LIPIDS

Question 1

IMPORTANT FATTY ACIDS

Answer 1

Question 2

FA naming

Answer 2

Question 3

ACTIVATION OF FATTY ACIDS

Answer 3

• A fatty acid must be converted to its activated form before it can participate in metabolic processes
• Enzyme: Fatty acyl CoA synthetase
• Occurs in the cytosol

Activated FA: Acyl-CoA

Question 4

End product of mammalian FA synthesis (Lipogenesis)

Answer 4

Palmitic acid

Question 5

rate liming step of Lipogenesis

Answer 5

Acetyl CoA + HCO 3 – + ATP → Malonyl CoA

Enzyme: Acetyl CoA carboxylase​

Question 6

Substrate and product of Lipogenesis

Answer 6

Acetyl CoA

Palmitoyl CoA

Question 7

Citrate Shuttle

*Mitochondrial acetyl CoA (from the oxidation of pyruvate) is transported to the cytosol using the citrate shuttle

Answer 7

Question 8

Activators of Acetyl-CoA Carboxylase (rate-limiting enzyme of Lipogenesis)

Answer 8

Citrate and Insulin

Question 9

Inhibitors of Acetyl-CoA Carboxylase (rate-limiting enzyme of Lipogenesis)

Answer 9

Glucagon and epinephrine

Question 10

Sources of NADPH for Lipogenesis:

Answer 10

• Pentose phosphate pathway
• Malic enzyme
• Isocitrate dehydrogenase

Question 11

Sequence of steps repeated seven times for Elongation of PAlmitoyl COA (Lipogenesis)

Answer 11

Condensation → Reduction → Dehydration → Reduction

“CoRe DR

Question 12

Fatty acids are stored as ______

Answer 12

TRIACYLGLYCEROL

Question 13

Enzyme that breaks down TAG to Glycerol and Fatty Acids

Answer 13

Hormone Sensitive lipase

Question 14

Beta Oxidation / Lipolysis

Answer 14

• Removal of acetyl CoA fragments from the ends of fatty acids, also yielding NADH and FADH2 in the process
  
  • Acetyl CoA can enter the citric acid cycle
  • NADH and FADH 2 can enter the ETC

Question 15

Substrate for Lipolysis

Answer 15

Palmitate

Question 16

What are the products of Lipolysis?

Answer 16

8 Acetyl CoA, 7 NADH, 7 FADH 2

Question 17

Rate limiting step of BETA-OXIDATION or LIPOLYSIS.

Answer 17

Translocation of fatty acyl CoA from the cytosol to the mitochondria

Enyzme: Carnitine-palmitoyl transferase​

Question 18

How many NADPH are consumed in LIPOGENESIS

Answer 18

14

Question 19

What shuttle is used in Beta oxidation?

Answer 19

Carnitine shuttle

Question 20

TRANSPORT OF FATTY ACYL COA TO THE MITOCHONDRIA

Answer 20

1. Fatty acyl synthetase activates the fatty acid
2. Carnitine acyltransferase-1 attaches fatty acyl to carnitine in the outer mitochondrial membrane
3. Fatty acyl-carnitine is shuttled through the inner membrane
4. Carnitine acyltransferase-2 transfers fatty acyl group back to a CoA in the mitochondrial matrix

Question 21

Sequence of steps repeated seven times in Beta Oxidataion/Lipolysis:

Answer 21

Oxidation → Hydration → Oxidation → Thiolysis​

Question 22

Enzymes collectively known as fatty acid oxidase​ in Lipolysis.

Answer 22

“DeHyDeThy”

o Fatty acyl CoA dehydrogenase

o Δ2 enol CoA hydratase

o 3-hydroxyacyl-CoA dehydrogenase

o Thiolase

Question 23

ATP YIELD of PALMITATE

Answer 23

Question 24

produced only during beta oxidation of odd-numbered fatty acids (because beta oxidation removes 2 carbons at a time.

Answer 24

Propionyl CoA

Question 25

Differentiate Lipogenesis from Beta Oxidation

Answer 25

Question 26

• Leads to decreased oxidation of fatty acids with 6–10 carbons
• Most common inborn error of fatty acid oxidation o Autosomal recessive disorder with a higher incidence in Northern Europeans

Answer 26

MEDIUM-CHAIN FATTY ACYL COA DEHYDROGENASE (MCAD) DEFICIENCY

o Severe hypoglycemia

o Accumulation of fatty acids (dicarboxylic acids) in the urine

o Can manifest as Sudden Infant Death Syndrome (SIDS)

Question 27

CARNITINE-PALMITOYL TRANSFERASE I DEFICIENCY

Answer 27

• Affects the liver
• Reduced fatty acid oxidation, leading to severe hypoglycemia, coma, and even death

Question 28

CARNITINE-PALMITOYL TRANSFERASE II DEFICIENCY

Answer 28

• Affects primarily cardiac and skeletal muscle
• Cardiomyopathy, muscle weakness with myoglobinemia after prolonged exercise

Question 29

• Caused by eating the unripe fruit of the akee tree
• The toxin hypoglycin inactivates medium- and short-chain acylCoA dehydrogenase, inhibiting β-oxidation and causing hypoglycemia

Answer 29

JAMAICAN VOMITING SICKNESS

Question 30

• Deficiency of phytanoyl-CoA hydroxylase leads to accumulation of phytanic acid

Answer 30

REFSUM DISEASE

o Peripheral neuropathy and ataxia, retinitis pigmentosa, and abnormalities of skin and bones

Accumulation of phytanic acid blocks β-oxidation.

Question 31

• Cerebrohepatorenal syndrome
• Inherited absences of peroxisomes in all tissues leads to marked accumulation of very-long-chain, saturated, unbranched fatty acids in liver and central nervous system

Answer 31

ZELLWEGER SYNDROME

• Liver dysfunction with jaundice
• Marked mental retardation, weakness, hypotonia
• Craniofacial dysmorphism (high forehead, shallow orbits, hypertelorism, high arched palate, abnormal helices of ears, retrognathia)
• Early death

Question 32

Inability to transport VLCFAs across the peroxisomal membrane leads to accumulation in the brain, adrenals, and testes

Answer 32

ADRENOLEUKODYSTROPHY (ALD)

o Neurodegeneration (Initial apathy and behavioral change, followed by visual loss, spasticity, and ataxia)

o Adrenocortical insufficiency

o Hypogonadism

Question 33

Where does ketogenesis occur?

Answer 33

liver mitochondria

Question 34

Substrate for ketogenesis

Answer 34

o Acetyl CoA

* Ketone bodies are alternate fuel sources for tissues like the brain during the fasting phase. They are derived from acetyl CoA. Recall tha acetyl CoA comes from glycolysis when you are well fed, but from beta oxidation when you are fasting.

Question 35

Products of ketogenesis

Answer 35

o Acetoacetate

o β-hydroxybutyrate

o Acetone

*Of the three ketone bodies, only acetoacetate and β-

hydroxybutyrate can be used as fuel.

Question 36

rate limiting step of KETOGENESIS

Answer 36

Acetoacetyl CoA + Acetyl CoA → HMG CoA

Enzyme: HMG CoA Synthase​

Question 37

Answer 37

During fasting, there’s almost no glucose available to be converted to acetyl CoA. Free fatty acids in the blood will be sent to the liver to be broken down into acetyl CoA units which can enter ketogenesis. KBs will then be made. KBs are small, can travel to blood & can enter the BBB. As KBs travel in the blood, some KBs can be excreted in the urine &/or one of the KBs (acetone) will be exhaled in the lungs. Once KBs reach the target tissue (extrahepatic), KBs will undergo ketolysis and be converted to AcetylCoA that then enters Krebs cycle (producing 10 ATPs per cycle). Ketogenesis & ketolysis are opposittes but both occur during fasting.

Question 38

Substrate for Cholesterol Synthesis

Answer 38

Acetyl CoA

Question 39

The liver is NOT able to use ketone bodies as fuel because it lacks the enzyme ___

Answer 39

succinyl CoA-acetoacetate-CoA transferase (thiophorase)

Question 40

Describe the structure of cholesterol

Answer 40

o 27-carbon compound

o Steroid nucleus: four fused hydrocarbon rings (A-D)

o An eight-carbon, branched hydrocarbon chain attached to carbon 17 of the D ring

o Hydroxyl group at carbon 3 of the A ring

o Double bond between carbon 5 and 6 of the B ring

Question 41

Primary bile acids

Answer 41

o Cholic acid

o Chenodeoxycholic acid

Question 42

Secondary bile acids

Answer 42

o Deoxycholic acid

o Lithocholic acid

Question 43

• Bile salts

Answer 43

o Conjugated to taurine and glycine (e.g., taurocholic acid, glycocholic acid)

Question 44

Cholesterol Synthesis

Answer 44

1. Acetyl CoA is produced from glucose
2. Acetoacetyl-CoA and acetyl-CoA condense to form HMG-CoA
3. HMG-CoA is reduced to mevalonate
4. Mevalonate is converted to C-5 isoprenoid, isoprenyl pyrophosphate
5. Two isoprenyl pyrophosphates condense to form C-10 compound, geranyl pyrophosphate, which reacts with another C-5 compound to form C-15 farnesyl pyrophosphate
6. Squalene is formed from two C-15 units, and then oxidized and cyclized to form lanosterol
7. Lanosterol is converted to cholesterol

Question 45

Rate limiting step for Cholesterol Synthesis

Answer 45

Hydroxymethylglutaryl-CoA (HMG CoA) → Mevalonate

Enzyme: HMG-CoA Reductase Requirement: 2 NADPH​

Question 46

are drugs used for the treatment of hypercholesterolemia, to reduce the risk for cardiovascular diseases. They are competitive inhibitors of HMG CoA reductase.​

Answer 46

Statins

Question 47

• 7-dehydrocholesterol reductase deficiency

• Leading to low plasma cholesterol and elevated 7dehydrocholesterol
• Presents with dysmorphic facial features, microcephaly, mental retardation, congenital heart disease, other malformations, often stillborn

Answer 47

SMITH-LEMLI-OPITZ SYNDROME

Question 48

• Precipitation of cholesterol in the gallbladder
• Results when more cholesterol enters the bile than can be solubilized by the bile salts and phosphatidyl choline present

Answer 48

CHOLELITHIASIS

Question 49

o Most common form of CAH (>90%)

o Mineralocorticoids and glucocorticoids are absent or deficient

o Overproduction of androgens leads to masculinization of external genitalia in females and early virilization in males

Answer 49

21 -α-Hydroxylase deficiency

Question 50

• Largest diameter
• Lowest density

• Highest TAG content

Answer 50

Chylomicron

Question 51

o Decrease in serum cortisol, aldosterone, and corticosterone

o Increased production of deoxycorticosterone causes fluid retention (low-renin hypertension)

o Overproduction of androgens causes masculinization and virilization

Answer 51

11-β1-Hydroxylase Deficiency

Question 52

• Autoimmune destruction of the adrenal cortex leads to adrenocortical insufficiency
• Acute addisonian crisis precipitated by stress (infection, trauma, surgery, vomiting, diarrhea, or noncompliance with replacement steroids)
• Hyperpigmentation due to excess ACTH stimulating melanocytes to produce melanin

Answer 52

ADDISON DISEASE

Question 53

Highest cholesterol content

Answer 53

LDL

Question 54

• Highest protein content

Answer 54

HDL

Question 55

• Cofactor of lecithin:cholesterol acyltransferase (LCAT)
• Structural component of HDL

Answer 55

Apo A-1

Question 56

• Mediates assembly and secretion of VLDL
• Structural protein of VLDL, IDL, LDL

Answer 56

Apo B-100

Question 57

Main apoprotein and mediates secretion of chylomicrons from small intestines

Answer 57

Apo B-48

Question 58

Cofactor of lipoprotein lipase

Found in Chylomicrons, VLDL IDL, HDL

Answer 58

Apo C-II

Question 59

Mediates uptake of chylomicron remnants and IDLs

Found in Chylomicron remnants, VLDL, IDL, HDL

Answer 59

Apo E

Question 60

Type I

Familial Lipoprotein Lipase Deficiency

Answer 60

Question 61

Type IIa

Familial Hypercholesterolemia

Answer 61

Question 62

Type III

Familial dysbetalipoproteinemia

Answer 62

Question 63

Type IV

Familial Hypertriacylglycerolemia

Answer 63

Question 64

Familial Lipoprotein (a) Excess

Answer 64

Question 65

Familial hyperalphalipoproteinemia

Answer 65

Question 66

Abetalipo-proteinemia

Answer 66

Question 67

Familial alpha-lipoprotein deficiency

Tangier disease

Fish-eye disease

Apo A-1 deficiencies

Answer 67

Question 68

Metabolism of Chylomicrons

Answer 68

Question 69

VLDL Metabolism

Answer 69

Question 70

HDL Metabolism

Answer 70