaling output of a NarX-Tar chimera to nitrate. We discovered that nitrate specifically decreased the reversal frequency of NazDF-expressing cells and increased that of NazDR-expressing cells. These results show that directional motility in M. xanthus can be regulated independently of cellular metabolism and physiology. Surprisingly, the NazDR strain failed to adapt to nitrate in temporal assays, as did the wild type to known repellents. Therefore, the lack of temporal adaptation to negative stimuli is an intrinsic property in M. xanthus motility regulation.
Third, the Dif and Frz pathways are both involved in the chemotactic response towards certain PE molecules such that the Dif pathway is required for excitation and while the Frz system is essential for adaptation. In addition, 12:0 PE, known to be sensed by DifA, results in increased FrzCD methylation. These findings suggested that in the regulation of PE response, two pathways communicate with each other to mediate adaptation. Here we provided evidence to indicate that DifA does not undergo methylation during EPS regulation and PE chemotaxis. On the other hand, using mutants expressing the NarX-DifA chimera, it was found that signal transduction through DifA, DifC (CheW-like) and DifE (CheA-like) modulates FrzCD methylation. Surprisingly, the attractant 12:0 PE can modulate FrzCD methylation in two ways distinguishable by the dependency on DifA, DifC and DifE. The DifACE-independent mechanism, which may result from specific sensing of 12:0 PE by FrzCD, increases FrzCD methylation as expected. Unexpectedly, 12:0 PE decreases FrzCD methylation with the DifACE-dependent mechanism. This "opposite" FrzCD methylation by DifACE-dependent signaling was supported by results from NafA-expressing mutants because nitrate, which acts as a repellent, increases FrzCD methylation. Based on these findings, we proposed a model for chemotaxis toward 12:0 PE (and 16:1 PE). In this model, DifA and FrzCD both sense the same signal and activate the pathways of excitation (Dif) and adaptation (Frz) independently. The two pathways communicate with each other via methylation crosstalk between DifACE and FrzCD in such a way that processes of excitation and adaptation can be coordinated. / Ph. D.
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Ostéogénie, intégration et qualité de la nacre d’un bivalve des côtes tunisiennes : Pinctada radiata (Leach, 1814) / Osteogenie, integration and quality of nacre of a tunisian coast bivalve Pinctada Radiata (Leach, 1814)Ben Ammar, Rym 15 December 2014 (has links)
La couche de nacre de la coquille de l'huître perlière Pinctada radiata des côtes tunisiennes est considérée comme un biomatériau ostéogénique prometteur. L’objectif de ce travail intitulé « Ostéogénie, intégration et qualité de la nacre d’un bivalve des côtes tunisiennes : Pinctada radiata (Leach, 1814) » consiste dans un premier temps à valoriser l’espèce P. radiata par sa qualité nutritionnelle par un suivi saisonnier de la composition de sa chair en lipides totaux et en phospholipides particulièrement les PC, PE, PS et PI. Les analyses effectuées ont montré que les lipides de P.radiata sont caractérisés par une richesse en acides gras polyinsaturés (AGPI) de la série n-3 qui dépasse 3 fois celle des AGPI de la série n-6. Ces AGPI de la série n-3 en particulier l’EPA (C20:5n-3) et le DHA (C22:6n-3), sont connus comme étant les AG les plus importants dans l’alimentation humaine puisqu’ils préviennent des maladies cardiovasculaires et des pathologies ostéo-articulaires. Par ailleurs, P. radiata de la région de Maharès présente la meilleure qualité de nacre en Tunisie. Les analyses biochimiques ont montré que cette région, constitue la meilleure localisation de cette espèce qui est loin des zones portuaires et des différentes origines de stress (pêche, exploitation, zone touristique etc…). En plus de cet aspect, la zone de Maharès renferme des pintadines présentant une bonne qualité en termes d’épaisseur de nacre. Nos résultats montrent que la composition, saisonnière, en acide gras des phospholipides et en particulier des glycérophospholipides (PE, PI, PS et PC) de la nacre est riche en acides gras saturés C14 :0, C16 :0 et C18 :0 particulièrement en hiver et dans un moindre degré au printemps. La nacre, substance ostéogénique, a été également caractérisée par un taux élevé de plusieurs AGPI de la série n-3 et n-6, particulièrement (18:3n-3, 18:4n-3, 20:5n-3, 22:5n-3, 22:6n-3 et le 20:4n-6). Pour démontrer les potentialités ostéogéniques des extraits de la nacre, nous avons utilisé un modèle "in vitro" utilisant 4 extraits lipidiques : l’extrait lipidique de la nacre de P.radiata (Ln), l’extrait lipidique de la chair de P.radiata (Lc), l’ESM (Ethanol soluble Matrix) de la nacre de P.radiata (Br) et l’ESM de la nacre de P.margaritifera (Bm). Nous avons comparé, in vitro, le pouvoir ostéogénique des extraits ESM des deux espèces P. radiata et P. margaritifera sur deux types de cellules les préchondrocytes ATDC5 et les préostéoblastes murins MC3T3. Les différents extraits (Ln, Lc, Br et Bm) induisent l’engagement des cellules MC3T3 vers le lignage ostéoblastique par l’activation des promoteurs des gènes spécifiques du tissu osseux, tels que: le collagène de type 1, l’ostéocalcine (OC), l’ostéopontine(OP) et le Runx2. Ces extraits induisent aussi l’engagement des cellules ATDC5 vers la différenciation endochondrale par l’activation des promoteurs des gènes spécifiques du tissu osseux, tels que: le collagène de type 1 alpha-1 (Col1a1), l’Aggrécane et le collagène de type X alpha-1 (ColXA1). De plus, nous remarquons que la fraction organique ou ESMr(Br) en comparaison avec celle de P.margaritifera (Bm) présente également les propriétés stimulantes de la nacre et la stimulation est même beaucoup plus importante. Ces résultats mettent en évidence, dans les modèles expérimentaux mis en oeuvre, l’intérêt des lipides. Ces derniers semblent jouer un rôle important dans cette stimulation. De plus, nous pouvons penser à la possibilité de l’association des molécules de nacre ou de biominéralisation avec les acides gras de la nacre et de la chair dans les défauts osseux à travers les sites actifs de l’os ou du cartilage humain présentant les différentes pathologies ostéarticulaires / The nacre layer of the shell of the pearl oyster Pinctada radiata of tunisian coast is considered a promising osteogenic biomaterial. The objective of this work entitled "Osteogenie, integration and quality of nacre of a tunisian coast bivalve: Pinctada radiata (Leach, 1814)" is a first step to enhance the species P.radiata its nutritional quality by seasonal monitoring of the composition of the flesh of total lipids and phospholipids in particular PC, PE, PS and PI. The analyzes showed that lipids of P.radiata are characterized by rich in polyunsaturated fatty acids (PUFAs) of the n-3 more than 3 times that of PUFAs n-6 series. These PUFAs of the n-3 series particularly EPA (C20: 5n-3) and DHA (C22: 6n-3) are known to be the most important AG in the food as prevent of the cardiovascular disease, and joint/ bone pathologies. Moreover, P. radiata of Mahares region has the best quality of nacre in Tunisia. Biochemical analyzes showed that this region is the best location of this species that is far from the port areas and different sources of stress (fishing, exploitation, tourist area etc ...). In addition to this aspect, the area contains pintadines having good quality in terms of thickness of nacre. Our results show that the seasonal composition of fatty acid of phospholipids in particular glycerophospholipids (PE, PI, PS and PC) nacre is rich in saturated fatty acids C14: 0, C16: 0 and C18: 0 especially in winter and spring in a lesser degree. Nacre, osteogenic substance, was also characterized by a high rate of PUFA of the n-3 and n-6 rate, especially (18: 3n-3, 18: 4n-3, 20: 5n-3, 22 5n-3, 22: 6n-3 and 20: 4n-6). To demonstrate the osteogenic potential of extracts of nacre, we have established an "in vitro" model using 4 lipid extracts: the lipid extract of nacre P.radiata (Ln); the lipid extract of the flesh of P.radiata (Lc), ESM (Ethanol soluble Matrix) of the mother-of P.radiata (Br) and ESM nacre of P. margaritifera (Bm). We compared “in vitro” osteogenic power ESM extracts of both species P. radiata and P. margaritifera on two types of cells the préchondrocytes ATDC5 and the murine preosteoblasts MC3T3. The different extracts (Ln, Lc, Br and Bm) induce engagement MC3T3 osteoblast lineage cells to the activation of the promoters of specific genes of bone tissue, such as collagen type 1, osteocalcin (OC), osteopontin (OP) and Runx2. These extracts also induce the commitment of ATDC5 cells to endochondral differentiation by activating specific genes promoters of bone tissue, such as collagen type 1 alpha 1 (COL1A1), the aggrecan and collagen type alpha 1-X (ColXA1). Moreover, we note that the organic fraction or ESMR (Br) compared with that of P. margaritifera (Bm) also has stimulant properties of nacre and the stimulation is even more important. These results demonstrate, in experimental models used, the interest of lipids. They seem to play an important role in this stimulation. Moreover, we can think about the possibility of the association of molecules or nacre biomineralization with the fatty acids of the nacre and flesh in bone defects through the active sites of bone or cartilage presenting the human osteoarticular different pathologies
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<strong>OH LIPIDS, THE PLACES WE HAVE GONE</strong>De'Shovon M Shenault (16650516) 27 July 2023 (has links)
<p>The development of a novel charge inversion ion/ion reaction in conjunction with a mass spectrometry technique (collisional induced dissociation (CID)) to induce fragmentation of selected ions species in the gas-phase. The utility of this experiment allows identification of varying saturated and unsaturated classes of glycerophospholipids (GPLs) in a biological matrix. In this work, we are able to characterize GPLs species at the subclass, headgroup, fatty acyl sum compositional levels, leaving the location(s) of carbon-carbon single bond (C-C), carbon-carbon double bond (C=C), cyclopropane moiety, branching site and differentiate isomeric species. </p>
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<p>All data were collected on modified a Sciex QTRAP4000 hybrid triple quadrupole/linear ion trap mass spectrometer. Briefly, alternately, pulsed nano-electrospray ionization (nESI) was used for ion generation. Deprotonated lipid anions were generated via negative ion mode nESI, mass selected during transit through Q1, and transferred to q2 for storage. Next, the charge inversion (IIRXN) reagent doubly charged magnesium complex cations, were generated via positive ion mode nESI. To facilitate the ion/ion reaction, magnesium complex dictations and lipid anions were simultaneously stored in q2, resulting in the formation of charge-inverted lipid cations. Ion-trap CID of charge-inverted isomers resulted in distinctive fragmentation, facilitating differentiation of isomeric and localization of unsaturation sites in acyl chain constituents. </p>
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