Nucleotide sequencing and DNA polymorphism studies of BMP 15 gene in Corriedale and local Kashmir valley sheep (Ovis aries)

The families of TGF-β proteins are the most important growth factors in the ovary for growth and differentiation of early ovarian follicles. Three related oocyte-derived members of the transforming growth factor-β superfamily, namely GDF9, BMP15 and BMPR-IB have been shown to be essential for follicular growth and ovulation. The objective of the present study was to detect the incidence of mutation in intronic portion of BMP 15 gene in Corriedale and local Kashmir valley sheep breeds. Blood samples were collected from 85 ewes and genomic DNA was extracted using the modified phenol chloroform method. The quantity and quality of extracted DNA was examined using spectrophotometry and gel electrophoresis, respectively. A fragment with the size of 356 bp was amplified using polymerase chain reaction (PCR) with a pair of specific primers. The amplified PCR products were digested with Mph11031 restriction enzyme. In the presence of mutation at this locus, the Mph11031 enzyme cannot recognize the restriction site. However, here in the absence of mutations, the enzyme recognizes one restriction site and divides the amplified fragment into two fragments of 152 and 204 bp. The 356 bp fragment was also analyzed for polymorphism by SSCP technique. The results indicated two different banding patterns AA and AB for this fragment. Later on two different allelic forms A and B were confirmed by nucleotide sequencing. The 356 bp nucleotide sequence was subjected to alignment analysis and it was observed that sequence similarity of this fragment with that of other sheep and Jining grey goat was more than 97.8%. Phylogenetic analysis revealed that both designated A and B alleles as well as published sequence of sheep form a common cluster indicating their evolutionary closeness. The origin of Jining grey goat was located some distance away from the sheep. The overall frequencies of AA and AB genotypes were 0.79 and 0.21. The breed wise frequencies were 0.78 and 0.22 in Corriedale sheep and the frequencies in Kashmir valley sheep were 0.80 and 0.20 for AA and AB genotypes, respectively. The overall allelic frequencies of A and B alleles were 0.89 and 0.11 whereas allelic frequencies Corriedale sheep was 0.89 and 0.11 and that of Kashmir valley sheep were 0.90 and 0.10.     

Association between PCR-SSCP of growth differentiation factor 9 gene and high prolificacy in Small Tail Han sheep

Small Tail Han sheep that has significant characteristics of high prolificacy and nonseasonal ovulatory activity is an excellent local sheep breed in P.R. China. The lambing percentage averaged 260% in Small Tail Han sheep. Growth differentiation factor 9 (GDF9) gene, which was essential for growth and differentiation of early ovarian follicles, was considered as a possible candidate gene for litter size in Small Tail Han sheep. The genetic polymorphism of a part of the GDF9 gene was detected in 130 ewes of Small Tail Han sheep by PCR-SSCP. The results indicated that there were two genotypes (AA and AB) detected by two primer pairs. In both exon 1 and exon 2 of the GDF9 gene in Small Tail Han sheep, frequencies of AA genotype were 0.846 and 0.908, frequencies of AB genotype were 0.154 and 0.092, frequencies of A allele were 0.923 and 0.954, and frequencies of B allele were 0.077 and 0.046, respectively. The results of chi2 fitness test indicated that both exon 1 and exon 2 of the GDF9 gene were in Hardy-Weinberg equilibrium (p > 0.05) in Small Tail Han sheep. Least squares means of litter size in the first and the second parity for genotype AA were 0.30 (p <0.05) and 0.77 (p <0.0001) more than those for genotype AB detected in exon 1 of the GDF9 gene in Small Tail Han sheep, respectively. Fragments detected in exon 2 of the GDF9 gene had no significant effect (p > 0.05) on litter size in both the first and the second parity in Small Tail Han sheep. Litter size in sheep is lowly heritable, expressed only in females, and manifested relatively late in life. Access to genetic markers would thus be advantageous in selection programs.     

甘肃肉羊新品种选育群GDF9基因外显子2多态性及其与产羔性状关联分析

根据GenBank发布的绵羊GDF9基因外显子2的序列设计4对引物,采用PCR-SSCP技术分析GDF9基因外显子2在甘肃内羊新品种选育群羊中的单核苷酸多态性,并与产羔性状进行关联分析.结果表明,GDF9基因的扩增片段在所检测的新品种群羊中存在PCR-SSCP多态性,检测到3种基因型(AA、AB和BB),而在32只无角陶赛特母羊群中只检测到AA和AB基因型.测序结果显示,GDF9基因编码区第978位碱基发生A→G突变,但没有导致氨基酸的改变;第994位碱基发生G→A突变,导致Ⅴ变成Ⅰ(缬氨酸→异亮氨酸).新品种选育群羊产羔数的最小二乘均值关系为AB＞ AA＞ BB,统计分析结果初步表明3种基因型之间差异不显著(P＞0.05).故该区域可能不是影响新品种群羊繁殖力的功能结构区城.     

GDF9 as a candidate gene for prolificacy of Small Tail Han sheep

Growth differentiation factor 9 (GDF9) which controls the fecundity of Belclare, Cambridge, Santa Ines, Moghani, Ghezel and Thoka ewes was studied as a candidate gene for the prolificacy of Small Tail Han sheep. According to the sequence of ovine GDF9 gene, six pairs of primers were designed to detect single nucleotide polymorphisms of two exons of GDF9 gene in both high fecundity breed (Small Tail Han sheep) and low fecundity breed (Dorset sheep) by polymerase chain reaction-single strand conformation polymorphism (PCR-SSCP). Only the products amplified by primers 2-1 and 2-2 displayed polymorphisms. For primer 2-1, three genotypes (AA, AB and BB) were detected in both sheep breeds. Sequencing revealed one silent mutation (G477A) in exon 2 of GDF9 gene in the BB genotype in comparison with the AA, which was known as G3 mutation of GDF9 gene in Belclare and Cambridge ewes. The relationship of least squares means for litter size was AA?>?AB?>?BB in Small Tail Han sheep (P?>?0.05). For primer 2-2, two genotypes (CC and CD) were detected in both sheep breeds. Sequencing revealed one novel single nucleotide mutation (G729T) in exon 2 of GDF9 gene in the CD genotype in comparison with the CC, which resulted in an amino acid change (Gln243His). The ewes with mutation heterozygous genotype CD had 0.77 (P?相似文献   

Genotyping of Novel SNPs in BMPR1B,BMP15, and GDF9 Genes for Association with Prolificacy in Seven Indian Goat Breeds

Goats form the backbone of rural livelihood and financial security systems in India but their population is showing decreasing trend. Improvement of reproductive traits such as prolificacy offers a solution to stabilize the decreasing goat population and to meet the nutritional needs of growing human population. In the present study, six novel SNPs in three candidate genes for prolificacy (BMPR1B, BMP15, and GDF9) were genotyped in seven breeds of Indian goats to evaluate their association with litter size. Tetra primer ARMS-PCR and PCR-RFLP based protocols were developed for genotyping six novel SNPs, namely, T(-242)C in BMPR1B; G735A and C808G in BMP15; and C818T, A959C, and G1189A in GDF9 gene. The effect of breed was highly significant (p ≤ 0.01) on litter size but the effect of genotype was nonsignificant. The effect of parity on litter size was also significant in the prolific Black Bengal breed. The litter size differences observed between breeds are attributed to breed differences. Novel mutations observed at different loci in GDF9, BMP15, and BMPR1B genes do not contribute to the reproductive capability of the investigated breeds. Further studies with more number of breeds and animals exploring association of these novel SNPs with reproductive traits may be fruitful.     

Polymorphism of fecundity genes (BMPR1B, BMP15 and GDF9) in the Indian prolific Black Bengal goat

The Black Bengal is a prolific goat breed in India. Natural mutations in prolific sheep breeds have shown that the transforming growth factor beta (TGF-β) super family ligands such as growth differentiation factor 9 (GDF9), bone morphogenetic protein 15 (BMP15) and their type I receptor (bone morphogenetic protein receptor, BMPR1B) are crucial for ovulation and as well as for increasing litter size. Mutations in any of these genes increased prolificacy in sheep. Based on the known mutation information in sheep PCR primers were designed to screen known polymorphism in 88 random Black Bengal goats. Only the BMPR1B gene was polymorphic. Three genotypes of animals were detected in tested animals with mutant (FecB^B) and wild type (FecB⁺) alleles were 0.57 and 0.43, respectively. Non-carrier, heterozygous carrier and homozygous carrier Black Bengal does had 2.7, 3.04 and 3.11 kids, respectively. All known point mutations of BMP15 and GDF9 genes were monomorphic in the animals tested. These results preliminarily showed that the BMPR1B gene might be a major gene that influences prolificacy of Black Bengal goats.     

Polymorphism of 5′ regulatory region of ovine FSHR gene and its association with litter size in Small Tail Han sheep

Single nucleotide polymorphisms of 5?? regulatory region of follicle-stimulating hormone receptor (FSHR) gene were detected in two high prolificacy sheep breeds (Small Tail Han and Hu sheep) and two low prolificacy sheep breeds (Corriedale and Chinese Merino sheep) by polymerase chain reaction-single strand conformation polymorphism (PCR-SSCP). The results indicated that there were three genotypes (AA, AB and BB) detected by primer 1 in Hu sheep while only one genotype (AA) in other three sheep breeds, and frequencies of AA, AB and BB genotypes in Hu sheep were 0.700, 0.225 and 0.075, respectively. There were three genotypes (EE, EF and EG) detected by primer 3 in Small Tail Han sheep while only EE genotype occurred in other three sheep breeds, and frequencies of EE, EF and EG genotypes in Small Tail Han sheep were 0.775, 0.200 and 0.025, respectively. No polymorphism was detected in four sheep breeds by primer 2 and primer 4. The sequencing results showed that there were two nucleotide mutations (g. ?681T>C and g. ?629C>T) in genotype BB compared with AA for primer 1. As for primer 3, two mutations (g. ?197G>A and g. ?98T>C) in genotype EF compared with EE and two mutations (g. ?200G>A and g. ?197G>A) in genotype EG compared with EE. The heterozygous ewes with EG or EF had 0.89 (P?<?0.05) or 0.42 (P?<?0.05) lambs more than homozygous ewes (EE genotype) in Small Tail Han sheep, respectively, while there was no significant difference on litter size between EG and EF ewes.     

Association of BMPR-1B and GDF9 genes polymorphisms and secondary protein structure changes with reproduction traits in Mehraban ewes

BMPR-1B and GDF9 genes are well known due to their important effects on litter size and mechanisms controlling ovulation rate in sheep. In the present study, polymorphisms of BMPR-1B gene exon 8 and GDF9 gene exon 1 were detected by single strand conformational polymorphism (SSCP) analysis and DNA sequencing methods in 100 Mehraban ewes. The PCR reaction forced to amplify 140 and 380-bp fragments of BMPR-1B and GDF9 genes, respectively. Two single nucleotide polymorphisms (SNP_S) were identified in two different SSCP patterns of BMPR-1B gene (CC and CA genotypes) that deduced one amino acid exchange. Also, two SNP_S were identified in three different SSCP patterns of GDF9 gene (AA, AG and GG genotypes) that deduced one amino acid exchanges. Two different secondary structures of protein were predicted for BMPR-1B exon 8, but the secondary protein structures predicted for GDF9 exon 1 were similar together. The evaluation of the associations between the SSCP patterns and the protein structure changes with reproduction traits showed that BMPR-1B exon 8 genotypes have significant effects on some of reproduction traits but the GDF9 genotypes did not have any significant effect. The CA genotype of BMPR-1B exon 8 had a significant positive effect on reproduction performance and could be considered as an important and new mutation, affecting the ewes reproduction performance. Marker assisted selection using BMPR-IB gene could be noticed to improve the reproduction traits in Mehraban sheep.     

Polymorphism identification in goat GNRH1 and GDF9 genes and their association analysis with litter size

This study investigated the polymorphisms of GNRH1 and GDF9 genes in 641 goats of three breeds: Xinong Saanen, Guanzhong and Boer. Two allelic variants were identified in the GNRH1 gene (JN645280:g.3548A>G and JN645281:g.3699G>A) and one allelic variant was found in the GDF9 gene (JN655693:g.4093G>A). Furthermore, g.4093G>A was a missense mutation (p.Val397Ile of GDF9). Results of an association analysis indicated that SNPs g.3548A>G and g.4093G>A had significant effects on litter size (P < 0.05). The combination genotypes of SNPs g.3548A>G, g.3699G>A and g.4093G>A also affected litter size with the C₅ genotype having the highest litter size in the first, third, fourth and average parity. Hence, the biochemical and physiological functions, together with the results obtained in our investigation, suggest that the GNRH1 and GDF9 genes could serve as genetic markers for litter size in goat breeding.     

Prolificacy genotypes at BMPR 1B,BMP15 and GDF9 genes in North African sheep breeds

The aim of this research was to investigate the genetic structure at BMPR 1B, BMP15 and GDF9 prolificacy genes in five sheep breeds reared in Tunisia: Barbarine, Queue Fine de L’Ouest, Noire de Thibar, Sicilo-Sarde and D’man. Genomic DNA of 204 sheep was investigated for the FecB^B (BMPR 1B), FecX^R, FecX^H, FecX^I, FecX^L, FecX^G, FecX^B (BMP15) and FecG^H (GDF9) mutations. The sequence variability of the different DNA fragments utilised for genotyping was further investigated by Single Stranded Conformation Polymorphism (SSCP) and sequencing. All the above-mentioned mutations were absent in the five sheep breeds examined. SSCP analysis and sequencing allowed the detection of two nucleotide variations. A non-functional mutation (T/C transition at nt 747 of BMP15 cDNA known as B3) was found at the BMP15 gene, in the Noire de Thibar breed; this mutation was first detected in the Belclare sheep. A new nucleotide change G/A at nt 1159 of BMP15 cDNA, causing the amino acid change A119T in the mature peptide, was detected in the Barbarine breed for the first time. The highly prolific D’man ewes were monomorphic for the absence of all the known prolificacy alleles.     

Prolactin Receptor as a Candidate Gene for Prolificacy of Small Tail Han Sheep

DNA polymorphism of the ovine prolactin receptor gene (PRLR) was investigated and used to study its effect on litter size in sheep. By means of PRLR gene sequence homology between sheep and human, three primer pairs were designed for polymerase chain reaction (PCR) amplification within intron 1 and exon 10 of the PRLR gene in sheep. In these parts of the gene the single nucleotide polymorphisms were detected by PCR-single strand conformation polymorphism (SSCP) in 314 Small Tail Han ewes. These poly-morphisms were used to study the associations with litter size. The results indicated that there were three genotypes (AA, AB and BB) detected by three primer pairs. For three primer pairs the frequency of allele A was 0.96, 0.79, 0.68; and the frequency of allele B was 0.04, 0.21, 0.32, respectively. The frequency of genotype AA was 0.93, 0.62, 0.51; the frequency of genotype AB was 0.06, 0.34, 0.34; the frequency of genotype BB was 0.01, 0.04, 0.15, respectively. The Small Tail Han ewes with genotype BB or AB had 0.64–0.76 or 0.44–0.54 more lambs than those with genotype AA, respectively. These results preliminarily showed that the prolactin receptor locus is either a major gene that influences the prolificacy in Small Tail Han sheep or is in close linkage with such a gene.     

Prolactin receptor as a candidate gene for prolificacy of small tail han sheep

DNA polymorphism of the ovine prolactin receptor gene (PRLR) was investigated and used to study its effect on litter size in sheep. By means of PRLR gene sequence homology between sheep and human, three primer pairs were designed for polymerase chain reaction (PCR) amplification within intron 1 and exon 10 of the PRLR gene in sheep. In these parts of the gene the single nucleotide polymorphisms were detected by PCR-single strand conformation polymorphism (SSCP) in 314 Small Tail Han ewes. These poly-morphisms were used to study the associations with litter size. The results indicated that there were three genotypes (AA, AB and BB) detected by three primer pairs. For three primer pairs the frequency of allele A was 0.96, 0.79, 0.68; and the frequency of allele B was 0.04, 0.21, 0.32, respectively. The frequency of genotype AA was 0.93, 0.62, 0.51; the frequency of genotype AB was 0.06, 0.34, 0.34; the frequency of genotype BB was 0.01, 0.04, 0.15, respectively. The Small Tail Han ewes with genotype BB or AB had 0.64-0.76 or 0.44-0.54 more lambs than those with genotype AA, respectively. These results preliminarily showed that the prolactin receptor locus is either a major gene that influences the prolificacy in Small Tail Han sheep or is in close linkage with such a gene.     

Maximum‐likelihood approaches reveal signatures of positive selection in BMP15 and GDF9 genes modulating ovarian function in mammalian female fertility

Bone morphogenetic proteins (BMPs) and the growth factors (GDFs) play an important role in ovarian folliculogenesis and essential regulator of processes of numerous granulosa cells. BMP15 gene variations linked to various ovarian phenotypic consequences subject to the species, from infertility to improved prolificacy in sheep, primary ovarian insufficiency in women or associated with minor subfertility in mouse. To study the evolving role of BMP15 and GDF9, a phylogenetic analysis was performed. To find out the candidate gene associated with prolificacy in mammals, the nucleotide sequence of BMP15 and GDF9 genes was recognized under positive selection in various mammalian species. Maximum‐likelihood approaches used on BMP15 and GDF9 genes exhibited a robust divergence and a prompted evolution as compared to other TGFβ family members. Furthermore, among 32 mammalian species, we identified positive selection signals in the hominidae clade resulting to 132D, 147E, 163Y, 191W, and 236P codon sites of BMP15 and 162F, 188K, 206R, 240A, 244L, 246H, 248S, 251D, 253L, 254F and other codon sites of GDF9. The positively selected amino acid sites such as Alanine, Lucien, Arginine, and lysine are important for signaling. In conclusion, this study evidences that GDF9 and BMP15 genes have rapid evolution than other TGFß family members and was subjected to positive selection in the mammalian clade. Selected sites under the positive selection are of remarkable significance for the particular functioning of the protein and consequently for female fertility.     

单碱基编辑系统介导欧拉藏绵羊GDF9、FecB多胎基因的定点突变

本研究旨在利用单碱基编辑系统(single base editing system)实现欧拉藏绵羊成纤维细胞FecB和GDF9基因靶位点A到G和C到T的碱基替换并检测其编辑效率。首先设计合成靶向欧拉藏绵羊FecB和GDF9基因的sgRNA序列,再分别连接至epi-ABEmax、epi-BE4max质粒,构建载体并电转至欧拉藏绵羊成纤维细胞,最后对阳性细胞FecB和GDF9基因进行Sanger测序鉴定靶位点突变结果,并通过T-A克隆估算单碱基编辑系统的编辑效率。结果显示获得了靶向欧拉藏绵羊FecB和GDF9基因的sgRNA,并构建使欧拉藏绵羊FecB和GDF9基因单碱基突变的载体,FecB基因靶位点编辑效率为39.13%,GDF9基因靶位点(G260、G721、G1184)编辑效率分别为10.52%、26.67%和8.00%。本研究运用单碱基编辑系统在欧拉藏绵羊成纤维细胞上实现了FecB和GDF9基因靶位点突变,为改良欧拉藏绵羊一胎多羔的繁殖性状奠定理论基础。     

Follicular growth in vitro: detection of growth differentiation factor 9 (GDF9) and bone morphogenetic protein 15 (BMP15) during in vitro culture of ovine cortical slices

Primordial follicles from different mammal species can survive and enter the growth phase in vitro but do not develop beyond the primary stage. The hypothesis was that, in sheep, in vitro follicular growth is arrested because of a lack of secretion of GDF9 and/or BMP15. Cortical slices of 0.3-0.5 mm thickness issued from 5- to 6-month-old lambs were cultured for 15 days. The pieces were fixed on days 0, 2, 4, 7, 10, and 15 of culture. Follicle morphology, RT-PCR exploration of GDF9 and BMP15 mRNA, immunohistochemical location of their proteins and their receptor BMPRIB and BMPRII were assessed at different time of culture. The mean percentage of primordial follicles decreased from 58.6% (day 0) to 13.4% (day 15) (P<0.01), whereas that of primary follicles increased from 3.2% (day 0) to 31.5% on day 4 (P<0.01), then remained stable until day 15 (35.6%). The percentage of atretic follicles increased from 14.7% (day 0) to 27.1% (day 15) (P<0.05). A few secondary follicles were observed on days 4 and 10, representing 1.0%, and 2.1% of the total number of follicles. GDF9 and BMP15 mRNAs were detected from harvesting (day 0) up to day 15 following culture. At the same time, positive immunoreactions for GDF9, BMP15 and for BMPRIB and BMPRII were also found in oocyte cytoplasm. In conclusion, expression of GDF9, BMP15 and their receptors BMPRIB and BMPRII are detected during in vitro culture of ovine cortical slices.     

Aromatase gene and its effects on growth, reproductive and maternal ability traits in a multibreed sheep population from Brazil

We determined the polymorphism C242T of the aromatase gene (Cyp19) and its allelic frequency, as well as the effect of the variants on productive and reproductive traits in 71 purebred Santa Inês sheep, 13 purebred Brazilian Somali sheep, nine purebred Poll Dorset sheep, and 18 crossbred 1/2 Dorper sheep. The animals were genotyped using the PCR-RFLP technique. The influence of the animal's genotype on its performance or on the performance of its lambs was analyzed by the least square method. Another factor assessed was the importance of the animal's genotype in analysis models for quantitative breeding value estimates, and whether there were differences among the averages of breeding values of animals with different genotypes for this gene. In the sample studied, no AA individuals were observed; the AB and BB frequencies were 0.64 and 0.36, respectively. All Brazilian Somali sheep were of genotype BB. All 1/2 Dorper BB animals presented a lower age at first lambing, and the Santa Inês BB ewes presented a lower lambing interval. In these same genetic groups, AB ewes presented higher litter weight at weaning. This is evidence that BB ewes have a better reproductive performance phenotype, whereas AB ewes present a better maternal ability phenotype. However, in general, animals with genotype AB presented better average breeding values than those with genotype BB.     

Characterization and polymorphism of Keratin Associated Protein 1.4 gene in goats

Keratin-associated proteins (KAPs) are among the main structural components of the animal fibers and form semi-rigid matrix wherein the keratin intermediate filaments (KIFs) are embedded. Variation in the KAP genes has been reported to affect the structure of KAPs and hence fiber characteristics. As no information is available on this gene in Capra hircus therefore, present work was undertaken to characterize and explore the different polymorphic variants of KAP1.4 gene at DNA level in different breeds/genetic groups of goats of Kashmir. Cashmere (Changthangi, 30 animals) and non-Cashmere (Bakerwal and Kargil goats, 20 animals each) goats formed the experimental animals for the study. Single strand conformation polymorphism technique was employed for exploring variability at gene level. On exploring the size variability in KAP1.4 gene between Ovine and Caprine, it was concluded that sheep KAP1.4 gene has a deletion of 30 nucleotides. In comparison to published nucleotide sequences of sheep, goat sequences explored are differing at positions 174, 462 and 568 and at these positions “G”, “T” and “T” nucleotides are present in sheep, but are replaced by “A”, “C” and “C” respectively, in goats. By SSC studies, two genotypes were observed in each genetic group and in Bakerwal goats the genotypes were designated as A1A1 (0.40) and A1A2 (0.60) and were formed by two alleles A1 (0.70) andA2 (0.30). The different SSC patterns observed in Kargil goats were designated as B1B1 (0.35) and B1B2 (0.65) genotypes with frequencies of B1 and B2 alleles as 0.675 and 0.325, respectively. Similarly, two genotypes C1C1 (0.60) and C1C2 (0.40) were observed in Changthangi goats and the frequencies of C1 and C2 alleles were 0.80 and 0.20, respectively. These alleles were later confirmed by sequencing. The sequences of these alleles are available in NCBI under Acc. No's. JN012101.1, JN012102.1, JN000317.1, JN000318.1, JQ436929 and JQ627657. It was concluded that all the alleles observed in a breed were unique to the breed. The designated A1 and A2 alleles of Bakerwal goats differ from each other at positions 245 and the nucleotides observed were “C” or “A” and at position 605 of the nucleotide sequence “T” or “C”, were observed. The designated B1 and B2 alleles of Kargil goats differed from each other at positions 224, 374, 375 and 521. The nucleotides observed in two SSC pattern were C→G, A→G, G→A and T→C, respectively. The designated C1 and C2 alleles of Changthangi goats differed from each other at one position 440 with the change of “A”→“C”.     

Regulation of GDF9 and CDKN1B expression in Tibetan sheep testes during different stages of maturity

Normal spermatogenesis is heavily dependent on the balance of germ cell proliferation, differentiation and apoptosis. Growth differentiation factor 9 (GDF9) and cyclin-dependent kinase inhibitor 1 B (CDKN1B) are strongly associated with cell cycle transition from G0/G1 to S and G2/M phase and hence regulating the growth and development of testicular germ cells and somatic cells. The current study was aimed at seeking out scientific evidence to determine if GDF9 and CDKN1B gene expression functions in the development of Tibetan sheep testes. To this end, developmental testes were derived from three-month-old (pre-puberty), one-year-old (sexual maturity), and three-year-old (adult) Tibetan sheep and then the expression and localization patterns of GDF9 and CDKN1B in these testes were evaluated using quantitative real-time PCR (qRT-PCR), Western blot and immunofluorescence. qRT-PCR and Western blot results showed that GDF9 and CDKN1B were detected in the testes throughout the different developmental stages. The abundance of GDF9 mRNA and protein in the testes of one- and three-year-old Tibetan sheep were higher than that in the testes of three-month-old Tibetan sheep; the mRNA and protein abundance of the CDKN1B gene in three-month-old Tibetan sheep testes were higher than that in the testes of the one-and three-year-old sheep. Moreover, immunofluorescence results suggested that the GDF9 protein was expressed in spermatogonia and Leydig cells, and that the CDKN1B protein was localized mainly in Leydig cells with some in the seminiferous epithelium throughout developmental stages. This indicated a novel role of the GDF9 and CDKN1B genes in Leydig cell development over and above their known roles in germ cell development. These findings have significant implications for our understanding of the molecular mechanisms of GDF9 and CDKN1B genes in Tibetan sheep spermatogenesis.     

Genome‐wide association study to identify genomic regions affecting prolificacy in Lori‐Bakhtiari sheep

Several causative mutations in candidate genes affecting prolificacy have been detected in various sheep breeds. A genome‐wide association study was performed on estimated breeding values for litter size in Lori‐Bakhtiari sheep. Prolific ewes with twinning records and others with only singleton records were genotyped using the medium‐density Illumina Ovine SNP50 array. Four single nucleotide polymorphisms (SNPs) associated with litter size were identified on chromosomes 3, 6 and 22. The region on sheep chromosome 3 between 75 739 167 and 75 745 152 bp included two significant SNPs (s52383.1 and OAR3_80038014_X.1) in high linkage disequilibrium with each other. The region that surrounds these SNPs contains a novel putative candidate gene: luteinizing hormone/choriogonadotropin receptor (LHCGR), known to be involved in ovarian steroidogenesis and organism‐specific biosystem pathways in sheep. Known prolificacy genes BMPR1B, BMP15 and GDF9 were not associated with litter size in Lori‐Bakhtiari sheep, suggesting that other biological mechanisms could be responsible for the trait's variation in this breed.