Post on 10-Jul-2020
Cholesterol metabolism
• Metabolis transformations of cholesterol
• Bile acids
• Steroid hormones
• Vitamin D
cholesteryl esters
kalciolsvitamins D
bile acids(24 C)
steroidhormones
adrenal corticalsteroid hormones
(21 C)
glucocorticoids mineralocorticoids
sexhormones
androgens(19 C)
estrogens(18 C)
18
HO 3
19
21 20
17
24
Metabolic transformation of cholesterol
HO
CH2-O-C
O
C-O-CH
CH2-O-
O
P -cholin
-R
CH2-O-C
O
HO-CH
CH2-O- P -cholin
-RC~CoA
O
O
C
O
1 - ACAT (intracellular e.)(acyl-CoA:cholesterol acyltransferase)
2 - Cholesterolesterase
3 - LCAT (plasma e.)(lecithin:cholesterol acyltransferase)
lecithin
lysolecithin
Cholesteryl ester (CE)
CoA-SH
1
23
cholesterol
Cholesteryl esters
Bile acids
24 carbon steroid compounds – degradation products of cholesterol(50-75% of daily cholesterol turnover)
Provide cholesterol excretion as:• metabolic products• solubilizer of cholesterol in bile
Bile salts- products of conjugation of bile acids with glycin or taurin
COOH + H2N-CH2-COO-
COOH + H2N-CH2-SO3 -
pKa = 2,2
pKa = 1,2
more polar sidechain
more effective detergents
pKa = 6polar and apolar face emulsifying agents
(bile, intestine)
- H2ORatio glycine- to taurine-conjugated acids ~ 3: 1
Metabolism of bile acids
Synthesis: liver
cholesterol primary bile acids primary bile salts
bile
intestine secondary bile acids/salts+ primary bile acids/salts
feces
enterohepatic circulation
bound to albumin
Cholelithiasis: cholesterol gallstones – precipitation of cholesterolin bile due to decreased amount of bile acids/salts in bile
malabsorption of bile acids, obstruction of biliary tract, decreased synthesis, increased cholesterol excretion into bile
Biosynthesis of primary bile acidscholesterol
7-α-hydroxycholesterol
choloyl-CoA
chenodeoxycholoyl-CoA
cholic acid = cholate
chenodeoxycholic acid= chenodeoxycholate
glycocholatetaurocholate
Cytochrome P450NADPH + H+ O2
CoASH
CoASH
glycin
taurin
7-α-hydroxylase (+ vitamin C, - BA)
conjugated bile acids = bile salts
HO
primary bileacids - liver
secondary bileacids - intestine
7-oxolithocholate lithocholate
ursodeoxycholate
cholate 30 % chenodeoxycholate 44 %
deoxycholate24 %
cholesterol
O
OH
derived by 7-dehydroxylation through action of bacterial enzymes primarily in large intestine
Metabolism of bile acids
Increase in bile acids fecal excretion increased conversion of cholesterol to bile acids, (for example pectins from fruit) incresed number of LDL- receptors on hepatocytes
decreased cholesterol plasma level
Treatment of hypercholesterolema – cholestyramin, colestipol – hydrophilic, water-insoluble,nondigestable and nonabsorbable synthetic resins– bind bile acids, increase their loss in fecesand interrupt their enterohepatic circulation
Steroid hormones
Synthesis: from cholesterol via pregnenolone
• Adrenal cortex - aldosterone
cortisol
• Corpus luteum - progesterone
• Ovaries - estradiol
• Testes - testosterone
Transport by blood to target tissues:
• Albumin - nonspecific carrier
• Transcortin - cortisol, corticosterone
• Sex hormone-binding protein – sex hormones
Conversion of cholesterol to adrenal cortical hormones
1. Side chain cleavage 21 C
pregnenolone
2. Dehydrogenation of 3-OH, moving of double bond from B ringtothe ring A
progesterone
3. Hydroxylations in several positions
aldosterone cortisol
21, 11, 18 17, 21, 11
211811
21
17
11Hydroxylases – cytochrome P450-linkedenzymes, require O2, NADPH
Conversion of cholesterol to sex hormones
1. Side chain cleavage 21 C
pregnenolone
2. Dehydrogenation of 3-OH, moving of double bond from B ringtothe ring A
progesterone
3. Hydroxylations in position 17, side chain removal 18 C testosterone
4. Aromatisation of the ring A, removal of C18 methyl group 17 C
estradiol
Estrogens – only steroids containing aromatic ring
Disorders in steroid hormone synthesis
Secretion of steroid hormones
Synthesis and secretion - elicited by other hormones (peptide hormones placed higher in hierarchyof hormonal regulation of the organism)
Peptide hormone – binds to cell membrane receptor –
activation of adenylate cyclase opening of Ca2+ channels
(mediated by G-protein
cAMP elevation of cytosolic Ca2+
protein kinase A activation
phosphorylation of several enzymes
hydrolysis of stored cholesterol esters, increased transport ofcholesterol into mitochondria, side chain cleavage, hormonesynthesis
Control of secretion of adrenal steroid hormones - glucocorticoids
stress , low level of circulating cortisol
hypothalamus
CRF (=corticotropin-releasing factor)
pituitary
ACTH(= adrenocorticotropic hormone)
adrenal cortex
cortisol (synthesis and secretion)
muscle liver
↑ protein degradation ↑ gluconeogenesis
StAR = steroidogenic acute phase regulatoryprotein – facilitates translocation of cholesterol From outer ro inner mitochondrial membrane –start of hormone biosyntheis
Control of secretion of adrenal steroid hormones - mineralocorticoids
↓ Na+/K+
renin-angiotensin system
angiotensin II, III
adrenal cortex
aldosterone(synthesis and secretion)
kidney tubules
retention of Na+
Control secretion of sex hormones secretion
circulating levels of sex hormones, LH, FSH
GSH (gonadotropin-releasing factor)
Metabolic transformation of steroid hormones= inactivation
Liver - reduction of unsaturated bonds- (hydroxylation) conjugation with glucuronic
or sulfuric acid soluble comounds
excretion
bile kidney
feces urine20-30 % 70-80 %
Mechanism of steroid hormone action
Hormone diffusion across plasma membrane
binding to intracellular receptor hormone-receptor complex
binding to HRE (hormone-response element)= specific regulatory sequence of DNA
initiation of transcription of target gene
translation (synthesis of a protein)
provide a response to a specific steroid hormone
Vitamin D
transformation to active forms = hydroxylation at C25, C1
1,25-dihydroxycholecalciferol =calcitriol = D-hormone
Function:↑↑↑↑ resorption of Ca 2+ in kidney
and intestine↓↓↓↓
induction of the synthesis ofcalcium-binding protein –
transport of Ca 2+ in enterocyte
Precursors: 7-dehydrocholesterol (D3),ergosterol (D2)
skinsun light (UV)
cleavage of B-ring calciferols