Successful laparoscopic insemination with a very low number of flow cytometrically sorted boar sperm in field conditions

The aim of this study was to develop a useful procedure for laparoscopic insemination (LI) with sex-sorted boar spermatozoa that yields adequate fertility results in farm conditions. In experiment 1, we evaluated the effects of single (oviducts) and double (oviducts and tips of the uterine horns) LI with X-sorted sperm on the reproductive performance of sows. Sows (N = 109) were inseminated once as follows: (1) single LI with 0.5 × 10⁶ unsorted sperm per oviduct; (2) single LI with 0.5 × 10⁶ sex-sorted sperm per oviduct; or (3) double LI with 0.5 × 10⁶ sex-sorted sperm per oviduct and 0.5 × 10⁶ sex-sorted sperm per uterine horn. The farrowing rates were lower (P < 0.05) in sows inseminated with sex-sorted sperm (43.2% and 61.9% for the single and double insemination groups, respectively) than in sows from the unsorted group (91.3%). Within the sex-sorted groups, the farrowing rate tended (P = 0.09) to be greater in sows inseminated using double LI. There were no differences in the litter size among groups. In experiment 2, we evaluated the effect of the number of sex-sorted sperm on the reproductive performance of sows when using double LI. Sows (N = 109) were inseminated with sex-sorted sperm once using double LI with: (1) 0.5 × 10⁶ sperm per oviduct and 1 × 10⁶ sperm per uterine horn; or (2) 1 × 10⁶ sperm per oviduct and 2 × 10⁶ sperm per uterine horn. Similarly high pregnancy (90%) and farrowing (80%) rates were achieved in both groups. The sows inseminated with the highest number of sperm tended (P = 0.09) to have more piglets (10.8 ± 0.7 vs. 9.2 ± 0.6). A high female proportion (number of female births divided by the total of all births ≥0.92) was obtained in both experiments using X-sorted sperm. Our results indicate that the double LI procedure, using between 3 and 6 × 10⁶ sex-sorted sperm per sow produces adequate fertility at the farm level, making sperm-sexing technology potentially applicable in elite breeding units.     

Non-surgical deep intra-uterine transfer of in vitro produced porcine embryos derived from sex-sorted frozen-thawed boar sperm

Embryos and offspring of a pre-determined sex have been produced in pigs using AI and IVF with unfrozen sperm, and after surgical insemination with sex-sorted frozen-thawed sperm. The aims of this study were to demonstrate that sex-sorted frozen-thawed boar sperm could be incorporated into pig IVF for the production of embryos of a pre-determined sex and that these embryos could be successfully non-surgically transferred. Oocytes were matured in vitro, fertilised with either unsorted or sex-sorted frozen-thawed sperm and cultured until the eight-cell stage. These embryos were then transferred to recipients (n = 7) non-surgically (n = 70 embryos per sow). Oocyte cleavage was similar between sex-sorted (1538/5044; 30.5%) and unsorted (216/756; 28.6%) frozen-thawed sperm, and PCR sex-determination of the embryos confirmed that they were of the predicted sex (n = 16). Delayed return to oestrus (>23 days) was observed in five recipient sows (71.4%). Fetal sacs were observed by transcutaneous ultrasound on Day 18 in one of these sows. Pre-sexed porcine IVP embryos can be successfully produced using sex-sorted frozen-thawed boar sperm, and these embryos are capable of initiating pregnancies when transferred to recipients. However, further refinement of porcine ET protocols are required to enable development to term.     

Pregnancy loss in heifers after artificial insemination with frozen-thawed,sex-sorted,re-frozen-thawed dairy bull sperm

The use of sex-sorted sperm by the dairy industry is often limited by the geographical distance between potential sires and the sex-sorting facility. One method that may be used to overcome this limitation is sex-sorting sperm that have been previously frozen, or transported to the sorting facility as cooled liquid semen. In this study the in vivo fertility of frozen-thawed, sex-sorted, re-frozen-thawed (FSF) and cooled, sex-sorted, frozen-thawed (CSF) bull sperm was determined after artificial insemination (AI) of Holstein heifers. Semen from two bulls was frozen in straws, or transported to the sorting facility in an egg yolk diluent at 5 °C over 24 h. Thawed or re-warmed semen was processed through a PureSperm^® density gradient, and sperm were sorted for sex and frozen (2 or 4 × 10⁶ sperm/straw). Synchronised heifers (n = 183) were inseminated with either non-sorted control sperm (Control; 20 × 10⁶ dose) or with FSF or CSF ‘X’ sperm (2 or 4 × 10⁶/dose). Pregnancy rates (detected at 7–9 weeks) after AI with control sperm were higher than with FSF or CSF sperm (57.4 vs. 4.1 and 7.3% respectively; p < 0.001). There was a significant difference between bulls (Bull 1: Control 63.0%, FSF 8.6%, CSF 10.0%; Bull 2: Control 45.5%, FSF 0%, CSF 4.8%; p = 0.001). Five out of six (83.3%) pregnancies produced with sexed sperm were lost after pregnancy diagnosis. The exception was one heifer inseminated with CSF sperm (2 million sperm dose), which produced a heifer calf. In the non-sorted control group, three pregnancies were lost (8.3%) and three stillbirths occurred (8.3%). The low fertility and high rate of pregnancy loss in the sexed groups, in addition to environmental influences, may be attributed to impaired sperm function caused by sex-sorting and re-freezing, leading to poor embryo quality or altered gene expression. More precise timing of insemination and higher sperm doses might improve the fertility of FSF sperm. Moreover, the in vitro function of double-frozen sexed compared with non-sorted sperm requires further investigation.     

Low dose insemination of mares using non-sorted and sex-sorted sperm.

Mares are generally inseminated with 500 million progressively motile fresh sperm and approximately 1 billion total sperms that have been cooled or frozen. Development of techniques for low dose insemination would allow one to increase the number of mares that could be bred, utilize stallions with poor semen quality, extend the use of frozen semen, breed mares with sexed semen and perhaps reduce the incidence of post-breeding endometritis. Three low dose insemination techniques that have been reported include: surgical oviductal insemination, deep uterine insemination and hysteroscopic insemination.Insemination techniques: McCue et al. [J. Reprod. Fert. 56 (Suppl.) (2000) 499] reported a 21% pregnancy rate for mares inseminated with 50,000 sperms into the fimbria of the oviduct.Two methods have been reported for deep uterine insemination. In the study of Buchanan et al. [Theriogenology 53 (2000) 1333], a flexible catheter was inserted into the uterine horn ipsilateral to the corpus luteum. The position of the catheter was verified by ultrasound. Insemination of 25 million or 5 million spermatozoa resulted in pregnancy rates of 53 and 35%, respectively. Rigby et al. [Proceedings of 3rd International Symposium on Stallion Reproduction (2001) 49] reported a pregnancy rate of 50% with deep uterine insemination. In their experiment, the flexible catheter was guided into position by rectal manipulation.More studies have reported the results of using hysteroscopic insemination. With this technique, a low number of spermatozoa are placed into or on the uterotubal junction. Manning et al. [Proc. Ann. Mtg. Soc. Theriogenol. (1998) 84] reported a 22% pregnancy rate when 1 million spermatozoa were inserted into the oviduct via the uterotubal junction. Vazquez et al. [Proc. Ann. Mtg. Soc. Theriogenol. (1998) 82] reported a 33% pregnancy rate when 3.8 million spermatozoa were placed on the uterotubal junction. Recently, Morris et al. [J. Reprod. Fert. 188 (2000) 95] utilized the hysteroscopic insemination technique to deposit various numbers of spermatozoa on the uterotubal junction. They reported pregnancy rates of 29, 64, 75 and 60% when 0.5, 1, 5 and 10 million spermatozoa, respectively, were placed on the uterotubal junction.Insemination of sex-sorted spermatozoa: One of the major reasons for low dose insemination is insemination of X- or Y-chromosome-bearing sperm. Through the use of flow cytometry, spermatozoa can be accurately separated into X- or Y-bearing chromosomes. Unfortunately, only 15 million sperms can be sorted per hour. At that rate, it would take several days to sort an insemination dose containing 800 million to 1 billion spermatozoa. Thus, low dose insemination is essential for utilization of sexed sperm. Lindsey [Hysteroscopic insemination with low numbers of fresh and cryopreserved flow-sorted stallion spermatozoa, M.S. Thesis, Colorado State University, Fort Collins, CO, USA, 2000] utilized either deep uterine insemination or hysteroscopic insemination to compare pregnancy rates of mares inseminated with sorted, fresh stallion sperm to those inseminated with non-sorted, fresh stallion sperm. Hysteroscopic insemination resulted in more pregnancies than ultrasound-guided deep uterine insemination. Pregnancy rate was similar for mares bred with either non-sorted or sex-sorted spermatozoa.In a subsequent study, Lindsey et al. [Proceedings of 5th International Symposium on Equine Embryo Transfer (2000) 13] determined if insemination of flow-sorted spermatozoa adversely affected pregnancy rates and whether freezing sex-sorted spermatozoa would result in pregnancies. Mares were assigned to one of four groups: group 1 was inseminated with 5 million non-sorted sperms using hysteroscopic insemination; group 2 was inseminated with 5 million sex-sorted sperms using hysteroscopic insemination; group 3 was inseminated with non-sorted, frozen-thawed sperm; and group 4 was inseminated with sex-sorted frozen sperm. Pregnancy rates were similar for mares inseminated with non-sorted fresh sperm, sex-sorted fresh sperm and non-sorted frozen sperm (40, 37.5 and 37.5%, respectively). Pregnancy rates were reduced dramatically for those inseminated with sex-sorted, frozen-thawed sperm (2 out of 15, 13%). These studies demonstrated that hysteroscopic insemination is a practical and useful technique for obtaining pregnancies with low numbers of fresh spermatozoa or low numbers of frozen-thawed spermatozoa. Further studies are needed to determine if this technique can be used to obtain pregnancies from stallions with poor semen quality. In addition, further studies are needed to develop techniques of freezing sex-sorted spermatozoa.     

Functional integrity of sex-sorted, frozen-thawed boar sperm and its potential for artificial insemination

Despite being developed in its present form 20 years ago, sex-sorting of mammalian sperm is still a work in progress. While relatively successful in cattle and sheep, the unique challenges of incorporating sex-sorted sperm into pig production have not yet been overcome. Generally speaking, boar sperm survive freeze-thawing less well and are required in larger numbers for insemination, while in vitro embryo production of pig embryos is less successful compared to other domestic species [Niemann H, Rath D. Progress in reproductive biotechnology in swine. Theriogenology 2001;56:1291-1304]. Due to the large number of sperm required for artificial insemination in pigs, a technique of storing sperm after sorting must be developed while adequate numbers of sperm are allocated into X- or Y-chromosome-bearing enriched pools. Cryopreservation is perhaps the ideal method of storage between sorting and insemination, as it allows unlimited time to build up a sperm bank, whereas liquid-storage requires the use of sperm within days of sorting. The limited number of studies investigating the survivability of sex-sorted, frozen-thawed boar sperm have produced promising in vitro results but poor in vivo outcomes. Before fertility can be improved, the causes of any damage to sperm function during the sex-sorting and freeze-thawing procedures must be more fully understood. Once defined, the source of damage may be minimised and this would lead to increased success rates after in vivo application of sex-sorted, frozen-thawed boar sperm.     

Birth of offspring of pre-determined sex after artificial insemination of frozen-thawed, sex-sorted and re-frozen-thawed ram spermatozoa

The fertility of ram spermatozoa cryopreserved prior to, and following, sex-sorting by flow cytometry was assessed after insemination of mature Merino ewes at a synchronised estrus. Ewes were inseminated with spermatozoa from three rams, split into four treatment groups: 50 x 10(6) motile non-sorted, frozen-thawed (Control50), 15 x 10(6) motile non-sorted, frozen-thawed (Control15), 15 x 10(6) motile sex-sorted, frozen-thawed (SF15) or 15 x 10(6) motile frozen-thawed, sex-sorted, re-frozen-thawed (FSF15) ram spermatozoa. Separation of SF15 and FSF15 treatments into X- and Y-chromosome-bearing populations was achieved using a high-speed sperm sorter. The percentage of ewes lambing after insemination was similar for Control15 (36/74; 48.6%), SF15 (35/76; 46.1%) and FSF15 (26/72; 36.1%) groups (P>0.05). A higher percentage of ewes produced lambs in the Control50 (38/70; 54.3%) than the FSF15 group (P<0.05). Fifty-one of the 55 (92.7%) lambs derived from fresh, sex-sorted frozen-thawed spermatozoa were of the predicted sex, as were 41/43 (95.3%) lambs derived from frozen-thawed, sex-sorted, re-frozen-thawed spermatozoa. This study demonstrated for the first time in any species that frozen-thawed spermatozoa, after sex-sorting and a second cryopreservation step, are capable of producing offspring of the predicted sex following artificial insemination.     

Hysteroscopic or rectally guided, deep-uterine insemination of mares with spermatozoa stored 18 h at either 5 degrees C or 15 degrees C prior to flow-cytometric sorting

Practical application of sex-selected spermatozoa in the horse industry would be greatly improved by the ability to develop simplified methods for shipping, storing, and inseminating sex-selected spermatozoa. Acceptable pregnancy rates have been achieved using fresh sex-sorted stallion sperm, however many stallion owners are reluctant to send their stallions to the sorter location for collection during the breeding season. Furthermore, the technology would be more applicable if the hysteroscopic insemination technique was not necessary for adequate pregnancy rates. Hysteroscopic insemination requires expensive equipment and specially trained personnel. In the present study, stallion sperm were sex-sorted after being stored at either 5 degrees C or 15 degrees C for 18 h. Twenty million sex-sorted sperm were then inseminated using one of two insemination techniques: the hysteroscopic method or the rectally guided, deep-uterine technique. Results were determined based on 16-day pregnancy status. A first-cycle pregnancy rate of 72% (18/25) was achieved when sperm were shipped at 15 degrees C, sex-sorted, and then inseminated using the hysteroscopic method. With these results, it can be concluded that stallions are not necessary at the sorter location to achieve acceptable fertility with sex-sorted sperm. There was a tendency for more mares to become pregnant when sperm were shipped at 15 degrees C prior to sorting, when compared to shipment at 5 degrees C. Similarly, there was a tendency for more mares to become pregnant when hysteroscopic insemination was utilized, when compared to the rectally guided, deep-uterine technique. These trends suggest that if larger group numbers were available, significant differences between the treatments may be revealed.     

Field fertility of frozen-thawed boar sperm at low doses using non-surgical, deep uterine insemination

The lowest dose of frozen-thawed boar sperm used for deep uterine artificial insemination (DUI) of sows has been 100x10(6). A three stage field study was performed to establish to what level the dose of frozen-thawed sperm used for DUI could be reduced without adversely affecting the fertility of the sow. In stage 1, 15 sows were inseminated twice with 1000x10(6) fresh or frozen-thawed sperm at 24 and 36 h post-detection of oestrus. In stage 2, 262 sows were inseminated with 62.5, 250 or 1000x10(6) fresh or frozen-thawed sperm at 24, 36, or 24 and 36 h after detection of oestrus. Stage 3 involved post mortem investigation of the uterine lining to assess damage caused by insertion of the insemination catheter. All sows inseminated in stage 1 of the study farrowed. In stage 2, the non-return (NRR) and farrowing rates of each group were compared to a control double cervical insemination of 3250x10(6) fresh sperm. As few as 62.5x10(6) fresh sperm could be deposited at a single insemination without reduction in NRR or farrowing rates compared with the control group. A double DUI with 250x10(6) frozen-thawed sperm was required before fertility was equivalent to the controls. Investigation of the uterine lining after insertion of the DUI catheter revealed evidence of bleeding, warranting further investigation of the viability of widespread use of the Firflex catheter, despite the promising fertility achieved here with low doses of spermatozoa.     

Successful low dose insemination of flow cytometrically sorted Sika (Cervus nippon) sperm in Wapiti (Cervus elaphus)

The purpose of this study was to determine a practical method in Wapiti (Cervus elaphus) of using predetermined sexed Sika (Cervus nippon) semen. Semen was collected by electro-ejaculation from one stag of proven fertility and transported to the laboratory where it was retained as unsorted (control) or was separated into X- and Y-chromosome-bearing sperm using a modified high-speed cell sorter. Wapiti hinds (n = 81) were inseminated into the uterus by rectum manipulation with 1 × 10⁶ (X1 and Y1 group, respectively) or 2 × 10⁶ (X2 and Y2 group, respectively) of sorted frozen-thawed and 1 × 10⁷ non-sorted frozen-thawed (a commercial dose control) Sika motile sperm 60–66 h after removal of intra-vaginal progesterone-impregnated CIDR devices and administration of 700 IU of PMSG at the time of CIDR removal. The percentage of hinds calving after insemination was similar for X1 (38.5%), X2 (41.7%), Y1 (44.4%), Y2 (38.9%) groups (P > 0.05), but higher for control (75%) treatment (P < 0.05). Ultimately 15 out of the 16 Sika and Wapiti-hybrid calves produced by Wapiti hinds inseminated with Y-sorted sperm were male (93.7%) and 10/10 (100%) Sika and Wapiti-hybrid calves from hinds inseminated with X-sorted sperm were female. The sex ratio of the Sika and Wapiti-hybrid calves born to hinds inseminated with sex-sorted sperm deviated significantly (P < 0.05) from 50% and 50.0% in the control group. All Sika and Wapiti-hybrid calves were born between 237 and 250 d of gestation. Male and female calves in the control group had similar birth weights and weaning weights as calves from hinds inseminated with X- or Y-sorted sperm. In conclusion it can be said that normal Sika and Wapiti-hybrid calves of predicted sex can be produced after artificial insemination of Wapiti does with low numbers of sex-sorted cryopreserved Sika sperm.     

Influence of storage time on functional capacity of flow cytometrically sex-sorted boar spermatozoa

Sex-sorting of boar spermatozoa is an emerging biotechnology, still considered suboptimal owing to the slowness of the process, which requires long sorting periods to obtain an adequate number of spermatozoa to perform a non-surgical insemination. This period involves storage of sorted cells that could impair their functional capacity. Here, we have studied how the storage of sex-sorted boar spermatozoa affects their functional capacity. Sorted spermatozoa were assessed at various times (0, 2, 5h or 10h) during storage after sorting and compared with diluted and unsorted spermatozoa for sperm motility patterns, plasma membrane and acrosomal integrity and their ability to penetrate homologous IVM oocytes. Sex-sorted sperm motility and membrane integrity only decreased significantly (p<0.05) by the end of the storage period (10h) compared to unsorted spermatozoa. Sperm velocity, ALH and Dance increased significantly (p<0.05), immediately post-sorting, returning to unsorted sperm values during storage. Acrosome integrity was not seriously affected by the sorting process, but decreased (p<0.05) during storage after sorting. Sorted spermatozoa stored 2h after sorting did not differ from unsorted in penetration rates and numbers of spermatozoa per oocyte, reaching the highest (p<0.05) penetration rates and sperm numbers per oocyte, when co-cultured for 6 or more hours. Non-storage or storage for 5h or 10h negatively (p<0.05) affected sperm penetration ability. In conclusion, although flow cytometrically sex-sorted spermatozoa are able to maintain motility, viability and acrosomal integrity at optimal levels until 10h of storage after sorting, fertilizing ability is maintained only over shorter storage times (<5h).     

Sex-sorting of boar spermatozoa does not influence the localization of glucose transporters

Sex-sorting damages spermatozoa function, shortening their lifespan and fertility. This study used an immunofluorescence technique to investigate the effect of sex-sorting on the localization of glucose transporters (GLUTs) in boar spermatozoa. GLUTs are trans-membrane proteins responsible for glucose transport within cells. Distribution of GLUTs on sperm cells was similar in unsorted and sex-sorted semen, suggesting that the flow cytometric sex-sorting process did not affect the sperm energy apparatus.     

Improving the efficiency of sperm technologies in pigs: the value of deep intrauterine insemination

The use of AI in pigs has dramatically expanded in the last few years. New methodological advances in AI are required to serve the requirements of new sperm technologies, such as the use of low dose AI, because the use of cervical AI has a very low efficiency leading to low fertility results. One of the strategies devised to meet these requirements is the deposition of semen near the site of fertilization in the oviduct. Using deep intrauterine insemination with a specially designed catheter, a 20-fold reduction in the number of freshly and diluted inseminated spermatozoa can be achieved without decreasing farrowing rates. Moreover, an advantage of deep intrauterine insemination is the possibility of using processed, 'weaker' spermatozoa such as those that have been frozen-thawed or sex-sorted. Although deep intrauterine insemination should be of benefit to the pig industry, more investigations are needed to understand the mechanisms related to sperm colonization of the oviducts and identify the minimal sperm numbers needed to obtain maximal fertility results for processed and unprocessed boar spermatozoa.     

Flow cytometric sexing of X- and Y-chromosome-bearing sperm in Sika deer (Cervus nippon)

The objectives of the study were to determine a practical method of using predetermined sexed semen in Sika deer (Cervus nippon). Semen was collected by electro-ejaculation from two Sika stags and transported to the laboratory and separated into X- and Y-chromosome-bearing sperm after analysis and re-analysis (using a modified high-speed cell sorter), or control (unsorted) semen. Eighty-four Sika hinds were inseminated with 2.8 × 10⁷ unsorted (control) or 2.3 × 10⁶ sorted (X or Y) frozen-thawed semen via intra-uterine laparoscopy 58–66 h after removal of intra-vaginal progesterone-impregnated CIDR devices and the administration of 330 IU PMSG at the time of CIDR removal. No significant differences in the post-thaw motility of control (43.4 ± 4.4%), X- (45.3 ± 4.5%) and Y-sorted (43.5 ± 3.2%) samples were recorded. The sorted frozen-thawed sperm (X, 72.5 ± 6.4%: Y, 75.2 ± 5.5%) recorded significantly (P < 0.05) more intact acrosomes following thawing than the unsorted frozen-thawed (68.2 ± 10.2%) sperm. The individual Sika stags had no effect on the post-thaw sperm motility. Sorted frozen-thawed sperm demonstrated a significantly shorter survival time after thawing than the control sperm (P < 0.05). The number of Sika hinds pregnant following insemination with unsorted or control thawed sperm was significantly higher (33/42; 78.6%) than for hinds inseminated with either X- (5/11; 45.5%) or Y-sorted sperm (15/31; 48.4%). Ultimately 14 out of the 15 calves produced by Sika hinds inseminated with Y-sorted sperm were male (92.9%) and 5/5 calves (100%) from Sika hinds inseminated with X-sorted sperm were female. The sex ratio of the calves born to hinds inseminated with sex-sorted sperm significantly (P < 0.05) deviated for the 48.5% (female, 16/33) and 51.5% (male, 17/33) in the control group. All calves were born between 230 d and 243 d of gestation. Male and female calves in the control group had similar birth and weaning weights as calves from hinds inseminated with X- or Y-sorted sperm. In conclusion it can be said that normal calves of the predicted sex may be produced after intra-uterine insemination conducted by laparoscopy with low numbers of sex-sorted cryopreserved Sika sperm.     

Timing of insemination using sex-sorted sperm in embryo production with Bos indicus and Bos taurus superovulated donors

Two experiments were designed to evaluate the effect of different insemination times (12 and 24h or 18 and 30h) and different types of semen (sex-sorted or non-sorted sperm) on embryo production in Nelore (Bos indicus) and Holstein (Bos taurus) superstimulated donors. In the first experiment, hormonal superstimulation of ovarian follicular development in Nelore donors (n=71) was performed in randomly allocated animals to one of the three treatment groups, and they were inseminated at 12 and 24h after an ovulatory stimulus with pLH treatment was applied, either with sex-sorted (4.2×10(6) sperm/insemination; S12/24; n=17) or non-sorted sperm (20×10(6) sperm/insemination; NS12/24; n=18), or they were inseminated at 18 and 30h using sex-sorted sperm (4.2×10(6) sperm/insemination; S18/30; n=19). A greater number of transferable embryos were found when sex-sorted sperm was used to inseminate the animals at 18 and 30h (4.5±3.0) compared to insemination at 12 and 24h (2.4±1.8; P<0.001). However, a greater embryo production (6.8±2.6) was obtained with non-sorted sperm. In the second experiment, the same insemination times and semen types were used in lactating high-production Holstein cows (n=12). A crossover design was employed in this trial. A lesser embryo production (P=0.007) was found in Holstein donors that were inseminated using sex-sorted sperm at 12 and 24h (4.6±3.0) compared to non-sorted sperm (8.7±2.8). However, intermediate results were obtained when the inseminations with sex-sorted sperm were performed at 18 and 30h (6.4±3.1). These results supported the current hypothesis that it is possible to improve embryo production using sex-sorted sperm in B. indicus and B. taurus superstimulated donors when the inseminations are performed near the same time as time-synchronized ovulations. However, the embryo production for timed artificial insemination (TAI) with sex-sorted sperm was still less than the production with non-sorted sperm.     

Embryo production from superovulated sheep inseminated with sex-sorted ram spermatozoa

An experiment was undertaken to assess the fertilizing capacity of sex-sorted, frozen-thawed ram spermatozoa, artificially inseminated into superovulated ewes, and the quality and survivability of the resultant pre-sexed embryos. Synchronized (intravaginal progestagen pessary and GnRH) donors were superovulated using PMSG and repeat ovarian stimulation with FSH before insemination. Ewes (n=67) were inseminated with either 30x10(6) or 15x10(6) motile non-sorted (control) or 15x10(6) motile sex-sorted (sorted) frozen-thawed spermatozoa (control: C30 or C15; sorted: S15, respectively) and the resultant embryos transferred immediately into synchronized recipients (n=160). The percentage of transferable embryos, pregnancy rate and embryo survival were similar (P>0.05) across all treatments. Oocyte cleavage rate was higher for ewes inseminated with S15 (172/230; 74.8%; P<0.05) than for C15 (97/151; 64.2%) or C30 (89/141; 63.1%) spermatozoa. Of the lambs resulting from embryos produced with sex-sorted spermatozoa, 86/93 (92.5%) were born of the predicted sex. This study demonstrated for the first time that pre-sexed offspring derived from superovulated sheep can be produced following transfer of embryos. Furthermore, sex-sorting by flow cytometry did not compromise the in vivo fertilizing capacity of ram spermatozoa in superovulated sheep, nor did it affect the quality or survivability of the resultant embryos.     

Production of piglets with sexed semen employing a non-surgical insemination technique

The aim of the present study was to ascertain whether multiparous sows could successfully be inseminated with sexed semen non-surgically. Spermatozoa were stained with Hoechst 33342 and separated flowcytometrically in X- and Y-chromosome bearing sperm populations employing the Beltsville Sperm Sexing Technology (BSST). After weaning, estrus was induced in sows with PMSG and hCG. Animals were inseminated once per estrus non-surgically with a specially designed catheter into the tip of the uterine horn, employing 50x10(6) of either sexed or non-sexed spermatozoa diluted in 2 ml Androhep. Pregnant sows were allowed to go to term. Mean pregnancy rate from inseminations with unsexed spermatozoa was 54.5% whereas inseminations with sexed spermatozoa resulted in 33.3% pregnant sows. All but one piglet born after insemination with sexed semen were of the predicted sex. The sex of those piglets born after inseminations with non-sexed spermatozoa was 61.1% for male and 38.9% for female sex. It is concluded that non-surgically inseminations with flowcytometrically sexed spermatozoa can be conducted successfully.     

Low-dose insemination--why, when and how

The typical dose for insemination into the uterine body of the mare is > 300 x 10(6) progressively motile spermatozoa (PMS) and an insemination dose of > 200 x 10(6) PMS is recommended for frozen-thawed semen. Low-dose insemination techniques allow for a drastic reduction in the numbers of spermatozoa required to achieve pregnancy. Acceptable pregnancy rates can be achieved with doses ranging from 1 to 25 x 10(6) PMS in volumes ranging from 20 to 1000 microL. Two techniques have been described: hysteroscopic insemination and transrectally guided deep horn insemination using a pipette. Similar pregnancy rates can be attained by either method when 5 x 10(6) PMS are used. Hysteroscopic insemination may provide an advantage when the dose is 1-3 x 10(6) PMS. These techniques have the potential to make more efficient use of frozen-thawed or sex-sorted semen from certain stallions. The use of low-dose insemination to improve fertility of infertile stallions warrants further investigation.     

Insemination of mares with low numbers of either unsexed or sexed spermatozoa

Two experiments were conducted to determine pregnancy rates in mares inseminated 1) with 5, 25 and 500 x 10(6) progressively motile spermatozoa (pms), or 2) with 25 x 10(6) sex-sorted cells. In Experiment 1, mares were assigned to 1 of 3 treatments: Group 1 (n=20) was inseminated into the uterine body with 500 x 10(6) pms. Group 2 (n=21) and Group 3 (n=20) were inseminated into the tip of the uterine horn ipsilateral to the preovulatory follicle with 25 and 5 x 10(6) pms, respectively. Mares in all 3 groups were inseminated either 40 (n=32) or 34 h (n=29) after GnRH administration. More mares became pregnant when inseminated with 500 x 10(6) (18/20 = 90%) than with 25 x 10(6) pms (12/21 = 57%; P<0.05), but pregnancy rates were similar for mares inseminated with 25 x 10(6) vs 5 x 10(6) pms (7/20 = 35%) (P>0.1). In Experiment 2, mares were assigned to 1 of 2 treatments: Group A (n=11) was inseminated with 25 x 10(6) spermatozoa sorted into X and Y chromosome-bearing populations in a skimmilk extender. Group B (n=10) mares were inseminated similarly except that spermatozoa were sorted into the skimmilk extender + 4% egg yolk. Inseminations were performed 34 h after GnRH administration. Freshly collected semen was incubated in 224 microM Hoechst 33342 at 400 x 10(6) sperm/mL in HBGM-3 for 1 hr at 35 degrees C and then diluted to 100 x 10(6) sperm/mL for sorting. Sperm were sorted by sex using flow cytometer/cell sorters. Spermatozoa were collected at approximately 900 cells/sec into either the extender alone (Group A) or extender + 4% egg yolk (Group B), centrifuged and suspended to 25 x 10 sperm/mL and immediately inseminated. Pregnancy rates were similar (P>0.1) between the sperm treatments (extender alone = 13/10, 30% vs 4% EY + extender = 5/10, 50%). Based on ultrasonography, fetal sex at 60 to 70 d correlated perfectly with the sex of the sperm inseminated, demonstrating that foals of predetermined sex can be obtained following nonsurgical insemination with sexed spermatozoa.     

Preselection of sex of offspring in swine for production: current status of the process and its application

It is estimated that as many as 30,000 offspring, mostly cattle, have been produced in the past 5 years using AI or some other means of transport with spermatozoa sexed by flow cytometric sperm sorting and DNA as the marker of differentiation. It is well documented that the only marker in sperm that can be effectively used for the separation of X- and Y-chromosome bearing spermatozoa is DNA. The method, as it is currently used worldwide, is commonly known as the Beltsville Sperm Sexing Technology. The method is based on the separation of sperm using flow cytometric sorting to sort fluorescently (Hoechst 33342) labeled sperm based on their relative content of DNA within each population of X- and Y-spermatozoa. Currently, sperm can be produced routinely at a rate of 15 million X- and an equal number of Y-sperm per hour. The technology is being applied in livestock, laboratory animals, and zoo animals; and in humans with a success rate of 90-95% in shifting the sex ratio of offspring. Delivery of sexed sperm to the site of fertilization varies with species. Conventional AI, intrauterine insemination, intra-tubal insemination, IVF with embryo transfer and deep intrauterine insemination are effectively used to obtain pregnancies dependent on species. Although sperm of all species can be sorted with high purity, achieving pregnancies with the low numbers of sperm needed for commercial application remains particularly elusive in swine. Deep intrauterine insemination with 50-100 million sexed boar sperm per AI has given encouragement to the view that insemination with one-fiftieth of the standard insemination number will be sufficient to achieve pregnancies with sexed sperm when specialized catheters are used. Catheter design, volume of inseminate, number of sexed sperm are areas where further development is needed before routine inseminations with sexed sperm can be conducted in swine. Cryopreservation of sex-sorted sperm has been routinely applied in cattle. Although piglets have been born from frozen sex-sorted boar sperm, freezing and processing protocols in combination with sex-sorted sperm are not yet optimal for routine use. This review will discuss the most recent results and advances in sex-sorting swine sperm with emphasis on what developments must take place for the sexing technology to be applied in commercial practice.