Lipid Circulation PDF

Summary

This document discusses intracellular and extracellular lipid circulation, focusing on lipoproteins. It details lipoprotein classes, their composition and roles in lipid transport and metabolism. It also covers regulation of cholesterol synthesis, including the role of HMG-CoA reductase. The document includes detailed descriptions of lipoproteins, their interactions, and the various receptors involved.

Full Transcript

Circulació Intracel.lular i
Extracel.lular de Lípids

Tema 4
 Lipoproteïnes
Cholesterol is in blood at a concentration 106 x its solubility in water.
How is this accomplished?
 Lipoproteïnes

Lipoprotein Density Diameter Protein % Phospholi Triacylglycerol
class (g/mL) (nm) of dry wt pid % % of dry wt
HDL 1.063-1.21 5 – 15 33 29 8

LDL 1.019 – 18 – 28 25 21 4
1.063

IDL 1.006-1.019 25 - 50 18 22 31

VLDL 0.95 – 1.006 30 - 80 10 18 50

chylomicrons < 0.95 100 - 500 1-2 7 84
Lipoproteïnes
Lipoproteïnes
Lípids transportats per Lipoproteïnes
Lipoproteïnes
Metabolisme de les lipoproteïnes
Lipoproteïnes: Quilomicrons
Lipoproteïnes: Quilomicrons
Lipoprotein lipasa
 Lipoproteïnes

ApoC-II activates
lipoprotein lipase which
catalyses the hydrolysis
of TG
Lipoproteïnes: VLDL
Lipoproteïnes: VLDL
Lipoproteïnes
Lipoproteïnes: LDL
 VLDL Remnant
Uptake

The remnant particle (IDL),
if it contains apoE, can be
taken up by the
apoE/remanant receptor
Lipoproteïnes: LDL
 Lipoproteïnes: LDL

LDL is removed by
apoB100 receptors
which are mainly
expressed in the
liver

Hepatic Lipase
Cholesteryl ester
transfer protein
Representation of the
LDL receptor (839 aa)

extracellular domain is
responsible for apo-B-
100/apo-E binding

intracellular domain is
responsible for
clustering of LDL
receptors into coated
pit region of plasma
membrane
 Lipoproteïnes: receptor LDL
Brown and Goldstein
Nobel in Medicine, 1985

Michael Brown Joseph Goldstein
Lipoproteïnes: HDL

Surface Monolayer
Phospholipids (25%)
Free Cholesterol (7%)
Protein (45%)

Hydrophobic Core
Triglyceride (5%)
Cholesteryl Esters
(18%)
Lipoproteïnes: HDL
 Lipoproteínas: HDL

Particle Shape Apolipoprotein Composition
Discoidal

Spherical
A-I HDL A-I/A-II A-II HDL
HDL

Particle Size Lipid Composition
TG, CE, and PL

HDL2b HDL2a HDL3a HDL3b HDL3c
Rye KA et al. Atherosclerosis 1999;145:227-238.
 HDL Maturation
HDL is secreted in a
discoidal form from the liver
and gut.

As it acquires cholesterol
from tissues in the
circulation, it matures into a
spherical form through the
action of lecithin:cholesterol
acyl transferase
Transport del colesterol
 ABCA1

SR-BI
Hiperlipidaemies
 HDL is Protective

120 110
186 events in 4,407
per 1,000 (in 6 years)

100 men (aged 40–65 y)

80
Incidence

60

40 30
21
20

0
< 35 35–55 > 55
HDL-C (mg/dL)

Assmann G, ed. Lipid Metabolism Disorders and Coronary Heart
Disease. Munich: MMV Medizin Verlag, 1993
The atherogenic lipoprotein phenotype
Digestió del colesterol
 Funcions del colesterol

Membrane component

Steroid synthesis

Bile acid/salt precursor

Vitamin D precursor
Molècula de colesterol
Síntesi de colesterol
Síntesi de colesterol
Síntesi de colesterol
HMG-CoA reductasa
Fosforilació de l’HMG-CoA reductasa
 Regulació de la Síntesi de colesterol

Transcriptional regulation
– SREBP-2
– Responds to cellular levels of sterols
 Regulació de la Síntesi de colesterol

SREBP cleavage
activating protein
Regulació de la Síntesi de colesterol
Site 1 and site 2 protease -
Model for conformational change in SCAP [sterol regulatory element-binding protein
(SREBP) cleavage-activating protein]. (a) In membranes from sterol-deprived cells, trypsin
cleaves SCAP on its N-terminal side at R496. Two point-mutations, Y298C and D443N,
render the sterol-sensing domain of SCAP resistant to the cholesterol-induced
conformational change. (b) Addition of cholesterol created a new trypsin cleavage site at
R503 and R505, whereas the trypsin cleavage site on the C-terminal side of SCAP occurs
within the same cluster of arginines (R747–R750) both in the absence and presence of
cholesterol. The conformational change in SCAP might be produced by intramembranous
cholesterol interaction with the transmembrane helices of the sterol-sensing domain.
Reproduced, with permission, from Ref.
 Regulació de la Síntesi de colesterol
HMG-CoA reductase, which
catalyzes the committed reaction
in cholesterol biosynthesis is a
primary target for regulation

dietary cholesterol suppresses
the endogenous synthesis of
cholesterol at both
transcriptional and translational
levels

HMG-CoA reductase is also
regulated hormonally, by insulin
and glucagon at the
transcriptional level

in vertebrates, the rate of
endogenous cholesterol
synthesis is controlled by
coordination with the rate of
cholesterol use by cells and by
dietary intake
Inhibidors de l’HMG-CoA reductasa