Research Article Volume 5 Issue 6
Department of Anthropology, University of Calcutta, India
Correspondence: Arup Ratan Bandyopadhyay, Department of Anthropology, University of Calcutta. 35, Ballygunge circular Road, Kolkata-700019, India
Received: October 23, 2018 | Published: November 22, 2018
Citation: Ghosh K, Sarkar P, Chatterjee D, et al. Association of fat patterning, hypertension and ACE (I/D) gene polymorphism: a study on two Tibeto-Burman linguistic group of Tripura, North East India. MOJ Anat & Physiol. 2018;5(6):368-371. DOI: 10.15406/mojap.2018.05.00227
Background: Hypertension is considered as a major cause of morbidity and mortality throughout the world and become a major global burden on public health in many developing countries. Regulation of blood pressure is a complex process. Apart from environmental factors, multiple genes have been responsible for hypertension. The gene-environment and fat patterning interaction in the pathogenesis of hypertension has not been extensively studied in the north-east Indian ethnic groups.
Aim: In this context, to best of our knowledge this is a maiden attempt to discern the association between fat patterning, blood pressure and ACE (I/D) gene polymorphism among the two Tibeto-Burman speaking ethnic groups (Chakmas and Tripuris) of North East India (Tripura).
Materials and methods: To achieve the purpose, total 293 (Chakma 148 and Tripuri 145) apparently healthy unrelated adult males from Tripura, North East India were incorporated in the present study. Anthropometric variables and physiological variables (blood pressure) have been collected using standard techniques. Extracted genomic DNA from mouthwash was PCR amplified and genotyped to understand ACE gene I/D polymorphism.
Results: Examination on the association of fat patterning and hypertension revealed significantly (p<0.05) higher hypertensive individuals and accumulation of central obesity among the Chakmas compared to the Tripuris. ACE (I/D) gene polymorphism demonstrated higher frequency of ‘I’ allele in the present study groups and the findings of the present study is in agreement with the distributions found in Asiatic populations and also in close corroboration with other Tibeto Burman linguistics groups of North East India.
Conclusion: Significantly (p<0.05) higher hypertensive individuals were found among the Chakmas in comparison to the Tripuris. The present study envisaged central adiposity is a major risk factor for hypertension in Chakmas rather than ACE (I/D) polymorphism.
Non-Communicable Disease(s) (NCDs) includes cardiovascular disease, cancer, chronic lung diseases, and diabetes. Hypertension, overweight, physical inactivity, alcohol consumption are considered as the most important risk factors for NCDs (WHO, 2012). Most of the NCDs are multifactorial in nature. Both genes and environment are responsible for the prevalence of NCDs. Hypertension is often called “The silent killer” because it generally has no symptoms until serious complications develop.1 Hypertension is considered as a major cause of morbidity and mortality throughout the world and become a major global burden on public health in many developing countries.2 The prevalence of hypertension will be gradually increased up to 60% by 2025. In developed countries, the prevalence of hypertension ranges between 22% and 55%. In a recent report by World Health Statistics 2012 it was estimated that 63% of global death were occur due to non-communicable diseases (NCDs). The largest proportion of NCD deaths is caused by cardiovascular diseases (48%). The prevalence of hypertension for the European average was 44.2% compared with 27.6% in North America. In US the median prevalence of total hypertension in 2009 was 37.6% in men and 40.1% in women.3 National Health and Nutrition Examination Survey (1999-2004) found that the prevalence of hypertension in the USA increased from approximately 27% to 29%. Similarly another survey by NHANES from 2004–2007 revealed a high prevalence of hypertension.4
The prevalence of hypertension varied among different studies in India, ranging from 2-15% in urban India and 2-8% in rural India. In developing countries, it is the seventh highest contributor to premature death. CVD was the largest cause of deaths in males (20.3%) as well as in females (16.9%) and it leads to 2 million deaths annually.5 In India there is a trend of gradual increase in the prevalence of hypertension in last six decade. The prevalence of hypertension was found around 16.9% among Gujarat labor population.6
The Renin Angiotensin System (RAS) is an important system in regulating blood pressure and electrolyte balance. Genes encoding components of the RAS have been proposed as candidate genes that determine genetic predisposition to hypertension, diabetes and the risk of developing cardiovascular complications. Among the multiple genetic polymorphisms, the gene that possibly playing an active role in the pathogenesis of hypertension and cardiovascular disease is the angiotensin-converting enzyme (ACE) insertion/deletion (I/D) polymorphism. The ACE gene is mapped to chromosome 17q23 and is encoded by a 21 Kb gene that consists of 26 exons and 25 introns. Variations in the ACE gene, many of which influence levels of the protein, are associated with diseases such as hypertension, myocardial and One of the most important and widely studied variations in ACE is a 287-base pair (bp) Alu insertion/deletion (I/D) polymorphism in intron 16 (rs4340). The D allele was found to raise ACE plasma levels in Europeans.7 The insertion/deletion (I/D) polymorphism of ACE is characterized by the presence (insertion) or absence (deletion) of a 28 bpAlu repeat sequence in intron 16 producing three genotypes (II homozygote, ID heterozygote and DD homozygote). Although the I/D polymorphism is located in a non-coding region (i.e. intron) of the ACE gene, several investigators have found that the D allele is related to increased activity of ACE in serum.8 It is observed that the II genotype has lowest ACE levels while the DD type has the highest and finally the ID genotype has the intermediate level.9
India, occupying the Centre-stage of Paleolithic and Neolithic migrations, and somewhat has been under-represented in genome-wide studies of variation.10 Being at the crossroads of migration, Indian populations have undergone complex and ancient admixture events over a long period11–13 and have been the melting-pot of disparate ancestries originating from different parts of Eurasia and South-East Asia.13 Although the date of entry of modern humans into India remains uncertain but it is reasonable to consider by the middle Paleolithic period (50,000–20,000 years before present [ybp]), humans appear to have spread onto many parts of India.14 Contemporary ethnic India is a land of enormous genetic, cultural, and linguistic diversity.15,16 A more recent study exploring Indian genomic diversity demonstrated four major ancestral genetic components in mainland India that included four dominant ancestries in populations from mainland India: Ancestral North-Indian (ANI), Ancestral South-Indian (ASI), Ancestral Tibeto–Burman (ATB) and Ancestral Austro-Asiatic (AAA).13
On the basis of the literature review on major and contributing publications regarding ACE I/D genetic polymorphism of the North East Indian population, it has been found that studies on the tribal population of Tripura seems to be under represented. In this backdrop, the present study, to best of the knowledge is the first attempt to understand the above mentioned issues on three Tibeto-Burman speaker endogamous ethnic populations (Chakmas - the migrant group and Tripuris–the aboriginal group) of North East India (Tripura).
Present study was conducted among the one forty eight (148) participants of Chakmas, one hundred forty five (145) participants from Tripuri group. Prior to the study verbal consent were obtained from the participants.
Mouth wash was collected from all the participants in 15ml centrifuge tube. Genomic DNA was isolated from mouthwash following standard technique17 with slight modification. PCR products were genotyped for I (Insertion) and D (Deletion) alleles of ACE gene using locus specific primer viz. Forward Primer-5’-CTG GAG ACC ACT CCC ATC CTT TCT-3’ Reverse Primer-5’-GAT GTG GCC ATC ACA TTC GTC AGA T-3’. PCR product was taken for 2.5% agar gel electrophoresis containing ethidium bromide. The ACE I/D polymorphism consists of the presence (insertion, I) or absence (deletion, D) of 287-bp Alu repeat in intron 16 resulting in three genotypes: insertion homozygous (Ins/Ins), insertion-deletion (Ins/Del) heterozygous and deletion homozygous (Del/Del). Eventually, after electrophoresis, each DNA sample revealed one of the three possible patterns: a 597-bp band (Ins/Ins genotype), a 319-bp band (Del/Del genotype) or both 597-bp and 319-bp bands (Ins/Del genotype). Each sample found to have the Del/Del genotype was subjected to a second PCR amplification with insertion-specific primers to avoid possible Del/Del mistyping.18 Blood pressure (Systolic blood pressures SBP and Diastolic blood pressure- DBP) were also taken following the standard technique19 and classified in accordance with the Seventh Report of the Joint National Committee (JNC-7) recommendation.20 The mean arterial pressure (MAP) was derived (Equation: MAP=[(2 x diastolic)+systolic]/3].21 Allele frequencies were calculated by Maximum Likelihood Estimation.22 Obtained data were doubly checked and analyzed using the SPSS (Version-16.0). Descriptive and inferential statistics were done in appropriate places and cut off was set as p=0.05.
The studied population
The Chakmas have inhabited the Chittagong Hill Tracts since long before the region became part of the Mughal Empire in 1666. Buddhism flourished in Bangladesh from the 5th to 12th centuries. Since the 13th century, Buddhism has been confined to the Chittagong area. The Chakma 'continued to acknowledge the suzerainty of the Arakanese king until 1784. According to the Census of India (2011) Chakmas in Tripura is 79813. Tripuris belong to linguistically within the Tibeto-Burman family. Tripuris are the largest tribal community in Tripura. They have first migrated in this territory and could be introduced as aboriginal tribe of Tripura. Numerically as per 2011 Census they are 592255 people in the State and Tripuris are numerically highest in number among all the tribal groups.23
Anthropometric and physiological characteristics of the age matched studied populations (Table 1) demonstrated the Chakmas were significantly (p<0.05) taller than the Tripuris. Examination on Waist Circumference (WC) and Hip circumference (HC) revealed significantly (p<0.05) higher circumferences among the Chakmas in comparison to the Tripuris. However, BMI as general obesity marker did not show any difference between the two populations might be due to no difference in weight. Waist to Hip Ratio (WHR) as a measure of central obesity demonstrated significantly (p<0.05) higher central obesity among the Chakmas in comparison to the Tripuris. So far the Blood pressure as physiological variables concerns revealed significantly (p<0.05) higher SBP, DBP and derived MAP among the Chakmas compared to those of the Tripuris.
Variables |
Chakma (N=48) |
Tripuri (N=45) |
Age (years) |
36.07±12.65 |
35.62±12.03 |
Anthropometric |
||
Stature (cm) |
165.53±4.88* |
162.54±6.71 |
Weight (kg) |
62.98±9.12 |
61.19±12.63 |
WC (cm) |
87.18±10.128* |
81.44±10.51 |
HC (cm) |
92.70±9.32* |
91.76±8.02 |
BMI |
23.21±3.38 |
23.48±4.37 |
WHR |
0.89±.08* |
0.86±0.09 |
Physiological |
||
SBP (mm/Hg) |
150.00±29.3* |
133.72±19.2* |
DBP (mm/Hg) |
88.42±13.30* |
81.22±13.20 |
MAP (mm/Hg) |
108.94±16.65* |
98.72±13.58 |
Table 1 Anthropometric and physiological characteristics of studied population
Distribution of genotypes of ACE (I/D) gene polymorphism (Table 2) demonstrated significant (p<0.05) difference in genotypes between the Chakmas and Tripuris and also revealed higher I alleles among the Chakmas in comparison to Tripuris.
Population |
Genotype |
Allele frequency |
|||
II |
ID |
DD |
I |
D |
|
Chakma |
96 (64.86) |
1 (0.68) |
51 (34.46) |
0.652 |
0.348 |
Tripuri |
74 (51.03) |
1 (0.69) |
70 (48.28) |
0.514 |
0.486 |
Table 2 Distribution of genotype and allele frequencies of ACE (I/D) gene polymorphism of the studied populations
Figures in the (parenthesis) denotes the percentage
Distribution of hypertensive and normotensive groups classified in terms of SBP and DBP according to JNC 7 and ACE (I/D) genotypes including the allele frequencies among the studied populations presented in Table 3 & 4 revealed significantly (p<0.05) higher hypertensive individuals among the Chakmas compared to the Tripuris. Furthermore, the distribution of ACE (I/D) gene polymorphism demonstrated significant (p<0.05) between the two populations and higher I allele among the Chakmas in comparison to Tripuris for both the SBP and DBP.
Population |
Hypertensive |
Normotensive |
Genotypes |
Allele frequency |
|||
II |
ID |
DD |
I |
D |
|||
Chakma (n=148) |
59(39.86) |
89 (60.14) |
96 (64.86) |
1 (0.68) |
51 (34.46) |
0.652 |
0.348 |
Tripuri (n=145) |
30 (20.69) |
115 (79.31) |
74 (51.03) |
1(0.69) |
70 (48.28) |
0.514 |
0.486 |
Table 3 Distribution of Normotensive and Hypertensive (JNC7) according to SBP and the genotypes including allele frequency of ACE (I/D) gene polymorphism among the studied populations
Figures in the (parenthesis) denotes the percentage
Population |
Hypertensive |
Normotensive |
Genotypes |
Allele frequency |
|||
II |
ID |
DD |
I |
D |
|||
Chakma (n=148) |
54 (33.78) |
94 (66.28) |
93 (64.86) |
1 (0.68) |
54 (34.46) |
0.632 |
0.368 |
Tripuri (n=145) |
36 (24.83) |
109 (75.17) |
80 (51.03) |
1 (0.69) |
75 (48.28) |
0.556 |
0.444 |
Table 4 Distribution of Normotensive and Hypertensive (JNC7) according to DBP and the genotypes including allele frequency of ACE (I/D) gene polymorphism among the studied populations
Figures in the (parenthesis) denotes the percentage
Examination of blood pressure categories classified according to obesity pattern among the Chakmas (Table 5) and Tripuris (Table 6) revealed significant (p<0.05) differences in BMI (general obesity), WC and WHR (Central obesity) between hypertensive and normotensive individuals for both the populations.
Category |
Hypertensive |
Normotensive |
P |
|
BMI |
Normal |
18 |
90 |
0.05 |
Overweight |
36 |
1 |
||
Obese |
2 |
1 |
||
WC (cm) |
Normal |
17 |
65 |
0.05 |
Risk |
39 |
27 |
||
WHR |
Normal |
15 |
85 |
0.05 |
Risk |
41 |
7 |
Table 5 Distribution of Fat patterning according to hypertension and normotensive blood pressure among the Chakmas
Category |
Hypertensive |
Normotensive |
P |
|
BMI |
Normal |
11 |
86 |
0.05 |
Overweight |
9 |
35 |
||
Obese |
3 |
1 |
||
WC(cm) |
Normal |
42 |
92 |
0.05 |
Risk |
9 |
2 |
||
WHR |
Normal |
46 |
83 |
0.05 |
Risk |
11 |
5 |
Table 6 Distribution of Fat patterning according to hypertension and normotensive blood pressure among the Tripuris
It would be apparent from the results, that the Chakmas vindicated significantly (p<0.05) higher hypertension and accumulation of central obesity than the Tripuris. The computed MAP (Table 1) indicated Hypertension Grade I24 among the Chakmas compared to that of the Tripuris. The risk factors for NCDs including hypertension so far the central obesity measured through WC and WHR for Asian population.25 The present study revealed significant (p<0.05) effect for Chakmas (Table 5) compared to the Tripuris (Table 6). Although there was no previous study regarding the ACE (I/D) gene polymorphisms of these two Tibeto Burman linguistic groups (Chakma and Tripuri), but the present study observed a higher frequency of ‘I’ allele in the present studied ethnic populations groups and the finding is in agreement with distributions found in Asiatic populations26 and also in close corroboration with other Tibeto Burman linguistics groups like Jamatia and Mizo of North East India.27,28
Authors gratefully acknowledge the financial support from University of Calcutta [BI ((65) 8 & 9] and UGC- UPE 2 grant. Authors are thankful to the study participants and Dr. Rajesh Chatterjee of Tripura University for his untiring support to the fieldwork.
There is no conflict of interest whatsoever.
©2018 Ghosh, et al. This is an open access article distributed under the terms of the, which permits unrestricted use, distribution, and build upon your work non-commercially.