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.     

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.     

Early embryonic cells from in vivo-produced goat embryos transmit the caprine arthritis-encephalitis virus (CAEV)

The aim of this study was to investigate whether cells of early goat embryos isolated from in vivo-fertilized goats interact with the caprine arthritis-encephalitis virus (CAEV) in vitro and whether the embryonic zona pellucida (ZP) protects early embryo cells from CAEV infection. ZP-free and ZP-intact 8-16 cell embryos were inoculated for 2 h with CAEVat the 10(4) tissue culture infectious dose 50 (TCID50)/ml. Infected embryos were incubated for 72 h over feeder monolayer containing caprine oviduct epithelial cells (COECs) and CAEV indicator goat synovial membrane (GSM) cells. Noninoculated ZP-free and ZP-intact embryos were submitted to similar treatments and used as controls. Six days postinoculation, infectious virus assay of the wash fluids of inoculated early goat embryos showed typical CAEV-induced cytopathic effects (CPE) on indicator GSM monolayers, with fluids of the first two washes only. The mixed cell monolayer (COEC + GSM) used as feeder cells for CAEV inoculated ZP-free embryos showed CPE. In contrast, none of the feeder monolayers, used for culture of CAEV inoculated ZP-intact embryos or the noninoculated controls, developed any CPE. CAEV exposure apparently did not interfere with development of ZP-free embryos in vitro during the 72 h study period when compared with untreated controls (34.6 and 36% blastocysts, respectively, P > 0.05). From these results one can conclude that the transmission of infectious molecularly cloned CAEV-pBSCA (plasmid binding site CAEV) by embryonic cells from in vivo-produced embryos at the 8-16 cell stages is possible with ZP-free embryos. The absence of interactions between ZP-intact embryos and CAEV in vitro suggests that the ZP is an efficient protective embryo barrier.     

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.     

Susceptibility of pig embryos to porcine circovirus type 2 infection

The aim of the present study was to determine if porcine circovirus type 2 (PCV2) is able to infect embryonic cells of in vivo produced porcine embryos with and without zona pellucida (ZP). ZP-intact and ZP-free morulae (6-day post-insemination) and early blastocysts (7-day post-insemination), and hatched blastocysts (8-day post-insemination) were exposed to 10(5.0) TCID50 PCV2 per ml (strain 1121, fifth passage PK15). At 48 h post-incubation, the percentage of infected embryos and the percentage of viral antigen-positive cells per embryo were determined by indirect immunofluorescence (IF). Significantly different percentages of infected embryos were detected: 15% for ZP-free morulae, 50% for ZP-free early blastocysts and 100% for hatched blastocysts. The percentage of cells that expressed viral antigens was similar for the three stages of development. PCV2 exposure did not affect the in vitro development of the embryos during the 48 h study period. All ZP-intact embryos remained negative for viral antigens. In an additional experiment the diameter of the channels in the porcine ZP was determined. After incubation of early blastocysts with fluorescent microspheres of three different sizes, beads with a diameter of 20 nm and beads with a diameter of 26 nm crossed the zona whereas beads with a diameter of 200 nm did not. In conclusion, it can be stated that PCV2 is able to replicate in in vivo produced ZP-free morulae and blastocysts and that the susceptibility increases during development. The ZP forms a barrier to PCV2 infection, but based on the size of the channels in the ZP the possibility that PCV2 particles cross the ZP cannot be excluded.     

Maedi-Visna virus was detected in association with virally exposed IVF-produced early ewes embryos

The objective of this study was to determine whether MVV can be transmitted by ovine embryos produced in vitro and whether the zona pellucida (ZP) provides any protection against MVV infection.Zona pellucida (ZP)-intact and ZP-free embryos, produced in vitro, at the 8-16 cell stage, were cocultured for 72h in an insert over an ovine oviduct epithelial cell (OOEC)-goat synovial membrane (GSM) cell monolayer that had been previously infected with MVV (K1514 strain). The embryos were then washed and transferred to either direct contact or an insert over a fresh GSM cell monolayer for 6 h. The presence of MVV was detected using RT-PCR on the ten washing fluids and by the observation of typical cytopathic effects (CPE) in the GSM cell monolayer, which was cultured for 6 weeks.This experiment was repeated 4 times with the same results: MVV viral RNA was detected using RT-PCR in the first three washing media, while subsequent baths were always negative. Specific cytopathic effects of MVV infection and MVV-proviral DNA were detected in GSM cells that were used as a viral indicator and cocultured in direct contact or as an insert with MVV-exposed ZP-free embryos. However, no signs of MVV infection were detected in cells that were cocultured with exposed ZP-intact or non-exposed embryos.This study clearly demonstrates that (i) in vitro, ZP-free, early ovine embryos, which had been exposed to 10³ TCID₅₀/m MVV in vitro, are capable of transmitting the virus to susceptible GSM target cells, and that (ii) the IETS recommendations for handling in vivo produced bovine embryos (use of ZP-intact embryos without adherent material and performing ten washes) are effective for the elimination of in vitro MVV infection from in vitro produced ovine embryos. The absence of interaction between ZP-intact embryos and MVV suggests that the in vitro produced embryo zona pellucida provides an effective protective barrier.     

Can bluetongue virus (BTV) be transmitted via caprine embryo transfer?

The three objectives of this study were to investigate whether cells of early goat embryos isolated from in vivo fertilized goats interact with bluetongue virus (BTV) in vitro, whether the embryonic zona pellucida (ZP) protects early embryo cells from BTV infection, and whether the 10 wash cycles recommended by the International Embryo Transfer Society (IETS) for bovine embryos effectively decontaminates caprine embryos exposed to Bluetongue Virus (BTV) in vitro. Donor goats and bucks were individually screened and tested negative for the virus by RT-PCR detection of BTV RNA in circulating erythrocytes. ZP-free and ZP-intact 8-16 cell embryos were co-cultured for 36 h in an insert over a Vero cell monolayer infected with BTV. Embryos were washed 10 times in accordance with IETS recommendations for ruminant and porcine embryos, before being transferred to an insert on BTV indicator Vero cells for 6 h, to detect any cytopathic effects (CPE). They were then washed and cultured in B2 Ménézo for 24 h. Non-inoculated ZP-free and ZP-intact embryos were submitted to similar treatments and used as controls.The Vero cell monolayer used as feeder cells for BTV inoculated ZP-free and ZP-intact embryos showed cytopathic effects (CPE). BTV was found by RT-qPCR in the ten washes of exposed ZP-free and ZP-intact embryos. In the acellular medium, the early embryonic cells produced at least 10^2.5 TCID₅₀/ml. BTV RNA was detected in ZP-free and ZP-intact embryos using RT-qPCR.All of these results clearly demonstrate that caprine early embryonic cells are susceptible to infection with BTV and that infection with this virus is productive. The washing procedure failed to remove BTV, which indicates that BTV could bind to the zona pellucida.     

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.     

Damage of zona pellucida reduces the developmental potential and quality of porcine circovirus type 2–infected oocytes after parthenogenetic activation

The present aimed to study if porcine circovirus type 2 (PCV2), which adhered to zona pellucida (ZP), was able to enter mature porcine oocytes with intact and damaged ZP. Four groups, including uninfected ZP-intact oocytes (UOZI), uninfected ZP-damaged oocytes (UOZD), PCV2-infected ZP-intact oocytes (POZI), and PCV2-infected ZP-damaged oocytes (POZD) were studied. The oocytes were incubated with 1 mL minimum essential medium, containing 3.1 × 10⁸ copies of PCV2 DNA for 1 hour. Mechanical procedure of the insertion by microneedle induced injuries to the ZP of porcine oocytes. At the blastocyst stage, the percentage of PCV2-infected embryos and the ratio of viral antigen-positive cells per embryo were determined by indirect immunofluorescence. To assess the effect of ZP injury on the developmental competence and quality of porcine PCV2-infected oocytes after parthenogenetic activation, blastocyst formation rates and terminal deoxynucleotidyl transferase–mediated deoxyuridine triphosphate nick-end labeling staining were analyzed. Moreover, real-time polymerase chain reaction was used to evaluate the expression of genes related to apoptosis and pluripotency at different developmental stages. The results of indirect immunofluorescence showed that only POZD group presented PCV2-infected embryos and viral-positive cells. The blastocyst rate of POZD group dropped down to approximately half of POZI group's (7.1 ± 1.5 vs. 14.5 ± 3.3). At the blastocyst stage, ZP injury increased apoptotic index of PCV2-infected embryos. The relative expression levels of Caspase 3 were higher in POZD group than the ones in POZI group at the two- and four-cell stages (not statistically significant). Compared with the one in POZI group, the ratio of antiapoptotic Bcl-xl gene to proapoptotic Bax gene, an indicator of the ability to resist apoptosis, was lower in POZD group at the one-cell stage, but higher at the two- and four-cell stages. Expression levels of Oct4 and Nanog associated with pluripotency were lower in POZD group than the ones in POZI group at the morula stage (not statistically significant). Noteworthily, the expression of Nanog was significantly lower in POZD group versus POZI group (P < 0.05), whereas relative expression of Oct4 was significantly higher in the former at the blastocyst stage (P < 0.01). In conclusion, PCV2, which attached to ZP, was able to enter mature porcine oocytes with damaged ZP and subsequently reduced the developmental competence and quality of the oocytes after parthenogenetic activation.     

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.     

Nitric oxide as an endogenous mutagen for Sendai virus without antiviral activity

Nitric oxide (NO) may affect the genomes of various pathogens, and this mutagenesis is of particular interest for viral pathogenesis and evolution. Here, we investigated the effect of NO on viral replication and mutation. Exogenous or endogenous NO had no apparent antiviral effect on influenza A virus and Sendai virus. The mutagenic potential of NO was analyzed with Sendai virus fused to a green fluorescent protein (GFP) gene (GFP-SeV). GFP-SeV was cultured in SW480 cells transfected with a vector expressing inducible NO synthase (iNOS). The mutation frequency of GFP-SeV was examined by measuring loss of GFP fluorescence of the viral plaques. GFP-SeV mutation frequency in iNOS-SW480 cells was much higher than that in parent SW480 cells and was reduced to the level of mutation frequency in the parent cells by treatment with an NO synthase (NOS) inhibitor. Immunocytochemistry showed generation of more 8-nitroguanosine in iNOS-SW480 cells than in SW480 cells without iNOS transfection. Authentic 8-nitroguanosine added exogenously to GFP-SeV-infected CV-1 cells increased the viral mutation frequency. Profiles of the GFP gene mutations induced by 8-nitroguanosine appeared to resemble those of mutations occurring in mouse lungs in vivo. A base substitution that was characteristic of both mutants (those induced by 8-nitroguanosine and those occurring in vivo) was a C-to-U transition. NO-dependent oxidative stress in iNOS-SW480 cells was also evident. Together, the results indicate unambiguously that NO has mutagenic potential for RNA viruses such as Sendai virus without affecting viral replication, possibly via 8-nitroguanosine formation and cellular oxidative stress.     

Rescue of a positive stranded RNA virus from antigen negative neuroblastoma cells.

Single cell clones of latently infected mouse neuroblastoma cells were isolated from a culture chronically infected with mouse hepatitis virus in the presence of an antiviral antibody. These cell clones did not produce infections virus or exhibit viral cytopathic effects during cultivation at 32, 37, or 39°C. Infectious virus was isolated from single cell clones via fusion with permissive cells using polyethylene glycol, but not after fusion with inactivated Sendai virus or following treatment with metabolic inhibitors. One cell clone (S-3) from which virus was rescued was negative for viral antigen by immunofluorescence. The S-3 cell clone and no demonstrable virus antigen by complement-fixation tests using cytoplasmic extracts or virus-specified proteins detectable by polyacrylamide gel electrophoresis. The rescued viruses exhibited a temperature dependent growth defect at 32°C and have been classified as cold sensitive mutants. This study suggests that a complete genome of a positive stranded RNA virus can remain latent in infected cells without the expression of detectable virus antigen.     

Can Coxiella burnetii be transmitted by embryo transfer in goats?

The detection of significant bacterial loads of Coxiella burnetii in flushing media and tissue samples from the genital tracts of nonpregnant goats represents a risk factor for in utero infection and transmission during embryo transfer. The aim of this study was to investigate (1) whether cells of early goat embryos isolated from in vivo–fertilized goats interact with C. burnetii in vitro, (2) whether the embryonic zona pellucida (ZP) protects early embryo cells from infection, and (3) the efficacy of the International Embryo Transfer Society (IETS) washing protocol for bovine embryos. The study was performed in triple replicate: 12 donor goats, certified negative by ELISA and polymerase chain reaction, were synchronized, superovulated, and subsequently inseminated by Q fever-negative males. Sixty-eight embryos were collected 4 days later by laparotomy. Two-thirds of the resulting ZP-intact and ZP-free 8- to 16-cell embryos (9-9, 11-11, and 4-4 in replicates 1, 2, and 3, respectively) were placed in 1 mL minimum essential medium containing 10⁹C. burnetii CBC1 (IASP, INRA Tours). After overnight incubation at 37 °C and 5% CO₂, the embryos were washed according to the IETS procedure. In parallel, the remaining third ZP-intact and ZP-free uninfected embryos (3-3, 5-5, and 2-2 in replicates 1, 2, and 3, respectively) were subjected to the same procedures, but without C. burnetii, thus serving as controls. The 10 washing fluids for all batches of each replicate were collected and centrifuged for 1 hour at 13,000 × g. The washed embryos and pellets were tested by polymerase chain reaction. Coxiella burnetii DNA was found in all batches of ZP-intact and ZP-free infected embryos after 10 successive washes. It was also detected in the first five washing fluids for ZP-intact embryos and in the first eight washing fluids for ZP-free embryos. None of the control batches (embryos and washing fluids) were found to contain bacterial DNA. These results clearly indicate that caprine early embryonic cells are susceptible to infection by C. burnetii. The bacterium shows a strong tendency to adhere to the ZP after in vitro infection, and the washing procedure recommended by the IETS for bovine embryos failed to remove it. The persistence of these bacteria makes the embryo a potential means of transmission to recipient goats. Further studies are needed to investigate whether the enzymatic treatment of caprine embryos infected by C. burnetii would eliminate the bacteria from the ZP.     

Studies of sperm from mutant mice suggesting that two neurotransmitter receptors are important to the zona pellucida-initiated acrosome reaction

Two sperm neurotransmitter receptor/channels, the glycine receptor (GlyR) and a nicotinic acetylcholine receptor containing an alpha7 subunit (alpha7nAChR) were previously shown to be important to the mouse acrosome reaction (AR) initiated by solubilized egg zona pellucida (ZP). Here, we investigated whether sperm from homozygous mutant mice with a single amino acid mutation in the alpha subunit of their GlyR and sperm from homozygous mutant mice with an engineered disruption of the gene for the nicotinic acetylcholine receptor alpha7 subunit could undergo the AR on ZP-intact eggs. Wild-type and mutant sperm were treated with 3-quinuclidinyl benzilate (QNB), known to be an inhibitor of the ZP-initiated AR (but shown in the present work not to inhibit the acetylcholine-initiated AR). The ZP-initiated AR on ZP-intact eggs should occur only in sperm not treated with QNB. The absence of such an increase in the untreated mutant sperm would demonstrate that such sperm were unable to respond to the intact ZP. The results demonstrated for the first time that GlyR mutant sperm do not undergo the AR on ZP-intact mouse eggs, and that their ability to fertilize is inhibited by 63% in vitro. Moreover, we found that GlyR mutant sperm exhibited normal capacitation and confirmed that they not undergo the AR initiated by solubilized mouse ZP. Our studies demonstrated for the first time that sperm from mutant alpha7nAChR mice exhibit normal capacitation, do not undergo the AR in response to acetylcholine, solubilized ZP or on ZP-intact eggs, and display a 25% reduction in fertilization in vitro. This is the first genetic evidence for the importance of the alpha7nAChR in the ZP-initiated AR. While defects in either the GlyR or the alpha7nAChR completely inhibit the ZP-initiated AR, fertilization by these mutant sperm can still occur in vitro, probably due to sperm that complete spontaneous AR on the ZP.     

In vitro exposure of the early mouse embryo to Herpes Simplex Virus-1 strain Wal

The causes of early embryonic death are not clearly understood, but one of them may be viral infection. To study the interaction between the virus and the undifierentiated cell, early mouse embryos in morula and blastocyst stages were exposed to Herpes Simplex Virus-1 WAL (HSV-1 WAL). In one group of a total of 167 embryos, 108 were exposed to HSV-1 WAL; the rest were maintained as controls. After washing in culture medium, these embryos were cultured on a murine fetal fibroblast monolayer for viral isolation. None showed cytopathic effects in the susceptible monolayer. In a second group, 140 empryos were exposed and 106 were maintained as controls. These embryos were cultured without a monolayer or washing to permit continuous viral contact. Eighty-seven of the exposed embryos and 74 control empryos developed normally 2 to 3 d post hatching with no morpnological differences between the two groups. No statistical differences were observed when the proportion of natched and degenerated embryos was compared. Our results indicated that the cells of early mouse embryos are not susceptible to HSV-1 WAL. We concluded that possibly the susceptibility of empryonic cells to viral agents partially depends on stage of differentiation.     

Cooperation between humoral factor(s) and Lyt-2+ T cells in effective clearance of Sendai virus from infected mouse lungs

The mechanism of cooperation between the L3T4+ and Lyt-2+ T cell subsets in effective clearance of Sendai virus from infected mouse lungs was studied by adoptive cell transfer using nude mice. Simultaneous transfer of a long-term-cultured Sendai virus-specific L3T4+ T cell line with L3T4+ cell-depleted immune spleen cell (L3T4-) fraction to infected nude mice could result in viral clearance, although single injection with either of these cells was not effective. Instead of the L3T4+ T cells, culture supernatants of the L3T4- T cell line or concanavalin A-stimulated mouse spleen cells and mouse serum immunized with the virus were also active in the cooperative viral clearance with L3T4- fraction. The role of the Sendai virus-sensitized L3T4- cell fraction in cooperative viral clearance with humoral factors could be replaced by neither T cell-deprived immune spleen cell fraction nor normal spleen cells. The 1,500 units of recombinant mouse interleukin 2 (IL-2), which was more than 12 times the IL-2 activity present in the supernatants of the T cell line or concanavalin A-stimulated spleen cells, failed to clear the virus in combination with the L3T4- fraction. Monoclonal antibodies to Sendai or mouse hepatitis viruses were also effective in the cooperative antiviral activity. IL-2 activity was not detected in these monoclonal antibodies and the mouse immune serum. Single injection of any humoral factors failed to clear the virus. These results indicate that Sendai virus-sensitized Lyt-2+ subset of T cells acts cooperatively with humoral factor(s) other than IL-2 or Sendai virus-specific antibody present in supernatants of the T cell line, of concanavalin A-stimulated spleen cells or hybridomas, and in mouse serum immunized with the virus.     

Structural and viral association comparisons of bovine zonae pellucidae from follicular oocytes, Day-7 embryos and Day-7 degenerated ova

Bovine zonae pellucidae (ZP) from follicular oocytes and from embryos and degenerated ova collected on Day 7 from superovulated cows were examined by scanning electron microscopy, by dimensional measurement, and by total protein determination. The number of plaque-forming units (PFU) of infectious bovine rhinotracheitis virus (IBRV) that were associated with ZP-intact embryos/ova from each of the 3 sources after in vitro exposure was also determined.

Scanning electron microscopy revealed that the surfaces of Day-7 embryos and degenerated ova were smoother than those of follicular oocytes. Mean dimensional measurements of the diameter/thickness of the ZP from follicular oocytes, Day-7 embryos, and degenerated Day-7 ova were 156.7 μm/12.3μm, 161.3μm/12.6μm, and 158.9μm/12.8μm, respectively. The mean total protein per ZP of follicular oocytes, embryos, and degenerated ova was 0.331 μg, 0.349 μg, and 0.254 μg, respectively. Considerable variability existed within groups, but significantly greater quantities of IBRV were associated with follicular oocytes (mean PFU/oocyte = 68.1) than with Day-7 embryos (mean PFU/embryo = 43.0; P<0.05) or with Day-7 ova (mean PFU/ovum = 31.9; P<0.01).

The reliability of using an assay for IBRV associated with nontransferable ova/embryos as an indicator of the presence or absence of the virus in transferable embryos from the same collection (Day 7) was supported. Although structural differences between the ZPs of follicular oocytes and Day-7 embryos were observed in this study, further investigation is needed to determine if there are differences in the protective function of the respective ZPs.     

DNA methylation,retroviruses, and embryogenesis

By exposing preimplantation embryos to Moloney leukemia virus (M-MuLV), we have previously derived substrains of mice designated as Mov-1-Mov-13 which genetically transmit the virus from one generation to the next. In some of the substrains the inserted viral genome becomes activated at specific stages of embryogenesis and the available evidence suggests that these viral genomes are developmentally regulated. To investigate the effect of cellular differentiation on virus expression, M-MuLV was introduced either into preimplantation or postimplantation mouse embryos or into embryonal carcinoma (EC) cells. Whereas preimplantation embryos or EC cells are not permissive for virus expression, efficient replication occurred in postimplantation embryos or in differentiated cell lines. The viral genomes introduced into early embryonal cells were highly methylated and noninfcctious when analyzed in the adult. In contrast, viral genomes introduced into postimplantation embryos or into differentiated cells remained unmethylated and were infectious in a transfection assay. These results demonstrate an efficient de novo methylation activity which appears to be involved in repression of genes introduced into pluripotent embryonal cells and which is not observed in cells of the postimplantation embryo or in differentiated cells in tissue culture.     

Risk of Coxiella burnetii transmission via embryo transfer using in vitro early bovine embryos

Coxiella burnetii, an obligate intracellular bacterium of worldwide distribution, is responsible for Q fever. Domestic ruminants are the main source of infection for humans. The objectives of this study were to determine (1) whether C. burnetii would adhere to the intact zona pellucida (ZP-intact) of early in vitro–produced bovine embryos; (2) whether the bacteria would adhere to or infect the embryos (ZP-free) after in vitro infection; and (3) the efficacy of the International Embryo Transfer Society (IETS) washing protocol. One hundred and sixty, eight- to 16-cell bovine embryos produced in vitro, were randomly divided into 16 batches of 10 embryos. Twelve batches (eight ZP-intact and four ZP-free) were incubated in a medium containing C. burnetii CbB1 (Infectiologie Animale et Santé Publique, Institut National de Recherche Agronomique Tours, France). After 18 hours of incubation at 37 °C and 5% CO₂ in air, the embryos were washed in 10 successive baths of a PBS and 5% fetal calf serum solution in accordance with the IETS guidelines. In parallel, four batches (two ZP-intact and two ZP-free) were subjected to similar procedures but without exposure to C. burnetii to act as controls. Ten washing fluids from each batch were collected and centrifuged for 1 hour at 13,000× g. The embryos and wash pellets were tested using conventional polymerase chain reaction. C. burnetii DNA was found in all ZP-intact and ZP-Free embryos after 10 successive washes. It was also detected in the first four washing fluids for ZP-intact embryos and in the 10th wash fluid for two of the four batches of ZP-free embryos. In contrast, none of the embryos or their washing fluids in the control batches were DNA positive. These results demonstrate that C. burnetii adheres to and/or penetrates the early embryonic cells and the ZP of in vitro bovine embryos after in vitro infection, and that the standard washing protocol recommended by the IETS for bovine embryos, failed to remove it. The persistence of these bacteria after washing makes the embryo a potential means of transmission of the bacterium during embryo transfer from infected donor cows to healthy recipients and/or their offspring. Further studies are required to investigate whether enzymatic and/or antibiotic treatment of bovine embryos infected by C. burnetii would eliminate the bacteria from the ZP and to verify if similarly results are obtained with in vivo–derived embryos.