Biochemistry: Cholesterol and Steroid Metabolism PDF

Summary

This document provides an outline of plasma lipoproteins, including their composition, structure, and function. It also covers the digestion of lipids, CM, VLDL, LDL, and HDL metabolism, the role of lipoprotein (a) in heart disease, and various disorders of lipoprotein metabolism.

Full Transcript

BIOCHEMISTRY
Cholesterol and Steroid Metabolism
BRENDO V. JANDOC, M.D.
1A
OUTLINE
PLASMA LIPOPROTEINS
A. Composition of Plasma Lipoproteins
B. Structure of Plasma Lipoproteins
C. Digestion of Lipids
CM METABOLISM
VLDL METABOLISM
LDL METABOLISM
HDL METABOLISM
ROLE OF LIPOPROTEIN (A) IN HEART DISEASE
DISORDERS OF LIPOPROTEIN METABOLISM

lipid composition, protein composition, size,
Differ in
density
PLASMA LIPOPROTEINS
keep lipids soluble as they transport them to
spherical macromolecular complexes of lipids
plasma
Description and specific proteins (apolipoproteins or
provide an less perfect in humans
apoproteins)
efficient than in animals > gradual
Bond noncovalent
Function mechanism for deposition of lipids
hydrophobic interior containing
delivering their (especially cholesterol) in
triacylglycerols and cholesteryl esters
Composition lipid content to tissues > plaque formation
encased in an amphiphilic outer layer of
the tissues > narrowing of blood
protein, phospholipid, and cholesterol
vessels (atherosclerosis)
Synthesis, degradation, removal from the
Constant rate of
plasma
Principal Lipids TAG, cholesterol (free, esterified)
Include
Carried
Site of Plasma Function
formation Lipoproteins
Carry dietary
triacylglycerol, cholesterol,
Chylomicrons
Intestines fat-soluble vitamins, and
(CM)
cholesteryl esters to the
peripheral tissues
Very Low Transports triglyceride
Density from liver to adipose
Liver
Lipoproteins tissue
(VLDL)
Transports triglyceride,
Low Density cholesterol, and
Plasma Lipoproteins phospholipids from liver to
Neutral Lipid contains TAG or
(LDL) tissues and organs like
Core cholesteryl esters or both
heart
-apolipoproteins
Transports triglyceride,
(apoproteins)
High Density cholesterol, and
-phospholipid
Liver Lipoproteins phospholipids from tissues
Composition Surrounding -nonesterified cholesterol
(HDL) and organs like heart back
Shell (of -polar portions are
to liver
Amphipathic) exposed on the surface
Intermediate Transports triglyceride,
of the lipoproteins >
Density cholesterol, and
soluble in aqueous
Plasma phospholipids from liver to
Lipoproteins solution
(IDL) peripheral tissues
constantly interchange lipids and
apolipoproteins with each other >
Lipoprotein Particles
variable actual apolipoprotein and lipid
content of each class of particles
TAG and Cholesterol - from the diet (exogenous)
Carried - de novo synthesis (endogenous)

Trans 6 |ABACCO, ASSISTIN, ALDERITE, BALANZA, BAYAS, BIANG 1 of 12
 BIOCHEMISTRY
Fatty Acid and Triacylglycerol Metabolism
A. Composition of Plasma Lipoproteins - activators or coenzymes for
1. Size and Density (by - determined by floatation rate on enzymes involved in lipoprotein
Ultracentrifugation) of centrifuge in 1.063 d NaCl solution metabolism
Lipoprotein Particles - the densities of lipoprotein classes - functions of all of the
increase as the quantity of lipid apolipoproteins are not yet known
contained in the core b. Classification by most classes having subclasses
decreases Structure and Function
B. Structure of Plasma Lipoproteins
5 Fractions
a. CM - lowest in density
- largest in size
- highest percentage of lipid
- smallest percentage of protein
b. VLDL, LDL - successively more dense
- higher content of protein
- lower content of lipid
c. HDL - most dense
d. IDL

1. Sphere - with the protein plus the
amphipathic lipid
(phosphatidylcholine and
unesterified cholesterol) forming
an outer shell
- different classes have
characteristic lipid : protein ratios
- different lipid classes are
associated with apoproteins

a. Apolar Segments directed inward
b. Polar Segments face water outside
c. Nonpolar Lipids - form the inside of the sphere
- include triglyceride and esterified
cholesterol
C. Digestion of Lipids
2. Electrophoretic Mobility plasma lipoproteins migrating with 1. Triacylglycerol major dietary lipid of nutritional
α-and β-globulins of plasma value
2. Emulsification
a. Acid Chyme - from the stomach
- enters the duodenum
- stimulates secretion of enteric
hormones (small peptides) by the
duodenal mucosa
b. Bile Salts and amphipathic structures > act as
Phosphatidylcholine detergents in the duodenum > aid
in the formation of mixed micelles
3. Apoproteins may be transferred freely between
(large surface area) from fat
lipoproteins
globules (small surface area)
a. Diverse Functions - structural components of the
c. Micellar Associations of substrates for hydrolyzing enzymes
particles
Lipids
- provide recognition site for cell-
3. TAG Hydrolysis by 3 Lipid-Specific Enzymes
surface receptors

Trans 2 |ABACCO, ALDERITE, ASSISTIN, BALANZA, BAYAS, BIANG 2 of 12
 BIOCHEMISTRY
Fatty Acid and Triacylglycerol Metabolism
a. Pancreatic Lipase cleaves TAG > 2-MAG + 2 free fatty 100 > nonsense codon > translation
acids of only 48% of the mRNA > apo B-48
i. Lipoprotein Lipase - negatively charged extracellular
enzyme
- resides on the capillary walls of
most tissues
- found predominantly in the
capillaries of the adipose tissue and
cardiac and
skeletal muscles
- activated by apoC-II on circulating
lipoprotein particles
- hydrolyzes the TAG contained on
the circulating lipoprotein particles
ii. Lipoprotein Lipase or dramatic accumulation of TAG-rich
ApoC-II Deficiency lipoproteins in the plasma
ex: type I hyperlipidemia (familial
hypercholesterolemia) 2. CM Assembly - apolipoprotein synthesis begins in
b. Cholesterol Esterase hydrolyze cholesterol esters > the rough ER
cholesterol + fatty acid - enzymes involved in TAG,
c. Phospholipase A2 hydrolyze phospholipid cholesterol and phospholipid
synthesis are located in the smooth
ER
- assembly of apolipoproteins and
lipid into CM occurs during transition
from the ER to the Golgi apparatus >
packaged in secretory vesicles >
exocytosis > lymphatic system >
blood
- requires microsomal TAG transfer
protein
- loads apo B-48 with lipid
3. Modification of - functionally incomplete
Nascent CM Particles - particles released by intestinal
mucosal cells
CM METABOLISM - contains apolipoprotein B-48 (apoB-
assembled in intestinal mucosal cells 48)
are TAGs given a coat - protein - when reaches the plasma >
composed of - phospholipids modified by receiving apoE (in
- cholesterol esters conjunction with apoB-48, is
diameter 0.2 - 1. um recognized by hepatic receptors) and
carry to the peripheral - dietary TAG C apolipoproteins (including apoC-II,
tissues - cholesterol necessary for the activation of
- cholesteryl esters lipoprotein lipase, the enzyme that
- fat soluble vitamins degrades the TAG contained in the
1. Synthesis of Apolipoproteins CM)
a. Apolipoprotein B-48 - synthesis begins on the rough ER i. HDL - source of the apolipoproteins
(Apo B-48) - glycosylated as it moves from the
ER and Golgi
- unique to chylomicrons
- constitutes the N-terminal 48% of
the protein coded for by the apo B
gene
b. Apolipoprotein B-100 - synthesized by the liver
- found in VLDL & LDL
- represents the entire protein coded
for by the apo B gene
- post-transcriptional editing of a
cytosine to uracil in intestinal apo B-

Trans 2 |ABACCO, ALDERITE, ASSISTIN, BALANZA, BAYAS, BIANG 3 of 12
 BIOCHEMISTRY
Fatty Acid and Triacylglycerol Metabolism
- allows heart continuing access to
circulating fuel even when plasma
lipoprotein concentrations are low
6. Formation of CM CM in membrane-bound vesicles >
Remnants lateral cell membranes of mucosal
cells > exocytosis > extracellular
space > plasma
a. As the CM Circulates - TAG (lipids) in its core is degraded
by lipoprotein lipase (delipidation) >
decreased
size, increased density
- C apolipoproteins return to HDLs
- remaining particle is a “remnant”
b. In Humans CM remnants are removed by the
4. TAG Degradation by Lipoprotein Lipase liver
a. Lipoprotein Lipase - extracellular enzyme c. Lipoprotein Receptor - in hepatocyte membranes
- anchored by heparan sulfate to - recognize the combination of
capillary walls of most tissues apolipoproteins B-48 and E
predominantly in adipose tissue, - bind CM remnants > taken up by
cardiac muscle, skeletal muscle hepatocytes by endocytosis > fuse
- not present in adult liver with lysosome > hydrolysis of
- activated by apo C-II on circulating apolipoproteins, cholesteryl esters,
lipoprotein particles > hydrolyze TAG other components of the remnants >
in the particles > fatty acids + release of amino acids, free
glycerol cholesterol, fatty acids
ai. Fatty Acids - stored by the adipose or - cholesterol released (> decreases
- used for energy by the muscle cell content of HMG-CoA reductase
- if not taken up by a cell > (also allosterically inhibit the enzyme)
transported by albumin > regulates
aii. Glycerol - used by the liver for lipid synthesis, the rate of de novo cholesterol
synthesis in the liver) > bile
glycolysis, gluconeogenesis
acid synthesis
Type I Hyperlipoproteinemia
- fatty acid released > phospholipid
(Familial Lipoprotein Lipase Deficiency)
biosynthesis
deficiency of - lipoprotein lipase or
- recycling of receptor
- apo C-II
d. Physiologic Role of deliver dietary fat to the liver
chylomicron accumulation (1000 mg/dl or greater) in the plasma
CM Remnants
(hypertriacylglycerolemia) even in the fasted state
b. Hepatic Lipase - on the surface of hepatic
endothelial cells
- does not significantly attack
chylomicrons or VLDL TAG
- assists with HDL metabolism
5. Lipoprotein Lipase Activity Regulation
a. Insulin - signifying fed state
- stimulates lipoprotein lipase
synthesis and transfer of lipoprotein
lipase to the luminal surface of the
capillary
b. Isomers of different Kms for TAG
Lipoprotein Lipase
i. Adipose Enzyme - large Km
- allows removal of fatty acids from
circulating lipoprotein particles >
stored as TAG when plasma
lipoprotein concentrations are
elevated
ii. Heart Muscle - small Km
Lipoprotein Lipase

Trans 2 |ABACCO, ALDERITE, ASSISTIN, BALANZA, BAYAS, BIANG 4 of 12
 BIOCHEMISTRY
Fatty Acid and Triacylglycerol Metabolism
VLDL METABOLISM - observed during the transition
a. VLDLs - produced in the liver from VLDL to LDL in the plasma
- composed predominantly of TAG (initial
- carry TAG from the liver to the product of VLDL degradation in the
peripheral tissues > degraded by plasma)
lipoprotein lipase - can also be taken up by cells
b. Fatty Liver (Hepatic imbalance causes through receptor-mediated
Steatosis) between - hepatitis endocytosis that uses
hepatic - obesity apo E as the ligand
TAG - uncontrolled DM b. Apo E
synthesis and - chronic ethanol 3 Isoforms
VLDL ingestion - bind poorly to receptors
secretion - homozygosis to apo E2 >
1. VLDL Release - released from the liver as deficiency in the clearance of
nascent VLDL particles containing chylomicron remnants and IDLs >
E2
apolipoprotein B-100 and A-I familial type III
- must obtain apoC-II (required for hyperlipoproteinemia (familial
activation of lipoprotein lipase) and dysbetalipoproteinemia or broad
apoE from circulating beta disease)
HDL E3
a. Abetalipoproteinemia - rare hypolipoproteinemia - confers increased susceptibility to
- defect in microsomal TAG E4 late-onset Alzheimer
transfer protein > inability to load disease
apo B with lipid > no chylomicrons
or VLDLs formed > TAGs
accumulate in the liver and
intestines
2. Circulating VLDL - VLDL > circulation > altered
Modification structure
- TAG is removed by lipoprotein
lipase > decreased size, more
dense
- surface components (C and E
apolipoproteins) are transferred to
HDL by exchange reaction (TAG or
phospholipid from VLDL to HDL)
- accomplished by cholesteryl ester
transfer protein
- the particles retain apo B-100

LDL METABOLISM
a. LDL - retain apoB-100
- lose their other apolipoproteins to
HDL
- contain much less TAG than VLDL
- have high concentration of cholesterol
and cholesteryl esters
- transport cholesterol esters
throughout the body

3. LDL Production from after the VLDL modifications > LDL
VLDL in the Plasma
a. IDL (VLDL Remnant) - intermediate (density) sized
particle

Trans 2 |ABACCO, ALDERITE, ASSISTIN, BALANZA, BAYAS, BIANG 5 of 12
 BIOCHEMISTRY
Fatty Acid and Triacylglycerol Metabolism
endosome (LDL stay free in the vesicular
lumen) > formation of a new structure
called CURL (Compartment for
Uncoupling of Receptor and Ligand)
Receptors Recycled
i. Number of Receptors - availability of these lipoprotein
for Lipoproteins Varies particles
According to the - needs of the cell
ii. Lipoprotein transferred to lysosomes > degradation
Remnants in the Vesicle by lysosomal (hydrolytic) enzymes
> release of free cholesterol, amino
acids, fatty acids, and phospholipids >
reutilization by the cell
iii. “Down-Regulation” if there is a large amount of particular
circulating plasma lipoprotein >
number of cell-surface receptors for it
decreases
iv. “Up-Regulation” if cells are starved with cholesterol >
increase the number of cell-surface
receptors
v. Wolman disease - rare; autosomal recessive
- inability to hydrolyze lysosomal
cholesteryl esters
vi. Niemann-Pick - rare; autosomal recessive
disease type C - inability to transport unesterified
cholesterol out of the lysosome
2. Effect of CM remnant-, IDL-, and LDL-derived
Endocytosed cholesterol affects cellular cholesterol
1. Receptor-Mediated Endocytosis
Cholesterol on content through
a. Primary Function of bind to receptors on cell-surface Cellular Cholesterol
LDL Particles membranes that recognize Homeostasis
apolipoprotein B-100 > deposit free
a. Increased inhibition of HMG-CoA reductase
cholesterol on the membranes of cells
Cholesterol Content activity > decreased de novo
> provide cholesterol to peripheral
cholesterol
tissues
synthesis
LDL Receptors - negatively charged glycoprotein
b. If Cholesterol is Not esterified by acyl CoA : cholesterol
molecules
Required Immediately acyltransferase (ACAT)
- clustered in pits on cell membranes
(for Some Structural or
i. Clathrin - protein coating the intracellular side Synthetic
of the pit Purpose)
- stabilizes the shape of the pit
i. ACAT - transfers a fatty acid from a fatty acyl
ii. Deficiency of - significant elevation of plasma LDL CoA derivative to cholesterol >
Functional LDL (and therefore plasma cholesterol) cholesteryl ester formation > stored in
Receptor - plasma TAG remains normal the cell
- greatly accelerate the progress of - activity is enhanced in the presence of
atherosclerosis increased intracellular
- ex: type II hyperlipidemia (familial cholesterol
hypercholesterolemia)
iii. Triiodothyronine (T3) have positive effect on the binding of
LDL to its receptor
iiia.
Hypothyroidism hypercholesterolemia
LDL Internalization as intact particles by endocytosis
Vesicle Containing rapidly losses clathrin coat > fuses with
LDL other vesicles > endosome (larger
vesicle)
c. Decreased LDL Gene - lowered new LDL receptor protein
Proton-Pumping pH endosome contents decrease >
Transcription synthesis > further entry of LDL
Activity of Endosomal separation of LDL from its receptor >
cholesterol limited
ATPase receptor migrates to 1 side of the

Trans 2 |ABACCO, ALDERITE, ASSISTIN, BALANZA, BAYAS, BIANG 6 of 12
 BIOCHEMISTRY
Fatty Acid and Triacylglycerol Metabolism
- regulation of LDL gene receptor - secreted into blood
involves a hormone response element - accounts for about 70% of the
(HRE) apoproteins in HDL
3. Chemically Modified LDL Uptake by Macrophage Functions
Scavenger a. Circulating reservoir - apolipoprotein that is transferred to
a. LDL Receptors - have broad ligand-binding specificity of apoC-II VLDL and chylomicrons
- can mediate the endocytosis of - activator of lipoprotein lipase
chemically modified LDL b. Remove free transferring cholesteryl esters to VLDL
b. Chemical - convert circulating LDL into ligands (unesterified) and LDL in exchange for
Modifications that can be recognized by the receptors cholesterol from TAG
acetylation and apolipoprotein B extrahepatic tissues
oxidation and esterifying it using
- initiating step involves the the plasma enzyme
peroxidation of polyunsaturated fatty phosphatidylcholine:
acids in the LDL lipids cholesterol
- inhibited by antioxidants (vitamin E) acyltransferase (PCAT
c. Macrophages possess high levels of scavenger or LCAT)
receptor activity c. Carry cholesteryl esters to the liver
d. Scavenger Receptor - bind to broad range of ligands 1. HDL as a Reservoir of Apolipoproteins
Class A (SR-A) - mediate the endocytosis of chemically a. Apo C-II - lipoprotein transferred to VLDL and
modified LDL > oxidation of the - lipid chylomicrons
components > apo B - activator of lipoprotein lipase
- not down-regulated in response to b. Apo E apolipoprotein required for receptor-
increased intracellular cholesterol mediated endocytosis of IDLs and
e. Modified LDL Taken - does not regulate intracellular chylomicron remnants
Up by Macrophages cholesterol levels > cholesterol 2. HDL Uptake of Free Cholesterol
accumulation a. Newly Secreted - disc-shaped
- excessive uptake > “foam cells” > (Nascent) HDL - contains
participate in atherosclerotic plaque -primarily phospholipid (largely
formation phosphatidylcholine)
o apolipoproteins (apoE, apoA,
apoC)
o unesterified cholesterol
o rapidly converted to spherical
particles as they accumulate
cholesterol
- high phospholipid concentration
(important cholesterol solubilizer) >
excellent acceptors of unesterified
cholesterol from
o surface of cell membranes
o other circulating lipoproteins
3. Free Cholesterol Esterification
a. Cholesterol Uptake esterification by PCAT
by HDL
b. Phosphatidylcholine: - activated by apo A-I of the HDL
Cholesterol - plasma levels of apo A-I are increased
Acyltransferase (PCAT) by modest alcohol intake
or Lecithin:Cholesterol - synthesized by the liver
Acyltransferase (LCAT) - binds to nascent HDLs
- transfers the fatty acid from carbon 2
HDL METABOLISM of phosphatidylcholine to cholesterol >
HDL Particles - released into the blood stream by production of
exocytosis from liver and intestines
- formed in blood by the addition of
lipid to apo A-1
Apo A-1 - apolipoprotein
- made by the liver and intestine

Trans 2 |ABACCO, ALDERITE, ASSISTIN, BALANZA, BAYAS, BIANG 7 of 12
 BIOCHEMISTRY
Fatty Acid and Triacylglycerol Metabolism
Hydrophobic Lysophosphatidyl
Cholesterol Ester choline
- sequestered in - binds to
the core of HDL > albumin
can no longer be
transferred to a
membrane

e. 2/3 of Plasma esterified with fatty acid
Cholesterol
f. Liver Disease decreased concentrations of plasma
cholesteryl esters may be due to
o phosphatidylcholine production
deficiency
o PCAT/LCAT deficiency
4. Fate of HDLs spherical HDL > taken up by liver by
receptor-mediated endocytosis >
cholesteryl ester degradation
cholesterol release >
o repackaged in lipoproteins
o converted into bile acids
o secreted into the bile
5. Reverse Cholesterol Transport
a. Key Components of Cholesterol Homeostasis
from peripheral HDLs
cells to
from HDLs to liver for
Deficiencies hypercatabolism of lipid-poor HDLs > - bile acid
markedly increased HDL synthesis
Familial LCAT complete LCAT - disposal via the
Deficiency deficiency bile
selective cholesterol
Fish Eye Disease partial LCAT steroidogenic
transfer
deficiency cells for
- hormone
c. As Nascent HDL HDL3 > round, micellar-like particle
synthesis
Accumulates HDL2
Cholesteryl Esters HDL as good cholesterol carrier
inverse relationship between plasma
d. Cholesteryl Ester removes some cholesteryl esters from
HDL concentration and
Transfer Protein HDL to VLDL in exchange for
atherosclerosis
triacylglycerol > ultimately remains in
the LDL until the particle is taken up by b. Involves
a cell cholesterol efflux from peripheral by ABCA1 (transport
cells to HDL protein)
cholesterol by PCAT
esterification
binding of cholesteryl
ester-rich HDL (HDL2) to liver and steroidogenic cells
selective transfer of
cholesteryl esters
release of lipid- Hepatic Lipase
depleted HDL (HDL3) degrade
- triacylglycerols
- phospholipids

Trans 2 |ABACCO, ALDERITE, ASSISTIN, BALANZA, BAYAS, BIANG 8 of 12
 BIOCHEMISTRY
Fatty Acid and Triacylglycerol Metabolism
participate in the formation of HDL3
c. Mediator
cell-surface receptor binds HDL
(scavenger receptor
class B type 1, SR-B1)

ROLE OF LIPOPROTEIN (A) IN HEART DISEASE
1. Lipoprotein (a) - increased plasma concentration >
or lp (a) increased risk of coronary heart disease
- nearly identical in structure to LDL particle
a. Apo (a) - additional lipoprotein molecule 2. Hypolipidemias deficiency of 1 or more of the
(distinguishing feature) plasma lipoproteins
- covalently linked at a single site to apo a. - rare genetic disorder
B-100 Hypobetalipoproteinemia - recessive inheritance
- highly homologous to plasminogen (Abetalipoproteinemia) - characterized by neurologic
- elevated lp (a) > competes with symptoms including ataxia and
plasminogen for the binding of mental retardation
plasminogen activators > slowed blood - plasma TAG and cholesterol levels
clot breakdown > trigger heart attacks are decreased
b. Levels Genetics primarily - complete absence of β-lipoproteins
Determined By Diet trans fatty acids increase (no chylomicrons or VLDLs)
levels of lp (a) - greatly reduced fat absorption
Estrogen decreases - no effective treatment for the
- LDL prevention of the neurologic
- lp (a) symptoms
b. HDL Deficiency - rare familial disorder
(Tangier Disease) - very rare deficiency of ABCA1
- low plasma cholesterol levels
DISORDERS OF LIPOPROTEIN METABOLISM
- normal or increased plasma TAG
1. Hyperlipidemias abnormally high level of one or more
- virtual absence of HDL particles
of the plasma lipoproteins
due to degradation of lipid-poor apo
a. Classification on the basis of electrophoretic
A-1
pattern
- no known treatment
Characteristics - recurrent polyneuropathy
- lymphadenopathy
- tonsillar hyperplasia
- hepatosplenomegaly (from
cholesterol storage in
reticuloendothelial cells)
3. Case: Hypercholesterolemia
a. Presentation
30-year-old male
Presents with - evidence of coronary heart disease
b. Atherosclerosis - arterial disease that causes heart
- xanthomas (cholesterol deposits)
attacks and strokes
in the tendons
- most serious consequence of
hyperlipidemia is the increased risk Blood Analysis - plasma cholesterol = 420 mg/dL
(normal = 150-240)
of atherosclerosis

Trans 2 |ABACCO, ALDERITE, ASSISTIN, BALANZA, BAYAS, BIANG 9 of 12
 BIOCHEMISTRY
Fatty Acid and Triacylglycerol Metabolism
- plasma TAG = 75 mg/dL (35-160)
b. Diagnosis and Treatment
i. Hypercholesterolemia - high plasma cholesterol level
- normal plasma TAG level
ii. Treatment - dietary modification
Implemented - restricted cholesterol intake to
< 200 mg/day
- calories from saturated fats to
< 8% of total calories
- combined drug therapy
- lovastatin 50 mg/day
- colestipol 30 g/day
- niacin 5 g/day
iii. Outcome after 15 months
- plasma cholesterol level = 190
mg/dL
- no noted drug toxicity or side
effects
c. Discussion
i. Lovastatin - inhibits HMG CoA reductase activity
> blocks endogenous cholesterol
synthesis
ii. Colestipol - insoluble resin > binds bile acids >
prevent reabsorption by the
intestines
iii. Niacin inhibit the synthesis and secretion of
VLDL

Trans 2 |ABACCO, ALDERITE, ASSISTIN, BALANZA, BAYAS, BIANG 10 of 12
 BIOCHEMISTRY
Fatty Acid and Triacylglycerol Metabolism

Trans 2 |ABACCO, ALDERITE, ASSISTIN, BALANZA, BAYAS, BIANG 11 of 12
 BIOCHEMISTRY
Fatty Acid and Triacylglycerol Metabolism

Trans 2 |ABACCO, ALDERITE, ASSISTIN, BALANZA, BAYAS, BIANG 12 of 12