The oocyte cumulus complex regulates mouse sperm migration in the oviduct.

As the time of ovulation draws near, mouse spermatozoa move out of the isthmic reservoir, which is a prerequisite for fertilization. However, the molecular mechanism remains unclear. The present study revealed that mouse cumulus cells of oocytes-cumulus complexes (OCCs) expressed transforming growth factor-ß ligand 1 (TGFB1), whereas ampullary epithelial cells expressed the TGF-ß receptors, TGFBR1 and TGFBR2, and all were upregulated by luteinizing hormone (LH)/human chorionic gonadotropin (hCG). OCCs and TGFB1 increased natriuretic peptide type C (NPPC) expression in cultured ampullae via TGF-ß signaling, and NPPC treatment promoted spermatozoa moving out of the isthmic reservoir of the preovulatory oviducts. Deletion of Tgfb1 in cumulus cells and Tgfbr2 in ampullary epithelial cells blocked OCC-induced NPPC expression and spermatozoa moving out of the isthmic reservoir, resulting in compromised fertilization and fertility. Oocyte-derived paracrine factors were required for promoting cumulus cell expression of TGFB1. Therefore, oocyte-dependent and cumulus cell-derived TGFB1 promotes the expression of NPPC in oviductal ampulla, which is critical for sperm migration in the oviduct and subsequent fertilization.

Revealing mechanisms of mating plug function under sexual selection.

Mating plugs are produced by many sexually reproducing animals and are hypothesized to promote male fertilization success under promiscuous mating. However, tests of this hypothesis have been constrained by an inability to discriminate ejaculates of different males in direct competition. Here, we use stable isotope labeling in vivo and proteomics to achieve this in a promiscuous rodent, Myodes glareolus We show that, although the first male's plug is usually dislodged, it can be retained throughout the second male's copulation. Retained plugs did not completely block rival sperm but did significantly limit their numbers. Differences in the number of each male's sperm progressing through the female reproductive tract were also explained by natural variation in the size of mating plugs and reproductive accessory glands from which major plug proteins originate. Relative sperm numbers in turn predicted the relative fertilization success of rival males. Our application of stable isotopes to label ejaculates resolves a longstanding debate by revealing how rodent mating plugs promote fertilization success under competitive conditions. This approach opens new opportunities to reveal cryptic mechanisms of postcopulatory sexual selection among diverse animal taxa.

Getting to and away from the egg, an interplay between several sperm transport mechanisms and a complex oviduct physiology.

In mammals, the architecture and physiology of the oviduct are very complex, and one long-lasting intriguing question is how spermatozoa are transported from the sperm reservoir in the isthmus to the oocyte surface. In recent decades, several studies have improved knowledge of the factors affecting oviduct fluid movement and sperm transport. They report sperm-guiding mechanisms that move the spermatozoa towards (rheotaxis, thermotaxis, and chemotaxis) or away from the egg surface (chemorepulsion), but only a few provide evidence of their occurrence in vivo. This gives rise to several questions: how and when do the sperm transport mechanisms operate inside such an active oviduct? why are there so many sperm guidance processes? is one dominant over the others, or do they cooperate to optimise the success of fertilisation? Assuming that sperm guidance evolved alongside oviduct physiology, in this review we propose a theoretical model that integrates oviduct complexity in space and time with the sperm-orienting mechanisms. In addition, since all of the sperm-guidance processes recruit spermatozoa in a better physiological condition than those not selected, they could potentially be incorporated into assisted reproductive technology (ART) to improve fertility treatment and/or to develop innovative contraceptive methods. All these issues are discussed in this review.

Active peristaltic movements and fluid production of the mouse oviduct: their roles in fluid and sperm transport and fertilization†.

To study how the oviduct behaves in relation to fluid secretion and sperm transport, ovary-oviduct-uterus complexes of the mouse were installed in a fluid-circulating chamber without disturbing the blood circulation or parasympathetic innervation. Injection of a bolus of Indian ink into the lower isthmus revealed very active adovarian peristalsis of the isthmus, which was most prominent during the periovulatory period. Oviduct fluid, secreted by the entire length of the isthmus, was rapidly transported to the ampulla and ovarian bursa before draining into the peritoneal cavity. The upper isthmus, in particular the isthmic-ampullary junction, was responsible for this adovarian fluid flow. Peristalsis of the oviduct, undisturbed flow of oviduct fluid from the isthmus to the peritoneal cavity, and the spermatozoon's own motility all contribute to efficient sperm ascent and to fertilization within the oviduct. Therefore, chemotaxis, rheotaxis, and thermotaxis of spermatozoa toward oocyte-cumulus complexes in the ampulla are all unlikely mechanisms for explaining sperm-oocyte contact and successful fertilization, given the rapid adovarian flow of oviduct fluid in this species.

The flagellar protein Enkurin is required for mouse sperm motility and for transport through the female reproductive tract.

Enkurin was identified initially in mouse sperm where it was suggested to act as an intracellular adaptor protein linking membrane calcium influx to intracellular signaling pathways. In order to examine the function of this protein, a targeted mutation was introduced into the mouse Enkurin gene. Males that were homozygous for this mutated allele were subfertile. This was associated with lower rates of sperm transport in the female reproductive tract, including reduced entry into the oviduct and slower migration to the site of fertilization in the distal oviduct, and with poor progressive motility in vitro. Flagella from wild-type animals exhibited symmetrical bending and progressive motility in culture medium, and demembranated flagella exhibited the "curlicue" response to Ca2+ in vitro. In contrast, flagella of mice homozygous for the mutated allele displayed only asymmetric bending, nonprogressive motility, and a loss of Ca2+-responsiveness following demembrantion. We propose that Enkurin is part of a flagellar Ca2+-sensor that regulates bending and that the motility defects following mutation of the locus are the proximate cause of subfertility.

In vivo three-dimensional tracking of sperm behaviors in the mouse oviduct.

Mammalian sperm evolutionarily acquired complex mechanisms to regulate their behaviors, which are thought to be crucial in navigating through the female reproductive tract toward fertilization. However, all current knowledge of this process is largely extrapolated from in vitro and ex vivo studies, because in vivo analysis of sperm in their native fertilization environment has not been possible. Here, we report a functional optical coherence tomography approach that allows, for the first time, in vivo three-dimensional tracking of sperm behaviors in the mouse oviduct. Motile sperm are identified with their intrinsic dynamic characteristics. Sperm trajectories are reconstructed in three dimensions with a ∼5 µm spatial resolution, allowing for quantitative analysis of the sperm velocity and location relative to the oviduct. Using this method, we found different behavior patterns, including sperm collection by the oviduct epithelium, spatial dependence of sperm velocity, and sperm grouping and separation as the first in vivo evidence of sperm cooperation in the ampulla, the site of fertilization. This approach opens new avenues to study sperm-oviduct interactions in vivo toward a more complete understanding of fertility and reproductive disorders.

Biological basis for human capacitation-revisited.

BACKGROUND: A little more than a decade ago a review entitled 'Biological basis for human capacitation' was published. A primary conclusion of the review was that with all the technological advances that have been made since the first experiments demonstrated the in vivo requirement of capacitation for fertilization, very little progress had since been made, most significantly for human. OBJECTIVE AND RATIONALE: The present review was carried out to provide an update on the biological basis for human capacitation. It briefly revisits the original schema, presents a review of the literature that urged research interest in human sperm capacitation and puts under the spotlight the original definition of capacitation balanced against the limitations of experiments in vitro to characterize a complex process that necessarily mandates a female component, and very recent findings in the mouse. It also includes proposed considerations for new thinking regarding capacitation, and progress toward understanding the biology of human capacitation. SEARCH METHODS: The PubMed, Google Scholar and Scopus literature databases were reviewed extensively using inclusive, broad and multispecies search terms without publication date limitation. OUTCOMES: Comprehensive screening of the literature database showed that no papers regarding human sperm capacitation in vivo have been published in the past 20 years. Recent experiments in the mouse have provided compelling and unanticipated data regarding capacitation and in vivo fertilization. Questions were posed and addressed regarding: stimuli for initiation of capacitation, capacitation relative to the cumulus-oocyte complex, comparison between in vivo and in vitro capacitation, and potential species-specific differences in location and timing of capacitation. WIDER IMPLICATIONS: There has been no progress on the in vivo biology of human sperm capacitation since before the turn of the century. Human IVF and its technologies may likely have inhibited, and continue to hold back, any future in vivo experiments that would address one or more questions regarding acquisition of fertilizing capacity in human. The limiting factor for progress in the area is access to funding and human subjects.

Deciphering the mechanisms involving cenexin, ninein and centriolin in sperm maturation during epididymal transit in the domestic cat.

The sperm centrosome is an essential organelle with a key role in organizing the sperm aster for proper syngamy and formation of the first mitotic spindle. The sperm cell acquires the functional capability during epididymal transit by incorporation of key factors. The objective of the study was to identify these key maturation proteins, such as ninein and centriolin as well as cenexin-a scaffold protein that serves to bind ninein and centriolin. Epididymal samples were dissected from 17 adult cat testes (>1 year old) and spermatozoa were extracted from the different regions, including rete testis, caput, corpus, cauda and vas deferens. Tissue samples and sperm cells were fixed separately in 4% paraformaldehyde before immunostaining with anticenexin, ninein or centriolin antibodies. Results showed that the proportion of sperm cells with cenexin localized at the centrosome progressively increased along the tract with the lowest percentage of stained cells in the testis (mean = 45%) and highest in the cauda (mean = 81%). Although not significant, the intensity of cenexin immunofluorescence in positive cells increased twofold from the testis to vas deferens. There was no significant difference in the proportion of sperm labelled with centriolin or ninein (ranges of 21%-26% and 33%-48% between segments, respectively) or the intensity (±58% and ±63% change as compared to testis, respectively). Cenexin may serve as a scaffold protein for centriolin and ninein, as the vast majority of spermatozoa only displayed colocalization of these proteins when cenexin was also present (mean = 85% and 91% colocalization, respectively). In summary, these results could be applied to future efforts to create an in vitro culture system capable of rescuing the impaired centrosome of an infertile male, with particular potential for wild felid conservation.

Importance of sperm morphology during sperm transport and fertilization in mammals.

After natural or artificial insemination, the spermatozoon starts a journey from the site of deposition to the place of fertilization. However, only a small subset of the spermatozoa deposited achieves their goal: to reach and fertilize the egg. Factors involved in controlling sperm transport and fertilization include the female reproductive tract environment, cell-cell interactions, gene expression, and phenotypic sperm traits. Some of the significant determinants of fertilization are known (i.e., motility or DNA status), but many sperm traits are still indecipherable. One example is the influence of sperm dimensions and shape upon transport within the female genital tract towards the oocyte. Biophysical associations between sperm size and motility may influence the progression of spermatozoa through the female reproductive tract, but uncertainties remain concerning how sperm morphology influences the fertilization process, and whether only the sperm dimensions per se are involved. Moreover, such explanations do not allow the possibility that the female tract is capable of distinguishing fertile spermatozoa on the basis of their morphology, as seems to be the case with biochemical, molecular, and genetic properties. This review focuses on the influence of sperm size and shape in evolution and their putative role in sperm transport and selection within the uterus and the ability to fertilize the oocyte.

Epididymal protein markers and fertility.

The last stages of male gamete differentiation occur outside the gonad in a specific environment controlled by the epididymal epithelium. All the fundamental characteristics of a fertile spermatozoon are acquired sequentially during transit through the epididymal tubule. Full understanding of the mechanisms involved in these gamete modifications is a key to understanding and controlling such important stages in male fertility. With the development of new large scale technologies, large amounts of information give hope of identifying the fundamental elements involved in such cellular events and of being able to obtain some markers predictive of male fertility that would be valuable both in human and/or animal reproduction.

Evaluación de la motilidad espermática usando dos crioprotectores / Evaluation of sperm motility using two cryoprotectants

La infertilidad, es un problema que afecta a una gran cantidad de parejas. Una de sus causas es la disminución de la calidad seminal debido, por ejemplo, a tratamientos gonadotóxicos. La criopreservación seminal es la técnica que permite conservar y almacenar espermatozoides sin que pierdan su capacidad fecundante; siendo esta una herramienta fundamental en reproducción asistida. El objetivo de este trabajo ha sido optimizar la técnica de criopreservación. Para ello se llevó a cabo un estudio, sobre muestras de pacientes en estudio por problemas de fertilidad, en el que se compararon dos medios de criopreservación (SpermCryo™All-round y CryoSperm™) y la aplicación o no de un baño en nitrógeno líquido a las muestras (previo a su almacenamiento); así como el efecto del tiempo que transcurre desde la eyaculación hasta el procesado sobre la calidad de la muestra. Las posibles variaciones fueron estudiadas con un analizador automático, mediante la realización de test pre- y post-congelación para comprobarla movilidad espermática

Infertility is a problem that affects a lot of couples. One of its causes is a decreased semen quality due to, for example, gonadotoxic treatments. The cryopreservation of human semen is the technique that allows sperm preserving and storing without losing their fertilizing capacity; being a fundamental tool in assisted reproduction. The aim of this study was to optimize the cryopreservation technique. To this end, a study carried out on samples of patients under study by fertility problems, in which two cryoprotectant media (SpermCryo™ All-round and CryoSperm™) and the execution or non-execution of an immersion of the samples in liquid nitrogen (before storage) were compared; and the effect of the time between ejaculation and the processing on the quality of the sample. Variations were studied with an automatic analyzer by performing pre- and post-thaw sperm motility tests. The results show no difference between the two cryoprotectants media, but seems to have a tendency to obtain better postthaw mobility with either depending on sample characteristics. Moreover, the liquid nitrogen bath had no apparent effects on post-thaw results. However, we must highlight the importance of time in the processing of semen samples once liquefied, to avoid decreased sperm quality. To improve post-thaw outcomes the key lies in the necessity to adjust the freezing protocol to the sample characteristics and a correct implementation of the protocol cryopreservation (selection and addition of cryoprotectant media...); favoring the management of infertility and the success of assisted reproduction techniques

Transport, Distribution and Elimination of Mammalian Sperm Following Natural Mating and Insemination.

The integrity of transport, distribution and elimination of sperm in the female genital tract plays a pivotal role for successful reproduction in mammals. At coitus, millions or billions of sperm are deposited either into the anterior vagina (human, primates), the cervix (most mammalian species) or the uterus (pig). In most species, the first anatomical barrier is the cervix, where spermatozoa with poor morphology and motility are filtered out by sticking to the cervical mucus. The second anatomical barrier is the uterotubal junction (UTJ) with its tortuous and narrow lumen. Finally, only a few thousand sperm enter the oviduct and less than 100 sperm reach the site of fertilization. As soon as the sperm enter the oviduct, they form a sperm reservoir enabling them to stay vital and maintain fertilizing capacity for 3-4 days (cow, horse) up to several months (bats). After ovulation, mammalian sperm show hyperactivation which allows them to detach from the tubal epithelium and migrate to the site of fertilization. This review will focus on recent insights of sperm transport, sperm storage and sperm-oviduct interaction in mammals which have been gained by live cell imaging in cows and mice under near in vivo conditions. Detailed knowledge of the biology of spermatozoa within the female genital tract creates the basis for new therapeutic concepts for male subfertility and infertility - an essential prerequisite to increase success rates in assisted reproduction.

Vias de sinalização reguladoras das funções do espermatozoide / Signaling pathways in sperm functions regulation

O espermatozoide é o gâmeta masculino e, como tal, a sua principal func¸ão é fecundar o oócito. Aquando da ejaculac¸ão, esta célula ainda não se encontra madura, pelo que não consegue realizar a sua func¸ão. Ao entrar em contato com o trato reprodutor feminino, o espermatozoide sofre a capacitac¸ão. Este processo é caracterizado por alterac¸ões bioquímicas e funcionais. A reac¸ão acrossómica é o processo final para a fecundac¸ão e caracteriza-se pela libertac¸ão das enzimas de proteolíticas que hidrolisam a zona pelúcida. Todos estes processos dependem de vias de sinalizac¸ão. A maioria das vias de sinalizac¸ão descritas para células somáticas já foram identificadas no espermatozoide, contudo, os seus efeitos não são completamente conhecidos. Nesta revisão serão descritas as principais vias de sinalizac¸ão dos espermatozoides, nomeadamente PPP1CC2, cAMP/PKA, fosfolipase C, PI3K-AKT e ROS (AU)

Spermatozoon is the male gamete and its main function is to fertilize the oocyte. When ejaculation occurs, this cell is immature and therefore cannot perform its function. When it contacts the female reproductive tract, the sperm undergoes capacitation. This process is characterized by biochemical and functional changes. The acrosome reaction is the last process for fertilization and it is characterized by the release of proteolytic enzymes which hydrolyze the zona pellucida. All of these processes depend of signaling pathways. Most of the signaling pathways described for somatic cells have been identified in the sperm, but their effects are not completely known. In this review the main signaling pathways of sperm are described, including PPP1CC2, cAMP/PKA, phospholipase C, PI3K-AKT and ROS (AU)

Sperm activation by heat shock protein 70 supports the migration of sperm released from sperm storage tubules in Japanese quail (Coturnix japonica).

Systems for maintaining the viability of ejaculated sperm in the female reproductive tract are widespread among vertebrates and invertebrates. In birds, this sperm storage function is performed by specialized simple tubular invaginations called sperm storage tubules (SSTs) in the uterovaginal junction (UVJ) of the oviduct. Although the incidence and physiological reasons for sperm storage in birds have been reported extensively, the mechanisms of sperm uptake by the SSTs, sperm maintenance within the SSTs, and control of sperm release from the SSTs are poorly understood. In this study, we demonstrated that the highly conserved heat shock protein 70 (HSP70) stimulates sperm motility in vitro and also that HSP70 expressed in the UVJ may facilitate the migration of sperm released from the SSTs. Quantitative RT-PCR analysis demonstrated that the expression of HSP70 mRNA in the UVJ increases before ovulation/oviposition. Gene-specific in situ hybridization and immunohistochemical analysis with a specific antibody to HSP70 demonstrated that HSP70 is localized in the surface epithelium of the UVJ. Furthermore, injection of anti-HSP70 antibody into the vagina significantly inhibited fertilization in vivo. In addition, we found that recombinant HSP70 activates flagellar movement in the sperm and that the binding of recombinant HSP70 to the sperm surface is mediated through an interaction with voltage-dependent anion channel protein 2 (VDAC2). Our results suggest that HSP70 binds to the sperm surface by interacting with VDAC2 and activating sperm motility. This binding appears to play an important role in sperm migration within the oviduct.

New insights into epididymal function in relation to sperm maturation.

Testicular spermatozoa acquire fertility only after 1 or 2 weeks of transit through the epididymis. At the end of this several meters long epididymal tubule, the male gamete is able to move, capacitate, migrate through the female tract, bind to the egg membrane and fuse to the oocyte to result in a viable embryo. All these sperm properties are acquired after sequential modifications occurring either at the level of the spermatozoon or in the epididymal surroundings. Over the last few decades, significant increases in the understanding of the composition of the male gamete and its surroundings have resulted from the use of new techniques such as genome sequencing, proteomics combined with high-sensitivity mass spectrometry, and gene-knockout approaches. This review reports and discusses the most relevant new results obtained in different species regarding the various cellular processes occurring at the sperm level, in particular, those related to the development of motility and egg binding during epididymal transit.

[Research progress in sperm mediated gene transfer technology].

With the rapid development of biotechnology, we can change the trait of organism using transgenetic technology. In recent years, there are growing interests in the establishment of sperm mediated gene transfer (SMGT) technology as an effective and convenient method to produce transgenic animals. SMGT technology is a transgenetic method, which is easy in operation and does little harm to the cell compared with the other transgenetic methods. In this review, we expound the background, development, mechanism, operation and application of SMGT.

A neuropeptide circuit that coordinates sperm transfer and copulation duration in Drosophila.

Innate behaviors are often executed in concert with accompanying physiological programs. How this coordination is achieved is poorly understood. Mating behavior and the transfer of sperm and seminal fluid (SSFT) provide a model for understanding how concerted behavioral and physiological programs are coordinated. Here we identify a male-specific neural pathway that coordinates the timing of SSFT with the duration of copulation behavior in Drosophila. Silencing four abdominal ganglion (AG) interneurons (INs) that contain the neuropeptide corazonin (Crz) both blocked SSFT and substantially lengthened copulation duration. Activating these Crz INs caused rapid ejaculation in isolated males, a phenotype mimicked by injection of Crz peptide. Crz promotes SSFT by activating serotonergic (5-HT) projection neurons (PNs) that innervate the accessory glands. Activation of these PNs in copulo caused premature SSFT and also shortened copulation duration. However, mating terminated normally when these PNs were silenced, indicating that SSFT is not required for appropriate copulation duration. Thus, the lengthened copulation duration phenotype caused by silencing Crz INs is independent of the block to SSFT. We conclude that four Crz INs independently control SSFT and copulation duration, thereby coupling the timing of these two processes.

Using computational modeling to investigate sperm navigation and behavior in the female reproductive tract.

The processes by which individual sperm cells navigate the length and complexity of the female reproductive tract and then reach and fertilize the oocyte is fascinating. Numerous complex processes potentially influence the transport of spermatozoa within the tract, resulting in a regulated supply of spermatozoa to the oocytes at the site of fertilization. Despite significant differences between species, breeds, and individuals, these processes converge to ensure that a sufficient number of high quality spermatozoa reach the oocytes, resulting in successful fertilization without a significant risk of polyspermy. Different factors, such as the physical complexity of the oviductal environment, changing swimming patterns, capacitation, chemotactic and thermotactic attraction, attachment and detachment from the oviductal epithelium, interactions with local oviductal secretions, individual variations in spermatozoa and subpopulations, peristaltic contractions, and the movement of fluid have all been theorized to influence the transport of spermatozoa to the site of fertilization. However, the predominance of each factor is not fully understood. Computational modeling provides a useful method for combining knowledge about the individual processes in complex systems to help understand the relative significance of each factor. The process of constructing and validating an agent-based computational model of sperm movement and transport within the oviductal environment is described in this report. Spermatozoa are modeled as individual cells with a set of behavioral rules defining how they interact with their local environment and regulate their internal state. The inclusion or potential exclusion of each factor is discussed, along with problems identifying parameters and defining behavioral rules from available literature. Finally, the benefits and limitations of the model are described.

Can the controversy about the putative role of the human female orgasm in sperm transport be settled with our current physiological knowledge of coitus?

INTRODUCTION: Spermatozoal uptake, facilitated by uterine contractions induced by oxytocin at orgasm during coitus, has been a long term concept. Studies attempting its support, however, have been poorly examined especially in the context of the changes in the female genital tract activated by sexual arousal. AIM: To examine experimental support for the concept. METHODS: Using a variety of search engines, mainly peer reviewed articles and un-reviewed books were examined relating to sperm transport and function in the human female genital tract in the absence and presence of arousal to orgasm. MAIN OUTCOME MEASURES: Identifying evidence-based data to support authority-based opinion. RESULTS: All the experimental observations of sperm or model substitute's transport have been undertaken in women who were not sexually aroused. They fail to take into account that arousal creates vaginal tenting lifting the cervico-uterine complex into the false pelvis away from the ejaculated semen. This delays sperm uptake and transport making conclusions from these observations invalid in relation to transport during coitus. Studies injecting oxytocin have not used women in their sexually aroused state and used supraphysiological doses unlikely to be comparable with coitus and orgasm. The proposal that the transport of extra sperm by oxytocin-induced uterine contractions at orgasm is needed to facilitate fertility ignores possible harm from increased sperm numbers creating polyspermy and sperm enzyme release causing ovum degeneration, leading to decreased fertility. The role of sperm motility in their uptake from the vagina into the cervix as opposed to en bloc transfer through uterine archimyometrial-mediated transport in the absence of orgasm is at present unresolvable because of conflicting studies. CONCLUSION: The bulk of the reported evidence favors the conclusion that the female orgasm, with its concomitant central release of oxytocin, has little or no effective role in the transport of spermatozoa in natural human coitus.

Sperm migration in pigs after deep intrauterine and intraperitoneal insemination.

Deep intrauterine insemination in pigs allows sperm deposition only into one uterine horn, but bilateral fertilization of oocytes occurs. How the sperm reach the contralateral oviduct remains disputable. The aim of this experiment was to study possible transperitoneal and/or transuterine sperm migration ways. Follicle growth and ovulation were induced in 24 peripubertal gilts with eCG and hCG 72 h after eCG. Endoscopic intrauterine insemination (IUI) was performed 32 h after hCG with 20 ml of extended semen (60 × 10(6) spermatozoa) as follows: Group CONTROL (n=8) received IUI into the right horn, and the left horn served as non-treated control; Group LIGATURE (n=8) received IUI into the right horn, and the left horn was closed by endoscopic double ligature close to the bifurcation; Group INTRAPERITONEAL (IPI; n=8) received IUI into the right uterine horn, the left horn was closed by double ligature and semen was deposited intraperitoneally at the surface of the left ovary. Genital tracts were removed 65-66 h after hCG, the oviducts were flushed and ova (n=299) were analyzed for fertilization and cleavage. Furthermore, the accessory spermatozoa count/oocyte was graded as 0, without spermatozoa, 1, <5 spermatozoa, 2, 5-50 spermatozoa, 3, 50-100 spermatozoa and 4, >100 spermatozoa. The results indicate that low dose IUI into one horn provides a lower grade of accessory spermatozoa in the contra-lateral side (1.6 vs. 2.8). No spermatozoa were found in ova flushed from oviducts of the ligated uterine horn, even after intraperitoneal insemination (P<0.05), and no fertilization occurred, respectively. Our results clearly indicate that after low dose IUI into one uterine horn, spermatozoa reach the contralateral oviduct via transuterine migration.