利用流式细胞仪建立牦牛X、Y精子分选体系的研究

旨在探索与优化牦牛精子分选条件,建立高效的牦牛X、Y精子分选技术体系。本研究制备了牦牛精液细胞悬液,采用不同量的DNA染料Hoechst33342和诱惑红共孵育精子细胞。利用流式细胞仪分选牦牛X、Y精子,通过比较分选效率、分选后精子活力及发育潜能,优化分选条件。运用RT-PCR检测分选精子的纯度,利用精子分析系统检测分选后精子的活力。将分选后的精子与体外成熟的卵母细胞进行体外受精,统计分选后精子的发育潜力,并采用SRY片段的PCR法检测早期胚胎的性别。结果显示,10 μL Hoechst33342染色40 min后的分选效果最佳,其分选产物的准确度和分选效率显著优于其他组,分选后的X、Y精子活力与20 μL Hoechest33342染色20 min组相当,显著高于其他组（P<0.05）。添加5 μmol·L^-1的诱惑红对分选的纯度无显著影响（P>0.05）,但能显著提高分选后精子的活力（P<0.05）。分选后X、Y精子分别与卵母细胞进行体外受精,受精率和囊胚形成率与未分选组差异不显著（P>0.05）,且胚胎性别比例与分选后精子纯度吻合。综上,本研究建立并优化了流式细胞仪分选牦牛X、Y精子的方法,添加诱惑红有助于改善分选后牦牛精子的活力,为后期牦牛性控精液的制备及生产奠定了基础。     

Validating bovine sexed semen samples using quantitative PCR

In cattle, separation of X‐ and Y‐bearing sperm cells by flow‐sorting technology makes it possible to predetermine the sex of calves. Due to high costs and decrease in fertilization, the extensive use of sexed semen in livestock depends heavily on sorting purity of sperm cells. Validating the accuracy of sperm sexing requires reliable procedures, therefore a real‐time polymerase chain reaction (PCR) assay was established to calculate the male cell proportion in the sexed semen based on the relationship between the amplification of a SRY fragment and an autosomal gene (MSHR) fragment. Our results showed stable amplification of SRY for 100–1 ng of genomic DNA, which allows detection of 1% of male cells if 100 ng of target DNA is used. To account for the discrepancy in the efficiency of the MSHR and the SRY amplification correction of the difference of the mean values was performed. The ratio of male to female sperm cells in unsexed semen cells was very accurately determined. The fractions of the sexed samples, however, were different from the expected range appearing lower than estimated. Thus, the study reveals that real‐time PCR provides a good basis for the examination of sexed sperm cells, but needs to be optimized for the samples.     

水牛精液中X和Y精子比率的鉴定

利用流式细胞仪分析水牛分离和未分离精液中精子的DNA含量,所得的直方图用高斯曲线拟合,分析计算出样本中X和Y精子的比率。结果表明:未分离的水牛精液中X精子的比率为50%,与正常水牛后代性别比率没有显著差异;而水牛的分离X精液样本中X精子占93%,分离Y精液样本中Y精子占89%。实验结果显示了流式细胞仪DNA分析法鉴定水牛精液中X和Y精子比率的可靠性,而流式细胞仪分离精子程序和方法在水牛上的应用是可靠而有效的。     

转基因牛与非转基因牛性控精液分离及配种效果初探

本研究对转基因牛以及非转基因牛精液经流式细胞仪分离冷冻后精子活力、分离准确率进行了比较,同时对分离的性控冷冻精液进行了人工输精,对受体牛的情期受胎率进行了统计分析。结果表明,转基因牛与非转基因牛精液在冷冻解冻后活力以及分离准确率方面差异不显著(P>0.05);转基因牛与非转基因牛的性控冷冻精液的情期受胎率分别为57.4%、59.3%,二者之间差异不显著(P>0.05)。     

性控奶山羊精液X和Y精子分离比例检测方法的建立

旨在建立可以定量计算奶山羊精液中X、Y精子数量的双重TaqMan荧光定量PCR方法,用以检测经过分离的奶山羊精液X和Y精子的数量和比例,为性控技术的开发和生产应用提供技术支撑.本研究选择X、Y染色体中特异基因F9及ZFY片段设计引物,建立标准曲线,优化荧光定量PCR反应体系和条件.通过对阳性标准品梯度稀释以及对60支已...     

Effect of separating bull semen into X and Y chromosome-bearing fractions on the sex ratio of resulting embryos.

Seventy-six, day 12 to day 15 bovine embryos, collected from 14 donors which had been inseminated with either X or Y chromosome-bearing spermatozoa fractions of semen separated by a thermal convection counterstreaming sedimentation and forced convection galvanization process, were processed for sexing by chromosomal analysis. Fifty-seven embryos were sexed; 20 from Y chromosome-bearing and 37 from X chromosome-bearing fractions of semen. Statistical analysis of the sexing data indicated that there was no significant difference in the male: female ratio for donors receiving male fractions compared to those receiving female fractions. The Y chromosome-bearing fractions produced a male: female ratio that was indistinguishable from the expected 1:1 ratio. However, the X chromosome-bearing fractions of semen produced a highly significant deviation from the expected 1:1 ratio towards the male.     

Economic effects of using sexed semen in Japanese dairy herds

Dairy farm agricultural income should increase when sexed semen is used instead of unsexed semen. This study simulated three scenarios: using unsexed semen (N), using X sperm of Holstein and unsexed semen of Japanese Black (H), and using X sperm of Holstein and Y sperm of Japanese Black (HJ). Two management scenarios were considered: conventional management (CONV); and the use of Japanese Black semen with surplus cows to produce F₁s where sufficient replacement female Holstein calves were obtained for maintenance (MAINT). In CONV, the agricultural incomes of H and HJ were 610 000–2 400 000 yen higher than that of N. The agricultural income increased when the difference in the prices between Holstein males and average F₁ male/female calves was 34 000–50 000 yen, that between Holstein male and female calves was 80 000–110 000 yen, and that between F₁ male and female calves was 50 000–90 000 yen. Therefore, the agricultural income can be increased by using sexed semen to select calves of a more valued breed and sex.     

奶牛性控冻精人工授精影响因素研究

用分离X和Y精子的性控精液进行人工授精是控制家畜性别之最简单可行的方法.然而,低密度性控精液输精效果还不如常规人工授精,许多技术环节都有待改进.以常规冻精和稀释常规冻精为对照,研究解冻方法、输精时间和部位、不同精液来源和输精员以及育成和经产牛等因素对性控冻精人工授精妊娠率的影响.结果显示,精液解冻水浴温度和持续时间对人工授精效果有显著影响,性控精液对解冻水浴温度更敏感;性控冻精和稀释常规冻精比常规冻精对输精时间要求更严格;3种精液输精到排卵卵泡同侧子宫角基部受胎率都显著高于输精于子宫体和同侧子宫角前端;3种精液育成牛受胎率(80%)都显著高于经产牛(50%);于输精同时注射促排卵素3号明显提高性控冻精受胎率;经严格挑选、能够从事胚胎移植操作的技术熟练输精员之间性控冻精受胎率差异不显著;在所设计的不同条件下,性控冻精与稀释同样倍数的常规冻精行为相似,说明精子分离过程没有对精子造成特殊损伤.研究结果说明,精确控制人工授精各个技术环节可以实现消除性控与非性控、低密度与高密度精演之间的差别,获得高妊娠率.     

Short‐Term Storage and Swim‐Up Selection Do Not Affect the X/Y Ratio in Equine Spermatozoa

The standard procedure of artificial insemination with fresh equine spermatozoa involves short‐term storage (to 48 h at 5°C). This procedure is accompanied by a gradual loss of sperm viability. The aim of this study was to investigate whether the X/Y ratio of equine spermatozoa is affected by short‐term storage and the swim‐up procedure. We used a standard protocol, for short‐term storage (0, 24 and 48 h at 5°C) of stallion semen diluted in the commercial extender EquiPro? (Minitüb GmbH, Tiefenbach, Germany). After each set‐up storage period, the motile fraction of sperm cells was selected by the swim‐up method. The X/Y ratio was evaluated by fluorescence in situ hybridization (FISH) in the fresh, non‐selected sperm, and in motile spermatozoa selected after each of the storage periods. Molecular probes for the equine chromosomes X and Y were used. The X/Y ratio in all sperm samples analysed in this study (fresh and stored) was not different from the theoretical 1 : 1 value. The incidence of chromosomally abnormal sperm cells in the fresh (0.28%) and motile (0.13%) sperm samples was not significantly different. The two approaches (sperm storage up to 48 h and the swim‐up procedure) applied to this study did not affect the X/Y ratio in the motile fraction of equine spermatozoa. This finding does not conform to phenomena described for human and cattle. For this reason, the finding may imply species‐related differences.     

Effect of Overnight Staining on the Quality of Flow Cytometric Sorted Stallion Sperm: Comparison with Tradtitional Protocols

Flow cytometry is considered the only reliable method for the separation of X and Y chromosome bearing spermatozoa in equines. The MoFlo SX DP sorter is highly efficient, allowing the production of foals of the desired sex. However, to achieve acceptable pregnancy rates the currently used protocol requires working with fresh semen obtained close to, or at, the sorting facility. An alternative protocol was tested during two consecutive breeding seasons. Fresh stallion semen was cooled for 20 h, during which staining with Hoechst 33342 took place. On the following day, this sample was flow sorted and compared with spermatozoa from the same ejaculate that had been sexed on the previous day. All sperm parameters evaluated remained unchanged when fresh sorted and refrigerated sorted semen were compared. Pre‐sorting storage at 5°C did not alter sperm velocities nor kinetics, viability or membrane permeability, production of reactive oxygen species, mitochondrial membrane potential or DNA fragmentation index of the sorted sample. The findings open for the possibility of using semen from stallions housed far from the sorting facilities. Processed and stained sperm could be shipped refrigerated on the previous day, sorted and inseminated on the next day.     

Recovery of sperms bearing X chromosomes with different concentrations of magnetic nanoparticles in ram

Pre-conceptual sex selection is still a highly debatable process whereby X and Y chromosome bearing spermatozoa are isolated before oocyte fertilization. Recently, magnetic nanoparticles (MNP) have been used to determine X and Y chromosomes bearing spermatozoa as a result of searching for a cheap, highly efficient method using non-toxic materials. This study aimed to recover the sperm bearing X chromosomes in ram with different concentrations of MNP and then evaluate the success of this method using polymerase chain reaction (PCR). Ram sperms were divided into four groups, treated with 0 (control), 50, 100 and 200 μg/ml MNP, respectively. MNP was used to restore sperm cells bearing X chromosomes. Upon recovery, the PCR was performed to identify the X and Y sperms, Methyl ThiazoleTetrazolium (MTT), to assess MNP toxicity and sperm viability and acridine orange (AO) to evaluate sperm DNA integrity. The results of PCR revealed that the treatment of spermatozoa- bearing X chromosomes with 50 μg/ml MNP had the highest effects on the recovery of X sperm rather than the other concentrations of MNP. However, the concentrations of MNP did not have any toxic effects on spermatozoa, sperm viability and, DNA integrity, but the high concentration of MNP (200 μg/ml) significantly reduced DNA integrity. According to MTT and AO results, the concentrations of MNP used in this study had no toxic effects on spermatozoa and did not reduce the sperm viability and DNA integrity, except that 200 μg/ml MNP significantly reduced DNA integrity.     

Generation of Sperms Containing EGFP‐LacZ Following Transfection of Chicken Testis with a Eukaryotic Dual Reporter Vector

Male germ cells modified by foreign genes can be used to generate transgenic chicken. In this study, in vivo transfection of chicken testis with an EGFP‐LacZ dual reporter expression vector was performed. Large‐scale plasmid DNA preparation of the EGFP‐LacZ eukaryotic expression vector was carried out and efficient transfection of chicken testicle cells using the prepared plasmid DNA was confirmed in vitro. The reporter plasmid was directly injected into adult rooster testes. Semen samples were collected on 10‐days post‐transfection and every other day thereafter; and a total of six collections were made. Semen slides were subjected to fluorescence microscopy and β‐galactosidase activity assay to identify sperms carrying the reporter genes. The presence of EGFP and LacZ was further confirmed by PCR amplification with sperm genomic DNA as template. The testicles of those birds were subjected to cryostat sectioning, fluorescence microscopy and β‐galactosidase activity assay. The results showed that sperms with green fluorescence were not observed on semen slides; however, sperms positive for β‐galactosidase were detected. Specific amplicons of EGFP and lacZ were detected in four of the six sequentially collected semen samples. Fluorescence microscopy of the corresponding semen slides revealed yellow‐green fluorescence, but not clear green fluorescence. The β‐galactosidase activity assay and GFP histochemistry using monoclonal antibodies demonstrated positive staining for subsets of testicle cells. Together, these results showed that direct injection of the dual reporter vector into adult rooster testis allowed in vivo transfection of chicken sperm precursor cells, which further developed into sperm containing EGFP‐LacZ.     

The Beltsville sperm sexing technology: high-speed sperm sorting gives improved sperm output for in vitro fertilization and AI

The Beltsville sperm sexing technology is currently the only effective means of altering the sex ratio of offspring in livestock. The method is based on the flow-cytometric separation of X- and Y-chromosome-bearing sperm based on X/Y DNA content difference. It is an effective means of producing progeny of predetermined sex in cattle, swine, sheep, and laboratory animals. The method involves treating sperm with a DNA-binding fluorochrome, Hoechst 33342, and flow-cytometrically sorting them into separate X and Y populations that can subsequently be used for surgical intratubal or intrauterine insemination, deep-uterine insemination, regular artificial insemination in some cases, in vitro fertilization to produce sexed embryos for transfer, and intracytoplasmic sperm injection of ova. Skewed sex ratios of 85 to 95% of one sex or the other have been repeatably achieved in most species. The method has been used worldwide to produce several hundred morphologically normal animal offspring of the predicted sex. It has also been validated in the laboratory using DNA reanalysis of the sorted sperm populations and by fluorescence in situ hybridization and PCR of individual sperm. We developed a new orienting nozzle that we have fitted to both conventional and high-speed cell sorters that have been modified for sperm sorting. Recently we completed the adaptation of the new orienting nozzle to a Cytomation MoFlo high-speed cell sorter modified for sperm. This adaptation of the nozzle has increased the overall production rate of sorted X and Y sperm from about .35 million/h to 5 or 6 million sperm/h (each population). Calves have been born from cows artificially inseminated using conventional technique and sexed sperm. In addition, numerous litters of pigs have been born after transfer of embryos produced from X or Y sorted sperm.     

Sexing sperm of domestic animals

The ability to preselect or predetermine the sex of offspring prior to conception is a highly desired technological tool for assisted female breeding programs specifically for milk production, and in males, for meat production and increasing livestock numbers. The current technology is based on the well-known differences in X- and Y-sperm in the amount of DNA. The technology uses modified flow cytometric instrumentation for sorting X- and Y-bearing sperm. The method can be validated on the basis of live births, laboratory reanalysis of sorted sperm for DNA content, and embryo biopsy for sex determination. Currently, the sex of animals has been predetermined with 90 % accuracy by sexing spermatozoa. In the bovine breeding industry, flow cytometric sperm sexing has not fulfilled its original promise. Sexed sperm doses are too expensive for widespread application while the fertility of sexed sperm doses is lower than unsexed ones. Essentially all bovine sexed semen is frozen and then applied through artificial insemination (AI) or in vitro fertilization. There is still a need in the animal breeding industry to develop a technique for sperm sexing that provides sufficient spermatozoa for AI doses, does not compromise sperm fertility, and is widely applicable to a range of species. In this review, we will summarize the current state-of-the-art in sex preselection in domestic animals and some wildlife species using flow cytometric sperm-sorting of X from Y sperm based on DNA differences.     

Application and Commercialization of Flow Cytometrically Sex-Sorted Semen

The current technology to sort X and Y chromosome bearing sperm population requires individual identification and selection of spermatozoa in a modified high-speed flow cytometer. For farm animal species, the technology is capable of producing sexed sperm at greater than 90% purity. However, only in the bovine, the technology has reached a developmental level that allows its commercial application. Meanwhile, the demand for female calves has grown rapidly, which encourages the demand for sex-sorted semen from high genetic value bulls. The success of the technology will depend mainly on the fertilizing capacity of the sorted spermatozoa, as this is the most affecting and economically relevant factor. To date, fertility is still variable and is quite dependant on post-sort processing. New processing techniques are under investigation and will likely be able to improve the fertility rates after AI with sex-sorted semen. It is of great importance to select the right bulls and to test the sorted samples on a routine basis. In addition to the demand for sex-sorted semen by the cattle industry, there is also a significant demand expressed by pig farmers. However, it is still unknown if the use of sex-sorted semen through commercial pig AI will be economically feasible. For the pig, the combination of in vitro fertilization with sexed semen and non-surgical embryo transfer is an alternative that merits further scientific attention. Recent developments in ovine AI and ET will make it very likely that commercial sheep industry will adopt the sexing technology in their breeding concepts.     

Effects of sex-sorted spermatozoa on the efficiency of in vitro fertilization and ultrastructure of in vitro produced bovine blastocysts

Frozen-thawed sexed semen from six bulls (Holstein) was used for studying their efficiency in an in vitro fertilization (IVF)-programme and to compare their ultrastructure with in vitro produced bovine blastocysts produced with non-sorted sperm. Progressive motility of sorted spermatozoa, their IVF rate, development of produced blastocysts and the ultrastructure of the blastocysts were analysed. The cleavage rates of sexed sperm of bulls (groups S1, S2 and S4) were significantly lower than that of unsorted control sperm (P < 0.01). Blastocyst development at day 7 of the sexed semen groups varied between 3.5% and 28.8% versus 33.6% for non-sexed semen. The individual blastocyst yield with sexed semen of group S5 (28.8%) was similar to the mean blastocyst production of the non-sexed control spermatozoa (C, 33.6%; P > 0.05). The remaining five sexed sperm groups resulted in significantly lower developmental rates of blastocysts on day 7 (S1, 4.9%; S2, 0%; S3, 0%, S4, 3.5%; S6, 25.8%, P < 0.01). Group S2 showed microbiological contamination in 50% (four of eight) and S3 in 100% of the experiments (eight of eight). Progressive motility of sexed sperm was significantly lower than that of unsorted sperm (S1, 48 +/- 12.0%; S2, 41 +/- 11.9%; S3, 39.0 +/- 9.9%; S4, 42 +/- 4.6%; P < 0.01; S5, 72 +/- 7.1% and S6, 64 +/- 9.3; P < 0.05 versus C 82 +/- 4.6%). The percentage of progressive motile spermatozoa showed a good correlation with the developmental capacity of blastocysts (r(2): >0.70), the regression parameter was significant (P < 0.01). Furthermore, with a straw containing 10 x 10(6) sexed spermatozoa significantly lower number oocytes was fertilized than with the same concentration of non-sexed sperm (P < 0.01). Our results demonstrate that the suitability of sperm sorting for in vitro fertilization (IVF) is lower than no sexed sperm. Our ultrastructural studies showed that blastocysts produced with flow-cytometrically sex-sorted spermatozoa possessed deviations in the number and structure of organelles like mitochondria, rough endoplasmic reticulum (ER) and nuclear envelope. These morphological alterations may be responsible for compromised development that observed in embryos produced with sex-sorted spermatozoa. Thus, we conclude that sperm sex sorting can markedly affect the efficiency of an IVF-programme.     

白绒山羊性控胚胎生产及移植应用研究初探

应用X性控冷冻精液对超排供体白绒山羊进行人工授精,生产性控胚胎并进行鲜胚移植。结果发现,①用性控冻精和鲜精输精的供体母羊,平均卵子回收数分别为13.3和12.5枚,其中性控冻精组受精卵比例为29.6%（55/186）,极显著低于鲜精组94.0%（281/299）的比例（P<0.01）;②性控胚胎和普通胚胎移植受体母羊产羔率分别为42.2% 和58.1% ,二者差异极显著（P<0.01）;③性控胚胎移植受体母羊所产羔羊雌性所占百分数为100%,极显著高于普通胚胎移植（P<0.01）。表明通过白绒山羊X、Y精子分离、人工授精生产性控胚胎,同时结合胚胎移植技术,可以达到按照生产实际中的意愿得到性别控制子代白绒山羊的目的。     

Genomic selection strategies in dairy cattle breeding programmes: Sexed semen cannot replace multiple ovulation and embryo transfer as superior reproductive technology

The aim of this study was to test whether the use of X-semen in a dairy cattle population using genomic selection (GS) and multiple ovulation and embryo transfer (MOET) increases the selection intensity on cow dams and thereby the genetic gain in the entire population. Also, the dynamics of using different types of sexed semen (X, Y or conventional) in the nucleus were investigated. The stochastic simulation study partly supported the hypothesis as the genetic gain in the entire population was elevated when X-semen was used in the production population as GS exploited the higher selection intensity among heifers with great accuracy. However, when MOET was applied, the effect was considerably diminished as was the exchange of females between the nucleus and the production population, thus causing modest genetic profit from using X-sorted semen in the production population. In addition, the effect of using sexed semen on the genetic gain was very small compared with the effect of MOET and highly dependent on whether cow dams or bull dams were inseminated with sexed semen and on what type of semen that was used for the bull dams. The rate of inbreeding was seldom affected by the use of sexed semen. However, when all young bull candidates were born following MOET, the results showed that the use of Y-semen in the breeding nucleus tended to decrease the rate of inbreeding as it enabled GS to increase within-family selection. This implies that the benefit from using sexed semen in a modern dairy cattle breeding scheme applying both GS and MOET may be found in its beneficial effect on the rate of inbreeding.     

奶牛性控精液品质检测及效果分析

本试验旨在利用精子分析仪对奶牛性控冷冻精液精子的运动性能及体外受精率进行分析。结果表明:性控精液精子活力及顶体完整率、前向性与常规精液相比差异显著(P<0.05);曲线速度、直线速度、平均路径速度、平均移动角度、前向性差异均不显著(P>0.05);体外受精率差异不显著(P>0.05)。结论:奶牛性控精液运动性能及受精率低于常规精液。     

New technique of sex preselection for increasing female ratio in boar sperm model

In this study, we tried to optimize the porcine semen extender conditions to maximize the differences between live X chromosome-bearing (X) spermatozoa and to Y chromosome-bearing (Y) spermatozoa without a decline in the fertility rate at different pH conditions during storage. We observed the viability of X and Y boar spermatozoa in acidic (pH 6.2), original (pH 7.2), and alkaline condition (pH 8.2) for 5 days to investigate the effect of storage conditions on the X to Y spermatozoa ratio. The functional parameters of spermatozoa were also examined to evaluate sperm quality. Sperm motility was preserved at pH 7.2 and pH 6.2 for 3 days, while sperm motility at pH 8.2 decreased significantly after 2 days. Non-capacitated spermatozoa increased while capacitated spermatozoa decreased during storage. Sperm viability decreased significantly duration-dependent under all pH conditions, but there was no significant difference during storage at pH 6.2 and 7.2. The X: Y ratio of live spermatozoa in acidic condition was maximized (1.2:1) without affecting the sperm function and fertility-related protein expression after 2 days compared to original conditions. Moreover, insemination of sows using acidic extender increased the number of female pups on days 1 and 2 of preservation. These results indicate that the production of female offspring may increase when acidic BTS is used for 2 days without affecting the success rate of AI. Above all, this method is simple and economical compared to other methods.