Effects of methylation and hydroxylation of sphingomyelins on their biophysical properties and interactions with cholesterol

Sfingomyeliner är viktiga sphingolipidmolekyler som finns i cellmembranets exoplastiska monolager. Sfingomyeliner är sällsynta i växter och mikroorganismer. Den enigmatiska sfingomelinmolekylen som Thudicum isolerade från hjärnvävnad i slutet på 1800-talet fick sitt namn på basen av det grekiska ordet”sfinx”. Sfingomyeliner återfinns speciallt rikligt i myelinskidorna i nervvävnad, var de sfingomyelinrika membranen bildar ett isolerande lager runt nervcellernas axoner. De polära sfingomyelinerna är viktiga beståndsdelar av ägg, mjölk och kött, och betraktas som viktiga näringsämnen speciellt för spädbarn. Det finns ett flertal sjukdomar uppstår på grund av defekter i sfingomyelinmetabolismen., t.ex. Niemann-Picks sjukdom, som är en obotlig ärftlig metabolisk sjukdom. Nyligen har det rapporterats att sfingomyelin tillsammans med kolesterol och specifika proteiner bildar funtionella domäner, s.k. membranflottar, i cellers membran. Membranflottar anses delta i många viktiga biologiska processer som t.ex. signalöverföring, lipid- och proteinsortering, apoptos, celladhesion, cellmigration och synapsers signalöverföring. Därför är det ytterst viktigt att förstå samverkan mellan sfingomyelin och kolesterol och hur denna samverkan påverkar bildandet membranflottar. I avhandlingen presenteras data från våra studier av sfingomyelin samverkan med kolesterol. För avhandlingen syntetiserade vi unika sfingomyelin molekyler genom att införa metyl- och hydroxylgrupper i olika positioner i sphingomyelinmolekylerna, med målet att lära oss mera om sphingomyelinets membranegenskaper och samverkan med kolesterol. Alla sfingomyelin molekyler som användes i avhandlingsarbetet är biologiskt relevanta. I studierna fann vi att hydroxyl- och amidgrupperna i sfingomyelin är viktiga i vätebindningar mellan sfingomyelinmolekyler samt mellan sfingomyelin och kolesterol. Vi upptäckte ytterligare att substition av metylgrupper i acylkedjan eller i interfasregionen hos sfingomyelinmolekyler signifikant destabiliserade sphingomyelin bilagret och försvagade/upphävde molekylernas samverkan med kolesterol. Hur sfingomyelinbilagrens stabilitet och sfingomyelinen-koleterol samverkan påverkades av hydroxylgrupper var beroende av hydrohygruppens position. Förekomst av en extra hydroxylgrupp i sfingomyelionmolekylens sfingoidbasen ökade stabilitetnen hos sfingomyelinbilagren samt stabiliserade sfingomyelinets samverkan med kolesterol.

Membrane Lipid Profile Monitored By Mass Spectrometry Detected Differences Between Fresh And Vitrified In Vitro-produced Bovine Embryos.

Summary This study aimed to evaluate the impact of vitrification on membrane lipid profile obtained by mass spectrometry (MS) of in vitro-produced bovine embryos. Matrix-assisted laser desorption ionization-mass spectrometry (MALDI-MS) has been used to obtain individual embryo membrane lipid profiles. Due to conditions of analysis, mainly membrane lipids, most favorably phosphatidylcholines (PCs) and sphingomyelins (SMs) have been detected. The following ions described by their mass-to-charge ratio (m/z) and respective attribution presented increased relative abundance (1.2-20×) in the vitrified group: 703.5 [SM (16:0) + H]+; 722.5 [PC (40:3) + Na]+; 758.5 [PC (34:2) + H]+; 762.5 [PC (34:0) + H]+; 790.5 [PC (36:0) + H]+ and 810.5 [PC (38:4) + H]+ and/or [PC (36:1) + Na]+. The ion with a m/z 744.5 [PCp (34:1) and/or PCe (34:2)] was 3.4-fold more abundant in the fresh group. Interestingly, ions with m/z 722.5 or 744.5 indicate the presence of lipid species, which are more resistant to enzymatic degradation as they contain fatty acyl residues linked through ether type bonds (alkyl ether or plasmalogens, indicated by the lowercase 'e' and 'p', respectively) to the glycerol structure. The results indicate that cryopreservation impacts the membrane lipid profile, and that these alterations can be properly monitored by MALDI-MS. Membrane lipids can therefore be evaluated by MALDI-MS to monitor the effect of cryopreservation on membrane lipids, and to investigate changes in lipid profile that may reflect the metabolic response to the cryopreservation stress or changes in the environmental conditions.

Single embryo and oocyte lipid fingerprinting by mass spectrometry

Methods used for lipid analysis in embryos and oocytes usually involve selective lipid extraction from a pool of many samples followed by chemical manipulation, separation and characterization of individual components by chromatographic techniques. Herein we report direct analysis by matrix-assisted laser desorption/ionization mass spectrometry (MALDI-MS) of single and intact embryos or oocytes from various species. Biological samples were simply moisturized with the matrix solution and characteristic lipid ( represented by phosphatidylcholines, sphingomyelins and triacylglycerols) profiles were obtained via MALDI-MS. As representative examples, human, bovine, sheep and fish oocytes, as well as bovine and insect embryos were analyzed. MALDI-MS is shown to be capable of providing characteristic lipid profiles of gametes and embryos and also to respond to modifications due to developmental stages and in vitro culture conditions of bovine embryos. Investigation in developmental biology of the biological roles of structural and reserve lipids in embryos and oocytes should therefore benefit from these rapid MALDI-MS profiles from single and intact species.-Ferreira, C. R., S. A. Saraiva, R. R. Catharino, J. S. Garcia, F. C. Gozzo, G. B. Sanvido, L. F. A. Santos, E. G. Lo Turco, J. H. F. Pontes, A. C. Basso, R. P. Bertolla, R. Sartori, M. M. Guardieiro, F. Perecin, F. V. Meirelles, J. R. Sangalli, and M. N. Eberlin. Single embryo and oocyte lipid fingerprinting by mass spectrometry. J. Lipid Res. 2010. 51: 1218-1227.

Chemical Composition of Lipids Present in Cat and Dog Oocyte by Matrix-Assisted Desorption Ionization Mass Spectrometry (MALDI- MS)

Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq)

Phosphatidylcholine and Sphingomyelin Profiles Vary in Bos taurus indicus and Bos taurus taurus In Vitro- and In Vivo-Produced Blastocysts

Fundação de Amparo à Pesquisa do Estado de São Paulo (FAPESP)

Optimal single-embryo mass spectrometry fingerprinting

In pre-implantation embryos, lipids play key roles in determining viability, cryopreservation and implantation properties, but often their analysis is analytically challenging because of the few picograms of analytes present in each of them. Matrix-assisted laser desorption/ionization mass spectrometry (MALDI-MS) allows obtaining individual phospholipid profiles of these microscopic organisms. This technique is sensitive enough to enable analysis of individual intact embryos and monitoring the changes in membrane lipid composition in the early stages of development serving as screening method for studies of biology and biotechnologies of reproduction. This article introduces an improved, more comprehensive MALDI-MS lipid fingerprinting approach that considerably increases the lipid information obtained from a single embryo. Using bovine embryos as a biological model, we have also tested optimal sample storage and handling conditions before the MALDI-MS analysis. Improved information at the molecular level is provided by the use of a binary matrix that enables phosphatidylcholines, sphingomyelins, phosphatidylserines, phosphatidylinositols and phosphoethanolamines to be detected via MALDI(±)-MS in both the positive and negative ion modes. An optimal MALDI-MS protocol for lipidomic monitoring of a single intact embryo is therefore reported with potential applications in human and animal reproduction, cell development and stem cell research. Copyright © 2013 John Wiley & Sons, Ltd. Copyright © 2013 John Wiley & Sons, Ltd.

Membrane lipid profile monitored by mass spectrometry detected differences between fresh and vitrified in vitro-produced bovine embryos

Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq)