Bacteria detected in the genital tract, semen or pre-ejaculatory fluid of Swedish stallions from 2007 to 2017

Semen is collected and processed from a variety of animal species for use in artificial insemination breeding programmes. Because of the inherent nature of the semen collection process, bacterial contamination of the ejaculate is a common occurrence. Additionally, manipulation of the ejaculate during processing in the laboratory can expose the sample to possible introduction of bacterial contamination. If preventative measures at the stud fail to adequately control these risks, decreases in semen quality, dose longevity and fertility may occur. Multiple mammalian and non-mammalian sources have been identified as origins of contamination in the stud. Knowledge of these sources has aided the industries in developing strategies that help in controlling the introduction of contaminant bacteria in extended semen. A primary step in minimizing contamination is in the practice of good hygiene by stud personnel. Prudent general sanitation protocols should also be followed in the laboratory, animal housing and semen collection areas. Cleanliness and attention to the actual semen collection process can also aid in reducing bacterial load originating from the stud semen donor. Attentiveness to all of these steps significantly contributes to an overall reduction in the type and amount of bacterial contamination. However, their complete elimination still remains unavoidable. To address residual bacteria load in the sample, antimicrobials are commonly used in semen extenders intended to promote in vitro sperm longevity beyond that of a few hours. Current research by the animal industries continues in the selection and prudent use of antimicrobials that will lead to the success and sustainability of this modality in controlling bacterial contamination.

ABSTRACT Bacteria in a biofilm community have increased tolerance to antimicrobial therapy. To characterize the role of biofilms in equine endometritis, six mares were inoculated with lux-engineered Pseudomonas aeruginosa strains isolated from equine uterine infections. Following establishment of infection, the horses were euthanized and the endometrial surfaces were imaged for luminescence to localize adherent lux-labeled bacteria. Samples from the endometrium were collected for cytology, histopathology, carbohydrate analysis, and expression of inflammatory cytokine genes. Tissue-adherent bacteria were present in focal areas between endometrial folds (6/6 mares). The Pel exopolysaccharide (biofilm matrix component) and cyclic di-GMP (biofilm-regulatory molecule) were detected in 6/6 mares and 5/6 mares, respectively, from endometrial samples with tissue-adherent bacteria (P 0.05) in the number of inflammatory cells in the endometrium between areas with and without tissue-adherent bacteria. Neutrophils were decreased (P < 0.05) in areas surrounding tissue-adherent bacteria compared to those in areas free of adherent bacteria. Gene expression of interleukin-10, an immune-modulatory cytokine, was significantly (P < 0.05) increased in areas of tissue-adherent bacteria compared to that in endometrium absent of biofilm. These findings indicate that P. aeruginosa produces a biofilm in the uterus and that the host immune response is modulated focally around areas with biofilm, but inflammation within the tissue is similar in areas with and without biofilm matrix. Future studies will focus on therapeutic options for elimination of bacterial biofilm in the equine uterus.

In an attempt to evaluate the possible relationship between the microbial flora in the stallion ejaculate and its ability to freeze,three ejaculates from five stallions were frozen using a standard protocol. Before freezing, an aliquot was removed for bacteriological analysis. Bacterial growth was observed in all the ejaculates studied. The isolated microorganisms were:Staphylococcus spp. and Micrococcus spp. (in all the stallions), beta-haemolytic Streptococcus (in stallions 3 and 4), Corynebacterium spp. (in stallions 1, 3-5), Rhodococcus spp. (in stallion number 2), Pseudomonas spp. (in stallion number 1) and Klebsiella spp. (in stallions 1, 3 and 5). The presence and richness of Klebsiella and beta-haemolytic Streptococcus in the ejaculate were related to two sperm variables post-thaw,namely the proportion of dead spermatozoa (ethidium+ cells; r = 0.55, p < 0.05) and the amplitude of lateral displacement of the sperm head (ALH, microm; r = -0.56, p < 0.05), respectively.The degree of growth of Corynebacterium spp. in the ejaculate was positively correlated with the percentage of spermatozoa showing high caspase activity post-thaw(r = 0.62, p < 0.05). The presence and number of colonies of beta-haemolytic Streptococcus were negatively correlated (r = -0.55, p < 0.05) with low sperm caspase activity. It is concluded that the microbial flora of the equine ejaculate maybe responsible for some of the sublethal damage experimented by the spermatozoa during cryopreservation.