Nucleotide Polymorphism of Leptin Gene in Anatolian Water Buffaloes
Nucleotide Polymorphism of Leptin Gene in Anatolian Water Buffaloes
Selçuk Kaplan
Namik Kemal University, Faculty of Veterinary Medicine, Department of Genetics, Tekirdag, 59100, Turkey
ABSTRACT
Marker assisted selection (MAS) have been using to determine the associations between the genes and economic traits of livestock animals. However, phenotypic values do not generally indicate the real genotypic values of animals. However, using MAS approaches in selection of animals can increase the accuracy of selection. From this point of view, validation of candidate gene markers for marker assisted selection is very important to increase genetic gains in breeding. Leptin is a 16 kDa protein which is highly expressed in adipose tissue. Leptin is one of the most significant candidate gene marker for MAS studies. Therefore, bubaline leptin gene exon 2, part of the intron 1 and intron 2 region were amplified and sequenced to identify nucleotide variations in Anatolian water buffaloes. Sequence analysis were revealed seven polymorphic site (G1072A, T1081C, T1131G, T1143C, T1145G, T1151G and C1221T) and one monomorphic site (C1071T) in Anatolian water buffaloes. To the best of my knowledge, this is the first study that fully describes seven polymorphic sites of bubaline leptin gene in Anatolian water buffaloes.
Article Information
Received 26 February 2018
Revised 29 March 2018
Accepted 04 May 2018
Available online 07 August 2018
Key words
Leptin, Anatolian water buffaloes, Adipose tissue, Feed ıntake, Marker assisted selection.
DOI: http://dx.doi.org/10.17582/journal.pjz/2018.50.5.1841.1846
* Corresponding author: [email protected]
0030-9923/2018/0005-1841 $ 9.00/0
Copyright 2018 Zoological Society of Pakistan
Introductıon
Marker assisted selection (MAS) have been widely used to identify the relationships between the genes and economic traits of livestock animals. It’s well known that phenotypic values not generally represent the real genotypic values of animals. Therefore, using MAS approaches in selection of animals can increase the accuracy of selection. From this point of view, validation of candidate gene markers for marker assisted selection is very important to increase genetic gains in breeding. Owing to have key biological features, leptin is one of the most significant candidate gene marker for MAS studies (Friedman and Halaas, 1998; Aytekin and Boztepe, 2013; Hristov et al., 2012, 2013; Kök et al., 2017).
Leptin is a 16 kDa protein which is highly expressed in adipose tissue (Frühbeck, 2001). However, Leptin is also expressed in pituitary gland, brain and mammary gland (Morash et al., 1999; Sayed-Ahmed et al., 2003). Leptin plays pivotal role in regulating feed intake and down regulating the adipose tissue storage. Moreover, leptin has also related to appetite, energy balance (Giblin et al., 2010), fertility and immune system (Orrù et al., 2012).
The obesity gene (leptin) first clonned and discovered in 1994 (Zhang et al., 1994). Leptin gene has three exons and two introns and located on chromosome 4 in cattle. (Javanmard et al., 2008). Buffalo leptin gene had three exons and two introns (GenBank: AH013754.2) and mapped on chromosome 8 (BBU8q32) and consist of 5872 bp (Vallinoto et al., 2004).
Leptin gene shows 67% sequence similarity between cow, rat, human, rhesus monkey, orangutan, pig, mouse, dog and chimpanzee species (Zhang et al., 1997).
The buffaloes are mostly found in the South and South East Asia of the world. They are usually grown under extreme conditions. They can benefit from low quality roughage in swamp and reed areas (Kelgokmen and Unal, 2015).Turkey’s buffalo population (Anatolian water buffaloes) are belongs to the Mediterranean type buffaloes. Anatolian water buffaloes have distributed in Thrace, Black Sea and North of Middle Anatolia region. They can be found Afyon, Kars, Sivas, Muş, Hatayand Diyarbakir province of Turkey (Borghese and Mazzi, 2005). Anatolian water buffalo is generally reared for draught power, milk and meat yield in Turkey (Soysal et al., 2007).
Cattle and buffalo species have important contributions to world agricultural economy with their products. However, cattle is one of the most studied livestock animals in genetic researches. Previous studies have identified many significant associations between genetic markers and economically important traits in dairy and beef cattle (Buchanan et al., 2003; Schenkel et al., 2006). Until today, there were many studies reported strong sequence homology with buffalo and cattle (Kumar et al., 2004; Mahfouz, 2007; de Camargo et al., 2015). Moreover, previous study was also revealed that bubaline leptin gene has strong sequence similarity (97%) with bovine leptin gene (Datta et al., 2012). Therefore, this study was aimed to identify leptin gene nucleotide variations in Anatolian water buffaloes.
Materials and Methods
Sample collection and DNA purification
A total of 54 Anatolian water buffalo muscle tissue samples were collected after slaughtering and stored at -20°C in a deep freezer as far as molecular genetic studies are performed. The genomic DNA was isolated within the muscle tissue using the GeneMatrix tissue DNA purification kit (Eurx, E3551) as the manufacturer’s instructions. The control of isolated DNA was checked in agarose gel electrophoresis.
DNA amplification and sequencing
The primer pair (Lep forward, GGCTTACTGCTGTGTGGTCT and rreverse, AATGGCCACGGTTCTACCTC) amplifying the 461 bp DNA fragment (containing the exon 2 and part of the intron 1 and intron 2) was designed using the Primer 3 (NCBI) program (accession AY495587). (C1071T), (G1072A), (T1081C), (T1131G), (T1143C), (T1145G), (T1151G) and (C1221T) SNPs were determined in lactoferrin gene intron 1 and exon 2, respectively. PCR amplifications were performed with the PCR master mix (Thermo, K0171) in accordance with the manufacturer’s instructions. The PCRs were carried out in volumes of 25 µl using; 12,5 µl Pcr Master Mix, 50 ng (5 µl) genomic DNA, 1 µl (5 pmol) each primer, and the rest was ddH2O. The amplification was performed at 95°C for 3 min, followed by 35 cycles at 95°C for 30 sec, annealing at 66 for 30 sec, 72°C for 45 sec and a final extension of 72°C for 10 min on T100 Thermal Cycler (Biorad). The PCR products were subjected to electrophoresis on 2 % agarose/ethidium bromide gel (Aga003R, Bioshop, Canada) in 1× TAE buffer (TAE-001, New Bioscience). Gels were visualized under UV light and documented in WGD30S Molecular Imager apparatus (Wisd) (Fig. 1). After the purification and quality analysis; PCR products were sequenced by automated fluorescent sequencing using Quick Start Kit (Beckman Coulter, RN608120) and GenomeLab GeXP DNA analyzer (Beckman Coulter).
Statistical analysis
In this study, the Chi-square test whether genotype frequencies of all polymorphism were in Hardy Weinberg equilibrium estimated by PopGene Version 1.32 (Yeh et al., 1999).
Results and dıscussıon
In this study, the genetic analysis were performed to identify the polymorphic sites of (C1071T), (G1072A), (T1081C), (T1131G), (T1143C), (T1145G), (T1151G) and (C1221T) (GenBank) of (containing the exon 2, part of the intron 1 and intron 2) bubaline leptin gene in Anatolian water buffaloes. Therefore, the 461 bp DNA fragment (containing the exon 2, part of the intron 1 and intron 2) of bubaline leptin gene in Anatolian water buffaloes were sequenced. And sequence data of this study were analysed by BioEdit Sequence Alignment Editor (Hall, 1999). As a result, the sequence analysis were revealed seven polymorphic site (G1072A, T1081C, T1131G, T1143C, T1145G, T1151G and (C1221T) and one monomorphic site (C1071T) in Anatolian water buffaloes. Statistical analysis showed that T1143C polymorphic locus was in agreement with Hardy Weinberg equilibrium (P<0.05). However, G1072A, T1081C, T1131G, T1145G, T1151G and C1221T polymorphic locus were not in agreement with Hardy Weinberg equilibrium (P<0.05). Basic statistics of bubaline leptin gene in Anatolian water buffaloes are given in Table I. The PCR product of bubaline leptin gene (461 bp) on agarose gel electrophoresis and sequence analysis of (T1131G) are given in Figures 1 and 2, respectively.
In the current study, apart from the Murrah (Datta et al., 2012), Italian and Egyptian Buffaloes (Orrù et al., 2007) the polymorphic site of (C1071T) was found monomorphic in Anatolian water buffaloes. Orrù et al. (2007) have investigated the SNPs of bubaline leptin gene exon 2, exon 3 and part of the intron 1 in Italian and Egyptian Buffaloes. They have identified twelve single nucleotide polymorphisms (G3333A, C1221T, G3195A, C1221T, G3434A, T1015C, C1071T, G1072A, T1081C, T1131G, T1143C, T1145G) in Italian and Egyptian Buffaloes. G3318A polymorphism was found monomorphic in Italian Buffaloes while G3441A polymorphism was reported monomorphic for Italian and Egyptian Buffaloes. Datta et al. (2012) have reported five synonymous SNPs (G983A, C1083T, T1147G, A1152G, T1371C) in leptin exon 2 and intron 1 for cattle and Murrah buffaloes. In another study, five SNPs of leptin intron 1 region (98, 111, 172, 209. 266) have been identified in Mehsana buffalo (Tanpure et al., 2012). Scatà et al. (2012) have performed sequence analysis of bubaline leptin gene exon 1 and 5’ flanking region. They found eight SNPs (A83G, A90G, A121G, G256T, A283G, G959T, A1010C, G1254A) in Mediterranean Italian water buffaloes. Jhala et al. (2009) studied bubaline leptin gene exon 3 region in Mehsana buffalo. Three SNPs the positions at 42, 44, 250 have been found in this study. Vallinoto et al. (2004) studied to identify leptin polymorphism in swamp and river buffalo. They determined two SNPs (276 and 384) bubaline leptin gene exon 3 and one SNP the nucleotide position 137(G/A) in the promoter region. Although, there have been limited scientific reports about the bubaline leptin gene. In contrast, many scientific reports about the associations of leptin gene with economically important traits such as milk yield (Banos et al., 2008), meat quality traits (Schenkel et al., 2005), carcass traits (Buchanan et al., 2002), fertility (Liefers et al., 2002), feed intake (Lagonigro et al., 2003), protein yield and energy balance (Liefers et al., 2005) and body weight (Lusk, 2007) have been reported in dairy and beef cattle.
Table I.- Basic statistics of bubaline leptin gene in Anatolian water buffaloes.
Loci |
Allele frequencies |
Heterozygosity |
Chi-square |
||
Observed |
Expected |
||||
G1072A |
0.777 (G) |
0.222 (A) |
0.8889 |
0.6511 |
25.998775S |
T1081C |
0.722 (T) |
0.277 (C) |
0.9259 |
0.5950 |
37.080627 S |
T1131G |
0.509 (T) |
0.490 (G) |
0.9444 |
0.4955 |
43.569257 S |
T1143C |
0.981 (T) |
0.018 (C) |
0.9630 |
0.9633 |
0.009524 NS |
T1145G |
0.203 (T) |
0.796 (G) |
0.9259 |
0.6726 |
33.635561 S |
T1151G |
0.111 (T) |
0.888 (G) |
1.0000 |
0.8006 |
58.426794 S |
C1221T |
0.907 (C) |
0.092 (T) |
0.9259 |
0.8304 |
18.876162 S |
C1071T |
Locus monomorphic in Anatolian water buffaloes |
1 χ 20.05;1 ; 3,84 test of Hardy-Weingberg equlibrium; S, deviation from Hardy-Weinberg equlibrium is significant; NS, deviation from Hardy-Weinberg equlibrium is not significant.
Conclusıon
With advances in molecular genetics in recent years, have providing valuable contributions to improve the efficiency of livestock animals. It is well known that buffalo is high efficient animal that can convert poor quality roughage to milk and meat products. Furthermore, buffalo breeds have high resistance to diseases compared to other livestock animals. To beter understanding the genetic basis of economically important traits and resistance to diseases, it is required to increase genetic researches in buffalo breeds. Leptin is well studied significant genetic marker due to having key biological features in all the species. Therefore, the primary aim of this study was screen nucleotide variations of leptin gene in Anatolian water buffaloes. In summary, this study provided a new report about the findings of seven polymorphic site of leptin gene in Anatolian water buffaloes. And these findings have providing valuable informations for further association studies about the economically important traits of livestock animals.
Acknowledgements
I gratefully acknowledge to Cekmece meat and meat products company for providing tissue samples.
Statement of conflict of ınterest
The author declare that there is no conflict of interests regarding the publication of this article.
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