Differences of the porcine amelogenin X and Y chromosome genes (AMELX and AMELY) and their application for sex determination in pigs

Molecular sexing in wild and domestic animals has becoming an important issue in several fields including reproduction. X and Y chromosome-specific sequence differences of the amelogenin genes (AMELX and AMELY) have been described in different mammalian species and used for sex determination. We studied the possibility to use sequence variability between the porcine AMELX and AMELY genes for sex determination in pigs. Sequence analysis of about 400 bp of intron 3 of the porcine amelogenin genes showed the presence of a 9-10 bp deletion in AMELY gene compared to AMELX sequences. Moreover, one single nucleotide polymorphism (SNP) was detected for the AMELY sequence. Four other SNPs and 1 bp insertion differentiated three AMELX haplotypes indicating an unexpected quite high nucleotide diversity for a chromosome X region. Two sex determination assays targeting the 9-10 bp difference between AMELX and AMELY were developed. Assessment of the accuracy of the amelogenin assays to correctly sex individuals was tested on 329 pigs belonging to different breeds/lines. All analysed animals were correctly sexed with the new designed amelogenin tests. No amplification was obtained in human, cattle, goat, sheep, and horse genomic DNA. These assays can be used for sex diagnosis of small amounts of genomic DNA (20 pg) obtained from different sources including embryo biopsies, hair, meat, and other biological specimens. Thus, apart from the application in the reproduction field, these tests can be useful in several other sectors including forensics, archaeozoology, meat production, and processing as well as for quality control in sample identification.     

Sex determination in cattle based on simultaneous amplification of a new male-specific DNA sequence and an autosomal locus using the same primers

A PCR-based method for sex determination of bovine DNA samples and embryo biopsies is presented. Using only one primer pair both the male-specific sequence FBNY (127 bp) and a sex-independent control PCR-fragment, the microsatellite marker FBN17 (136-140 bp) are generated in the same PCR reaction. Synteny mapping assigned the male-specific sequence to bovine chromosome Y (BTA Y), whereas FBN17 was mapped to bovine chromosome 2. Localisation of FBNY on BTA Y was confirmed by fluorescence in hybridisation of two BAC clones containing the male-specific sequence. There was no amplification of the male-specific target sequence FBNY in sheep, pig, goat, mice, man, and several wild species of the tribe Bovini. The bovine male-specific fragment was detected in dilutions containing as little as 10 pg genomic DNA and in blastomeres from embryo biopsies. The PCR assay presented here does require neither restriction endonuclease digestion of the PCR product nor additional nested PCR steps. Owing to the advantage of parallel amplification of the autosomal locus FBN17 no additional control fragment is necessary to detect PCR failure. The results of sex determination in embryo biopsies using FBNY were in agreement with the outcome from a reference assay used in commercial breeding programs.     

Reliability of sex determination in ovine embryos using amelogenin gene (AMEL)

Sex specific sequence variability of the amelogenin gene has been used for sex determination in the family of Bovidae. In our study, suitability and reliability of the amelogenin gene for ovine sex determination in embryos was studied. The specificity of the method was previously demonstrated by testing 579 blood samples from several Spanish sheep breeds (161 males and 198 females). No amplification failures and very high agreement between genotypic and phenotypic sex was found (578/579), in contrast to humans, where errors in sex determination has been reported because of mutations in AMELX or AMELY genes. However, one female animal showed a male genotypic sex, being the most plausible explanation that a recombination event has happened during the meiosis. In our study only 0.17% (1/579) of the samples tested has been misdiagnosed using the amelogenin gene. Finally, 1-10 cells from each of 67 compact morulae were aspirated through the zona pellucida, and genotyped for sex determination. The efficiency in sex determination was 95 and 98% when more than two and more than three cells were sampled, respectively. The total time required for the genetic test, was less than 4h. These results confirm that the amelogenin gene can be used for rapid sex determination in ovine embryos, with a high efficiency and accuracy (100%) when three or more cells are sampled, allowing transferring sexed fresh embryos in MOET programmes. To our knowledge, this was the first time that sex determination using the amelogenin gene was performed in ovine embryos.     

Sequence length polymorphisms within primate amelogenin and amelogenin-like genes: usefulness in sex determination

Sequence length polymorphisms between the amelogenin (AMELX) and the amelogenin-like (AMELY) genes both within and between several mammalian species have been identified and utilized for sex determination, species identification, and to elucidate evolutionary relationships. Sex determination via polymerase chain reaction (PCR) assays of the AMELX and AMELY genes has been successful in greater apes, prosimians, and two species of old world monkeys. To date, no sex determination PCR assay using AMELX and AMELY has been developed for new world monkeys. In this study, we present partial AMELX and AMELY sequences for five old world monkey species (Mandrillus sphinx, Macaca nemestrina, Macaca fuscata, Macaca mulatta, and Macaca fascicularis) along with primer sets that can be used for sex determination of these five species. In addition, we compare the sequences we generated with other primate AMELX and AMELY sequences available on GenBank and discuss sequence length polymorphisms and their usefulness in sex determination within primates. The mandrill and four species of macaque all share two similar deletion regions with each other, the human, and the chimpanzee in the region sequenced. These two deletion regions are 176-181 and 8 nucleotides in length. In analyzing existing primate sequences on GenBank, we also discovered that a separate six-nucleotide polymorphism located approximately 300 nucleotides upstream of the 177 nucleotide polymorphism in sequences of humans and chimps was also present in two species of new world monkeys (Saimiri boliviensis and Saimiri sciureus). We designed primers that incorporate this polymorphism, creating the first AMELX and AMELY PCR primer set that has been used successfully to generate two bands in a new world monkey species.     

Sex identification of pigs using polymerase chain reaction amplification of the amelogenin gene

The amelogenin (AMEL) gene exists on both sex chromosomes of various mammalian species and the length and sequence of the noncoding regions differ between the two chromosome-specific alleles. Because both forms can be amplified using a single primer set, the use of AMEL in polymerase chain reaction (PCR)-based methods has facilitated sex identification in various mammalian species, including cattle, sheep and humans. In this study, we designed PCR primers to yield different-sized products from the AMEL genes on the X (AMELX) and Y (AMELY) chromosomes of pigs. PCR amplification of genomic DNA samples collected from various breeds of pigs (European breeds: Landrace, Large White, Duroc and Berkshire; Chinese breeds: Meishan and Jinhua and their crossbreeds) yielded the expected products. For all breeds, DNA from male pigs produced two bands (520 and 350 bp; AMELX and AMELY, respectively), whereas samples from female pigs generated only the 520 bp product. We then tested the use of PCR of AMEL for sex identification of in vitro-produced (IVP) porcine embryos sampled at 2 or 5 to 6 days after fertilization; germinal vesicle (GV)-stage oocytes and electroactivated embryos were used as controls. More than 88% of the GV-stage oocytes and electroactivated embryos yielded a single 520 bp single band and about 50% of the IVP embryos tested produced both bands. Our findings show that PCR analysis of the AMEL gene is reliable for sex identification of pigs and porcine embryos.     

The species and chromosomal distribution of the centromeric alpha-satellite I sequence from sheep in the tribe Caprini and other Bovidae

The evolution of chromosomes in species in the family Bovidae includes fusion and fission of chromosome arms (giving different numbers of acrocentric and metacentric chromosomes with a relatively conserved total number of arms) and evolution in both DNA sequence and copy number of the pericentromeric alpha-satellite I repetitive DNA sequence. Here, a probe representing the sheep alpha-satellite I sequence was isolated and hybridized to genomic DNA digests and metaphase chromosomes from various Bovidae species. The probe was highly homologous to the centromeric sequence in all species in the tribe Caprini, including sheep (Ovis aries), goat (Capra hircus) and the aoudad or Barbary sheep (Amnotragus lervia), but showed no detectable hybridization to the alpha-satellite I sequence present in the tribe Bovini and at most very weak to species in the tribes Hippotragini, Alcelaphini or Aepycerotini. The sex chromosomes of sheep, goat and aoudad did not contain detectable alpha-satellite I sequence; in sheep, one of the three metacentric autosomal chromosomes does not carry the sequence, while in aoudad, it is essentially absent in three large autosomal pairs as well as the large metacentric chromosome pair. The satellite probes can be used as robust chromosome and karyotype markers of evolution among tribes and increase the resolution of the evolutionary tree at the base of the Artiodactyla.     

Sequence of specific mitochondrial 16S rRNA gene fragment from Egyptian buffalo is used as a pattern for discrimination between river buffaloes,cattle, sheep and goats

Characterization of molecular markers and the development of better assays for precise and rapid detection of domestic species are always in demand. This is particularly due to recent food scares and the crisis of biodiversity resulting from the huge ongoing illegal traffic of endangered species. The aim of this study was to develop a new and easy method for domestic species identification (river buffalo, cattle, sheep and goat) based on the analysis of a specific mitochondrial nucleotide sequence. For this reason, a specific fragment of Egyptian buffalo mitochondrial 16S rRNA gene (422 bp) was amplified by PCR using two universal primers. The sequence of this specific fragment is completely conserved between all tested Egyptian buffaloes and other river buffaloes in different places in the world. Also, the lengths of the homologous fragments were less by one nucleotide (421 bp) in case of goats and two nucleotides (420 bp) in case of both cattle and sheep. The detection of specific variable sites between investigated species within this fragment was sufficient to identify the biological origin of the samples. This was achieved by alignment between the unknown homologous sequence and the reference sequences deposited in GenBank database (accession numbers, FJ748599–FJ748607). Considering multiple alignment results between 16S rRNA homologous sequences obtained from GenBank database with the reference sequence, it was shown that definite nucleotides are specific for each of the four studied species of the family Bovidae. In addition, other nucleotides are detected which can allow discrimination between two groups of animals belonging to two subfamilies of family Bovidae, Group one (closely related species like cattle and buffalo, Subfamily Bovinae) and Group two (closely related species like sheep and goat, Subfamily Caprinae). This 16S DNA barcode character-based approach could be used to complement cytochrome c oxidase I (COI) in DNA barcoding. Also, it is a good tool for identification of unknown sample belonging to one of the four domestic animal species of family Bovidae quickly and easily.     

Characteristics of X- and Y-chromosome specific regions of the amelogenin gene and a PCR-based method for sex identification in red deer (<Emphasis Type="Italic">Cervus elaphus</Emphasis>)

The present study attempts to analyse sequences of the X- and Y-chromosome specific regions of the amelogenin (AMEL) gene in red deer. To this end, primers specific for each form of the gene (AMELX and AMELY) were designed based on bovine genomic sequences and the homologous regions of the genes were sequenced. The obtained sequence of AMELX gene showed high similarity with the corresponding region in cattle (91%) and humans (77%), but this similarity was slightly lower among AMELY genes and showed 87 and 73% of identical nucleotides, respectively. In addition, three single nucleotide polymorphisms (SNPs) were found in the AMELX gene of the female red deer investigated. Comparative analysis of the homologous fragments of the red deer AMELX and AMELY genes confirmed the deletion of an AMELY gene fragment in relation to AMELX. Homology of both sequences was 82% of identical nucleotides in the coding region and 74% in 3′ non-coding sequence. The sequences studied showed considerable similarity to homologous fragments of the human and bovine gene, but the structural differences observed lead us to design PCR-based method for sex identification in red deer, based on the presented sequences.     

山羊卵泡刺激素α亚基cDNA的分子克隆与序列分析

从新屠宰的雌山羊脑垂体中提取总RNA ,反转录获得cDNA .以此cDNA为模板用PCR法扩增目的片段 ,获得长为 380bp的山羊卵泡刺激素α亚基cDNA片段 .将它克隆至pMD 18 T Verctor.随机挑选 3个阳性重组子进行测序 ,将测序结果与绵羊、牛、猪等多种哺乳动物该基因的核苷酸序列及相应氨基酸序列进行比较 .结果表明 ,山羊卵泡刺激素α亚基基因氨基酸序列与绵羊、水牛的同源性最高 ,达 96 % ,与牛的同源性达 95 % ,与人的同源性较低 ,为 74 % .山羊卵泡刺激素α亚基基因编码区的核苷酸与绵羊的同源性最高 ,达 95 % ,与水牛、牛的同源性达 94 % ,与马和大鼠的同源性较低 ,为 85 % .总体来看 ,在哺乳类动物中FSHα亚基基因同源性还是很高的 .     

Sex determination in 6 bovid species by duplex PCR

Sex determination in domestic animals is of potential value to livestock breeding programs. The aim of this study was to develop a simple and accurate PCR-based sex determination protocol, which can be applicable to 6 major domesticated species of the family Bovidae,viz. Bos frontalis, B. grunniens, B. indicus, Bubalus bubalis, Capra hircus, andOvis aries. In silico analysis was done to identify conserved DNA sequence in the HMG box region of the sex-determining region of the Y-chromosome (SRY gene) across the bovids. Duplex PCR assay, including theSRY gene and theGAPDH housekeeping gene, was optimized by using genomic DNA extracted from blood samples of known sex. It was possible to identify the sex of animals by amplifying both gender-specific (SRY) and autosomal (GAPDH) genes simultaneously in the duplex reaction, with the male yielding two bands and the female one band. The protocol was subjected to a blind test that showed a 100 percent specificity and accuracy, thus it can be used in sex determination in livestock breeding programs.     

Cross-species amplification of Bovidae microsatellites and low diversity of the endangered Korean goral

The Korean goral (Nemorhaedus caudatus) is an endangered species of wild goat. The conservation and management of this species could benefit from a better understanding of its genetic diversity and structure. Cross-species amplification of 34 Bovidae microsatellite loci was tested on a panel of 6 Korean gorals and 10 domestic goats. After polymerase chain reaction (PCR) optimization, 29 (85.3%) microsatellite loci amplified successfully for the Korean gorals and 27 (79.4%) for the domestic goats. Of the amplified products, 16 (55.2%) were polymorphic in the Korean goral and 22 (81.5%) in domestic goats. Nei's unbiased mean heterozygosity and mean allele number per locus were, respectively, 0.356 and 2.6 in the Korean goral and 0.636 and 4.8 in domestic goats. Low genetic diversity in the Korean gorals observed in this preliminary microsatellite survey suggests an urgent need for further detailed study of genetic diversity in Korean goral populations and a population management strategy based on these studies. Current results of cross-species amplification of domestic Bovidae microsatellites could be employed for the necessary population genetic studies on the Korean goral and other endangered Caprinae species.     

Comparative analysis of a putative tuberculosis-susceptibility gene, MC3R, and pseudogene sequences in cattle, African buffalo, hyena, rhinoceros and other African bovids and ruminants

Studies in humans have suggested the possible involvement of melanocortin-3-receptor (MC3R) and other components of the central melanocortin system in host defense against mycobacteria. We report a genomic DNA nucleotide sequence highly homologous to human MC3R in several bovids and non-bovid African wildlife species. Nucleotide sequence analysis indicates that the orthologous genes of cattle and buffalo are highly homologous (89.4 and 90%, respectively) to the human MC3R gene. Sequence results also identified a typical non-functional, duplicated pseudogene, MC3RP, in 7 species from the family Bovidae. No pseudogene was found in animals outside Bovidae. The presence of the pseudogene in tuberculosis-susceptible species could have possible immunomodulatory effects on susceptibility to bovine tuberculosis infection, as well as a considerable influence on energy metabolism and food conversion efficiency.     

Evolution and recombination of bovine DNA repeats

The history of the abundant repeat elements in the bovine genome has been studied by comparative hybridization and PCR. The Bov-A and Bov-B SINE elements both emerged just after the divergence of the Camelidae and the true ruminants. A 31-bp subrepeat motif in satellites of the Bovidae species cattle, sheep, and goat is also present in Cervidae (deer) and apparently predates the Bovidae. However, the other components of the bovine satellites were amplified after the divergence of the cattle and the Caprinae (sheep and goat). A 23-bp motif, which as subrepeat of two major satellites occupies 5% of the cattle genome, emerged only after the split of the water buffalo and other cattle species. During the evolution of the Bovidae the satellite repeat units were shaped by recombination events involving subrepeats, other satellite components, and SINE elements. Differences in restriction sites of homologous satellites indicate a continuing rapid horizontal spread of new sequence variants. Correspondence to: J.A. Lenstra     

Determination of sex and chimaerism in the domestic sheep by DNA amplification using HMG-box and microsatellite sequences

We describe a rapid, reliable method for the sexing of the domestic sheep (Ovis aries) by amplification of Y-chromosome-specific sequences in male genomic DNA using the polymerase-chain reaction (PCR). Oligonucleotide primers were selected from a conserved sequence, the HMG box, in the sequence of ovine Sry, permitting amplification of a defined 161 bp fragment only from male-specific genomic DNA. As a control, microsatellite primers also were used in PCR reactions, recognising a sequence that is amplifiable in genomic DNA from both males and females. In addition, we demonstrate the feasibility of using this technique for the detection of Y-specific sequences in foetal biopsies (specifically small numbers of foetal germ cells), and in reconstruction mixtures of male and female genomic DNA to simulate the analysis of intersex chimaeras which would be produced when pluripotent cells have been established for this species.     

Including endophenotypes as covariates in variance component heritability and linkage analysis

Background

Simple and precise methods for sex determination in animals are a pre-requisite for a number of applications in animal production and forensics. However, some of the existing methods depend only on the detection of Y-chromosome specific sequences. Therefore, the abscence of a signal does not necessarily mean that the sample is of female origin, because experimental errors can also lead to negative results. Thus, the detection of Y- and X-chromosome specific sequences is advantageous.

Results

A novel method for sex identification in mammals (sheep, Ovis aries and European red deer, Cervus elaphus ) is described, using a polymerase chain reaction (PCR) and sequencing of a part of the amelogenin gene. A partial sequence of the amelogenin gene of sheep and red deer was obtained, which exists on both X and Y chromosomes with a deletion region on the Y chromosome. With a specific pair of primers a DNA fragment of different length between the male and female mammal was amplified.

Conclusion

PCR amplification using the amelogenin gene primers is useful in sex identification of samples from sheep and red deer and can be applied to DNA analysis of micro samples with small amounts of DNA such as hair roots as well as bones or embryo biopsies.     

Heterogeneity of amelogenin mRNA in the bovine tooth germ

The amelogenins are a complex mixture of hydrophobic proteins that are the major organic component of developing enamel. To study the molecular mechanisms underlying the heterogeneity of the amelogenins we isolated cDNA clones encoding these proteins. The clones were definitively identified by hybrid-selected translation experiments and by comparison of the DNA sequence with the protein-derived amino acid sequence. Southern hybridization of bovine genomic DNA indicated that amelogenin is a single copy gene. However, Northern hybridization experiments distinctly showed two major species of mRNA, each of which were sufficiently large enough to encode the highest known molecular weight species of amelogenin proteins. Furthermore, immunoprecipitation of hybrid-selected translation products using isolated amelogenin cDNA showed multiple, translated protein products. These data are supportive of a differential mRNA processing mechanism involved in generating a heterogeneous family of amelogenin matrix proteins from a single gene.     

Gender determination in single bovine blastomeres by polymerase chain reaction amplification of sex-specific polymorphic fragments in the amelogenin gene.

A sensitive technique for the sexing of bovine embryos was developed using polymerase chain reaction (PCR) amplification of the bovine amelogenin (bAML) gene on the X- and Y-chromosomes of Holstein dairy cattle. Cloning and DNA sequencing showed a 45.1% homology between the fifth intron of the bAML-X and bAML-Y gene with multiple deletions. A pair of sex-specific primers was designed to allow amplification of a single fragment of 467-bp from the X-chromosome of female cattle and two fragments of 467-bp and 341-bp from the X- and Y-chromosomes of male cattle. The primers were successfully applied to bovine sexing from single blastomeres isolated from day-6 to day-7 cow embryos by direct cell lysis and PCR. Our protocol of embryo sexing should be applicable to the diagnosis of defective genes in vitro in human embryos and in other domestic or recreational animals.     

Pstl repeat: a family of short interspersed nucleotide element (SINE)-like sequences in the genomes of cattle, goat, and buffalo.

The PstI family of elements are short, highly repetitive DNA sequences interspersed throughout the genome of the Bovidae. We have cloned and sequenced some members of the PstI family from cattle, goat, and buffalo. These elements are approximately 500 bp, have a copy number of 2 x 10(5) - 4 x 10(5), and comprise about 4% of the haploid genome. Studies of nucleotide sequence homology indicate that the buffalo and goat PstI repeats (type II) are similar types of short interspersed nucleotide element (SINE) sequences, but the cattle PstI repeat (type I) is considerably more divergent. Additionally, the goat PstI sequence showed significant sequence homology with bovine serine tRNA, and is therefore likely derived from serine tRNA. Interestingly, Southern hybridization suggests that both types of SINEs (I and II) are present in all the species of Bovidae. Dendrogram analysis indicates that cattle PstI SINE is similar to bovine Alu-like SINEs. Goat and buffalo SINEs formed a separate cluster, suggesting that these two types of SINEs evolved separately in the genome of the Bovidae.     

Characterization and SNP Identification of Part of the Goat Melanophilin Gene

The melanophilin (MLPH) gene has been characterized as the candidate gene for dilute coat color in some species, but little is known about it in the goat. In this study, part of the genomic DNA sequence (19,289 bp) containing the whole coding region of the MLPH gene from goat, as well as from sheep, was determined. We found 16 exons and 15 introns; the coding region was 1767 bp distributed in 15 exons (2–16). In sheep, the length of part of the genomic DNA sequence was 16,988 bp, with 16 exons and 15 introns, and the coding region was 1833 bp, distributed in 15 exons (2–16). Dozens of SNPs as well as some noticeable motifs in the goat MLPH gene were found during the process of sequencing and polymorphism screening. Based on the SSR Tool, three simple sequence repeat motifs were detected in the goat and sheep DNA sequences. Compared with cattle, we found insertions of 4 amino acids in goats and 26 amino acids in sheep.     

Species and sex identification of the Korean goral (Nemorhaedus caudatus) by molecular analysis of non-invasive samples

Korean long-tailed goral (Nemorhaedus caudatus) is one of the most endangered species in South Korea. However, detailed species distribution and sex ratio data on the elusive goral are still lacking due to difficulty of identification of the species and sex in the field. The primary aim of this study was to develop an economical PCR-RFLP method to identify species using invasive or non-invasive samples from five Korean ungulates: goral (N. caudatus), roe deer (Capreolus pygargus), feral goat (Capra hircus), water deer (Hydropotes inermis) and musk deer (Moschus moschiferus). The secondary aim was to find more efficient molecular sexing techniques that may be applied to invasive or non-invasive samples of ungulate species. We successfully utilized PCR-RFLP of partial mitochondrial cytochrome b gene (376 bp) for species identification, and sex-specific amplification of ZFX/Y and AMELX/Y genes for sexing. Three species (goral, goat and water deer) showed distinctive band patterns by using three restriction enzymes (XbaI, StuI or SspI). Three different sexing primer sets (LGL331/335 for ZFX/Y gene; SE47/48 or SE47/53 for AMELX/Y gene) produced sex-specific band patterns in goral, goat and roe deer. Our results suggest that the molecular analyses of non-invasive samples might provide us with potential tools for the further genetic and ecological study of Korean goral and related species.