Lipidomics as a Principal Tool for Advancing Biomedical Research

Sin Man Lam; Guanghou Shui

doi:10.1016/j.jgg.2013.06.007

Volume 40 Issue 8

Aug. 2013

Turn off MathJax

Article Contents

Article Navigation > Journal of Genetics and Genomics > 2013 > 40(8): 375-390

PDF( 1143 KB)

Lipidomics as a Principal Tool for Advancing Biomedical Research

doi: 10.1016/j.jgg.2013.06.007

State Key Laboratory of Molecular Developmental Biology, Institute of Genetics and Developmental Biology, Chinese Academy of Sciences, Beijing 100101, China

More Information

Corresponding author: E-mail address: ghshui@genetics.ac.cn (Guanghou Shui)
Received Date: 2013-04-04
Accepted Date: 2013-06-19
Rev Recd Date: 2013-06-04

Available Online: 2013-07-12

Publish Date: 2013-08-20

Abstract

Abstract

Lipidomics, which targets at the construction of a comprehensive map of lipidome comprising the entire lipid pool within a cell or tissue, is currently emerging as an independent discipline at the interface of lipid biology, technology and medicine. The diversity and complexity of the biological lipidomes call for technical innovation and improvement to meet the needs of various biomedical studies. The recent wave of expansion in the field of lipidomic research is mainly attributed to advances in analytical technologies, in particular, the development of new mass spectrometric and chromatographic tools for the characterization and quantification of the wide array of diverse lipid species in the cellular lipidome. Here, we review some of the key technical advances in lipidome analysis and put forth the applications of lipidomics in addressing the biological roles of lipids in numerous disease models including the metabolic syndrome, neurodegenerative diseases and infectious diseases, as well as the increasing urgency to construct the lipidome inventory for various mammalian/organism models useful for biomedical research.
- Lipidomics,
- Mass spectrometry,
- Metabolic syndrome,
- Neurodegenerative diseases,
- Infectious diseases

FullText(HTML)

References(132)

References

[1]	Aerts, J.M., Ottenhoff, R., Powlson, A.S. et al. Pharmacological inhibition of glucosylceramide synthase enhances insulin sensitivity Diabetes, 56 (2007),pp. 1341-1349
[2]	Agarwal, A.K., Arioglu, E., De Almeida, S. et al. Nat. Genet., 31 (2002),pp. 21-23
[3]	Agarwal, A.K., Garg, A. Genetic disorders of adipose tissue development, differentiation, and death Annu. Rev. Genomics Hum. Genet., 7 (2006),pp. 175-199
[4]	Aloia, R.C., Tian, H., Jensen, F.C. Lipid composition and fluidity of the human immunodeficiency virus envelope and host cell plasma membranes Proc. Natl. Acad. Sci. USA, 90 (1993),pp. 5181-5185
[5]	Ashrafi, K., Chang, F.Y., Watts, J.L. et al. Nature, 421 (2003),pp. 268-272
[6]	Athenstaedt, K., Daum, G. J. Bacteriol., 179 (1997),pp. 7611-7616
[7]	Bankaitis, V.A., Aitken, J.R., Cleves, A.E. et al. An essential role for a phospholipid transfer protein in yeast Golgi function Nature, 347 (1990),pp. 561-562
[8]	Barceló-Coblijn, G., Golovko, M.Y., Weinhofer, I. et al. Brain neutral lipids mass is increased in alpha-synuclein gene-ablated mice J. Neurochem., 101 (2007),pp. 132-141
[9]	Bar-On, P., Crews, L., Koob, A.O. et al. J. Neurochem., 105 (2008),pp. 1656-1667
[10]	Barry, C.E., Lee, R.E., Mdluli, K. et al. Mycolic acids: structure, biosynthesis and physiological functions Prog. Lipid Res., 37 (1998),pp. 143-179
[11]	Bauer, R., Voelzmann, A., Breiden, B. et al. EMBO J., 28 (2009),pp. 3706-3716
[12]	Benghezal, M., Roubaty, C., Veepuri, V. et al. J. Biol. Chem., 282 (2007),pp. 30845-30855
[13]	Berman, D.E., Dall'Armi, C., Voronov, S.V. et al. Oligomeric amyloid-beta peptide disrupts phosphatidylinositol-4,5-bisphosphate metabolism Nat. Neurosci., 11 (2008),pp. 547-554
[14]	Bijl, N., Sokolović, M., Vrins, C. et al. Modulation of glycosphingolipid metabolism significantly improves hepatic insulin sensitivity and reverses hepatic steatosis in mice Hepatology, 50 (2009),pp. 1431-1441
[15]	Bonham, L., Leung, D.W., White, T. et al. Lysophosphatidic acid acyltransferase-beta: a novel target for induction of tumour cell apoptosis Expert Opin. Ther. Targets, 7 (2003),pp. 643-661
[16]	Bosco, D.A., Fowler, D.M., Zhang, Q. et al. Elevated levels of oxidized cholesterol metabolites in Lewy body disease brains accelerate alpha-synuclein fibrilization Nat. Chem. Biol., 2 (2006),pp. 249-253
[17]	Brooks, K.K., Liang, B., Watts, J.L. PloS ONE, 4 (2009),p. e7545
[18]	Brügger, B., Erben, G., Sandhoff, R. et al. Quantitative analysis of biological membrane lipids at the low picomole level by nano-electrospray ionization tandem mass spectrometry Proc. Natl. Acad. Sci. USA, 94 (1997),pp. 2339-2344
[19]	Brügger, B., Glass, B., Haberkant, P. et al. The HIV lipidome: a raft with an unusual composition Proc. Natl. Acad. Sci. USA, 103 (2006),pp. 2641-2646
[20]	Carvalho, M., Schwudke, D., Sampaio, J.L. et al. Survival strategies of a sterol auxotroph Development, 137 (2010),pp. 3675-3685
[21]	Chan, C., Qi, X., Li, M.W. et al. Recent developments of genomic research in soybean J. Genet. Genomics, 39 (2012),pp. 317-324
[22]	Chan, R.B., Oliveira, T.G., Cortes, E.P. et al. Comparative lipidomic analysis of mouse and human brain with Alzheimer disease J. Biol. Chem., 287 (2012),pp. 2678-2688
[23]	Chan, R., Uchil, P.D., Jin, J. et al. Retroviruses human immunodeficiency virus and murine leukemia virus are enriched in phosphoinositides J. Virol., 82 (2008),pp. 11228-11238
[24]	Chavez, J.A., Knotts, T.A., Wang, L.P. et al. A role for ceramide, but not diacylglycerol, in the antagonism of insulin signal transduction by saturated fatty acids J. Biol. Chem., 278 (2003),pp. 10297-10303
[25]	Choo, H.J., Kim, J.H., Kwon, O.B. et al. Mitochondria are impaired in the adipocytes of type 2 diabetic mice Diabetologia, 49 (2006),pp. 784-791
[26]	Corbett, E.L., Watt, C.J., Walker, N. et al. The growing burden of tuberculosis: global trends and interactions with the HIV epidemic Arch. Intern. Med., 163 (2003),pp. 1009-1021
[27]	Cortés, V.A., Curtis, D.E., Sukumaran, S. et al. Molecular mechanisms of hepatic steatosis and insulin resistance in the AGPAT2-deficient mouse model of congenital generalized lipodystrophy Cell Metab., 9 (2009),pp. 165-176
[28]	Davignon, J., Gregg, R.E., Sing, C.F. Apolipoprotein E polymorphism and atherosclerosis Arteriosclerosis, 8 (1988),pp. 1-21
[29]	Deb, C., Daniel, J., Sirakova, T.D. et al. J. Biol. Chem., 281 (2006),pp. 3866-3875
[30]	Dehwah, M.A.S., Xu, A., Huang, Q. MicroRNAs and type 2 diabetes/obesity J. Genet. Genomics, 39 (2012),pp. 11-18
[31]	Dexter, D.T., Holley, A.E., Flitter, W.D. et al. Increased levels of lipid hydroperoxides in the parkinsonian substantia nigra: an HPLC and ESR study Mov. Disord., 9 (1994),pp. 92-97
[32]	Diefenbach, C.S.M., Soslow, R.A., Iasonos, A. et al. Lysophosphatidic acid acyltransferase-beta (LPAAT-beta) is highly expressed in advanced ovarian cancer and is associated with aggressive histology and poor survival Cancer, 107 (2006),pp. 1511-1519
[33]	Dircks, L., Sul, H.S. Prog. Lipid Res., 38 (1999),pp. 461-479
[34]	Ehrt, S., Schnappinger, D. Nat. Med., 13 (2007),pp. 284-285
[35]	Ejsing, C.S., Sampaio, J.L., Surendranath, V. et al. Global analysis of the yeast lipidome by quantitative shotgun mass spectrometry Proc. Natl. Acad. Sci. USA, 106 (2009),pp. 2136-2141
[36]	Ekroos, K., Chernushevich, I.V., Simons, K. et al. Quantitative profiling of phospholipids by multiple precursor ion scanning on a hybrid quadrupole time-of-flight mass spectrometer Anal. Chem., 74 (2002),pp. 941-949
[37]	Elle, I.C., Olsen, L.C.B., Pultz, D. et al. FEBS Lett., 584 (2010),pp. 2183-2193
[38]	Exil, V.J., Silva Avila, D., Benedetto, A. et al. PloS ONE, 5 (2010),p. e14228
[39]	Fahy, E., Subramaniam, S., Brown, H.A. et al. A comprehensive classification system for lipids J. Lipid Res., 46 (2005),pp. 839-861
[40]	Fahy, E., Subramaniam, S., Murphy, R.C. et al. Update of the LIPID MAPS comprehensive classification system for lipids J. Lipid Res., 50 (2009),pp. S9-S14
[41]	Fan, N., Lai, L. Genetically modified pig models for human diseases J. Genet. Genomics, 40 (2013),pp. 67-73
[42]	Fei, W., Shui, G., Gaeta, B. et al. Fld1p, a functional homologue of human seipin, regulates the size of lipid droplets in yeast J. Cell Biol., 180 (2008),pp. 473-482
[43]	Fitzgerald, M., Murphy, R.C. Electrospray mass spectrometry of human hair wax esters J. Lipid Res., 48 (2007),pp. 1231-1246
[44]	Fletcher, M.J. A colorimetric method for estimating serum triglycerides Clin. Chim. Acta, 22 (1968),pp. 393-397
[45]	Gai, W.P., Yuan, H.X., Li, X.Q. et al. Exp. Neurol., 166 (2000),pp. 324-333
[46]	Guan, X.L., Cestra, G., Shui, G. et al. Dev. Cell, 24 (2013),pp. 98-111
[47]	Guan, X.L., He, X., Ong, W.Y. et al. Non-targeted profiling of lipids during kainate-induced neuronal injury FASEB J., 20 (2006),pp. 1152-1161
[48]	Guan, X.L., Souza, C.M., Pichler, H. et al. Functional interactions between sphingolipids and sterols in biological membranes regulating cell physiology Mol. Biol. Cell, 20 (2009),pp. 2083-2095
[49]	Guan, X.L., Wenk, M.R. Yeast, 23 (2006),pp. 465-477
[50]	Halliday, G.M., Ophof, A., Broe, M. et al. Alpha-synuclein redistributes to neuromelanin lipid in the substantia nigra early in Parkinson's disease Brain, 128 (2005),pp. 2654-2664
[51]	Han, X.L., Gross, R.W. Plasmenylcholine and phosphatidylcholine membrane bilayers possess distinct conformational motifs Biochemistry, 29 (1990),pp. 4992-4996
[52]	Han, X.L., Gross, R.W. Alterations in membrane dynamics elicited by amphiphilic compounds are augmented in plasmenylcholine bilayers Biochim. Biophys. Acta, 1069 (1991),pp. 37-45
[53]	Han, X., Gross, R.W. Quantitative analysis and molecular species fingerprinting of triacylglyceride molecular species directly from lipid extracts of biological samples by electrospray ionization tandem mass spectrometry Anal. Biochem., 295 (2001),pp. 88-100
[54]	Han, X., Gross, R.W. Global analyses of cellular lipidomes directly from crude extracts of biological samples by ESI mass spectrometry: a bridge to lipidomics J. Lipid Res., 44 (2003),pp. 1071-1079
[55]	Hartmann, T., Kuchenbecker, J., Grimm, M.O.W. Alzheimer's disease: the lipid connection J. Neurochem., 103 (2007),pp. 159-170
[56]	Hermansson, M., Uphoff, A., Käkelä, R. et al. Automated quantitative analysis of complex lipidomes by liquid chromatography/mass spectrometry Anal. Chem., 77 (2005),pp. 2166-2175
[57]	Hishikawa, D., Shindou, H., Kobayashi, S. et al. Discovery of a lysophospholipid acyltransferase family essential for membrane asymmetry and diversity Proc. Natl. Acad. Sci. USA, 105 (2008),pp. 2830-2835
[58]	Holland, W.L., Brozinick, J.T., Wang, L.P. et al. Inhibition of ceramide synthesis ameliorates glucocorticoid-, saturated-fat-, and obesity-induced insulin resistance Cell Metab., 5 (2007),pp. 167-179
[59]	Hsu, F.F., Turk, J. Characterization of phosphatidylinositol, phosphatidylinositol-4-phosphate, and phosphatidylinositol-4,5-bisphosphate by electrospray ionization tandem mass spectrometry: a mechanistic study J. Am. Soc. Mass Spectrom., 11 (2000),pp. 986-999
[60]	Hsu, F.F., Turk, J. Electrospray ionization/tandem quadrupole mass spectrometric studies on phosphatidylcholines: the fragmentation processes J. Am. Soc. Mass Spectrom., 14 (2003),pp. 352-363
[61]	Huang, P., Zhu, Z., Lin, S. et al. Reverse genetic approaches in zebrafish J. Genet. Genomics, 39 (2012),pp. 421-433
[62]	Inokuchi, J.I. Membrane microdomains and insulin resistance FEBS Lett., 584 (2010),pp. 1864-1871
[63]	Jain, S., Stanford, N., Bhagwat, N. et al. J. Biol. Chem., 282 (2007),pp. 30562-30569
[64]	Kerwin, J.L., Tuininga, A.R., Ericsson, L.H. Identification of molecular species of glycerophospholipids and sphingomyelin using electrospray mass spectrometry J. Lipid Res., 35 (1994),pp. 1102-1114
[65]	Krumova, S.B., Laptenok, S.P., Kovács, L. et al. Digalactosyl-diacylglycerol-deficiency lowers the thermal stability of thylakoid membranes Photosyn. Res., 105 (2010),pp. 229-242
[66]	Kutik, S., Rissler, M., Guan, X.L. et al. The translocator maintenance protein Tam41 is required for mitochondrial cardiolipin biosynthesis J. Cell Biol., 183 (2008),pp. 1213-1221
[67]	Lee, L.H.W., Shui, G., Farooqui, A.A. et al. Lipidomic analyses of the mouse brain after antidepressant treatment: evidence for endogenous release of long-chain fatty acids? Int. J. Neuropsychopharmacol., 12 (2009),pp. 953-964
[68]	Lehmann, W.D., Koester, M., Erben, G. et al. Characterization and quantification of rat bile phosphatidylcholine by electrospray-tandem mass spectrometry Anal. Biochem., 246 (1997),pp. 102-110
[69]	Li, J., Romestaing, C., Han, X. et al. Cardiolipin remodeling by ALCAT1 links oxidative stress and mitochondrial dysfunction to obesity Cell Metab., 12 (2010),pp. 154-165
[70]	Li, S.F., Song, L.Y., Yin, W.B. et al. J. Genet. Genomics, 39 (2012),pp. 47-59
[71]	Lim, W.L.F., Lam, S.M., Shui, G. et al. Effects of high-fat, high- cholesterol diet on brain lipid profiles in apolipoprotein E ɛ3 and ɛ4 knock-in mice Neurobiol. Aging (2013)
[72]	Low, C.P., Shui, G., Liew, L.P. et al. Caspase-dependent and -independent lipotoxic cell-death pathways in fission yeast J. Cell Sci., 121 (2008),pp. 2671-2684
[73]	Low, K.L., Rao, P.S.S., Shui, G. et al. J. Bacteriol., 191 (2009),pp. 5037-5043
[74]	Low, K.L., Shui, G., Natter, K. et al. J. Biol. Chem., 285 (2010),pp. 21662-21670
[75]	Lwin, A., Orvisky, E., Goker-Alpan, O. et al. Glucocerebrosidase mutations in subjects with parkinsonism Mol. Genet. Metab., 81 (2004),pp. 70-73
[76]	Maasen, J.A. Mitochondria, body fat and type 2 diabetes: what is the connection? Minerva Med., 99 (2008),pp. 241-251
[77]	Mak, H.Y., Nelson, L.S., Basson, M. et al. Nat. Genet., 38 (2006),pp. 363-368
[78]	Mancuso, D.J., Kotzbauer, P., Wozniak, D.F. et al. J. Biol. Chem., 284 (2009),pp. 35632-35644
[79]	Melser, S., Molino, D., Batailler, B. et al. Links between lipid homeostasis, organelle morphodynamics and protein trafficking in eukaryotic and plant secretory pathways Plant Cell Rep., 30 (2011),pp. 177-193
[80]	Merrill, A.H., Sullards, M.C., Allegood, J.C. et al. Sphingolipidomics: high-throughput, structure-specific, and quantitative analysis of sphingolipids by liquid chromatography tandem mass spectrometry Methods, 36 (2005),pp. 207-224
[81]	Montine, T.J., Montine, K.S., McMahan, W. et al. F2-isoprostanes in Alzheimer and other neurodegenerative diseases Antioxid. Redox Signal., 7 (2005),pp. 269-275
[82]	Nakamura, Y., Koizumi, R., Shui, G. et al. Proc. Natl. Acad. Sci. USA, 106 (2009),pp. 20978-20983
[83]	Ndamukong, I., Jones, D.R., Lapko, H. et al. PloS ONE, 5 (2010),p. e13396
[84]	Neumann, J., Bras, J., Deas, E. et al. Glucocerebrosidase mutations in clinical and pathologically proven Parkinson's disease Brain, 132 (2009),pp. 1783-1794
[85]	Nguyen, D.H., Hildreth, J.E. Evidence for budding of human immunodeficiency virus type 1 selectively from glycolipid-enriched membrane lipid rafts J. Virol., 74 (2000),pp. 3264-3272
[86]	Niemelä, P.S., Castillo, S., Sysi-Aho, M. et al. Bioinformatics and computational methods for lipidomics J. Chromatogr. B Analyt. Technol. Biomed. Life Sci., 877 (2009),pp. 2855-2862
[87]	Okamoto, Y., Higashiyama, H., Rong, J.X. et al. Comparison of mitochondrial and macrophage content between subcutaneous and visceral fat in db/db mice Exp. Mol. Pathol., 83 (2007),pp. 73-83
[88]	Oliveira, T.G., Chan, R.B., Tian, H. et al. Phospholipase d2 ablation ameliorates Alzheimer's disease-linked synaptic dysfunction and cognitive deficits J. Neurosci., 30 (2010),pp. 16419-16428
[89]	Ono, A., Freed, E.O. Role of lipid rafts in virus replication Adv. Virus Res., 64 (2005),pp. 311-358
[90]	O'Rourke, E.J., Soukas, A.A., Carr, C.E. et al. Cell Metab., 10 (2009),pp. 430-435
[91]	Parrish, N., Osterhout, G., Dionne, K. et al. J. Clin. Microbiol., 45 (2007),pp. 3915-3920
[92]	Peters, C., Li, M., Narasimhan, R. et al. Plant Cell, 22 (2010),pp. 2642-2659
[93]	Pickersgill, L., Litherland, G.J., Greenberg, A.S. et al. Key role for ceramides in mediating insulin resistance in human muscle cells J. Biol. Chem., 282 (2007),pp. 12583-12589
[94]	Pike, L.J. Rafts defined: a report on the Keystone Symposium on Lipid Rafts and Cell Function J. Lipid Res., 47 (2006),pp. 1597-1598
[95]	Pulfer, M., Murphy, R.C. Electrospray mass spectrometry of phospholipids Mass Spectrom. Rev., 22 (2003),pp. 332-364
[96]	Puppala, J., Siddapuram, S.P., Akka, J. et al. Genetics of nonalcoholic fatty liver disease: an overview J. Genet. Genomics, 40 (2013),pp. 15-22
[97]	Rajendran, L., Simons, K. Lipid rafts and membrane dynamics J. Cell Sci., 118 (2005),pp. 1099-1102
[98]	Rappley, I., Myers, D.S., Milne, S.B. et al. Lipidomic profiling in mouse brain reveals differences between ages and genders, with smaller changes associated with α-synuclein genotype J. Neurochem., 111 (2009),pp. 15-25
[99]	Rong, J.X., Qiu, Y., Hansen, M.K. et al. Adipose mitochondrial biogenesis is suppressed in db/db and high-fat diet-fed mice and improved by rosiglitazone Diabetes, 56 (2007),pp. 1751-1760
[100]	Ruipérez, V., Darios, F., Davletov, B. Alpha-synuclein, lipids and Parkinson's disease Prog. Lipid Res., 49 (2010),pp. 420-428
[101]	Sanchez-Mejia, R.O., Newman, J.W., Toh, S. et al. Phospholipase A2 reduction ameliorates cognitive deficits in a mouse model of Alzheimer's disease Nat. Neurosci., 11 (2008),pp. 1311-1318
[102]	Savchenko, T., Walley, J.W., Chehab, E.W. et al. Arachidonic acid: an evolutionarily conserved signaling molecule modulates plant stress signaling networks Plant Cell, 22 (2010),pp. 3193-3205
[103]	Schwudke, D., Hannich, J.T., Surendranath, V. et al. Top-down lipidomic screens by multivariate analysis of high-resolution survey mass spectra Anal. Chem., 79 (2007),pp. 4083-4093
[104]	Sharman, M.J., Shui, G., Fernandis, A.Z. et al. Profiling brain and plasma lipids in human APOE epsilon2, epsilon3, and epsilon4 knock-in mice using electrospray ionization mass spectrometry J. Alzheimers Dis., 20 (2010),pp. 105-111
[105]	Shindou, H., Shimizu, T. Acyl-CoA:lysophospholipid acyltransferases J. Biol. Chem., 284 (2009),pp. 1-5
[106]	Shui, G., Bendt, A.K., Jappar, I.A. et al. Mycolic acids as diagnostic markers for tuberculosis case detection in humans and drug efficacy in mice EMBO Mol. Med., 4 (2012),pp. 27-37
[107]	Shui, G., Bendt, A.K., Pethe, K. et al. Sensitive profiling of chemically diverse bioactive lipids J. Lipid Res., 48 (2007),pp. 1976-1984
[108]	Shui, G., Guan, X.L., Gopalakrishnan, P. et al. PloS ONE, 5 (2010),p. e11956
[109]	Shui, G., Guan, X.L., Low, C.P. et al. Mol. Biosyst., 6 (2010),pp. 1008-1017
[110]	Shui, G., Lam, S.M., Stebbins, J. et al. Polar lipid derangements in type 2 diabetes mellitus: potential pathological relevance of fatty acyl heterogeneity in sphingolipids Metabolomics, 9 (2013),pp. 786-799
[111]	Spillantini, M.G., Schmidt, M.L., Lee, V.M. et al. Alpha-synuclein in Lewy bodies Nature, 388 (1997),pp. 839-840
[112]	Springett, G.M., Bonham, L., Hummer, A. et al. Lysophosphatidic acid acyltransferase-beta is a prognostic marker and therapeutic target in gynecologic malignancies Cancer Res., 65 (2005),pp. 9415-9425
[113]	Srinivasan, S., Sadegh, L., Elle, I.C. et al. Cell Metab., 7 (2008),pp. 533-544
[114]	Sullards, M.C., Wang, E., Peng, Q. et al. Metabolomic profiling of sphingolipids in human glioma cell lines by liquid chromatography tandem mass spectrometry Cell. Mol. Biol. (Noisy-le-grand), 49 (2003),pp. 789-797
[115]	Tian, Y., Bi, J., Shui, G. et al. PLoS Genet., 7 (2011),p. e1001364
[116]	van der Meer-Janssen, Y.P.M., van Galen, J., Batenburg, J.J. et al. Lipids in host-pathogen interactions: pathogens exploit the complexity of the host cell lipidome Prog. Lipid Res., 49 (2010),pp. 1-26
[117]	van Eijk, M., Aten, J., Bijl, N. et al. Reducing glycosphingolipid content in adipose tissue of obese mice restores insulin sensitivity, adipogenesis and reduces inflammation PloS ONE, 4 (2009),p. e4723
[118]	van Meer, G. Cellular lipidomics EMBO J., 24 (2005),pp. 3159-3165
[119]	Vergnes, L., Beigneux, A.P., Davis, R. et al. Agpat6 deficiency causes subdermal lipodystrophy and resistance to obesity J. Lipid Res., 47 (2006),pp. 745-754
[120]	Wayne, L.G., Sohaskey, C.D. Annu. Rev. Microbiol., 55 (2001),pp. 139-163
[121]	Welti, R., Wang, X. Lipid species profiling: a high-throughput approach to identify lipid compositional changes and determine the function of genes involved in lipid metabolism and signaling Curr. Opin. Plant Biol., 7 (2004),pp. 337-344
[122]	Wenk, M.R. The emerging field of lipidomics Nat. Rev. Drug Discov., 4 (2005),pp. 594-610
[123]	Wenk, M.R. Lipidomics of host-pathogen interactions FEBS Lett., 580 (2006),pp. 5541-5551
[124]	Wild, S., Roglic, G., Green, A. et al. Global prevalence of diabetes: estimates for the year 2000 and projections for 2030 Diabetes Care, 27 (2004),pp. 1047-1053
[125]	Yamashita, T., Hashiramoto, A., Haluzik, M. et al. Enhanced insulin sensitivity in mice lacking ganglioside GM3 Proc. Natl. Acad. Sci. USA, 100 (2003),pp. 3445-3449
[126]	Yang, K., Cheng, H., Gross, R.W. et al. Automated lipid identification and quantification by multidimensional mass spectrometry-based shotgun lipidomics Anal. Chem., 81 (2009),pp. 4356-4368
[127]	Yang, Q., Gong, Z.J., Zhou, Y. et al. Cell. Mol. Life Sci., 67 (2010),pp. 1477-1490
[128]	Yen, K., Le, T.T., Bansal, A. et al. PloS ONE, 5 (2010),p. e12810
[129]	Yetukuri, L., Ekroos, K., Vidal-Puig, A. et al. Informatics and computational strategies for the study of lipids Mol. Biosyst., 4 (2008),pp. 121-127
[130]	Yu, B., Wakao, S., Fan, J. et al. Plant Cell Physiol., 45 (2004),pp. 503-510
[131]	Zhao, H., Przybylska, M., Wu, I.H. et al. Inhibiting glycosphingolipid synthesis improves glycemic control and insulin sensitivity in animal models of type 2 diabetes Diabetes, 56 (2007),pp. 1210-1218
[132]	Zheng, Z., Zou, J. J. Biol. Chem., 276 (2001),pp. 41710-41716