Lipids and Lipoproteins PDF

Summary

This document provides an overview of lipids and lipoproteins, including their metabolism and associated disorders. Diagrams, chemical structures, pathway maps of lipid metabolism are included in the presentation (PPT).

Full Transcript

Lipids and
lipoproteins
Metabolism and associated disorders
 Intro to Lipids
Unlike the other major biomolecules that are defined
by their chemical properties, lipids are defined by their
physical properties
Lipids are soluble in organic solvents but are nearly
insoluble in water
Primarily contain nonpolar carbon-hydrogen (C-H)
bonds and yield fatty acids and/or complex alcohols
after hydrolysis
 Intro to lipids
They are found
throughout the body as
structural components,
hormones, and nerve
insulators
The clinical significance
of lipids is their link to
coronary heart disease
(atherosclerosis),
cardiovascular disease,
and lipoprotein
disorders
Broadly subdivided

1) Cholesterol
2) Fatty acids
3) Acylglycerols
4) Sphingolipids
5) Prostaglandins
6) Terpenes
 Cholesterol

12 17
11 13
D 16
C 14 15
1 9
2 10
A B 8
3 5
4 6 7
HO

Found almost exclusively in animals
Key membrane component of cells, and a
precursor in the synthesis of bile acids and
steroid hormones
A,B,C,D = Cyclopentanoperhydrophenanthrene
(steroid alcohol)
Cholesterol Absorption

Derived from animal and dairy
products in our diet
Only ~30% to 60% is absorbed
Acted upon by cholesterol
esterases secreted from the
pancreas and small intestine
Delivered to the liver and
peripheral tissues by
chylomicrons (more on those
later)
Cholesterol
Synthesis
Made by all cells
in the body, but
particularly by
the liver and
intestine.
Occurs in 3
stages, beginning
with acetyl CoA,
to produce the
27- carbon
molecule

https://epomedicine.com/medical-students/cholesterol-synthesis-mnemonic/
Cholesterol synthesis (basic steps)

Acetyl CoA mevalonic acid
(mevalonate) squalene (structure
before rings close) Lanosterol (rings
close) cholesterol
bile salts
steroid
hormones
Vitamin D production
Cholesterol synthesis (Complex steps)

Acetyl-CoA 3-Hydroxy-3-methylglutaryl-CoA
HMG-CoA
reductase

Squalene Mevalonate

Cholesterol + Cholesterol
Lecithin ester

“Statin” drugs inhibit this enzyme
Cholesterol Esterification
Esterified to a fatty acid to form cholesteryl ester by
2 different enzymes
In cells, esterified by acylcholesterol acyltranferase
(ACAT) then stored in intracellular lipid drops
In plasma, lecithin cholesterol acyltranferase (LCAT)
will esterify cholesterol
Cholesterol esters account for ~70% of total
cholesterol in plasma
In this form, cholesterol loses its free hydroxyl group
and becomes more hydrophobic
Cholesterol Catabolism
Majority of catabolism occurs in the liver
Remainder is used to synthesize steroid hormones
by specialized endocrine cells
~1/3 of daily production is converted into bile
acids
Much of the rest is re-secreted into circulation on
lipoproteins, with the remainder excreted into bile
unchanged.
When amount of cholesterol exceeds capacity, it
is possible for it to precipitate and form gall
stones
 Fatty acids
RCOOH is the general formula
Classified by chain length as well as degree of
saturation
Saturated FA’s have no double bonds (C=C) between
carbon atoms
Monounsaturated contain one double bond
Polyunsaturated contain multiple double bonds
Most FAs are synthesized by the body except essential
FAs
 FA catabolism
Catabolized in the mitochondria
Produce energy by a series of reactions known as ß-
oxidation
Process is repeated to shorten the FA chain by 2 carbon
atoms at a time
Ex. A 16 carbon FA is converted into 8 molecules of a 2-
carbon sugar, Acetyl CoA
Acetyl CoA will condense with oxaloacetate to yield
citrate and enter the Krebs cycle
Acylglycerols (Glycerol Esters)
Glycerol is a 3-carbon alcohol
Class of acylglycerol is determined by the number of
fatty acyl groups present:
One fatty acid- monoacylglycerols
Two FA- diacylglycerol
Three FA- triacylglycerol a.k.a triglycerides
 Triglycerides (triacylglycerol)

Constitute 95% of tissue storage
fat
Predominant form of glycerol
esters found in plasma
Generally, triglycerides from
plant sources tend to be
enriched in unsaturated FAs and
are liquids at room temp
Those from animals tend to have
saturated FAs and are solids at
room temp
 Sphingolipids
Derived from the amino alcohol sphingosine
It is an intermediate structure in the formation of:
Sphingomyelin
Galactosylceramide
Glucosylceramide
Involved in the recognition of cells as self and in
recognition of blood group antigens
Also used to form complex globosides and gangliosides,
the latter of which is abundant in the membranes of grey
matter of the brain
 Prostaglandins
Represents about 20 different tissue
hormones
These hormones are synthesized at the
sight of reaction and have a short life
(rapidly catabolized)
Involved with smooth muscle
contractions, glandular secretion
Made from arachidonic acid (a 20 –
carbon unsaturated fatty acid)
 Terpene
s
Made from 5 –carbon isoprene units
to make other fat-soluble vitamins
(vitamins A, E, K).
Used to make carotenoids - red,
yellow, orange plant pigments.
Beta-carotene
Blood Lipids – Lipoproteins
Chylomicrons
VLDL
IDL
LDL
HDL
Lipoprotein (a)- LP(a)

Lipoproteins are spherical
micelle-like particles with
nonpolar neutral lipids
(triglycerides and cholesterol
esters) in their core and more
polar amphipathic lipids at their
surface.
They also contain one or more
specific proteins, called
apolipoproteins, on their surface
Classification

Have different physical and chemical properties
because they contain different proportions of lipids
and proteins
Traditionally categorized based on differences in
their densities
In general, the larger lipoproteins contain more core
lipids in their core (triglycerides and cholesterol
esters) and hence are lighter in density
Relative Sizes of Lipoproteins

VLDL

(50%) Relative sizes of the
Chylomicron four main types of
LDL
lipoproteins and their
(85%) (10%) relative triglyceride
content.
HDL

(4%)
Composition of Chylomicrons
Chylomicron (% by mass)

7%
triglycerides
2% phospholipids
3% protein
cholesterol esters
2%
86% cholesterol
Composition of VLDLs

VLDL (% by mass)

3%
7%

12%
triglycerides
phospholipids
50% protein
10% cholesterol esters
cholesterol
other

18%
Composition of ldls

LDL (% by mass)

8% 10%

20% triglycerides
phospholipids
protein
38% cholesterol esters
cholesterol

24%
Composition of hdls

HDL (% by mass)

2 % 4%
15%

24%
triglycerides
phospholipids
protein
cholesterol esters
cholesterol

55%
Lipoproteins

Chylomicron:
Transports lipids from the intestinal mucosa to the tissues
via the lymph system and circulatory system
In the blood stream, triglycerides are hydrolyzed to
monoglycerides and fatty acids which are absorbed by
the tissues.
The remnants carry cholesterol to the liver.
Very Low-Density Lipoprotein (VLDL):
Transports triglycerides from the liver to the tissues.
In the blood stream, triglycerides are hydrolyzed to
monoglycerides and fatty acids which are absorbed by
the tissues.
The remnants are LDL and some IDL (intermediate
density lipoprotein)
Lipoproteins
Low Density Lipoprotein (LDL):
Transports cholesterol and cholesterol esters to the
tissues.
LDL is absorbed through receptor-mediated endocytosis
where the cell hydrolyzes the cholesterol esters, any
remaining triglycerides, and the protein.
High Density Lipoprotein (HDL):
HDL removes excess cholesterol in the form of cholesterol
esters from tissues and transports it to the liver.
It is sometimes called the “good cholesterol”, because it
helps to impede the accumulation of artheroscleotic
plaque on blood vessel walls.
Lipoprotein (a)- LP(a)

Distinct class of lipoprotein that is structurally
related to LDL but contains a carbohydrate protein
apo(a)
Plasma levels are mostly genetically determined
Lp(a) is particularly proatherogenic and has been
associated with aortic stenosis
Currently no adequate drug or dietary therapy for
lowering levels
APOLIPOPROTEINS
The protein
composition
differs from
one
lipoprotein
class to
another, and
the protein
constituents
are called
Apolipoprotein
Functions of apolipoproteins
Activate enzymes involved in
lipid metabolism
Maintain structural integrity of
lipid/protein complex
Delivery of lipids to cells via recognition
of cell surface receptors (APO B)
Apolipoprotein content of LPs

Lipoprotein Apolipoprotein(s)
Chylomicron AI, B-48, CI, CII, CIII
VLDL B-100, CI, CII, CIII, E
IDL B-100, E
LDL B-100
HDL AI, AII
Metabolism of
lipoproteins
Exogenous Pathway

In mouth = nothing happens
Stomach = emulsification begins by churning
action, and gastric lipases which produce some
diacylglycerols and fatty acids
Small Intestine =
1. Emulsification by bile salts (from bile duct)
which act like a soap causing large droplets to
become small droplets. This creates more
surface area for lipase contact. This is NOT a
chemical reaction.
Absorption of Lipids

2. Hydrolysis reaction by pancreatic
lipase and some intestinal mucosal
lipases. Triglycerides become mono and
di glycerides; cholesterol esters become
free cholesterol; phospholipids become
lysophospholipids
The breakdown products of fats form large
aggregates with bile acids called micelles.

Absorption occurs when the micelles
encounter the microvilli of the
intestinal cells
The micelles are re-esterified in
intestinal cells (golgi apparatus) to
form triglycerides and cholesteryl
 These fats are
packaged into
chylomicrons,
which are large
micelles containing
a core of the fats
surrounded by a
shell of
phospholipids,
apolipoproteins,
and free
cholesterol. This
outer shell is polar
in structure, which
helps for
Chylomicrons
Leave mucosal cells to enter lacteals (lymph
capillaries), which are more porous, where
they are carried in lymph to the thoracic
duct, which empties into the blood stream
(at the left subclavian/jugular vein junction).
Subclavian from the arm
Jugular from the neck
Junction is at the collar bone
The chylomicrons make their way to the
liver, adipose tissue, and other organs as
needed.
 Exogenous Pathway

After entering circulation, chylomicrons interact with
proteoglycans
Proteoglycans promote the binding of LPL (lipoprotein
lipase) which hydrolyzes triglycerides
Triglycerides are hydrolyzed back into FAs and glycerol
so they can be used as an energy source for cells
Excess FAs are re-esterified into triglycerides for long-
term energy storage in adipocytes
Endogenous Pathway
Function is to transfer hepatically derived lipids
(synthesized by the liver, or dietary lipids that were
transferred) to peripheral cells for energy metabolism
Mediated by the apo B-100 containing lipoproteins
VLDL is the molecule responsible for more of the
transport of lipids from the liver to the cells
Upon reaching the cells, LPL (lipoprotein lipase) will
breakdown the VLDL to release the lipids for energy
usage
Intracellular-cholesterol transport
pathway
Represents the mechanisms that cells use to maintain
cholesterol balance- excess cholesterol is toxic to cells
All cells receive cholesterol via uptake of extracellular
lipoproteins
Cholesterol delivered to the cells is
1) Used for membrane biogenesis
2) Stored in intracellular lipid drops
3) Carried from the cell via reverse-cholesterol transport
pathway
Reverse-cholesterol transport
pathway
Purpose is to remove excess cellular cholesterol from
peripheral cells and return it to the liver for excretion
Largely mediated by HDL → secreted from the liver as
crescent-shaped molecules containing mostly
phospholipids and apo A-I
Gain their spherical shape in the extracellular space
Control of Lipids in the Body
 Lipid metabolism is a constant state of
dynamic equilibrium; some lipids are
constantly being oxidized to meet energy
needs, while others are being synthesized
and stored.
A delicate balance between two
antagonistic processes adjusts body fat
storage: lipogenesis produces fat stores
and lipolysis mobilizes fat
Fat Mobilization
Pulling lipids out of storage
Making new fats
Opposite from digestion

Lipolysis: hydrolysis of lipids

Triglycerides + water lipase> glycerol + 3
fatty acids
Glycerol (gluconeogenesis)

Glycerol glycerol-3-phosphate DHAP PGAL
glucose
DHAP = dihydroxy acetone
phosphate

PGAL =
phosphoglyceraldehyde
 Fatty Acid – Beta oxidation

ß-oxidation is a 4-step biochemical
pathway
Fatty acids are chopped 2 carbons at a
time resulting in production of acetyl
CoA for Kreb’s cycle and electron
transport chain

i.e., 16 carbons will result in 8 acetyl
CoA’s
 Step 1: Oxidation and FADH2 is produced

Step 2: Hydration

Step 3: Oxidation and NADH produced

Step 4: Carbon-carbon bond broken – shortens chain by
two carbons and produces Acetyl CoA
 Ketogenesi
s
Too much beta oxidation of fat.
Occurs when body needs energy, but
no carbs are stored so excess Acetyl
CoAs are produced
2 Acetyl CoAs condense into ketone
bodies, since they can’t enter the
Kreb’s cycle fast enough
Result: ketoacidosis and drop with
blood pH
Energy Yield: Fat vs.
Carbohydrate

Per carbon, fat yields more energy
than sugar, carbons are more
reduced (saturated) therefore more
oxidation steps are possible
Fat Metabolism OR
Lipogenesis
Making lipids from:
1.AcetylCoA fatty
acids
Where? Not in the mitochondria, but in the
Endoplasmic Reticulum. The reducing agent
isn’t NADH or FADH, but NADPH from the HMP
shunt.
Very different pathway (not an exact
reversal of beta- oxidation). Reverse
reactions such as reduction and
dehydration.
Why? Don’t want to utilize a pathway where
NADH/FADH are used, as they would then be
Making lipids from:
2. DHAP glycerol 3-phosphate
glycerol

How? DHAP is a product of fructose split
from PGAL.

Why? Glycerol now available to bind with
3 fatty acids to produce a new triglyceride