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This article is protected by copyright. All rights reserved.
Non-invasive prenatal diagnostic testing for -thalassaemia using cell-free
fetal DNA and next generation sequencing
Li Xiong1,2*, Angela N Barrett1*, Rui Hua1,2, Tuan Zea Tan3, Sherry Sze Yee
Ho4,Jerry KY Chan5,6, Mei Zhong2#, Mahesh Choolani1#
1Department of Obstetrics and Gynaecology, Yong Loo Lin School of Medicine,
National University of Singapore, Singapore, 119228.
2Department of Gynecology & Obstetrics, Nanfang Hospital, Southern Medical
University, Guangzhou, China.
3Cancer Science Institute of Singapore, National University of Singapore,
Singapore.
4Department of Laboratory Medicine, Molecular Diagnosis Centre, National
University Hospital, Singapore, S119074
5Experimental Fetal Medicine Group, Department of Obstetrics and
Gynaecology, Yong Loo Lin School of Medicine, National University of
Singapore, Singapore, 119228.
6Department of Reproductive Medicine, KK Women's and Children's Hospital,
Singapore, S229899
This article has been accepted for publication and undergone full peer review but has not been through the copyediting, typesetting, pagination and proofreading process, which may lead to differences between this version and the Version of Record. Please cite this article as doi: 10.1002/pd.4536
This article is protected by copyright. All rights reserved.
* Authors contributed equally
# Corresponding Authors:
Mahesh Choolani, Department of Obstetrics & Gynaecology, National University
of Singapore, NUHS Tower Block, Level 12, 1E Kent Ridge Road, Singapore
119228.
Tel: +65 67722672; Fax: +65 67794753; e-mail: obgmac@nus.edu.sg.
Mei Zhong, Department of Obstetrics & Gynaecology, Nan Fang Hospital,
Southern Medical University, Guangzhou, Guangdong, 510515,PR China.
Tel: +86 20-61641901; Fax: +86 20-62787562; e-mail: drmzhong@gmail.com
Running title: NIPD for β-thalassaemia using next generation sequencing
Word count: 3,414
Figure count: 2
Tables: 3
Funding: We acknowledge the National Medical Research Council /Clinician
Scientist Award (NMRC/CSA/007/2009) for supporting our work. The funders
played no part in the study design, data collection, data analysis or manuscript
preparation.
Conflict of Interest: The authors have no conflicts of interest to declare.
What is already known about this topic?
Cell-free fetal DNA in maternal plasma can be used to detect paternally
inherited mutations absent from the mother’s DNA.
If the fetus has not inherited the paternal mutation, no further invasive
testing is required.
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What does this study add?
A simple next generation sequencing test with a 100% detection rate can
detect inheritance of paternal -thalassaemia alleles.
This sequencing method can be applied to any paternally inherited point
mutation or small insertion/deletion.
ABSTRACT
Objective To develop an accurate non-invasive prenatal test using next
generation sequencing (NGS) for HbE and the four most common β-
thalassaemia mutations found in South East Asia (namely -28A>G, CD17A>T,
CD41/42(-TTCT), and IVS-II-654C>T).
Methods: Cell-free DNA was extracted from maternal plasma from 83 families
where both parents were carriers of the HbE mutation or one of four common β-
thalassaemia mutations. Overlapping PCR amplicons covering each mutation
were generated, pooled, and sequenced using the Illumina Miseq. Fastq files
were analysed to detect inheritance of the paternal mutation.
Results: In two cases where the fathers were compound heterozygotes for HbE
and -28A>G, the fetus was correctly diagnosed as having inherited one of the
paternal mutations. In 35/85 cases, the paternal mutation was not detected, and
in 50/85 cases it was classified as inherited. Overall sensitivity for detection of
paternal mutations was 100% (95% CI: 92.4%-100%), and specificity was
92.1% (95% CI: 79.2%-97.3%).
This article is protected by copyright. All rights reserved.
Conclusion: We demonstrated that detection of paternal mutations using NGS
can be readily achieved with high sensitivity and specificity, removing the need
for an invasive test in 50% of pregnancies at risk of a thalassaemia in cases
where the father and mother carry a different mutation.
INTRODUCTION
Beta-thalassaemia is a common autosomal recessive disorder caused by
reduced (β+) or absent (β0) synthesis of the -globin chains of the haemoglobin
tetramer1. Mutations occur on the HBB gene located on chromosome 11. When
both parents are carriers of a thalassaemia mutation, there is a 25% risk for
thalassaemia major in each pregnancy. Thalassaemia can result in profound
anaemia from early life and, if not treated with regular blood transfusions, can
lead to death in the first year2,3. These blood transfusions bring their own
complications, mainly caused by iron-overload, resulting in endocrinopathies,
cardiac complications and death3. Over 200 different HBB mutations have been
identified to date, the majority being single nucleotide substitutions, deletions, or
insertions of nucleotides leading to a frame-shift4; rarely, -thalassaemia results
from gross gene deletion. In South East Asia between up to 11% of the
population are estimated to be carriers for -thalassaemia, with approximately
65% of all β-thalassaemia mutations caused by four mutations in the HBB gene:
-28A>G (under HGVS nomenclature, HBB:c.-78A>G), CD17A>T
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(HBB:c.52A>T), CD41/42(-TTCT) (HBB:c.126_129delCTTT), and IVS-II-
654C>T (HBB:c.316-197C>T)1,5. Haemoglobin E is another common structural
haemoglobin variant in South Asia, caused by a CD26GAG>AAG
(HBB:c.79G>A) mutation in the HBB gene, often occurring as compound β-
thalassaemia leading to serious anaemia and transfusion dependency6.
Prenatal diagnosis for thalassaemia syndromes is an essential part of
preventive genetics, and is currently dependent on the use of invasive
diagnostic tests, which carry a small but significant risk of miscarriage of up to
1%7. Although more recent data suggests that the risk is generally much lower
than 1%8, it may be the case that in centres with less experienced staff, the risk
is far greater. Because of this potential risk, a major goal in prenatal diagnosis
has been to develop methods to test non-invasively using cell-free DNA
(cfDNA) from a maternal blood sample, thus eliminating the risk of miscarriage.
Cell-free fetal DNA (cffDNA) constitutes approximately 10-15% of the total
cfDNA9, and has been shown to represent the entire fetal genome10.
Detection of inheritance of paternal β-thalassaemia mutations using NIPD has
been previously reported11-16. Many different methods have been used in the
development of these tests, including allele-specific real-time PCR (AS-
PCR)11,12, single-allele base extension reaction (SABER)13, mass arrayed
primer extension (APEX)14, digital PCR15, and MALDI-TOF mass spectrometry16
methods. The sensitivity of any test for NIPD is hampered by the low proportion
of cffDNA present in maternal plasma. In order to overcome this problem,
strategies for enrichment of circulating cffDNA and depletion of maternal
background cfDNA have been used. These strategies are dependent on the fact
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that cffDNA molecules have been shown to be shorter than maternally derived
cfDNA10, with a length of less than 146bp on average, but all have their
disadvantages. Agarose gel electrophoresis followed by DNA purification can
be used to enrich smaller DNA fragments17, but is relatively labour-intensive
and prone to contamination, so is not ideal for implementation into clinical
practice. Digital nucleic acid size selection (NASS) gives a 32.6-38.0%
enrichment of fetal DNA15; however this methodology requires expensive digital
PCR equipment and has not been widely adopted. Enrichment of the fetal
fraction by suppression of maternal cfDNA can be achieved by the use of a
peptide-nucleic-acid (PNA) clamp17,18 and COLD-PCR19, requiring extensive
optimization for each amplicon. Addition of formaldehyde to a blood sample was
shown by Dhallan et al. to enrich the fetal fraction20; however these results are
controversial, since other groups have not found them to be reproducible21, 22.
The advent of next generation sequencing (NGS) has allowed us to count
millions of DNA molecules from a single sample, greatly increasing the
sensitivity of molecular tests using cfDNA. Several groups are working to
develop NIPD for β-thalassaemia using NGS. Lo et al.10 performed massively
parallel whole genome sequencing on a sample from a family where both
parents were carriers of different β-thalassaemia mutations, and successful
diagnosis of the fetus as a heterozygous carrier revealed that it is feasible to
use NIPD for single gene disorders. However, the expense associated with this
high coverage sequencing precludes its use for routine prenatal diagnosis.
Targeted sequencing is a far more cost-effective strategy to capture cfDNA
molecules from specific genomic regions. Using in-solution capture, sequence
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coverage of targeted regions can be increased by over 200 times23. This
approach was utilized to capture thousands of SNPs on the HBB gene cluster
and targeted RHDO analysis was used to diagnose β-thalassaemia in two
families24. In another study, using NGS for four informative SNPs in the HBB
locus, Papasavva et al. achieved correct classification of paternal inheritance in
eight samples out of ten using haplotype analysis25.
In this study, we directly targeted the five most common South East Asian
mutation loci on the HBB gene using overlapping PCR amplicons, and used the
Illumina MiSeq next generation sequencing platform to detect the presence of
paternally inherited mutant alleles in maternal plasma. Our aim was to develop
a simple, rapid, and cost-effective method for detection of paternal mutations
using NIPD, thereby removing the need for an invasive test in 50% of cases at
risk of β-thalassaemia where parents are heterozygous for different mutations.
MATERIALS AND METHODS
Patient recruitment and sample collection
Blood was collected at the Department of Gynaecology and Obstetrics at
Nanfang Hospital, Southern China from 140 pregnant couples at risk of β-
thalassaemia, attending a clinic for prenatal diagnosis. This study was
performed with the approval of the Institutional Review Board for Nanfang
Hospital (study number NFEC-2014-048). 10mL of maternal peripheral blood
was collected into two K3-EDTA tubes and 2mL of paternal peripheral blood
was collected into a single K3-EDTA tube. Specimens for genotyping the fetus
obtained between 11-14 weeks of gestation were collected by chorionic villus
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sampling (CVS), and from 14+1 - 24 weeks of gestation were obtained by
amniocentesis. Cord blood was collected during the third trimester.
Sample processing and DNA extraction
Plasma was separated from 10 mL of maternal blood within 4 hours of blood
draw using previously published protocols26. Plasma DNA was extracted from 2
mL plasma using the QIAamp Circulating Nucleic Acid Kit (Qiagen, California,
USA) according to manufacturer's instructions. Plasma DNA was eluted into a
final volume of 60 µL AVE elution buffer, provided as part of the kit. Genomic
DNA (gDNA) was extracted from buffy coat and fetal material (CVS samples,
amniotic fluid samples) using a FuJi-film gDNA extraction kit (FuJi, Japan)
according to manufacturer's instructions.
Molecular genotyping of β-thalassaemia mutations
Parental buffy coat DNA and fetal DNA were genotyped using a PCR-based
reverse dot blot method27. Only samples from couples carrying different
mutations were selected for further analysis.
Primer design
Three pairs of primers specific for each of the four most common South East
Asian β-thalassaemia mutations, namely -28A>G, CD17A>T, CD41/42(-TTCT),
and IVS-II-654C>T, were designed using Primer 3 software, using the reference
sequence for the haemoglobin gene locus (from the NCBI database, accession
number NG_000007.3; http://www.ncbi.nlm.nih.gov/nuccore/NG_000007.3).
Since a fifth mutation, HbE (CD26GAG>AAG), and the CD17A>T mutations are
located very close together on the HBB gene, the same primer pairs were used
to amplify both. Forward primers contained P5 adaptor sequences
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complementary to those found on the Illumina MiSeq flow cell, a unique patient-
specific index sequence to allow sample multiplexing, and amplicon-specific
sequences; reverse primers contained a P7 primer sequence (all sequences
detailed in Supplementary Table 1). Amplicons ranged in size from 178-212bp
(including adaptor and index sequences). All primer sequences were examined
for the presence of SNPs using SNPCheck3
(https://secure.ngrl.org.uk/SNPCheck/snpcheck.htm).
Library preparation and NGS
Targeted PCR was performed using three overlapping amplicons per mutation.
Each reaction was carried out using 10 µL of 2 x SensiFAST SYBR Lo-Rox kit
(Bioline, UK), 10 M each primer and 5 µL of cfDNA in a total final volume of 20
µL. Thermal cycling conditions were as follows: 2 minutes at 95°C, followed by
32 cycles of 95°C for 20 s, 60°C for 30 s, and 72°C for 15 s. Amplicons were
purified using Isolate II PCR Kit clean-up columns (Bioline) and eluted into 20
µL of elution buffer, then quantified using a Qubit Fluorometer (Life
Technologies, USA). Amplicon quality was assessed using a Bioanalyzer
(Agilent, USA) and a DNA1000 chip to check for presence of primer dimers.
Purified PCR products were diluted to 2 nM in Elution Buffer (Qiagen, USA) and
equal amounts were pooled for up to 20 patients to yield a single 2 nM library.
The sample was denatured using sodium hydroxide according to MiSeq v3
sample preparation kit instructions (Illumina, California, USA), and then the
library was diluted to a final concentration of 8 pM. This library was mixed with
an 8 pM PhiX control to give a 5% PhiX spike, providing sequence diversity.
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Cluster generation was carried out on board the MiSeq followed by initiation of a
single-end 100 cycle sequencing protocol.
Data Analysis
De-multiplexing and base-calling were performed using Illumina MiSeq Reporter
Software version 2.4 to generate FASTQ sequence files for each sample. A
Visual Basic script was used to search each FASTQ file for wild-type and
mutant sequences, with five to six base pairs up- and down-stream of each
mutation included in the search terms. Frequency of wild-type and mutant
alleles were generated by counting the occurrence of the wild-type and mutant
sequences in each FASTQ file, with only exact matches being detected. We
calculated the proportion of the paternal allele present in each sample using the
formula: f = (2p/(p+q)) x 100%, where f is the percentage of fetal DNA, p is the
read count for the fetus-specific allele (paternal origin), and q is the read count
for the allele shared by the maternal and fetal genomes15. A threshold of 1%
was set below which the paternal mutation was said not to be inherited. Since
each mutation locus was targeted by three overlapping amplicons the
proportion of paternal mutation allele was counted, and two out of three
amplicons were required to be negative for us to consider that the paternal
mutation had not been inherited by the fetus; if two out of three were positive,
we considered that the fetus had inherited the paternal mutation.
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RESULTS
Genotyping of the parental mutations
Eleven different mutations were found in the HBB gene of the 140 couples
recruited to the study, with 92.9% (262/282) of these being the five common
South East Asian mutations (Table 1). Two fathers were compound
heterozygotes, hence the 282 mutations for 140 couples. Of those carrying the
common mutations, eighty-three couples were found to be carriers of different
β-thalassaemia mutations (Table 2), the remaining forty-one carrying the same
mutations. Among those cases where parents carried different mutations,
twenty-seven fathers were carriers of the CD41/42(-TTCT) mutation, 21 carried
the IVS-II-654 mutation, 14 carried CD17A>T, and 18 carried the -28A>G
mutation. In one case the paternal mutation was HbE. For the two remaining
families, the fathers were compound heterozygotes for HbE and -28A>G
mutations. Fetal genomic DNA was also genotyped for each family where the
parents carried different mutations, and we found that 24/83 were affected with
β-thalassaemia (and therefore all carrying a paternal mutation), 47/83 were
carriers (of which 23 were carrying the paternal mutation) and the remaining
12/83 were unaffected. cfDNA was extracted from maternal plasma from all
cases where parent’s carried different mutations, and was analysed to detect
inheritance of the paternal mutation.
Detection of paternal mutations in cfDNA
All paternal mutation loci were targeted by three overlapping amplicons. Single-
end sequencing produced an average of 25 million reads per run, with a mean
read count of 82,282 per individual amplicon, giving an average read count per
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mutation for each patient of 246,846. Raw NGS data is presented in
Supplementary Table 2.
Thirty-three of the eighty-one cases in which the fathers carried a single
mutation were correctly found to be negative for the paternal mutation, with less
than 1% paternal mutation detected per amplicon (Figure 1). Of these, 24 of 33
cases were shown to be negative by all three overlapping amplicons and the
remaining nine by two negative amplicons. Three cases that had not inherited
the paternal mutation were found to be positive using our test (false positives).
Amongst these false positives, there was one case of CD41/42(-TTCT), one of
CD17A>T and one of -28A>G. We correctly detected paternal inheritance
(greater than 1% mutant sequence) in all 45 cases where the father carried a
single mutation (Figure 2), as well as detecting the three false positives
mentioned previously, giving a total count of 48 mutation-positive samples.
Thirty-six of these forty-eight cases were positive according to results for all
three overlapping amplicons and the remaining 12 cases were shown to be
positive in two amplicons each (all data presented in Supplementary table 2).
In the two families where the fathers were compound heterozygotes for HbE
and -28A>G, both fetuses were correctly diagnosed as having inherited only
one paternal mutation, in one case only inheriting the HbE mutation and in the
other case only inheriting the -28A>G mutation (Figures 1 and 2). Counting a
total of 85 mutations (81 cases of a single mutation, and two cases of a
compound mutation), inheritance of the paternal mutation was not detected in
35 of 85 cases (41.2%), with inheritance being diagnosed in 50 of 85 cases
(58.8%) (Table 1). There were three cases (3.5%) that gave a false positive
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result using the overlapping amplicon sequences. Diagnostic accuracy was
96.5% (82/85), sensitivity was 100% (95%CI: 92.4%-100%), and specificity was
92.1% (95%CI: 79.2%-97.3%). The positive predictive value is therefore 94.0%
(95% CI: 83.8%-97.9%) and negative predictive value is 100% (90.1%-100%).
DISCUSSION
In this study we have shown that NIPD using cfDNA can detect paternally
inherited β-thalassaemia mutations with 100% sensitivity. We used overlapping
amplicons to target the four most common β-thalassaemia mutations in South
East Asia, as well as HbE (together affecting 92.9% of our study cohort), and
performed targeted sequencing on 83 cases where the parents were carriers of
different β-thalassaemia mutations. As well as 100% sensitivity, we achieved a
specificity of 92.1%, with a positive predictive value of 94% and a negative
predictive value of 100%. The latter indicates that the β-thalassaemia major can
be reliably excluded in the absence of a paternal mutation, removing the
requirement for an invasive test in 50% of cases where the father is a carrier for
one of five common South East Asian mutations. Assuming that our data
reflects the incidence of the mutations in the South East Asian population as a
whole, we would expect that 59.3% of couples would carry a different mutation.
In 50% of cases, the baby will not have inherited the father’s mutant allele, and
therefore the test will remove the need for an invasive procedure in 29.6% of all
pregnancies at risk of -thalassaemia.
The use of overlapping amplicons is essential for reducing potential for false
negative results due to the presence of SNPs under the primers (and indeed, in
our study, no false negatives were seen). The HBB gene contains a high
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number of SNPs, and so it is challenging to design primer pairs avoiding all
known SNPs. Although we attempted to minimize the number of SNPs covered
by any given primer pair using SNPCheck, to increase our confidence in a
negative result, we decided to include three pairs of primers per mutation that
covered the same mutation, but avoided using the same priming regions. If the
paternal allele happens to be located in a region near to a linked SNP, this
strategy should help to prevent misclassification due to allele dropout. Cell-free
DNA is highly fragmented, and although evidence suggests that the fragments
are approximately 146bp in length, and are associated with nucleosomes10
there is no accurate method to predict exactly where the fragmentation will be
located. It is therefore possible that any given pair of primers may not bind to all
fragments containing a particular mutation. Ideally, amplicons will be designed
to be as small as possible, increasing their chance of annealing, but another
benefit of using three overlapping amplicons is that even if one pair of primers
cannot bind to a particular fragment, another should be able to, thus reducing
the likelihood of false negatives.
Sequencing errors caused by the MiSeq itself, library preparation, and starting
quantity of template can affect the results for a particular sample28-31, but it is
unlikely that the same error would have been introduced to all three amplicons.
We found that this was particularly important for the CD41/42(-TTCT) site,
where accuracy was enhanced from 81.5% to 96% by use of overlapping
amplicons (see Table 3). Another study using amplicons targeting four linked
SNPs found in the HBB gene to detect the paternally inherited mutant allele25
returned four false negative and three false positive results from a total of 34
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cases. Our study yielded a significant improvement of more than 17% in
diagnostic accuracy on a larger cohort, possibly attributable to the use of three
overlapping amplicons for each mutation.
We obtained three false positives, one for a sample where the father carried
the four base pair CD42/42(-TTCT) deletion, with all three overlapping
amplicons indicating that the fetus had inherited the paternal mutation. The
other two false-positive cases were one -28A>G and one CD17A>T, both cases
having two out of three overlapping amplicons providing false positive results.
Our laboratory is developing a panel of insertion/deletion polymorphisms that
can be added to the sequencing reaction; this may help to prevent false positive
results due to contamination going undetected, since it should alert us to the
presence of an unexpected proportion of alleles being found in the sample,
indicating the possibility of a sample mix-up. There is also the possibility of PCR
bias being introduced during the library preparation32, although it seems unlikely
that this would affect only a single sample for each of three mutations,
especially considering that the overlapping amplicons do not share a priming
site. Our one-step process for library preparation involves significantly less
sample-handling and subsequent PCR than a standard multi-step library
preparation protocol, and so less bias should be introduced33. Even so, high
numbers of PCR cycles can still lead to higher error rate, and reduction of the
PCR cycles may improve the data further. The GC content of our targeted
amplicons ranged from 30.0% to 60.3%, and so we would not expect there to
be any contribution of GC content to PCR-bias. With the exception of the
CD41/42(-TTCT) mutation, the wild-type and mutant amplicons are the same
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length, and just have one base-pair substitution, so it would be expected that
the amplification efficiency differences would be minimal. We introduced a 1%
threshold below which a sample was considered to be negative for a particular
mutation. Low levels of background counts can occasionally be seen for some
samples, and are most likely attributable to inherent raw sequencing errors that
can be found in data from all NGS platforms34. Using a conservative threshold
of 1%, we ensure that we reduce false positives caused by these stochastic
sequencing chemistry errors.
Women will be encouraged to take an invasive test to confirm whether the
fetus has also inherited the maternal mutation in the case of a positive result for
paternal inheritance. Using targeted sequencing specific for the mutations of
interest means that this method is applicable to any disorder where there is a
point mutation or small indel, in contrast to approaches that rely on haplotyping
for the paternal allele, where there may be no informative SNPs present near to
the mutation of interest25. We expect to be able to expand the panel of
mutations to cover all -thalassaemia mutations. The main limitation will be that
in areas of lower genetic diversity, the chances may be high that parents will
both carry the same mutation, and so paternal detection using our test cannot
be carried out. In the cohort that we tested, the parents carried a different
mutation in two thirds of cases.
The assay only requires a simple PCR to generate the libraries, and with the
addition of sample-specific index sequences, samples from a number of
different patients can be examined in a single MiSeq run. Therefore our
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procedure is cost-effective, and has a very short turnaround time, since the
MiSeq run itself takes approximately six hours.
CONCLUSIONS
We have demonstrated that overlapping targeted amplicon sequencing for
the four most common South East Asian β-thalassaemia mutations plus HbE
can be used for reliable detection of paternally inherited alleles. A test with
100% sensitivity will allow us to detect all cases of paternally inherited β-
thalassaemia mutations, and so in 29.6% of all the cases referred for prenatal
testing for -thalassaemia, the requirement for an invasive test will be removed.
ACKNOWLEDGEMENTS
We would like to acknowledge Chaoqun Xiao and Siping Liu for assistance in
collection of the samples.
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Table 1: The allele frequency of β-thalassaemia and HbE mutations in 140
couples. HGVS nomenclature is also given.
Mutations HGVS Nomenclature Number (n) Frequency (%)
Five Common Mutations 262 92.9
CD 41/42(-TTCT) HBB:c.126_129delCTTT 102 36.2
IVS-II-654C>T HBB:c.316-197C>T 79 28.0
CD17A>T HBB:c.52A>T 38 13.5
-28A>G HBB:c.-78A>G 35 12.4
CD26GAG>AAG
(HbE)
HBB:c.79G>A 8 2.8
Rare Mutations 20 7.1
CD27-28(+C) HBB:c.84_85insC 5 1.8
CD14-15(+G) HBB:c.45_46insG 5 1.8
CD71-72(+A) HBB:c.216_217insA 4 1.4
-29A>G HBB:c.-79A>G 3 1.1
IVS-1-1G>T HBB:c.92+1G>T 2 0.7
CD43G>T HBB:c.130G>T 1 0.4
Total 282
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Table 2: Genotyping results for parental mutations in 124 couples
Father Mother Cases(n)
Parents carrying different mutations 83
Hetero CD41/42(-TTCT) Hetero IVS-II-654C>T 15
Hetero CD41/42(-TTCT) Hetero CD17A>T 4
Hetero CD41/42(-TTCT) Hetero-28 A>G 6
Hetero CD41/42(-TTCT) Hetero-29A>G 1
Hetero CD41/42(-TTCT) Hetero HbE 1
Hetero IVS-II-654C>T Hetero CD41/42(-TTCT) 10
Hetero IVS-II-654C>T Hetero CD17A>T 7
Hetero IVS-II-654C>T Hetero-28A>G 2
Hetero IVS-II-654C>T Hetero-29A>G 1
Hetero IVS-II-654C>T Hetero HbE 1
Hetero CD17A>T Hetero CD41/42(-TTCT) 7
Hetero CD17A>T Hetero IVS-II-654C>T 3
Hetero CD17A>T Hetero-28A>G 2
Hetero CD17A>T Hetero HbE 2
Hetero-28A>G Hetero CD41/42(-TTCT) 10
Hetero-28A>G Hetero IVS-II-654C>T 6
Hetero-28A>G Hetero CD17A>T 1
Hetero-28A>G Hetero HbE 1
Hetero HbE Hetero IVS-II-654C>T 1
Hetero-28A>G/HbE Hetero IVS-II-654C>T 1
Hetero -28A>G/HbE Hetero CD41/42(-TTCT) 1
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Parents carrying the same mutations
41
Hetero CD41/42(-TTCT) Hetero CD41/42(-TTCT) 22
Hetero IVS-II-654C>T Hetero IVS-II-654C>T 14
Hetero CD17A>T Hetero CD17A>T 5
Total 124
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Table 3: Diagnostic accuracy for the three overlapping amplicons for each
mutation.
Mutation Amplicon 1 Amplicon 2 Amplicon 3 Totala
CD41/42(-TTCT) 81.5%
(22/27)
92.6%
(25/27)
81.5%
(22/27)
96.3%
(26/27)
IVS-II-654C>T 90.5%
(19/21)
90.5%
(19/21)
85.7%
(18/21)
95.2%
(20/21)
CD17A>T 92.9%
(13/14)
85.7%
(12/14)
100%
(14/14)
100%
(14/14)
HbE 100% (3/3) 100% (3/3) 100% (3/3) 100% (3/3)
-28A>G 90%
(18/20)
95%
(19/20)
95%
(19/20)
95%
(19/20)
aTotal accuracy refers to the number of samples classified correctly by at least
two out of three amplicons
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Figure 1: The relative proportion of mutant paternal allele identified in the
samples where the paternal mutation has not been inherited. The result is an
average obtained from the three overlapping amplicons. The two cases labelled
with * were analysed for both the HbE and -28A>G mutations since the fathers
are compound heterozygotes. Three false positives are indicated by arrows.
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Figure 2: The relative proportion of mutant paternal allele identified in the
samples where the paternal mutation has been inherited. The result is an
average obtained from the three overlapping amplicons. The two cases labelled
with * were analysed for both the HbE and -28A>G mutations since the fathers
are compound heterozygotes.
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