biochemistry of the liver vladimíra kvasnicová. the figure was adopted from (april
TRANSCRIPT
Biochemistry of the liver
Vladimíra Kvasnicová
The figure was adopted from http://faculty.washington.edu/kepeter/119/images/liver_lobule_figure.jpg (April 2007)
The figure was adopted from http://connection.lww.com/Products/porth7e/documents/Ch40/jpg/40_003.jpg (April 2007)
The figure is from: Color Atlas of Biochemistry / J. Koolman, K.H.Röhm. Thieme 1996. ISBN 0-86577-584-2
Central position in energy and intermediary metabolism
• regulation of blood concentration of many metabolites
• regulation of storage and production of energy
• synthesis of molecules for other tissues
• interconversion of nutrients
• storage of some substances
• formation and secretion of bile
a) transformed to fatty acids
b) stored in glycogen molecules
c) oxidized to acetyl-CoA
d) used for production of NADPH
Glucose in the liver can be
Metabolism of saccharides
• glucostatic function of the liver
• glycogen synthesis, glycolysis
• glycogen degradation, gluconeogenesis
• glucokinase, glc-6-phosphatase
• pentose cycle
• Cori cycle and glucose-alanine cycle
• excess of glucose FFA TAG
• transformation of saccharides to glucose
• metabolism of fructose (fructokinase)
• synthesis of amino saccharides
• synthesis of uronic acids
• degradation of insulin and glucagon
Metabolism of saccharides (II)
The figure was adopted from http://connection.lww.com/Products/porth7e/documents/Ch40/jpg/40_004.jpg (April 2007)
a) used for synthesis of TAG
b) transformed to glucose
c) transformed to ketone bodies
d) oxidized to CO2 and H2O
Fatty acids entering the liver can be
Metabolism of lipids
• liver controls blood FFA concentration
• energy is produced mainly by -oxidation
• synthesis of ketone bodies
• synthesis of TAG (from FFA, glc, AA)
• synthesis of cholesterol
• synthesis of bile acids
• synthesis of phospholipids
• synthesis of VLDL and HDL
• degradation of plasma lipoproteins
The figure is from: Color Atlas of Biochemistry / J. Koolman, K.H.Röhm. Thieme 1996. ISBN 0-86577-584-2
The figure was adopted from http://connection.lww.com/Products/porth7e/documents/Ch40/jpg/40_006.jpg (April 2007)
a) the hepatocyte synthesizes chylomicron particles
b) triacylglycerols leave the liver incomporated in VLDL
c) apoproteins are synthesized in the liver
d) LDL transports cholesterol from peripheral tissues to the liver
Choose the correct statement(s) about the metabolism of lipoproteins in the liver:
a) used for synthesis of clotting factors
b) used for synthesis of immunoglobulins
c) transformed to glucose (only glucogenic amino acids)
d) decomposed, urea is one of the main products
Amino acids in the liver can be
Metabolism of N-containing compounds
• synthesis of plasma proteins (except Ig)
• synthesis of coagulation factors
• synthesis of acute phase reactants
• degradation of amino „N“ (urea, Gln)
• synthesis of nonessential amino acids
• metabolism of aromatic AAs
• degradation of purines to uric acid
• synthesis of creatine
• conjugation and excretion of bilirubin
The figure was adopted from http://connection.lww.com/Products/porth7e/documents/Ch40/jpg/40_005.jpg (April 2007)
a) belongs among linear tetrapyrrols
b) is excreted mainly with bile
c) is soluble in water after itsconjugation, e.g. with glucuronic acid
d) is called „direct bilirubin“ if it is bound to albumin
BilirubinNO N
C
N
C
ONH HH
OOO OHH
H
The figure is from: Color Atlas of Biochemistry / J. Koolman, K.H.Röhm. Thieme 1996. ISBN 0-86577-584-2
excretion
The figure was adopted from http://connection.lww.com/Products/porth7e/documents/Ch40/jpg/40_007.jpg (April 2007)
The figure was adopted from the book: Klinická biochemie - požadování a hodnocení BCH vyšetření /J. Masopust (Karolinum 1998)
Causes of hyperbilirubine
mia
1) increased bilirubin formation
2) decreased bilirubin uptake by hepatocyte
3) deficit in conjugation
4) defect of active transport to bile
5) biliary obstruction
causejaundic
eBILI in serum
BILI in urine
UBG in urine
UBG in feaces
prehepatic hemolytic indirect no
hepatic liver
both: indirect
and direct
yes
posthepatic
obstructive
direct yes no no
indirect = unconjugated = insoluble in water (= fat soluble) = bound to albumin
direct = conjugated = soluble in water
Metabolism of vitamins
• provitamins vitamins, storage of vitamins
• carotenes vitamin A
• 25-hydroxylation of provitamin D (→ calcidiol)
• cleavage of side chain of vitamin K
• storage of vitamin B12
• synthesis of nicotinic acid from Trp
• formation of coenzymes from B vitamins
Metabolism of minerals
• storage of iron (ferritin)
• storage and metabolism of other trace elements(Cu, Mn, Co, Mo, Zn,..)
• synthesis of transport proteins(transferrin, ceruloplasmin)
• deiodation of thyroidal hormones → I- (iodide)
Metabolism of hormones
• degradation and excretion
(see 3rd semester)
Metabolism of xenobiotics
• see next seminar
The figure was adopted from http://www.tharu.com/academic/html/newcastle/liver.htm
(April 2007)
Metabolic pathways in
different zones of the liver lobule
a) periportal hepatocytes - higher pO2:
• more mitochondria, less ER
• blood contains a lot of O2 and nutriens
• more of oxidative reactions
• antioxidative defense (glutathion)
• CC, RCH, oxidative phosphoryl., -oxidation
• urea synthesis
• glukoneogenesis
• cholesterol synthesis
• proteosynthesis
b) perivenous hepatocytes - lower pO2:
• blood contains few O2 and nutriens
• more of reductive reactions
• synthesis of lipids
• glycogen synthesis
• ketogenesis
• biotransformation of xenobiotics (sm. ER)
• detoxification of NH3: synthesis of Gln
Glutamine cycle
in the liver
The figure was adopted from: Devlin, T. M. (editor): Textbook of Biochemistry with Clinical Correlations, 4th ed. Wiley‑Liss, Inc., New York, 1997. ISBN 0‑471‑15451‑2
a) gluconeogenesis
b) ketogenesis
c) synthesis of urea
d) synthesis of bile acids
Choose the mtb pathway(s) proceeding only in the liver:
a) ALT participates in a metabolismof amino acids
b) ALP belongs among esterases
c) LD needs NADH as a coenzyme
d) AST catalyzes one of reactionsof a pentose cycle
Choose correct statement(s) about enzymes of hepatocytes
• total bilirubin (‹ 22 M)
• ALT (‹ 0,75 kat/L)
• AST (‹ 0,75 kat/L)
• ALP (‹ 2,29 kat/L)
• GMT (men: 0,25-1,77, women: 0,17-1,10 kat/L)
the values are used in FNKV
Liver tests