W2L3 - Haemoglobinopathies

Question 1

Adult Haemoglobin Components

Answer 1

HbA - 97%
HbA2 - 2%-3%
HbF - <1%
Composed of
- HbA = α2β2
- HbA2 = α2δ2
- HbF = α2γ2

Question 2

How are the individual haemoglobin ‘types’ assessed?

Answer 2

Electrophoresis
HPLC
Isoelectric focussing

Question 3

Analytical Effects

Answer 3

In some of these disorders the RBC may be resistant to lysis by reagents employed by automated haematology analysers (AHA)
In this circumstance, routine FBC results may be affected…
- typically RBC are lysed to allow analysis of WBC
- => failure to lyse RBC => falsely increased [WBC]
- often ‘flagged’ by the analyser
Repeat analysis with extended lysis (‘lysis resistant mode’) usually rectifies the situation

Question 4

Laboratory Assessment of Hb - Electrophoresis

Answer 4

At alkaline pH, haemoglobin is a negatively charged protein and will migrate toward the anode (+)
Structural variants that have a change in the charge on the surface of the molecule at alkaline pH will separate from HbA
Haemoglobin variants that have:
- an amino acid substitution that is internally sited may not separate
- an amino acid substitution that has no effect on overall charge will not separate by electrophoresis

Question 5

Laboratory Assessment of Hb - HPLC

Answer 5

HPLC depends on the interchange of charged groups on the ion exchange material with charged groups on the haemoglobin molecule
When a haemolysate containing a mixture of haemoglobins is adsorbed onto the resin, the rate of elution of different haemoglobins is determined by the pH and ionic strength of any buffer applied to the column
Elution of the charged molecules is achieved by a continually changing salt gradient
Fractions are detected as they pass through an ultraviolet/visible light detector and are recorded
Analysis of the area under these absorption peaks gives the percentage of the fraction detected
The time of elution (retention time) of any normal or variant haemoglobin present is compared with that of known haemoglobins, providing quantification of both normal haemoglobins (A, F and A2) and many variants

Question 6

Disorders of Haemoglobin

Answer 6

Disorders of Haemoglobin may result from:

• altered Hb structure
• altered Hb stability
• altered Hb production
• altered Hb amount
• altered Hb function

Question 7

Disorders of Hb - Thalassemias and Haemoglobinopathies

Answer 7

Thalassemias - group of recessively autosomal inherited diseases characterised by a decreased or absent synthesis of one of the two globin chains that form adult haemoglobin (haemoglobin A, α2β2)
Haemoglobinopathies - group of inherited disorders that result in the altered structure of haemoglobin

Question 8

Clinical Features of Haemoglobinopathies

Answer 8

Very variable
Anaemia variable mild-severe
- lethargy, weakness etc.
- jaundice
Medullary  haematopoiesis
- bone deformation
Extramedullary haematopoiesis
- hepato-splenomegaly, ‘other tissue masses’

Question 9

Thalassemia

Answer 9

Mutations or deletions of the alpha or beta globin genes lead to reduced synthesis of alpha or beta globin chains
Alpha thalassemia results from mutations in alpha globin gene
Beta thalassemia results from mutations in the beta globin gene
The resultant anaemia in thalassemia is due to the deleterious effects of excessive (unbalanced) production of the unaffected globin chains

Question 10

Alpha Thalassemia

Answer 10

A tandem pair of alpha globin genes (chromosome 16) is inherited from each parent => yielding four alpha globin genes
If one or more alpha globin genes are non-functional => alpha thalassemia
Reduced alpha globin synthesis leads to an imbalance in alpha & non alpha (beta, gamma, delta) globin synthesis
- reduced haemoglobin synthesis
- microcytic, hypochromic RBC
- shortened half-life of RBC due to formation of unstable homotetramers of excess non-alpha globin chains may lead to RBC destruction in the bone marrow

Question 11

Alpha Thalassemia - Clinical Manifestations

Answer 11

Dependent on how many (of 4) genes affected

• 1 gene: (- α /αα) alpha thalassemia minima
• 2 genes: (- α/-α “trans” or –/ αα “cis”) alpha thalassemia minor/ alpha thalassemia trait
• 3 genes (–/-α) HbH disease
• 4 genes: (–/– ) Hydrops fetalis

Question 12

Alpha Thalassemia Minimia (- α/αα)

Answer 12

Typically clinically unapparent
Normocytic, normochromic
No HbH inclusion
Normal HbA2 & HbF as adults
‘Silent carrier’

Question 13

Alpha Thalassemia Minor (-α/-α or –/ αα)

Answer 13

Mild anaemia
Microcytic, hypochromic RBC 
Target cells/poikilocytes
Occasional HbH inclusion
Normal HbA2 & HbF as adults
α/β ratio ~ 0.8/1.0

Question 14

Alpha Thalassemia - HbH Disease (–/-α)

Answer 14

Results in moderately severe haemolytic anaemia as HbH is unstable

• microcytic, hypochromic
• poikilocytosis, target cells
• precipitated haemoglobin evident with supravital stains

Question 15

Alpha Thalassemia - Hydrops Fetalis (–/– )

Answer 15

Prevents formation of all normal haemoglobins (haemoglobins F, A, and A2)
In this situation, the major haemoglobin that forms in the foetus is haemoglobin Bart’s, a non-functional gamma chain homotetramer (γ4)
Oxygen delivery to foetal tissues is markedly reduced, leading to a severe hypoxic condition

Question 16

Beta Thalassemia

Answer 16

A single β gene is located on each chromosome 11
Most β thalassemias result from point mutations in the β globin gene
Nomenclature:
- β+ => partial block in β-chain synthesis
- β0 => complete absence of β-chain synthesis
Reduced beta chain synthesis leads to decreased HbA (α2β2)
Promotes compensatory increase of gamma & delta globins that leads to increased levels of HbA2 (α2δ2) & HbF (α2γ2)
Excess alpha chains form insoluble alpha chain tetramers (α4) which are destroyed in bone marrow/spleen

Question 17

Beta Thalassemia Minor Features

Answer 17

Clinical
-  typically minimal clinical signs
Laboratory results
- mild anemia
- microcytic, hypochromic
Peripheral blood smear
- variable anisocytosis and poikilocytosis
- target cells, basophilic stippling
- slightly ↑ polychromatophilic RBC
Hb electrophoresis
- mild increase in HbA2 (4-7% instead of normal 2-3%)

Question 18

Beta Thalassemia Intermedia Features

Answer 18

Clinical
- active erythropoiesis
- splenomegaly
Laboratory results
- moderate anaemia
- microcytic, hypochromic
- ↑ reticulocytes
Peripheral blood smear
- target cells, basophilic stippling, nRBCs
BM
- erythroid hyperplasia
Hb electrophoresis:
1. Severe forms
- HbA2 5-10%
- HbF 30-75%
- HbA remainder
2. Milder forms
- HbA2 >3.2%
- HbF 1.5-12.0%

Question 19

Beta Thalassemia Major

Answer 19

Beta thalassemia major (homozygous β0/β0)
Marked by severe microcytic hypochromic anaemia & anisopoikilocytosis
No beta chain is produced at either allele (β0 signifying a non-functional gene) and nearly all the hemoglobin is HbF with a small fraction of HbA2
Requiring multiple red cell transfusions
Inadequate transfusion therapy leads to:
- childhood growth retardation
- skeletal abnormalities
- hepatosplenomegaly
- high risk of infection

Question 20

Beta Thalassemia Major Features

Answer 20

Laboratory results
- severe anaemia
- microcytic hypochromic
- ↑ RDW
Peripheral blood smear
- anisocytosis, poikilocytosis
- basophilic stippling, polychromasia
- nRBCs
Hb electrophoresis
1. Cord blood
- < 2% HbA
2. Adult
- β0/β0 => ‘No’ HbA, 90% HbF, variable HbA2
- β0/β+ and β+/β+ => ‘some’ HbA, majority HbF, normal to ↑ HbA2

Question 21

Haemoglobinopathies

Answer 21

Specific inherited point mutations of the beta globin gene lead to abnormal unstable haemoglobin
- e.g. HbS, HbC, & HbE
Autosomal recessive
- symptomatic homozygous state ‘disease’
- asymptomatic heterozygous state ‘trait’
Often result in haemolytic anaemia

Question 22

Sickle Cell (HbS) Disease

Answer 22

Substitution of 6th amino acid on β chain
Glutamic acid (polar) replaced with non polar valine
- heterozygous ααββs (sickle cell trait)
- homozygous ααβsβs (sickle cell disease)
Deoxygenation => HbS polymerisation, sickling & microvascular occlusion
Re-oxygenation of erythrocytes breaks down the HbS polymer and restores the normal shape
This process of sickling and un-sickling continues until the erythrocyte membrane is no longer flexible
Irreversibly sickled cells undergo intravascular haemolysis or extravascular removal by the reticuloendothelial system

Question 23

Sickle Cell Disease Features

Answer 23

Laboratory findings
- Hb ~ 60-90 g/L
- sickle cells, poikilocytosis
Solubility test (sodium dithionite)
- HbS is insoluble in deoxygenated state
- crystals refract light, solution becomes turbid
Electrophoresis/HPLC
- used to identify/quantify HbSS

Question 24

HbC Disease

Answer 24

Predominantly west African populations
Substitution of lysine for glutamine in β-globin
Rhomboid haemoglobin crystals form in RBC
Hb identification
- HbC migrates with HbA2
Homozygous HbC (ααβc βc)
- mild haemolytic anaemia, target cells
Heterozygous HbC (ααββc)
- benign, few target cells
Blood film
- microcytosis, target cells

Question 25

HbE Disease

Answer 25

Largely confined to south east Asian populations
Homozygous HbE (ααβeβe)
- mild haemolytic anaemia
- mild microcytic, hypochromic
Combination of HbE β-thalassemia (HbE/β0 ) => severe disease, usually as severe as β-thalassemia major

Question 26

Molecular Diagnostics for Haemoglobinopathies

Answer 26

Multiplex gap-PCR
- primer spacing too great for normal allele
- product only for deletion allele
Direct sequencing
- detect point mutations
Multiplex ligation dependent probe amplification (MPLA)
- quantitative amplification of multiple fluorescent probe pairs to α− & βglobin
- signal increases with duplication
- signal decreases with deletion
Microarrays