Polymorphism of SYNE2 Gene and its Association with Litter Size in Small Tail Han Sheep

1Key Laboratory of Animal Genetics and Breeding and Reproduction of Ministry of Agriculture and Rural Affairs, Institute of Animal Science, Chinese Academy of Agricultural Sciences, Beijing 100193, China 2College of Animal Science and Technology, Henan University of Science and Technology, Luoyang, Henan 471003, China 3Institute of Animal Husbandry and Veterinary Medicine, Anhui Academy of Agricultural Sciences, Hefei 230031, China Article Information Received 15 August 2019 Revised 22 September 2019 Accepted 01 October 2019 Available online 25 June 2020


INTRODUCTION
L itter size plays a vital role in the livestock economy (Rothschild et al., 1996). The litter size in sheep is a complex trait that is influenced by many factors, such as genetic background (Chu et al., 2007), nutritional level (Mellor, 1983), and feeding management. The genetic experience principally includes the number of ovulation (Chu et al., 2007), fertilization efficiency (Edwards et al., 2016), and estrus (Sánchez-Dávila et al., 2015). Among them, the ovulation is particularly important, which can affect the number of lambs per year in the sheep. Identification of the candidate genes that are responsible for variation in continuous traits or quantitative traits has been a challenge in modern genetics. So far, there have been some studies of a candidate gene, such as FecB, BMP15, and GDF9 on reproductive traits in sheep, which revealed that candidate gene plays an important role in sheep reproduction. The FecB gene is crucial in the regulation of prolificacy phenotype in sheep (Mulsant et al., 2001).
Nuclear envelope spectrin repeat proteins (Nesprins) are the latest identified members of the spectrin repeat (SR)-containing protein family (Zhou et al., 2018a). Nesprin-1/2 giant isoforms localize at the outer nuclear membrane and form the L Inker of Nucleoskeleton-and-Cytoskeleton (LINC) complex via associations between their KASH domains and the SUN domains of SUN1/2 in the perinuclear space (Sosa et al., 2012;Sosa et al., 2013). The LINC complex tethers the nuclear envelope to cytoskeletal elements, including actin filaments and the microtubule network (Gimpel et al., 2017;Wilson and Holzbaur, 2015). This molecular linking network is pivotal in regulating nuclear integrity, maintaining nuclear-cytoskeleton coupling, and participating in mechanotransduction, nuclear migration and positioning uniquely in muscle cell differentiation (Mellad et al., 2011;Stroud et al., 2014;Zhou et al., 2018a). Previous studies O n l i n e

F i r s t A r t i c l e
have suggested that Nesprin-2 regulates the Wnt/β-catenin signaling pathway (Sascha et al., 2010;Zhang et al., 2016). Several reports have shown that the Wnt/β-catenin pathway plays an essential role in follicular development, granulosa cell growth, and oocyte maturation (Gustin et al., 2016). Most studies on the SYNE2 gene have focused on diseases in the human (Baumann et al., 2017;Marina et al., 2015) and the mouse (Zhou et al., 2018a). However, few studies have investigated the effect of the SYNE2 gene on litter size in sheep. Therefore, the objectives of the present research were to detect SNPs associated with the litter size in small tail han (STH) sheep and identify a genetic marker conceivably valuable for marker-assisted selection.

MATERIALS AND METHODS
All the experimental procedures mentioned in the present study were approved by the Science Research Department (in charge of animal welfare issue) of the Institute of Animal Sciences, Chinese Academy of Agricultural Sciences (IAS-CAAS) (Beijing, China). Ethical approval on animal survival was given by the animal ethics committee of IAS-CAAS (No. IASCAAS-AE-03, 12 December 2016).
Animals selection, blood sampling, and DNA extraction As detailed in Table I, 726 ewes from six sheep breeds were selected for genotyping. Jugular vein blood samples (10 mL blood per ewe) were collected using citrate glucose as an anticoagulant. Genomic DNA was extracted by the phenol-chloroform method (Deininger, 1983), dissolved in ddH 2 O and stored at -20℃.

Primer design and genotyping
Four pairs of primers were designed according to the ovine SYNE2 sequence from Ensemble (ENSOART00000023042.1). Primer sequence, product size and annealing temperature are presented in Table II. All primers were synthesized by Beijing Tianyihuiyuan Biotechnology Co. Ltd. (Beijing, P.R. China). PCR was carried out in 50 μL volume containing 25 μL of 2×GC Buffer Ⅰ, 8 μL of 2.5 mmol/L each dNTP, 0.5 μL of 5 U/μL TaKaRa LA Taq, 2 μL of 40 ng/μL genomic DNA, and 1 μL of 10 μmol/L each primer, the rest was ddH 2 O. Amplification conditions were as follows: initial denaturation at 95℃ for 5 min; followed by 34 cycles of denaturation at 95℃ for 30 s, annealing for 30 s, extension at 72℃ for 1 min with a final extension at 72℃ for 5 min.
All of the PCR products were sent to Sangon Biotech Co, Ltd. (Shanghai, China). The sequencer software Chromas Pro 2 was used to identify SNPs. Genotyping of SYNE2 SNPs by Sequenom MassARRAY ® SNP as described by Zhou (Zhou et al., 2018b). Genotyping primer sequence and product size are presented in Table II.

Statistical analysis
Allelic frequencies, heterozygosity (He), polymorphism information content (PIC) and the Hardy-Weinberg equilibrium tests were calculated using Pop gene (version 1.31). Linkage disequilibrium was analyzed using Haploview. Statistical analysis was performed by univariate analysis in a General Linear Model procedure of SAS (V. 8.1) (SAS Institute Inc., Cary, NC, USA). Multiple comparisons of means were performed using the least significant difference method. The applied model was expressed as follows: y ijn =μ+ P i + G j + I PG + e ijn , where y ijn is the phenotypic value of litter size; μ is the population mean; P i is the fixed effect of the ith parity (i = 1, 2, 3); G j is the fixed effect of the jth genotype (j=1, 2, 3); I PG is the interaction effect of parity and genotype; and e ijn is the random residual.

Polymorphisms of the coding region of the SYNE2 gene
In this study, sequencing of the amplicons of different primer pairs identified four polymorphic nucleotide sites in sheep SYNE2 gene. The g.73310578G>A mutation was in the 112 exons and the g.73312892G>A, g.73312791A>G and g.73314606G>A mutations were in the 114 exons ( Fig. 1). Four SNPs (g.73310578G>A, g.73312892G>A, g.73312791A>G and g.73314606G>A) were genotyped in STH sheep ( Fig. 2). At g.73312892G>A locus, the PIC was 0.07 in STH ( Fig. 2). At g.73310578G>A, g.73314606G>A and g.73312791A>G locus, the PIC was 0.18~0.30 in STH. Genotypic distribution and allelic frequencies of four SNPs are shown in Figure 2. It was shown that STH sheep were in Hardy-Weinberg equilibrium at four-locus (p > 0.05) (Fig. 2). To reveal the linkage relationships between the four SNPs, the linkage disequilibrium was estimated at in STH sheep (Fig. 3). If r 2 > 0.33 and D' > 0.5 the linkage disequilibrium was considered strong (Ardlie et al., 2002). Following the result, both g.73310578G>A and g.73312791A>G loci were closely linked in STH sheep.

Population genetic analysis of polymorphism in the SYNE2 gene
Besides STH sheep (Fig. 2), population genetic characteristics of four SNPs in the other five sheep breeds were also analyzed, the results were listed in Table III. It revealed that the g.73314606G>A and g.73312791A>G loci were moderately polymorphic (0.25 <PIC<0.5) in the Sunite sheep and Hu sheep, respectively.   Table IV.

Association analysis of SNPs with litter size
At the g.73312892G>A locus in the STH sheep, individuals with the GG genotype higher litter size than did those with AA genotypes in each parity (Table V). However, it did not reach a significant level (P > 0.05). At other loci, no significant differences in each parity litter size between different genotypes were found. The results of association analysis of the combined genotypes showed O n l i n e

O n l i n e F i r s t A r t i c l e
Polymorphism of SYNE2 Gene and its Association 5   Note: Different small letters in the same group mean a significant difference (p < 0.05).
that individuals in the STH sheep with the AA/AG genotype had larger litter sizes than did those with AA/ GG, GA/AG and GG/AA genotypes in the second and third parity (P < 0.05; Table VI).

DISCUSSION
Several reports have shown that nesprins (nuclear envelope spectrin repeat proteins) are the latest identified members of the spectrin repeat (SR)-containing protein family (Zhang et al., 2001) for different KASH domain-containing proteins named as nesprins-1, -2, -3, -4, lymphoid-restricted membrane protein (LRMP) and KASH5 have been identified in mammals (Zhou et al., 2018a). Nesprins play pivotal roles in the maintenance of NE integrity (Luke et al., 2008), nuclear positioning (Zhang et al., 2007) and anchorage to the cytoskeleton and the centrosome (Roux et al., 2009). Previous studies have suggested that Nesprin-2 regulates the Wnt/β-catenin signaling pathway (Sascha et al., 2010;Zhang et al., 2016). Several reports have shown that the Wnt/β-catenin pathway plays an important role in follicular development, granulosa cell growth and oocyte maturation (Gustin et al., 2016). WNT families consist of local-acting glycoproteins. They can regulate a wide range of biological processes, which include cell fate determination, proliferation, differentiation, apoptosis and embryogenesis (Fan et al., 2010). Therefore, we want to know that the SYNE2 gene is related to sheep reproduction or not and then detect SNPs of the SYNE2 gene in STH sheep and identify a genetic marker conceivably valuable for marker-assisted selection (MAS). In this study, a total of four SNPs were identified and that SNPs were identified as that involved in amino acid change all SNPs were in Hardy-Weinberg disequilibrium in six sheep (P>0.05). Previous studies have demonstrated that Ne and PIC are important genetic parameters that indicate the level of intra-population genetic variation (Botstein et al., 1980). The results of the present study show that the g.73314606G>A and g.73312791A>G loci were moderately polymorphic (0.25<PIC<0.5) in the Sunite sheep and Hu sheep, respectively. These results indicated that the g.73314606G>A and g.73312791A>G loci have a higher level of intra-population genetic variation. The results of this study show that we found g.73312892G>A, g.73310578G>A, g.73312791A>G, g.73314606G>A are all missense mutations. There are many studies that missense mutations change sheep reproductive traits, such as FecB, BMP15, and GDF9 (Chong et al., 2018;Zhou et al., 2018b). Several studies indicated that ewes carrying FecB-mutation have significantly higher ovulation rates if compared with their wild-type contemporaries (Mulsant et al., 2001;Qiuyue et al., 2015). Six mutations (FecX I , FecX H , FecX G , FecX B , FecX L , FecX R ) of bone morphogenetic protein 15 (BMP15) can increase ovulation rate in heterozygotes and cause complete sterility in homozygotes. However, homozygous ewes with mutations (FecX Gr , FecX O ) of BMP15 had increased ovulation rate without causing sterility (Qiuyue et al., 2015). Five mutations (FecG H , FecG T , FecG E , FecG F , FecG V ) in growth differentiation factor 9 (GDF9) associated with sheep prolificacy where FecG E and FecG F have additive an effect on ovulation rate and litter size (Qiuyue et al., 2015). When amino acid changes, the spatial structure of the protein changes, but its function may not change. The association analysis has shown that the four SNPs have no significant differences in each parity litter size between different genotypes. Further research is required to verify the mechanism of the impact of the SNPs on the parity litter size in STH sheep. Reproductive traits are complex quantitative traits involving multiple genes, loci and their interactions. Therefore, the combined effects of multiple genes or loci on reproductive traits should be analyzed. Association analysis revealed that mutations at g.73310578G>A and g.73312791A>G had a significant impact on litter size in STH sheep, which is consistent with the linkage disequilibrium result. The interesting finding was that of association analysis of the combined genotypes showed that individuals in the STH sheep with the AA/AG genotype had larger litter sizes than did those with AA/GG, GA/AG and GG/AA genotypes in the second and third parity. This result may be explained by the fact that this mutation in linkage disequilibrium with other responsible mutations or this mutation may change some events of SYNE2 in term of the post-transcriptional regulation (Oerum et al., 2017;Zhang et al., 2019).

CONCLUSIONS
In Summary, the current study explored the genetic polymorphisms in the coding region of the SYNE2 gene, indicating that the AAAG haplotypes of SYNE2 gene g.73310578G>A and g.73312791A>G linkage loci could influence the third parity litter size in STH sheep. Therefore, it could be useful in the marker-assisted selection of the second and third parity litter size in STH sheep.