Metabolism of acylglycerols and sphingolipids

1. Metabolism of acylglycerols and sphingolipids Alice Skoumalová

2. Types of glycerolipids and sphingolipids

3. Triacylglycerols • function as energy reserves • adipose tissue (storage of triacylglycerol), lipoproteins

4. 2. Glycerophospholipids • the major lipid components of biological membranes • lipoproteins, bile, lung surfactant • source of PUFA (eicosanoids) • signal transmission (hydrolysis of PIP2)

5. 3. Plasmalogens • myelin, heart muscle PAF (Platelet-activating factor) • released from phagocytic blood cells in respons to varios stimuli (platelet aggregation, edema, hypotension)

6. 4. Sphingomyelins (sphingophospholipids) • membrane components (make up 10-20% of plasma membrane lipids) • myelin Sphingosine

7. 4. Glycolipids • the surfaces of cell membranes, receptors (hormons, cholera toxin), specific determinats of cell-cell recognition, the antigenic determinants of the ABO blood groups • cerebrosides, sulfatides, gangliosides

8. Lipogenesis -the synthesis of triacylglycerols from glucose (mainly in the liver) FA (from the diet, synthetized) • TG • glycerophospholipides • sphingolipides

9. Synthesis of TG in the smooth endoplasmic reticulum The sources of glycerol 3-phosphate: 1. the phosphorylation of glycerol (glycerol kinase) liver 2. the reduction of dihydroxyacetone phosphate (from glycolysis) liver, adipose tissue Phosphatidic acid - the precursor for: 1. TG 2. glycerophospholipids

10. Dephosphorylation: Addition of another acyl: Formation of TG:

11. Synthesis, processing and secretion of VLDL • proteins synthesized on the rough ER are packaged with TG in the ER and GC to form VLDL • TG, cholesterol, phospholipids and proteins VLDL

12. Lipoproteins Function: • Lipid transport (cholesterol, cholesterol esters, triacylglycerols, phospholipids) Structure: A nucleus: triacylglycerols, cholesterol esters A shell: phospholipids, apoproteins, cholesterol

13. Fate of VLDL TG • Lipoprotein lipase • present on the lining cells of the capillaries (in adipose and sceletal muscle tissue) • coenzyme Apo C-II (from HDL) • hydrolyses TG from VLDL and chylomicrons

14. Storage of TG in adipose tissue • Insulin • glucose transport into cells • synthesis and secretion of LPL

15. Release of FA from adipose TG • ↓Insulin, ↑Glucagon • intracellular cAMP increases - activates protein kinase A - phosphorylates hormone-sensitive lipase • FA - complexes with albumin, oxidized to CO2 and water in tissues • Prolongedfasting - ketone bodies (from acetyl CoA), gluconeogenese (glycerol)

16. Synthesis of glycerophospholipids 1. Phosphatidic acid - addition of a head group to the molecule 2. Phospholipid interconversions:

17. Degradation of glycerophospholipids Phospholipases located in cell membranes or in lysosomes Phospholipase A2 Phospholipase C Arachidonic acid - eicosanoids Hydrolysis of PIP2 - the second messengers Repair mechanism for membrane DAG and inositol PIP2 lipids damaged by free radicals

18. Synthesis of sphingolipids In the Golgi complex (membranes of SV) Formation of ceramide: Precursors: Serine + Palmitoyl CoA condense

20. Degradation of sphingolipids • by lysosomal enzymes (deficienties result in lysosomal storage disease = sphingolipidoses) Sphingolipidoses genetic mutations, mental retardation, death

21. Tay-Sachs disease • ganglioside accumulation in neurons

22. Summary • Triacylglycerols (synthesis) • Storage of TG in adipose tissue • Release of FA from adipose tissue • Glycerophospholipids (synthesis, degradation) • Sphingolipids (synthesis, degradation)

23. Pictures used in the presentation: Marks´ Basic Medical Biochemistry, A Clinical Approach, third edition, 2009 (M. Lieberman, A.D. Marks)