Identification of a Specific Plasma Sphingolipid Profile in a Group of Normal-Weight and Obese Subjects: A Novel Approach for a “Biochemical” Diagnosis of Metabolic Syndrome?

Metabolic syndrome is nosographically defined by using clinical diagnostic criteria such as those of the International Diabetes Federation (IDF) ones, including visceral adiposity, blood hypertension, insulin resistance and dyslipidemia. Due to the pathophysiological implications of the cardiometabolic risk of the obese subject, sphingolipids, measured in the plasma, might be used to biochemically support the diagnosis of metabolic syndrome. A total of 84 participants, including normal-weight (NW) and obese subjects without (OB-SIMET−) and with (OB-SIMET+) metabolic syndrome, were included in the study, and sphingolipidomics, including ceramides (Cer), dihydroceramides (DHCer), hexosyl-ceramides (HexCer), lactosyl-ceramides (LacCer), sphingomyelins (SM) and GM3 ganglosides families, and sphingosine-1-phosphate (S1P) and its congeners, was performed in plasma. Only total DHCers and S1P were significantly higher in OB-SIMET+ than NW subjects (p < 0.05), while total Cers decreased in both obese groups, though statistical significance was reached only in OB-SIMET− (vs. NW) subjects (p < 0.05). When considering the comparisons of the single sphingolipid species in the obese groups (OB-SIMET− or OB-SIMET+) vs. NW subjects, Cer 24:0 was significantly decreased (p < 0.05), while Cer 24:1, DHCer 16:0, 18:0, 18:1 and 24:1, and SM 18:0, 18:1 and 24:1 were significantly increased (p < 0.05). Furthermore, taking into account the same groups for comparison, HexCer 22:0 and 24:0, and GM3 22:0 and 24:0 were significantly decreased (p < 0.05), while HexCer 24:1 and S1P were significantly increased (p < 0.05). After having analyzed all data via a PLS-DA-based approach, the subsequent determination of the VIP scores evidenced the existence of a specific cluster of 15 sphingolipids endowed with a high discriminating performance (i.e., VIP score > 1.0) among the three groups, including DHCer 18:0, DHCer 24:1, Cer 18:0, HexCer 22:0, GM3 24:0, Cer C24:1, SM 18:1, SM 18:0, DHCer 18:1, HexCer 24:0, SM 24:1, S1P, SM 16:0, HexCer 24:1 and LacCer 22:0. After having run a series of multiple linear regressions, modeled by inserting each sphingolipid having a VIP score > 1.0 as a dependent variable, and waist circumference (WC), systolic/diastolic blood pressures (SBP/DBP), homeostasis model assessment-estimated insulin resistance (HOMA-IR), high-density lipoprotein (HDL), triglycerides (TG) (surrogates of IDF criteria) and C-reactive protein (CRP) (a marker of inflammation) as independent variables, WC was significantly associated with DHCer 18:0, DHCer 24:1, Cer 18:0, HexCer 22:0, Cer 24:1, SM 18:1, and LacCer 22:0 (p < 0.05); SBP with Cer 18:0, Cer 24:1, and SM 18:0 (p < 0.05); HOMA-IR with DHCer 18:0, DHCer 24:1, Cer 18:0, Cer 24:1, SM 18:1, and SM 18:0 (p < 0.05); HDL with HexCer 22:0, and HexCer 24:0 (p < 0.05); TG with DHCer 18:1, DHCer 24:1, SM 18:1, and SM 16:0 (p < 0.05); CRP with DHCer 18:1, and SP1 (p < 0.05). In conclusion, a cluster of 15 sphingolipid species is able to discriminate, with high performance, NW, OB-SIMET− and OB-SIMET+ groups. Although (surrogates of) the IDF diagnostic criteria seem to predict only partially, but congruently, the observed sphingolipid signature, sphingolipidomics might represent a promising “biochemical” support for the clinical diagnosis of metabolic syndrome.

[1]  Daowen Wang,et al.  Emerging Roles of Ceramide in Cardiovascular Diseases , 2022, Aging and disease.

[2]  N. Akawi,et al.  Role of Ceramides in the Molecular Pathogenesis and Potential Therapeutic Strategies of Cardiometabolic Diseases: What we Know so Far , 2022, Frontiers in Cell and Developmental Biology.

[3]  C. Costea,et al.  Involvement of Ceramides in Non-Alcoholic Fatty Liver Disease (NAFLD) Atherosclerosis (ATS) Development: Mechanisms and Therapeutic Targets , 2021, Diagnostics.

[4]  M. Maceyka,et al.  Sphingolipids in metabolic disease: The good, the bad, and the unknown. , 2021, Cell metabolism.

[5]  B. Keavney,et al.  Circulating ceramides as biomarkers of cardiovascular disease: Evidence from phenotypic and genomic studies. , 2021, Atherosclerosis.

[6]  R. Choi,et al.  Ceramides and other sphingolipids as drivers of cardiovascular disease , 2021, Nature Reviews Cardiology.

[7]  Tatsuo Kawai,et al.  Adipose Tissue Inflammation and Metabolic Dysfunction in Obesity. , 2020, American journal of physiology. Cell physiology.

[8]  S. Summers,et al.  Metabolic Messengers: ceramides , 2019, Nature Metabolism.

[9]  Mathieu Almeida,et al.  Elevated serum ceramides are linked with obesity-associated gut dysbiosis and impaired glucose metabolism , 2019, Metabolomics.

[10]  James E. Cox,et al.  Targeting a ceramide double bond improves insulin resistance and hepatic steatosis , 2019, Science.

[11]  T. Langer,et al.  CerS6-Derived Sphingolipids Interact with Mff and Promote Mitochondrial Fragmentation in Obesity , 2019, Cell.

[12]  E. Strettoi,et al.  Novel ophthalmic formulation of myriocin: implications in retinitis pigmentosa , 2019, Drug delivery.

[13]  International Association for the Study of Obesity , 2018, The Grants Register 2019.

[14]  S. Summers,et al.  Could Ceramides Become the New Cholesterol? , 2018, Cell metabolism.

[15]  Yuehua Wu,et al.  Activation of intestinal hypoxia-inducible factor 2α during obesity contributes to hepatic steatosis , 2017, Nature Medicine.

[16]  M. Hussain,et al.  Sphingolipids and Lipoproteins in Health and Metabolic Disorders , 2017, Trends in Endocrinology & Metabolism.

[17]  P. Meikle,et al.  Adipocyte Ceramides Regulate Subcutaneous Adipose Browning, Inflammation, and Metabolism. , 2016, Cell metabolism.

[18]  M. Vendelbo,et al.  The Crucial Role of C18-Cer in Fat-Induced Skeletal Muscle Insulin Resistance , 2016, Cellular Physiology and Biochemistry.

[19]  Wei Chen,et al.  Sphingosine 1-phosphate in metabolic syndrome (Review). , 2016, International journal of molecular medicine.

[20]  Kim Ekroos,et al.  Plasma ceramides predict cardiovascular death in patients with stable coronary artery disease and acute coronary syndromes beyond LDL-cholesterol , 2016, European heart journal.

[21]  T. Geng,et al.  SphK1 mediates hepatic inflammation in a mouse model of NASH induced by high saturated fat feeding and initiates proinflammatory signaling in hepatocytes[S] , 2015, Journal of Lipid Research.

[22]  P. Serruys,et al.  Plasma concentrations of molecular lipid species in relation to coronary plaque characteristics and cardiovascular outcome: Results of the ATHEROREMO-IVUS study. , 2015, Atherosclerosis.

[23]  S. Summers,et al.  Ceramides – Lipotoxic Inducers of Metabolic Disorders , 2015, Trends in Endocrinology & Metabolism.

[24]  D. Rader,et al.  Microsomal Triglyceride Transfer Protein Transfers and Determines Plasma Concentrations of Ceramide and Sphingomyelin but Not Glycosylceramide* , 2015, The Journal of Biological Chemistry.

[25]  B. Bergman,et al.  Serum sphingolipids: relationships to insulin sensitivity and changes with exercise in humans. , 2015, American journal of physiology. Endocrinology and metabolism.

[26]  J. McDonald,et al.  Targeted Induction of Ceramide Degradation Leads to Improved Systemic Metabolism and Reduced Hepatic Steatosis. , 2015, Cell metabolism.

[27]  W. Pan,et al.  Ceramide is upregulated and associated with mortality in patients with chronic heart failure. , 2015, The Canadian journal of cardiology.

[28]  I. Albert,et al.  Intestinal farnesoid X receptor signaling promotes nonalcoholic fatty liver disease. , 2015, The Journal of clinical investigation.

[29]  S. Summers,et al.  CerS2 haploinsufficiency inhibits β-oxidation and confers susceptibility to diet-induced steatohepatitis and insulin resistance. , 2014, Cell metabolism.

[30]  Matthias Blüher,et al.  Obesity-induced CerS6-dependent C16:0 ceramide production promotes weight gain and glucose intolerance. , 2014, Cell metabolism.

[31]  J. Górski,et al.  Inhibition of ceramide de novo synthesis reduces liver lipid accumulation in rats with nonalcoholic fatty liver disease , 2014, Liver international : official journal of the International Association for the Study of the Liver.

[32]  Sarah Spiegel,et al.  Sphingolipid metabolites in inflammatory disease , 2014, Nature.

[33]  W. Pan,et al.  Elevation of ceramide and activation of secretory acid sphingomyelinase in patients with acute coronary syndromes , 2014, Coronary artery disease.

[34]  W. März,et al.  Molecular Lipids Identify Cardiovascular Risk and Are Efficiently Lowered by Simvastatin and PCSK9 Deficiency , 2013, The Journal of clinical endocrinology and metabolism.

[35]  A. Goldfine,et al.  Plasma ceramides are elevated in female children and adolescents with type 2 diabetes , 2013, Journal of pediatric endocrinology & metabolism : JPEM.

[36]  P. Meikle,et al.  Ceramides Contained in LDL Are Elevated in Type 2 Diabetes and Promote Inflammation and Skeletal Muscle Insulin Resistance , 2013, Diabetes.

[37]  A. Scherz,et al.  Ablation of Ceramide Synthase 2 Causes Chronic Oxidative Stress Due to Disruption of the Mitochondrial Respiratory Chain* , 2013, The Journal of Biological Chemistry.

[38]  Joseph B. Williams,et al.  The control of the balance between ceramide and sphingosine-1-phosphate by sphingosine kinase: oxidative stress and the seesaw of cell survival and death. , 2012, Comparative biochemistry and physiology. Part B, Biochemistry & molecular biology.

[39]  M. Jensen,et al.  Sphingolipid content of human adipose tissue: relationship to adiponectin and insulin resistance , 2012, Obesity.

[40]  S. Summers,et al.  Fenretinide Prevents Lipid-induced Insulin Resistance by Blocking Ceramide Biosynthesis* , 2012, The Journal of Biological Chemistry.

[41]  E. Abel,et al.  Ceramide Mediates Vascular Dysfunction in Diet-Induced Obesity by PP2A-Mediated Dephosphorylation of the eNOS-Akt Complex , 2012, Diabetes.

[42]  D. Clegg,et al.  Lipid-induced insulin resistance mediated by the proinflammatory receptor TLR4 requires saturated fatty acid-induced ceramide biosynthesis in mice. , 2011, The Journal of clinical investigation.

[43]  Wei Hu,et al.  Differential Regulation of Dihydroceramide Desaturase by Palmitate versus Monounsaturated Fatty Acids , 2011, The Journal of Biological Chemistry.

[44]  Gerd Schmitz,et al.  Sphingolipid profiling of human plasma and FPLC-separated lipoprotein fractions by hydrophilic interaction chromatography tandem mass spectrometry. , 2011, Biochimica et biophysica acta.

[45]  A. Bielawska,et al.  Blood sphingolipidomics in healthy humans: impact of sample collection methodology , 2010, Journal of Lipid Research.

[46]  D. Muoio,et al.  Inhibition of De Novo Ceramide Synthesis Reverses Diet-Induced Insulin Resistance and Enhances Whole-Body Oxygen Consumption , 2010, Diabetes.

[47]  S. Grundy,et al.  Harmonizing the metabolic syndrome: a joint interim statement of the International Diabetes Federation Task Force on Epidemiology and Prevention; National Heart, Lung, and Blood Institute; American Heart Association; World Heart Federation; International Atherosclerosis Society; and International As , 2009, Circulation.

[48]  Wei Hu,et al.  Palmitate increases sphingosine-1-phosphate in C2C12 myotubes via upregulation of sphingosine kinase message and activity[S] , 2009, Journal of Lipid Research.

[49]  M. Uusitupa,et al.  Link between plasma ceramides, inflammation and insulin resistance: association with serum IL-6 concentration in patients with coronary heart disease , 2009, Diabetologia.

[50]  Jacek Bielawski,et al.  Central role of ceramide biosynthesis in body weight regulation, energy metabolism, and the metabolic syndrome. , 2009, American journal of physiology. Endocrinology and metabolism.

[51]  S. Pyne,et al.  Targeting sphingosine-1-phosphate signalling for cardioprotection. , 2009, Current opinion in pharmacology.

[52]  P. Scherer,et al.  PAQRs: A Counteracting Force to Ceramides? , 2009, Molecular Pharmacology.

[53]  R. DeFronzo,et al.  Plasma Ceramides Are Elevated in Obese Subjects With Type 2 Diabetes and Correlate With the Severity of Insulin Resistance , 2009, Diabetes.

[54]  K. Williams,et al.  Acid Sphingomyelinase Promotes Lipoprotein Retention Within Early Atheromata and Accelerates Lesion Progression , 2008, Arteriosclerosis, thrombosis, and vascular biology.

[55]  M. Kowala,et al.  Serine palmitoyltransferase inhibitor myriocin induces the regression of atherosclerotic plaques in hyperlipidemic ApoE-deficient mice. , 2008, Pharmacological research.

[56]  J. Bismuth,et al.  Ceramide: a common pathway for atherosclerosis? , 2008, Atherosclerosis.

[57]  M. Birnbaum,et al.  Inhibition of ceramide synthesis ameliorates glucocorticoid-, saturated-fat-, and obesity-induced insulin resistance. , 2007, Cell metabolism.

[58]  M. Rekhter,et al.  Modulation of lipoprotein metabolism by inhibition of sphingomyelin synthesis in ApoE knockout mice. , 2006, Atherosclerosis.

[59]  G. Reaven,et al.  The metabolic syndrome: is this diagnosis necessary? , 2006, The American journal of clinical nutrition.

[60]  A. Merrill,et al.  Sphingolipidomics: high-throughput, structure-specific, and quantitative analysis of sphingolipids by liquid chromatography tandem mass spectrometry. , 2005, Methods.

[61]  V. Mohan,et al.  Association of low adiponectin levels with the metabolic syndrome--the Chennai Urban Rural Epidemiology Study (CURES-4). , 2005, Metabolism: clinical and experimental.

[62]  M. Hojjati,et al.  Effect of Myriocin on Plasma Sphingolipid Metabolism and Atherosclerosis in apoE-deficient Mice* , 2005, Journal of Biological Chemistry.

[63]  F. Liu,et al.  Regulation of Insulin Action by Ceramide , 2004, Journal of Biological Chemistry.

[64]  R. Turner,et al.  Homeostasis model assessment: insulin resistance and β-cell function from fasting plasma glucose and insulin concentrations in man , 1985, Diabetologia.

[65]  É. Hajduch,et al.  Ceramide Disables 3-Phosphoinositide Binding to the Pleckstrin Homology Domain of Protein Kinase B (PKB)/Akt by a PKCζ-Dependent Mechanism , 2003, Molecular and Cellular Biology.

[66]  R. Dobrowsky,et al.  A Role for Ceramide, but Not Diacylglycerol, in the Antagonism of Insulin Signal Transduction by Saturated Fatty Acids* , 2003, The Journal of Biological Chemistry.

[67]  J. Wang,et al.  Sphingomyelinase and ceramide analogs induce contraction and rises in [Ca(2+)](i) in canine cerebral vascular muscle. , 2000, American journal of physiology. Heart and circulatory physiology.

[68]  M. Visser,et al.  Elevated C-reactive protein levels in overweight and obese adults. , 1999, JAMA.

[69]  K. Williams,et al.  Rabbit aorta and human atherosclerotic lesions hydrolyze the sphingomyelin of retained low-density lipoprotein. Proposed role for arterial-wall sphingomyelinase in subendothelial retention and aggregation of atherogenic lipoproteins. , 1996, The Journal of clinical investigation.

[70]  Y. Hannun,et al.  Ceramide: an intracellular signal for apoptosis. , 1995, Trends in biochemical sciences.

[71]  Y. Hannun,et al.  Programmed cell death induced by ceramide. , 1993, Science.

[72]  R. Kolesnick,et al.  Ceramide: a novel second messenger. , 1992, Advances in lipid research.