Rapid sexing of preimplantation bovine embryo using consecutive and multiplex polymerase chain reaction (PCR) with biopsied single blastomere.

The objective of this study was to establish a rapid and reliable PCR method for the sexing of 8- to 16-cell stage bovine embryos. The BOV97M and bovine 1.715 satellite DNA sequences were selected for amplification of male- and bovine-specific DNA, respectively. But the unequal number of copies of these two repetitive sequences required some modification of the multiplex PCR method. In consecutive and multiplex PCR, the first 10 PCR cycles were done with male-specific primer followed by an additional 23 cycles with bovine-specific primer. In this PCR method, the appearance of male- and bovine-specific bands was independent of the DNA concentration. This PCR method was applied successfully using groups of 8, 4, 2, and 1 blastomeres dissociated from the embryos, and the sexing efficiency was 100.0, 96.3, 94.3 and 92.1%, respectively. The coincident rate of sex determination between biopsied single blastomere and matched blastocyst was 90.0%. Therefore the developmental potential from 8- to 16-cell stage embryos to the blastocyst stage was not significantly different (P>0.2) for intact embryo (42.3%) than for demi-embryos (53.8%), suggesting that trauma to the demi-embryo caused by single-blastomere aspiration using a bevelled micropipette was very small. In conclusion, we developed a rapid (within 2 hours) and effective PCR method for the sexing of 8- to 16-cell stage bovine embryos using a single blastomere.     

Frequency of sex chromosomal mosaicism in bovine embryos and its effects on sexing using a single blastomere by PCR

Assessment of nuclear status is important when a biopsied single blastomere is used for embryo sexing. In this study we investigated the nuclear status of blastomeres derived from 8- to 16-cell stage in vitro fertilised bovine embryos to determine the representativeness of a single blastomere for embryo sexing. In 24 embryos analysed, the agreement in sex determination between a biopsied single blastomere and a matched blastocyst by polymerase chain reaction (PCR) was 83.3%. To clarify the discrepancies, karyotypes of blastomeres in 8- to 16-cell stage bovine embryos were analysed. We applied vinblastine sulfate at various concentrations and for different exposure times for metaphase plate induction in 8- to 16-cell stage bovine embryos. The 1.0 mg/ml vinblastine sulfate treatment for 15 h was selected as the most effective condition for induction of a metaphase plate (> 45%). Among 22 embryos under these conditions, only 8 of 10 that had a normal diploid chromosome complement showed a sex chromosomal composition of XX or XY (36.4%) and 2 diploid embryos showed mosaicism of the opposite sex of XX and XY in blastomeres of the embryo (9.1%). One haploid embryo contained only one X-chromosome (4.5%). Four of another 11 embryos with a mixoploid chromosomal complement contained a haploid blastomere with a wrong sex chromosome (18.2%). In conclusion, assessment of nuclear status of 8- to 16-cell stage bovine embryos revealed that morphologically normal embryos had a considerable proportion of mixoploid blastomeres and sex chromosomal mosaicism; these could be the cause of discrepancies in the sex between biopsied single blastomeres and matched blastocysts by PCR.     

Rapid sexing of murine preimplantation embryos using a nested,multiplex polymerase chain reaction (PCR)

The objective of this study was to develop a rapid and efficient means of sexing murine preimplantation embryos at the 4- to 8-cell stage of development. To achieve this goal, a nested, multiplex polymerase chain reaction (PCR) was optimized using DNA from male and female mice and primers specific for X- (DXNds3)- and Y- (Sry,Zfy) gene sequences. Sensitivity of the assay was measured using groups of 4, 2, or 1 blastomere from dissociated embryos. Efficiency was evaluated using single blastomeres obtained by embryo biopsy. Accuracy of sexing was determined by comparing single-cell results with those of matched blastocysts. Robust amplification of male (XY) and female (XX) gene sequences was obtained in less than 6 hours. The percentage of male (3 bands) and female (1 band) reactions for groups of 4, 2, or 1 blastomere was 100% (6/6), 100% (15/15), and 94.4% (17/18), respectively. Assay efficiency for single, biopsied blastomeres from 4 to 8 cell embryos was 95.8% (207/216). For male and female embryos, sexing of single blastomeres accurately predicted results of matched blastocysts, 100% (10/10) and 100% (13/13), respectively. Simultaneous amplification of one X- and two Y-gene sequences ensured correct interpretation of sexing reactions. Short thermal cycling times and minimal tube handling increased the assay speed and decreased the potential risk of contamination. Mol. Reprod. Dev. 49:261–267, 1998. © 1998 Wiley-Liss, Inc.     

Multiple genotype analysis and sexing of IVF bovine embryos

Twenty-one in vitro-fertilized bovine blastocysts were quartered, lysed and subjected to primer elongation preamplification (PEP) procedure, allowing for the analysis of up to 40 genotypes per quarter embryo. The quarter-embryos were sexed by polymerase chain reaction (PCR) using BRY.1, Bov97M and ZFX/ZFY loci, and then genotyped for k-casein, bovine leukocyte adhesion deficiency (BLAD) and microsatellite D9S1. The mitochondrial cytochrome B locus was used as an internal control with a 95% success rate. The PEP procedure amplified genomic fragments in 93% of all cases. The embryos were identified to be 11 males and 10 females. Sexing accuracy was 87% for BRY.1, 97% for ZFX/ZFY and 100% for Bov97M. False genotyping was due mostly to amplification of BRY.1 in the female embryos and to the nonamplification of the ZFY locus in the male embryos. The results indicate that the combined use of Bov97M and ZFX/ZFY loci is a highly accurate procedure for sexing bovine embryos. Genotyping for kappa-casein, D9S1 and BLAD was successful in 94, 99 and 91% of assays, respectively. Sex ratios and allele frequencies of embryos for gk-casein, BLAD and D9S1 were all close to the observed frequencies in the Israeli Holstein population. These results support the conclusion that the genotyping of embryos is as accurate as that of mature animals. Thus, marker-assisted selection can be efficiently applied at the preimplantation embryo level for loci of economic importance.     

Sexing of mouse preimplantation embryos by detection of Y chromosome-specific sequences using polymerase chain reaction.

Detection of genes known to be present on the mammalian Y chromosome was adapted for sexing mouse early embryos using the polymerase chain reaction (PCR) method. Sry and Zfy genes located in the sex-determining region of the Y chromosome were chosen for Y-specific target sequences, and DXNds3 sequence on the X chromosome was chosen for control. The two-step PCR method using two pairs of primers for each of the target sequences was employed for detecting the sequences. When DNAs of male and female mice were amplified with these primers, male-specific fragments were detected even in DNAs that were equivalent in amount to two cells. Mouse embryos at the two-cell stage were separated into two individual blastomeres, and one blastomere was karyotyped at the second cleavage. The remaining blastomere was subjected to PCR amplification immediately or after having been cultured for 48 h up to the morula stage. The Sry and Zfy sequences were detected in about half the embryos; detection of the Sry and Zfy sequences corresponded exactly to the presence of the Y chromosome, except in one sample of male morula in which embryos may have been lost before the PCR amplification. It is concluded that the sex of mouse preimplantation embryos can be accurately determined through detection of the Y-specific sequences using the two-step PCR method, even with the single blastomeres separated at the two-cell stage.     

Effect of aging of recipient oocytes on the development of bovine nuclear transfer embryos in vitro

The present study was undertaken to examine the effect of the length of in vitro maturation of oocytes on the efficiency of enucleation, parthenogenetic activation and blastomere fusion by electric stimulus. In vitro development of reconstituted oocytes receiving a blastomere from 8 to 16-cell bovine embryos fertilized in vitro was investigated to assess the effect of aging of the oocytes. The proportion of oocytes with a first polar body at 22 to 24 hours after maturation was high (80%) compared with those obtained at 16 to 18, 28 to 30 or 42 to 44 hours (50 to 75%). The success rate of enucleation significantly decreased with aging (88, 85, 74 and 55%). The activation rate significantly increased with the length of maturation in vitro (P<0.01) (1 to 4, 24 to 41, 57 to 70 and 80 to 87%). The proportion of oocytes fused with a blastomere from 8- to 16-cell embryos was not dependent on the age of the oocytes (54 approximately 59%). The ability of the reconstituted oocytes to develop to the 2-cell and the 8- to 16-cell stage increased with the length of maturation of recipient oocytes. When oocytes enucleated and a blastomere at 22 to 24 hours were incubated further for 22 to 23 hours until electrofusion. The proportions of oocytes which developed to the 2-cell and the 8- to 16-cell stages (74 and 17%) were similar to those obtained at 42 to 44 hours after maturation. However, only 1 to 6% of reconstituted eggs receiving a blastomere from 8- to 16-cell embryos fertilized in vitro developed into a blastocyst in vitro.     

Sex determination of bovine embryo blastomeres by fluorogenic probes

One of the major challenges of using genetic information in marker assisted selection (MAS) is the detection of multiple marker loci from a small biopsy sample of a preimplantation stage embryo. The objective of this study was to develop a fast, nested, multiplex preamplification, polymerase chain reaction (PCR) method for the determination of sex in bovine embryo blastomeres. For this aim, ZFX/ZFY sequences were preamplified simultaneously with other genomic regions. The preamplification product was used as a template in an allelic discrimination assay, with nested primers and sex specific fluorogenic probes for ZFX and ZFY. Fluorogenic probes were used to eliminate the need for time consuming electrophoresis. Compared to sexing with Bovy/kappa-casein co-amplification method and other replicates from the same embryo, the accuracy of sexing with the use of fluorogenic probes after preamplification was 99% (112/113 blastomeres). The amplification efficiency was 96% (113/117 blastomeres).     

Production of identical mouse twins and a triplet with predicted gender

The aim of this study was to develop a method to generate identical twins and triplets with predicted gender. As a first step toward that aim, single blastomeres obtained from EGFP expressing eight-cell stage embryos and either diploid or tetraploid host embryos were used to compose chimera. We could follow the fate of EGFP expressing diploid blastomere derived cells in 3.5- and 4.5-day-old chimera embryos in vitro. We found that the diploid blastomere-derived cells had significantly higher chance to contribute to the inner cell mass if tetraploid host embryos were applied. After that, we developed a quick and reliable multiplex PCR strategy for sex diagnosis from single blastomeres by simultaneous amplification of the homologous ZFX and ZFY genes. By composed chimeras using single blastomeres, derived from sexed eight-cell stage embryos and a tetraploid host embryo, we could get preplanned sex newborns, wholly derived from these blastomeres. Among these mice, identical twins and a triplet were identified by microsatellite analysis. Unlike clones produced by nuclear transfer, these mice are identical at both the nuclear as well as mitochondrial DNA level. Therefore, the tetraploid embryo complementation method to produce monozygotic twins and triplets could be a valuable tool both in biomedical and agricultural applications.     

Preimplantation diagnosis of the β1 integrin knockout mutation as a model for aneuploid gene testing

The autosomal beta1 integrin knockout mouse mutation was selected as a model to experimentally determine preimplantation diagnosis test reliability for autosomal gene deletions and duplications. In experiment 1, which analyzed 198 individually disaggregated single blastomeres, the observed test frequencies matched the mathematically predicted frequencies calculated from the independently derived values of 90% normal allele amplification, 92% mutant allele amplification, 4% alternate allele contamination, and 4% failure to transfer amplifiable target DNA into the PCR reaction mix. This experiment correctly predicted a normal embryonic phenotype in 143 (99.3%) of the 144 phenotypically normal autosomal recessive results. Experiment 2 compared single biopsied blastomere test results to test results on the remaining embryonic cells cultured 1 week until trophoblast outgrowth. Single biopsied blastomere analysis correctly predicted a normal autosomal recessive phenotype in 87 (98%) of the 89 embryos that would have been selected for implantation. Experiment 3 compared the PCR results of two biopsied blastomeres tested independently to the PCR result from the remaining cultured blastomeres to improve test reliability. Given that embryos would have been implanted only when two normal results were obtained, 17 of 17 phenotypically normal embryos would have been implanted from among the 44 embryos tested. These experiment 3 results are consistent with the mathematical prediction that about 99.9% of embryos implanted with two unaffected biopsied blastomere results would have had a phenotypically normal genotype.     

Sex determination and milk protein genotyping of preimplantation stage bovine embryos using multiplex PCR

A method for determining the sex and milk protein genotypes (RFLPs) of preimplantation stage bovine embryos using multiplex polymerase chain reaction (PCR) is described. Day 6 to 7 embryos were micromanipulated to isolate 5 to 6 cells. These cells were then dried in reaction tubes for transport to the laboratory. Subsequently, two sets of PCRs were performed using Y chromosome, k-casein and beta-lactoglobulin gene specific primers, followed by electrophoretic analysis of the PCR products. The presence or absence of the Y chromosome was ascertained in 90 of 92 embryos. Moreover, the k-casein specific fragment was amplified and detected in all these embryos. The PCR products were digested in order to genotype the k-casein gene. In 70% of the embryos, the beta-lactoglobulin specific fragment was amplified, although together with some unspecific fragments.     

Efficient production of sex-identified and cryosurvived bovine in-vitro produced blastocysts

To establish a protocol for production of bovine in-vitro produced (IVP) blastocysts that were sex-identified and cryopreserved, we examined the sexing efficiency and accuracy of Day-3 and Day-4 embryos by polymerase chain reaction (PCR), the development of the biopsied embryos into Day-7 blastocysts and the freezability of these blastocysts by vitrification in gel-loading tips. One or two blastomeres were isolated from IVP embryos at either the 8-cell or 16-cell stage (Days 3 and 4, respectively) by a pressing-out method, and were then subjected to primer extension preamplification (PEP)-PCR. The successful sex-identification rate of biopsied samples amplified, purified and analyzed for sex by a second PCR (88.9%) was higher than that of those amplified and analyzed without purification (32.0%). Developmental rates into Day-7 blastocysts of biopsied embryos (Day-3, 65.5%; Day-4, 70.8%) were similar to those of non-biopsied control embryos (Day-3, 74.5%; Day-4, 65.1%). Total cell numbers and the inner cell mass (ICM) ratio of blastocysts derived from biopsied embryos were also comparable with those of control embryos. Blastocysts were vitrified-warmed in the presence of 20% DMSO, 20% ethylene glycol and 0.6M sucrose using gel-loading tips as containers. The proportions of biopsied blastocysts that were hatched or hatching rates after warming were high, regardless of the biopsy time (Day-3, 94.1%; Day-4, 91.9%), similar to the rates for control blastocysts (Day-3, 97.5%; Day-4, 96.9%). In conclusion, a protocol that allows sexing of Day-3 and Day-4 bovine embryos without compromising either the developmental ability to the blastocyst stage or freezability of Day-7 blastocysts was developed.     

Application of high-resolution melting for genotyping bovine mitochondrial DNA

Recent studies have demonstrated that mitochondrial DNA (mtDNA) haplotype has a significant impact on the efficiency of bovine somatic cell nuclear transfer. Conventional methods for detecting mtDNA variations and haplotypes, such as restriction fragment length polymorphism (RFLP), temporal temperature gradient gel electrophoresis, dHPLC and sequencing, are labor intensive or expensive and have low sensitivity. High-resolution melting (HRM) analysis is a new technique for mutation detection and has the advantages of speed, cost, and accuracy. Here, we describe the genotyping of bovine mtDNA using HRM analysis. DNA samples containing mtDNA were extracted from 75 Holstein cows and subjected to rapid-cycle (<20 min) PCR of small amplicons (<120 bp) using specific primer sets. Capillaries containing the PCR products were then subjected to HRM analysis; data were acquired in 2 min and analyzed using the instrument's software. Five common bovine mtDNA single nucleotide polymorphisms were identified: 9602 G>A, 169 A>G, 166A>G with 173A>G, and 363C>G. These results agree with both sequencing and RFLP analysis. In addition, a very small amount of heteroplasmic variants (<5%) was sufficiently to be distinguished by HRM analysis that would be very useful to differentiate heteroplasmy vs. homoplasmy. HRM analysis thus provides a new approach to genotyping bovine mtDNA sequence variations and has many advantages over other methods, including speed of analysis, cost, and accuracy. We believe this will be a valuable technique for determining the efficiency of nuclear transfer in cloned embryos and for studying maternal effects on nuclear-cytoplasm interactions.     

Rapid sexing of bovine preimplantation embryos using polymerase chain reaction: production of calves with predetermined sex under field conditions

Two to four blastomere size biopsies were obtained from each 6-day-old embryo of zebu and crossbred cattle for sex determination. The sex of the embryos was determined with a set of bovine Y-chromosome specific primer pairs by using polymerase chain reaction. Thirty two biopsied embryos after their sex was determined, when transferred fresh to synchronized recipients, resulted in 56.2% pregnancy rate. Sixteen healthy calves were born at full term, while 2 heifers aborted at mid-term from fresh embryo transfer. Simultaneously, 44 biopsied embryos which were kept frozen, were thawed at a later date and transferred to the previously synchronized recipients, thereby leading to 24 pregnancies (54.5%). Twenty-three healthy calves were born at full term, while 1 heifer aborted at mid-term from frozen-thawed embryo transfer. The pregnancy rates from both fresh and frozen-thawed biopsied embryos were comparable with that of controls (P > 0.05). Except for a single misidentification of a male calf as a female by our PCR assay (2.6%), the phenotypic sex of all the live born calves as well as the aborted fetuses was correctly matched with the PCR detection.     

The kinetics of donor cell mtDNA in embryonic and somatic donor cell-derived bovine embryos

The mechanisms controlling the outcome of donor cell-derived mitochondrial DNA (mtDNA) in cloned animals remain largely unknown. This research was designed to investigate the kinetics of somatic and embryonic mtDNA in reconstructed bovine embryos during preimplantation development, as well as in cloned animals. The experiment involved two different procedures of embryo reconstruction and their evaluation at five distinct phases of embryo development to measure the proportion of donor cell mtDNA (Bos indicus), as well as the segregation of this mtDNA during cleavage. The ratio of donor cell (B. indicus) to host oocyte (B. taurus) mtDNA (heteroplasmy) from blastomere(NT-B) and fibroblast(NT-F) reconstructed embryos was estimated using an allele-specific PCR with fluorochrome-stained specific primers in each sampled blastomere, in whole blastocysts, and in the tissues of a fibroblast-derived newborn clone. NT-B zygotes and blastocysts show similar levels of heteroplasmy (11.0% and 14.0%, respectively), despite a significant decrease at the 9-16 cell stage (5.8%; p<0.05). Heteroplasmy levels in NT-F reconstructed zygotes, however, increased from an initial low level (4.7%), to 12.9% (p<0.05) at the 9-16 cell stage. The NT-F blastocysts contained low levels of heteroplasmy (2.2%) and no somatic-derived mtDNA was detected in the gametes or the tissues of the newborn calf cloned. These results suggest that, in contrast to the mtDNA of blastomeres, that of somatic cells either undergoes replication or escapes degradation during cleavage, although it is degraded later after the blastocyst stage or lost during somatic development, as revealed by the lack of donor cell mtDNA at birth.     

Generation of transgenic rabbits by the novel technique of chimeric somatic cell cloning

A novel technique of chimeric somatic cell cloning was applied to produce a transgenic rabbit (NT20). Karyoplasts of transgenic adult skin fibroblasts with Tg(Wap-GH1) gene construct as a marker were microsurgically transferred into one, previously enucleated, blastomere of 2-cell non-transgenic embryos, while the second one remained intact. The reconstructed embryos either were cultured in vitro up to the blastocyst stage (Experiment I) or were transferred into recipient-females immediately after the cloning procedure (Experiment II). In Experiment I, 25/102 (24.5%) embryos formed blastocysts from whole embryos and 46/102 (44.12%) embryos developed to the blastocyst stage from single non-operated blastomeres, while the reconstructed blastomeres were damaged and degenerated. Thirteen (12.7%) embryos did not exceed 3- to 4-cell stages and 18 (17.7%) embryos were inhibited at the initial 2-cell stage. Out of 14 blastocysts which were subjected to molecular analysis, the transgene was detected in the cells of 4 blastocysts. In Experiment II, 163/217 (75.0%) embryos were transferred into 9 pseudopregnant recipient-rabbits (an average of 18 embryos per recipient). Four recipient-females (44.4%) became pregnant and delivered a total of 24 (14.7%) pups. Molecular analysis confirmed that two pups (1.2%), one live and one stillborn, showed a positive transgene signal. Live transgenic rabbit NT20 appeared healthy and anatomically as well as physiologically normal. The results of our experiments showed that transgenic adult skin fibroblast cell nuclei, which have been introduced into the cytoplasmic microenvironment of single enucleated blastomeres from 2-cell stage rabbit embryos, are able to direct the development of chimeric embryos not only to the blastocyst stage but also up to term.     

Cloning and sequencing of buffalo male-specific repetitive DNA: sexing of in-vitro developed buffalo embryos using multiplex and nested polymerase chain reaction

Buffalo Y-chromosome specific repetitive DNA (BuRY.I) was cloned and sequenced in order to develop a sensitive method for sexing of buffalo preimplantation stage embryos using polymerase chain reaction (PCR). A highly sensitive and reliable sex determination assay using a primary (BRY.I), nested (BuRYN.I) and multiplex (BuRYN.I, ZFX/ZFY) PCR was developed. The BRY.I and BuRYN.I primers are targeted to amplify Y-specific sequences, while the ZFX/ZFY loci was amplified to serve as a positive control for both male and female samples. Accuracy of the sex determination assay was initially verified with genomic DNA obtained from blood of known gender. Further sensitivity and reproducibility of the assay was examined using DNA obtained from 1 or 2 blastomeres to demi embryos. Altogether, 80 IVF-derived embryos ranging from the 2 to 4 cell to the blastocyst stage were used for sex determination. Definite and clear signals following PCR amplification were obtained from all embryo samples. Accuracy of assays was determined by comparing results from a single cell with those of blastocyst stage embryos, thereby indicating that 1 or 2 blastomeres from a preimplantation buffalo embryo is sufficient for sex determination by PCR. No misidentification was observed within the embryo samples using nested (BuRY.I), primary (BRY.I) and multiplex (BuRYN.I; ZFX/ZFY) PCR, suggesting that this technique is a highly reliable method for sexing buffalo embryos.     

Chromosomal diagnosis in each individual blastomere of 5- to 10-cell bovine embryos derived from in vitro fertilization

Chromosomal normality and sex were diagnosed in each blastomere of bovine embryos derived from in vitro fertilization (IVF). Bovine embryos developing to the 5- to 10-cell stage were separated into individual blastomeres with 0.5% protease. After treatment with 100 ng/mL vinblastine sulfate for 8 to 10 h, they were prepared for chromosome samples. In total, 33 bovine embryos and 185 blastomeres were examined. Chromosomal normality was analyzed in 43.8% (81/185) of the blastomeres and 60.6% (20/33) of the embryos; while chromosomal anomalies were found in 16 (80%, 16/20) of the embryos, 5 haploid embryos and 11 mosaic (n/2n) embryos. Mosaicism characteristic of the opposite sex in X-and Y-chromosomes was found in 2 haploid embryos, and that of a Y-chromosome and of XX chromosomes in 1 n/2n embryo. Various sex-chromosome compositions were also observed in the other 10 chromosomal mosaic n/2n embryos.     

Effects of the removal of cytoplasm on the development of early cloned bovine embryos

Oocyte cytoplasm plays a prominent role in cloned embryonic development. To investigate the influence of oocyte cytoplasmic amount on cloned embryo development, we generated bovine somatic cell nuclear transfer (SCNT) embryos containing high (30-40% of the cytoplasm was removed), medium (15-25% of the cytoplasm was removed) and low (<10% of the cytoplasm was removed) nucleocytoplasmic volume ratios (N/C) using enucleated metaphase II oocyte as recipient, and fibroblast as donor nucleus, and analyzed the expression levels of ND1, Cytb and ATPase6, as well as the embryonic quality. The results indicated: (1) the process of embryonic development was not influenced by <40% of cytoplasm removal; (2) the rate of blastocyst formation, the total number of blastomere and the ratio of ICM to TE were inversely proportional to the N/C; (3) SCNT embryos with reduced volume equal to 75-85% or >90% of an intact oocyte volume showed similar karyotype structure of the donor cells; (4) the number of mtDNA copy was larger in low N/C embryos than that in medium or high N/C embryos, and the expression levels of each gene hardly varied from the 2-cell to 8-cell stage, while the expression levels increased dramatically at the blastocyst stage; (5) from 16-cell to the blastocyst stage, the change of the expression level of each gene was not significant between low N/C embryos and IVF embryos, but it was more significant than those of high or medium N/C embryos. The results suggest that the decrease of mtDNA copy number and mitochondrial gene expression may be related to the impairment in early embryonic development, and removal of <10% adjacent cytoplasm volume may be optimal for bovine SCNT embryo development.