SQU Med J, December 2009, Vol. 9, Iss. 3, pp. 305-310, Epub. 19th Dec 2009
Submitted - 19th May 2009
Revision Req. 4th Oct 09. Revision Recd. 28th Oct 09
Accepted - 31st Oct 09

Departments of  1Hematology and 2Biochemistry, Baqai Medical University, Karachi, Pakistan.
*To whom correspondence should be addressed. Email: staytune1@hotmail.com  

حتري مخسة أنواع من طفرات ثاالسيميا ) ب( يف 
باكستان

محمد عثمان، معني الدين معني الدين، روبينة غاني، ساديا عثمان

»حزام  في  للمرض  انتشار  أعلى  العالم.  في  انتشارا  السائد  األحادي  املورث  اضطرابات  أكثر  من  (ثاالسيميا)  املتوسط  األبيض  البحر  دم  فقر  الهدف:  امللخص: 
وباكستان  األقصى  الشرق  من  اجلنوبية  واألجزاء  الهندية  القارة  وشبه  األوسط   الشرق  مناطق  وبعض  املتوسط  األبيض  البحر  منطقة  يشمل  الثاالسيميا« الذي 
معهد  في  الدراسة  وجنوب شرق آسيا. نهدف هذه الدراسة إلى اكتشاف التشوهات اجلزيئية الشائعة ملتالزمة الثاالسيميا (ب) في باكستان.  الطريقة: أجريت 
الدم بجامعة باكي الطبية (كرانسي/باكستان) من أغسطس 2005 إلى نوفمبر 2007. أخذت عينات الدم من (400) مريضا مصابا بالثاالسيميا الكبرى (ب) من 
مراكز نقل الدم واخملتبرات التشخيصية في مختلف مناطق كراتشي ميثلون األجناس اخلمسة الكبيرة: البنجابي ، الباثان ،السندي ، البلوشي واألوردو. مت حتليل كل 

العينات للطفرات الشائعة اخلمسة باستعمال تقنية سلسلة انزمي البوليميريز. النتائج: أظهرت النتائج خمسة طفرات شائعة وهي 
                                                                                                                       .هذه تشمل (%90) من كل مورثات الثاالسيميا (ب) في باكستان. 
كان مورث  ال}IVS 1-5(GRC){ األكثر شيوعا عند الباكستانيني حيث مثل (%44) عند كل األجناس الرئيسية . اخلالصة: ستساعد نتائج هذه الدراسة على 

تأسيس برنامج واسع النطاق لتشخيص حاالت املرض خالل احلمل في الباكستان.

مفتاح الكلمات: ثاالسيميا (ب)، طفرات ، شعب باكستان، أثناء احلمل.

abstract: Objectives: Thalassemia is one of the most common autosomal single-gene disorder worldwide. The highest 
prevalence of the disease is in the “thalassemia belt” which includes the Mediterranean region, parts of the Middle East, 
the Indian subcontinent, the southern parts of the Far East, Pakistan and South-East Asia. This study aimed to detect 
the common molecular abnormalities of the beta thalassemia syndrome in Pakistan. Methods: The study was conducted 
at the Institute of Hematology, Baqai Medical University, Karachi, Pakistan from August 2004 to November 2007. 
Blood samples of patients with beta thalassemia major (n = 400) were collected from hospital transfusion centres and 
diagnostic laboratories in different districts of Karachi  representing five major ethnic groups including Punjabi, Pathan, 
Sindhi, Baluchi and Urdu speaking. All the samples were analysed for five common mutations by using the polymerase 
chain reaction technique ARMS (amplification of refractory mutation system). Results: The data revealed five common 
mutations including IVS 1-5(GC), Fr 41/42(-CTTT), Fr 8/9 (+G), IVS 1-1 and Del 619. These accounted for 90% of the 
total beta thalassemia genes in Pakistan. The IVS 1-5(GC) was found to be the most common beta thalassemia gene 
in the Pakistani population with a frequency of 44.4% present in all major ethnic groups. Conclusion: The results of this 
study will be helpful in the establishment of a large scale prenatal diagnosis programme in Pakistan.

Keywords: Beta thalassemia; Mutations; Pakistani population; Prenatal diagnosis. 

Screening of Five Common Beta Thalassemia 
Mutations in the Pakistani Population

A basis for prenatal diagnosis
*Muhammad Usman,1 Moinuddin Moinuddin,1 Rubina Ghani,2 Sadia Usman1 

clinical & basic research

Advances in knowledge
1. This study shows that in the Pakistani population only five mutations are common and these account for 90% of beta thalassemia 

genes. 

Application to patients care
1. This study could help in establishing an economical and cost effective large scale prenatal diagnosis programme in Pakistan by focusing 

on a limited number of mutations since the heterogeneity and complexity of the molecular abnormalities of the beta thalassemia 
syndrome make antenatal diagnosis difficult and expensive. 

2. This study will be useful to stop the propagation of the beta thalassemia gene in the homozygous form that causes transfusion dependent 
beta thalassemia.   



Screening of Five common Beta Thalassemia Mutations in the Pakistani Population 
A basis for prenatal diagnosis

306 | SQU Medical Journal, December 2009, Volume 9, Issue 3

Thalassemia is the most common genetic disorder world wide.1,2 More than 200 causative molecular defects have been 
described to date in the beta-globin gene causing  
beta thalassemia.3,4,5 These are not uniformly 
distributed, but have geographic specificity, and 
each ethnic group has a few common mutations 

and a variable number of rare ones. Immigration 
plays a major role in both the distribution and the 
extent of mutation variations across the globe.6,7 
Beta thalassemia usually results from mutations 
that affect transcription, translation, or ribonucleic 
acid (RNA) stability.8, 9,10 

Thalassemia is a serious public health problem, 
demanding the use of a preventive program with 
newborn screening in specific areas. To date, the 

highly heterogeneous distribution of molecular 
defects in the beta-globin gene has hampered the 
development of a flexible strategy that allows rapid 
analysis of mutations.7 

Thalassemia occurs with a particularly high 
frequency in a broad belt extending from the 
Mediterranean basin through the Middle East, 
Indian subcontinent, Burma to South East Asia. 
9,11,12,13,

During the last 8-10 years, the amplification 
refractory mutation system (ARMS) and restriction 
fraction length polymorphisms (RFLP) were the 
principal techniques used for the diagnosis of beta 
thalassemia.14 However, Pakistan, with a multiethnic 
population of around 160 million, represents a 
vast spectrum of beta thalassemia mutations. We 
report the application of the ARMS procedure for 
the detection of five common mutations in five 
major ethnic groups and its advantages in prenatal 
diagnosis of beta thalassemia. 

Methods
The blood samples from patients with beta 
thalassemia major (n = 400) were collected in 
ethylenediaminetetraacetic acid (EDTA). The 
patients included in this study were all transfusion 
dependent and had been diagnosed earlier in life 
as beta thalassemia major with the help of basic 
haematological parameters, peripheral blood 
morphology and haemoglobin electrophoresis. 
Among the 400 beta thalassemia major patients 
250 were males and 150 were females with a mean 
age of 13.5 years. All samples were tested by the 

modified method of amplification of refractory 
mutation system (ARMS)14,15 for the five commonest 
mutations previously reported in population of 
the sub-continent.16,17,18 The five mutated primer 
sequences which were used during this study were 
IVSI-1 (G→T), IVSI-5 (G→C), Del 619, Fr 41-42(-
TTCT) and Fr 8-9 (+G). For the isolation of DNA, 
the blood samples were collected in EDTA and 
DNA was extracted from whole blood by following 
the kit protocol, using the Gentra Pure Gene kit 
(Minneapolis, Minnesota, USA). 

The ARMS technique was used to characterise 
and screen the mutations as follows. After DNA 
extraction, polymerase chain reaction (PCR) 
reactions were set up in two separate tubes for 
each sample. The mutant primers, namely IVS 
1-1(G→T), IVS 1-5 (G→C), Fr 41/42(-TCTT), Fr 
8/9(+G) and Del 619 at the 3’ end of the gene were 
distributed in two separate tubes according to their 
base pairs. The amplification with primers A and B 
served as internal controls in all the PCR reaction 
mixtures giving rise to 861bp fragments.  

A total of 20μl final PCR reaction volume was 
used to measure the PCR condition. The reaction 
volume was composed of 0.5 micrograms of the 
DNA template, 10 pmol of each of the five primers 
(2 control primers, and 1 mutant ARMS primer for 
the reaction), 2.5 unit Taq DNA polymerase, and 
0.2 mM of each deoxyribonucleotide triphosphate 
(dNTP) in a solution of 10 mM Tris-HC1, 50mM 
KCl and 1.2mM MgCl2, (Promega, USA). The 
thermal cycling regimen consisted of 25 cycles; 
denaturation 94oC for 1 minute, primer annealing 
at 65oC for 1 minute and extension at 72oC for 
1.5 minute with the final extension at 72oC for 3 
minutes. 

The electrophoresis condition was measured 
as follows. Fifteen microlitres of the PCR products 
were removed and mixed with 3 μL of a loading 
buffer and then loaded on a 2% agarose gel. The 
gel was set at 100 volts for 1 hour and then stained 
with ethidium bromide. After staining, the bands 
became visible under ultraviolet (UV) light. The 
different mutations were characterised with 100bp 
or 50 bp DNA ladders. 

Approval for this study was obtained from the 
Ethical Committee of Baqai Medical University.



Muhammad Usman, Moinuddin Moinuddin, Rubina Ghani and Sadia Usman

Clinical and Basic Research | 307

Results
In this study, we used ARMS for the detection of 
beta-thalassemia mutations, which is one of the 
most commonly used techniques for diagnosis of 
this disease. The analyses were carried out on 800 
alleles by ARMS technique for the detection of five 
common mutations IVS-1 nt 5 (G→C), IVS-1 nt 
1(G→T), Fr 41/42 (TCTT), Fr 8/9 (+G) and Del 
619. 

A total of sample of 400 homozygous beta 
thalassemia patients was analysed and among 800 
beta thalassemia genes, 720 were identified with 
five common mutations [Table 1 and Figures 1a and 
1b]. 

This study confirmed the presence of these 
five common mutations were: IVS 1-5(G→C), Fr 
41/42 (-CTTT), Fr 8/9 (+G), IVS 1-1 and Del 619 
comprising 90% of the total beta thalassemia genes 
in the Pakistani population [Table 1 and Figures 1a 
and 1b]. 

Molecular analysis in this study revealed that IVS-
1-5 (G→C) was the most common beta thalassemic 
gene that was present in all major ethnic groups of 
Pakistan. This mutation comprised around 44.4% of 
the total beta thalassemia genes in Pakistan with a 
frequency of 48.6% in Punjabis, 47.3% in Pathans, 
36.5% in Sindhis, 36.8% in Baluchis and 61.6% in 
the Urdu speaking population. Its prevalence in the 
Urdu speaking population is very high compared to 
the other four ethnic groups.

Fr 41/42c (-TTCT) was the second most 
common beta thalassemia gene in  this study; it 
comprised 17.5% of the total beta thalassemia 
gene with a frequency of 24% in Punjabis, 28.4% 
in Pathans, 13% in Sindhis, 27.4% in Baluchis and 
12.5% in the Urdu speaking population.

The third most common beta thalassemia gene 
observed during this study was Fr 8/9 (+G). It 
comprised 14.6% of the total beta thalassemia gene 
in the Pakistani population with frequency of 17.1% 
in Punjabis, 18.9% in Pathans, 34.8% in Sindhis, 
7.4% in Baluchis and 9.2% in the Urdu speaking 
population.

Screening of the five common mutations of 
the beta thalassemia syndrome revealed IVS-1-1 
(G→T) as the fourth most common mutation in 
the Pakistani population. This accounted for 7.5% 
of total beta thalassemic genes in Pakistan with 
frequency 6.8% in Punjabis, 3.1% in Pathans, 4.3% 
in Sindhis, 21% in Baluchis and 8.3% in the Urdu 
speaking population. These data revealed that the 
prevalence of IVS 1-1 (G→T) is high in the Baluchi 
population of Pakistan. 

Del 619 was identified as the fifth commonest 
beta thalassemia gene in this study. It comprised 
6% of the total beta thalassemia genes in our 
population with a frequency of 3.4% in Punjabis, 
2.1% in Pathans, 11.3% in Sindhis, 7.4% in Baluchis 
and 8.3% in the Urdu speaking population. In the 
Urdu speaking group, the Del 619 mutation was 
present at high frequency in the Gujurati and 
Memon communities.

Discussion
Pakistan has a population of around 160 million 
people. The annual rate of population growth is 3% 
and almost 40% of the population is below 15 years 
of age.16,20 There are five major ethnic groups: Sindhi, 
Urdu speaking, Punjabi, Baluchi and Pathan. The 
carrier frequency of beta thalassemia is estimated 
at around 6% in Pakistani population.17 The results 
of the molecular analysis of the beta thalassemia 

Table 1: Five commonest beta thalassemia mutations among the five main ethnic groups in Pakistan

Mutation Punjabi Pathan Sindhi Baluchi
Urdu 

Speaking
All

IVS-1-5 (G-C) 85 (48.6%) 45 (47.3%) 42  (36.5%) 35 (36.8%) 148 (61.6%) 355 (44.4%)

Fr-8/9 (+G) 30 (17.1%) 18 (18.9%) 40 (34.8%) 07 (7.4%) 22 (9.2%) 117 (14.6%)

Fr-41/42  (-TTCT) 42 (24%) 27 (28.4%) 15 (13%) 26 (27.4%) 30 (12.5%) 140              (17.5%)

IVS-1-1 (G-T) 12 (6.8%) 03 (3.1%) 05 (4.3%) 20 (21%) 20 (8.3%) 60 (7.5%)

Del 619 06 (3.4%) 02  (2.1%) 13 (11.3%) 07  (7.4%) 20  (8.3%) 48 (0.6%)

Total 175 95 115 95 240 720 (90%)



Screening of Five common Beta Thalassemia Mutations in the Pakistani Population 
A basis for prenatal diagnosis

308 | SQU Medical Journal, December 2009, Volume 9, Issue 3

syndrome in these five major ethnic groups revealed 
five common mutations, which comprised 90% of 
the total beta thalassemia genes in the Pakistani 
population. These mutations included IVS-1-5 
(G→C), Fr 8/9 (+G), Fr 41/42 (-TTCT),   IVS-1-1 
(G→T) and Del 619. 

Although the five common beta thalassemia 
mutations reported during this study have already 
been detected and reported in Pakistani population 
by Ahmed et al. in 1996,20 the most important 
difference between the previous study and the 
present one is that this study detected the frequency 
of these five common mutations. The data of 
this study reveal that the frequency of these five 
mutations is 90% in the Pakistani population while it 
was reported at around 82% in the previous study. In 
the light of present study, it is quite clear that   these 
five mutations play a major role in propagation of the 

beta thalassemia gene in Pakistan as they comprised 
around 90% of the total beta thalassemia genes in 
this region. Results of this study showed the strong 
need for a large scale prevention program based on 
ante-natal diagnosis by PCR. 

The spectrum of beta thalassemia mutations that 
was identified in the Indian population also showed 
the same five common mutations IVS-1-5 (G→C), 
Fr 8/9 (+G), Fr 41/42 (-TTCT), IVS-1-1 (G→T) 
and Del 619. These accounted for 93.6% of the total 
beta thalassemia genes in the Indian population.17 
Another exclusive study of molecular genetics 
of beta thalassemia in the Indian population also 
showed the same five common mutations i.e. IVS-
1-5 (G→C), Fr 8/9 (+G), Fr 41/42 (-TTCT), IVS-1-1 
(G→T) and Del 619 that accounted for 91.8% of the 
total beta thalassemia genes. These mutations were 
frequently encountered in various regions of India 

1 2 3 4 5 6 7 8 9 10 11 M
50bp

Control 861 bp Fr 8/9 215 bp

Fr 41/42 439 bp
IVS 1-1 281 bp

IVS 1-5 285 bp Del 619 242 bp

Figure 1a: The analysis of DNA sample with mutation primer IVS 1-5, frame 41/42  IVS 1-1 and frame 8/9Lane 1,2 
and 3 are IVS 1-5; Lane 4,5 and 6 are Fr 41/42; Lane 7 shows normal control band ; Lane 8 is del 619, lane 9 and 10 is 
IVS 1-1 and lane 10 and 11 shows Fr 8/9.

1 2 3 4 5 6 7 8 9 M
100bp

Control 861 bp

IVS 1-5 285 bp

IVS 1-1 281 bp

Figure 1b: The analysis of DNA sample with mutation primer IVS 1-5 and   IVS 1-1 Lane 1, 2, 3 and 4 are IVS 1-1; 
Lane5 and 9 are IVS 1-5.



Muhammad Usman, Moinuddin Moinuddin, Rubina Ghani and Sadia Usman

Clinical and Basic Research | 309

including Southern, Eastern and Northern states.18

Similar patterns of molecular genetics of beta 
thalassemia syndromes in the Pakistani and Indian 
populations may have two basic causes. First, 
Pakistan and India was one state for several hundred 
years before partition in August 1947.  Therefore 
cross-population and inter-linkage marriages were 
common. Second, there was large scale migration 
from India to Pakistan and from Pakistan to India 
during the Indo-Pak partition in 1947. 

The spectrum of molecular genetics of the 
beta thalassemia syndrome in Pakistan and India 
also shows the influence of genetic distribution of 
beta thalassemia from the Mediterranean region. 
The exact cause of the influence of Mediterranean 
region in Indian and Pakistani people is unknown; 
geographical migration and a history of invasions 
of the subcontinent favour the influence across the 
borders.19

Studies of the molecular spectrum of beta 
thalassemia syndrome in the UAE (United Arab 
Emirates) revealed that IVS-1-5 (G→C) was the 
most frequent mutation in the UAE population.21, 22

A study of the molecular spectrum of beta 
thalassemia in Arab populations (Jordan, Egypt, 
Syria, Lebanon, Yemen and Saudi Arabia) revealed 
that the most frequent mutations were IVS-1-5 
(G→C), IVS-II-1 (G→A), IVS-1-1, Fr 8/9, Fr 41/42, 
Cd 15, Cd 16, Cap +1 (A-C), IVS-1-110, IVS-1-3’ 
end (-25 bp) and IVS-1-6.23 

The close similarity in molecular genetics of 
the beta thalassemia syndrome in the Arab and 
Pakistani populations is likely to have arisen because 
of the influence of trading and invasions of Sindh 
and Pakistani Punjab by Arabs.

Conclusion
This research will help in the establishment of a 
large-scale prevention programme based on fetal 
diagnosis (prenatal) of beta thalassemia by DNA 
analysis (PCR) in the Pakistani population.  

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