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Kiewhuo M, Yanthan R, MilepoVese M, Swu M, Kiso M, Imsong M. I, PazhüniPfote P, Nandakumar R. Polymorphismic Changes in Blood Groups of the Naga Tribes of Nagaland. Biosci Biotech Res Asia 2019;16(3).
Manuscript received on : 8-June-2019
Manuscript accepted on : 23-Sep-19
Published online on:  30-09-2019

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Polymorphismic Changes in Blood Groups of the Naga Tribes of Nagaland

Magdalene Kiewhuo , RollenYanthan , MilepoVese, Mary Swu,  Medonguno Kiso,  Meyisenla I Imsong, PazhüniPfote, Nandakumar R*

Department of Zoology, St.Joseph University Ikishe Model Village, Dimapur, Nagaland, India- 797115

Corresponding Author E-mail: drnkzoo@gmail.com

DOI : http://dx.doi.org/10.13005/bbra/2770

ABSTRACT: Northern India is one of the oldest geophysical regions of human evolution and migration in the world. Genetic and anthropological studies have shown that the peopling the subcontinent is characterized by a complex history, contributed from different ancestral populations. Genetic level studies of  polymorphisms always associated with health and diseases of population becoming the need of hours.  The present study was aimed to explore the relationship of ABO blood groups association of populations  and to assess the prevalence of blood groups in different categories of Northern India and to compare our results with other studies conducted in India. Blood samples from 155 unrelated individuals was collected from Naga tribal settlements Blood groups of individuals were evaluated with the presence of antigen using monoclonal antibody by a standard blood typing are protocol, Gene frequencies was calculated by Hardy-Weinberg method. The blood group O 67 (43.23%) was the commonest group prevalent in donors followed by group B 45 (29.03%), A 33(21.29%) and AB 10 (6.45%). The Rh negative was not observed in female donors, whereas in male it was found to be 1.3%.Data among tribal suggest their common origin as well as a drift from an original population due to the possible founder effect among tribal Naga Ten Tribal

KEYWORDS: ABO Blood Groups; Diphupar-B; Diversity; Nagaland; Rhesus Factor

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Kiewhuo M, Yanthan R, MilepoVese M, Swu M, Kiso M, Imsong M. I, PazhüniPfote P, Nandakumar R. Polymorphismic Changes in Blood Groups of the Naga Tribes of Nagaland. Biosci Biotech Res Asia 2019;16(3).

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Kiewhuo M, Yanthan R, MilepoVese M, Swu M, Kiso M, Imsong M. I, PazhüniPfote P, Nandakumar R. Polymorphismic Changes in Blood Groups of the Naga Tribes of Nagaland. Biosci Biotech Res Asia 2019;16(3). Available from: https://bit.ly/33MIdS4

Introduction

The ABO blood group system was the first human blood group system to be discovered by Landsteiner in 1900[1]. The ABO blood group system is the only system in which antibodies are consistently and predictably present in the serum of normal individuals whose red cells lack the antigens . Apart from differences amongst species, differences between the individuals of the same species have also been demonstrated. During the world wars, it was discovered for the first time that the frequency of ABO and Rhesus blood groups was different in persons native to different parts of the world [2-3]. ABO and Rh gene phenotypes vary widely across races and geographical boundaries  despite the fact that the antigens involved are stable throughout life. The resultant polymorphism remains important in population genetic studies, estimating the availability of compatible blood, evaluating the probability of hemolytic disease in the new born, resolving disputes in paternity/maternity and for forensic purposes[4]. The frequency of ABO and Rh phenotypes in different populations hasve been extensively studied. Rh system emerged as second most important blood group system due to hemolytic disease of newborn and its importance in RhD negative individuals in subsequent transfusions once they develop Rh antibodies. The D antigen, after A and B, is the most important red cell antigen in transfusion practice[5] . Unlike the situation with A and B, persons whose red cell lacks the D antigen do not regularly have anti D in their serum. Blood bank usually has a problem of ever-changing  stock position and it being very difficult to predict the prevalence of a particular blood group at a particular time. The present study was done to assess the prevalence of blood groups in different categories of Northern India and to compare our results with other studies conducted in India and elsewhere in the world and its multipurpose future utilities for the health planners[ 6-8].

Materials and Methodology

The study of ABO and Rhesus Blood Group was carried out on 155 blood donors (male and female) during a period of two months from 1st september to 31st October 2018 in Diphupar-B area Dimapur, Nagaland. The blood donors were selected after taking a detailed history and a complete examination regarding their eligibility criteria for blood donation. Donor’s name, age, sex, occupation, caste, complete postal address and contact number was recorded. Blood samples were obtained by standard procedures of venupuncture and subjected to determination of ABO and Rhesus blood group using “antisera” by combined slide and test tube method. Each sample of donors was tested for ABO and Rhesus status.

Laboratory analysis

ABO and Rh blood group tests are carried out by a standard protocol using AB D Antisera typing Kit.(Fig. 1.)

Figure 1: The Plate Showing the the result of A B O blood groups Figure 1: The Plate Showing the the result of A B O blood groups

click here to view figure

Statistical analysis

The gene and allele frequencies of blood group, are calculated by Hardy-Weinberg model using S2 ABO estimator software[7].  Allele frequencies are calculated under the assumption of Hardy–Weinberg equilibrium and expressed as percentages. The chi – square test is used to compare observed allelic and genotypic frequency distributions of the blood group and Rh antigens to that of under the Hardy–Weinberg. [9]. ABO blood was aligned according to their respective frequencies in populations using PAST software : PCA and Phylogenetic trees were constructed, using Neighbor-Joining (NJ) method

Table 1: Hardy-Weinberg model for ABO blood group

Phenotype

(blood group)

Genotype Phenotype

frequency

Genotypic

frequency

Expected

frequency

A

B

O

AB

AA+AO

BB+BO

AB

OO

𝑛A

𝑛B

𝑛AB

𝑛O

𝑛AA + 𝑛AO

𝑛BB + 𝑛BO

𝑛AB

𝑛OO

p2 + 2pr

q2 + 2qr

2pq

r2

Results

The ABO and Rhesus blood Group in Diphupar-B showsed various typical results. The frequency of ABO and Rh blood groups in a total of 155 (male and female)donor population was compared. Amongst Rh positive female donors blood group O was found to be most prevalent in  group 34(45.95%), followed by group B 23(31.08%), A 14(18.92%) and AB 3(4.05%). Amongst Rh positive male donors blood group O was the most prevalent group 33(41.77%), followed by group B 21(26.58%), group A 18(22.78%) and group AB 7(8.86%).  The Rh negative does not exist in any female donors. The Rh negative appears only in male donors in blood group A-ve(1) and B-ve (1)with 1.3%..

Table 2: Overall allele frequencies for the ABO and Rh antigens in the Ten studied populations

Group Gene frequency Hardy-

Weinberg log

likelihood

Genotypic

frequency

𝜒2 𝑃value Rh+(D) Rh-(d)
p[A] q[B] r[O]
Total 0.16 0.2 0.64 -179.3 O>B>A 0.11 0.73 0.99 0.01
Chekhesang 0.13 0.30 0.57 -57.48 O>B>A 0.95 0.32 1.00 0.00
Sumi 0.27 0.03 0.70 -15.20 O>A>B 0.39 0.52 1.00 0.00
Angami 0.10 0.10 0.8 -15.09 O>A =B 0.39 0.53 1.00 0.00
Ao 0.20 0.27 0.51 -40.03 O>B>A 1.45 0.22 0.97 0.03
Mao 0.2 0.16 0.64 -16.40 O>A>B 1.34 0.25 1.00 0.00
Lotha 0.13 0.07 0.8 -07.30 O>A>B 0.17 0.68 1.00 0.00
Konyak 0.23 0.44 0.32 -09.17 B>O>A 0.47 0.50 1.00 0.00
Zeliang 0.15 0.15 0.70 -08.07 O>A =B 1.59 0.20 1.00 0.00
Sangtam 0.28 0.28 0.44 -05.75 O>A =B 0.42 0.51 0.63 0.33
Phom 0.42 0.18 0.40 -07.62 A>O>B 0.02 0.90 1.00 0.00

The study populations used in blood groupings   occurred in the order O> B >A > AB .The allele frequency of blood group O was the highest ABO allele p (A), q (B), r (O) as 0.16, 0.2 , 0.64, respectively. This occurred in the order O> B >A. The allele frequency of blood group O is the highest 𝜒2. The goodness of fit test was resulted in value was = 0.11 and p value was 0.73. The genotype frequencies are reached (D) = 99.0% and (d) = 1%, genotype frequencies are (D) = 0.99 and (d) = 0.01. There is the high proportion of Rh (D) +ve individuals than the Rh – ve in the study populations.

Table 3: Detailed list of all donors and their corresponding bio-data

Sl No. Name Age Sex Blood Group Tribe
1 Medou 22 F O+ Chakhesang
2 Awistoli 22 F O+ Sumi
3 Asenuo 22 F O+ Angami
4 Supenro 19 F B+ Lotha
5 Nyemang 21 F O+ Konyak
6 kilingna 20 F O+ Zeliang
7 Amy 19 F A+ Sumi
8 Woben 21 F O+ Lotha
9 Savinu 21 F A+ Angami
 10 Wesly 21 F O+ Chakhesang
11 Kenlingunuuo 19 F O+ Sumi
12 Pelevituo-u 24 F O+ Angami
13 Mhasilenuo 45 F O+ Angami
14 paziini 22 F B+ Mao
15 A.moses 22 M B+ Mao
16 Amenla 23 F A+ Mao
     17 Bethibra 33 F B+ Mao
18 Sentiro 22 F A+ Mao
19 Leshini 30 F A+ Mao
20 Kokhrolu 24 M O+ Mao
21 Eliveyi 24 M O+ Mao
22 Rokositi 23 M O+ Mao
23 Benlo 24 M A+ Mao
24 Savio 45 M A+ Angami
     25 Itevika 22 M O+ Sumi
26 Manato 21 M O+ Sumi
27 S.sanmei 23 M B+ Angami
28 Khrilazo 22 M O+ Sumi
29 Savito 22 M O+ Sumi
30 Nyewe-u 21 F O+ Chakhesang
31 Julie 19 F B+ Chakhesang
32 Krecheni 22 F O+ Mao
33 Aniphro 22 F A+ Mao
34 Marini 21 F O+ Mao
35 Tsukhum 22 M B+ Mao
36 Fuchumlo 22 F O+ Lotha
37 Lutsu 22 F O+ Pochury
38 Asen 22 F A+ Ao
39 Atsu 21 F O+ Yimchunger
40 Hukai 24 M O+ Sumi
41 Asang 49 F B+ Ao
42 Kehosedel 54 M O+ Angami
43 Roko 22 M B+ Angami
44                 Nieketouzo 22 M O+ Angami
45 Kenli 23 F O+ Angami
46 Alokeu 24 F O+ Lotha
47 Lanu 25 F O+ Sumi
48 Mhalevino 22 F A+ Sumi
49 Rencham0 22 F O+ Ao
50 Vilasilie 22 M B+ Angami
51 Vileto 24 M A+ Angami
52 Nchumbeni 21 F O+ Angami
53 Adino 25 F O+ Muslim
54 Jabeda 25 F A+ Muslim
55 Yantsuntung 26 M A+ Lotha
56 Sai 23 M O+ Zeliang
57 Merlin 2 F B+ Pochury
58 Sentilemla 24 F A+ Ao
59 Akato 25 M O+ Suni
60 Kewe 26 M O+ Sumi
61 Mercy 4 F O+ Sumi
62 Manen 22 F O+ Sumi
63 Nally 23 M A+ Phom
64 Seyiesu 24 F B+ Zeliang
65 Waltrina 25 M AB+ Angami
66 Alona 26 F A+ Garo
67 Kivisu 21 M O+ Angami
68 Binlozu 30 F B+ Rengma
69 Keyiening 32 F O+ Zeliang
70 Vikeithozo 23 M O+ Angami
71 Vinoka 22 M B+ Sumi
72 Temjen 22 M A+ Ao
73 Wapang 22 M AB+ Ao
74 Yapani 23 F B+ Loyha
75 Nungsen 23 M O+ Ao
76 Sianglu 23 F A+ Zeliang
77 Esther 23 F B+ Konyak
78 Levilu 22 F AB+ Chakhesang
79 Lipok 21 M AB+ Ao
80 Lijingba 30 M A- Sangtam
81 Bishoka 24 F O+ Dimasa
82 Alemla 23 F O+ Ao
83 Aloto 24 M A+ Sumi
84 Vihuka 23 M A+ Sumi
85 Anoka 21 M A+ Sumi
86 Bokato 25 M A+ Sumi
87 Mercy 23 F B+ Konyak
88 Akok 21 M A+ Ao
89 Anengla 22 F B+ Ao
90 Sunglu 22 F B+ Ao
91 Mabeni 24 F O+ Lotha
92 Menibeni 21 F A+ Lotha
93 Alisong 23 M O+ Ao
94 Aka 22 M B- Ao
95 Easter 24 F O+ Sangtam
96 Kese 23 M O+ Angami
97 Even 23 M B+ Konyak
98 Juniya 24 F B+ Dimasa
99 Lily 24 F O+ Konyak
100 Hemsu 23 F B+ Khiamniungun
101 Asen 22 F AB+ Ao
102 Vili 21 M A+ Sumi
103 Velu 21 F O+ Chakhesang
104 Imti 21 M A+ Ao
105 Wati 23 M B+ Ao
106 Lanu 23 M AB+ Ao
107 Amsong 23 M O+ Ao
108 Tatong 25 M B+ Ao
109 Temjen 22 M O+ Ao
110 Akaba 19 M O+ Ao
111 Atubu 22 M B+ Ao
112 Sama 21 M AB+ Ao
113 Tia 18 M O+ Ao
114 Moa 21 M B+ Ao
115 Sunep 22 M B+ Ao
116 Tako 23 M A+ Ao
117 Sashi 27 M O+ Ao
118 Toshi 45 M O+ Ao
119 Yinu 43 M B+ Ao
120 Melekho 22 M O+ Chakhesang
121 Vekho 22 M B+ Chakhesang
122 Veto 22 M O+ Chakhesang
123 Vethi 22 M A+ Chakhesang
124 Achi 22 M A+ Chakhesang
125 Akho 21 M A+ Chakhesang
126 Ato 21 M B+ Chakhesang
127  Khoto 24 M B+ Chakhesang
128 Khrupu 25 M O+ Chakhesang
129 Khruhu 25 M B+ Chakhesang
130 Shehu 23 M B+ Chakhesang
131 Michivo 24 M A+ Chakhesang
132 Vechipo 21 M B+ Chakhesang
133 Kuvezo 24 M AB+ Chakhesang
134 Vebuzo 42 M AB+ Chakhesang
135 Vemucho 33 M B+ Chakhesang
136 Khoshe 31 M O+ Chakhesang
137 Zhosheku 31 M O+ Chakhesang
138 Vepopu 31 M O+ Chakhesang
139 Popo 34 M O+ Chakhesang
140 Alepu 22 M B+ Chakhesang
141 Aku 22 M O+ Chakhesang
142 Khrope 22 M B+ Chakhesang
143 Atalu 34 F B+ Chakhesang
144 Asulu 32 F O+ Chakhesang
145 Avelu 23 F B+ Chakhesang
146 Shelu 21 F B+ Chakhesang
147 Khrulu 22 F O+ Chakhesang
148 Khotalu 22 F B+ Chakhesang
149 Abi 23 F O+ Chakhesang
150 Atho 32 F B+ Chakhesang
 151 Vebunielu 34 F AB+ Chakhesang
152 Shetolu 24 F A+ Chakhesang
153 Shekhrulu 43 F A+ Chakhesang
154 Tsinolu 23 F B+ Chakhesang
155 Vetholu 21 F B+ Chakhesang
Figure 2: Dendrogram of Ten Naga Tribal populations on diversity for ABO polymorphic loci Figure 2: Dendrogram of  Ten Naga Tribal populations on diversity for ABO polymorphic loci

click here to view image

The Neighbour Joining Analyses

Population relationships can be easily represented by Neighbor Joining (NJ) trees. To study the genomic affinities of the tribal populations of Nagalnd, NJ trees was constructed by using various reported investigations in the tribes of India and globally by means of same set of loci/alleles. In the first NJ tree analysis, given in Fig.2. ABO blood  polymorphic loci alleles are used to construct the tree to find the genomic affinities among the tribal populations of Nagaland  under study Interestingly, this tree showed that Mao are clustered with Sumi who are geographically distant from Mao instead of Zeliang, who are thought as same to Sumi,Angami and Lotha. Another surprising genetic relation was established between Ao and Chekesang , though both are geographically very far-off. Overall, this tree showed that the Naga tribes under consideration are interrelated and equally distant from each other in terms of ABO blood allele frequencies.

Figure 3: Principal component analysis based on allele frequencies of ABO polymorphic loci Principal Component Analysis Figure 3: Principal component analysis based on allele frequencies of ABO polymorphic loci Principal Component Analysis

click here to view image

Principal component analyses (PCA) was performed to identify possible clustering among the populations. In the PCA (Figure.3.) using ABO blood, the populations Zeliang, Lotha and  Angami are observed to be falling under a single cluster among the populations.

Human shares the same blood group systems, differing only in the frequencies of specific types. The incidence of ABO, Rh and MN groups varies in different parts of the world and in different races [10]. Geographical and ethnic groups and socioeconomic groups, [11- 12]. Many studies have revealed possible associations of various diseases with the ABO blood group, but the reasons for such associations are remain controversial[13-14].  With Blood group O has a greater incidence of association with hypertension[15] and melanoma[12].  As far as abortion is concerned, it is found to be higher in between A type husband and O type wife and high in couples with  combination of  A type husband and B type wife. The frequencies of Rh positive and Rh-negative individuals are 96.5% and 3.5% respectively[16].  ABO blood groups are important in determining migration of races and in hereditary diseases. [17]. Some diseases are more common to develop in certain blood groups; hence the relationship of different blood groups with diseases is important [18].

The genomic affinities among eleven study populations are represented in Fig2 & 3, using allele frequency data of four loci by a standard NJ tree and Principal component analysis. It has been that all student groups are genetically related to each other, to asses genomic affinities of the ten study populations, the data from the results of presents study groups are assured together and represented in an others NJ tree and Principal component analysis (Fig.2 &

Conclusion

In conclusion, based on ABO blood group poylmpohsms the Naga tribes have genetic roots with others Indian  population. Studieds association of ABO blood group polymorphism and disease prevalence in populations of India need to be established using molecular markers, such as nDNA, mtDNA etc. Which right clear the picture in the human biography of the Indian subcontinent

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