2-10 Hemoglobinopathies + Associated Anemias.pdf

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LO3. Describe the etiology, pathogenesis, morphological changes, clinical presentation, complications, laboratory data, treatment, and prognosis of β- and ⍺thalassemia

α-Thal: HbH Disease
•
•
•
•
•

(α/- -/-) —> β4 tetramers (HbH)
PBS: similar to ß-thal intermedia
Clinical manifestations: similar to ß-thal intermedia
Hb electrophoresis: HbH
Supravital stain: HbH aggregates (similar to Heinz bodies)

41

LO3. Describe the etiology, pathogenesis, morphological changes, clinical presentation, complications, laboratory data, treatment, and prognosis of β- and ⍺thalassemia

α-Thal: Hb Barts Disease

• (-/- -/-) = no ⍺-globin genes —> excess of γ-globin —> formation of
γ-globin tetramers (Hb Barts)
• High affinity to Hb Barts to oxygen —> no oxygen delivery to tissues
st
nd
• Survival of an embryo/fetus in the 1 and 2 trimesters is possible
due to synthesis of ζ2γ2 (Hb Portland) that is capable to deliver
oxygen to peripheral tissues
• Trimester 3: rapid fetal growth, decline of Hb Portland production —
> an increase in tissue hypoxia —> anoxia —> hydrops fetalis:
severe pallor, generalized edema and massive hepatosplenomegaly
—> death in utero or soon after delivery

- Survival is possible only with intrauterine blood transfusion
42

LO3. Describe the etiology, pathogenesis, morphological changes, clinical presentation, complications, laboratory data, treatment, and prognosis of β- and ⍺thalassemia

α-Thal: Newborn Infant with Hydrops Fetalis

https://commons.wikimedia.org/wiki/File:Newborn_infant_with_severe_hemolytic_disease_(erythroblastosis_foetalis)_resulting_in_hydrops_foetalis.png
43
Benkerroum Zineb, Lachiri Boutaina, Lazrak Ikram, Moussaoui Rahali Driss, Dehayni Mohammed, CC BY 4.0 <https://creativecommons.org/licenses/by/4.0>, via Wikimedia Commons

LO3. Describe the etiology, pathogenesis, morphological changes, clinical presentation, complications, laboratory data, treatment, and prognosis of β- and ⍺thalassemia

Summary of Lab findings in Thalassemias (α and β
•) RBC count: normal-to-increased (very characteristic)
• MCV: low
• PBS

-

Microcytic hypochromic RBCs
Target cells
Polychromatophilic RBCs
Fragmented RBCs
Nucleated RBCs (normoblasts)

-

β-thal minor: moderate increase in HbA2 and HbF
β-thal major: moderate increase in HbA2 and severe increase on Hb F
α-thal trait: normal HbA and HbA2
HbH disease: increased HbH (β4)
67
Hb Barts disease: increased Hb Barts (γ4)

• Hb electrophoresis

44

67

The End

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Slide 1

Hemoglobinopathies - Genetics
(hemolytic anemias)
Hemoglobin gene diseases
Dr. Larsen
Turningpoint id: Larsen
1

Slide 2

Correlate changes in fetal expression pattern of hemoglobin (Hb) with
onset of Hb diseases
Explain molecular mechanisms causing disease and modulating disease
severity in the different Hb diseases
Recognize inheritance pattern of the Hb diseases and apply that knowledge
to family counseling (including risk calculation)

Learning
Objectives

List and explain the clinical presentation, etiology, pathogenesis, diagnosis,
laboratory data, complications and treatments of the Hb diseases
Interpret results from electrophoretic and other DNA/protein methods
applied to Hb diseases
List and explain the interaction of thalassemia mutations with structural Hb
variants
Reading: Emery’s elements of medical genetics (15th ed.) pp 154-162

Sample questions in Canvas

Lectures presenting relevant material include Hemoglobin, Risk Calculation,
DNA Technology. We will assume you known this material.

2

Slide 3

Overview
• Introduction
• Diseases involving changed protein sequence
• Diseases involving protein truncation or reduced expression
• Mixed forms
(some concepts visited more than once)
Clinico-Pathologic Correlations of these diseases will be
presented by Dr. Yakubovskyy next hour
3

Slide 4

Tetramers
• All hemoglobin proteins (should) consist of 2 α-like + 2 β-like subunits
in one tetrameric protein
• If production of β-hemoglobin is reduced 10%, so will production of αhemoglobin

• However, if production of one is reduced more than 50% - then
surplus of the other type will be seen
• Remember, Hb is found in RBC, with normal lifespan of about 120
days  constant, lifelong production
• RBC lifespan usually reduced in Hb diseases

4

You will see at later slides that the surplus of the other type of hemoglobin chain o�en is at the
center of the molecular mechanism of disease. According to the companies that make review
courses for NBME step exams, molecular mechanisms are important!

Slide 5

Routine identification
• Protein electrophoresis under two different
conditions together identifies most common
variants
• Cellulose acetate at pH 8.6
• Citrate-agar at acidic pH

• Or iso-electric focusing can do the same in one gel
• More advanced problems are sent to specialty
labs.
[Document on protein electrophoresis in Canvas]
5

Please use �me to understand the electrophoresis of hemoglobins and what the expected
electrophoresis patern would be for genotypes in each disease.

Slide 6

Hemoglobin Gene Expression

6

This slide shows you when hemoglobin molecules are produced. No�ce that on any given point
in �me, the majority of RBCs that are present were produced weeks to months earlier. Also,
No�ce the �ming of expression switch from gamma to beta.

Slide 7

Caption and info

•
•
•
•
•
•

HbGower(1) = ζ2ε2 (zeta2-epsilon2)
HbGower(2) = α2ε2 (alpha2-epsilon2)
HbPortland = ζ2γ2 (zeta2-gamma2)
HbF = α2 γ2 (alpha2-gamma2)
HbA = α2 β2 (alpha2-beta2)
HbA2 = α2 δ2 (alpha2-delta2)

C
E
O

D
G
Lepore

Portland

• Expression switch involves epigenetics (methylation) of genes no
longer needed
• Hemoglobin types
Application
Barts
A
F
S
A2

H

Adult

Newborn

7

You need to be cognizant of which chains are found in each of HbF, HbA, HbA2 – and from later
in the lecture, HbS, HbC, HbE, HbH, Hb Barts proteins.
Epigene�cs is a term you heard about in FFM1 and you will hear more about in Reproduc�ve.
For now, remember that it does not refer to changing the DNA sequence but to changing access
to the DNA and therefore altera�on of the expression patern of proteins.
Notes about the electrophoresis: here are presented the expected patern in an adult and in a
newborn. The adult produces a lot of beta chain which combines with alpha to become HbA,
and small amounts of delta which together with alpha becomes HbA2. The thin line to the le� in
the adult therefore indicates this lower amount of HbA2, and the much heavier band under HbA
indicates the α2 β2 .
In the newborn as expected, the majority of the protein produces is HbF and about 20% HbA.
HbA2 is not yet present at that age.

Slide 8

Hemoglobin Gene Clusters

• All α-like genes in one cluster, all β-like in another
(on different chromosomes)
• Locus control region (LCR) upstream (5’) of it all
• Progression so that more downstream genes are
more heavily expressed later in development
8

Alpha hemoglobin genes on 16pter-16p13.3
Beta hemoglobin genes on 11p15.5
The chromosomal loca�on will not be tested!
The Greek leter Psi used in front of some of the genes listed above indicates a pseudogene = an
inac�ve copy of a gene.

Slide 9

Variants and alleles
• More than 1000 variants described, most neutral
• OMIM lists 522 alleles of the β-hemoglobin gene

• Variants are Hb with changed amino acid content (usually from point
mutation) – and those causing disease are pathological variants
• Alleles include both those causing variants and those with reduced
expression
• Each variant is caused by a different allele at the DNA/gene level
• Heterozygote frequency can be very high in some populations

9

Slide 10

Diseases due to changed
Hb proteins
Mutations in beta-hemoglobin:
Sickle Cell Disease and
Hemoglobin C disease
These are autosomal recessive

10

Slide 11

Hemoglobin S: Sickle Cell Anemia
N:

S:

• All carriers of this anemia have exactly the same
mutation
• Mutation happened independently at least twice
• HbS: tetramer of α2βS2
11

Glutamic acid to valine (charged to uncharged) in codon #6
Note that you need to be fluent in going back and forth between the different designa�ons for
the same molecule, HbS: tetramer of α2βS2
--- HbSS is o�en used to designate a homozygote for Sickle Cell.
Regarding how many �mes the muta�on has happened (independently) – this is the text book
version. Some recent reports claim that the muta�on really only happened once.

Slide 12

Electrophoretic pattern of Sickle Cell carrier
and homozygote
A2
C
E
O

S
D
G
Lepore

F

A

Portland

Application

Barts H

N. Adult

Heterozygote
Sickle cell
homozygote

12

This is electrophoresis of na�ve protein tetramers.

Slide 13

13

High occurrence of Sickle Cell alleles in historical malaria areas

Slide 14

Why is HbS common?
• In areas with Plasmodium falciparum malaria
Genotype HbAA
Survival

HbAS

Medium Higher than HbAA

HbSS
Low

• This is known as “heterozygote advantage”
• High frequency of Thalassaemia in the Mediterranean
and east Asia probably have the same cause
• As does some enzyme deficiencies taught by biochemistry
14

Frequently used nota�on:
HbAA = homozygote normal
HbAS = heterozygote
HbSS = homozygote for sickle cell alleles
What is the mechanism of heterozygote advantage? Here we will describe one hypothesis which
builds on the fact that sickling of a red blood cell happens when the hemoglobin becomes
anoxic. In a heterozygote for sickle cell disease, the oxygen levels inside the RBC usually does
not become low enough that sickling happens. Infec�on with malaria changes this, because one
early stage of infec�on is for the parasite to enter a RBC and start dividing. This is a drain on the
oxygen of the cell, it become more anoxic than usual, and sickling is likely to happen. The sickled
cell is likely to be recognized as foreign by macrophages and therefore, parasite load is reduced
in the body of the person. With reduced parasite load comes improved survival.

Slide 15

Sickle cell disease vs Sickle cell anemia
• “Sickle cell anemia” = = = disease found in homozygote
• “Sickle cell disease”: two usages
1. Disease found in homozygote
2. Descriptor for everyone who has any sickled cells = = =
homozygotes + heterozygotes

• Heterozygotes most frequently described with “Sickle cell trait”

15

The two usages of Sickle Cell Disease are in current use in different laboratories.

Slide 16

Traits Modifying Severity of HbSS
• HbF (persistence of fetal Hb)
• α-thalassaemia trait or silent carrier (lower Hb concentration)
• HbC
• Why? Sickling is similar to precipitation. The larger the concentration
of HbS is, the more likely the patient experience sickling.
• Dr. Yakubovskyy will explain some environmental factors involved,
some of these also depends on the concentration.

16

These are all expected to improve the clinical picture. Please see individual sec�ons for more
detail

Slide 17

Molecular testing for HbS
• Restriction enzyme difference (MstII) and allele specific
oligonucleotide (ASO) hybridization presented during FFM1 (DNA
technology).

17

Therefore, I will assume this known.

Slide 18

Hemoglobin C

Heterozygote
advantage

• Glu6Lys
• Mutation happened only once in western sub-Saharan Africa
• HbC crystals seen in blood analysis

• HbAC and HbCC both significantly lower risk of Malaria death
• Significantly less pathology than HbAS and HbSS, respectively

• HbSC gives a somewhat milder sickle cell disease compared to HbSS
but worse than HbAS
• HbSC is example of compound heterozygote

18

Glutamic acid to Lysine: nega�ve charge to posi�ve charge. No�ce the codon number if 6, same
loca�on as in HbS
Compound heterozygote: person carrying two different disease causing alleles in the same
gene.

Slide 19

Diseases with diminished
production of Hb
Thalassemia (American English)
Thalassaemia (British English)

19

Slide 20

THALASSEMIA
Autosomal Recessive Disorder
Absence or decreased synthesis of α OR ß chains

QUANTITATIVE

HEMO

Beta-Thalassemia

GLOBIN ABNORMALITIES
Alpha-Thalassemia

Diminished beta chain synthesis

Diminished alpha chain synthesis

Common in Afro-Americans, Greeks,
Italians, East Indians and East Asians.

Common in South-East Asians and AfroAmericans

• Fetal Hb – Predominant in fetus, trace in adults HbF • Adult Hb – 95-97% adult blood – HbA -

2ß2..

• Adult Hb 2 - 1-4% adult blood – HbA2 -

2

Fetal Hb - Predominant in fetus, trace in adults - HbF Adult Hb - 95-97% adult blood - HbA - 2 2
Adult Hb 2 - 1-4% adult blood - HbA2 - 2 2

2.

2

2 2.

20

2

From NIH: Beta thalassemia occurs most frequently in people from Mediterranean countries,
North Africa, the Middle East, India, Central Asia, and Southeast Asia.

Slide 21

-Thalassemia
• Single base substitutions including frameshifts
• Rare: large deletions or insertions

• Estimates: about 60,000 people with symptomatic β-Thal born each
year, less then 300,000 alive

21

Most people with β-Thalassaemia do not survive very long!
No�ce that the more common type of muta�on is different in beta- vs alpha-thalassemia.

Slide 22

Genetics
• β-Hb production from the thalassemia allele can be none (β0) or
reduced (β+, sometimes milder versions are stated as β++) while
normal alleles can be designated βN or βWT.
• Homozygous β0 β0 or compound heterozygote β0β+ usually have βthalassaemia major
• Homozygous β+β+ usually have β-thalassaemia intermedia
• The heterozygotes with one normal allele (β0 βN, β+βN) all have βthalassaemia minor (= carrier)
• See also last section

22

Genotype-phenotype correla�on is incomplete: no�ce the use of the word usually indica�ng
varia�on among pa�ents in each group

Slide 23

Mechanism -Thalassemia
• Severely reduced production of β-Hb chains:
• α-Hb chains in surplus
• Cannot produce homo-tetramers
• Precipitation inside cells
• Centers for oxidative damage of membrane proteins and lipids

• Increased destruction of RBC precursors in bone marrow (therefore
ineffective RBC formation)
• Shortened RBC lifespan in circulation
• In contrast to sickle cell animia, this is a more constant problem.
23

For molecular mechanism of cell damage, focus on the chain that is in surplus.

Slide 24

Alpha-Thalassemia

24

Slide 25

-Thalassemia alleles
• α-Thalassemia carriers: malaria
areas of Africa and Asia
(especially south-east Asia),
rare in the Mediterranean
• Allele -thalassemia 1: usually
found in people of Asian
descent only
• Allele -thalassemia 2: African
and Asian descent

1

2

25

The drawing shows a normal copy of the gene as a blue box and a deleted copy is illustrated with
crossing out. Reminder: you have seen already that a normal chromosome would have two copies
producing alpha-Hb, so in a person with two copies of the chromosome (expected) missing one copy
lowers produc�on by 25%.
E.g., 1/3 of people from Thailand are carriers of one of these two alleles

Slide 26

-Thalassemia
Deletions on Chromosome 16,

•
•
•
•
•

A
B
C
D
E
A: silent carrier
B, C: α-Thalassemia trait (mild anemia)
D: hemoglobin H disease, moderately severe anemia
E: hemoglobin Barts disease, hydrops fetalis
Notice that HbXYZ disease and HbXYZ protein are very different from each other!
26

Hemoglobin H disease and Hemoglobin Barts disease is rare in people of African descent but
more common in people from SE Asia because of the distribu�on of the two types of alleles
(see previous slide)

Slide 27

Hb-Tetramers
• Reminder: production of alpha chains and beta-like chains are
balanced down to 50%
• Deletion of one or two alpha genes

• Deletion of three alpha chains = HbH disease  surplus of beta-like
chains
• In fetus/newborn mainly gamma-4 = HbBarts protein
• In adult mainly beta-4 = HbH protein

• Deletion of four alpha chains = HbBarts disease  surplus of beta-like
chains
• In fetus gamma-4 = HbBarts protein
27

Slide 28

a - Thal

normal

:

B-Thal

or
↓

↑ HbAz

:

HbAz

4HbF

+

HbE

+

wont

,

iron

deficiency

84 B4
Application

1

S
D
G
Lepore

Barts
A
Portland

F

H

EzUz

N Adult

-

.

2

3 newborn
WI

4 Adult

5

A2
C
E
O

HbEs present
e

WI age
2

HbH disease

&

HDH

↓

HbBarts

-

AbH

andE

-

HDA

Adult +b Barts
disease
28

Please hear the explana�on in class or on Panopto for what this slide is used for. Similar
ques�ons might appear on the exam.

Slide 29

Mechanisms alpha-thalassemia
• Imbalance of Hb with β- or γ-Hb chains not bound
to α-chains
• β- and γ-Hb chains can form homo-tetramers
• Therefore, less precipitation than in β-thalassemia

• Shortened RBC lifespan and aborted production
just like in β-thalassemia

29

The bullet sta�ng “less precipita�on” is under the assump�on of equal % reduc�on in
produc�on

Slide 30

Comparison of Thalassemias
Disease

Chain in surplus

Homo-tetramers

Precipitation

α-thalassemia β-chain (and γ-chain)

Yes

Yes, but less of the
surplus

β-thalassemia α-chain

No

Yes, all surplus

30

No�ce that the table is for severe thalassemia, not for carrier or “trait”

Slide 31

Mixed processes

Where both content and
amount of protein changes

31

Slide 32

HbE
• The HbE is a substitution GAG-to-AAG in codon 26 leading to
Glu26Lys
• This substitution also leads to altered splicing (slow removal of intron 1,
partial use of alternative splice donor around codon 26)  some products
are non-functional  reduced concentration of Hb

• HbE is common in India and South-east Asia, up to 30% allele
frequency in some areas
• Most common Hb variant in California

• Heterozygotes HbAE some protection against P. falciparum malaria

32

No�ce again change of charge of the amino acid. What is the consequence for electrophoresis?
Also no�ce the codon number, where is this rela�ve to the sickle cell muta�on?
This is a mixed process because HbE both changes an amino acid and reduces produc�on.

Slide 33

HbE phenotypes
• HbE/HbA heterozygotes near normal MCV
• HbE/HbE homozygotes frequently benign (mild hypochromic,
microcytic anemia)
• Can be classified as mild β+ thalassemia (Hb > 10 g/dL)

33

Slide 34

HbE/ -thalassemia
compound heterozygotes
• Mild (15%): 9-12 g/dL Hb – rarely need treatment except when
infections hit
• Intermediate (most): 6-7 g/dL Hb – similar to β-Thal intermedia
• Severe (rest – up to ½ in some reports): 4-5 g/dL Hb – treat as β-Thal
major
• What causes the variation?

• β0 vs β+
• Persistence of HbF to varying degrees: in many E/β0 with no HbA, 40-60% of
Hb is HbE, the rest HbF (and a little HbA2)
• Possibly difference in splicing efficiency and other modifier genes?

34

No�ce that genotype does not directly predict severity of phenotype.
Again no�ce that to understand this, you need to know which subunits are found in the
different types of hemoglobin tetramers.
Beta-thalassemia intermedia is essen�ally those who have reduc�on beyond 50% and therefore
show symptoms but who does not have a severe enough reduc�on that they need frequent
transfusions.

Slide 35

HbS/ -Thalassemia
compound heterozygotes
• Symptoms will be Sickle Cell disease, not β-Thalassemia
• Sickle cell anemia for Sβ0 (or slightly milder due to lower concentration of Hb)
• Milder for Sβ+

35

Reason for the outcome of this compound heterozygote: β-Thalassemia would be the expected
outcome when less than 50% of normal beta-chain is produced. In this case there is 50%
produc�on of beta chain. However, the fact that the beta-chain produced is of the beta-S type
with no produc�on of normal beta-chain means that the person will have sickle cell anemia.

Slide 36

Persistent HbF
• Fetal hemoglobin is <1% in most adults. (Why?)
• Some people synthesize high amounts of HbF – No significant clinical
problem
• Genetic variation at position –158 of the G gamma globin gene

• In people with HbSS, HbF constitute 2-20%
• Hydroxyuria is used experimentally to increase HbF production in βthalassemia

36

The second bullet: the high amounts of HbF in people with inherited persistent HbF will happen
even if they have no hemoglobinopathy alleles.
Hydroxyuria mechanism of ac�on may be (hypothesis!) a selec�ve destruc�on of the fastest
dividing RBC precursers – it so happens that HbF producing cells (F-cells) are dividing at a slower
pace.