Introduction to Human Nutrition

(Sean Pound) #1

102 Introduction to Human Nutrition


and CHD risk in prospective cohort studies. The
activity of the HDL pathway is infl uenced by genetic
and dietary factors that can interact to either increase
or reduce the effi ciency of cholesterol removal. This,
in turn, may be refl ected in changes in the concentra-
tion of serum HDLs and their functional properties.
HDLs are synthesized in the gut and liver, and
increase their particle size in the circulation as a result
of the acquisition of cholesterol from two principal
sources: (1) surface material released from TAG-rich
lipoproteins during lipolysis and (2) peripheral
tissues. The particles, which are responsible for
removing cholesterol from cells, are very small pre-
HDLs and are disk-shaped particles composed of
phospholipid and apoA-I (ApoA-I is capable of this
function on its own). The effl ux of free cholesterol
from tissue sites, including deposits of cholesterol in
the coronary arteries, is facilitated by the formation
of a free cholesterol gradient from the cell across the
cell membrane to pre-HDLs. The gradient is gener-
ated by the re-esterifi cation of free cholesterol by the
enzyme lecithin–cholesterol acyltransferase (LCAT)
and via the migration of these newly formed choles-
terol esters into the hydrophobic core of what becomes
mature, spherical HDL. The newly acquired choles-
terol is transported back to the liver either directly by
HDL or indirectly by transfer to apoB-containing
lipoproteins VLDL and LDL. Blood vessels in the liver
contain a close relative of LPL, i.e., HL. This enzyme
acts on smaller lipoproteins and especially the surface


phospholipid of HDL, where it effectively punches
a hole in the surface coat to facilitate access to the
lipid core and delivery of CE to the hepatocyte
(Figure 6.9).

Interrelationships among serum
triacylglycerols and low- and
high-density lipoproteins
Lipids are constantly moving between lipoprotein
particles. This movement is not totally random but
infl uenced by the relative lipid composition of the
lipoproteins and by specifi c lipid transfer proteins
(LTPs) that act as lipid shuttles. In a normal, healthy
individual, TAG-rich lipoproteins transfer TAG to
LDL and HDL in equimolar exchange for CE. This is
mediated through an LTP called cholesteryl transfer
protein (CETP). In this way, CEs are transferred from
HDL to VLDL for passage back to the liver. Conversely,
when the concentration of serum TAG and thus TAG-
rich lipoproteins is increased, for example by either
the overproduction of TAG in the liver or the impaired
removal of TAG by LPL, the result is a net transfer of
TAG into LDL and HDL. As LDL and HDL are over-
loaded with TAG they become favored substrates for
the action of HL and are remodeled into smaller and
denser particles. While small, dense HDL is catabo-
lized rapidly in the liver, lowering serum HDL and
impairing reverse cholesterol transport, small, dense
LDLs are removed less effectively by LDL receptors
and accumulate in serum. Small, dense LDL, by virtue

Peripheral tissues
(including lesions)

Free

Pre--HDL

LCAT

HDL 3

HDL 2

CETP

Hepatic
lipase

LPL

CE

CE

Liver

LDL VLDL

cholesterol

Figure 6.9 Reverse cholesterol trans-
port. CE, cholesterol ester; CETP, choles-
terol ester transfer protein; HDL,
high-density lipoprotein; LCAT, lecithin–
cholesterol acyltransferase; LDL, low-
density lipoprotein; LPL, lipoprotein
lipase; VLDL, very low-density
lipoprotein.
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