Aufnahme von Fettsäuren in Spermatozoenlipide von Sus scrofa domestica und physiologische Auswirkungen

Svetlichnyy, Valentin

07 February 2013

Die vorliegende Arbeit beschäftigt sich mit den physiologischen Veränderungen porciner Spermatozoen, die durch einen metabolischen Einbau von Fettsäuren in Spermatozoenlipide hervorgerufen werden. Ziel dieser Arbeit war die Untersuchung der metabolischen Aufnahme von Fettsäuren in die Spermatozoenlipide und die Bewertung des physiologischen Zustandes porciner Spermatozoen mit Hinblick auf die Niedrigtemperaturlagerung. Alle in den porcinen Spermatozoen vorkommenden Lipide wurden mittels GC und MALDI-TOF-MS analysiert. Hauptvertreter der polaren Lipidklassen sind Glycerophospholipide (GPC, GPE). Der Hauptvertreter der neutralen Lipidklassen ist Diacylglycerol (DAG). Die metabolische Aufnahme von Fettsäuren in die Lipide wurde durch die Supplementierung des Flüssigkonservierungsmediums mit [14C]-Octadecadiensäure radiochemisch untersucht. Anhand dieser Experimente wurde gezeigt, dass die Temperatur und die Inkubationsdauer wichtige Faktoren für die metabolische Aufnahme dieser Radiochemikalie in die Spermatozoenlipide sind. Die zugesetzten Fettsäuren werden sowohl in die neutralen (DAG) als auch in die polaren Lipide (diacyl-GPC) der Spermatozoen eingebaut. Nach Supplementierung mit 13C-markierter Octadecadiensäure wurden die Lipide mittels MALDI- und Q-TOF-MS als DAG (18:2/18:2), GPC (16:0/18:2) und GPC (18:2/18:2) charakterisiert. Die gleichen Ergebnisse wurden auch für die in den Spermatozoenlipiden vorkommenden Hexadecen-, Octadecen-, und Octadecatriensäure erhalten. Bei der Untersuchung des physiologischen Zustandes von Spermatozoen wurde gezeigt, dass insbesondere Supplementierungsvarianten mit endogen vorkommenden Fettsäuren zu einer besseren Spermatozoenvitalität und Motilität bei Niedrigtemperaturlagerung führten. Gleichzeitig wurde eine Verminderung des Auftretens von akrosomalen Schäden festgestellt. Damit stellt eine Supplementierung der Spermatozoen mit ausgewählten Fettsäuren eine effektive Maßnahme zur Lagerung von Spermatozoen bei 4 bis 6°C dar. / This study examines the metabolic incorporation of selected fatty acids into the lipids of porcine spermatozoa and evaluates the physiological state of spermatozoa subsequent to low temperature storage supplementation with selected free fatty acids. The aim was to understand the role of fatty acids in relation to the (cryo-)preservation of spermatozoa and successful reproduction in more detail. All lipids present in porcine spermatozoa were analysed using gas chromatography (GC) and mass spectrometry (MALDI-TOF-MS). The main representatives of the polar lipid classes are glycerophospholipids (in particular GPC and GPE). The main representatives of the neutral lipid classes are diacylglycerols (DAG). Metabolic incorporation of fatty acids into lipids was radiochemically monitored using [14C]-octadecadienoic acid in the supplied spermatozoa-preservation medium. Temperature and incubation time were shown to be particularly important determinants. The added fatty acids were incorporated into both the spermatozoas’ neutral (DAG) and polar lipids (diacyl-GPC). The affected lipids were characterised by means of MALDI- and Q-TOF-MS subsequent to the supplementation of uniformly 13C-labelled octadecadienoic acid. DAG (18:2/18:2), GPC (16:0/18:2) and GPC (18:2/18:2) could be identified and a de-novo biosynthesis of DAG (18:2/18:2) could be proven. The same results were obtained when spermatozoa were supplemented with hexadecenoic, octadecenoic and octadecatrienoic acids. Finally, it was shown that the physiological state of the spermatozoa, especially those supplemented with endogeneously present fatty acids, led to an enhanced vitality and motility in spermatozoa subsequent to low temperature storage. It was also observed that acrosomal damage was reduced and that hexadecenoic acid significantly stabilised all the vitality parameters. In conclusion, supplementing spermatozoa with selected fatty acids is an effective solution for the storage of spermatozoa at 4 to 6°C.

Glycerophospholipid

Diacylglycerol

porcine Spermatozoen

Fettsäure

glycerophospholipid

diacylglycerol

boar spermatozoa

fatty acid

570 Biowissenschaften, Biologie

32 Biologie

WX 5500

ddc:570

Incorporation of the Paternò–Büchi reaction into mass spectrometry-based systems for lipid structural characterization

Elissia T Franklin (8087996)

10 December 2019

<p>Lipids are important cellular biomolecules that perform essential functional and biological roles. For instance, lipids in the cell are the compartmentalizer for the cytoplasm and an energy storage unit. The knowledge surrounding lipids is abundant, yet there is still so much to uncover. There are many categories of lipids and within each category the structural composition is extremely diverse. In turn, the dramatic structural complexity of lipids demands analytical methods capable of providing in-depth structural characterization of individual molecular structures. However, lipid structural elucidation has remained challenging, namely due to the presence of isomeric and isobaric species with a complex mixture. In particular, isomeric/isobaric lipid structures arise from variations in class, headgroup, fatty acyl chain, <i>sn</i>-position, and/or carbon-carbon double bond (C=C) position(s). Recently, recent research suggests C=C composition impacts lipid physical properties, metabolic fate, and intermolecular interactions. Thus, analytical strategies capable of localizing sites of unsaturation are of interest in the lipidomics community.</p> <p>Mass spectrometry (MS) is a leading tool for lipid analysis. Electrospray ionization (ESI), a soft ionization method, is the most commonly used method for lipid ionization as a means of taking the ions from liquid-phase to gas-phase without extensive decomposition of the species. Utilizing ESI-MS, lipids can be identified at a sum compositional level via accurate mass measurements. . With tandem mass spectrometers, lipid ions can be further probed, utilizing tandem-MS (MS/MS) to generate structurally informative product ion spectra that facilitate the assignment of lipid molecular structure. More so, gas-phase ion/ion reactions represent a unique MS-based technique that has improved the analysis of lipids structures. Gas-phase ion/ion reactions allow for lipid species to be charge inverted from one polarity to the opposite polarity. This reaction enables lipids to be ionized in a polarity that is optimal for class identification and further investigated in the opposite polarity where more structural information is obtained. All the information provided is captured without the requirement of multiple solution conditions which is necessary when analyzing in both polarities. In the case of charge inverted lipids from positive ion mode to negative ion mode, fatty acyl composition can be obtained; however, C=C information is lacking.</p> <p>MS can also be paired with other analytically technologies to assist with lipid analysis. One of those technologies is liquid chromatography (LC), which allows for the separation of lipids based on different characteristic depending on the column type being used. Reverse-phase LC (RPLC) allows for the separation of lipid molecular species based on structural composition. RPLC-MS/MS benefits from the ability to separate lipids and determine their fatty acyl chain composition but it is difficult to specify C=C location with the use of a synthetic standard that is identical to each molecular species being analyzed.</p> <p>Commonality between the gas-phase ion/ion reactions for charge inversion of lipids and RPLC-MS/MS approaches is the inability to provide C=C coverage. In-solution and unique ion activation techniques have been developed for seeking such information. The Paternò–Büchi reaction is a UV-initiated [2 + 2]-cycloaddition of an excited carbonyl containing compound onto an olefin group. This reaction can be initiated onto the alkene group within an unsaturated lipid aliphatic chain to form an oxetane ring modification. There are two product ions that can be formed upon each unsaturation site due to a lack of regioselectivity the reagent can attach at either side of the C=C. The modified lipids can be taken into gas-phase and collisionally activated via low-energy collision induced dissociation, generating product ions indictive of C=C position(s). The work herein shows the incorporation of the PB reaction into the gas-phases ion/ion reaction and RPLC-MS/MS apparatuses for C=C localization. The methods have been applied to the lipid extracts of bovine liver and human plasma for confident molecule species determination.</p>

Paternò–Büchi

Mass spectrometry

Charge Inversion

Ion/ion reactions

Gas-phase

Trimethylation

Triacylglycerol

Glycerophospholipid

The interaction of obesity and age and their effect on adipose tissue metabolism in the mouse

Liu, Ke-di

January 2019

Numerous studies have investigated how bulk lipid metabolism is influenced in obesity and in particular how the composition of triglycerides found in the cytosol change with increased adipocyte expansion. However, in part reflecting the analytical challenge the composition of cell membranes, and in particular glycerophospholipids, an important membrane component, have been seldom investigated. Cell membrane components contribute to a variety of cellular processes including maintaining organelle functionality, providing an optimized environment for numerous proteins and providing important pools for metabolites, such as choline for one-carbon metabolism and S-adenosylmethionine for DNA methylation. Here, I have conducted a comprehensive lipidomic and transcriptomic study of white adipose tissue in mice that become obese either through genetic modification (ob/ob genotype), diet (high-fat diet) or a combination of the two across the life course. Specifically, I demonstrated that the changes in triglyceride metabolism that dominate the overall lipid composition of white adipose tissue were distinct from the compositional changes of glycerophospholipids. These latter lipids became more unsaturated to maintain the fluidity and normal function of the membrane in the initiation of obesity but then turned saturated after long-term administration of HFD and aging. This suggests that while triglycerides within the adipose tissue may be a relatively inert store of lipids, the compositional changes occur in cell membranes with more far-reaching functional consequences in both obesity and aging. The two-phase change of phospholipids can be correlated well with transcriptional and one-carbon metabolic changes within the adipocytes. The transcriptomic study demonstrated that the lipid metabolic pathways regulated by the peroxisome, AMPK, insulin and PPARγ signaling were activated in the initiation of obesity but inhibited in the adipose tissue of old ob/ob mice along with up-regulated inflammation pathways. The brown and white adipose tissue of PPARα-knock-out mice were also studied by lipidomic tools to get a deeper understanding of the effect of the peroxisome and PPAR system on adipose tissue and lipid metabolism during obesity. Most of the lipids were increased and became more saturated and shorter in adipose tissues of PPARα null mice, which is in good accordance with the results of the former animal study. In conclusion, my work using different rodent models and multi-omics techniques demonstrated a protective metabolic mechanism activated in the initiation but impaired at the end of the processes of obesity and aging, which could be an explanation of the similarity of obesity and aging in terms of high incidence of the metabolic syndrome and related diseases.

Characterization of Molecular Glycerophospholipids by Quadrupole Time-of-Flight Mass Spectrometry

Ekroos, Kim

10 November 2003

The physical properties of glycerophospholipids (GPLs) are not only determined by the head group (HG), but also by their fatty acid (FA) chains, which affect their distribution and function within membranes in the cell. Understanding the microheterogenity of lipid membranes on a molecular level requires qualitative and quantitative characterization of individual lipids and identification of their FA moieties. The aim of my study was to introduce the new technology of multiple precursor ion scanning (MPIS) on a QSTAR Pulsar time-of-flight mass spectrometer (QqTOF) to analyze lipids. Detailed information on fatty acid composition of individual GPL molecules could be obtained in parallel with conventional profiling of lipid classes, and this could be done by direct analysis of total lipid extracts. This method was termed Fatty Acid Scanning (FAS) and Head Group Scanning HGS, respectively. In this way the molecular GPL composition of total lipid extracts could be charted in a single analysis accurately and rapidly at a low picomole concentration level. Furthermore, combining FAS and HGS together with ion trap MS3 analysis allowed complete charting of the molecular composition of PCs, including quantification of their positional isomers, thus providing a detailed and comprehensive characterization of molecular composition of the pool of PCs. Development of the Lipid Profiler software allowed full automation and rapid processing of complex data, including identification and quantification of molecular GPLs. This approach was evaluated by preliminary applications. First, the molecular composition of PCs of total lipid extracts of MDCK cells and of human red blood cells (RBC) could accurately be charted. Significant presence of positional isomers was observed increasing the total number of individual PC species close to one hundred. Secondly, the molecular PC and SM species distribution in detergent resistant membranes (DRMs) prepared by Triton X-100 DRMs were analyzed and were found to be enriched in distinct GPLs. The distribution in PCs and SMs of Triton X-100 DRMs of RBC were compared with those of the DRMs of MDCK cells. Finally, combining the use of a 96 well plate and a robotic system demonstrated that these analyses can be automated and analyzed with high throughput. This system we termed Shotgun Lipidomics. Taken together, this mass spectrometric methodology provides rapid and detailed insight into the distribution of the molecular GPLs of membranes and membrane sub-fractions.

Glycerophospholipide

Lipidenrafts

Massenspektrometrie

characterization

detergent resistant membranes

fatty acid scanning

glycerophospholipid

head group scanning

lipid rafts

mass spectrometry

quadrupole time-of-flight

shotgun lipidomics

ddc:570

rvk:WD 5400

rvk:WC 4150

Glycerophospholipide

Lipidmembran

Quadrupolmassenspektrometrie

Characterization of Molecular Glycerophospholipids by Quadrupole Time-of-Flight Mass Spectrometry

Ekroos, Kim

12 December 2003

The physical properties of glycerophospholipids (GPLs) are not only determined by the head group (HG), but also by their fatty acid (FA) chains, which affect their distribution and function within membranes in the cell. Understanding the microheterogenity of lipid membranes on a molecular level requires qualitative and quantitative characterization of individual lipids and identification of their FA moieties. The aim of my study was to introduce the new technology of multiple precursor ion scanning (MPIS) on a QSTAR Pulsar time-of-flight mass spectrometer (QqTOF) to analyze lipids. Detailed information on fatty acid composition of individual GPL molecules could be obtained in parallel with conventional profiling of lipid classes, and this could be done by direct analysis of total lipid extracts. This method was termed Fatty Acid Scanning (FAS) and Head Group Scanning HGS, respectively. In this way the molecular GPL composition of total lipid extracts could be charted in a single analysis accurately and rapidly at a low picomole concentration level. Furthermore, combining FAS and HGS together with ion trap MS3 analysis allowed complete charting of the molecular composition of PCs, including quantification of their positional isomers, thus providing a detailed and comprehensive characterization of molecular composition of the pool of PCs. Development of the Lipid Profiler software allowed full automation and rapid processing of complex data, including identification and quantification of molecular GPLs. This approach was evaluated by preliminary applications. First, the molecular composition of PCs of total lipid extracts of MDCK cells and of human red blood cells (RBC) could accurately be charted. Significant presence of positional isomers was observed increasing the total number of individual PC species close to one hundred. Secondly, the molecular PC and SM species distribution in detergent resistant membranes (DRMs) prepared by Triton X-100 DRMs were analyzed and were found to be enriched in distinct GPLs. The distribution in PCs and SMs of Triton X-100 DRMs of RBC were compared with those of the DRMs of MDCK cells. Finally, combining the use of a 96 well plate and a robotic system demonstrated that these analyses can be automated and analyzed with high throughput. This system we termed Shotgun Lipidomics. Taken together, this mass spectrometric methodology provides rapid and detailed insight into the distribution of the molecular GPLs of membranes and membrane sub-fractions.

info:eu-repo/classification/ddc/570

ddc:570