1. Introduction
Iris colour as a multifactorial hereditary trait varies depending on the race and ethnicity of people. Pigmentation of the eye is due to a polymer known as melanin, consisting of Eumelanin and Pheomelanin controlling normal pigmentation. Eumelanin is present in a black-brownish colour that is present in dark hairs, eyes and skin. Opposite to the Eumelanin, the Pheomelanin is yellow reddish in colour and found in light hairs, eyes and light skin colour [
1,
2,
3]. For eye pigmentation, the ratio of eumelanin and pheomelanin plays a key role. Eumelanin is the main pigment in most eye colours while pheomelanin is present only in traces. For example, the concentration of pheomelanin is the same in both blue and brown eyes [
4]. The exception is made to this in green eyes where a concentration of pheomelanin is higher as compared to eumelanin [
5]. Other than colour, other differentiating biochemical properties are present in eumelanin and pheomelanin. Eumelanin is photo protective and an antioxidant protecting against harmful UV rays. In contrast, pheomelanin is photo reactive and oxidative [
6]. To date, multiple studies have been conducted to develop a universal classification for eye colour. Initially, eye colours were classified into blue, grey, black and auburn categories by Pétrequin in 1843. Later on in 1854, the categories of blue eye colour were expanded into gray, green and blue, while brown eye colour categories are black shades, dark brown, hazel and auburn [
7]. A colour chart was developed in 1903 and consisted of 16 eye colours from dark brown (number 1) to light blue (number 16) [
8]. Later on, standardized computerizes colours were used against digital images [
9]. In 2008, a study proposed a 24-scale classification from 1 (least pigmentation) to 24 (most pigmentation), which is like to the previous Martin’s eyes [
10,
11]. Despite all of these, a new stem of eye colour classification is used and classified eye colour into blue, brown and intermediate based on eye colour photographed [
12]. Eye colour shows a varied global spread across the globe. It showed extreme variation ranging from brown, intermediate and blue. The percentage of eye colour for blue, intermediate and brown eye colour differs in different populations. The highest percentage of any colour is observed in Uzbekistan based on the available literature, where more than 90% of the population have brown-coloured eyes. In contrast, brown-coloured eyes are less prevalent in Iceland. Blue eye colour is prevalent in Iceland with nearly three-quarters (74.52%) of the population possessing blue-coloured eyes while the lowest blue eye colour was reported in Iran (1%). Intermediate eye colour is less prevalent, with a maximum prevalence in the Spanish population (55.2%) and a minimum prevalence in Uzbekistan (6.02%) [
13]. Genome-wide association studies (GWAS) have revealed that different types of genes are involved in complex traits, such as externally visible characteristics (EVCs) in human beings [
14]. Eye and Hair pigmentation in humans is a polygenic trait involving different genes controlling the synthesis and localization of melanin [
10]. Strong associations of numerous SNPs have been found with differences in eye and hair colour [
10]. In 2014, the HIrisPlex system was released which is used as an EVC prediction tool. This model predicts three EVCs: hair, eye and skin colour. HIrisplex shares six SNPs with Irisplex, a previously developed interactive model [
15]. IrisPlex is an eye pigmentation prediction tool developed by the same research group that classifies an individual’s eye colour as being either blue, brown or intermediate based purely upon their DNA [
16]. This assay is fully compatible with Scientific Working Group on DNA Analysis Method (SWGDAM) guidelines, who governs forensic assays and validations [
15,
16].
Pakistan is the sixth-most populous nation in the world with a population of more than 212 million [
17]. Pakistan is connected to Central Asia, South Asia and West Asia, and there have been several instances of human migration to this region throughout recorded history. At present, the population of Pakistan is divided into 18 ethnic groups and more than 60 different languages have been reported [
18]. The Pakhtoons are the largest ethnic group in the Khyber Pakhtunkhwa province and the second largest ethnic group in Pakistan (15.4%) [
19]. For this large population, very limited documentation about forensically informative DNA markers is available so far. Therefore, it is needed to record the eye colour prevalence and also to check the validation of the Irsisplex system on the Pakhtoon population in the Malakand Division. The results of this study may prove beneficial for researchers in the field of population genetics, anthropology and forensic genetics.
4. Discussion
Eye colour shows a varied global spread across the globe showing extreme variation in the eye colour pigmentation ranging from blue to intermediate to brown [
23]. Higher frequencies of brown categories were reported in Azerbaijan, Armenia, Georgia, Kazakhistan, Tajikistan and Uzbekistan [
13,
24], Korea [
25] and Japan [
26]. In the current research, we report that people in the Malakand Division tend to have brown eyes as shown in
Figure 1. This study is comparable to the studies previously mentioned. This is in contrast to earlier studies that indicated that people with brown eyes make up a very small percentage of the population compared to people with other coloured irises in Iceland, Germany and Denmark [
13,
27,
28,
29]. The sampled individuals in the current research revealed that 12.8% had intermediate eye colour. Similar findings were reported previously, for example, in Iceland as 14.15%, in Kazakhstan as 11.65% and in Poland as 12.5% of intermediate eye-coloured individuals [
13,
23,
30]. Tajikistan has a ratio of 7.67% and Uzbekistan has a ratio of 6.02% for intermediate eye tone [
24]. In contrast, different intermediate colour frequencies are reported (44%) in France, (39.6%), in Germany (55.2%) and in the Spanish population [
12,
27]. Blue colours are more prevalent in people of Denmark (64.84%), Poland (52.50%) and Iceland (73.90%) [
28,
30]. Our study is different from the aforementioned studies but has similar results to those in the populations of Azerbaijan, Armenia, Georgia and Tajikistan [
13]. Different populations in European, East Asian, South Asian, African, and American populations displayed different eye colour ratios [
31,
32,
33,
34,
35], but in general, brown eyes were more prevalent in East Asia, North America, Oceania, Africa, and Sub-Saharan Africa than blue eyes in Northern Europe [
36,
37,
38]. Eye colour has been certainly connected with demographic features, such as sex and age. In the current study, brown eye colour is higher in females, while blue and intermediate is higher in males. When a multinomial regression test was applied, we also discovered a relationship between gender and eye colour. With blue eyes, males had a significant
p-value of (0.050) in
Table 1, but the remainder of the eye colours and gender did not. Similar findings were also found in the populations of Italy and Spain, where men tended to have intermediate and blue eyes while females tended to have brown eyes [
39,
40]. The same outcomes, though, could not be replicated in the populations of Sweden and Denmark [
41]. Consequently, the current and previous results showed that eye colour and sex association are mainly restricted to some specific populations. This significant association confirms that there must be an unknown factor that controls human eye colour variation. A further study is required in order to elucidate the influence of gender on eye colour variation in humans.
A consistent age category has not yet been given, and various researchers have used different categories to classify eye colour [
25,
26,
42,
43,
44,
45,
46,
47]. In the current study, it was reported that the prevalence of eye colour is based on age groups, and brown eye colour is higher throughout the entire study. Some findings were comparable; with a predominance of brown eyes in different age groups, i.e., Ref. [
25] revealed that the majority of people in Korea between the ages of 13 and 80 had brown eyes. A study on Japanese people discovered that the population of Japan has a greater percentage of brown eyes [
26]. A research team working on two separate studies, one on a population older than one year and the other on a population older than seven, discovered that brown eyes are most common [
46,
47]. Some of the results were in contrast to our research [
44], which examined 52–93-year old European Australians and discovered that blue/grey eyes are frequently seen. Another research study conducted in Northeast Europe on 12-year-olds and Americans aged 43 to 86 [
42], Australians over the age of 49 [
43], and Americans aged 60 to 69 [
33] revealed that people with blue eyes were more common [
33]. Even with the importance of eye colour in age groups, very few studies are available; only one study is significant with brown eye colour in the age groups 31–40 and 60–to above with blue eye colour [
47]. Our finding is a contrast where no significance was found between age groups and eye colour in
Table 2. The difference between our study and previous ones may be due to age category selection or may be due to ethnic and environmental factors.
In the current study, we found different percentages of the genotypes in specific SNPs when compared worldwide [
21,
29]. Genotyped of the three SNPs, rs12896399, rs12913832 and rs16891982 have an unevenly inverse genotypes ratio in Northern European when matched with Spain.
Developing a better understanding of eye colour will contribute greatly to the fields of forensics, anthropology and public health. At present, many forensic groups developed pigmentation predictor tools. The primary purpose of these tools is to allow crime scene investigators to predict the eye colour of unidentified individuals from small samples of their DNA. Irisplex and FROG-Kb are perhaps the most well known of these tools. A previous study in an Italian population has shown 76% accuracy of the Irisplex system [
48]. A similar study found 95%, 58% and 11% accuracy on the Irisplex system for the prediction of blue, brown and intermediate eye colour, respectively [
49]. In the study, 89% accuracy for blue eye colour and 94% for brown eye colour was found [
50]. In contrast, the present study reports a 100% accurate prediction for blue and brown eye colour while minority intermediate eye colour phenotypes are misclassified with 23.08% predicted as blue and 76.92% predicted as brown. Intermediate dark phenotypes were mostly predicted as brown, and a light eye-coloured individual was predicted as blue. Moreover, none of the individuals were unclassified. Issues in predicting intermediate eyes have already been shown in previous studies [
15,
16,
18,
20,
33,
51,
52,
53,
54,
55,
56,
57,
58,
59].
In the current study, we also compared the two models, FROG-kb and HIrisplex, and the same results were obtained. Through FROG-kb, brown eye colour was predicted 100% accurately, similar to the studies [
15,
16].
Overall, we used phenotype SNPs to obtain eye colour predictions. The comparison of the three prediction systems revealed that IrisPlex and FROG-Kb same higher prediction ratios for blue and brown eye colour. Our results suggest that iris colour SNPs should be analysed for the population in which the system IrisPlex is going to be implemented. Our results also show that the district Swat was significantly associated
p-value = (0.050) with brown eye colour, blue
p-value = (0.012), while district Buner was significant with brown
p-value = (0.026), intermediate
p-value = (0.015) while the rest of districts (Shangla, Malakand, U. Dir, Chitral and L. Dir) were non-significant
Table 5. A case-wise study was performed in Himachal Pradesh, Kangra, where the intermediate eye ratio is higher in a few generations at the temperate climate from Uttar Pradesh, Gorakhpur, Bihar and Darbhanga which are humid subtropical regions. Thus, climate might have a role in eye pigmentation due to the differential expression of the genes responsible for eye colour [
60]. Hence, the exact molecular mechanisms needed to be unearthed.
In the present study, the association of the (rs12913832) SNP in HERC2 gene with eye colours in the Pakhtoon Population of the Malakand Division was investigated. The results were similar to some earlier studies [
24,
29,
51,
61]. The SNP rs1800407 does not show a significant correlation. However, this SNP rs1800407 was previously found significant with eye colour [
50,
52]. The significant association of rs12896399 SNP was found with eye colour determination [
30,
50,
54] but, in the present study, this SNP has non-significant. The significance of rs16891982 SNP in eye colour prediction is lower in Northern Europe and higher in Southern Europe populations [
30]. The present finding also elucidated the higher significance of this SNP in eye colour prediction. In the present study, a significant association of rs1393350 SNP was found with eye colour, while [
30] showed a non-significant association of SNPs rs1393350 with eye colour. The weak association of this rs12203592 SNPs was found with eye colour [
55,
61,
62]. While from the study [
39], rs12203592 was strongly associated with eye colour. While in the current study, rs12203592 SNP was excluded from the analysis as it was not polymorphic in our study population.
Khyber Pakhtunkhwa (KPK) formerly called North-West Frontier Province is located in the northwest of Pakistan and has an estimated 13.4% of the total population of Pakistan in which Pakhtuns are the major ethnic group [
61]. Furthermore, we examined the effect of the six DNA variants included in the IrisPlex system on their potent ability to infer biogeographic ancestry. It had been advocated before those SNPs from pigmentation genes are useful for genetic ancestry detection [
62].
Figure 4 showed a two-dimensional plot of a non-metric multidimensional scaling (MDS) analysis of pairwise FST values and the findings showed that, based on eye colour, the Pakhtoon population of the Malakand Division is unique from other populations around the world. The MDS matrix put the Pakhtoon population at a near distance to the Pathan population and next to the Palastin, Burusho, Orcadian, Balochi and Adygei populations The MDS matrix compared the Pakhtoon population to the Pathan population and found some differences between with populations of Palastin, Burusho, Orcadian, Balochi, and Adygei., while the rest of world’s populations are more different from the Pakhtoon population. However, previous studies based on different molecular markers showed different results. Most of the historians believe that Pakhtoon is the offspring of Jews, and some novelists from Europe believe that Pakhtoon are Caucasian ethnic group that originated from Armenians, some authors also believe that Pakhtoon basically belong to Arians [
63]. Other researchers found Cultural and ethnic similarities between Pakhtoon and Jews [
4,
61]. From an earlier study, molecular ancestors confirmed minor contributions to the Pakhtoon DNA from Arab, Greek, Iranian and Turkish people [
64]. The Pakhtoon’s ancestry with different ethnic groups (ethnic groups from Afghanistan, Pakistan and neighbouring countries) were investigated using Y STR loci, and it was confirmed that they have no ties to Israel or the Jewish people [
65]. We concluded that the genetic background for iris colour in the Pakhtoon population living in Malakand Division is genetically different from that of other populations of the world. Our results highlight the importance of studying the variation of these genes and their association with iris colour, not only in this population but among the world’s population for identification of people based on iris colour.