5 Hemoglobin.pdf

Transcript

Hemoglobin
Presented by Dr. Zahi Damuni
Professor of Biochemistry
Reading: Lippincott Reviews in Biochemistry, 8th Ed., Chapter 3

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Office hours: Typically, online via https://teach.webex.com/meet/zahi.damuni and
will be announced in advance
Email for questions or to set up a one-on-one meeting: [email protected]

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Learning Objectives
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Understand myoglobin and hemoglobin with respect to α-helical structure, the role of
nonpolar interactions for the tertiary structure, and the roles of non-covalent interactions,
proximal histidine and distal histidine for heme binding to the apoprotein.
Understand the subunit structure of major adult hemoglobin and fetal hemoglobin and specify
the interactions between subunits.
Illustrate the reversible, coordinate covalent nature of oxygen binding to the heme iron and the
importance of the iron being in the ferrous state.
Understand the binding of 2,3-bisphosphoglycerate to adult hemoglobin and to fetal
hemoglobin.
Understand the combined effects of carbon dioxide, hydrogen ions and 2,3bisphosphoglycerate on oxygenation of hemoglobin in the lungs and in the tissues.
Identify changes in protein structure due to mutations and deletions of globin genes that lead
to disease.
Understand the competitive interaction between carbon monoxide and oxygen in carbon
monoxide poisoning and name the therapeutic approach.
State the chemical differences between hemoglobin and methemoglobin and main causes of
methemoglobin formation.
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Hemoproteins
•

This is a group of specialized proteins that contain heme as a tightly bound prosthetic
group.

•

Role of the heme group is dictated by the environment created by the 3-dimensional
structure of the protein.
1.

The heme group functions as an electron carrier in cytochromes.

2.

The heme group is a part of the active site of catalase which catalyzes the
breakdown of H2O2.

3.

The heme group serves to bind oxygen reversibly in hemoglobin and myoglobin.

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Heme
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Heme consists of a planar porphyrin ring
with an iron (Fe2+) in the center
Methyl (1C) and vinyl or propionate (3C)
side chains
Fe2+ can form 6 covalent bonds:
• 2 covalent and 2 coordinate bonds
with N’s in the porphyrin ring
• 1 coordinate bond with a His-residue in
the globin chain and another 1 with
oxygen

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A coordinate covalent bond, also known as a dative bond or coordinate bond is a
kind of 2-center, 2-electron covalent bond in which the two electrons derive from the
same atom.

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Myoglobin
•

A monomeric heme protein found in skeletal and
heart muscle

•

Has 153 amino acid residues (Human Mb)

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80% of the polypeptide chain is folded into 8 stretches
of -helix (labeled A to H)

•

Interior is composed almost entirely of non-polar
amino acids
• Stabilized by hydrophobic interactions

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heme

Charged amino acids are located mostly on the surface
• Can form hydrogen bonds with water

“proximal”
histidine

“distal”
histidine

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Myoglobin
Forms a crevice that almost completely encloses a heme group
o Hydrophobic interactions between the porphyrin ring of heme and
the amino acid R-groups on the interior of the protein cleft
stabilize the heme-protein conjugate
o Cleft contains 2 histidine residues:
 Proximal histidine (His F8) – binds directly to the iron in heme
 Distal histidine (His E7) – function to assist O2-binding
o A Phe residue is also at the surface of the cleft helping to hold the
heme in place
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Oxygenation of myoglobin is accompanied by movement of the iron atom, and consequently
movement of His F8 and residues covalently linked to His F8, toward the plane of the ring.
Oxygenation brings about a new conformation.
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Hemoglobin: A Tetrameric Protein
Found Mainly in RBC
Hemoglobin is a tetramer
composed of two non-identical
subunits.
Each subunit has a heme
prosthetic group identical to
that described for myoglobin

Types of Hb
Embryonic/Fetal/Adult
Adult: HbA α2β2 – 96%
HbA2 α2δ2 – 3%
HbF α2g2 – 1%
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Hemoglobin
at Various
Stages of
Development

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•

•

-chains have 141 amino acid residues

•

-chains have 146 amino acid residues

Even though the amino acid sequences differ, the 3-D structures of the - and chains of hemoglobin are similar to each other and to the single polypeptide chain
of myoglobin

Myoglobin and the  subunits of
hemoglobin have almost identical
secondary and tertiary structures

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Hemoglobin
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Functionally composed of 2  dimers
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Subunits in the tetramer are held together by:
1. Inter-chain hydrophobic interactions
2. Ionic interactions

3. Hydrogen bonds
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 dimers can move with respect to each other
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 dimers occupy different relative positions in deoxyhemoglobin
compared to oxyhemoglobin

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This movement enables hemoglobin to exist in 2 stable states
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Hemoglobin States
1. A stable inactive “taut” or “tense” (T) state
• Low oxygen affinity
• Resists the binding of oxygen
• Deoxygenated
2. A stable active “relaxed” (R) state
• High oxygen affinity
• Binding of oxygen is facilitated
• Oxygenated
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The 11 and 22 interfaces are the strongest
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35 residues
form the
interface
between
11 and 22

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19 residues form the
interface between
12 and 21

Interactions
between 1 and 1
and between 2 and
2 are dominant &
change little in the Tto-R conformational
change.
The major shifts are
at the interfaces
between 1 and 2
and 2 and 1.
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Oxygenation of Hemoglobin is Accompanied by
Conformational Changes Near the Heme Group

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The conformational
change at histidine F8 is
transmitted throughout
the peptide backbone
resulting in a significant
change in tertiary
structure of the entire
subunit.

pink

is

the

changed (new)
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t
a

Ibecomes
relaxed

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Distal Histidine (E7)

• Highly conserved throughout evolution
• Prevents oxidation of Fe2+ to Fe3+
• Reduces binding of CO in place of O2
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On the side of the heme group opposite the proximal histidine, where oxygen
reversibly binds, is another histidine residue called the distal histidine. This residue
serves two very important functions in the polypeptide. First, it prevents oxidation of
the iron ion to a higher oxidation state by any number of possible nearby oxidizing
agents. At a higher oxidation state, the iron (Fe+++) is unable to bond to oxygen.
Secondly, this histidine residue acts to reduce carbon monoxide (CO) binding to the
heme. If the distal histidine was absent, even low levels of CO would greatly interfere
with oxygen binding. The heme group alone (in the absence of the surrounding
protein of myoglobin or hemoglobin) has a much greater bonding affinity for carbon
monoxide than for oxygen.

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Binding of Oxygen to One Heme of
Hemoglobin Leads to:
• Changes in conformation at the subunit surface
• A new set of binding interactions between adjacent subunits which
are associated with
• Disruption of salt bridges and the formation of new salt bridges

•
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• The formation of new hydrogen bonds and new hydrophobic
interactions
Alterations in the quaternary structure (T to R)
Increased affinity of the hemoglobin molecule for subsequent
oxygen molecules
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Each pair of  and  subunits stay
relatively in the same position to
each other under both oxygenated
and deoxygenated states.
• Deoxy -  and  subunit pairs
twist relative to other pair
• Oxy -  and  subunits twist
back to reform salt bridges

Looking down from above the 2 alpha subunits

2,3BPG

Deoxyhe
moglobin

Oxyhemo
globin

Looking from side with the 2 alpha subunits above beta subunits

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The Difference In Function Between Myoglobin &
Hemoglobin Stems From Their Difference In Structure
• Myoglobin – can bind only 1 molecule of oxygen because it contains only
1 heme group
• Hemoglobin – can bind 1 oxygen molecule (O2) at each of its 4 heme
groups
• Oxygen Binding Curve (also termed Oxygen Dissociation Curve, Oxygen
Saturation Curve)
• A plot of the degree of saturation (Y) of the oxygen binding sites
measured at different partial pressures of oxygen (pO2)
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• Function of Myoglobin
• Binds oxygen released by hemoglobin at the low pO2 found in
muscle
• Releases oxygen within muscle cell in response to oxygen
demand
• Function of Hemoglobin
• Transports O2 from the lung to peripheral tissues
• Transports carbon dioxide and protons from peripheral tissues
to the lung for subsequent excretion

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Myoglobin

Oxygen Saturation Curve is
hyperbolic in shape

• pO2 in lung capillary bed ~ 100 mm Hg
• pO2 of venous blood ~ 40 mm Hg
• pO2 of active muscle ~ 20 mm Hg
1. pO2 of muscle tissue during oxygen
deprivation that accompanies strenuous
physical exercise ~ 5 mm Hg
2. At 5 mm Hg, myoglobin readily releases its
bound oxygen for oxidative synthesis of ATP
by muscle mitochondria
3. Since myoglobin cannot deliver a large
fraction of its bound oxygen even at 20 mm
Hg, it cannot serve as an effective vehicle
for delivery of oxygen from lungs to
peripheral tissues
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Oxygen Binding Curve for Hemoglobin
Demonstrates Cooperativity
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The steep slope over the range of
oxygen concentrations that occur
between the lungs and the tissues
permits hemoglobin to carry and
deliver oxygen efficiently from sites of
high pO2 to sites of low pO2
Cooperative binding allows
hemoglobin to deliver more oxygen to
the tissues in response to relatively
small changes in the partial pressure
of oxygen

pO2 in lung capillary bed
~ 100 mm Hg
pO2 of venous blood ~
40 mm Hg
pO2 of active muscle ~
20 mm Hg

Lower P50 = higher affinity for oxygen
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Binding of Ligands That Affect Hemoglobin’s Oxygen Binding
Examples:
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H+

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CO2

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2,3-bisphosphoglycerate

H+, CO2 and 2,3-BPG bind Hb in the T form,
i.e., the deoxy form, shifting the
equilibrium between the R and T states
toward the T, i.e., the low affinity form. This
shifts the oxygen binding curve to the right
i.e., hemoglobin is less saturated at a given
partial pressure of oxygen.
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Torr is a unit of pressure equivalent to 1 mm of mercury in a barometer and equal to
133.32 pascals.

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2,3-Bisphosphoglycerate
• Synthesized from 1,3bisphosphoglycerate (an
intermediate of the glycolytic
pathway)
• Present in small amounts in
all cells
• Most abundant organic
phosphate in Red Blood Cells
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2,3-Bisphosphoglycerate
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Binds to hemoglobin in
central “donut” cavity

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Cavity is of sufficient size
only when hemoglobin is
in the T form

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Its oxygen atoms form salt
bridges with positivelycharged side chains in the
cavity

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2,3-Bisphosphoglycerate
Important for the normal oxygen
transport function of hemoglobin

Permits greater unloading of
oxygen in the capillaries of
tissues
Hemoglobin deficient in 2,3bisphosphoglycerate acts as an
“oxygen trap” rather than an
oxygen transport system.

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2,3-Bisphosphoglycerate
2,3-Bisphosphoglycerate concentration increases in response to:
• Chronic hypoxia, e.g., high altitude
• Chronic anemia e.g., when fewer than normal red blood
cells are available to supply the body’s oxygen needs

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2,3 BPG and Smoking
• Blood of smokers displays reduced levels of 2,3 BPG relative
to non-smokers
• Thus, oxygen release from hemoglobin to the peripheral
tissues may be reduced

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Carbon Monoxide Poisoning
• Carbon monoxide (CO)
• Binds tightly but reversibly to the hemoglobin iron
forming carbon monoxyhemoglobin (HbCO)
• Shifts hemoglobin to relaxed conformation causing the
remaining heme sites to bind oxygen with high affinity

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Carbon Monoxide Poisoning
Carbon Monoxide (CO)
• Shifts the oxygen binding curve to
the left
• Changes the normal sigmoidal
shape toward a hyperbola
• Affected hemoglobin releases less
oxygen to the tissues
• 50% CO-Hb is lethal but mainly
because CO has poisoned
cytochrome oxidase
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Carbon Monoxide Poisoning
Treatment is to administer
pure O₂ and simultaneous
5% CO₂ which strongly
stimulates respiratory
center to increase alveolar
ventilation and decrease
alveolar CO.

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Methemoglobin
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Contains iron in the ferric (Fe3+) state

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Does not bind oxygen (flat oxygen
binding curve)

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Contains water at the sixth coordinate
position

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Forms in response to certain drugs,
H2O2, free radicals or mutations in the 
or  chain

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Normal, but occasional, formation is
corrected by NADH-cyt b5 reductase
present in erythrocytes
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Methemoglobin
In cyanide poisoning:
1. Vitamin B12 administration is the first line of treatment
2. Second line of treatment: Amyl nitrite is administered with other
agents e.g., sodium thiosulfate and sodium nitrite
3. Hemoglobin is oxidized to produce methemoglobin
4. Methemoglobin sequesters the circulating cyanide
5. Inhibition of ETC by cyanide is reduced and prevented

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Fetal Hemoglobin, Hb F
• Has a higher affinity for O2 than
maternal Hb A
• Structure is 2g2
• Binds less strongly to 2,3-BPG
than does Hb A since a serine in
gamma globin replaces histidine
143 in beta globin

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Mutations in Globin - Hemoglobinopathies
Hemoglobinopathies: A fascinating array of familial diseases affecting many aspects of
hemoglobin biology. Abnormal hemoglobin subunits are associated with hemoglobinopathies
Thalassemia is underproduction of one type of hemoglobin subunit
• Most mutations are in regulatory gene
• α thalassemia –
• One of 4 gene copies are not expressed
• ↓ α leads to ↑ death
• β subunits form tetramers and g subunits form tetramers
• β thalassemia – (microcytic anemia)
• One copy mutated or not expressed or incorrectly spliced
• Anemia
• Sickle cell anemia - point mutation in Hb → Hb S (Glu → Val at amino acid 6)
• Chronic hemolytic anemia - Hb point mutation → Hb C or Hb E
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Hereditary persistence of fetal hemoglobin (HPFH) is a benign condition in which
significant fetal hemoglobin (hemoglobin F) production continues well into
adulthood, disregarding the normal shutoff point after which only adult-type
hemoglobin should be produced.
Hemoglobin Gun Hill is an unstable mutant hemoglobin associated with mild
compensated hemolysis. This abnormal protein has a deletion of five amino acids in
the β-chains. Hb Barts (gamma 4) and HbH (beta 4) in alpha-thalassemia

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Other Examples of Hemoglobinopathies
HbE-Gower 1 ( ζ2ε2) and HbE Gower 2 (α2ε2)
Hb Barts (g4) and HbH (4) in -thalassemia

There are many others (- and -thalassemias, Hb Gun Hill , HPFHb etc.)

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Hereditary persistence of fetal hemoglobin (HPFH) is a benign condition in which
significant fetal hemoglobin (hemoglobin F) production continues well into
adulthood, disregarding the normal shutoff point after which only adult-type
hemoglobin should be produced.
Hemoglobin Gun Hill is an unstable mutant hemoglobin associated with mild
compensated hemolysis. This abnormal protein has a deletion of five amino acids in
the β-chains. Hb Barts (gamma 4) and HbH (beta 4) in alpha-thalassemia

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Diabetes and HbA1c
• Blood glucose level is normally around 90-100 mg/dL (~ 5.6 mM)
• At this concentration, some HbA gets glucosylated nonenzymatically to form HbA1c

• In uncontrolled diabetes, blood glucose can increase more than
twice normal – this generates more HbA1c than normal
• HbA1c has a long half-life compared to insulin and thus its
measurement can give information on how well a patient’s diabetes
has been controlled over several months
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teaser

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Summary
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Hemoproteins – Mb and Hb - similarities, differences and functions
Co-operative binding of oxygen by Hb
H+, CO2, 2,3- biphosphoglycerate
CO poisoning
Methemoglobin
Fetal Hb
HbA1c

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