Heme Metabolism Lecture Notes PDF

Summary

These lecture notes describe the metabolism of heme, a crucial component of hemoglobin and other proteins. The document covers the pathway of heme synthesis, emphasizing porphyrias. It also discusses the role of drugs in heme biosynthesis and the biochemistry of heme degradation.

Full Transcript

Heme Metabolism
Dr. Zahi Damuni
[email protected]
Recommended Reading: Lippincott Illustrated Reviews: Biochemistry (Lippincott
Illustrated Reviews Series) by Denise Ferrier 8th edition Chapter 21

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Learning Objectives
1.
2.
3.
4.

Describe the pathway of heme synthesis with emphasis on the porphyrias
Explain the types of porphyrias & their causes
Know which intermediates accumulate in the porphyrias
Describe the effects of various drugs on heme biosynthesis and their clinical
importance
5. Identify how blocking of one of the enzymes involved in heme biosynthesis
will affect the mode of presentation of the disease, e.g., Lead Poisoning
6. Describe the pathway of heme degradation and the main types of jaundice
7. Know the differences between conjugated (direct) and unconjugated
(indirect) hyperbilirubinemias (Crigler-Najjar, Gilberts, Dubin-Johnson,
Rotor)
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Heme Metabolism: Lecture Summary
•
•
•
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What are hemes?
Heme synthesis and its regulation
Disorders related to heme synthesis: Porphyrias
Heme degradation
Disorders of Heme degradation:
– Jaundice
– Hyperbilirubinemias

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Heme
Heme is a tightly bound prosthetic group of hemoglobin, myoglobin, the cytochrome P450,
catalase, and many other proteins

Heme comprises
• One ferrous ion (Fe2+) in the center
• Protoporphyrin IX (a tetrapyrrole ring)
• Thus, heme + globin protein = hemoglobin

Porphyrins
•
•
•
•

A group of macrocyclic organic compounds
Composed of 4 modified pyrrole subunits
The pyrroles are interconnected through methine/methylene bridges (=C-)
The pyrroles carry side chains that vary in structure and disposition on the macrocycle
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Heme

https://publications.nigms.nih.gov/findings/sept13/hooked-on-heme.asp

Myoglobin: An oxygen carrying protein; Journal of Experimental Biology 2004 207: 3441-3446
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Heme and hemin are porphyrin protein molecules. The key difference between heme and
hemin is that heme contains ferrous ion, whereas hemin contains ferric ion. Furthermore,
hemin molecules contain chloride atoms in the chemical structure, whereas heme does not
contain chloride atoms.

Heme
Heme is a tightly bound prosthetic group of hemoglobin, myoglobin, the cytochrome
P450, catalase, and many other proteins
Heme comprises
One ferrous ion (Fe2+) in the center
Protoporphyrin IX (a tetrapyrrole ring)
Thus heme + globin protein = hemoglobin
Porphyrins
A group of macrocyclic organic compounds
Composed of 4 modified pyrrole subunits
The pyrroles are interconnected through methine/methylene bridges ( =C-)

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The pyrroles carry side chains that vary in structure and disposition on the macrocycle

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Heme Side Chains
• Heme contains:
– Pyrrole
– Methyl
– Vinyl
– Propionate

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Porphyrins
A group of macrocyclic organic compounds
Composed of 4 modified pyrrole subunits
The pyrroles are interconnected through methine bridges ( =C-)
The pyrroles carry side chains that vary in structure and disposition on the macrocycle

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Porphyrin & Heme Synthesis
• Heme is synthesized principally in the:
– Bone marrow for erythrocytes
– Liver for Cytochrome P-450
– Other locales are minor in amount,
but support mitochondrial and other
enzymes
• Heme is ultimately excreted and not
recycled
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Heme is made where it is needed
Hemoglobin
1.
2.
3.
4.
5.

The body contains 800-900 gm
This amount includes about 30-35 gm heme
About 6 gm of hemoglobin is synthesized daily (2.4 million erythrocytes)
This translates to about 250-300 mg of heme synthesized daily in the bone marrow
This amount is ~ 70-80% of bodily heme synthesis

Note: Erythropoiesis is the process which produces red blood cells (erythrocytes). It is stimulated by
decreased O2 in circulation, which is detected by the kidneys, which then secrete the hormone
erythropoietin. This hormone stimulates proliferation and differentiation of red cell precursors, in the red
bone marrow.

Cytochrome P-450
1. This major liver enzyme contains heme and accounts for 65% of the total liver heme synthesis
2. This protein is responsible for inactivation of drugs and other xenobiotics
3. Cytochrome P-450 has a faster turnover rate than does hemoglobin, and therefore liver heme
synthesis accounts for ~15% of the bodily total
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Porphyrin Synthesis

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Porphyrins are macrocycles of 4 smaller cycles
Contain side chains in various patterns (types I, II, III, and IV). Heme uses type III, which is the
only physiologically relevant pattern for people
Chelate metals in the center
Porphyrinogens are porphyrin precursors and are intermediate between porphobilinogen &
protoporphyrin
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Porphyrin Synthesis
• d-aminolevulinate synthase
– ALAS1, liver
– ALAS2, bone marrow
– Both are mitochondrial
– Rate-limiting step of heme synthesis
• Inhibited by hemin and low iron:
– Hemin decreases expression of ALAS1 in liver
– Low iron inhibits ALAS2 expression in
erythroid cells

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Hemin is the Fe3+ Form of Heme (Fe2+)

Hemin is effectively a feedback inhibitor acting on ALAS1 in the liver by
repression. ALAS1 supplies heme principally for Cytochrome P450, which is
inducible. ALAS1 is readily repressed and induced and has a relatively short 1-3 hr
half life. Thus, its levels are readily regulated through changes in expression.
Cytochrome P-450 is often induced during drug administration to metabolize the
drugs and this induction leads to an increase in ALAS1 activity to supply heme.
Phenobarbital, griseofulvin or hydantoins, by causing ALA synthase activity
increase, induce high levels of ALA and porphobilinogen in urine and an
accumulation of protoporphyrin in liver, leading to regressive processes and
cirrhosis. The cause is a production of cytochrome P450, induced by the drugs,
consuming heme. When the amount of heme in the liver decreases, its hemin
form no longer acts as a repressor for its synthesis.
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ALAS2 in the bone marrow is regulated by the availability of iron.
Low iron inhibits ALAS2 production. The enzyme is produced only if there is an
adequate supply of iron. Transcription of ALA synthase is tightly controlled by
the presence of Fe2+‐binding elements, to prevent accumulation of porphyrin
intermediates in the absence of iron.

X-linked sideroblastic anemia is due to an ALAS2 deficiency. In this
disorder, iron is available, but cannot be used for heme. The marrow produces
ringed sideroblasts that are atypical, nucleated erythroblasts with iron granules
accumulated in their mitochondria.
Expression of ALAS2 is also regulated by erythropoietin.
Both ALAS1 and ALAS2 are regulated by expression.
[Note: The inhibition shown in the figure is not allosteric.]
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Erythropoietin (Epo) was found to act as a concentration-dependent inducer of aminolevulinic
acid (ALA) synthase and porphobilinogen (PBG) deaminase in normal human bone marrow in
culture.

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Porphyrin Synthesis
• Next steps are cytosolic
• 2 ALA are condensed to porphobilinogen
by ALA dehydratase
• This generates the characteristic side
chains and the linkers that will be used to
form the macrocyclic porphyrin
– Note side chains and linkers
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Porphyrin Synthesis
• Condensation
• Macrocycle Closure
• Side-chain modification:
– Decarboxylation to make
methyl groups
– Decarboxylation and
oxidation to make vinyl
groups
• Oxidation of linkers from
methyl to methine groups
• Note: The oxidation steps
(last two arrows in the right
figure) take place in the
mitochondria.
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Hydroxymethylbilane Synthase is the same as Porphobilinogen Deaminase

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Heme Synthesis from Protoporphyrin
• Ferrochelatase
– Adds Fe2+
– Mitochondrial
– Sensitive to lead – one source of lead
poisoning pathophysiology
– Lead poisoning results in formation
of zinc protoporphyrin (ZnPP)
resulting in anemia
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Porphyrias:
Defects in Heme Synthesis
• Lead poisoning
• Congenital defects in
Porphyrin and heme synthesis
– Can be liver or bonemarrow specific
• Porphyrias are generally rare
• Diagram also shows which
steps are mitochondrial vs
cytosolic

Porphobilinogen
Deaminase

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Porphyrias
Rare, usually inherited defects in one of the enzymes of heme synthesis. One or more porphyrin
precursors accumulate and increase in the blood and in the urine. Most are autosomal dominant, except
erythropoietic porphyria, which is recessive.
Neurological abnormalities are seen in many porphyrias because some intermediates of heme
biosynthesis are neurotoxic. Abdominal pain is a frequent symptom, most likely because visceral pain
fibers are stimulated by the accumulating metabolic intermediates.
Cutaneous photosensitivity is typical for porphyrias in which porphyrins or porphyrinogens accumulate.
Photosensitive – if a closed ring structure. Photosensitivity arises from enzyme defects that lead to
accumulation of tetrapyrroles (enzymes after formation of hydroxymethylbilane). The porphyrinogens
are oxidized nonenzymatically to the corresponding porphyrins. In the skin, the porphyrins become
photoexcited by the action of sunlight, which leads to the formation of highly reactive and therefore toxic
singlet oxygen (free radical formation). These porphyrias frequently result in unusually dark or colorful
urine.

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Classification of Porphyrias
Hepatic

Erythropoetic

• Chronic

• Congenital erythropoetic porphyria
• Erythropoetic protoporphyria

• Porphyria cutanea tarda

• Acute
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ALA dehydratase deficiency
Acute intermittent porphyria
Hereditary coproporphyria
Variegate porphyria
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Porphyria Cutanea Tarda
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Chronic, hepatic porphyria
Deficiency in uroporphyrinogen decarboxylase
This is the most common Porphyria
Late onset – 4th or 5th decade
Clinical expression is influenced by iron load,
sunlight exposure, alcohol use, Hepatitis (B or
C), HIV, or estrogen therapy
• Symptoms:
– Skin eruptions
– Discolored urine

normal

Porphyria cutania tarda

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All porphyrias result in decreased synthesis of heme
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Therefore, ALAS activity is higher in hepatic porphyria’s because ALAS1 is regulated by heme (derepression of ALAS1)
Increased enzyme synthesis and activity results in accumulation of more intermediates upstream of the deficient
enzyme block.
It is the accumulation of these intermediates that lead to toxicity and the major pathophysiology of the porphyrias

Chronic Hepatic Porphyria
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Clinical expression dependent on hepatic iron overload, exposure to sunlight, alcohol use, and presence of hepatitis B
or C or HIV
Onset is late in life, in the 4th or 5th decade

Acute Hepatic Porphyrias
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Acute attacks of GI, neuropsychiatric, and motor symptoms
May be accompanied by photosensitivity
Porphyrias that accumulate ALA and porphobilinogen (acute intermittent porphyria) cause abdominal pain and
neuropsychiatric disturbances (anxiety to delirium)
Symptoms can be precipitated by drug administration such as alcohol, barbiturates, because of p450 induction

Erythropoetic Porphyrias
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Skin rashes and blisters that appear early in childhood. Eventually complicated by cholestatic liver cirrhosis and
progressive hepatic failure
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Heme Degradation &
Excretion
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Senescent erythrocytes taken up by
macrophages
Heme converted to bilirubin in
macrophages
Bilirubin travels on albumin to the
liver
Liver conjugates bilirubin and sends it
to bile and then intestine
Bilirubin is de-conjugated in intestine
and converted to urobilinogen
Urobilinogen is
– Mostly converted by bacteria to
brown stercobilin and excreted
– Some is re-absorbed, oxidized in
the kidney, and excreted there as
urobilin (yellow)
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Heme Degradation
Summary
• Erythrocytes last about 120 days
• Most lost heme is from
erythrocytes (85%) with the
remainder from hepatic P450 and
other cytochromes
• Heme is oxidized, iron released,
and the macrocycle broken
• Converted to bilirubin
• Sent to liver for excretion in the
bile as a diglucuronide adduct
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• Heme oxygenase
– Release of Fe3+
– Breaking of protoporphyrin IX
• Product is Biliverdin

Heme Degradation:
Oxidation steps

Fe3+

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Heme Degradation:
Oxidation steps
• Biliverdin Reductase:
– Reduces methine bond to
methane in one place in the
macrocycle
• Product: Bilirubin
– Carried in the blood on albumin
– Delivered to the liver
– Further modified in the liver

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Heme Degradation:
Conversion to Bilirubin Diglucuronide
• After transport to liver:
– Propionic acids are
modified
– Reacted with UDPglucuronide
• Secreted as Bilirubin
diglucuronide into the
bile

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Disorders of Heme Degradation - Jaundice
• Also called icterus: not a disease,
but a common symptom
• Yellow discoloration of sclerae,
nails, and skin
• Reflects increased bilirubin levels
in the blood and deposition
• Bilirubin is readily measured
• Normal serum bilirubin is 2-17
micromolar (or 1.0 mg/dL)
• Jaundice occurs with > 40
micromolar serum bilirubin (or >
2.5 to 3 mg per dL)
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Jaundice
• Prehepatic Jaundice
– Hemolytic anemia, thalassemia, transfusion

• Hepatic Jaundice
– Congenital disorders
– Hepatitis, cirrhosis, cancer, drugs

• Post-Hepatic Jaundice – obstructive (pale stools)
– Blocked bile duct (e.g., tumor)
– Gallstones

• Neonatal
– Incomplete maturation of bilirubin UDP-glucuronyl
transferase
– Treat with light (phototherapy) to make bilirubin
isomers that are soluble.
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Cholestasis is a liver disease. It occurs when the flow of bile from the liver is reduced or
blocked. Bile is fluid produced by the liver that aids in the digestion of food, especially fats.
When bile flow is altered, it can lead to a buildup of bilirubin. Gallstones are hardened deposits
of digestive fluid that can form in the gallbladder. The gallbladder is a small, pear-shaped organ
on the right side of the abdomen, just beneath the liver. The gallbladder holds the digestive
fluid bile that's released into the small intestine.

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Unconjugated Hyperbilirubinemias
(Indirect Bilirubin)
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•

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Due to:
– Hemolysis
– Impaired conjugation
– Hemolytic disease of the newborn
Autoimmune condition where maternal antibodies cause
hemolysis in the fetus
Gilbert Syndrome
– Mild Familial, can occur along with neonatal jaundice
– Slight increase in unconjugated bilirubin
– Yellow tinge of skin
– 3‐12% of the population
Crigler-Najjar
– Reduced or no UDP-glucuronyl transferase in liver
– Requires lifelong phototherapy
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Hemolytic disease of the newborn is a severe form of anemia caused in a fetus or newborn
infant by incompatibility with the mother's blood type, typically when the mother is rhesus
negative and produces antibodies which attack rhesus positive fetal blood through the
placenta.

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Unconjugated Hyperbilirubinemias
(indirect Bilirubin)
• Neonatal jaundice
– Incomplete maturation of bilirubin
glucuronyl-transferase
– Treat with phototherapy to make
bilirubin isomers that are soluble
– Can also occur from congenital
disorders, hemolytic disease of the
newborn, sepsis and others

• Kernicterus
– Bilirubin induced brain dysfunction
– Can occur in newborns due to
transiently low UDP-glucuronyl
transferase
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Conjugated Hyperbilirubinemias
(Direct Bilirubin)
• Dubin-Johnson syndrome
– Defective secretion of
bilirubin from hepatocytes
into the bile
– Results in dark-brown liver
• Rotor syndrome
– Transporter defect
– Mild elevation of
conjugated/direct bilirubin
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Perivenous hepatocytes are exposed to lower oxygen tension, and lower nutrient and
hormone levels, than periportal hepatocytes. Periportal hepatocytes receive both nutrientrich blood from the portal vein, and oxygen-rich blood via the hepatic artery, which contains
circulating hormones. During glucose metabolism, periportal hepatocytes execute
gluconeogenesis.

How does Rotor syndrome cause conjugated hyperbilirubinemia?
This phenomenon is a result of impaired hepatocellular storage of conjugated bilirubin
that leaks into plasma causing hyperbilirubinemia. Its presenting symptom is jaundice,
but Rotor Syndrome is a benign and self-limiting disorder that does not require
treatment.

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Dubin–Johnson syndrome (DJS) is a rare, autosomal recessive,
benign disorder that causes an isolated increase of conjugated/
direct bilirubin in the serum. This condition is associated with a
defect in the ability of hepatocytes to secrete conjugated bilirubin
into the bile. Impaired biliary excretion of bilirubin glucuronides is
due to a mutation in the canalicular multiple drug‐resistance
protein 2 (MRP2). Usually, no treatment required.
Rotor Syndrome: Autosomal recessive defect in organic anion
transporting polypeptides 1B1 and 1B3 (OATP1B1/B3), which
transport bilirubin and other compounds from the blood into the
liver so that they can be cleared from the body. Liver cells are not
pigmented. Can produce jaundice.
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Summary
Synthesis of heme starts from
glycine and succinate and
continues with a series of
reactions that occur in both
mitochondria and the cytosol.
Defects in heme synthesis lead
to porphyrias, relatively rare
congenital defects in synthetic
enzymes.
Lead poisoning leads to anemia
through effects on
ferrochelatase and ALA
dehydratase.
Heme is oxidized to bilirubin in
macrophages and conjugated in
the liver for secretion into bile
and excretion in the feces.
Defects in heme degradation
and secretion lead to jaundice,
which is a symptom of
hyperbilirubinemias.
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Summary

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Hepatocellular jaundice
It occurs when bilirubin is unable to leave the liver cells and cannot be removed from the
body by the kidneys. Hepatocellular jaundice is usually caused by liver failure, liver disease
(cirrhosis), hepatitis (inflammation of the liver), or by taking certain types of medication.

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