BIOC 312 Lecture 8-4 Heme Synthesis and Degradation PDF

Summary

This lecture covers the heme synthesis pathway and breakdown, including the structure and functions of porphyrins. It also discusses the diseases caused by defects in this pathway, porphyrias, such as chronic hepatic porphyria (PCT). This lecture is about various aspects of heme metabolism. It details the synthesis steps and the role of enzymes. The lecture also details the degradation and the transfer of bilirubin to the liver.

Full Transcript

Conversion of amino acids
to specialized products
Nucleic acid metabolism
 Porphyrins
Porphyrins:
Are cyclic
compounds that
readily bind metal
ions: ferrous or
ferric ion.
Four pyrrole rings
The formation of
complexes with
metal ions bound
to the nitrogen
atom of the
pyrrole ring.
Porphyrins
 Structure
A) Side chains:
May vary in the nature of the said chains attached
to each of the four pyrrole rings.
Uroporphyrin I has Acetate and Propionate side chains
Coproporphyrin has Methyl and Propionate side chains
Protoporphyrin IX has Methyl, Vinyl and Propionate
 Structure
B) Side chains distribution:
Only Type III porphyrins are normally important for humans.

asymmetric
Symmetric
 Porphyrins
Example of some important human and animal hemeproteins :

Rapidly synthesized and degraded
Structure of Heme
Ferrous iron (Fe2+)
V
Protoporphyrin IX: contains
tetrapyrrole rings linked M

together by methenyl bridges
I

M M
IV II
P V

III
The side chains are:
methyl = M M

vinyl = V
propionyl = P
P
Where does heme biosynthesis take place?
1- Hepatocytes
Synthesizes 15% of
heme proteins
particularly
Cytochrome P450
Rate of heme
2- synthesis is variable
(alteration of heme
pool).
Erythrocyte-producing
cells –bone marrow
Active in HB synthesis
Rate of heme synthesis is
constant
About 85% of heme
occurs in Erythroid tissue.

Note: mature RBCs can NOT make heme??????
 Where exactly in the cells?
The pathway takes place in the mitochondria
and the cytosol
The pathway starts and ends at the
mitochondria
 Heme synthesis
steps process
1 and 2 Formation of a pyrrole molecule: a
compound containing four carbon atoms and
one nitrogen atom joined in a ring structure

3 Linkage of four pyrrole molecules to form a
linear tetramer

4 Formation of the porphyrin (tetrapyrrole) ring

5-7 Decarboxylation and oxidation
8 Incorporation of the iron atom
 First step in heme pathway is a
committed step
It’s involve a condensation reaction
between Glycine (a nonessential amino
acid) and succinyl CoA (an intermediate
from TCA cycle).
This reaction is catalyzed by the
mitochondrial enzyme Aminolevulinic
acid synthase (ALAS) which requires
Coenzyme PLP
Rate limiting step in the heme synthesis
pathway.
There are two isoforms of this enzyme:
ALA-S1 is located in all tissues
ALA-S2 is produced in erythroid tissue.
 Succinyl
Glycine + CoA
_
end product
1 Pyrrole formation Aminolevulinic acid
synthase (ALAS1)

2 Aminolevulinic acid
Pyrrole formation (ALA)
2
H2O ALA dehydratase Or PBG synthase

4 Porphobilinogen (PBG)
3 Linear tetrpyrrole Hydroxymethylbilane synthase

Hydroxymethylbilane
4 Tetrapyrrole ring Uroporphyrinogen III synthase

Uroporphyrinogen III
CO2 Uroporphyrinogen decarboxylase
5 Decarboxylation
Coproporphyrinogen III
Hemin
6 Decarboxylation/ oxidation CO2 Coproporphyrinogen oxidase

protoporphyrinogen IX
oxidation protoporphyrinogen oxidase
7
Ferrochelatase
protoporphyrin IX Heme
Fe+2 8 Heme formation
 Effect of alcohol and drugs on heme
synthesis

ALAS1 CP450
Alcohol/drugs
Detoxification
of drugs

heme

Low level of heme in liver cells -> increase the synthesis of ALAS1-
> ALA synthesis
 Succinyl
Lead poisoning Glycine + CoA

Aminolevulinic acid
synthase

2 ALA

ALA dehydratase Lead
4 Porphobilinogen 1- factory workers
2- kid eats paint
Hydroxymethylbilane synthase containing lead

Hydroxymethylbilane
Uroporphyrinogen III synthase

Uroporphyrinogen III
Uroporphyrinogen decarboxylase

Coproporphyrinogen III
Coproporphyrinogen oxidase

protoporphyrinogen IX Lead
protoporphyrinogen oxidase
Ferrochelatase
protoporphyrin IX Heme
Fe+2
Porphyria: Vampire disease

Porphyrias are rare metabolic diseases resulting from a defect
(Deficiency of an enzyme) in heme biosynthesis.
It’s result in the accumulation of porphyrins or porphyrins
precursors.
It classified as:
1) hepatic porphyria (chronic or acute)
2) erythropoietic porphyria
 Succinyl
Chronic hepatic Glycine + CoA
porphyria
or porphyria cutanea tarda Aminolevulinic acid
(PCT) synthase
Chronic Liver disease
2 Aminolevulinic acid
Most common porphyria
Patient are photosensitive
Aminolevulinate dehydratase

4 Porphobilinogen
Hydroxymethylbilane synthase

Kidney
Hydroxymethylbilane
Uroporphyrinogen III synthase

Photoactive Built up
Uroporphyrinogen III
molecule that Uroporphyrinogen
is able to PCT
decarboxylase
absorb UV Coproporphyrinogen III
light from the Urine red to brown
Coproporphyrinogen oxidase
sun causing
(sun burn) protoporphyrinogen IX
protoporphyrinogen oxidase

Ferrochelatase
protoporphyrin IX Heme
Fe+2
 Succinyl
Acute hepatic Glycine + CoA
porphyria
Or hepatic acute intermittent Aminolevulinic acid
porphyria (AIP) synthase
drugs
2 ALA
Built up
ALA dehydratase

4 PBG
Hydroxymethylbilane synthase In AIP
Kidney
Hydroxymethylbilane
Uroporphyrinogen III synthase

Uroporphyrinogen III
Uroporphyrinogen decarboxylase Urine turns
dark Red
Coproporphyrinogen III
Coproporphyrinogen oxidase

protoporphyrinogen IX
protoporphyrinogen oxidase

Ferrochelatase
protoporphyrin IX Heme
Fe+2
 Degradation of Heme
Hb in RBCs life span
is around
120 days

About 80-85% of heme
comes from RBC
myoglobin

Heme

Cytochromes
 Location of heme degradation
Macrophage system (reticuloendothelial
system) of RBC mainly occurs in liver and
spleen.
 Degradation of Heme

Hemoglobin

Heme
Globin

Fe2+
Return to Bilirubin Amino acids
body iron
stores

Excreted
Degradation of Heme

Microsomal heme oxygenase in
macrophage catalyzes three
oxygenations results in:
a) Open porphyrin ring -> biliverdin
b) Release Fe2+ as Fe3+
c) Release CO
Biliverdin is reduced to bilirubin by
biliverdin reductase enzyme.

1
Formation of
bilirubin
Degradation of Heme
Bilirubin is transferred to the
liver as a (bilirubin-albumin
complex). 2
Uptake of
Bilirubin dissociate from bilirubin by the
albumin and enter hepatocytes liver
and binds to ligandin.
The bilirubin is made more
soluble by conjugation with two
glucuronic acid from ( donor 3
UDP-glucuronic acid) in a Formation of
reaction catalyzed by bilirubin CB
UDP glucuronyl transferase
(UGT) -> Bilirubin diglucuronide
or conjugated bilirubin (CB) (conjugated bilirubin)
which is secreted into bile. 4
Secretion of
Unconjugated bilirubin is not bilirubin into bile
secreted into bile
 Summary of
the bilirubin
metabolism

Urobilin excreted in urine
Formation of colorless urobilinogen by bacteria in the intestine
Stercobilin excreted in stool
2-5%

20%
 Disorder linked to heme degradation
pathway: Jaundice

Definition Jaundice:
is the clinical syndrome refers to yellow color of skin, nails and sclerae caused by
bilirubin deposition ( elevated bilirubin levels in blood above the normal level < 1
mg/dl | hyperbilirubinemia).
Types of jaundice

Jaundice

prehepatic hepatic Post-hepatic
Prehepatic jaundice: Hemolytic
jaundice
Liver can conjugate and excrete >
3000 mg bilirubin/day - normal is
300 mg/day.
Massive hemolysis causes more
than can be processed may be
due to sickle cell anemia (PK or
G6PDH deficiency)
Ø It produces faster bilirubin that
cannot be conjugated ->
increased unconjugated bilirubin
(UCB) in blood.
Ø Increased CB excreted into bile
Ø Urobilinogen is increased in
blood, urine
 Hepatocellular jaundice
Damage of liver cells (cirrhosis or
hepatitis) causes unconjugation
hyperbilirubinemia as a result of
decreased conjugation.
CB is made but not efficiently
secreted from liver to bile (leak
into the blood so CB is elevated
in blood)
Urobilinogen is increased in
urine because hepatic damage
decreases the enterohepatic
circulation more goes to urine
the urine is darker and stool is
pale, clay-colored
AST and ALT levels are elevated
due to hepatic damage
Post-hepatic: Obstructive jaundice
Obstruction of the bile duct
– Tumor or bile stones
– Prevents passage of CB into
intestine
– GI pain and pale, clay-colored
stools
– Increased CB in blood excreted
in urine (darker)
 Jaundice in newborns
Most newborn infants shows a rise in
UCB in the first prenatal week
because the enzyme bilirubin UGT is
low.
Maximum expression (adult
level) at ~ 4 weeks
Excess UCB can cause toxic
encephalopathy
Elevated bilirubin is treated with
blue fluorescent light
converts bilirubin to more polar
compound (water soluble
isomers)
can be excreted in bile without
conjugation
Catecholamines and melanin
 Catecholamines
Biologically-active water-soluble amines derived from tyrosine that
serve as:
– neurotransmitters in the CNS
– hormones in circulation in response to psychological stress (fight
or flight response) or hypoglycemia:
Dopamine and Norepinephrine are synthesized in the brain
Epinephrine (adrenaline) are synthesize in the adrenal medulla
Function:
1. Catecholamines act as regulators of carbohydrate and lipid
metabolism
2. They are released from storage vesicles in the adrenal medulla in
response to fright, exercise, cold and low level blood glucose
3. They increase the degradation of glycogen and triacylglycerol,
blood pressure and the output of the heart
Melanin
Is a pigment occurs in several
tissues eye, hair and skin.
It is synthesized from tyrosine in
the epidermis by pigment
forming cells called melanocytes.
It is function to protect cells
from harmful effects of sunlight.
Albinism results from a defect in
melanin production due to
defects in copper-containing
tyrosinase.
 Synthesis of melanin
Melanocytes
Melanin
Albinism Cu2+ containing
tyrosinase
Synthesis of Catecholamines

Rate limiting step
hydroxylation decarboxylation

hydroxylation

methylation
 Degradation of
Catecholamines
Once released, catecholamines have a
half-life of 1 min due to subsequent
inactivation. It is degraded by:
1) Monoamine oxidase (MAO) inactivates
catecholamines by oxidative
deamination to yield the aldehyde which
oxidized to corresponding acids urine
2) Catechol-O-methyltransferase (COMT)
inactivates catecholamines by
methylation using S-adenosylmethionine
(SAM) as the one-carbon donor
MAO inhibitors block catecholamine
degradation, allowing their accumulation
in the presynaptic neuron and subsequent
leakage into circulation, providing an
antidepressant action.
urine
Histamine Synthesis
Histamine is a chemical
messenger mediating a range
of cellular responses including:
allergic, inflammatory
reactions and gastric acid
secretion.
Powerful vasodilator decarboxylation
PLP

Synthesized by histidine
decarboxylase in a reaction
requiring PLP

It is secreted by mast cells as a
result of allergic reactions or
trauma.
Serotonin Synthesis
§Serotonin also called
5’hydroxytryptamine is synthesized
predominately in the GI tract hydroxylation

§Synthesized from tryptophan

§Inactivated by MAO

§It has multiple physiologic roles
including
decarboxylation
§ Pain perception
§ Regulation of sleep, appetite,
temperature, blood pressure,
cognitive function and mood
 Amidino
group

Creatine Synthesis

§Amidinotransferase is a mitochondrial
enzyme catalyzing the rate-limiting step
of the pathway Kidney

§Methyltransferase uses S-
Adenosylmethionine SAM as a one-
carbon donor to yield creatine
SAM
§Creatine kinase catalyzing the Liver
phosphorylation of creatine using ATP as
the phosphate donor

§ Degradation: Creatine and Creatine
phosphate spontaneous cyclizes to
creatinine, which is secreted in the urine phosphorylation
§Serum creatinine level is routinely Brain, Heart
measured on admission as a test of And Skeletal muscle
kidney function. Kidney impairment
results in elevated serum creatinine
urine