D. Alternative Pathways for Fatty Acid Oxidation
1. w-Oxidation
- oxidation of the terminal methyl group to form w-hydroxy fatty acid → dicarboxylic acid
- minor pathway observed with liver microsomal preparations
2. a-Oxidation
- oxidation of long-chain fatty acids to 2-hydroxy fatty acids (constituents of brain lipids)
followed by oxidation to a fatty acid with 1 less carbon
a. Phytanic Acid
- not a substrate for acyl CoA dehydrogenase because of the methyl group on its third (B) carbon
→ hydroxylated at the a-carbon by fatty acid a-hydroxylase → product decarboxylated → activated to CoA derivative → B-oxidation
b. Normal Individuals
- a-oxidation of phytanic acid removes the terminal carbonyl before B-oxidation, allowing the latter pathway to operate, as the B-carbon is now available
c. Refsum’s Disease (Phytanic Acid Storage Disease)
- rare
- autosomal recessive
- fatty acid a-hydroxylase deficiency
- unable to oxidize fatty acids at the a-carbon → build-up of phytanic acid (derived from
animal fat and cow’s milk and probably originally from chlorophyll) in the
- plasma
- tissues
i. Phytanic Acid
- not a substrate for acyl CoA dehydrogenase
- cannot be oxidized by the B-oxidation system because the B position is blocked by a methyl group
- branched-chain fatty acid
ii. Symptoms
- retinitis pigmentosa
- failing night vision
- peripheral neuropathy
- cerebellar ataxia
iii. Treatment
- dietary restriction
CLINICAL ASPECTS
A. Carnitine Deficiency
- can occur in the newborn, especially in preterms, due to inadequate biosynthesis or renal leakage
- can also be caused by hemodialysis and defect in the transport system for carnitine in muscle
1. Signs and Symptoms
- episodic periods of hypoglycemia owing to decreased gluconeogenesis from impaired fatty acid oxidation in the presence of increased plasma free fatty acids → lipid accumulation with muscular weakness
2. Treatment
- supplementation with oral carnitine
B. Medium-Chain Acyl CoA Dehydrogenase (MCAD) Deficiency
- there are 4 fatty acyl CoA dehydrogenase species in the mitochondria with specificities for
— short- chain length fatty acids
-— medium- chain length fatty acids
-— long chain length fatty acids
—- very long-chain length fatty acids
- one of the most common inborn errors of metabolism
- most common inborn errors of fatty acid oxidation
- found in 1/40,000 births (more prevalent than phenylketonuria) worldwide
- causes up to 10% of cases of sudden infant death syndrome (SIDS) or Reye’s syndrome
1. Hallmarks
- decrease in fatty acid oxidation
- profound fasting hypoglycemia
- low to absent ketones
- lethargy, coma, death if untreated
- C8-C10 acyl carnitines in blood
- episode may be provoked by overnight fast in an infant
- often provoked by illness (flu) that causes loss of appetite and vomiting in older child
2. Primary Treatment
- IV glucose
3. Prevention
- frequent feeding, high-carbohydrate, low-fat diet
C. Carnitine Palmitoyltransferase I Deficiency
- affects only the liver
1. Characteristics
- decreased fatty acid oxidation
- ketogenesis
- hypoglycemia
D. Carnitine Palmitoyltransferase II Deficiency (Myopathic Form)
- adolescent or adult onset
- affects primarily the skeletal muscles and liver in its most severe form
- muscle-specific CAT/CPT gene defect
Carnitine Palmitoyltransferase II Deficiency (Myopathic Form)
- muscle aches, mild to severe weakness
- rhabdomyolysis, myoglobinuria, “red urine”
- episode provoked by prolonged exercise especially after fasting, cold, or associated stress
- symptoms may be exacerbated by high-fat, low-carbohydrate diet
- muscle biopsy shows elevated muscle triglyceride detected as lipid droplets in cytoplasm
- cease muscle activity and give glucose
E. Oral Hypoglycemic Agent - Sulfunylurea (Glyburide, Tolbutamide)
- inhibits carnitine palmitoyltransferase → decreased fatty acid oxidation
F. Long-Chain 3-Hydroxyacyl CoA Dehydrogenase Deficiency
→ acute fatty liver of pregnancy
G. Jamaican Vomiting Sickness
1. Hypoglycin
- toxin from unripe fruit of akee tree
- inactivate short- and medium-chain acyl CoA dehydrogenase → inhibition of B-oxidation → hypoglycemia and excretion of medium- and short-chain mono- and dicarboxylic acids
H. Dicarboxylic Aciduria
1. Characterized by
- excretion of C6-C10 w-dicarboxylic acids
- non-ketotic hypoglycemia
2. Etiology
- deficiency of mitochondrial medium-chain acyl CoA dehydrogenase
I. Refsum’s Disease
J. Zellweger’s (Cerebrohepatorenal) Syndrome
- rare inherited absence of peroxisomes in all tissues
- accumulate C26-C38 polyenoic acids in brain tissues due to inability to oxidize long-chain fatty acids in
peroxisomes
SPECIALIZED FATTY ACIDS: PROSTAGLANDINS and RELATED COMPOUNDS
A. Prostaglandins and Related Compounds (Thromboxanes, Leukotrienes)
- eicosanoids
- extremely potent compounds
- elicit a wide range of physiologic responses
- extremely short half-life
- produced in very small amounts
- formed in almost all tissues
- generally act locally
- metabolized to inactive products at their site of synthesis
- not stored to any appreciable extent
KETONE BODIES: an ALTERNATE FUEL for CELLS
1. Liver Mitochondria
- capacity to divert any excess acetyl CoA derived from fatty acid or pyruvate oxidation into
ketone bodies
2. Ketone Bodies
- small
- water-soluble
- potential units of acetate
- transported in the blood to the peripheral tissues reconverted to acetyl CoA TCA cycle
a. Preferred Energy Substrates of the
- heart
- skeletal muscle
- kidney
- if blood levels of -hydroxybutyrate and acetoacetate increase sufficiently (after 20
days of starvation) form valuable energy substrate for the brain (may
account for up to 75% of brain oxidation)
b. Important Sources of Energy for the Peripheral Tissues Because
- soluble in aqueous solution and do not need to be incorporated to lipoproteins or
carried by albumin
- produced in the liver during periods when the amount of acetyl CoA present exceeds
A. Synthesis of Ketone Bodies by the Liver
- synthesized in liver mitochondria used as metabolic fuel by other tissues (liver cannot use ketone
bodies as metabolic fuel)
- synthesis is limited except under conditions of
- high rates of fatty acid oxidation
- limited carbohydrate intake
- ex: fasting
starvation
- flooding of liver with fatty acids elevated hepatic acetyl CoA pyruvate dehydrogenase
inhibition
pyruvate carboxylase activation
oxaloacetate production used by the liver for gluconeogenesis rather than for the TCA
cycle
acetyl CoA channelled into ketone body synthesis
1. 3-Hydroxy-3-Methylglutaryl CoA (HMG-CoA) Synthesis
a. Acetoacetyl CoA Formation
- 1st step
- can occur by 1 of 2 processes
- incomplete breakdown of fatty acid
- reversal of the thiolase reaction of fatty acid oxidation
b. Mitochondrial HMG-CoA Synthase
- catalyzes the rate-limiting step of ketone body synthesis
- present in significant quantities only in the liver
- combines a 3rd molecule of acetyl CoA with acetoacetyl CoA produce 3-hydroxy-3-
methylglutaryl CoA (HMG-CoA)
c. HMG-CoA
- structural intermediate in the catabolism of leucine
- precursor of cholesterol
- cleaved to produce acetoacetate and acetyl CoA
2. Ketone Body Synthesis
a. HMG CoA Cleavage Yields
- acetoacetate
- acetyl CoA
b. Acetoacetate
- can be reduced to form 3-hydroxybutyrate (NADH as hydrogen donor)
- can be spontaneously decarboxylated acetone formation
c. -Hydroxybutyrate
- formed from acetoacetate by -hydroxybutyrate dehydrogenase when the
NADH/NAD+
ratio is high (as it is in the liver during fasting)
d. Acetone
- volatile biologically nonmetabolizable side product
- formed spontaneously from a small fraction of circulating acetoacetate
lost in the expired air from the lungs
i. Untreated DM
- odor of acetone is apparent on the patient’s fruity breath (in this condition,
ketone body production can be extremely high)
B. Utilization of Ketone Bodies by the Peripheral Tissues
- ketone bodies are constantly produced by the liver at low levels
- the liver cannot reconvert acetoacetate to acetoacetyl CoA cannot use them as fuels
- production becomes more significant during starvation (when ketone bodies are much more needed to
provide energy to the peripheral tissues)
1. -Hydroxybutyrate Dehydrogenase
- oxidizes -hydroxybutyrate to acetoacetate
- produces NADH
2. Activation
- occurs by the formation of the CoA thioester of acetoacetate
- CoA provided by succinyl CoA
- catalyzed by succinyl CoA : acetoacetate CoA transferase (thiophorase)
- reversible reaction
3. Thiolase
- cleavage of acetoacetyl CoA to 2 acetyl CoAs oxidation by the TCA cycle
C. Energy Yield from Oxidation of Ketone Bodies
- conversion of -hydroxybutyrate to acetoacetate yields NADH 2.5 ATP molecules by electron
transport and oxidative phosphorylation
- each acetyl CoA yields 10 ATP molecules via TCA cycle, electron transport, and oxidative
phosphorylation
- activation requires 1 mole ATP
- acetoacetate oxidation 2 acetyl CoAs 20 moles ATP
- -hydroxybutyrate oxidation yield NADH 2.5 moles ATP
21.5 moles ATP
D. Ketoacidosis
- rate of ketone body formation > rate of use increased blood levels (ketonemia) increased urinary
levels (ketonuria) ketosis
- high fatty acid degradation excessive acetyl CoA NAD+
depletion
increased NADH pool
slowing of TCA cycle acetyl CoAs forced to ketone body formation
1. Starvation
- ketone body production increases dramatically
- blood levels rise only slowly to a maximum of 7 mM after 20-30 days of starvation
- ketone bodies are the only source of fuel consumed by the body no excess to accumulate
ketonuria and ketonemia are never high enough to
2. Diabetes Mellitus
a. Type 1 Insulin-Dependent Diabetes Mellitus (IDDM)
- adipose tissue lipolysis fatty acid release hepatic ketone body synthesis exceed
the ability of other tissues to metabolize them profound, life-threatening
ketoacidosis may occur
- infection or trauma increased cortisol, epinephrine hormone-sensitive lipase
activation may precipitate ketoacidosis
b. Type 2 Non-Insulin-Dependent Diabetes Mellitus (NIDDM)
- much less likely to show ketoacidosis (much slower, insidious onset)
- not complete insulin resistance in the peripheral tissues
- can develop ketoacidosis after an infection or trauma
c. Diabetic Patients with Ketosis
- urinary excretion of ketone bodies may be as high as 5000 mg/24 hours
- blood concentration may reach 90 mg/dL (< 3 mg/dL in normal individuals)
- elevated ketone body concentration in the blood acidemia
- carboxyl group of a ketone body has a pKa of 4 losses proton (H+
) as it
circulates in the blood lowers blood pH acidosis (ketoacidosis)
- urinary excretion of glucose and ketone bodies (osmotic diuresis) dehydration
3. Alcoholics
- can develop ketoacidosis
- chronic hypoglycemia (often present in chronic alcoholism) fat release from adipose
increased hepatic ketone body production
- slower than normal muscle ketone body utilization (hepatic alcohol conversion to
acetate diffusion into blood oxidation by muscle as alternative source of
acetyl-CoA)
4. Associated with Ketoacidosis
- polyuria, dehydration, and thirst (exacerbated by hyperglycemia and osmotic diuresis)
- CNS depression and coma
- potential depletion of K+
(loss may be masked by a mild hyperkalemia)
- decreased plasma bicarbonate
- breath with sweet or fruity odor (acetone)
E. Laboratory Measurement of Ketones
a. Normal Ketosis
- accompanies fasting
- does not produce acidosis
- acetoacetate and β-hydroxybutyrate formed in approximately equal quantities
b. Pathologic Conditions (Diabetes, Alcoholism)
- β-hydroxybutyrate production predominates
1. Urinary Nitroprusside Test
- detects only acetoacetate can dramatically underestimate the extent of ketoacidosis and
its resolution during treatment
2. β-Hydroxybutyrate Measurement
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