cholesterol synthesis, transport, and excretion.ppt
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Cholesterol Synthesis, transport, and
excretion
Abdul Salam M SofroFaculty of Medicine
YARSI University
Introduction• Cholesterol present in tissue & in plasma
lipoproteins either as free cholesterol or, combined with a long chain FA as cholesteryl ester
• It is synthesized in many tissues from acetyl-CoA and is ultimately eliminated from the body in the bile as cholesterol or bile salts
• Cholesterol is precursor of all other steroids in the body (corticosteroids, sex hormons, bile acids & vitamin D)
• It is typically a product of animal metabolism occurs in food of animal origin (egg yolk, meat, liver, brain)
• Slightly less than half of the cholesterol in the body derives from biosynthesis de novo.
• Biosynthesis in the liver accounts for approximately 10%, and in the intestines approximately 15%, of the amount produced each day.
• Cholesterol synthesis occurs in the cytoplasm and microsomes from the two-carbon acetate group of acetyl-CoA.
Biomedical importance
• Cholesteryl ester is a storage form of cholesterol found in most tissues
• It is transported as cargo in the hydrophobic core of lipoprotein
• LDL is the mediator of cholesterol & cholesteryl ester uptake into many tissues
• Free cholesterol is removed from tissues by HDL and transported to liver for conversion to bile acids (cholesterol is major constituent of gallstones)
• Cholesterol plays major role in the genesis of atheroclerosis
Acetyl-CoA is the source of all carbon atom in cholesterol
• Five stages in biosynthesis of cholesterol:– Synthesis of Mevalonate, a six-carbon
compound, from acetyl-CoA– Isoprenoid units are formed from
mevalonate by loss of CO2– Six isoprenoid units condense to form the
intermediate squalene– Squalene cyclisized to parent steroid,
lanosterol– Cholesterol is formed from lanosterol after
several further steps including the loss of three methyl groups
Pathway of cholesterol biosynthesis. Synthesis begins with the transport of acetyl-CoA ffrom the mitochondrion to the cytosol. The rate limiting step occurs at the 3-hydroxy-3-methylglutaryl-CoA (HMG-CoA) reducatase, HMGR catalyzed step. The phosphorylation reactions are required to solubilize the isoprenoid intermediates in the pathway.
Regulating Cholesterol Synthesis
Normal healthy adults synthesize cholesterol at a rate of approximately 1g/day and consume approximately 0.3g/day. A relatively constant level of cholesterol in the body (150 - 200 mg/dL) is maintained primarily by controlling the level of de novo synthesis. The level of cholesterol synthesis is regulated in part by the dietary intake of cholesterol.
• Regulation of HMG-CoA reductase:– Reduced activity in fasting animals
(reduced synthesis of cholesterol during fasting)
– Feedback mechanism whereby HMG-CoA reductase in liver in inhibited by mevalonate, the immediate product & cholesterol, the main product of the pathway (cholesterol metabolite, eg. oxygenated sterol is considered to repress transcription of the HMG-CoA reductase gene
• Many factors influence the cholesterol balance in tissues:– Increase is due to uptake of
cholesterol-containing lipoproteins by receptors; uptake of free cholesterol from cholesterol-rich lipoproteins to the cell membrane; cholesterol synthesis; and hydrolysis of cholesteryl-ester by the enzyme cholesteryl ester hydrolase
– Decrease is due to efflux of cholesterol from the membrane to lipoproteins of low cholesterol potential; esterification of cholesterol by acyl-CoA:cholesterol acyltransferase (ACAT); and utilization of cholesterol for synthesis of other steroids, such as hormones or bile acids in liver
The cellular supply of cholesterol is maintained at a steady level by three distinct mechanisms:
1. Regulation of HMGR activity and levels 2. Regulation of excess intracellular free
cholesterol through the activity of acyl-CoA:cholesterol acyltransferase, ACAT
3. Regulation of plasma cholesterol levels via LDL receptor-mediated uptake and HDL-mediated reverse transport.
Good and Bad Cholesterols and their affect on Health.
• It is commonly known that a high level of cholesterol in the blood – hypercholesterolemia- poses a risk for coronary heart disease and heart attack. Cholesterol is insoluble in the blood, it is transported to and from the cells by carriers known as lipoproteins.
Low-density lipoprotein (LDL) or “Bad Cholesterol”
• is the major cholesterol carrier in the blood. If too much LDL cholesterol circulates in the blood
• it can slowly build up in the walls of the arteries feeding the heart and brain. Together with other substances it can form plaque, a thick, hard deposit that can clog those arteries (a condition known as atherosclerosis).
High-density lipoprotein (HDL) or “Good Cholesterol”
• carries about one-third to one-fourth of blood cholesterol
• Experts think HDL tends to carry cholesterol away from the arteries and back to the liver, where it is metabolised and removed.
• It is believed that HDL can remove excess cholesterol from plaques and therefore slow their growth. However, while a high level of HDL decreases the associated risks, a low level of HDL cholesterol level may increase the possibility of stroke or heart attack.
Cholesterol Excretion
• Cholesterol must enter the liver and excreted in the bile as cholesterol or bile acids (salts)
• About 1 g cholesterol is eliminated from the body per day
• Much of cholesterol secreted in the bile is reabsorbed
• Some of the cholesterol that serves as precursor for the fecal sterols is derived from the intestinal mucosa.
• Coprostanol is the principal sterol in the feces (formed from cholesterol by the bacteria in lower intestine)
Cholesterol 7α-hydroxycholesterol
Chenodeoxycholyl-CoACholyl-CoA
Glycocholic acid
Taurocholic acidTauro & glyco-
chenodeoxycholic acid
Deoxycholic acid Lythocholic acid
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