Effects of oviductal proteins, including heat shock 70 kDa protein 8, on survival of ram spermatozoa over 48 h in vitro.

Following insemination, ram spermatozoa are transported to the isthmus region of the oviduct where they bind to the oviductal epithelial cells (OEC), remaining viable for several hours. The aim of the present study was to begin to decipher which component(s) of the ewe oviduct actively participates in maintaining the viability of ram spermatozoa. A series of experiments was conducted to investigate whether: (1) soluble OEC apical plasma membrane proteins (sAPM) isolated from ewes prolong survival of ram spermatozoa over an extended (48 h) coincubation period at 39 degrees C; (2) a recombinant form of one of these oviductal proteins, namely heat shock 70 kDa protein 8 (HSPA8), prolongs survival of ram spermatozoa; and (3) pretreatment with HSPA8 antibody compromises the ability of sAPM to prolong the survival of ram spermatozoa. Both sAPM and recombinant HSPA8 had a beneficial effect on the viability of ram spermatozoa during coincubation, although both these effects were dose dependent. In contrast, pretreatment with HSPA8 antibody significantly negated the ability of sAPM to maintain the viability of ram spermatozoa. These findings suggest that HSPA8 is an active component of the ewe oviduct that participates in maintaining the viability of ram spermatozoa. This is a potentially valuable observation given that there is a great deal of room for improving existing diluents for storing fresh ram semen.

Validation of an experimental strategy for studying surface-exposed proteins involved in porcine sperm-oviduct contact interactions.

Previous experiments have shown that boar sperm survival in vitro is enhanced when co-incubated with a solubilised protein extract of porcine oviducal apical plasma membrane proteins. Here, we examine the hypothesis that the effects are mediated by direct oviduct-sperm contact and use in situ biotinylation of the oviducal epithelial surface to trace the surface-exposed biotinylated proteins through purification and solubilisation steps. We have also examined the effectiveness of mechanical scraping as a method of recovering oviducal epithelial proteins. We show that a subset of proteins originally exposed at the oviducal surface eventually bind to spermatozoa during incubation in vitro, but also show that a different protein subset is implicated if the sperm incubation is performed with proteins that had been biotinylated after (ex situ) extraction from the oviduct. Apical plasma membrane fractions biotinylated after purification contained many more biotinylated protein bands than preparations labelled before purification and multiple protein bands were eventually found to associate with spermatozoa. Although the evidence presented here supports the hypothesis that protein(s) anchored to the oviducal epithelium bind populations of spermatozoa directly and may have a role in the enhancement of sperm viability, it also shows that the choice of investigative technique exerts a major influence on experimental outcomes.

Harnessing the biology of the oviduct for the benefit of artificial insemination.

Spermatozoa fulfil a single role, namely achieving syngamy by transporting the haploid genome to their counterpart gamete, the oocyte. Simple as this may seem, it is fraught with many difficulties, especially in the face of biological processes that enable females to select spermatozoa after they have mated multiply with several males. Conversely, the female reproductive tract sequesters a privileged sperm subpopulation in the oviductal isthmus for variable periods of time, releasing them when the time is opportune for fertilisation. Recent studies of sperm transport in the female reproductive tract suggest that these phenomena involve signalling dialogues between spermatozoa and the female reproductive tract environment. Opportunities for mutual signalling are immense but have received relatively little attention. The oviduct is an organ of crucial significance in modulating sperm function and may be one of the most important sites for determining many aspects of sperm selection and competition. The oviductal environment possesses the potential for enhancing sperm survival, suppressing and activating sperm motility as required, and responds to the arrival of spermatozoa by producing novel proteins. While the biological nature of the sperm-oviduct dialogue is interesting for its own sake, the mechanisms that govern these processes offer opportunities for the improvement of artificial insemination procedures. If oviductal proteins enhance sperm survival, they offer opportunities for the development of long-life semen diluents. Conversely, if we understood the basis of sperm selection we may be able to concentrate on identifying and using only the best sperm subpopulations for improved animal breeding efficiency.

In vitro maintenance of boar sperm viability by a soluble fraction obtained from oviductal apical plasma membrane preparations.

Oviductal apical plasma membrane fractions have been successfully used to provide an in vitro model to study the role of direct membrane contact in sperm-oviduct interactions. Apical plasma membrane preparations from pig oviductal tissues show a dose-response in their ability to maintain boar sperm viability in vitro. Membrane preparations obtained from other tissues (lung and duodenum) are incapable of maintaining boar sperm viability to the same extent as oviductal tissue. The present study examined the validity of two hypotheses that arise from current knowledge of sperm-oviduct interactions, namely, that (i) apical plasma membranes prepared from ampullar regions of the oviduct are less effective than those from isthmus regions, and (ii) sperm survival is more effective in apical plasma membrane preparations derived from follicular phase oviducts than those derived from luteal phase oviducts. Both hypotheses were proved false. The nature of the active component(s) in the oviductal apical plasma membrane fractions was further investigated. Heat treatment (100 degrees C for 20 min) diminished the capacity of membranes to support boar sperm viability. Furthermore, a soluble salt-extracted fraction obtained from oviductal apical plasma membrane preparations was biologically active and supported boar sperm viability in vitro. This may indicate that the active factor(s) responsible for the maintenance of boar sperm viability is not an integral part of oviductal membranes and is peripherally bound to these membranes.