In vitro fertilization and culture of ova from heifers infected with bovine herpesvirus-1 (BHV-1)

Oocytes collected from heifers infected experimentally with bovine herpesvirus-1 (BHV-1, 10(8) TCID(50)/ml) and from dexamethasone-treated (stressed) BHV-1 seropositive animals were matured, fertilized and co-cultured in vitro for 7 d prior to being tested for the presence of the virus. Nineteen of the 21 infected donors yielded embryos and follicular fluids that were BHV-1 positive. Oviductal cells (17 21 ) and uterine fluids (14 21 ) were also positive. Titers for the positive samples ranged 10(1.6)-10(9.6) TCID(50)/ml. The cleavage rate and the proportion of blastocysts that developed from oocytes of BHV-1 infected animals were 26% (n=361) and 6% compared with 56% (n=112) and 26% for uninfected control donors (P<0.05). In contrast, embryos produced from dexamethasone-treated animals tested negative for BHV-1 and yielded 11% blastocysts as compared with 25% for the control group. The results indicate that transferable-stage embryos can be produced by IVF from infected BHV-1 animals and that such embryos are associated with the virus, and might have potential for disease transmission.     

Effect of bovine herpesvirus-1 or bovine viral diarrhea virus on development of in vitro-produced bovine embryos.

In previous experiments, zona pellucida (ZP)-intact in vitro-produced (IVP) embryos incubated for 1 hr with 10(6.3) TCID(50)/ml bovine herpes virus-1 (BHV-1), 10(5.3) TCID(50)/ml cytopathic (CP) bovine viral diarrhea virus (BVDV) or 10(5.3) TCID(50)/ml noncytopathic (NCP) BVDV showed no signs of virus replication or embryonic degeneration. The aims of the present study were to investigate whether a prolonged presence (24 hr or 8 days) of 10(6.3) TCID(50)/ml BHV-1 or 10(5.3) TCID(50)/ml BVDV in an in vitro embryo production system affected the rate of cleavage and embryonic development of ZP-intact embryos, and to point out eventual causes of adverse effects. When virus was present in each step of an IVP system, significantly lower rates of cleavage and blastocyst formation of virus-exposed embryos were observed, in comparison with control embryos (P < 0.01). When embryos were only exposed to virus during the in vitro fertilization (IVF), the rates of cleavage and blastocyst formation were significantly affected. The introduction of BHV-1 or BVDV during in vitro maturation (IVM) or in vitro culture (IVC) resulted only in significantly lower rates of blastocyst (P < 0.01). In all experiments, virus replication was not detected in the embryonic cells. On the other hand, virus replication was clearly demonstrated in oviductal cells in the co-culture system, resulting in a degeneration of these cells. In an additional experiment, synthetic oviduct fluid (SOF) without somatic cells was used as an alternative culture system. Even when SOF-embryos were exposed to 10(6.3) TCID(50)/ml BHV-1 or 10(5.3) TCID(50)/ml CP, and NCP BVDV, the rates of blastocyst formation of the BHV-1-, CP-, and NCP BVDV-exposed embryos were not different from the unexposed control embryos, 23%, 24%, and 24%, respectively, vs. 27%. Taken together, it can be concluded that the virus-induced adverse effects on embryonic development in conventional co-cultures were due to changes in the embryonic environment caused by infection of oviductal cells.     

Effect of cryopreservation by slow cooling and vitrification on viral contamination of IVF embryos experimentally exposed to bovine viral diarrhea virus and bovine herpesvirus-1

The objective was to determine the effect of cryopreservation by conventional slow controlled cooling (0.5 °C/min) and by vitrification on the presence of bovine viral diarrhea virus (BVDV) and bovine herpesvirus-1 (BHV-1) infectivity associated with frozen-thawed Day 7 bovine embryos. In this study, Day 7 embryos generated by in vitro fertilization (IVF) were exposed in vitro for 1.5 h to BVDV (N = 393) and BHV-1 (N = 242) and subsequently tested before and after cryopreservation for the presence of infectivity. Exposure of embryos to viral agents resulted in 72% of them infected prior to cryopreservation. Stepwise exposure of embryos to cryoprotectants, as well as their removal, substantially reduced the proportion of contaminated embryos (46% vs. 72%, P < 0.05). Overall, both freezing methods reduced the percentage of infectious embryos compared with that of embryos similarly exposed to viruses but not cryopreserved (31% vs. 72%, respectively; P < 0.001). The percentage of embryos with infectious viruses was not significantly higher after vitrification than after slow cooling (38% vs. 22%). In addition, after cryopreservation, a higher percentage (P < 0.002) of embryos exposed to BHV-1 (42%) remained infectious than did embryos exposed to BVDV (24%). In conclusion, cryopreservation reduced the proportion of infected embryos but did not render all of them free from infectious pathogens.     

Inactivation of bovine herpesvirus-1 and bovine viral diarrhea virus in association with preimplantation bovine embryos using photosensitive agents

Hematoporphyrin (HP), hematoporphyrin derivative (HPD), and thiopyronine (TP) are photosensitive agents (PSA) that have a germicidal effect when they are activated by light: helium neon laser (He Ne ) light (HP, HPD), white light (HP, HPD), and yellow-green light (TP). Experiments were conducted with appropriate controls to determine the effect of photosensitive agents a) for inactivating bovine herpesvirus-1 (BHV-1; titre 10(6) TCID(50) /ml) and bovine viral diarrhea virus (BVDV; titre 10(6) TCID(50) /ml); b) for disinfecting Day-7, zona pellucida-intact (ZP-I) bovine embryos that had been exposed to BHV-1 (titre 10(6) TCID(50) /ml) or BVDV (titre 10(6) TCID(50) /ml); and c) on the in vitro development of embryos. Exposure to HP, HPD and TP followed by light irradiation inactivated BHV-1 and BVDV. Embryos exposed to BHV-I were disinfected by HP or HPD (5 mug/ml) in combination with He Ne light, or by HP or HPD (10 mug/ml) in combination with white light. Embryos exposed to BVDV were disinfected by HPD (5 and 10 mug/ml) followed by He Ne or white light irradiation. Exposure of embryos to light alone or to light and HP or HPD had no detrimental effect on their in vitro development; however, exposure of embryos to TP (5 mug/ml) followed by irradiation caused embryonic degeneration. Exposure of embryos to 5 mug of HPD followed by He Ne light, or 10 mug/ml of HP or HPD, followed by white light, is simple methods of disinfecting them of BHV-I and BVDV.     

Inactivation of bovine herpesvirus-1 (BHV-I) from in vitro infected bovine semen

Frozen-thawed bovine semen, experimentally infected with bovine herpesvirus-1 (BHV-1) at levels of 10(3) TCID(50)/ml and 10(4) TCID(50)/ml, was treated with a 0.3% trypsin solution to determine the effect of trypsin on the virus and on fertilization using superovulated animals. Virus was not isolated from any trypsin-treated samples using a cell culture assay system. Nor did two calves develop antibodies to BHV-1 following inoculation with trypsin-treated semen pooled from six bulls. Nonsurgical flushing of eight heifers inseminated with trypsin-treated frozen-thawed semen yielded 28 transferable-quality embryos.     

In vitro fertilization of ova from cows experimentally infected with a non-cytopathic strain of bovine viral diarrhea virus

Bovine viral diarrhea virus infection was induced in 16 heifers by inoculation of a noncytopathic strain of bovine viral diarrhea virus (BVDV). Six BVDV-free heifers served as controls. On Day 8 after inoculation, cumulus—oocyte complexes were collected from ovaries of animals at the second peak of fever preceded by leukopenia. The oocytes were then matured and fertilized in vitro. There was no significant difference (48% vs. 54% P>0.05) in the percentage of cleaved oocytes between infected and non-infected animals. However, the proportion of embryos that developed to the blastocyst stage was significantly higher for the control group than for BVDV group (29% vs. 14%) (P<0.01). All follicular fluids and cumulus—oocyte complexes collected from infected animals tested positive for the presence of the virus, but embryos produced by in vitro fertilization 7 days after in vitro co-culture tested negative.     

Trypsin treatment of bovine embryos after in vitro exposure to infectious bovine rhinotracheitis virus or bovine herpesvirus-4

The objectives of this study were to evaluate the efficacy of trypsin treatment for the removal/inactivation of infectious bovine rhinotracheitis virus (IBRV) adhering to zona pellucida-intact (ZP-I) bovine embryos and to determine if bovine herpesvirus-4 (BHV-4) adheres to ZP-I bovine embryos. When adherence of BHV-4 was demonstrated, an additional objective was to determine whether trypsin treatment removes or inactivates this virus. A total of 139 ZP-I embryos was collected from superovulated donor cows at 7 d after estrus. Embryos were exposed to 10(6) to 10(7) plaque-forming units (pfu) of either IBRV or BHV-4 for 1 to 2 h. Subsequently, approximately equal numbers of embryos exposed to each virus were either washed 12 times and the washes and embryos examined for the presence of infectious virus, or they were treated with trypsin and the embryos examined for the presence of infectious virus. Although the fourth wash was the last positive wash, an average of 18 pfu of virus was detected from each of six groups (a total of 24 embryos) after exposure to IBRV and washing. Infectious bovine rhinotracheitis virus was not isolated from any of nine trypsin-treated groups (a total of 43 embryos). The seventh wash was the last positive wash for any group after exposure to BHV-4, yet an average of 2 pfu of virus was detected from each of six groups (a total of 29 embryos) after washing. No BHV-4 was isolated from any of eight trypsin-treated groups (a total of 43 embryos). The study confirmed previous reports that IBRV adheres to the bovine ZP after in vitro exposure and that trypsin treatment is effective in keeping ZP-I embryos free of this virus. Adherence of BHV-4 to ZP-I bovine embryos was demonstrated for the first time. Trypsin treatment was also effective in removing this herpesvirus.     

Neutralizing antibodies to bovine herpesvirus-1 (BHV-1) and bovine parainfluenza-3 (PI-3) viruses in cattle in Tunisia

A serological survey was conducted in an attempt to detect antibodies to bovine respiratory viruses in cattle from several localities around Tunis. Blood was collected from approximately 10% of the animals in each of the 44 farms visited and tested for specific antibodies against bovine herpesvirus-1 (BHV-1) and bovine parainfluenza-3 (PI-3) viruses, by ELISA and serum neutralization (SN). Antibodies to PI-3 and BHV-1 viruses were demonstrated in 55.3% and 25.9% animals, respectively. An overall 21.2% of the 170 animals tested had antibodies to both viruses. The incidence of antibody presence varied at different location. A correlation of the presence of BHV-1 antibody with breed and age of the animals was observed; however, no such relationship for PI-3 antibodies appeared to exist.     

Development and viability of bovine preimplantation embryos after the in vitro infection with bovine herpesvirus-1 (BHV-1): immunocytochemical and ultrastructural studies

The aim of our study was to examine whether: (1) the exposure of bovine embryos to the BHV-1 virus in vitro can compromise their further development and alter the ultrastructural morphology of cellular organelles; (2) whether the zona pellucida (ZP) can be a barrier protecting embryos against infection; and (3) whether washing with trypsin after viral exposure can prevent virus penetration inside the embryo and subsequent virus-induced damages. The embryos were recovered from superovulated Holstein-Friesian donor cows on day 6 of the estrous cycle. Only compact morulas or early blastocysts were selected for experiments with virus incubation. We used the embryos either with intact ZP (either with or without trypsin washing) or embryos in which the ZP barrier was avoided by using the microinjection of a BHV-1 suspension under the ZP. ZP-intact embryos (n = 153) were exposed to BHV-1 at 10(6.16) TCID(50)/ml for 60 min, then washed in trypsin according to IETS guidelines and postincubated in synthetic oviduct fluid (SOF) medium for 48 h. Some of the embryos (n = 36) were microinjected with 20 pl of BHV-1 suspension under the ZP, the embryos were washed in SOF medium and cultured for 48 h. Embryo development was evaluated by morphological inspection, the presence of viral particles was determined both immunocytochemically, using fluorescent anti-IBR-FITC conjugate and by transmission electron microscopy (TEM) on the basis of the ultrastructure of the cellular organelles. It was found that BHV-1 exposure impairs embryo development to higher preimplantation stages independent of the presence of the ZP or the trypsin treatment step, as most of the embryos were arrested at the morula stage when compared with the control. Immunofluorescence analysis confirmed the presence of BHV-1 particles in about 75% of embryos that were passed through the trypsin treatment and in all the BHV-1-microinjected embryos. Ultrastructural analysis, using TEM, revealed the presence of virus-like particles inside the BHV-1-exposed embryos, where the trypsin washing step was omitted. Conversely, in trypsin-treated BHV-1-exposed embryos, TEM detected only the envelope-free virus-like particles adhered to pores of the ZP. The embryos that were microinjected with BHV-1 suspension showed the presence of BHV-1 particles, as well as ultrastructural alterations in cell organelles. Taken together these findings may suggest that BHV-1 infection compromises preimplantation development of bovine embryos in vitro and therefore the ZP may not be enough on its own to prevent virus-induced damage, unless it is not accompanied with trypsin washing.     

Washing and trypsin treatment of in vitro derived bovine embryos exposed to bovine viral diarrhea virus

Gametes, somatic cells and materials of animal origin in media are potential sources for introducing bovine viral diarrhea virus (BVDV) into systems for production of IVF bovine embryos. Further, the efficacy of washing and trypsin treatment for removal of BVDV from IVF embryos is questionable. Washing and trypsin treatments recommended by the International Embryo Transfer Society for in vivo-derived embryos were applied to in vitro-derived, virus-exposed, bovine embryos in this side-by-side comparison of treatments. Embryos for the study were produced in a virus-free system in which follicular oocytes were matured and fertilized in vitro and presumptive zygotes were co-cultured with bovine uterine tubal cells for 7 d. A total of 18 trials was performed, 9 using a noncytopathic BVDV and 9 using a cytopathic BVDV. In each trial, 4 equal groups of 10 or less, zona pellucida-intact embryos/ova were assembled, including 2 groups of morulae and blastocysts (M/B) and 2 groups of nonfertile or degenerated ova (NFD). Each group was prewashed and exposed to 10(4) to 10(6) TCID50/mL of either noncytopathic (SD-1) or cytopathic (NADL) BVDV for 2 h. Following in vitro viral exposure, one group of M/B and one group of NFD were washed. The other groups of M/B and NFD were trypsin-treated. Both treatments were consistent with IETS guidelines. After in vitro exposure to noncytopathic BVDV and washing, viral assays of 100% (9/9) and 78% (7/9) of the groups of M/B and NFD ova, respectively, were positive. After in vitro exposure to cytopathic BVDV and washing, viral assay of 33% (3/9) of the groups of both M/B and NFD ova were positive. After in vitro exposure to noncytopathic BVDV and trypsin treatment, viral assay of 44% (4/9) of groups of M/B and 67% (6/9) of groups of NFD ova were positive. Finally, after in vitro exposure to cytopathic BVDV and trypsin treatment, viral assay of 22% (2/9) of the groups of M/B and 44% (4/9) of the groups of NFD ova were positive. Contingency table analysis, in which data was stratified by embryo type and virus biotype, was used to compare results. While a difference existed between results of the 2 treatments of groups of M/B within the noncytopathic biotype (P = 0.01, Mantel Haenszel Chi-square), no difference was observed between comparison of treatment between all groups in both biotypes (P > 0.05).     

Detection of bovine viral diarrhea virus (BVDV) in single or small groups of preimplantation bovine embryos

The objectives of this study were to develop techniques to detect BVDV associated with single or small groups of bovine embryos contained in small aliquots of medium using either virus isolation (VI) or real time quantitative polymerase chain reaction (RT-QPCR) assays. In vivo-derived and in vitro-produced bovine embryos at 7 d post-fertilization were exposed to SD-1, a high affinity strain of BVDV, for 2 h and then processed according to the International Embryo Transfer Society (IETS) guidelines prior to testing. Groups of five or two in vivo-derived embryos, and single in vivo-derived embryos, were VI positive for BVDV 100, 50, and 33% of the time, and were RT-QPCR positive 100, 75, and 42% of the time, respectively. The virus was detected by the VI technique in all of the groups of five or two in vitro-produced embryos and in all of the single in vitro-produced embryos, and it was detected in 100, 80, and 50%, using RT-QPCR. Techniques for RT-QPCR were sufficiently sensitive to detect 10 copies of viral RNA in a sample and to detect BVDV associated with single embryos. Application of this new technology, RT-QPCR, will facilitate additional studies to further assess the risk of transmission of BVDV through embryo transfer.     

Efficacy of a recombinant trypsin product against bovine herpesvirus 1 associated with in vivo- and in vitro-derived bovine embryos

Although porcine-origin trypsin will effectively remove bovine herpesvirus 1 (BHV-1) associated with in vivo-derived embryos, TrypLE, a recombinant trypsin-like protease, has not been evaluated. In Experiment 1, 17 groups of 10 in vivo-derived embryos were exposed to BHV-1, treated with TrypLE Express or TrypLE Select (10x concentration) for varying intervals, and assayed as 2 groups of 5 embryos. TrypLE Select treatment for 5 and 10 min (two and seven groups of five embryos, respectively) effectively inactivated BHV-1. In Experiment 2, 22 groups of 10 IVF embryos were treated and assayed. Treatment with TrypLE Select for 7 and 10 min (six groups of five embryos each) and with TrypLE Select diluted 1:2 for 10 min (seven groups of five embryos) was also effective. In Experiment 3, 17 groups of 10 IVF embryos were further evaluated with TrypLE Select undiluted and diluted 1:2 for 10 min. Treatment with the diluted product was effective (18 groups of five embryos), whereas the undiluted product was not completely effective (virus isolated from 2 of 16 groups). In Experiment 4, IVF embryos were treated as described in Experiment 3 and then cultured individually or as groups of five on uterine tubal cells (UTCs) for 48 h; 60% of UTC samples associated with groups of embryos and 35% of UTC associated with individual embryo samples were positive for BHV-1. Therefore, although TrypLE Select appeared to have promise for the treatment of in vivo-derived embryos, it cannot be recommended for treatment of in vitro-derived embryos.     

Intrauterine inoculation of seronegative heifers with bovine viral diarrhea virus concurrent with transfer of in vivo-derived bovine embryos

Bovine viral diarrhea virus (BVDV) has been shown to be associated with single transferable in vivo-derived bovine embryos despite washing and trypsin treatment. Hence, the primary objective was to evaluate the potential of BVDV to be transmitted via the intrauterine route at the time of embryo transfer. In vivo-derived bovine embryos (n = 10) were nonsurgically collected from a single Bos tarus donor cow negative for BVDV. After collection and washing, embryos were placed into transfer media containing BVDV (SD-1; Type 1a). Each of the 10 embryos was individually loaded into an 0.25-mL straw, which was then nonsurgically transferred into the uterus of 1 of the 10 seronegative recipients on Day 0. The total quantity of virus transferred into the uterus of each of the 10 Bos tarus recipients was 878 cell culture infective doses to the 50% end point (CCID₅₀)/mL. Additionally, control heifers received 1.5 × 10⁶ CCID₅₀ BVDV/.5 mL without an embryo (positive) or heat-inactivated BVDV (negative). The positive control heifer and all 10 recipients of virus-exposed embryos exhibited viremia by Day 6 and seroconverted by Day 15 after transfer. The negative control heifer did not exhibit a viremia or seroconvert. At 30 d after embryo transfer, 6 of 10 heifers in the treatment group were pregnant; however, 30 d later, only one was still pregnant. This fetus was nonviable and was positive for BVDV. In conclusion, the quantity of BVDV associated with bovine embryos after in vitro exposure can result in viremia and seroconversion of seronegative recipients after transfer into the uterus during diestrus.     

Susceptibility of zona-intact and zona-free in vitro-produced bovine embryos at different stages of development to infection with bovine herpesvirus-1

The aim of the present study was to determine if BHV-1 is able to replicate within in vitro produced embryos and to investigate the degree to which the zona pellucida (ZP) is able to protect in vitro produced embryos against infection with BHV-1. Both ZP-intact and ZP-free matured oocytes, zygotes (1 d post insemination; 1dpi), 8-cell stage embryos (3 dpi), morulae (6 dpi) were incubated for 1 h in 1 ml of MEM containing 10(7.7) TCID(50)/ml BHV-1 (Cooper strain). Three titers (10(5.7), 10(6.7) and 10(7.7) TCID(50)/ml) of the Cooper strain were used for incubation of hatched blastocysts (9 dpi). Bovine embryonic lung cells (BEL) on microcarriers were inoculated following the same protocol as for the embryos. At 0, 12, 24, 36 and 48 h post inoculation (hpi), groups of embryos and BEL cells were collected for virus titration and for the determination of the percentage of viral antigen positive cells by immunofluorescence. For the 3 developmental stages in ZP-free embryos, similar maximal intracellular virus progeny titers were obtained at 24 to 48 hpi ranging from 10(1.32) to 10(1.43) TCID(50)/ 100 embryonic cells. The intracellular virus titer in the BEL cells peaked at 10(3.08) TCID(50)/ 100 BEL cells. The percentage of cells which expressed viral antigens was 13% in ZP-free hatched blastocysts, 17% in ZP-free morulae and 100% in BEL cells. In ZP-intact embryos, no replication of BHV-1 was detected. These results clearly show that only after removal of the zona pellucida, BHV-1 is able to replicate within the in vitro produced embryos, with only a subset of embryonic cells being fully susceptible.     

Microbial contamination of embryos and semen during long term banking in liquid nitrogen

We report on microbial contamination of embryos and semen cryopreserved in sealed plastic straws and stored for 6-35 years in liquid nitrogen. There were 32 bacterial and 1 fungal species identified from randomly drawn liquid nitrogen, frozen semen, and embryos samples stored in 8 commercial and 8 research facility liquid nitrogen (LN) tanks. The identified bacteria represented commensal or environmental microorganisms and some, such as Escherichia coli, were potential or opportunistic pathogens for humans and animals. Stenotrophomonas maltophilia was the most common contaminant identified from the samples and was further shown to significantly suppress fertilization and embryonic development in vitro. Analysis of the strains by pulsed field gel electrophoresis revealed restriction patterns with no relatedness indicating that there was no apparent cross-contamination of S. maltophilia strains between the germplasm and liquid nitrogen samples. In addition, no transmission of bovine viral diarrhea virus (BVDV) and bovine herpesvirus-1 (BHV-1) from infected semen and embryos straws to clean germplasm stored in the same LN tanks or LN was detected.     

Alteration in ultrastructural morphology of bovine embryos following subzonal microinjection of bovine viral diarrhea virus (BVDV)

The aim of the present study was to evaluate the development and ultrastructure of preimplantation bovine embryos that were exposed to bovine viral diarrhea virus (BVDV) in vitro.The embryos were recovered from superovulated and fertilized Holstein-Friesian donor cows on day 6 of the estrous cycle. Compact morulae were microinjected with 20 pl of BVDV suspension (10(5.16) TCID(50)/ml viral stock diluted 1:4) under the zona pellucida (ZP), then washed in SOF medium and cultured for 24-48 h. Embryos were evaluated for developmental stages and then processed immunocytochemically for the presence of viral particles, using fluorescent anti-BVDV-FITC conjugate. Ultrastructure of cellular organelles was analysed by transmission electron microscopy (TEM).After microinjection of BVDV under the ZP, significantly more (p<0.001) embryos (83.33%) were arrested at the morula stage compared with the intact control (30.33%). Immunocytochemical analysis localized the BVDV-FITC signal inside the microinjected embryos. TEM revealed: (i) the presence of virus-like particles in the dilated endoplasmic reticulum and in cytoplasmic vacuoles of the trophoblast and embryoblast cells; (ii) the loss of microarchitecture: and (iii) abnormal disintegrated nuclei, which lacked reticular structure and the heterochromatin area. In all, the embryo nuclear structure was altered and the microarchitecture of the nucleolus had disappeared when compared with the nuclei from control embryos. Dilatation of the intercellular space and the loss of the intercellular gap junctions were often observed in bovine BVDV-exposed embryos.These findings provide evidence for the adverse effect of BVDV virus on the development of bovine embryos, which is related to irreversible changes in the ultrastructure of cell organelles.     

BVDV and BHV-1 Infections in Dairy Herds in Northern and Northeastern Thailand

Bulk milk samples from 220 dairy herds were collected at 9 public milk collection centres in the northeastern and northern Thailand, and a subset of 11 herds was selected for individual testing. The samples were tested for presence of antibodies to BVDV and BHV-1 using an indirect ELISA. The results from the bulk milk testing demonstrated a moderate level of exposure to BVDV and BHV-1 (73% and 67%, respectively). However, the low proportion of herds with high BVDV antibody-levels (13%) and the low within-herd seroprevalence of BVDV and BHV-1 in the 11 herds (24% and 5%, respectively), particularly among the young stock (15% and 0%, respectively), demonstrated a low prevalence of active BVDV infection and a low rate of reactivation of latent BHV-1. The presence of a self-clearance process was also indicated by the results from the individual testing. Moreover, a surprisingly low prevalence of BVDV and BHV-1 antibody-positive herds at one of the milk centres was found. This centre was established 5–10 years before the others. Our impression is that this reflects the self-clearance process, where consecutive replacement of imported infected animals without further spread has resulted in a nearly total elimination of the infections.     

The effect of high concentrations of cryoprotectants on the passage of bovine viral diarrhea virus through the zona pellucida of in vitro fertilized embryos.

The effect of high concentrations of cryoprotectants on the passage of bovine viral diarrhea virus (BVDV) through the zona pellucida (ZP) of intact bovine embryos during the pre-freezing step of cryopreservation was investigated in a series of experiments. In vitro fertilized (IVF) embryos at the blastocyst stage were exposed to 10(6) TCID50 BVDV (non-cytopathic NY-1 strain) in a 30% suspension of either ethylene glycol, glycerol, DMSO, or 2 M sucrose in physiological saline for 10 min at 20 degrees C. Subsequently, the embryos were washed free of residual unbound viral particles, and the ZP of some embryos were removed by micromanipulation. Groups of ZP-intact embryos, ZP-free embryonic cells and their respective ZP were then tested separately for the presence of virus. The infectious virus was detected in association with 81% (17/21) of samples containing non-micromanipulated ZP-intact embryos which were exposed to the virus and cryoprotectants and then washed 10 times and in 83% (43/53) of the samples containing only ZP from micromanipulated embryos (P > 0.05). The virus was not found in the samples containing the corresponding embryonic cells of embryos exposed previously to the virus and cryoprotectants. It was concluded that the transfer of embryos from the isotonic PBS solution into a highly hypertonic cryoprotectant solution did not cause the passage of BVDV through ZP and its entry to embryonic cells.     

Large scale in vivo risk assessment of bovine viral diarrhea virus (BVDV) transmission through transfer of bovine embryos produced via somatic cell nuclear transfer (SCNT)

The objective was to use the bovine viral diarrhea virus (BVDV) as a model to assess the risk of infectious disease transmission in the system of in vitro embryo production and transfer via somatic cell nuclear transfer (SCNT) technology. The risks of BVDV transmission in the SCNT embryo production were previously evaluated [1]. In that in vitro study, following standard operating procedures (SOP), including pre-nuclear transfer donor cell testing, oocyte decontamination and virus-free cell and embryo culture conditions, SCNT embryos produced were free of detectable viral RNA. The current study focused on the evaluation of the potential risk of disease transmission from SCNT embryos to recipients, and the risk of producing persistently infected animals via SCNT embryo transfer. Blood samples were collected from 553 recipients of SCNT embryos and 438 cloned calves and tested for the presence of BVDV viral RNA via a sensitive real time PCR method. All samples tested were negative. These results, in conjunction with the previous in vitro study, confirmed that the established SCNT embryo production and transfer system is safe and presents no detectable risk of disease transmission.