Lipid metabolism Pavla Balínová. Lipids Lipids dissolve well in organic solvents but they are insoluble in water. Biological roles of lipids: ● lipids.

Slides:



Advertisements
Similar presentations
Review session for exam-III
Advertisements

Figure, Head group attachment Membrane phospholipids:
Lipid Metabolism Remember fats?? Triacylglycerols - major form of energy storage in animals Your energy reserves: ~0.5% carbs (glycogen + glucose) ~15%
 It can be divided into 3 processes: 1)Biosynthesis of glycerol. 2)Biosynthesis of fatty acids. 3)Biosynthesis of the triacylglycerol.  It occurs in.
LIPOLYSIS: FAT OXIDATION & KETONES BIOC DR. TISCHLER LECTURE 33.
Synthesis of Triglycerides
Lipogenesis Fats not only obtained from the diet but also obtained from lipogenesis in the body. Lipogenesis means synthesis of fats from CHO and proteins.
Introduction  lipids are a good source of energy as 1 gm supplies 9.1 calories, which is over double that supplied by carbohydrates or protein.  Dietary.
Welcome to class of Lipid metabolism Dr. Meera Kaur.
1 Metabolic Pathways for Lipids. Ketogenesis and Ketone Bodies. Fatty Acid Synthesis.
Lipid Metabolism Lipid Metabolism 2 nd Year Nursing By Eman Mokbel Alissa, Ph.D
Lipid Metabolism 1: Overview of lipid transport in animals, fatty acid oxidation, ketogenesis in liver mitochondria Bioc 460 Spring Lecture 35 (Miesfeld)
Chapter 16 (Part 3) Fatty acid Synthesis.
1 Fatty Acid Metabolism. 2 Free Energy of Oxidation of Carbon Compounds.
Prentice Hall c2002Chapter 161 Fig 10.5 Overview of catabolic pathways.
1 Oxidation of Fatty Acids. Digestion of Triacylglycerols Beta-Oxidation of Fatty Acids ATP and Fatty Acid Oxidation.
Pratt & Cornely, Chapter 17
Overview of catabolic pathways. Chapter 16 - Lipid Metabolism Triacylglycerols and glycogen are the two major forms of stored energy in vertebrates Glycogen.
Chem 454: Biochemistry II University of Wisconsin-Eau Claire Chem 454: Biochemistry II University of Wisconsin-Eau Claire Chapter 22. Fatty Acid Metabolism.
Cholesterol Cholesterol Sources:
Lipid Metabolism Dietary Lipid Reactions Lecture 1 of 5 Jim Littlejohn 11/20/03 Texas A+M Health Sciences Center: College of Medicine.
Biosynthesis of Fatty Acids Medical Biochemistry Lecture #46.
Section 7. Lipid Metabolism
BIOSYNTHESIS OF FATTY ACIDS Hendra Wijaya Esa unggul University.
Energy economy of the cells
Structure of lipids Pavla Balínová. Lipids Lipids are a large and heterogenous group of substances of biological origin. They are easily dissolved in.
Chapter 23 Fatty Acid Metabolism Denniston Topping Caret 5th Edition
Ketogenesis & Ketolysis
Oxidation of Fatty Acids Fatty acids are an important source of energy Fatty acids energy Oxidation is the process where energy is produced by degradation.
Generation and Storage of Energy
Carbohydrates, nucleotides, amino acids, now lipids Lipids exhibit diverse biological function –Energy storage –Biological membranes –Enzyme cofactors.
LIPID METABOLISM: CHOLESTEROL METABOLISM. Functions of Cholesterol a precursor of steroid hormones (progesterone, testosterone, estradiol, cortisol, etc.)
Metabolism of steroids Pavla Balínová. Cholesterol is a maternal molecule of all steroids in human body is a starting molecule for synthesis of bile acids.
Metabolism of lipids Dr. Mamoun Ahram Biochemistry for Nursing Summer 2015.
Lipid metabolism By Dr. Hoda Gad. OBJECTIVES BY THE END OF THESE LECTURES, STUDENT SHOULD BE ABLE TO:  Understand the structure of lipids including 
Fatty acid oxidation 3 steps to break down fatty acids to make energy 1.Fatty acid must be activated: bond to coenzyme A 2.Fatty acid must be transported.
Chapter 23 Fatty Acid Metabolism Denniston Topping Caret 6 th Edition Copyright  The McGraw-Hill Companies, Inc. Permission required for reproduction.
ECDA SEPT LIPOGENESIS  Fatty acids are formed by the action of fatty acid synthase from acetyl-CoA and malonyl-CoA (a 3- carbon compound) precursors.
Lipolysis. Largest storage form of energy Provides energy at the slowest rate Stored: –adipose tissue –muscle –Brain, CNS, abdomen, etc. Use of lipids.
Fatty Acid Metabolism. Why are fatty acids important to cells? fuel molecules stored as triacylglycerols building blocks phospholipids glycolipids precursors.
Fatty acid catabolism 1.Digestion, Mobilization, and Transport of Fatty acids  Oxidation 3. Ketone Bodies.
Metabolism of lipids Vladimíra Kvasnicová. Lipids = group of biological molecules that are insoluble in aqueous solutions and soluble in organic solvents.
Lipogenesis Fats not only obtained from the diet but also obtained from lipogenesis in the body. Lipogenesis means synthesis of neutral fats (TAG) from.
23-1 Principles and Applications of Inorganic, Organic, and Biological Chemistry Denniston,Topping, and Caret 4 th ed Chapter 23 Copyright © The McGraw-Hill.
Figure, Head group attachment Membrane phospholipids:
Lipogenesis Fats not only obtained from the diet but also obtained from lipogenesis in the body. Lipogenesis means synthesis of neutral fats (TAG) from.
Biochemistry: A Short Course Second Edition Tymoczko Berg Stryer CHAPTER 27 Fatty Acid Degradation.
Sources pof energy in fasting state In adipose tissue: In fasting state, the stored TAG will be the major source of energy. -Stored TAG in adipose tissue.
Fatty Acid Metabolism 1. Fatty acid synthesis.
LECTURE 10 Introduction to lipid metabolism and oxidation of fatty acids I V. SRIDEVI
Pratt & Cornely, Chapter 17
Lipogenesis & Lipolysis
Hormonal regulation of lipid metabolism
Lipid metabolism.
OXIDATION OF FATTY ACIDS
Cholesterol and its transport
Fatty acid synthesis (Lipogenesis & Lipolysis)
METABOLISM OF LIPIDS: SYNTHESIS OF FATTY ACIDS
LIPIDS AND LIPOPROTEINS Dr. Gamal Gabr
Lipid Catabolism.
LIPID METABOLISM.
Lipid/Fat metabolism Chapter 4
Prof. Dr. Zeliha Büyükbingöl
Metabolism of the lipids
Chapter Twenty-One Lipid Metabolism.
Lipids.
Advanced Nutrition Lipids 5 MargiAnne Isaia, MD MPH.
Dr. Diala Abu-Hassan, DDS, PhD
Chapter Twenty-One Lipid Metabolism.
Presentation transcript:

Lipid metabolism Pavla Balínová

Lipids Lipids dissolve well in organic solvents but they are insoluble in water. Biological roles of lipids: ● lipids are important source of energy – they serve as metabolic fuel ● amphipathic lipids are building blocks of cellular membranes ● some of them are substrates for synthesis of other compounds (eicosanoids, bile acids) ● lipids are excellent insulators

Classification of lipids I. Simple lipids ● Triacylglycerols TAG (fats) ● Waxes II. Complex lipids ● Phospholipids ● Sphingophospholipids ● Glycolipids III. Isoprenoids and steroids Isoprenoids: vitamins A, D, E, K Steroids: sterols, bile acids, steroid hormones Figure is found on

The figure was adopted from: J.Koolman, K.H.Röhm / Color Atlas of Biochemistry, 2 nd edition Fatty acids (FA)

Degradation of fats in adipose tissue Adipose tissue (fat cells) = fat storage Degradation of TAG in adipose tissue (lipolysis) is catalyzed by hormone sensitive lipase (HSL). This enzyme is activated by epinephrine and glucagon and inhibited by insulin. Figure is found on

Utilization of FA within the cell Tissues take up FA from the blood to rebuild fats or to obtain energy from their oxidation. Metabolism of FA is especially intensive in the liver. „Free“ fatty acids (FFA) are transferred with albumin in the blood. FA in blood → enter to the cell → in the cytoplasm FA are converted to their CoA derivatives by enzyme acyl- CoA-synthetase (ATP is consumed) → acyl-CoAs Fatty acid + ATP + CoA ---> Acyl-CoA + PP i + AMP

Transfer of acyl-CoAs from cytoplasm to the mit. matrix is performed by a carnitine transporter Figure is found on

β -oxidation of fatty acids substrate: acyl-CoA product: n acetyl-CoA, n NADH + H +, n FADH 2 function: gain of energy from fatty acids subcelullar location: matrix of mitochondria organ location: liver, skeletal muscles and other tissues with expection to CNS regulatory enzyme: carnitine acyltransferase I

Summary For complete degradation of palmitic acid 7 cycles are required. Degradation of palmitic acid (16 C) gives 106 ATP in total. Regulation of β-oxidation of FA: Regulatory enzyme is carnitine acyltransferase I – it is inhibited by malonyl-CoA (intermediate of FA synthesis).

Synthesis of ketone bodies (ketogenesis) substrate: acetyl-CoA product: acetoacetate, 3-hydroxybutyrate, acetone function: energy substrate for extrahepatal tissues subcelullar location: matrix of mitochondria organ location: liver Excessive production of ketone bodies is typical during starvation or diabetes mellitus: ↑ lipolysis → ↑ FA → β-oxidation of FA → excess of acetyl-CoA → ↑ ketogenesis

Synthesis of ketone bodies (ketogenesis) Figure is found at

Use of ketone bodies by the extrahepatal tissues acetoacetate and 3-hydroxybutyrate are reconverted to acetyl-CoA ( → citric acid cycle) is located in matrix of mitochondria of the peripheral tissues is significant in skeletal muscles, heart and also in the brain if lack of Glc occurs

Use of ketone bodies by the extrahepatal tissues Figure is found at Liver lacks this enzyme therefore is unable to use ketone bodies as fuel

Fatty acid synthesis substrate: acetyl-CoA, NADPH + H + product: palmitate (= endproduct of FA synthesis) function: de novo synthesis of FA which are stored as TAG subcelullar location: cytosol organ location: mainly liver and adipose tissue and also other tissues regulatory enzyme: acetyl-CoA carboxylase

The committed step in FA synthesis Formation of malonyl-CoA from acetyl-CoA and HCO 3 - is catalyzed by enzyme acetyl-CoA carboxylase (a key regulatory enzyme). Citrate is an allosteric stimulator and palmitoyl-CoA inhibits this enzyme. Hormonal regulation: glucagon and epinephrine - inhibition insulin - stimulation

The growing fatty acids are linked to a phosphopantetheine group of an acyl carrier protein (ACP) of FA synthase. Acetyl-CoA is carboxylated by HCO 3 - to yield malonyl-CoA → condensation between the acetyl-ACP and the malonyl-ACP → acetoacetyl-ACP is formed.

FA synthesis is performed through a cycle of four reactions: Figure is found on

Biosynthesis of TAG Biosynthesis of TAG occurs in cytoplasm and ER of liver and fat cells but also in other tissues. Figure is found on

Complex lipids (phospholipids, sphingophospholipids, glycolipids) Phospholipids = glycerol + 2 FA + phosphate group + hydrophilic compound Phosphatidylethanolamine (cephalin) Phophatidylinositol Phosphatidylcholine (lecithin) choline

Sphingophospholipids = sphingosine + FA + phosphate residue + amino alcohol or sugar alcohol Ceramide = sphingosine + fatty acid Sphingomyelin acyl residue

Glycolipids = sphingosine + FA + sugar or oligosaccharide residue The phosphate group is absent. Galactocerebroside

Degradation of phospholipids Phospholipases are divided according to the type of the bond which is cleaved. Figure is found on

Synthesis of cholesterol substrate: acetyl-CoA product: cholesterol function: de novo synthesis of endogenous cholesterol subcelullar location: cytosol and endoplasmic reticulum organ location: liver, intestine, adrenal cortex, ovaries, testes and placenta make the largest contributions to the body´s cholesterol pool Cholesterol is a constituent of cellular membranes and it is present in all animal tissues.

Biosynthesis of isoprenoids and steroids Figure is found on

Regulation of cholesterol synthesis reduction of HMG-CoA to mevalonic acid is catalyzed by HMG-CoA reductase – rate-limiting and key regulatory step expression of HMG-CoA reductase gene is inhibited by cholesterol ● activity of HMG-CoA reductase is increased by insulin and thyroxine but glucagone has the opposite effect Figure was adopted from textbook T. M. Devlin et al.: Textbook of Biochemistry With Clinical Correlations, 4th ed.

Lipoproteins ● Chylomicrons carry TAG (fat) from the intestine to the liver and adipose tissue ● VLDL carry (newly synthesized) TAG from the liver to peripheral tissues ● IDL are intermediate between VLDL and LDL ● LDL carry cholesterol from the liver to cells of the body ● HDL collects cholesterol from body´s tissues and brings it back to the liver Figure was assumed from art/720793/92254/Cutaway-view-of-a-low-density-lipoprotein-complex-The-LDL

Metabolism of lipoproteins Figure was assumed from

Enzyme lipoprotein lipase (LPL) is present on the surface of the vascular endothelia. This enzyme hydrolyses TAG in chylomicrons → chylomicrons remnants → liver LPL also catalyzes cleavage of TAG in VLDL → IDL. LPL synthesis is stimulated by insulin. Enzyme lecithin cholesterol acyltransferase (LCAT) catalyzes esterification of cholesterol with acyl. It is included in HDL formation. Figure was adopted from textbook T. M. Devlin et al.: Textbook of Biochemistry With Clinical Correlations, 4th ed.