Rapid sexing of bovine preimplantation embryos using loop-mediated isothermal amplification

Loop-mediated isothermal amplification (LAMP) is a novel DNA amplification method that amplifies a target sequence specifically under isothermal conditions. The product of LAMP is detected by the turbidity of the reaction mixture without electrophoresis. The objective of this study was to develop a rapid sexing method for bovine preimplantation embryos using LAMP. The first experiment was conducted to optimize the DNA extraction method for LAMP-based embryo sexing. The DNA of single blastomeres was extracted using three methods: heat, NaOH, and proteinase K-Tween 20 (PK-TW) treatments. Sexing was performed with two LAMP reactions, male-specific and male-female common reaction, after DNA extraction. The rates of correct determination of sex were 88.9-94.4%, with no difference among methods. The sensitivity and accuracy of LAMP-based embryo sexing were evaluated in the next experiment. The proportion of samples in which the sex was correctly determined was 75-100% for one to five biopsied cells. Lastly, in vivo-derived embryos were examined to verify the usefulness of LAMP-based embryo sexing, and some of these fresh, sexed embryos were transferred into recipient animals. The time needed for sexing was <1 h. The pregnancy rate was 57.4% and all calves born were of the predicted sex (12 male and 21 female). Therefore, LAMP-based embryo sexing accurately determined gender and is suitable for field application.     

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.     

Detection of microinjected genes in bovine preimplantation embryos with combined DNA digestion and polymerase chain reaction

We have developed a simple digestion-polymerase chain reaction (PCR) assay for a simultaneous transgene detection and sexing of pronucleus-injected bovine preimplantation embryos. Bovine embryos were microinjected with dam-methylated gene construct and cultured in vitro for 6–7 days after the injections. The developed blastocysts and compact morulae were bisected and the embryonic biopsies representing mainly trophoblasts were subjected to the digestion-PCR, while the biopsied embryos remained in culture. Embryonic DNA was released with proteinase K and the samples were digested with a Dpnl-Bal31 mixture before the PCR amplification of the transgene, bovine αS1-casein, and bovine Y-chromosome fragments in the same reaction. The whole assay from biopsy to electrophoresis took less than 6 hr. The digestion removed up to 50 fg of dam-methylated transgene copies (unintegrated or contaminants) and also a few hundred copies of contaminating PCR products from the embryonic samples. The digestion-PCR assay eliminated all transgene contaminations from noninjected blastocysts, which were exposed to the microinjection DNA during the stay in injection chambers, and reduced the amount of transgene-positive embryos among pronucleus-injected blastocysts as compared with unmodified PCR. Analysis of 486 microinjected bovine embryo biopsies in 13 separate experiments revealed that we were able to sex 398 (82%) of the biopsies and 77 (19%) of the biopsies were scored as transgene positive and 57 (14%) as transgene questionable. Upon reanalysis of 41 of the biopsied embryos, 38 (93%) of the embryos were observed to be transgene negative and 2 questionable in both assays and uneven distribution of transgene copies was observed in one embryo. The results from sexing were in accordance with biopsies and remaining embryos in 38 (93%) of the embryos. © 1996 Wiley-Liss, Inc.     

PCR-sexing of bovine embryos: a simplified protocol

To make bovine embryo sexing under farm conditions more feasible we developed a simplified protocol utilizing manual biopsy and detection of the Y chromosome directly from polymerase chain reaction (PCR) reaction tubes. Twenty-four embryos (morulae and blastocysts) were biopsied manually into 2 to 4 samples. One sample of each original embryo was diagnosed for sex, based on restriction fragment length polymorphism of PCR-amplified DNA of the ZFX/ZFY locus. The remaining 44 samples were diagnosed using the tube detection assay. In this assay the biopsies were pipetted into 0.5 -ml reaction tubes containing lysis mixture, incubated 10 to 60 min at 37 degrees C and inactivated 10 min at 98 degrees C. Then the PCR mixture was added containing buffer, DNA polymerase, ethidium bromide and primers designed to amplify the highly repeated btDYZ-1 region of the bovine Y chromosome. After 50 cycles of PCR, the reaction tubes were examined under UV illumination for pink fluorescence indicating the presence of Y-chromosomal DNA. All sexing results from the replicates were in agreement with the ZFX/ZFY assay, with 12 of the original embryos diagnosed as females and 12 as males. We conclude that highly efficient and accurate PCR-sexing of embryos can be accomplished without the use of micromanipulators, control primers and electrophoresis. The 2 reaction mixtures needed for sex diagnosis can be stored at -20 degrees C and -196 degrees C, respectively. The tube detection assay minimizes the risk of carryover contamination by previously amplified products as there is no need to open the tubes following PCR.     

Sex determination of buffalo embryos (Bubalus bubalis) by polymerase chain reaction

The aim of this study was to identify a simple, rapid method for sex determination of in vitro produced buffalo embryos, amplifying Y-chromosome-specific repeat sequences by polymerase chain reaction (PCR). Buffalo oocytes collected from slaughtered animals were matured, fertilised and cultured in vitro for 7 days. On day 7 embryos were evaluated and divided in to six groups according to developmental stage (2, 4, 8, 16 cells, morulae and blastocyst). Each embryo was stored singly in phosphate-buffered saline at -20 degrees C until PCR. Two different methods of extraction of DNA were compared: a standard procedure (ST), using a normal extraction by phenol-chloroform, isoamyl alcohol and final precipitation in absolute ethanol and a direct procedure (DT), using a commercial kit (Qiaquik-Qiagen mini blood). A pair of bovine satellite primers and two pairs of different bovine Y-chromosome-specific primers (BRY4.a and BRY.1) were used in the PCR assay on embryos and on whole blood samples collected from male and female adult buffaloes, used as control. The trial was carried out on 359 embryos (193 for ST and 166 for DT). When DNA samples from blood were amplified, the sex determined by PCR always corresponded to the anatomical sex. Embryo sexing was not possible in two embryos in ST and one embryo in DT. Both extraction protocols recovered sufficient quantities of target DNA at all developmental stages, but the time required for the ST (24 h) limits its use in embryo sexing and supports the use of commercial extraction kits (5 h).     

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.     

两温度梯度多重PCR鉴别牛早期胚胎性别的技术研究

稳定、可靠和快速的牛胚胎性别鉴定方法在生产应用中具有重要意义。通过两温度梯度PCR方法对牛基因组、克隆胚胎、胚胎样品进行性别鉴别实验研究,建立了稳定、简便、快速的牛早期胚胎性别鉴别两温度梯度PCR方法,鉴定时间仅为57分钟。采用两温度梯度PCR方法对30枚奶牛胚胎进行了早期性别鉴别,并将鉴别的15枚胚胎（11枚为雌性,4枚为雄性）移植到同期处理的15头受体母牛体内。60天后妊娠检查,有7个受体成功受孕,5头受体怀孕晚期流产,流产犊牛全部为母犊。结果产下1公1母两头犊牛,流产个体与出生个体的性别与PCR鉴别结果完全相符。      

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.     

Sexing and detection of gene construct in microinjected bovine blastocysts using the polymerase chain reaction

We present a polymerase chain reaction (PCR)-based procedure for rapid bovine embryo sexing and classifying embryos for the presence of exogenous DNA. Fourteen bovine blastocysts microinjected with gene construct DNA at the pronuclear stage were divided into quarters and subjected to amplification with construct-specific and sex gene-specific (ZFY/ZFX) primers in the same initial PCR reaction. Blastocysts carrying microinjected construct DNA could be identified by the presence of construct-specific PCR product in approximately 4 h. Approximately half of the microinjected and two of 16 non-microinjected blastocysts typed PCR-positive for the construct DNA. Owing to erroneous amplifications in the two non-microinjected control blastocysts, and the inability of the system to distinguish integrated from non-integrated copies of the microinjected construct, the number of construct-positive blastocysts determined in our assay most likely overestimates the number of true transgenic embryos. Nevertheless, using this assay, we were able to determine that approximately half of the microinjected embryos were negative for the transgene construct and thus could be eliminated from transfer to a recipient cow. Embryo sexing was achieved in less than 6 h by restriction fragment length polymorphism analysis of nestedZFY/ZFXPCR products reamplified from initial PCR reactions. In 11/14 microinjected blastocysts all sections assayed unambiguously as the same sex. In one embryo, only one section was analysed, while two other blastocysts whowed some discrepancies of sexing results between the sections analysed. The approach employed here to determine the sex and presence of microinjected construct DNA in bovine preimplantation embryos is rapid, accurate among different sections of an embryo and can be used to increase the efficiency of current transgenic cattle production procedures.     

Sexing of murine and bovine embryos by developmental arrest induced by high-titer H-Y antisera

Murine and bovine embryos at the late morula stage were cultured in medium containing high-titer rat H-Y antisera. After 12h of incubation, embryos blocked at the late morulae stage were classified as males and those at the blastocyst stage were classified as females. Sexing of murine embryos by PCR and cytogenetics revealed that 83% of the embryos classified as males and 82% of those classified as females had their sex correctly predicted (P < 0.05). Bovine embryos were transferred to recipient females. Pregnancy rates were 71.4% (10/14) for embryos classified as males and 68.8% (11/16) for embryos classified as females. The sex was correctly predicted for 80% (8/10) of the embryos classified as males and for 81.8% (9/11) of those classified as females (overall accuracy, 80.9%, P < 0.05). Therefore, the induction of developmental arrest by high-titer male-specific antisera was an efficient strategy for non-invasive embryo sexing. The procedure was straightforward and has considerable commercial potential for sexing bovine embryos.     

Sexing using single blastomere derived from IVF bovine embryos by fluorescence in situ hybridization (FISH)

Fluorescence in situ hybridization (FISH) is a sensitive technique for molecular diagnosis of chromosomes on single cells and can be applied to sex determination of embryos. The objective has been to develop an accurate and reliable bovine Y chromosome-specific DNA probe in order to sex biopsed blastomeres derived from IVF bovine embryos by FISH. Bovine Y chromosome-specific PCR product derived from BtY2 sequences was labeled with biotin-16-dUTP (BtY2-L1 probe), and FISH was performed on karyoplasts of biopsed blastomeres and matched demi-embryos. Our FISH signal was clearly detected in nuclei of blastomeres of male embryos. FISH analysis of bovine embryos gave high reliability (96%) between biopsied blastomeres and matched demi-embryos. These results indicated that the BtY2-L1 bovine Y chromosome-specific FISH probe was an effective probe for bovine embryo sexing, and the FISH technique of probe detection could improve the efficiency and reliability.     

Sex determination of in vitro developed buffalo (Bubalus bubalis) embryos by DNA amplification

This study was conducted to determine the sex of buffalo embryos produced in vitro by amplifying male specific DNA sequences using the polymerase chain reaction (PCR). This method uses three different pairs of bovine Y-chromosome specific primers and a pair of bovine satellite specific primers. Buffalo in vitro fertilized embryos at the 4-cell to blastocyst stage were collected at days 3, 4, 6, and 8 postinsemination, and the sex of each embryo was determined using all three different Y-chromosome specific primers. The bovine satellite sequence specific primers recognize similar sequences in buffalo and are amplified both in males and in females. Similarly, Y-chromosome specific primers amplify the similar Y-chromosome specific sequences in male embryos of buffalo. Upon examining genomic DNA from lymphocytes of adult males and females, and embryos, the results demonstrate the feasibility of embryo sexing in buffaloes. Furthermore, sex determination by PCR was found to be a rapid and accurate method. © 1993 Wiley-Liss, Inc.     

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).     

Normal calves from transfer of biopsied, sexed and vitrified IVP bovine embryos

Data on biopsied, sexed and cryopreserved in vitro produced (IVP) bovine embryos, and their in vivo developmental competence are very limited. Two preliminary studies were conducted before the primary study. In Experiment 1, post-thaw in vitro developmental competence of biopsied and vitrified IVP embryos was evaluated using re-expansion as an endpoint. In Experiment 2, the pregnancy rates of biopsied fresh, frozen or vitrified embryos following single embryo transfer were compared. Since vitrified embryos resulted in a higher pregnancy rate than frozen-thawed embryos, in the primary study (Experiment 3), all IVP embryos were vitrified following biopsy and sexing (by DNA fingerprinting). In Experiment 3, we compared pregnancy initiation and calving results of heifers in the following treatments: 1) artificial insemination (AI); 2) AI plus contralateral transfer of a single embryo (AI + SET); 3) ipsilateral transfer of single embryo (SET); or 4) bilateral transfer of two embryos (DET). Birth weights, gestation lengths and dystocia scores were recorded. In Experiment 1, post-thaw re-expansion rate of biopsied and vitrified embryos was 85% (70/82). In Experiment 2, pregnancy rates (90 d) were 44% (7/16), 23% (3/13), and 50% (7/14) for vitrified, frozen and fresh embryos, respectively (P < 0.10). In Experiment 3, pregnancy rates of AI and SET were 65% (20/31) and 40% (16/40), respectively (P < 0.05). The pregnancy rate of AI + SET was 75% (27/36) with 11 carrying twins, and the pregnancy rate of DET was 72% (26/36) with 10 carrying twins. All AI fetuses were carried to term, but only half the SET fetuses were carried to term. Similar calving rates were observed in the AI + SET and DET groups, 76 and 70%, respectively, of those pregnant at Day 40. Mean birth weight, dystocia score and gestation length of AI calves were not different from those of SET calves. Mean birth weight and dystocia score of single-born calves were greater than those of twin born calves (P < 0.05). These data demonstrate that biopsied IVP bovine embryos can be successfully cryopreserved by vitrification and following post-thaw embryo transfer, acceptable rates of offspring with normal birth weights can be obtained without major calving difficulties.     

Amplification and application of the HMG box of bovine SRY gene for sex determination

A fast and reliable method for bovine sexing has been developed through amplification of the bovine high motility group (HMG) box of the sex-determining region of the Y chromosome gene (SRY). Oligonucleotide primers were designed according to the conserved bovine SRY HMG box sequence motif. In agarose gel electrophoresis, a normal bull showed 1 SRY band, and a normal cow showed no SRY band. After optimization, the PCR procedure for sex determination was applied to 14 embryo biopsies. The biopsied embryos were transferred into 14 recipient cows on the same day (day 7 of the estrus cycle) that the embryos were collected and sex of the calf was confirmed after parturition. Nine calves were born and anatomical sex corresponded to those sex determined by PCR in all cases (100% accuracy). Thus, this study showed for the first time that the present method can be applied in bovine breeding programs to facilitate manipulation of the sex ratio of offspring and also allows a quick diagnosis for the XY-bovine offspring by amplification of the HMG box of the bovine SRY gene.     

Sex determining of cat embryo and some feline species

Sex identification in mammalian preimplantation embryos is a technique that is used currently for development of the embryo transfer industry for zootechnical animals and is, therefore, a resource for biodiversity preservation. The aim of the present study was to establish a rapid and reliable method for the sexing of preimplantation embryos in domestic cats. Here we describe the use of nested PCR identify Y chromosome-linked markers when starting from small amounts of DNA and test the method for the purpose of sexing different species of wild felids. To evaluate the efficiency of the primers, PCR analysis were performed first in blood samples of sex-known domestic cats. Cat embryos were produced both in vitro and in vivo and the blastocysts were biopsied. A Magnetic Resin System was used to capture a consistent amount of DNA from embryo biopsy and wild felid hairs. The results from nested PCR applied on cat blood that corresponded to the phenotypical sex. Nested PCR was also applied to 37 embryo biopsies and the final result was: 21 males and 16 females. Furthermore, beta-actin was amplified in each sample, as a positive control for DNA presence. Subsequently, nested PCR was performed on blood and hair samples from some wild felines and again the genotyping results and phenotype sex corresponded. The data show that this method is a rapid and repeatable option for sex determination in domestic cat embryos and some wild felids and that a small amount of cells is sufficient to obtain a reliable result. This technique, therefore, affords investigators a new approach that they can insert in the safeguard programmes of felida biodiversity.     

Novel approach to cell sampling from preimplantation ovine embryos and its potential use in embryonic genome analysis

The major obstacle in the extensive analysis of the embryonic genome is the small number of cells typically obtained after the embryo biopsy. The object of the present study was to develop a simple approach that would allow the collection of a sufficient number of cells from a single embryo for use in further analyses. A micromanipulator was used to make a hole in the zona pellucida of 28 compacted morulae, 27 early blastocysts and 31 expanded blastocysts. After further culture, the trophoblastic cells, which herniated through this hole, were cut and cultured in vitro for different periods and used for embryo sexing. The results showed that biopsies can be taken successfully from 96.3% of early blastocysts, compared with 67.7% of expanded blastocysts and 71.4% of compacted morulae. The trophoblastic vesicles contained 20.8 +/- 6.7 cells (mean +/- SEM) and, when cultured, formed a confluent monolayer. The sex of cells cultured was assayed by PCR and the 12 lambs born after transfer of biopsied embryos confirmed its 100% accuracy. Moreover, no significant differences were found in the viability rates in vitro among blastocysts vitrified immediately after biopsy (77.8%), blastocysts biopsied and vitrified after 24 h culture (76.9%) and blastocysts vitrified without manipulation (88.5%). In experiments in vivo, the lambing rate of biopsied and vitrified blastocysts was significantly (P < 0.05) lower (40.0%) compared with vitrified control embryos (68.7%). This new approach to the biopsy of preimplantation embryos is a useful good model in the assisted reproductive technologies of domestic, wild and human species.     

Efficacy of a commercially available post-thaw bovine semen sexing kit in both single-ovulating and hyperstimulated cows

Currently, there are few inexpensive, reliable, effective methods for commercially separating X- and Y-chromosome bearing fresh and frozen bovine sperm. The objective of these experiments was to determine the efficacy of a commercially available post-thaw bovine semen sexing kit, HeiferPlus™ (HP) which claims to alter the sex ratio in favor of female calves following artificial insemination. Three trials included the insemination of hyperstimulated cows with Control or HP-treated semen, non-surgical embryo collection on Day 7, and a combined PCR/dot blot assay to determine embryo sex. Chi-square analysis showed that the Control group produced a greater proportion (p < 0.0005) of female embryos than the HP group. There were no differences in the proportions of transferable compared with degenerate embryos or in number of ovulations, embryos, and unfertilized ova collected from Control compared with HP groups. When treatments were combined, one of the two bulls used in the hyperstimulation studies produced an overall greater proportion of females (p < 0.05), suggesting a bull effect.Another trial involved the insemination of cows synchronized via OvSynch^® with fetal sexing via ultrasonography. Results of these studies indicated that HP semen sexing kit did not alter the sex ratio in favor of females in either hyperstimulated or single-ovulating cows; however, potential bull effects may be further evaluated to understand the capacity of HP with semen from specific bulls. Additionally, perhaps the sex of the surviving embryo can be manipulated by the maternal side, through ovarian, hormonal, oviductal, or uterine influences.     

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.