Oktavianus


205

*Faculty of Mathematics and
Natural Sciences, Padang
State University
**Faculty of Medicine,
Andalas University
***Faculty of Agriculture,
Andalas University
****Faculty of Medicine,
Trisakti University
*****Faculty of Science and
Technology, Ar-Raniry Islamic
State University, Banda Aceh

Correspondence
Drs. Syamsurizal, M.Biomed
Fakultas Matematika dan
Ilmu Pengetahuan Alam
Universitas Negeri Padang
Komplek Kampus UNP Air
Tawar Padang, Sumatera
Barat, Indonesia
Phone:+628126709150
Email:
syam_unp@yahoo.co.id

Univ Med 2014;33:205-12

ABSTRACT

UNIVERSA MEDICINA
September-December, 2014September-December, 2014September-December, 2014September-December, 2014September-December, 2014                         Vol.33 - No.3                        Vol.33 - No.3                        Vol.33 - No.3                        Vol.33 - No.3                        Vol.33 - No.3

BACKGROUND
The prevalence of type-2 diabetes mellitus (T2DM) has been increasing rapidly
in developed and developing countries. Many new loci associated with T2DM
have been uncovered by genetic and genome-wide association studies, eg. the
transcription factor 7-like 2 (TCF7L2) gene variant rs7895340 has been
associated with type-2 diabetes mellitus. The aim of this research was to find
an association between polymorphisms of TCF7L2 gene variant rs7895340
with T2DM in ethnic Minangkabau.

METHODS
This was a case-control study using a consecutive sampling technique among
ethnic Minangkabau patients who came for treatment to the Metabolic
Endocrinology Polyclinic at Dr. M. Jamil Hospital. Analysis was performed
on 132 subjects (66 T2DM patients and 66 controls). DNA was isolated from
venous blood samples and amplified using the amplification refractory mutation
system - polymerase chain reaction (ARMS-PCR) method to detect single
nucleotide polymorphisms (SNPs) of TCF7L2 gene variant rs7895340. To
determine the significance of association of SNPs of rs7895340 with T2DM in
ethnic Minangkabau, data analysis was performed using chi-square test.

RESULTS
The ARMS - PCR for TCF7L2 gene variant rs7895340 found polymorphisms
in 28 (42.42%) subjects with type 2 diabetes mellitus and in 15 (22.72%) non-
diabetic subjects.There was a significant association between rs7895340 SNPs
with the probability of T2DM in ethnic Minangkabau (OR=2.505, p=0.026).

CONCLUSIONS
Single nucleotide polymorphism rs7895340 of TCF7L2 gene can be used as
genetic marker of type-2 diabetes mellitus in ethnic Minangkabau.

Keywords: TCF7L2 gene, rs7895340 SNP, type-2 diabetes mellitus, ethnic
Minangkabau

Transcription factor 7-like 2 as type-2 diabetes mellitus
diagnostic marker in ethnic Minangkabau

Syamsurizal*, Yanwirasti**, Asman Manaf**, Jamsari***, ML Edy Parwanto****,
and Arif Sardi*****



206

Transcription factor 7-like 2 sebagai petanda diagnostik
untuk diabetes melitus tipe-2 pada etnik Minangkabau

LATAR BELAKANG
Prevalensi diabetes melitus tipe 2 (DMT-2) semakin meningkat baik di negara berkembang maupun negara maju.
Penelitian mengenai hubungan genetik dengan berbagai kelainan masih perlu diteliti. Varian gen transcription
factor 7-like 2 (TCF7L2) yang diduga kuat berasosiasi dengan DMT-2 adalah snp rs7895340. Kehadiran G alel
dalam rs7895340 mengindikasikan meningkatnya kerentanan individu terhadap DMT-2. Tujuan penelitian
menentukan hubungan antara polimorfisme snp rs7895340 dari gen TCF7L2 dengan DMT-2 pada etnik
Minangkabau.

METODE
Penelitian ini merupakan penelitian kasus-kontrol. Pemilihan sampel berdasarkan teknik consecutive sampling
pada etnik Minangkabau yang datang berobat ke poliklinik Endokrinologi Metabolik RSUP Dr. M. Djamil. Sebagai
pembanding dipakai kelompok kontrol orang sehat tidak diabetes melitus tipe-2. Kasus adalah subjek etnik
Minangkabau penderita DMT-2 sebanyak 66 orang dengan kontrol juga sebanyak 66 orang. DNA diisolasi dari
darah semua sampel, kemudian diamplifikasi menggunakan metoda amplification refractory mutation system -
polymerase chain reaction (ARMS-PCR) untuk mendeteksi single nucleotide polymorphisms (SNPs) rs7895340
pada gen TCF7L2. Analisis hubungan gen TCF7L2 varian rs7895340 dengan diabetes melitus tipe-2 digunakan
uji chi-square.

HASIL
Hasil ARMS-PCR pada gen TCF7L2 varian rs7895340 pada subyek diabetes mellitus tipe-2 ditemukan polimorfisme
sebanyak 28 orang (42,42%), dan pada subyek tidak DMT2 (kontrol) hanya 15 orang (22,72%). Hasil uji chi-
square membuktikan adanya hubungan yang signifikan antara gen TCF7L2 varian rs7895340 dengan DMT-2 (OR
= 2,505, p=0,026).

KESIMPULAN
Gen TCF7L2 varian rs7895340 dapat dijadikan petanda genetik untuk diabetes melitus tipe-2 pada etnik
Minangkabau.

Kata kunci: Gen TCF7L2, rs7895340, diabetes melitus tipe-2, etnik Minangkabau

ABSTRAK

INTRODUCTION

Diabetes mellitus (DM) is a complex
metabolic disease caused by pancreatic cellular
damage. It is clinically classified into four types:
type 1 diabetes mellitus, type 2 diabetes mellitus
(T2DM), gestational diabetes mellitus, and other
t y p e s  o f  d i a b e t e s  m e l l i t u s .  T 2 D M  i s
characterized by the phenomenon of insulin
resistence as a result of relative insulin
deficiency.(1) The prevalence of T2DM has been
increasing in developed and developing

countries.(2-4) The prevalence of DM in Indonesia
is 4.1%, while in West Sumatra for the year 2000
it was estimated to be 5.1%.(5) Patients with
diabetes commonly suffer from cardiovascular
complications, which are the most common cause
of death in patients with diabetes mellitus.(6-8) The
diagnostic methods for DM are still being
developed, e.g. using DNA analysis. To perform
DNA analysis, data are required on genes
associated with T2DM. Several ethnic groups
in the world have already gene banks for T2DM,
e.g. in Denmark, USA, UK, France, and India.(9)

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207

Through DNA or gene analysis, patients with
T2DM can be more rapidly and accurately
diagnosed.

Although there are not many monogenic
causes of diabetes, such as in  maturity onset
diabetes in the young (MODY), several gene
variants have been found through extensive
research as causes of T2DM, among others
PPARG (Pro12 Ala), KCNJ11, CAPN-10, and

the genes for  PC-1, PGC-1á , and IRS-2.(9)

Recently the association of the transcription
factor 7-like 2 (TCF7L2) gene with T2DM was
mapped and consistent gene variants were found
in several populations or ethnic groups. The
TCF7L2 gene on chromosome 10q is strongly
associated with T2DM (10) in ethnic Danes,
Indians, and several Asian ethnic groups.(9,11,12)

The human TCF7L2 gene consists of 224429
bp and encodes a high mobility group (HMG)
box that is a transcription factor for the Wnt
pathway. The protein transcription product is
implicated in the homeostasis of glucose in the
blood. Its gene variants are associated with an
increased risk for T2DM.(13)

An appropriate marker or haplotype may
furnish indications of increased susceptibility of
an individual to T2DM, characterized by a
minimum relative risk of 1.2-1.4. One variant
of the TCF7L2 gene that is believed to be
associated with T2DM is rs7895340, with
ACAGTTCTAGACACCTAGAGAGTAAA[A/
G]TGAAGAAGCCTGTTTTCAGGTTTCC as
sequence motif.(13) The presence of the G allele
in rs7895340 is an indication of increased
susceptibility to T2DM.(10,14,15)

The aim of the present study was to evaluate
TCF7L2 gene variant rs7895340 polymorphisms
as diagnostic marker for T2DM in ethnic
Minangkabau.

METHODS

Design of the study
T h i s  w a s  a  c a s e - c o n t r o l  s t u d y  o n  a

population of ethnic Minangkabau patients with
type-2 diabetes mellitus who attended the

Metabolic Endocrinology Polyclinic at Central
General Hospital Dr. M. Djamil. Controls were
taken from healthy ethnic Minangkabau without
T2DM.  The study was carried out at the
Biomedical Laboratory, Faculty of Medicine,
Andalas University, from February 2013 until
April 2014.

Subjects of the study
The subjects of the study were ethnic

Minangkabau who were healthy as well patients
with T2DM. The diagnostic criteria for cases
and controls were fasting blood glucose (FBG)
a n d  2 - h o u r  p o s t p r a n d i a l  b l o o d  g l u c o s e
(2HPPBG). The diagnosis of T2DM was based
on FBG >126 mg/dL, 2HPPBG >200 mg/dL,
that of nondiabetic controls FBG <100 mg/dL
and 2HPPBG <140 mg/dL.

The inclusion criteria in this study were:
ethnic Minangkabau domiciled in West Sumatra;
b o t h  p a r e n t s  a n d  a l l  g r a n d p a r e n t s  o f
Minangkabau ethnicity, and aged 40-60 years.
The exclusion criteria were: type 2 prediabetes
mellitus; malignancies; chronic disease such as
h e p a t i c ,  r e n a l ,  p u l m o n a r y  d i s e a s e s ,  a n d
pregnancy.

Recruitment was by consecutive sampling
among ethnic Minangkabau patients with T2DM
who came for treatment to the Metabolic
Endocrinology Polyclinic at Central General
H o s p i t a l  D r.  M .  D j a m i l .  H e a l t h y  e t h n i c
Minangkabau without T2DM were used as
controls.
The sample size was determined from the

formula;(16)

where n = number of subjects per group; Zá =
1.960 ; Zâ = 0.842; P = expected proportion of
cases P=1/2 (P1+P2); P1= estimated proportion
of cases (42%) (3) ; P2 = proportion of controls
(subjects without risk factors) (26%).(3)

According to the formula, the sample size
for each group was 62 (62 cases and 62 controls).
In anticipation of drop-outs, each group was
expanded by 5%, giving 66 subjects per group.

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Assay for single nucleotide polymorphisms of
TCFL2 gene variant rs7895340

Blood samples of 2 mL were collected from
each subject in tubes containing EDTA (0.1
mmol/L) and stored at –20 oC before use. For
DNA extraction we used PureLink Genomic
DNA kits (Invitrogen). Testing for success and
e ff e c t i v i t y  o f  g e n o m i c  i s o l a t i o n  w a s  b y
electrophoresis on agarose gel 1.5% at 100 volts
for 30 minutes. The DNA isolation products were
then used as templates for in vitro reaction in
the assay for single nucleotide polymorphisms
(SNPs) of TCF7L2 gene variant rs7895340.

Primers for detection of TCF7L2 gene
variant rs7895340 SNPs were constructed using
a primer designer software. The TCF7L2 gene
sequence used for primer contruction was
obtained from the NCBI gene bank.(13)

Before application of the primers on the
clinical samples, the primer constructs were
subjected to computerized testing, to find any
mispriming of primers against other regions of
the Homo sapiens genome. After no evidence of
mispriming was found, the primer constructs
were ready for synthesis into oligonucleotides.

To evaluate the ability of the primers to
detect TCF7L2 gene variant rs7895340 SNPs,
amplification was done using the Amplification
Refractory Mutation System-Polymerase Chain
Reaction (ARMS-PCR) method. The PCR
reaction was carried out with a PCR master mix
using the Invitrogen RTG kit. Its principle
consists of using three or more primers for
simultaneous amplification of several DNA
regions. One of the three primers is the specific
primer for identification of SNP or mutating
strains. The occurrence of an SNP in a specific
region can be detected by constructing a specific
primer that can recognize the SNP site.

To  d e t e c t  t h e  A R M S - P C R  D N A
amplification products, electrophoresis was done
on agarose 1.5%. A test sample without
rs7895340 polymorphisms (wild type) produces
two large fragments of ± 431 bp and ±209 bp,
respectively. The presence of one fragment of ±

431 bp indicates a mutation or polymorphism in
TCF7L2 gene variant rs7895340. All samples,
consisting of 66 T2DM patients and 66 controls,
were subjected to tests for TCF7L2 gene variant
rs7895340 polymorphisms. Selected samples
were sequenced for checking and confirmation
of the ARMS-PCR results. Description of the
primer and the assay for the ability to detect
TCF7L2 gene rs7895340 SNPs were performed
at the Biomedical Laboratory, Faculty of
Medicine, Andalas University.

Ethical clearance
The present study obtained ethical clearance

f r o m  t h e  F a c u l t y  o f  M e d i c i n e ,  A n d a l a s
University.

Data analysis
The significance of the association of

TCF7L2 gene variant rs7895340 SNPs was
analyzed by the chi-square test.

RESULTS

Three primer constructs were made, i.e.
RS78F, RS78R and RS78C. The primers RS78F
and RS78C were forward primers, whereas
RS78R was the reverse primer. Primers RS78F
and RS78R were used for DNA amplification
comprising a region of ± 431 bp (external
primer). Primers RS78C and RS78R were used
for amplification of the region that will directly
recognize the rs7895340 SNP (internal primer,
of ± 209 bp).

The RS78F primer sequence was: 5'-
CCTTGTGATGTCTTCTCTCC-3', with GC=
50% and Tm C=64oC. The RS78R primer
sequence was: 5'-ACATCTTCTCTCCTCA
CTC-3', with GC=50% and Tm C=61 oC. The
RS78C primer sequence was: 5'-GAGACCTAG
AGAGT GAAG-3', with GC=50% and Tm
C=58 oC. Visualization of the electrophoresis
results (electrophoregram) of the PCR products
for the primer pairs RS78C, RS78F and RS78R
is presented in Figure 1.

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209

Figure 1. Visualization of ARMS-PCR assay using
the primer pairs RS78C, RS78F and RS78R. D11 =
sample code for T2DM patients; N11 = sample code

for normal controls; L = 100 bp DNA ladder

In addition to the use of the ARMS-PCR
method for recognizing rs7895340 SNPs, this
study also used direct DNA sequencing. After
having been submitted to a BLAST search, the
direct sequencing results yielded a query score
of 200, indicating that the PCR results with the
RS78 forward and reverse primers indeed
originated from a fragment of the TCF7L2 gene.

Figure 2. Alignment sequencing results with TCF7L2 variant rs7895340 SNP motif; a. Sample with
polymorphism resulting in A�G base change; b. Sample without polymorphism, with sequencing

results identical to the rs7895340 SNP motif.

The sequencing results were then aligned with
the rs7895340 SNP nucleotide profile. The
alignment results proved that the PCR products
with RS12 forward and reverse primers indeed
orignated from a fragment of the TCF7L2 variant
rs7895340 SNP, so that they could be used to
detect the SNP of interest. The sequencing results
are shown in Figure 2.

The results of association analysis of
TCF7L2 variant rs7895340 SNP in 66 subjects
with T2DM and 66 non-T2DM subjects of
Minangkabau ethnicity may be seen in Table 1.

DISCUSSION

In this study we found a significant
association of rs7895340 SNP with the risk for
T2DM in ethnic Minangkabau. Our results are
consistent with those of several previous studies
carried out on a number of ethnic groups in
Asia,(18) Iceland,(15) and Finland.(19) Table 2
illustrates that rs7895340 is highly correlated
with T2DM in ethnic Minangkabau. This
indicates that Minangkabau individuals with an
rs7895340 SNP have a 2.5-fold probability to
suffer from DM in comparison with individuals
without the SNP.

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Syamsurizal, Yanwirasti, Manaf, et al                                                            Transcription factor 7-like 2 as diagnostic marker

Table 1. Association of TCF7L2 variant rs7895340 SNP with T2DM subjects

The TCF7L2 gene, also known as TCF-4,
belongs to the T-Cell Factor (TCF)/Lymphoid-
enhancing factor family of the HMG box that
comprise transcription factors for the Wnt
signaling pathway, a key component for the
r e g u l a t i o n  o f  c e l l  p r o l i f e r a t i o n  a n d
differentiation.(20) Wnt activity is also important
for lipid and glucose metabolism, proliferation
and functioning of pancreatic beta cells, and
production of the glucagon-like peptide-1 (GLP-
1) incretin hormone. (21) Together with the
TCF7L2 nuclear receptor, WNT signaling is an
important factor in GLP-1 secretion by intestinal
endocrine L-cells. A change in this pathway may
trigger decreased GLP-1 secretion, which then
affects insulin secretion. GLP-1, in close
association with insulin, plays an important role
in the homeostasis of glucose in the blood. It
has been established that variation of the
T C F 7 L 2  g e n e  m a y  i n d i r e c t l y  t r i g g e r
susceptibility to T2DM through alterations in
GLP-1 levels.(22)

Diabetes melittus type 2 is a degenerative
disease that will appear in an individual carrying
a genetic defect after long term genetic changes.
With an appropriate diagnostic marker we may
be able to predict the possibility of developing
the disease at an early stage, which will aid in
the prevention and treatment of the disease. On
the basis of the obtained data, the TCF7L2 gene
variant rs7895340 can be used as a diagnostic
marker in ethnic Minangkabau. The diagnosis
of T2DM susceptibility can be established by
detection of polymorphisms in rs7895340. The
detection may be done by ARMS-PCR that can
specifically recognize the SNP-bearing region.

The success of an ARMS-PCR assay in
detecting mutations/SNPs is highly dependent on

the specificity of the constructed primer. The
choice of the correct primer will facilitate
recognition and analysis of an SNP in a sample.
E r r o r s  i n  p r i m e r  s e l e c t i o n  r e s u l t  i n  t h e
amplification of a different region, which will
influence the quality of the assay results.
Nonspecificity of the selected primer for a given
region or SNP will preclude detection. Therefore
the primer construction process is an early and
crucial step in SNP detection.

Before being applied to a clinical sample,
the primer should subjected to computerized
testing, involving not only the site of primer
adherence, but also other criteria that may
influence the PCR assay. Among the several
criteria for primer construction to be considered
are the Tm and G+C content, which will affect
the annealing temperature of the primer. Other
criteria are primer homology to template DNA,
the possibility of primer dimer and hairpin
formation, and various intra- and inter-molecular
reactions capable of leading to erroneous PCR
results.(17) From the enumeration of primer
criteria, it may be seen that all three primers were
in relatively ideal condition.

Visualization of the ARMS-PCR assay
using the primer pairs RS78C, RS78F and
R S 7 8 R  c a n  b e  s e e n  i n  F i g u r e  1 .  T h e
electrophoresis results show the presence of 2
DNA bands formed by amplification of the non-
T2DM (control) blood samples. Both bands have
estimated positions of ± 239 bp and ± 431 bp,
respectively, while amplification of the T2DM
templates yielded one band at a position of ±
431 bp. This indicates that in these conditions
only the primers RS78F and RS78R were able
to amplify the DNA target, whereas amplification
of primers RS78C and RS78R could not be



211

continued because of the prior occurrence of
changes (SNPs) in the DNA sequence of the
TCF7L2 gene. The occurrence of an SNP in a
given region may be found with a primer
construct that specifically recognizes the mutant
site. This may be done by positioning the 3’ end
of the primer exactly within the SNP/point
mutation sequence. The primer could not amplify
the proposed target DNA because of a nucleotide
change in the template. As a result of the differing
PCR target, the Taq DNA polymerase was unable
to continue the amplification process in the region
of interest.(17)

On the basis of these data, it may be
concluded that the ARMS-PCR assay may be
used to detect SNPs in the TCF7L2 gene,
particularly rs7895340 SNPs. However, this
method has a limitation: the assay cannot
possibly detect 100% of the SNPs in the TCF7L2
gene, which contains more than 25 types of
SNP.(15) In spite of this, its high specificity and
sensitivity in detecting SNPs may be cited as one
of the reasons why this method can be used. In
comparison with other SNP detection methods,
ARMS-PCR has several advantages, being more
economic and easily applied. It is faster in
execution, since the whole process, from the
preparation of reagents and equipment, addition
of genomic DNA (template), ARMS-PCR
amplification, to agarose gel electrophoresis, can
be completed in one day. Its rapid application
and ease of execution for detection of rs7895340
SNPs are essential for the prevention of T2DM.
This method is relatively ideal to be applied in
Indonesia, since in contrast with other molecular
m u t a n t  d e t e c t i o n  m e t h o d s  ( s u c h  a s  t h e
microarray technique), that use sophisticated
equipment, are expensive, and need specialized
expertise, the ARMS–PCR method is simpler.
T h i s  m e t h o d  a p p l i e d  t h e  p r i n c i p l e s  o f
simultaneous PCR with a number of primers
(multiplex PCR), which are generally available
in almost every region in Indonesia. Although
relatively simple, the ARMS–PCR technique still
has a high sensitivity in detecting SNPs.

CONCLUSIONS

The TCF7L2 gene variant rs7895340 may
be used as a genetic marker for type 2 diabetes
mellitus in ethnic Minangkabau. In other words,
the polymorphisms in the TCF7L2 gene variant
rs7895340 can be used as an indicator of the
r i s k  f a c t o r  c o n t r i b u t i n g  t o  i n d i v i d u a l
susceptibility to type 2 diabetes mellitus in ethnic
Minangkabau.

ACKNOWLEDGEMENTS

We hereby express our gratitude to the
R e c t o r  o f  P a d a n g  St a t e  U n i v e r s i t y,  w h o
facilitated this study, so that it could be
sponsored by a Hibah Bersaing grant for 2014
f r o m  t h e  D i r e c t o r a t e  G e n e r a l  o f  H i g h e r
Education (Dirjen Dikti), Ministry of Education
and Culture, Republic of Indonesia. We also
thank all staff at the Biomedical Laboratory,
Faculty of Medicine, Andalas University, who
contributed towards the successful completion
of this study.

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Syamsurizal, Yanwirasti, Manaf, et al                                                            Transcription factor 7-like 2 as diagnostic marker