Pregnancy rates in cattle with cryopreserved sexed sperm: effects of sperm numbers per inseminate and site of sperm deposition

In six field trials, doses between 1.0 and 6.0 x 10(6) total sexed, frozen-thawed sperm were inseminated into the uterine body or bilaterally into the uterine horns of heifers and nursing Angus cows 12 or 24h after observed estrus. Except for one comparison in one trial in which uterine body insemination was slightly superior (P<0.05) to uterine horn insemination, there was no significant (P>0.1) difference between sites of semen deposition. Additionally, except for one small study with limited numbers, there was essentially no difference in pregnancy rates in the range between 1.5 and 6 x 10(6) sexed, frozen-thawed sperm per inseminate. Pregnancy rates with smaller doses of sexed sperm averaged about 75% of controls of 20 x 10(6) total frozen-thawed, unsexed sperm. While 1.0 x 10(6) sexed, frozen-thawed sperm per insemination dose resulted in decreased pregnancy rates compared to larger doses, the lesser fertility with sexed sperm could not be compensated by increasing sperm numbers in the range of 1.5-6 x 10(6) sperm per dose. Pregnancy rates with 2 x 10(6) sexed, frozen-thawed sperm per dose were not markedly less than control pregnancy rates with 20 x 10(6) frozen-thawed unsexed sperm/dose in well-managed herds.     

Sperm sexing technology-the transition to commercial application. An introduction to the symposium "update on sexing mammalian sperm"

Over the past decade, procedures for sexing mammalian sperm by flow cytometry/cell sorting have been refined sufficiently for large-scale commercial application in cattle; millions of doses of sexed sperm are sold each year for artificial insemination. Furthermore, more than a hundred babies are born annually from use of sexed human sperm via artificial insemination or in vitro fertilization, and to a lesser extent by injection of single sperm into oocytes. Semen sexing technology is also being applied for various objectives in a number of other species. Accuracy of sexing is around 90% in most species. However, this technology is still rather expensive, and fertility of sexed sperm is lower than unsexed controls in most instances. Speakers in this symposium, “Update on sexing mammalian sperm,” held in San Diego, California on 3 January 2009, presented the latest research on sexing sperm, including documentation of success rates. The written versions were peer-reviewed and follow in this issue of Theriogenology.     

Overview of sexing sperm

Hundreds of thousands of off springs have been born as a result of AI with sexed sperm. Although this technology has been used for many species, the overwhelming majority of pregnancies have been in cattle, nearly all as a result of sperm that were sexed and subsequently frozen. The technology for sexing sperm has not changed greatly in the past 7 years, but refinements have speeded up the process and reduced damage to sperm. The process of commercialization of sexed sperm has accelerated recently. However, this technology is characterized by high costs, complexity of implementation and lower pregnancy rates than with control sperm. Nevertheless, sexed, frozen bovine sperm are being produced commercially in many countries, although from a limited number of bulls. The main application of sexed sperm to date has been to breed dairy heifers to produce female calves. Because of the slow speed of sexing sperm, fewer sperm are used per insemination dose of sexed than conventional sperm, and pregnancy rates with this product are often only slightly decreased. Successful use of sexed sperm requires excellent management of cattle, careful handling of sperm and use of skilled inseminators. As costs decline, sexed sperm will be used increasingly for cattle breeding, horse breeding and niche applications in other species.     

Insemination of heifers with sexed sperm

Data from inseminating 1,000 heifers consecutively with sexed sperm and 370 heifers with control sperm in 11 small field trials are summarized. Semen was from 22 bulls of unknown fertility of various beef and dairy breeds, and 6 inseminators participated. Freshly collected sperm were sexed using a MoFlo flow cytometer/cell sorter after staining sperm with the DNA-binding dye Hoechst 33342; the principle is that the bovine X chromosome has 3.8% more DNA than the Y chromosome. Accuracy approaching 90% males or females was achieved. There was little difference in pregnancy rates between sexed, unfrozen and sexed, frozen sperm. In 5 of 6 field trials, there was little difference in pregnancy rates between insemination doses of 1.0 to 1.5 x 10(6) versus 3.0 x 10(6) sexed, frozen sperm. In the most recent trials, pregnancy rates with sexed, frozen sperm were within 90% of unsexed, frozen controls that had 7 to 20 times more sperm/insemination dose; however, in a few trials, control pregnancy rates were substantially higher than with low doses of sexed sperm. There were too few inseminations per bull to test bull differences in pregnancy rates rigorously. Insemination of sexed, frozen sperm bilaterally into the uterine horns produced pregnancy rates similar to insemination into the uterine body in 4 of 5 field trials. Pregnancy rates among inseminators did not differ significantly. There was no excess embryonic death between 1 and 2 months of gestation with pregnancies from sexed sperm, and very few abortions occurred between 2 months of gestation and term. Although rigorous epidemiological studies remain to be done, calves resulting from sexed sperm appear to exhibit no more abnormalities than controls.     

Flow cytometric sexing of mammalian sperm

This review reexamines parameters needed for optimization of flow cytometric sexing mammalian sperm and updates the current status of sperm sexing for various species where this technology is currently being applied. Differences in DNA content have provided both a method to differentiate between these sex-determining gametes and a method to sort them that can be used for predetermining sex in mammals. Although the DNA content of all cells for each mammalian species is highly conserved, slight but measurable DNA content differences of sperm occur within species even among cattle breeds due to different sizes of Y-chromosomes. Most mammals produce flattened, oval-headed sperm that can be oriented within a sorter using hydrodynamic forces. Multiplying the percentage the difference in DNA content of the X- or Y-chromosome bearing sperm times the area of the flat profile of the sperm head gives a simple sorting index that suggests that bull and boar sperm are well suited for separation in a flow sorter. Successful sperm sexing of various species must take into account the relative susceptibilities of gametes to the stresses that occur during sexing. Sorting conditions must be optimized for each species to achieve acceptable sperm sexing efficiency, usually at 90% accuracy. In the commercial application of sperm sexing to cattle, fertility of sex-sorted bull sperm at 2 x 10(6)/dose remains at 70-80% of unsexed sperm at normal doses of 10 to 20 x 10(6) sperm. DNA content measurements have been used to identify the sex-chromosome bearing sperm populations with good accuracy in semen from at least 23 mammalian species, and normal-appearing offspring have been produced from sexed sperm of at least seven species.     

Sexing mammalian sperm--intertwining of commerce, technology, and biology

Sperm from many mammalian species can be sexed by flow cytometry/cell sorting at about 90% accuracy without damaging them unduly. However, because sperm are evaluated one at a time, in series, the number of sexed sperm produced per unit time is limited. Furthermore, the equipment required currently is expensive, in the order of 300,000 US dollars per machine. Despite these limitations, commercialization of this technology has begun with bovine semen, in part by inseminating cattle with relatively low number of sperms. No other approach to sexing sperm in any practical way is likely to be available within the next few years. The constraints for commercial application of sexed sperm in cattle can be somewhat lowered fertility, the high costs of equipment and skilled personnel, and costs of intellectual property such as licensing fees and royalty payments. Most economic analyses indicate that farmers can afford to pay 10-20 US dollars more per dose of sexed sperm than unsexed sperm if costs must be recouped by selling milk or meat. When the product is breeding stock or for certain niche applications, a higher price for sexed semen may be justified. Sexed sperm will be used more broadly in cattle only when improved production and/or efficiency can compensate for the extra costs of purchasing sexed sperm.     

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.     

Issues affecting commercialization of sexed sperm

A decision tree for genetics or sperm-sexing entities considering sales of sexed sperm is discussed in terms of: (a) how best to avoid harm; (b) how best to do good; (c) needed synergy with other assisted reproductive technologies; (d) constraints on biotechnology; and (e) costs with current and likely technologies versus potential benefits to producers. The sexed-sperm industry might wish to take a pro-active stance on societal issues potentially affecting use of sexed sperm. For most sales in animal agriculture, cost of added value must be < 50% of benefit. Cost is less important for emotionally-driven uses with horses and human beings. Current procedures for flow-sorting allow most sperm to retain their fertilizing potential. Added cost to produce and package 2 x 10(6) sperm is estimated at US $30 to US $46 with flow sorted sperm. Estimating cost of any alternative technology is premature. For IVF/embryo transfer (ET), cost and numbers of flow-sorted sexed sperm are appropriate for commercial use. For use in low-dose AI, however, added cost to supply one insemination dose must be near US $12. Flow-sorting instruments with higher throughput and lower purchase and operating costs are obligatory for economic application in most AI situations. Developers of antibody-based separations also will face issues of retention of fertilizing potential while minimizing cell loss, separation of living from dead sperm concurrent with sperm sexing, output, and cost. To benefit producers and consumers in a changing world, genetics and sperm-sexing companies will have to collaborate and interface to provide funding for needed research and development and to recover these costs, using mechanisms not yet obvious.     

Bio-economic model to evaluate twinning rate using sexed embryo transfer in dairy herds

A stochastic bio-economic model has been used to determine the effects of new reproductive technologies over a 15-year period. A strategy of using conventional artificial insemination (AI) or embryo transfer (ET) using two sex-controlled embryos at different conception rates (CRs) and herd sizes resulted in a 24 state model. The genetic means of AI population increased over the years, and the genetic means of milk production for all of the embryo strategies were greater than those of AI. In addition, the genetic means of milk yield using different embryo-based scenarios in the expanding herds were greater than those for the fixed herds. The net profit of using sexed ET in the expanding herds was greater (P < 0.05) than that of fixed size herds. In general, there was a roughly consistent trend in net profit per cow for sexed ET strategies in the expanding herds over the years, but there was an increasing trend in net profit per cow for sexed ET strategies in the fixed herds over the years. Medium to high CRs for ET and the use of sex-controlled embryo systems, especially for induction of twin births to produce dairy replacements, will be critical elements of a system that produces significant numbers of female calves. The greater number of female calves produced in the sex-controlled scenarios allows the farmer to select animals with the best genetic potential as dairy replacement heifers; therefore, the rate of genetic gain increased in the dairy herd. Results of sensitivity analyses showed that a significant decrease in the production costs and increase in the ET performance are essential for embryo-based technologies to be profitable.     

In vitro embryo production in buffalo (Bubalus bubalis) using sexed sperm and oocytes from ovum pick up

The objective was to explore the use of sexed sperm and OPU-derived oocytes in an IVP system to produce sex-preselected bubaline embryos. Oocytes were recovered from 20 fertile Murrah and Nili-Ravi buffalo cows by repeated (twice weekly) ultrasound-guided transvaginal ovum pick up (OPU), or by aspiration of abbatoir-derived bubaline ovaries, and subjected to IVF, using frozen-thawed sexed or unsexed bubaline semen. On average, 4.6 oocytes were retrieved per buffalo per session (70.9% were Grades A or B). Following IVF with sexed sperm, oocytes derived from OPU had similar developmental competence as those from abattoir-derived ovaries, in terms of cleavage rate (57.6 vs. 50.4%, P=0.357) and blastocyst development rate (16.0 vs. 23.9%, P=0.237). Furthermore, using frozen-thawed sexed versus unsexed semen did not affect rates of cleavage (50.5 vs. 50.9%, P=0.978) or blastocyst development (15.3 vs. 19.1%, P=0.291) after IVF using OPU-derived oocytes. Of the embryos produced in an OPU-IVP system, 9 of 34 sexed fresh embryos (26.5%) and 5 of 43 sexed frozen embryos (11.6%) transferred to recipients established pregnancies, whereas 7 of 26 unsexed fresh embryos (26.9%) and 6 out of 39 unsexed frozen embryos (15.4%) transferred to recipients established pregnancies. Eleven sex-preselected buffalo calves (10 females and one male) and 10 sexed buffalo calves (six females and four males) were born following embryo transfer. In the present study, OPU, sperm sexing technology, IVP, and embryo transfer, were used to produce sex-preselected buffalo calves. This study provided proof of concept for further research and wider field application of these technologies in buffalo.     

Fertility in heifers and cows after low dose insemination with sex-sorted and non-sorted sperm under field conditions

The present study was performed to test fertility after low dose insemination with sexed and non-sexed sperm in dairy cattle under field conditions in Switzerland. Spermatozoa were stained with Hoechst 33342 and sorted by flow cytometry. A total of 132 heifers and cows were inseminated with 2 x 10(6) X-bearing, frozen-thawed sperm (A) and 91 animals were inseminated with the same dose using non-sorted, frozen-thawed sperm (B). Pregnancy examination by ultrasound was performed twice, 30-40 days (PE1) and 70-90 days (PE2) after insemination. The pregnancy rates after PE1 were 33.3% (9/27) and 59.3% (16/27) in heifers (P=0.05) and 27.6% (29/105) and 28.1% (18/64) in cows (P>0.05) for groups A and B, respectively. Embryonic losses between PE1 and PE2 in heifers were 11.1% (1/9) and 0% (0/16) and in cows 17.2% (5/29) and 5.6% (1/18), the differences between groups A and B not being significant (P>0.05). Calving rates in heifers were 29.6% (8/27) and 57.8% (15/26), whereas in cows 22.1% (23/104) and 23.4% (16/63) gave birth to calves (for both groups P>0.05). The sex ratio was different (P<0.05) between A (85.3%) and B (58.6%). From our results it can be concluded that conception rates of sorted and non-sorted semen are similar using an insemination dose of 2 x 10(6). Fertility may be increased by improving sexing technology and animal management.     

What affects fertility of sexed bull semen more, low sperm dosage or the sorting process?

Until now it has been unclear to what extent the reduced fertility with sexed semen in the dairy industry is caused by too few sperm per AI dose, or by the effect of flow cytometric sorting, which is the established procedure for sexing semen. Therefore, we evaluated the effects of low sperm numbers per dose with and without sorting on non-return rates after 56 days (NRR56); in addition, we evaluated the effects of bulls, in order to further optimize use of sexed semen.Based on results of using sexed semen from seven Holstein bulls, an overall numerical decline of 13.6% in NRR56 was observed (P < 0.05). About two-thirds of this decline (8.6%) was due to the low dose (P < 0.05), and a third (5.0%) due to the process of sorting (P < 0.05). The effect of low dosage and sorting differed among bulls. We observed a sex ratio of 91.6% females for sexed semen from the first 131 calves born.Currently the best way to increase fertility of sexed semen is by closely monitoring fertility so that the highest fertility bulls are used, and by improving farm animal management. However, to make substantial progress, more in depth studies are needed on the sexing technology, especially on aspects such as sorting procedures and sperm dosage.     

Pregnancy rates following AI with sexed semen in Mediterranean Italian buffalo heifers (Bubalus bubalis)

The use of sexed semen in farm animal production and genetic improvement has been shown to be feasible with variable degree of efficiency in a number of species, and proved to be economically viable in cattle. In the last two decades, various newly developed reproductive technologies applicable in buffaloes have mushroomed. Recently, following the birth of the first buffalo calves using AI with sexed semen, commercial interest to exploit sexing of semen in this species too is aroused. In order to verify the successful adoption of this technology in the buffalo, the present study on the use of sexed semen for AI was carried out and compared with conventional artificial insemination using nonsexed semen. A total of 379 buffalo heifers were used for synchronization of ovulation using the Presynch protocol in the South of Italy. Selected animals at the time of AI were randomly allocated to three different experiment groups: (1) 102 animals subjected to AI in the body of the uterus with sexed semen (SS body); (2) 104 animals subjected to AI in the horn of the uterus with sexed semen (SS horn); and (3) 106 animals subjected to AI in the body of the uterus with conventional nonsexed semen (NSS body). Semen of three buffalo bulls was sexed by a collaborating company and commercially distributed in 0.25 mL straws with a total of 2 million sexed spermatozoa. Pregnancy rates were first assessed at Day 28 following AI, and rechecked at Day 45 by ultrasound. Pregnancy rates were nonsignificantly different between animals inseminated with sexed or nonsexed semen: 80/206 (38.8%) and 40/106 (37.7%), respectively (P = 0.85). However, site of insemination of sexed semen affected pregnancy rate significantly as higher pregnancy rates were obtained when sexed semen was deposited into the body rather than the horn of the uterus: 46/101 (45.5%) and 34/105 (32.3%), respectively (P = 0.05). In conclusion, the use of sexed semen in buffalo heifers gave satisfactory and similar pregnancy rates when compared with conventional nonsexed semen. Deposition of sexed semen into the body of the uterus, however, increased pregnancy rates significantly.     

In vitro fertilization with flow-cytometrically-sorted bovine sperm

An attractive feature of IVF is that fewer sexed sperm are needed than for artificial insemination. However, sperm sexed by flow cytometry/cell sorting are probably pre-capacitated, necessitating modifications to standard IVF systems for optimal success. With current procedures, the percentages of oocytes fertilized with sorted and unsorted frozen bovine sperm are similar, and events during the first cell cycle are timed similarly for sorted and unsorted sperm. However, in most cases, blastocyst production with sorted sperm was approximately 70% of controls produced with unsorted sperm. In some early studies, there appeared to be an unexplained delay of about half a day in blastocyst development. Nevertheless, some dozens of apparently normal calves, pre-sexed with 90% accuracy, have resulted from frozen embryos produced via IVF with sexed sperm. IVF also has proven useful as a bioassay for improving sperm-sorting procedures such as determining potential detrimental effects of laser power. It is likely that use of IVF in cattle breeding programs will increase considerably when sexed, frozen sperm become commercially available.     

History of commercializing sexed semen for cattle

Although the basic principles controlling the sex of mammalian offspring have been known for a relatively long time, recent application of certain modern cellular methodologies has led to development of a flow cytometric system capable of differentiating and separating living X- and Y-chromosome-bearing sperm in amounts suitable for AI and therefore, commercialization of this sexing technology. After a very long history of unsuccessful attempts to differentiate between mammalian sperm that produce males from those that produce females, a breakthrough came in 1981 when it was demonstrated that precise DNA content could be measured. Although these initial measurements of DNA content killed the sperm in the process, they led to the ultimate development of a sperm sorting system that was capable, not only of differentiating between live X- and Y-sperm, but of sorting them into relatively pure X- and Y-sperm populations without obvious cellular damage. Initial efforts to predetermine the sex of mammalian offspring in 1989 required surgical insemination, but later enhancements provided sex-sorted sperm in quantities suitable for use with IVF. Subsequent advances in flow sorting provided minimal numbers of sperm sufficient for use in AI. It was not until the flow cytometric sorting system was improved greatly and successful cryopreservation of sex-sorted bull sperm was developed that efficacious approaches to commercialization of sexed semen could be implemented worldwide in cattle. A number of companies now offer sex-sorted bovine sperm. Innovative approaches by a diverse group of scientists along with advances in computer science, biophysics, cell biology, instrumentation, and applied reproductive physiology provided the basis for commercializing sexed semen in cattle.     

Pregnancy rates in heifers and cows with cryopreserved sexed sperm: Effects of sperm numbers per inseminate, sorting pressure and sperm storage before sorting

Field trials were conducted to increase fertility with AI of flow-sorted, sexed bovine sperm. In the first trial, a novel competitive fertilization approach was used to compare pressures (30 psi vs 50 psi) for sorting sperm. Both X- and Y-sperm were sorted to approximately 95% purity at 30 and at 50 psi; X-50 + Y-30 (and the converse) were mixed in equal numbers for AI of heifers. Fetal sex divulged which treatment produced the pregnancy; 82% of pregnancies resulted from the 30 psi treatment (P < 0.05). Based on a similar approach, a new-pulsed laser did not damage sperm any more than the previous standard continuous wave laser. In a large field trial, sorting sperm at 40 psi increased pregnancy rates in heifers relative to 50 psi (42.3% vs 34.1%, n = 367/group, P < 0.05). Storing sperm for 20 h before sorting at 40 psi decreased pregnancy rates from 42.3% (n = 367) to 36.8% (n = 368; P < 0.05). Breeding heifers with sexed sperm 55-56 h after CIDR removal and PGF_2α resulted in 34% (n = 32) pregnant, compared to 49% (n = 35) with fixed-time insemination 67-68 h after CIDR removal (P > 0.1). Lactating dairy cows pre-screened for normal reproductive tracts when OvSynch injections (GnRH, prostaglandin, GnRH) were initiated, had similar (P > 0.1) pregnancy rates to timed AI, with 10 × 10⁶ sexed sperm (43.9%, n = 57), 2 × 10⁶ sexed sperm (40.5%, n = 57) and 10 × 10⁶ unsexed control sperm (55.6%, n = 58). A final field trial with unselected, lactating dairy cows resulted in similar pregnancy rates for 2 × 10⁶ sexed sperm in 0.25 mL straws (25.0%, n = 708) and 0.5 mL straws (24.4%, n = 776), but lower (P < 0.05) than unsexed control sperm (37.7%, n = 713). Younger cows and those >84 days in milk had the highest pregnancy rates for both sexed and unsexed sperm. These studies improved sperm sexing procedures, and provided insight into appropriate commercial use of sexed sperm.     

The importance of porcine sperm parameters on fertility in vivo

It would be desirable to use semen parameters to predict the in vivo fertilizing capacity of a particular ejaculate. In animal production, an ejaculate is divided into multiple doses for artificial insemination (AI); therefore, it would be economically beneficial to know the functional quality (i.e., fertility) of the semen before it is inseminated. To identify a predictive assay of the fertilizing capacity of a porcine ejaculate, we performed 4 rapid assays of sperm quality (motility, viability, physiological status as assessed by chlortetracycline fluorescence, and ATP content) on samples from 9 ejaculates, before and after a thermal stress test (42.5 degrees C, 45 min). These parameters were subsequently correlated with in vivo fertility resulting from AI with 2 sperm doses, 3 x 10(9) or 0.3 x 10(9) motile cells in 70 mL (optimal or suboptimal sperm number per insemination, respectively) from these same ejaculates. No parameter was correlated to the fertility rates obtained after inseminating with the optimal semen doses, either before or after the thermal stress test (P > 0.05). However, with respect to the animals inseminated with the suboptimal semen dose, sperm motility (the percentage of motile spermatozoa as assessed visually by microscopy) prior to thermal stress was well-correlated to fertility rates (r = 0.783, P = 0.01). The percentage of spermatozoa displaying the chlortetracycline Pattern AR (acrosome reaction) was also statistically related to fertility (r = 0.05, P = 0.04), but the biological importance of this relationship is questionable given the small variation among ejaculates (range: 0 to 2%). No other sperm parameter was significantly related to fertility rates in this group (P > 0.05). These data, therefore, indicate that sperm motility is a useful indicator of sperm fertilizing capacity in vivo. Moreover, to identify a predictor of semen fertility it is critical that the number of spermatozoa used during insemination is sufficiently low to detect differences in sperm fertilizing efficiency.     

Embryo production from superovulated cattle following insemination of sexed sperm

Two trials were conducted to ascertain fertilization rate, embryo quality and numbers of transferable embryos in superovulated heifers and cows inseminated with sexed sperm. Inseminates contained 2 x 10(6), 10 x 10(6) or 20 x 10(6) total sperm enriched for the X- or Y-chromosome ( approximately 90%) by flow cytometry/cell sorting. Non-sexed inseminates contained 40 x 10(6) total sperm. Donors in each trial were allocated to one of each of the bulls included in that study. Each donor was inseminated with frozen/thawed sperm from the same bull for each treatment in successive courses of superstimulation with twice daily i.m. injections of FSH for 4 d. Heifers and cows were inseminated 12 and 24 h after visually observed standing estrus in Trial 1. In Trial 2, a single timed inseminate was used 70-72 h following PGF(2alpha). Ova/embryos were collected non-surgically 7-7.5 d after insemination. In both trials, fewer ova were fertilized with sexed versus non-sexed treatments and with 2 x 10(6) sexed sperm compared to higher doses (P < 0.05). However, insemination of 20 x 10(6) total sexed sperm of >or=90% purity resulted in similar numbers of transferable embryos of the desired sex compared to that for non-sexed sperm.     

Bluetongue virus serotype 8 (BTV-8) infection reduces fertility of Dutch dairy cattle and is vertically transmitted to offspring

In 2007, BTV-8 re-emerged for the second year in the Netherlands and caused morbidity and increased mortality in cattle herds. In addition, cattle farmers reported reduced fertility in their cows. For this study, fifteen herds that were not vaccinated were selected. These were matched to 10 vaccinated herds by geographic region. At the start of the study, in July 2008, all cattle in the non-vaccinated herds >1 year old were sampled. All seronegative cows entered the study program and blood samples from these cows were tested for antibodies against BTV-8 in an ELISA. Cows were sampled at intervals of three weeks and sampling was stopped once a cow tested seropositive. Sampling ceased in all remaining cows in December 2008.Newborn calves originating from infected dams or from vaccinated dams were tested by PCR for BTV-8. Fertility data were obtained from the Royal Dutch Cattle Syndicate (CRV). Multi-level generalized latent and linear models were used for analyses.In 2008, 185 (17.2%) out of 1,074 initially seronegative non-vaccinated cattle seroconverted and were assumed to be infected with BTV-8. Infected cows were 5 (95% CI: 1.9-14.3) times more likely to return for insemination within 56 days after first insemination. In addition, these cows needed 1.7 (95% CI: 1.4-2.0) times more inseminations for an assumed pregnancy, and needed 2.5 (95% CI: 2.4-2.6) times more days between first and last insemination compared to the period prior to seroconversion and compared to cows not infected by BTV-8 in 2008. No association between BTV-8 infection and the chance to abort between 100 and 260 days after last insemination was found.In total, 48 calves originating from infected cows were tested by PCR for the presence of BTV-8. Ten (20.8%) out of these 48 calves were born PCR-positive. None of 256 calves from vaccinated dams tested PCR-positive. Further, cows infected during the second half of gestation had a 15.5 times (95% CI: 1.3-190.4) higher chance of a PCR-positive newborn calf compared to cows infected in the first half of gestation. This study showed that BTV-8 has a negative effect on fertility of dairy cattle.     

Danish A.I. field data with sexed semen

The objective of this study was to compare conception rates, non-return rates and sex ratios of sexed and conventional semen from the same sires in commercial dairy herds in Denmark. The semen was produced from three bulls from each of the three major dairy breeds in Denmark: Holstein, Jersey and Danish Red Dairy Breed (nine bulls total), in order to answer questions on breeds differences in field results. AI was performed by trained technicians using a minimum of 150 doses of sorted sperm and 50 control doses from each bull. During the trial, a total of 2087 doses were used in 63 herds.The trial showed that the conception rate using sorted semen was 5% points lower than with conventional doses for Danish Reds, 7% points for Jerseys, and 12% points for Holsteins. Translating this into non-return rate revealed differences of 10-20% points among bulls. These differences are thought to be a good indicator of what to expect from commercial use of sexed semen.The sex ratios varied from 89% to 93% female calves among breeds, which on average is consistent with the theoretical average sex ratio of 93% females considering the low number of inseminations.