Attachment of Coxiella burnetii to the zona pellucida of in vitro produced goat embryos.

Previous work demonstrated that after infection of in vivo derived caprine embryos, Coxiella burnetti (C. burnetii) showed a strong tendency to adhere to the zona pellicida (ZP). To investigate the risk of C. burnetii transmission via embryo transfer of in vitro-produced goat embryos the aim of this study was, (i) to evaluate the ability of C. burnetii to adhere to the intact zona pellicida of in vitro-produced goat embryos and to determine by confocal microscopy the location of the bacteria, (ii) to test the efficacy of IETS recommended rules for the washing of bovine embryos to eliminate C. burnetii. One hundred ZP-intact caprine embryos, produced in vitro, at the 8 to 16 cell stage, were randomly divided into 11 batches of eight to nine embryos. Nine batches were incubated for 18 h with 109Coxiella/ml of CbB1 strain (IASP, INRA Tours). The embryos then were recovered and washed in batches in 10 successive baths following the IETS guidelines. In parallel, two batches of embryos were subjected to similar procedures but without exposure to C. burnetii, to serve as the control group. One of the nine batches of infected embryos and one of the two non-infected control batches were separated to perform immunolabeling to locate the bacteria. C. burnetii DNA was detected by C-PCR in all eight batches of infected embryos after 10 successive washings. However, bacterial DNA was not detected in the embryo control batch. The first five washing media of the infected group were consistently found to be positive and Coxiella DNA was detected in the wash bath up to the 10th wash for two batches. After immunolabeling, the observation of embryos under confocal microscopy allowed C. burnetti to be found on the external part of the zona pellucida without deep penetration. This study clearly demonstrates that C. burnetii, after in vitro infection at 109Coxiella/ml, stick strongly to the external part of the zona pellucida of in vitro produced caprine embryos without deap penetration and that the 10 washings protocol recommended by IETS to eliminate the pathogenic agents of bovine embryos is unable to eliminate these bacteria from in vitro-produced goat embryo.

Can Chlamydia abortus be transmitted by embryo transfer in goats?

The objectives of this study were to determine (i) whether Chlamydia abortus would adhere to or penetrate the intact zona pellucida (ZP-intact) of early in vivo-derived caprine embryos, after in vitro infection; and (ii) the efficacy of the International Embryo Transfer Society (IETS) washing protocol for bovine embryos. Fifty-two ZP-intact embryos (8-16 cells), obtained from 14 donors were used in this experiment. The embryos were randomly divided into 12 batches. Nine batches (ZP-intact) of five embryos were incubated in a medium containing 4 × 10(7)Chlamydia/mL of AB7 strain. After incubation for 18 hours at 37 °C in an atmosphere of 5% CO2, the embryos were washed in batches in 10 successive baths of a phosphate buffer saline and 5% fetal calf serum solution in accordance with IETS guidelines. In parallel, three batches of ZP-intact embryos were used as controls by being subjected to similar procedures but without exposure to C. abortus. The 10 wash baths were collected separately and centrifuged for 1 hour at 13,000 × g. The washed embryos and the pellets of the 10 centrifuged wash baths were frozen at -20 °C before examination for evidence of C. abortus using polymerase chain reaction. C. abortus DNA was found in all of the infected batches of ZP-intact embryos (9/9) after 10 successive washes. It was also detected in the 10th wash fluid for seven batches of embryos, whereas for the two other batches, the last positive wash bath was the eighth and the ninth, respectively. In contrast, none of the embryos or their washing fluids in the control batches were DNA positive. These results report that C. abortus adheres to and/or penetrates the ZP of in vivo caprine 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 goats to healthy recipients and/or their offspring. Nevertheless, the detection of C. abortus DNA by polymerase chain reaction does not prove that the bacteria found was infectious. Further studies are required to investigate whether enzymatic and/or antibiotic treatment of caprine embryos infected by C. abortus would eliminate the bacteria from the ZP.

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.

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 10(9)C. 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.

The risk of small ruminant lentivirus (SRLV) transmission with reproductive biotechnologies: state-of-the-art review.

Reproductive biotechnologies are essential to improve the gene pool in small ruminants. Although embryo transfer (ET) and artificial insemination (AI) greatly reduce the risk of pathogen transmission, few studies have been performed to quantify this risk. The aim of this review is to contribute to the elements needed to evaluate the risk of lentivirus transmission in small ruminants (SRLV) during ET, from embryos produced in vitro or in vivo, and with the use of the semen destined for AI. The purpose is to consider the genetic possibilities of producing uninfected embryos from infected females and males or bearers of the SRLV genome. We have reviewed various studies that evaluate the risk of SRLV transmission through genital tissues, fluids, cells, and flushing media from female and male animals. We have only included studies that apply the recommendations of the International Embryo Transfer Society, to obtain SRLV-free offspring from infected female animals using ET, and the justification for using healthy male animals, free from lentivirus, as semen donors for AI. As such, ET and AI will be used as routine reproductive techniques, with the application of the recommendations of the International Embryo Transfer Society and World Organization for Animal Health.

Evaluation of bluetongue virus (BTV) decontamination techniques for caprine embryos produced in vivo.

The objective of this study was to investigate methods of decontaminating early goat embryos that had been infected in vitro with bluetongue virus (BTV). Embryos were isolated from in vivo-fertilized BTV-free goats. Zona pellucida (ZP)-intact 8 to 16 cell embryos were cocultured for 36 h in an insert over a Vero cell monolayer infected with BTV serotype 8. The embryos were then treated with one of five different washing procedures. The treatment standard (TS) comprised phosphate-buffered saline (PBS) + 0.4% BSA (five times over for 10 s), Hank's +0.25% trypsin (twice for 45 s), and then PBS + 0.4% BSA again (five times for 10 s). The four other washing procedures all included the same first and last washing steps with PBS but without BSA (five times for 10 s) and with PBS + 0.4% BSA (five times for 10 s), respectively. The intermediate step varied for each washing procedure. Treatment 1 (T1): 0.25% trypsin (twice for 45 s). Treatment 2 (T2): 0.25% trypsin (twice for 60 s). Treatment 3 (T3): 0.5% trypsin (twice for 45 s). Treatment 4 (T4): 1% hyaluronidase (once for 5 min). After washing, the embryos were transferred and cocultured with BTV indicator Vero cell monolayers for 6 h, to detect any cytopathic effects (CPE). The effectiveness of the different washing techniques in removing the virus was evaluated by RT-qPCR analysis. The TS, T1, T3, and T4 trypsin or hyaluronidase treatments did not eliminate BTV; Treatment 2 eliminated the virus from in vitro infected goat embryos.

Is caprine arthritis encephalitis virus (CAEV) transmitted vertically to early embryo development stages (morulae or blastocyst) via in vitro infected frozen semen?

The aim of this study was to determine, in vivo, whether in vitro infected cryopreserved caprine sperm is capable of transmitting caprine arthritis-encephalitis virus (CAEV) vertically to early embryo development stages via artificial insemination with in vitro infected semen. Sperm was collected from CAEV-free bucks by electroejaculation. Half of each ejaculate was inoculated with CAEV-pBSCA at a viral concentration of 10(4) TCID(50)/mL. The second half of each ejaculate was used as a negative control. The semen was then frozen. On Day 13 of superovulation treatment, 14 CAEV-free does were inseminated directly into the uterus under endoscopic control with thawed infected semen. Six CAEV-free does, used as a negative control, were inseminated intrauterine with thawed CAEV-free sperm, and eight CAEV-free does were mated with naturally infected bucks. Polymerase chain reaction (PCR) was used to detect CAEV proviral-DNA in the embryos at the D7 stage, in the embryo washing media, and in the uterine secretions of recipient does. At Day 7, all the harvested embryos were PCR-negative for CAEV proviral-DNA; however, CAEV proviral-DNA was detected in 8/14 uterine smears, and 9/14 flushing media taken from does inseminated with infected sperm, and in 1/8 uterine swabs taken from the does mated with infected bucks. The results of this study confirm that (i) artificial insemination with infected semen or mating with infected bucks may result in the transmission of CAEV to the does genital tack seven days after insemination, and (ii) irrespective of the medical status of the semen or the recipient doe, it is possible to obtain CAEV-free early embryos usable for embryo transfer.

Can caprine arthritis encephalitis virus (CAEV) be transmitted by in vitro fertilization with experimentally infected sperm?

For each of the five fertilization trials of the experiment, frozen semen was prepared for in vitro capacitation at a concentration of 1 × 10(7) spz/ml and divided into three groups. One group was used as a control, while the two others were inoculated with 100 µl/ml of either culture medium from non-infected cells (placebo group) or cell culture medium containing virus at a concentration of 10(5) TCID(50)/ml (infected group). A total of 789 oocytes were used for IVF. For each of the five trials a group of oocytes were used as a non-infected control and were found to be caprine arthritis-encephalitis virus (CAEV) free. The other oocytes were divided in two equal batches. Oocytes in the first batch were in vitro fertilized with CAEV infected sperm (infected group) and the second batch were fertilized with CAEV non-infected sperm (placebo and control groups). After IVF, the zygotes of each group were washed 12 times. The CAEV genome was not detected (using RT-PCR) in the washing media of either the control or placebo groups from each trial. In contrast, the first three washing media from the infected group were consistently found to be positive for the CAEV genome (5/5), whereas subsequent washing media were CAEV-free (P < 0.05). Zygotes obtained using all semen groups tested negative for both the provirus and genome of CAEV. These results clearly show that the first four washes were sufficient to remove viral particles from CAEV infected fertilization media and that CAEV-free embryos can be produced by IVF using spermatozoa infected in vitro by CAEV.

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) TCID(50)/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.

Presence of Maedi Visna virus (MVV)-proviral DNA in the genital tissues of naturally infected ewes.

Maedi Visna virus (MVV) causes progressive degenerative inflammatory disease in multiple organs including the lungs (pneumonia, 'maedi'), mammary gland, joints and nervous system (meningoencephalomyelitis, 'visna') in sheep. Maedi Visna Virus has been detected in macrophages of several tissues and epithelial cells in vivo: bone marrow, cells of the central nervous system, lung and bronchial tissues, milk epithelial cells recovered from milk samples and epithelial cells of mammary tissue. However, the presence of MVV in the genital tracts of naturally infected ewes has not previously been studied. The aim of this study was to use nested-PCR, targeting the gag gene, to determine whether genital tissues (ovaries, oviducts and uterus) from 83 ewes originating from various breeding herds in the South-East of France were positive for MVV-proviral DNA. Peripheral blood mononuclear cells (PBMC) tested positive for MVV-proviral DNA, using nested-PCR analysis, in 57.8% of ewes (48/83). The provirus was also identified in 47% (78/166) of the ovaries, 38.6% (64/166) of the oviducts and 45.8% (38/83) of the uteri sampled. These findings clearly demonstrate, for the first time, that tissue samples from the genital tract of ewes (ovary, oviduct and uterus) can be infected with MVV. This suggests that there is a risk of vertical and/or horizontal transmission of MVV during embryo transfer from embryos produced in vivo or in vitro.

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 10(3) TCID(50)/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.

Detection of viral genomes of caprine arthritis-encephalitis virus (CAEV) in semen and in genital tract tissues of male goat.

The aim of this study was to determine the infectious status of semen and genital tract tissues from male goat naturally infected with the caprine lentivirus. Firstly, polymerase chain reaction (PCR) was used to detect the presence of CAEV proviral-DNA in the circulating mononuclear cells, semen (spermatozoa and non-spermatic cells), and genital tract tissues (testis, epididymis, vas deferens, and vesicular gland) of nine bucks. RT-PCR was used to detect the presence of CAEV viral RNA in seminal plasma. Secondly, in situ hybridization was performed on PCR-positive samples from the head, body, and tail of the epididymis. CAEV proviral-DNA was identified by PCR in the blood cells of 7/9 bucks and in non-spermatic cells of the seminal plasma of 3/9 bucks. No CAEV proviral-DNA was identified in the spermatozoa fraction. The presence of CAEV proviral-DNA in non-spermatic cells and the presence of CAEV in the seminal plasma was significantly higher (p<0.01) in bucks with PCR-positive blood. Two of the three bucks with positive seminal plasma cells presented with at least one PCR-positive genital tract tissue. Proviral-DNA was found in the head (3/9), body (3/9), and tail (2/9) of the epididymis. In situ hybridization confirmed the presence of viral mRNA in at least one of each of these tissues, in the periphery of the epididymal epithelium. This study clearly demonstrates the presence of viral mRNA and proviral-DNA in naturally infected male goat semen and in various tissues of the male genital tract.

Potential risk of equine herpes virus 1 (EHV-1) transmission by equine embryo transfer.

The objective of this study was to determine whether the 10 wash cycles proposed by the International Embryo Transfer Society (IETS) for bovine embryos efficiently decontaminated equine embryos exposed to equine herpes virus 1 (EHV-1) in vitro. Donor mares and stallions were individually screened and shown to be negative for the virus by PCR detection of EHV-1 DNA in blood leukocytes, semen, and uterine lavages in which embryos were recovered. Twenty embryos were recovered and randomly assigned to one of two groups: 10 embryos were exposed for 24h to infectious EHV-1 at 10(6)TCID(50)/ml, and 10 embryos were used as negative controls. Exposed embryos were washed in accordance with IETS recommendations for ruminant and porcine embryos, before being incubated for 24 h with semiconfluent rabbit kidney (RK13) cells to detect any cytopathic effects (CPE), and finally tested for the presence of EHV-1 viral DNA by PCR. The embryo washing media were also assayed for the virus on RK 13 cells and by PCR. Control embryos were neither exposed to the virus nor washed. EHV-1 was not found in the control embryos, or in the last five washes of the exposed embryos. However, the virus was detected in 7/10 of the embryos exposed to EHV-1 for 24h, as well as in the first five washes of the embryos. The gradual disappearance of EHV-1 from the 10 successive wash solutions from the exposed embryos and the detection of viral DNA in 7/10 washed embryos by PCR, demonstrated that the washing procedure was unable to remove EHV-1 and suggested that EHV-1 could be attached to the acellular layer surrounding embryos (zona pellucida or capsule) or had penetrated the embryo.

Cultured early goat embryos and cells are susceptible to infection with caprine encephalitis virus.

Zona-pellucida-free embryos at 8-16 cell stage were co-cultured for 6 days in an insert over a mixed cell monolayer infected with CAEV-pBSCA. Embryos were washed and transferred to an insert on CAEV indicator goat synovial membrane cells for 6 h, then they were washed and cultivated in B2 Ménézo for 24 h, finally, embryo cells were dissociated and cultivated on a feeder monolayer for 8 days. After 5 weeks, multinucleated giant cells typical of CAEV infection were observed in indicator GSM cell monolayers. In the acellular medium, the early embryonic cells produced at least 10(3.25) TCID50/ml over 24 h. The monolayer of cultivated embryonic cells developed cytopathic lesions within 8 days, and CAEV RNA, CAEV proviral DNA and protein p28 of the capsid were detected. All of these results clearly demonstrate that caprine early embryonic cells are susceptible to infection with CAEV and that infection with this virus is productive.

Detection of ovine lentivirus in the cumulus cells, but not in the oocytes or follicular fluid, of naturally infected sheep.

The aim of this study was to examine the Maedi-Visna virus (MVV) infection status of oocytes, cumulus cells, and follicular fluid taken from 140 ewes from breeding flocks. MVV proviral-DNA and MVV RNA were detected using nested-PCR and RT-PCR MVV gene amplification, respectively in the gag gene. Nested-PCR analysis for MVV proviral-DNA was positive in peripheral blood mononuclear cells in 37.1% (52/140) of ewes and in 44.6% (125/280) of ovarian cortex samples. The examination of samples taken from ovarian follicles demonstrated that 8/280 batches of cumulus cells contained MVV proviral-DNA, whereas none of the 280 batches of oocytes taken from the same ovaries and whose cumulus cells has been removed, was found to be PCR positive. This was confirmed by RT-PCR analysis showing no MVV-viral RNA detection in all batches of oocytes without cumulus cells (0/280) and follicular fluid samples taken from the last 88 ovaries (0/88). The purity of the oocyte fraction and the efficacy of cumulus cell removal from oocytes was proved by absence of granulosa cell-specific mRNA in all batches of oocytes lacking the cumulus cells, using RT-PCR. This is the first demonstration that ewe cumulus cells harbor MVV genome and despite being in contact with these infected-cumulus cells, the oocytes and follicular fluid remain free from infection. In addition, the enzymatic and mechanical procedures we used to remove infected-cumulus cells surrounding the oocytes, are effective to generate MVV free-oocytes from MVV-infected ewes.

Effect of quinolone treatment on selection and persistence of quinolone-resistant Escherichia coli in swine faecal flora.

AIMS: To study the effect of oral administration of a quinolone on emergence of resistance in an indicator bacterial species from faecal flora. METHODS AND RESULTS: Quinolone resistance was studied in Escherichia coli obtained from the faecal contents of pigs housed in nine commercial farrow-to-finish herds in France after administration of flumequine to sows. The percentage of quinolone-resistant E. coli increased in the faeces of sows after administration of flumequine (mean 21.78% at day 7 vs 6.42% before treatment for nalidixic acid) and then decreased (mean 12.6 and 10.4 at days 30 and 60, respectively for nalidixic acid), being not significantly different from initial values 1 month post-treatment. In young pigs, the proportion of resistant strains was lower and decreased over rearing period. Moreover, changes over time of both total E. coli and the proportion of resistant bacteria exhibited great inter-individual variability. CONCLUSIONS: Restoration of susceptible faecal flora occurred within 2 months after flumequine treatment. SIGNIFICANCE AND IMPACT OF THE STUDY: Effect of flumequine treatment of sows on the quinolone resistance of faecal E. coli of both sows and their progeny is noticeable but transitory.

Epidemiosurveillance of antimicrobial compound resistance of Staphylococcus intermedium clinical isolates from canine pyodermas.

In a retrospective study, 131 Staphylococcus intermedius strains isolated from apparently healthy dogs, and 187 Staphylococcus intermedius strains isolated from dog pyodermas in the clinical microbiology laboratory at the National Veterinary School in Nantes, during three successive periods: 1986-87, 1992-93 and 1995-96, were investigated and compared for their antimicrobial susceptibility. Results indicated that 60% to 65% of the strains were susceptible to Chloramphenicol and Doxycyclin, 65% to 80% of the strains were susceptible to macrolides (Erythromycin, Lincomycin and Clindamycin) and to Trimethoprim/Sulfonamide association. More than 95% of the strains were susceptible to three betalactamins tested: Oxacillin, Amoxycillin/Clavulanic acid, Cephalexin, to Gentamicin, to Fucidic Acid and to two quinolones: Enrofloxacin and Marbofloxacin. This last group is made up of choice antibacterials for the treatment of dog pyoderma. Many different resistance patterns were observed in each period with no really predominant profile, because of low plasmidic vs chromosomal balance of the genetic basis of antibacterial resistance in Staphylococcus intermedius. However, the proportion of multiresistant (> or = 3 drugs) strains increased from 10.8% in the first period, to 28% in the third period. This increased frequency of resistance suggests strongly that, as in Staphylococcus aureus human infections, the prescription of antibiotic compounds increases the prevalence of resistant strains.

Importance of the hour of sampling in the lymphoblastic transformation assay of sheep peripheral blood lymphocytes.

This paper describes the effect of the nycthemeral cycle on the lymphocyte response of sheep to different mitogens (PHA, Con A and PWM). A considerable decline in the lymphocyte response was evident in the afternoon and early in the morning in all 6 animals tested. Three peak responses were identified during a 24 hour study period, at 14.00 h, 24.00 h and 08.00 h. The results presented here suggest that this variation in lymphocyte response is a meaningful difference in the response ability of individual lymphocytes. Factors affecting the number of leukocytes and the proportion of different types of lymphocytes in peripheral blood might be the essential causes of variation. To obtain an accurate indication of an individual's immunocompetence, it is important to make a preliminary determination of the optimal hour for sampling. If this is not possible, all the samples must be taken at the same hour on each test day, in order to make significant comparisons.

Blastogenic response of peripheral blood lymphocytes from multiparous pregnant ewes.

The immunocompetence of pregnant multiparous ewes was investigated with respect to the blastogenic response of peripheral blood lymphocytes of (PBL) to three mitogens: PHA, Con A, and PWM. The profile of PBL responses shows 1) progressive suppression at 36 and 66 days of gestation, 2) enhanced response at 97 days of gestation, which approaches the mean values observed at the premating period, and 3) a redecline of the response at 137 days of gestation to depressed values lower than observed at 36 and 66 days of gestation. The results suggest that mitogen-treated lymphocytes were depressed and that the immunodepressive factor(s), which can influence lymphocytes at the systemic level, may be involved in the maintenance of the ovine fetal semiallograft.

Lymphoblastic transformation assay of sheep peripheral blood lymphocytes: a new rapid and easy-to-read technique.

A new micro-method was used to evaluate in vitro sensitivity of ovine peripheral blood lymphocytes (PBL) to different non specific mitogens (pHA, Con A, PWM) and to investigate the interest of a colorimetric assay for measurement of transformed lymphocytes. The results showed that sheep PBL in flat-bottomed microplates responded optimally at a cell density of 8 X 10(6) cells/ml to PHA (2.5 micrograms/ml), Con A (5 micrograms/ml) and PWM (5 micrograms/ml). The colorimetric assay using a tetrazolium salt (MTT), for measuring the transformed lymphocytes, is very well correlated with the classical method of [3H]thymidine incorporation. This new revelation technique of the mitogenic response improve the technical value of the assay, which is more rapid and easy-to-read, without diminishing the biological value.