Hostname: page-component-78c5997874-dh8gc Total loading time: 0 Render date: 2024-11-13T02:41:40.402Z Has data issue: false hasContentIssue false
  • English
  • Français

Review: Environmental impact on early embryonic development in the bovine species

Published online by Cambridge University Press:  06 February 2020

U. Besenfelder ,
G. Brem  and
V. Havlicek
U. Besenfelder*
Affiliation:
Department for Biomedical Sciences, University of Veterinary Medicine, Veterinaerplatz 1, A-1210 Vienna, Austria Department of Agrobiotechnology, IFA-Tulln, University of Natural Resources and Life Science, Konrad Lorenz Strasse 20, 3430 Tulln, Austria
G. Brem
Affiliation:
Department for Biomedical Sciences, University of Veterinary Medicine, Veterinaerplatz 1, A-1210 Vienna, Austria
V. Havlicek
Affiliation:
Department for Biomedical Sciences, University of Veterinary Medicine, Veterinaerplatz 1, A-1210 Vienna, Austria Department of Agrobiotechnology, IFA-Tulln, University of Natural Resources and Life Science, Konrad Lorenz Strasse 20, 3430 Tulln, Austria
*
E-mail: urban.besenfelder@vetmeduni.ac.at

Abstract

Assisted reproduction techniques (ARTs) provide access to early stage embryos whose analysis and assessment deliver valuable information. The handling of embryos, including the in vitro production of bovine embryos, is a rapidly evolving area which nonetheless exposes the embryos to unnatural conditions for a period of time. The Fallopian tube provides innumerable quantitative and qualitative factors, all of which guarantee the successful development of the embryo. It is well known that the Fallopian tube can be bypassed, using embryo transfer, resulting in successful implantation in the target recipient animal and the birth of calves. However, the question arises as to whether such circumvention has a negative impact on the embryo during this sensitive development period. First crosstalk between the embryo and its environment confirms mutual recognition activities and indicate bilateral effects. Nowadays, in vitro production of bovine embryos is a well-established technology. However, it is still evident that in vitro generated embryos are not qualitatively comparable to embryos obtained ex vivo. To counteract these differences, comparative studies between in vitro and ex vivo embryos are advantageous, as embryos grown in their physiological environment can provide a blueprint or gold standard against which to compare embryos produced in vitro. Attempts to harness the bovine oviduct were sometimes very invasive and did not result in wide acceptance and routine use. Long-term development and refinement of transvaginal endoscopy for accessing the bovine oviduct has meanwhile been routinely applied for research as well as in practice. Comparative studies combining in vitro development with development in the cattle oviduct revealed that the environmental conditions to which the embryo is exposed before activation of the embryonic genome can have detrimental and lasting effects on its further development. These effects are manifested as deviations in gene expression profiles and methylation signatures as well as frequency of whole chromosomal or segmental aberrations. Furthermore, it was shown that hormonal superstimulation (multiple ovulation and embryo transfer), varying progesterone concentrations as well as metabolic disorders caused by high milk production, markedly affected embryo development in the postpartum period. Assisted reproductive techniques that allow the production and handling of extra numbers of generated embryos promise to have a very high impact on scientific and practical application. Any influence on the early embryonic life, both in animals and in vitro, is accompanied by a sensitive change in embryonic activity and should be assessed in vivo on the basis of physiological conditions before being used for ART.

Keywords

embryo developmentenvironmentoviductin vitro productionendoscopy
Type
Review Article
Information
animal , Volume 14 , Issue S1: XIIIth International Symposium on Ruminant Physiology (ISRP 2019), 3-6 September 2019, Leipzig, Germany , March 2020 , pp. s103 - s112
Copyright
© The Animal Consortium 2020

Implications

Embryo collection using multiple ovulation and embryo transfer as well as in vitro production of bovine embryos has become a major part in animal breeding and science. The oviduct provides numerous prerequisites all of which guarantee a healthy conceptus, capable to implant and result in a healthy calf. Accordingly, techniques have been developed to access the bovine oviduct in order to perform comparable in vivo v. in vitro studies and to provide more information about components and dynamic changes in the oviduct to increase our comprehensive understanding of early embryo development and fertility problems such as early embryo death.

Introduction

A comprehensive understanding of the underlying factors affecting fertility is essential in order to make advances in basic science as well as the development and application of novel breeding strategies. The term fertility includes a large number of genetic factors and environmental influences, which interact in a complex fashion. Although currently much detailed information is available, revealing a deep insight into individual processes, a common understanding of relationships seems to be still a long way off. Within this context, the first few days of development represent a key window during a sensitive period, when the embryo is generated and guided across the oviduct which determines the subsequent life phase.

However, this early embryonic development is in conflict with some of the objectives of cattle breeding. Milk production represents one major economic goal in modern cattle breeding. Over the past decades, cow milk yield has increased significantly and herd management, including animal nutrition, is a great challenge which inevitably leads to metabolic disorders (Zebeli et al., Reference Zebeli, Ghareeb, Humer, Metzler-Zebeli and Besenfelder2015). In contrast, the reproductive performance of animals has deteriorated. One of the biggest contributors to reproductive efficiency is early embryonic mortality. The increase in embryonic losses within the first days and weeks seems to be directly associated with the increase in milking performance of dairy animals (Diskin and Morris, Reference Diskin and Morris2008; Sartori et al., Reference Sartori, Bastos and Wiltbank2010).

Although significant progress has been made by the bovine industry and fertility has been negatively affected including early embryonic development, the generation and collection of embryos from genetically valuable animals is of major importance for breeding purposes, as reflected in the annual statistics of the International Embryo Technology Society (IETS) (Viana, Reference Viana2018). The additional harvesting of embryos using multiple ovulation and embryo transfer (MOET) programs in cattle offers an extensive platform for introducing valuable breeding steps and thus significantly controlling the effects on breeding quality and progress. Thus, assisted reproduction techniques (ARTs) open up not only classical applications but also innovative approaches such as evaluation of the genomic breeding value and genome editing (Cornelissen et al., Reference Cornelissen, Mullaart, Van der Linde and Mulder2017; Fujii et al., Reference Fujii, Hirayama, Naito, Kashima, Sakai, Fukuda, Yoshino, Moriyasu, Kageyama, Sugimoto, Matsuyama, Hayakawa and Kimura2017, Granleese et al., Reference Granleese, Clark, Kinghorn and van der Werf2018, Jaton et al., Reference Jaton, Schenkel, Sargolzaei, Cánova, Malchiodi, Price, Baes and Miglior2018, Menchaca et al., Reference Menchaca, dos Santos-Neto, Cuadro, Souza-Neves and Crispo2018, Georges et al., Reference Georges, Charlier and Hayes2019). Since the recovery of embryos by means of superovulation is associated with limitations, significantly more embryos could be provided with the development and establishment of in vitro production (Galli et al., Reference Galli, Duchi, Crotti, Turini, Ponderato, Colleoni, Lagutina and Lazzari2003). The embryo production statistics of the IETS 2017 showed for the first time that more embryos were generated and transferred from in vitro production worldwide than from MOET programs (Viana, Reference Viana2018).

However, it should be emphasised that gametes and embryos are exposed to spatial and temporal unnatural conditions using such assisted reproductive techniques, the existence of which is known but their extent is not known in their entirety (Van Eetvelde et al., Reference Van Eetvelde, Heras, Leroy, Van Soom, Opsomer, Fazeli and Holt2017). Therefore, this review intends to briefly present physiological developmental conditions in the Fallopian tube for bovine embryos and epithelium and embryo interactions and compares embryo development in vitro, in the laboratory or in vivo, in the animal and under lactation conditions and hormonal substitution.

Physiological properties of the oviduct during embryo development

The bovine oviduct is a small, inconspicuous elongated tubular organ that connects the ovaries with the tip of the uterine horns. The gametes enter the Fallopian tube from opposite sides and meet in the ampulla where fertilisation occurs. Bovine embryos stay in the oviduct for 3.5 to 4 days and migrate to the distal end of the isthmus before they pass into the uterus. The multilayered structure (serosa, muscularis and mucosa) of the Fallopian tube depends on its individual sections: infundibulum, ampulla and isthmus. Internally, the Fallopian tube is characterised by ridges, grooves, furrows and folds of the mucosa to varying degrees. While the ampulla has numerous primary and secondary folds that are provided with cross-links, the isthmus has only minor elevations endowed with a distinct muscle layer (Yaniz et al., Reference Yániz, Lopez-Gatius, Santolaria and Mullins2000; Mouguelar et al., Reference Mouguelar, Díaz, Borghi, Quinteros, Bonino, Apichela and Aguilar2015). The mucosa is lined with cells that are either ciliated or have secretory activity (Yaniz et al., Reference Yániz, Lopez-Gatius, Santolaria and Mullins2000; Kölle et al., Reference Kölle, Dubielzig, Reese, Wehrend, König and Kummer2009).

The muscle layer with its longitudinal and circular layer in the Fallopian tube and the ciliated cells of the epithelium of the oviduct (Ruckebusch and Bayard, Reference Ruckebusch and Bayard1975) bathe the embryos in the fluid and transport them towards the tip of the uterine horns. The secretory cells are involved in the active production of the tubal fluid which is completed by transudation, peritoneal and follicular fluid (Hunter et al., Reference Hunter, Cicinelli and Einer-Jensen2007). The lumen of the ampulla is significantly larger and is filled with branches of multiform mucosal folds, while the isthmus with a very small lumen largely consists only of primary folds. The ratio of ciliated and secretory cells depends on the tubal location as well as on stage of the ovarian cycle. Thus, on the third day of the cycle, the ampulla contains almost 70% secretory cells, which continuously decrease along the Fallopian tube and are only present at the end of the isthmus at about 20% (Kölle et al., Reference Kölle, Dubielzig, Reese, Wehrend, König and Kummer2009). The oviduct supplies biochemical substrates (carbohydrates such as energy substrates, ions, proteins, enzymes, amino acids, fatty acids; Hugentobler et al., Reference Hugentobler, Sreenan, Humpherson, Leese, Diskin and Morris2010; Avilés et al., Reference Avilés, Coy and Rizos2015) to the embryos, provides physical requirements (pH, viscosity, osmolarity; Menezo and Guerin, Reference Menezo and Guerin1997; Hunter et al., Reference Hunter, Coy, Gadea and Rath2011) and components with modulating or interacting functions (such as growth factors, cytokines, and nucleic acids, reviewed by Wolf et al., Reference Wolf, Arnold, Bauersachs, Beier, Blum, Einspanier, Fröhlich, Herrler, Hiendleder, Kölle, Prelle, Reichenbach, Stojkovic, Wenigerkind and Sinowatz2003), among which the microvesicles are of particular importance (Raposo and Stoorvogel, Reference Raposo and Stoorvogel2013; Lopera-Vasquez et al., Reference Lopera-Vasquez, Hamdi, Maillo, Gutierrez-Adan, Bermejo-Alvarez, Ramírez, Yáñez-Mó and Rizos2017a; Almiñana et al., Reference Almiñana, Tsikis, Labas, Uzbekov, da Silveira, Bauersachs and Mermillod2018).

In contrast to many in vitro culture conditions, which usually take place under static conditions for 6 to 8 days, all processes in the Fallopian tubes are subjected to dynamic changes that are strongly linked to the ovarian cyclic activity such as transport speed (Ruckebusch and Bayard, Reference Ruckebusch and Bayard1975; Bennett et al., Reference Bennett, Watts, Blair, Waldhalm and Fuquay1988; Kölle et al., Reference Kölle, Dubielzig, Reese, Wehrend, König and Kummer2009), volume of fluid (Hugentobler et al., Reference Hugentobler, Humpherson, Leese, Sreenan and Morris2008), concentration of components (Buhi et al., Reference Buhi2002; Hugentobler et al., Reference Hugentobler, Diskin, Leese, Humpherson, Watson, Sreenan and Morris2007; Avilés et al., Reference Avilés, Gutiérrez-Adán and Coy2010), and the expression profile of the ipsi- or contralateral Fallopian epithelium (Bauersachs et al., Reference Bauersachs, Rehfeld, Ulbrich, Mallok, Prelle, Wenigerkind, Einspanier, Blum and Wolf2004).

While the embryos pass through the oviduct, they undergo specific key events. During this time, the epigenetic-directed reprogramming of the embryos takes place (de- and re-methylation of the embryonic DNA); and at the eight-cell stage, the main activation of the embryonic genome is initiated. The embryos migrate through the Fallopian tube contained within the zona pellucida (ZP), that is, cytoplasmic multiplication does not occur, cytoplasm and also organelles such as the mitochondria are equally distributed to the daughter blastomeres. A de novo synthesis of the mitochondria does not take place until the blastocyst stage (May-Panloup et al., Reference May-Panloup, Vignon, Chrétien, Heyman, Tamassia, Malthièry and Reynier2005; Graf et al., Reference Graf, Krebs, Zakhartchenko, Schwalb, Blum and Wolf2014).

In vitro systems for the production of bovine embryos aimed at imitating specific features of the Fallopian tube in order to successfully manage this stage of development outside the body. This led to different types of culture systems using standard media, conditioned media (Maeda et al., Reference Maeda, Kotsuji, Negami, Kamitani and Tominaga1996) or the addition of fluid from the blood or Fallopian tube (Aguilar and Reyley, Reference Aguilar and Reyley2005), two- or three-dimensional co-cell culture systems (Goovaerts et al., Reference Goovaerts, Leroy, Van Soom, De Clercq, Andries and Bols2009, Chen et al., Reference Chen, Palma-Vera, Langhammer, Galuska, Braun, Krause, Lucas-Hahn and Schoen2017, Ferraz et al., Reference Ferraz, Rho, Hemerich, Henning, van Tol, Hölker, Besenfelder, Mokry, Vos, Stout, Le Gac and Gadella2018), microfluidic systems (Beebe et al., Reference Beebe, Wheeler, Zeringue, Walters and Raty2002) or even mouse oviducts during the in vitro culture (Rizos et al., Reference Rizos, Ramirez, Pintado, Lonergan and Gutierrez-Adan2010b). Meanwhile, all in vitro systems have been developed and established over a long period and used with great success undergoing continuous improvements. Nevertheless, there are still significant differences between in vitro and in vivo derived embryos (Gad et al., Reference Gad, Hoelker, Besenfelder, Havlicek, Cinar, Rings, Held, Dufort, Sirard, Schellander and Tesfaye2012; Bonilla et al., Reference Bonilla, Block, Denicol and Hansen2014; Tšuiko et al., Reference Tšuiko, Catteeuw, Zamani Esteki, Destouni, Bogado Pascottini, Besenfelder, Havlicek, Smits, Kurg, Salumets, D’Hooghe, Voet, Van Soom and Vermeesch2017). In addition, studies show that the use of bovine oviduct fluid at higher concentrations (5%, 10% and 25%) in in vitro culture systems exerts a negative effect of embryo development which has been assessed as almost toxic (Lopera-Vasquez et al., Reference Lopera-Vasquez, Hamdi, Maillo, Lloreda, Coy, Gutierrez-Adan, Bermejo-Alvarez and Rizos2017b). Heterologous in vivo culture systems have been successfully used, but they do not allow the study of direct interactions of the embryo with its environment (Lazzari et al., Reference Lazzari, Colleoni, Lagutina, Crotti, Turini, Tessaro, Brunetti, Duchi and Galli2010). However, it should be kept in mind that short-term effects such as cultural successes will be followed by long-term effects, the consequences of which cannot yet be fully estimated (Duranthon and Chavatte-Palmer, Reference Duranthon and Chavatte-Palmer2018).

Undoubtedly, embryos can be produced without the assistance of the oviduct; furthermore, the recipients to whom the embryos are transferred do not have to have been in contact before transfer to the uterus. However, to pay more attention to this period in the Fallopian tube and its importance for embryo development, the following considerations will deal with direct interactions of the embryo with its physiological environment, including deviations.

Exchange of signals between embryo and oviduct in cattle

For a long time, the Fallopian tube has been neglected for its role and function in embryogenesis, possibly due to the success of ARTs such as MOET and in vitro production of bovine embryos. These techniques have clearly shown that pregnancies can be established without the involvement of the Fallopian tube (Leese et al., Reference Leese, Tay, Reischl and Downing2001, Fazeli and Holt, Reference Fazeli and Holt2016). However, these embryo transfers are accompanied by deficiencies in fertility. In ruminants, for example, interferon-τ plays a pivotal role in the establishment and maintenance of pregnancy. Although in vitro produced embryos secrete high amounts of interferon, their transfer results in a poorer pregnancy rate (Stojkovic et al., Reference Stojkovic, Wolf, Büttner, Berg, Charpigny, Schmitt and Brem1995).

However, since it has been shown that developmental disorders such as large offspring syndrome can occur through the use of ARTs (Young et al., Reference Young, Sinclair and Wilmut1998; Lazzari et al., Reference Lazzari, Wrenzycki, Herrmann, Duchi, Kruip, Niemann and Galli2002), early embryonic development in the bovine oviduct has gained much more attention. In non-ruminants, there is now a strong evidence that the embryo in the Fallopian tube induces responses that mediate its recognition following implantation in the uterus (Weber et al., Reference Weber, Freeman, Vanderwall and Woods1991; Lee et al., Reference Lee, Yao, Kwok, Xu and Yeung2002; Georgiou et al., Reference Georgiou, Sostaric, Wong, Snijders, Wright, Moore and Fazeli2005; Smits et al., Reference Smits, De Coninck, Van Nieuwerburgh, Govaere, Van Poucke, Peelman, Deforce and Van Soom2016). Good examples of the obligatory passage through the Fallopian tube are rabbit and hare embryos. Microscopically, these embryos are surrounded by a mucin layer that covers the ZP during the migratory phase through the oviduct. Absence of or damage to the mucin layer results in a lack of or inferior pregnancy (Murakami and Imai, Reference Murakami and Imai1996; Drews et al., Reference Drews, Ringleb, Waurich, Hildebrandt, Schröder and Roellig2013).

Based on the gene expression profile of the Fallopian tube epithelial cells, Bauersachs et al. (Reference Bauersachs, Blum, Mallok, Wenigerkind, Rief, Prelle and Wolf2003 and Reference Bauersachs, Rehfeld, Ulbrich, Mallok, Prelle, Wenigerkind, Einspanier, Blum and Wolf2004) successfully showed that when the oviduct mechanisms are induced, they prepare and determine the post-ovulation period and regulate early embryonic development via local modification of the transcription profile depending on the ovarian cycle. Differences between the ipsi- and contralateral sides were observed.

García et al. (Reference García, Hamdi, Barrera, Sánchez-Calabuig, Gutiérrez-Adán and Rizos2017) used an in vitro model to correlate processes in bovine oviduct epithelial cells with the developmental stage of the embryos. For this, Fallopian epithelial cells were cultured in vitro and covered with a woven polyester mesh having a grid size of 41 × 41 openings. Embryos were transferred to the mesh and placed individually in grids, which kept the embryos locally fixed to co-culture cells. It could be shown via the bone morphogenetic protein pathway that changes in the expression profile are induced via the embryo–oviduct interaction both in the embryo and in the epithelial cells (García et al., Reference García, Hamdi, Barrera, Sánchez-Calabuig, Gutiérrez-Adán and Rizos2017).

Maillo et al. (2016) studied the transcriptome of the bovine oviduct. Half of synchronised animals were inseminated at the time of oestrus and the other half were not inseminated. On Day 3 after heat, the animals were slaughtered and the Fallopian tubes removed. The isthmus was rinsed to confirm the presence of an embryo or ovum. Expression studies clearly showed differences between the ampulla and the isthmus and between the ipsilateral and contralateral sides. However, no difference was found between the Fallopian tubes containing a single embryo or unfertilised oocyte. The authors did not exclude the potential existence of local embryo-induced epithelial changes, however, which could not be detected within this experiment (Maillo et al., Reference Maillo, de Frutos, O’Gaora, Forde, Burns, Spencer, Gutierrez-Adan, Lonergan and Rizos2016).

In a further study, 50 embryos were transferred endoscopically to the oviducts on Day 1.5 after oestrus. These animals as well as control animals which received a sham transfer were slaughtered on Day 3 and their Fallopian tubes were removed and the isthmus was used for microarray analysis. In total, 278 differentially expressed genes were found between the groups, of which 123 were up-regulated and 155 down-regulated in pregnant animals. Most genes could be related to immunological functions. The reason for the differences between the two experiments was that signals caused by single embryos were not detectable by the method used (Maillo et al., Reference Maillo, Gaora, Forde, Besenfelder, Havlicek, Burns, Spencer, Gutierrez-Adan, Lonergan and Rizos2015). Overall, these studies indicate that there is a mutual modulatory activity between the gametes and embryos and the Fallopian epithelium. As shown by the experimental approach of these in vivo studies, using innovative techniques to access the Fallopian tube can provide more information about peculiarities in early embryonic development compared to in vitro models. From the historical point of view, it can be seen that attempts were made earlier to provide access to the cattle oviduct in order to promote embryo development in a versatile manner. Therefore, this development is briefly introduced below.

Steps to access the bovine Fallopian tube

Numerous attempts have been made to gain access to the bovine oviduct in order to obtain early ex vivo embryonic stages, to transfer early stages of in vitro production (IVP) embryos for in vivo culture and to recover tubal fluid for the study of the embryo environment. At the beginning, different surgical approaches to the bovine Fallopian tube were described. In general, two routes to the peritoneal cavity have been practised: Either the ventromedian approach via the linea alba was selected in anaesthetised animals or laterally, possibly over both flanks, in animals which received a lumbar anaesthesia (Trounson et al. Reference Trounson, Willadsen, Rowson and Newcomb1976; Ellington et al., Reference Ellington, Farrell, Simkin, Foote, Goldman and McGrath1990; Hugentobler et al., Reference Hugentobler, Diskin, Leese, Humpherson, Watson, Sreenan and Morris2007 and Reference Hugentobler, Humpherson, Leese, Sreenan and Morris2008). Jillela et al. (Reference Jillella, Eaton and Baker1977) transferred embryos via a polyethylene cannula into synchronised heifers. These polyethylene tubes were fixed in the right or left flank and a connection was established to one of the oviducts. Two transferred embryos led to the implantation of an embryo. However, the different surgical procedures were labour intensive and often associated with postoperative complications, which made the repeated use of animals nearly impossible.

In order to minimise stress and complications associated with surgery, a minimally invasive approach using laparoscopy was developed. Laparoscopy was used first for observations of ovarian activity and puncture of the follicles on the surface of the ovaries (Sirard and Lambert, Reference Sirard and Lambert1985). One of the first laparoscopic approaches to the Fallopian tube was reported by Fayrer-Hosken et al. (Reference Fayrer-Hosken, Younls, Brackett, McBride, Harper, Keefer and Cabaniss1989). A trocar from a bronchoscopy set and an atraumatic forceps trocar were inserted into the abdominal cavity via the right lumbar fossa. Before each transfer, the ovarian reaction of the recipient animal was recorded. The infundibulum of the Fallopian tube ipsilateral to the ovulated ovary was fixed with forceps to allow the insertion of a catheter through the abdominal ostium 2.5 to 5 cm into the ampulla under visual control. The embryos were slowly transferred from the catheter into the ampulla with about 50 μl of medium. Tubal transfer of 2- to 4-cell in vitro matured and fertilised embryos was performed in four synchronised recipients. One cow became pregnant and gave birth to a healthy calf. This result was encouraging (Fayrer-Hosken et al., Reference Fayrer-Hosken, Younls, Brackett, McBride, Harper, Keefer and Cabaniss1989); however, the described application of laparoscopy on the right paralumbar region involved a very complicated procedure, which was instrumentally very complex and did not become routine.

Reichenbach et al. (Reference Reichenbach, Wiebke, Besenfelder, Mödl and Brem1993 and Reference Reichenbach, Wiebke, Mödl, Zhu and Brem1994) described a transvaginal endoscopic approach for the repeated examination of the reproductive organs and for the recovery of oocytes from follicles of cows and heifers. The endoscope together with the puncture unit was inserted mid-dorsally through the fornix vaginae into the abdominal cavity. The rectal manipulation allowed the ovaries to be moved and fixed in an optimal distance in front of the endoscope. The ovaries were slightly rotated which allowed the ovum pickup (OPU) of all follicles on the surface of the ovaries under visual control. The repeated use of this method in the same animals for the oocyte collection confirmed that a routine application was possible and this had no negative effect on the health, fertility or performance of the animals.

This technique served as a further basis for the access of the Fallopian tube (Besenfelder and Brem, Reference Besenfelder and Brem1998). In order to provide enough space for inspection of the pelvic cavity and to enable manipulation and navigation of the endoscopic equipment, it was necessary to deprive animals from feed for 8 to 12 h before starting the procedure. The animals were fixed in a crush, which resulted in a temporarily restricted movement to ensure gentle handling of the endoscope and organs. An epidural anaesthesia facilitated rectal manipulation. A rigid universal tube was placed dorsally in the fornix vaginae and introduced through the vaginal wall. After passive air influx which caused an artificial pneumo-peritoneum, a bi-tubular inlay was inserted bearing the endoscope and tubing system, consisting either of the embryo flushing system or the embryo transfer system.

In contrast to the lumbar procedure, the transvaginal and medial position of the endoscope allows a non-instrumental, that is, manual, minimal invasive manipulation, visual inspection and control and access to oviducts, ovaries and uterine horns in situ. After completion of the endoscopic procedure and before the universal tube was removed, the air has to be removed from the abdominal cavity by means of a vacuum pump. No further medical treatment is recommended (Besenfelder and Brem, Reference Besenfelder and Brem1998). This technique allowed embryos to be transferred to the Fallopian tube as well as to be recovered after superovulation or in vivo culture at any time (Besenfelder et al., Reference Besenfelder, Havlicek, Kuzmany and Brem2010).

In the meantime, this technique has been assessed several times as ‘... a state of the art endoscopic embryo transfer technique …’ and has been steadily improved and adapted over a long period of time, thus providing skills and experience that can be successfully applied in gene expression and development studies (Lonergan and Fair, Reference Lonergan and Fair2008; Carter et al., Reference Carter, Rings, Mamo, Holker, Kuzmany, Besenfelder, Havlicek, Mehta, Tesfaye, Schellander and Lonergan2010, Rizos et al., Reference Rizos, Carter, Besenfelder, Havlicek and Lonergan2010a). Greater experimental precision can now be tailored to embryo-specific cleavage stages and embryo origin (see Figure 1).

Figure 1 Access to the bovine oviduct for transfer or for flushing. Embryo transfer via a glass capillary after single ovulation (a) or flushing after superovulation (b) can be performed in the same way. Slightly lifting the ovary allows the presentation of the adjacent oviduct ((c) presentation of the infundibulum and the ampulla). Once the entry can be gained into the oviduct ((d) see the capillary parallel to the first part of the ampulla), a capillary can be introduced along this route ((e) and (f)).

In vitro-embryo development, differences between in vitro and in vivo

In vitro derived blastocysts significantly differ from their in vivo collected counterparts with regard to gene expression profile (Gutiérrez-Adán et al., Reference Gutiérrez-Adán, Rizos, Fair, Moreira, Pintado, de la Fuente, Boland and Lonergan2004), chromosome abnormalities (Viuff et al., Reference Viuff, Hendriksen, Vos, Dieleman, Bibby, Greve, Hyttel and Thomsen2001), cryosurvival (Enright et al., Reference Enright, Lonergan, Dinnyes, Fair, Ward, Yang and Boland2000) and ultrastructural features (Crosier et al., Reference Crosier, Farin, Dykstra, Alexander and Farin2000; Rizos et al., Reference Rizos, Fair, Papadopoulos, Boland and Lonergan2002). These differences are discussed as an expression of different trophic factors that are available to the embryo in the respective culture systems.

Actually, it is not the embryonic cells that are in direct contact with the epithelial cells of the Fallopian tube but rather the ZP surrounding the embryo. The ZP consists of a compact meshwork displaying differently structured filamentous inner and outer layers (Denker Reference Denker2000; Sinowatz et al., Reference Sinowatz, Töpfer-Petersen, Kölle and Palma2001). This ZP represents an extracellular matrix that lies between the embryo and the oviduct epithelium and must be permeable to signalling and messenger substances. Therefore, the accumulation of substances in and around the ZP may serve as an indicator for the embryo–epithelial interactions. Mertens et al. (2006) studied the ZP of in vitro produced embryos in the zygote, 2-, 4-, 8-, 16-cell, morula and blastocyst stage and compared them with endoscopically collected zygotes, 4-cell and uterine-flushed morulae and blastocysts. The ZP was cut by laser and the wall was assessed by scanning electron microscopy. While the thickness of the outer layer, the reticular part of the ZP, increased from 7.5% to 10% for in vitro embryos, ex vivo embryos showed a thicker outer layer, expanding from 18% for zygotes to 30% for blastocysts (Mertens et al., Reference Mertens, Gilles, Rings, Hoelker, Schellander and Herrler2006). The number of pores and their size decreased with the duration of stay in the Fallopian tube. In addition, it could be seen that in most of the in vitro embryos the outer reticular layer showed signs of degeneration (Mertens et al., Reference Mertens, Besenfelder, Gilles, Hölker, Rings, Havlicek, Schellander and Herrler2007).

Overall, these processes revealed that the ZP represents a permeable wall and filter system where residues convince of an intensive exchange of nutrients, signals and other components between the embryo and the Fallopian epithelium. These oviductal properties can not only be found in the ZP but are correspondingly reflected in the cryosurvival of the embryos. Lonergan et al. (Reference Lonergan, Rizos, Kanka, Nemcova, Mbaye, Kingston, Wade, Duffy and Boland2003) produced bovine in vitro embryos that were either cultured in vitro or transferred to the ovine oviduct at different times and re-collected. The longer the embryos were cultured in the ovine oviduct, the more resistant they were to cryopreservation. It was noticeable that the resistance of the in vitro embryos to cryoinjury decreased very rapidly. Embryos cultured in vitro during the first period and then transferred in vivo showed a higher post-freezing survival rate compared to embryos that were first kept in the ovine oviduct and then cultured in vitro until the blastocyst stage (Lonergan et al., Reference Lonergan, Rizos, Kanka, Nemcova, Mbaye, Kingston, Wade, Duffy and Boland2003). These results have been confirmed in cattle by Havlicek et al. (2010). In vitro produced embryos were kept in culture for 7 days and compared with embryos that had already been endoscopically transferred as a mix of ovum–sperm co-incubation into the oviduct immediately after ovulation or as embryos at the 4- to 8-cell stage in synchronous cattle oviducts. It was clearly shown that the longer the embryos remain in the bovine oviduct, the more resistant they are to cryopreservation (Havlicek et al., Reference Havlicek, Kuzmany, Cseh, Brem and Besenfelder2010).

After having shown the general inferiority of in vitro embryos, the aim of the study by Gad et al. (Reference Gad, Hoelker, Besenfelder, Havlicek, Cinar, Rings, Held, Dufort, Sirard, Schellander and Tesfaye2012) was to reveal specific critical transition phases in in vitro production. In a large-scale study, in vitro produced embryos were transferred to the Fallopian tubes at various times, which flushed out of the uterus on Day 7. In turn, after superovulation, embryos were flushed out of the Fallopian tube at various times and cultured in vitro until the Day 7 blastocyst stage. In general, it could be shown that the change in the culture system before or after the activation of the embryo genome had no effect on the number of blastocysts. However, the source from which the embryos originated had a marked influence on the blastocyst rate (Rizos et al., Reference Rizos, Fair, Papadopoulos, Boland and Lonergan2002; Gad et al., Reference Gad, Hoelker, Besenfelder, Havlicek, Cinar, Rings, Held, Dufort, Sirard, Schellander and Tesfaye2012). Moreover, in vitro culture had a detrimental effect on the transcriptome of the blastocysts. It has been shown that molecular mechanisms and metabolic pathways are determined by the cultural environment that prevails at the time of genome activation. Such experimental approaches are seen as a potential source for the development of new strategies in in vitro culture (Gad et al., Reference Gad, Hoelker, Besenfelder, Havlicek, Cinar, Rings, Held, Dufort, Sirard, Schellander and Tesfaye2012).

A further investigation served for studying the genome-wide methylation pattern of embryos whose environment is influenced by in vitro conditions. For this reason, ex vivo tubal embryos at the 2-, 8- and 16-cell stage were collected from the Fallopian tube and cultured in vitro to the blastocyst stage. At this stage, the methylation pattern of blastocysts from each group was compared to that of the blastocysts obtained exclusively ex vivo. A total of 1623 hypermethylated regions were detected in the blastocysts, which were transferred as 2-, 8- or 16-cell stage in vitro. The earlier the embryos were transferred to the in vitro culture system, the larger were the deviations. The time point of genome activation was designated as particularly critical (Salilew-Wondim et al., Reference Salilew-Wondim, Saeed-Zidane, Hoelker, Gebremedhn, Poirier, Pandey, Tholen, Neuhoff, Held, Besenfelder, Havlicek, Rings, Fournier, Gagné, Sirard, Robert, Gad, Schellander and Tesfaye2018).

In addition to the expression and methylation pattern of embryos, several studies have already shown that in vivo embryos significantly differ from in vitro produced embryos in terms of chromosome abnormalities. Viuff and et al. (Reference Viuff, Rickords, Offenberg, Hyttel, Avery, Greve, Olsaker, Williams, Callesen and Thomsen1999) demonstrated that in vitro produced embryos are highly mixoploid as measured by the analysis of chromosomes 6 and 7 in the blastomeres. Blastocysts obtained and tested ex vivo were significantly less mixoploid (Viuff et al., Reference Viuff, Rickords, Offenberg, Hyttel, Avery, Greve, Olsaker, Williams, Callesen and Thomsen1999 and Reference Viuff, Hendriksen, Vos, Dieleman, Bibby, Greve, Hyttel and Thomsen2001).

In a more technically sophisticated study, Tšuiko et al. (Reference Tšuiko, Catteeuw, Zamani Esteki, Destouni, Bogado Pascottini, Besenfelder, Havlicek, Smits, Kurg, Salumets, D’Hooghe, Voet, Van Soom and Vermeesch2017) used a high-resolution analysis method that allowed the demonstration of chromosome instability (CIN) and subtle subchromosomal aberrations. For this purpose, a genome-wide single-cell analysis method was used for estimating haplotyping and copy number profiling on an individual isolated blastomere level. For the experimental design, in vitro embryos were obtained on Day 2 post insemination after OPU with or without FSH stimulation or synchronous embryonic stages from the oviduct were collected after superovulation. All embryos were produced and derived from the same parent animals. The genomic stability of individual blastomeres of both in vitro culture groups was severely impaired. The incidence of whole chromosome or segmental aberration was significantly higher in in vitro produced than in ex vivo derived embryos. Only 18.8% of in vivo cultured embryos contained at least one blastomere with chromosomal anomalies, while OPU embryos with hormonal stimulation and follicular aspiration without hormonal stimulation showed 69.2% and 84.6% anomalies, respectively (Tšuiko et al., Reference Tšuiko, Catteeuw, Zamani Esteki, Destouni, Bogado Pascottini, Besenfelder, Havlicek, Smits, Kurg, Salumets, D’Hooghe, Voet, Van Soom and Vermeesch2017).

Overall, these studies indicate that in vitro culture conditions require further refinement to minimise developmental differences in embryos and reduce anomalies.

In vivo embryo development: hormones and lactation

Hormones, applied to synchronisation or superovulation, especially during lactation, currently play a major role in practice. In this context, it is important to note that in vitro culture conditions per se represent extraordinary unnatural environmental conditions; therefore, they may also indicate at which time point the conceptus is particularly sensitive in early embryonic development (Gad et al., Reference Gad, Hoelker, Besenfelder, Havlicek, Cinar, Rings, Held, Dufort, Sirard, Schellander and Tesfaye2012). This sensitivity to environmental changes does not only seem to be limited to in vitro conditions but rather suggests that similar appearances in this developmental stage can also be seen in animals under certain circumstances or give indications of early embryonic death.

Overall it has been estimated that nearly half a million bovine embryos (2017: 495 054 embryos) are currently being harvested via MOET programs worldwide (Viana, Reference Viana2018). These embryos develop temporarily to the morula/blastocyst stage in superstimulated animals before being collected. This recovery treatment deviates significantly from the treatment with which recipient animals are prepared. Consequently, these embryos develop under suboptimal hormonally superstimulated conditions in a developmental period, which is known to be very crucial for IVP-derived embryos. As already shown for chromosomal aberrations (Viuff et al., Reference Viuff, Rickords, Offenberg, Hyttel, Avery, Greve, Olsaker, Williams, Callesen and Thomsen1999 and Reference Viuff, Hendriksen, Vos, Dieleman, Bibby, Greve, Hyttel and Thomsen2001; Tšuiko et al., Reference Tšuiko, Catteeuw, Zamani Esteki, Destouni, Bogado Pascottini, Besenfelder, Havlicek, Smits, Kurg, Salumets, D’Hooghe, Voet, Van Soom and Vermeesch2017), ex vivo embryos thus also show minor changes that appear even under in vivo conditions. In order to investigate the sensitivity in the early developmental stage of embryos on in vivo environmental effects, animals were hormonally primed or stimulated or the lactation period was used to investigate embryo development in more detail.

In a first study, more than 1400 embryos were obtained from the Fallopian tube at various stages, after which heifers were stimulated with either FSH or equine chorionic gonadotropin (eCG). In general, the embryos showed very similar developmental kinetics regardless of the treatment. However, it was noticed that embryos derived from eCG stimulation show a greater variation with regard to their cleavage stage. This variation was also seen in the luteal morphology. Equine chorionic gonadotropin-stimulated ovaries had corpora lutea of very different sizes. Numerous and even large partially haemorrhagic follicles were visible. In addition, the number of non-viable embryos in the later stage of development in the Fallopian tube increased significantly in eCG-stimulated heifers in contrast to FSH treatment (Besenfelder et al., Reference Besenfelder, Havlicek, Moesslacher, Gilles, Tesfaye, Griese, Hoelker, Hyttel, Laurincik, Brem and Schellander2008).

In a subsequent study, the development kinetics and the expression profile of embryos from stimulated heifers were examined. This study focused exclusively on the effect of hormone treatment on embryo development in the Fallopian tube. For this purpose, the embryos were assigned to two different groups: a group (biphasic development) of embryos was endoscopically collected on Day 2 after stimulation with FSH and insemination and transferred to synchronised, mono-ovulatory recipient animals. In a second group (single phase), the embryos were also generated via FSH stimulation and artificial insemination. In both groups, the embryos were flushed on Day 7. Microarray data analysis showed that a total of 454 genes were expressed differently in the groups. In the superovulation group, 429 genes were expressed abundantly, while the biphasic (superovulation followed by single ovulation) embryo development yielded only 25 genes that were up-regulated. These genes have been assigned to processes involved in oxidative phosphorylation as well as various metabolic pathways, actions associated with transcription, translation and stress. Surprisingly, the biphasic development in non-stimulated animals resulted in a faster embryo development compared to embryos found only in superovulated animals. There was a morula/blastocyst ratio of 0.48 compared to 1.81, respectively (Gad et al., Reference Gad, Besenfelder, Rings, Ghanem, Salilew-Wondim, Hossain, Tesfaye, Lonergan, Becker, Cinar, Schellander, Havlicek and Hölker2011).

In addition to superovulation, the hormone progesterone plays a major role. Progesterone is produced by the luteal tissue and mainly affects embryo growth, interferon-τ production and, consequently, embryo implantation. It is well known that lactating dairy cows suffer from low progesterone concentration in the blood. In experiments by Carter et al. (Reference Carter, Rings, Mamo, Holker, Kuzmany, Besenfelder, Havlicek, Mehta, Tesfaye, Schellander and Lonergan2010), Day 2 synchronised heifers served for the transfer of in vitro derived bovine embryos. Approximately 100 cleaved embryos were endoscopically transferred into the ipsilateral oviduct of each heifer. Half of the recipient animals received a progesterone-releasing intravaginal device (PRID) from Day 3 to Day 7. All embryos were flushed from the Fallopian tubes and uterine horns on Day 7, and the messenger RNA expression profile was assayed using the Affymetrix GeneChip Bovine Genome Array. The administration of the PRID resulted in a significant increase in the plasma progesterone concentration from Day 3.5 to Day 7. A total of 194 differently expressed genes were identified using the genome wide gene expression analysis. These genes were associated with cross-talk between the embryo and its maternal environment by means of an interaction network analysis. Although these genes cannot directly be attributed to a better growth of the embryo, this transcriptome profile is discussed as valuable information in the context of the time after hatching of the embryo and/or the subsequent elongation phase (Carter et al., Reference Carter, Rings, Mamo, Holker, Kuzmany, Besenfelder, Havlicek, Mehta, Tesfaye, Schellander and Lonergan2010).

In the following study, Rizos et al. (Reference Rizos, Carter, Besenfelder, Havlicek and Lonergan2010a) synchronised heifers and lactating cows 60 days postpartum for in vivo culture of bovine embryos. Each animal received approximately 100 embryos of 2- to 4-cell stages into the Fallopian tube ipsilateral to the corpus luteum on Day 2 of the oestrous cycle. After 5 days, these embryos were re-collected. The progesterone analyses confirmed that lactating cows had significantly less plasma progesterone compared to heifers. From the in vivo culture in heifers, it was further shown that significantly more embryos could be recovered compared to cows (heifers: 79% v. cows: 57%). Similar to this result, nearly 34% of the embryos cultured in the heifers developed into blastocysts, while in cows only 18% reached the blastocyst stage. These results suggest that lactating dairy cows do not provide comparably adequate environmental conditions for early embryonic growth compared to heifers (Rizos et al., Reference Rizos, Carter, Besenfelder, Havlicek and Lonergan2010a).

Since heifers receiving progesterone supplementation and the comparison of lactating dairy cows with heifers do not accurately reflect the fertility problems in the dairy industry, a third approach has been performed using groups of cows after calving. As done before, also these cows received in vitro derived bovine embryos for temporary in vivo culture. Half of the cows were dried off after parturition, while the second group was allowed to normally produce milk. Both groups were used for embryo transfers and recovery around 60 days after parturition for this experiment. Also, these cows were on Day 2 of the oestrous cycle when approximately 65 embryos were endoscopically transferred into the Fallopian tubes and recovered after five days. In addition, the metabolism status of the cows was determined by regular blood sampling. Body weight and body condition score were significantly reduced in the lactating cows. Accordingly, non-esterified fatty acids and β-hydroxybutyrates were higher while blood glucose, insulin, and IGF-I were lower in the lactating cows. The recovery rate of the embryos did not differ between the groups, whereas the embryo development rate (49% v. 33%) was higher in non-lactating cows. This experiment also confirmed that the environment caused by lactation exerted a negative impact on fertility (Maillo et al., Reference Maillo, Rizos, Besenfelder, Havlicek, Kelly, Garrett and Lonergan2012). As shown by these examples, early embryo life represents a very sensitive indicator for environmental conditions that deviate from its natural habitat.

Conclusion

The use of ARTs has opened up many opportunities and challenges to both scientifically valuable fields and breeding purposes. Simultaneously, these conditions are inevitably associated with the generation of a non-physiological environment. The steady increase in the number of embryos from in vitro production including the variety of protocols for the application and improvement of culture systems subsequently necessitates to also increase our efforts in in vivo studies to expand our knowledge about fertility in its complexity and, in turn, to promote the efficient use of ARTs with special regard to embryo competence, number and vitality of calves born and economic aspects.

Acknowledgements

The studies revived have been partially supported by the European Commission (EU-FP7, FECUND grant agreement no. 312097).

Declaration of interest

There is no conflict of interest.

Ethics statement

Not applicable.

Software and data repository resources

None of the data were deposited in an official repository

Footnotes

a

Present address: Reproduction Centre Wieselburg, University of Veterinary Medicine, A-1210 Vienna, Austria.

References

Aguilar, J and Reyley, M 2005. The uterine tubal fluid: secretion, composition and biological effects. Animal Reproduction 2, 91105.Google Scholar
Almiñana, C, Tsikis, G, Labas, V, Uzbekov, R, da Silveira, JC, Bauersachs, S and Mermillod, P 2018. Deciphering the oviductal extracellular vesicles content across the estrous cycle: implications for the gametes-oviduct interactions and the environment of the potential embryo. BMC Genomics 19, 622. doi: 10.1186/s12864-018-4982-5.CrossRefGoogle ScholarPubMed
Avilés, M, Coy, P and Rizos, D 2015. The oviduct: a key organ for the success of early reproductive events. Animal Frontiers 5, 2531. doi: 10.2527/af.2015-0005.CrossRefGoogle Scholar
Avilés, M, Gutiérrez-Adán, A and Coy, P 2010. Oviductal secretions: Will they be key factors for the future ARTs? Molecular Human Reproduction 16, 896906. doi: 10.1093/molehr/gaq056.CrossRefGoogle ScholarPubMed
Bauersachs, S, Blum, H, Mallok, S, Wenigerkind, H, Rief, S, Prelle, K and Wolf, E 2003. Regulation of ipsilateral and contralateral bovine oviduct epithelial cell function in the postovulation period: a transcriptomics approach. Biology of Reproduction 68, 11701177.CrossRefGoogle ScholarPubMed
Bauersachs, S, Rehfeld, S, Ulbrich, SE, Mallok, S, Prelle, K, Wenigerkind, H, Einspanier, R, Blum, H and Wolf, E 2004. Monitoring gene expression changes in bovine oviduct epithelial cells during the oestrous cycle. Journal Molecular Endocrinology 32, 449466.CrossRefGoogle ScholarPubMed
Beebe, D, Wheeler, M, Zeringue, H, Walters, E and Raty, S 2002. Microfluidic technology for assisted reproduction. Theriogenology 1, 125135.CrossRefGoogle Scholar
Bennett, WA, Watts, TL, Blair, WD, Waldhalm, SJ and Fuquay, JW 1988. Patterns of oviducal motility in the cow during the oestrous cycle. Journal of Reproduction and Fertility 83, 537543.CrossRefGoogle ScholarPubMed
Besenfelder, U and Brem, G 1998. Tubal transfer of bovine embryos: a simple endoscopic method reducing long-term exposure of in vitro produced embryos. Theriogenology 50, 739745.CrossRefGoogle ScholarPubMed
Besenfelder, U, Havlicek, V, Kuzmany, A and Brem, G 2010. Endoscopic approaches to manage in vitro and in vivo embryo development: use of the bovine oviduct. Theriogenology 73, 768776. doi: 10.1016/j.theriogenology.2009.07.003.CrossRefGoogle ScholarPubMed
Besenfelder, U, Havlicek, V, Moesslacher, G, Gilles, M, Tesfaye, D, Griese, J, Hoelker, M, Hyttel, PM, Laurincik, J, Brem, G and Schellander, K 2008. Endoscopic recovery of early preimplantation bovine embryos: effect of hormonal stimulation, embryo kinetics and repeated collection. Journal of Reproduction in Domestic Animals 43, 566572. doi: 10.1111/j.1439-0531.2007.00953.x.CrossRefGoogle ScholarPubMed
Bonilla, L, Block, J, Denicol, AC and Hansen, PJ 2014. Consequences of transfer of an in vitro-produced embryo for the dam and resultant calf. Journal of Dairy Science 97, 229239. doi: 10.3168/jds.2013-6943.CrossRefGoogle Scholar
Buhi, WC 2002. Characterization and biological roles of oviduct-specific, oestrogen-dependent glycoprotein. Reproduction 123, 355362.CrossRefGoogle ScholarPubMed
Carter, F, Rings, F, Mamo, S, Holker, M, Kuzmany, A, Besenfelder, U, Havlicek, V, Mehta, JP, Tesfaye, D, Schellander, K and Lonergan, P 2010. Effect of elevated circulating progesterone concentration on bovine blastocyst development and global transcriptome following endoscopic transfer of in vitro produced embryos to the bovine oviduct. Biology of Reproduction 3, 707719. doi: 10.1095/biolreprod.109.082354.CrossRefGoogle Scholar
Chen, S, Palma-Vera, SE, Langhammer, M, Galuska, SP, Braun, BC, Krause, E, Lucas-Hahn, A and Schoen, J 2017. An air-liquid interphase approach for modeling the early embryomaternal contact zone. Scientific Reports 7, 42298. doi: 10.1038/srep42298.CrossRefGoogle Scholar
Cornelissen, MAMC, Mullaart, E, Van der Linde, C and Mulder, HA 2017. Estimating variance components and breeding values for number of oocytes and number of embryos in dairy cattle using a single-step genomic evaluation. Journal of Dairy Science 100, 46984705. doi: 10.3168/jds.2016-12075.CrossRefGoogle ScholarPubMed
Crosier, AE, Farin, PW, Dykstra, MJ, Alexander, JE and Farin, CE 2000. Ultrastructural morphometry of bovine compact morulae produced in vivo or in vitro. Biology Reproduction 62, 14591465.CrossRefGoogle ScholarPubMed
Denker, HW 2000. Structural dynamics and function of early embryonic coats. Cells Tissues Organs 166, 180207.CrossRefGoogle ScholarPubMed
Diskin, MG and Morris, DG 2008. Embryonic and early foetal losses in cattle and other ruminants. Reproduction in Domestic Animals 43 (suppl. 2), 260267. doi: 10.1111/j.1439-0531.2008.01171.x.CrossRefGoogle ScholarPubMed
Drews, B, Ringleb, J, Waurich, R, Hildebrandt, TB, Schröder, K and Roellig, K 2013. Free blastocyst and implantation stages in the European brown hare: correlation between ultrasound and histological data. Reproduction Fertility and Development 25, 866878. doi: 10.1071/RD12062.CrossRefGoogle ScholarPubMed
Duranthon, V and Chavatte-Palmer, P 2018. Long term effects of ART: What do animals tell us? Molecular Reproduction Development 85, 348368. doi: 10.1002/mrd.22970.CrossRefGoogle ScholarPubMed
Ellington, JE, Farrell, PB, Simkin, ME, Foote, RH, Goldman, EE and McGrath, AB 1990. Development and survival after transfer of cow embryos cultured from 1-2-cells to morulae or blastocyst in rabbit oviducts or in a simple medium with bovine oviduct epithelial cells. Journal of Reproduction and Fertility 89, 293299.CrossRefGoogle ScholarPubMed
Enright, BP, Lonergan, P, Dinnyes, A, Fair, T, Ward, FA, Yang, X and Boland, MP 2000. Culture of in vitro produced bovine zygotes in vitro vs in vivo: implications for early embryo development and quality. Theriogenology 54, 659673.CrossRefGoogle ScholarPubMed
Fayrer-Hosken, RA, Younls, AI, Brackett, BG, McBride, CE, Harper, KM, Keefer, KL and Cabaniss, DC 1989. Laparoscopic oviductal transfer of in vitro matured and in vitro fertilized bovine oocytes. Theriogenology 32, 413420.CrossRefGoogle ScholarPubMed
Fazeli, A and Holt, WV 2016. Cross talk during the periconception period. Theriogenology 86, 438442. doi: 10.1016/j.theriogenology.2016.04.059.CrossRefGoogle ScholarPubMed
Ferraz, MAMM, Rho, HS, Hemerich, D, Henning, HHW, van Tol, HTA, Hölker, M, Besenfelder, U, Mokry, M, Vos, PLAM, Stout, TAE, Le Gac, S and Gadella, BM 2018. An oviduct-on-a-chip provides an enhanced in vitro environment for zygote genome reprogramming. Nature Communications 9, 4934. doi: 10.1038/s41467-018-07119-8.CrossRefGoogle ScholarPubMed
Fujii, T, Hirayama, H, Naito, A, Kashima, M, Sakai, H, Fukuda, S, Yoshino, H, Moriyasu, S, Kageyama, S, Sugimoto, Y, Matsuyama, S, Hayakawa, H and Kimura, K 2017. Production of calves by the transfer of cryopreserved bovine elongating conceptuses and possible application for preimplantation genomic selection. Journal of Reproduction and Development 63, 497504. doi: 10.1262/jrd.2017-025.CrossRefGoogle ScholarPubMed
Gad, A, Besenfelder, U, Rings, F, Ghanem, N, Salilew-Wondim, D, Hossain, MM, Tesfaye, D, Lonergan, P, Becker, A, Cinar, U, Schellander, K, Havlicek, V and Hölker, M 2011. Effect of reproductive tract environment following controlled ovarian hyperstimulation treatment on embryo development and global transcriptome profile of blastocysts: implications for animal breeding and human assisted reproduction. Human Reproduction 26, 16931707. doi: 10.1093/humrep/der110.CrossRefGoogle ScholarPubMed
Gad, A, Hoelker, M, Besenfelder, U, Havlicek, V, Cinar, U, Rings, F, Held, E, Dufort, I, Sirard, MA, Schellander, K and Tesfaye, D 2012. Molecular mechanisms and pathways involved in bovine embryonic genome activation and their regulation by alternative in vivo and in vitro culture conditions. Biology of Reproduction 87, 100. doi: 10.1095/biolreprod.112.099697.CrossRefGoogle ScholarPubMed
Galli, C, Duchi, R, Crotti, G, Turini, P, Ponderato, N, Colleoni, S, Lagutina, I and Lazzari, G 2003. Bovine embryo technologies. Theriogenology 59, 599616.CrossRefGoogle ScholarPubMed
García, EV, Hamdi, M, Barrera, AD, Sánchez-Calabuig, MJ, Gutiérrez-Adán, A and Rizos, D 2017. Bovine embryo-oviduct interaction in vitro reveals an early cross talk mediated by BMP signaling. Reproduction 153, 631643. doi: 10.1530/REP-16-0654.CrossRefGoogle ScholarPubMed
Georges, M, Charlier, C and Hayes, B 2019. Harnessing genomic information for livestock improvement. Nature Reviews Genetics 20, 135156. doi: 10.1038/s41576-018-0082-2.CrossRefGoogle ScholarPubMed
Georgiou, AS, Sostaric, E, Wong, CH, Snijders, AP, Wright, PC, Moore, HD and Fazeli, A 2005. Gametes alter the oviductal secretory proteome. Molecular and Cellular Proteomics 4, 17851796.CrossRefGoogle ScholarPubMed
Goovaerts, IG, Leroy, JL, Van Soom, A, De Clercq, JB, Andries, S and Bols, PE 2009. Effect of cumulus cell coculture and oxygen tension on the in vitro developmental competence of bovine zygotes cultured singly. Theriogenology 71, 729738. doi: 10.1016/j.theriogenology.2008.09.038.CrossRefGoogle ScholarPubMed
Graf, A, Krebs, S, Zakhartchenko, V, Schwalb, B, Blum, H and Wolf, E 2014. Fine mapping of genome activation in bovine embryos by RNA sequencing. Proceedings of the national Academy of Sciences USA 111, 41394144. doi: 10.1073/pnas.1321569111.CrossRefGoogle ScholarPubMed
Granleese, T, Clark, SA, Kinghorn, BP and van der Werf, JHJ 2018. Optimizing female allocation to reproductive technologies considering merit, inbreeding and cost in nucleus breeding programmes with genomic selection. Journal of Animal Breeding and Genetics 136, 7990. doi: 10.1111/jbg.12374.CrossRefGoogle Scholar
Gutiérrez-Adán, A, Rizos, D, Fair, T, Moreira, PN, Pintado, B, de la Fuente, J, Boland, MP and Lonergan, P 2004. Effect of speed of development on mRNA expression pattern in early bovine embryos cultured in vivo or in vitro. Molecular Reproduction and Development 68, 441448.CrossRefGoogle ScholarPubMed
Havlicek, V, Kuzmany, A, Cseh, S, Brem, G and Besenfelder, U 2010. The effect of long-term in vivo culture in bovine oviduct and uterus on the development and cryo-tolerance of in vitro produced bovine embryos. Journal of Reproduction in Domestic Animals 45, 832837. doi: 10.1111/j.1439-0531.2009.01364.x.Google ScholarPubMed
Hugentobler, SA, Diskin, MG, Leese, HJ, Humpherson, PG, Watson, T, Sreenan, JM and Morris, DG 2007. Amino acids in oviduct and uterine fluid and blood plasma during the estrous cycle in the bovine. Molecular Reproduction and Development 74, 445454.CrossRefGoogle ScholarPubMed
Hugentobler, SA, Humpherson, PG, Leese, HJ, Sreenan, JM and Morris, DG 2008. Energy substrates in bovine oviduct and uterine fluid and blood plasma during the oestrous cycle. Molecular Reproduction and Development 75, 496503.CrossRefGoogle ScholarPubMed
Hugentobler, SA, Sreenan, JM, Humpherson, PG, Leese, HJ, Diskin, MG and Morris, DG 2010. Effects of changes in the concentration of systemic progesterone on ions, amino acids and energy substrates in cattle oviduct and uterine fluid and blood. Reproduction Fertility and Development 22, 684694. doi: 10.1071/RD09129.CrossRefGoogle ScholarPubMed
Hunter, RH, Coy, P, Gadea, J and Rath, D 2011. Considerations of viscosity in the preliminaries to mammalian fertilization. Journal of Assisted Reproduction and Genetics 28, 191197.CrossRefGoogle Scholar
Hunter, RHF, Cicinelli, E and Einer-Jensen, N 2007. Peritoneal fluid as an unrecognised vector between female reproductive tissues. Acta Obstetricia et Gynecologica 86, 260265.CrossRefGoogle ScholarPubMed
Jaton, C, Schenkel, FS, Sargolzaei, M, Cánova, A, Malchiodi, F, Price, CA, Baes, C and Miglior, F 2018. Genome-wide association study and in silico functional analysis of the number of embryos produced by Holstein donors. Journal of Dairy Science 101, 72487257. doi: 10.3168/jds.2017-13848.CrossRefGoogle ScholarPubMed
Jillella, D, Eaton, RJ and Baker, AA 1977. Successful transfer of a bovine embryo through a cannulated fallopian tube. Veterinary Record 100, 385386.CrossRefGoogle ScholarPubMed
Kölle, S, Dubielzig, S, Reese, S, Wehrend, A, König, P and Kummer, W 2009. Ciliary transport, gamete interaction, and effects of the early embryo in the oviduct: ex vivo analyses using a new digital videomicroscopic system in the cow. Biology of Reproduction 81, 267274.CrossRefGoogle ScholarPubMed
Lazzari, G, Colleoni, S, Lagutina, I, Crotti, G, Turini, P, Tessaro, I, Brunetti, D, Duchi, R and Galli, C 2010. Short-term and long-term effects of embryo culture in the surrogate sheep oviduct versus in vitro culture for different domestic species. Theriogenology 73, 748757. doi: 10.1016/j.theriogenology.2009.08.001.CrossRefGoogle ScholarPubMed
Lazzari, G, Wrenzycki, C, Herrmann, D, Duchi, R, Kruip, T, Niemann, H and Galli, C 2002. Cellular and molecular deviations in bovine in vitro-produced embryos are related to the large offspring syndrome. Biology of Reproduction 67, 767775.CrossRefGoogle ScholarPubMed
Lee, KF, Yao, YQ, Kwok, KL, Xu, JS and Yeung, WS 2002. Early developing embryos affect the gene expression patterns in the mouse oviduct. Biochemical and Biophysical Research Communications 292, 564570.CrossRefGoogle ScholarPubMed
Leese, HJ, Tay, JI, Reischl, J and Downing, SJ 2001. Formation of Fallopian tubal fluid: role of a neglected epithelium. Reproduction 121, 339346.CrossRefGoogle ScholarPubMed
Lonergan, P and Fair, T 2008. In vitro-produced bovine embryos: dealing with the warts. Theriogenology 69, 1722.CrossRefGoogle ScholarPubMed
Lonergan, P, Rizos, D, Kanka, J, Nemcova, L, Mbaye, AM, Kingston, M, Wade, M, Duffy, P and Boland, MP 2003. Temporal sensitivity of bovine embryos to culture environment after fertilization and the implications for blastocyst quality. Reproduction 126, 337346.CrossRefGoogle ScholarPubMed
Lopera-Vasquez, R, Hamdi, M, Maillo, V, Gutierrez-Adan, A, Bermejo-Alvarez, P, Ramírez, , Yáñez-Mó, M and Rizos, D 2017a. Effect of bovine oviductal extracellular vesicles on embryo development and quality in vitro. Reproduction 153, 461470. doi: 10.1530/REP-16-0384.CrossRefGoogle ScholarPubMed
Lopera-Vasquez, R, Hamdi, M, Maillo, V, Lloreda, V, Coy, P, Gutierrez-Adan, A, Bermejo-Alvarez, P and Rizos, D 2017b. Effect of bovine oviductal fluid on development and quality of bovine embryos produced in vitro. Reproduction Fertility and Development 29, 621629. doi: 10.1071/RD15238.CrossRefGoogle ScholarPubMed
Maeda, J, Kotsuji, F, Negami, A, Kamitani, N and Tominaga, T 1996. In vitro development of bovine embryos in conditioned media from bovine granulosa cells and Vero cells cultured in exogenous protein and amino acid-free chemically defined human tubal fluid medium. Biology of Reproduction 54, 930936.CrossRefGoogle ScholarPubMed
Maillo, V, de Frutos, C, O’Gaora, P, Forde, N, Burns, GW, Spencer, TE, Gutierrez-Adan, A, Lonergan, P and Rizos, D 2016. Spatial differences in gene expression in the bovine oviduct. Reproduction 152, 3746. doi: 10.1530/REP-16-0074.CrossRefGoogle ScholarPubMed
Maillo, V, Gaora, , Forde, N, Besenfelder, U, Havlicek, V, Burns, GW, Spencer, TE, Gutierrez-Adan, A, Lonergan, P and Rizos, D 2015. Oviduct-embryo interactions in cattle: two-way traffic or a one-way street? Biology of Reproduction 92, 144. doi: 10.1095/biolreprod.115.127969.CrossRefGoogle ScholarPubMed
Maillo, V, Rizos, D, Besenfelder, U, Havlicek, V, Kelly, AK, Garrett, M and Lonergan, P 2012. Influence of lactation on metabolic characteristics and embryo development in postpartum Holstein dairy cows. Journal of Dairy Science 95, 38653876. doi: 10.3168/jds.2011-5270.CrossRefGoogle ScholarPubMed
May-Panloup, P, Vignon, X, Chrétien, MF, Heyman, Y, Tamassia, M, Malthièry, Y and Reynier, P 2005. Increase of mitochondrial DNA content and transcripts in early bovine embryogenesis associated with upregulation of mtTFA and NRF1 transcription factors. Reproductive Biology and Endocrinology 3, 65 doi: 10.1186/1477-7827-3-65.CrossRefGoogle ScholarPubMed
Menchaca, A, dos Santos-Neto, PC, Cuadro, F, Souza-Neves, M and Crispo, M 2018. From reproductive technologies to genome editing in small ruminants: an embryo’s journey. Animal Reproduction 15 (suppl. 1), 984995.CrossRefGoogle Scholar
Menezo, Y and Guerin, P 1997. The mammalian oviduct: biochemistry and physiology. European Journal of Obstetrics and Gynecology and Reproductive Biology 73, 99104.CrossRefGoogle ScholarPubMed
Mertens, E, Besenfelder, U, Gilles, M, Hölker, M, Rings, F, Havlicek, V, Schellander, K and Herrler, A 2007. Influence of in vitro culture of bovine embryos on the structure of the zona pellucida. Reproduction of Fertility and Development 19, 211212.CrossRefGoogle Scholar
Mertens, E, Gilles, M, Rings, F,Hoelker, M, Schellander, K and Herrler, A 2006. Influence of in vitro culture of bovine embryos on the structure of the zona pellucida. Journal of Reproduction in Domestic Animals 41 (suppl. 1), 23.Google Scholar
Mouguelar, H, Díaz, T, Borghi, D, Quinteros, R, Bonino, F, Apichela, SA and Aguilar, JJ 2015. Morphometric study of the mare oviductal mucosa at different reproductive stages. The Anatomical Record 298, 19501959. doi: 10.1002/ar.23193.CrossRefGoogle ScholarPubMed
Murakami, H and Imai, H 1996. Successful implantation of in vitro cultured rabbit embryos after uterine transfer: a role for mucin. Molecular Reproduction and Development 43, 167170.3.0.CO;2-P>CrossRefGoogle ScholarPubMed
Raposo, G and Stoorvogel, W 2013. Extracellular vesicles: exosomes, microvesicles, and friends Journal Cell Biology 18, 373383. doi: 10.1083/jcb.201211138.CrossRefGoogle Scholar
Reichenbach, HD, Wiebke, NH, Besenfelder, U, Mödl, J and Brem, G 1993. Transvaginal laparoscopic guided aspiration of bovine follicular oocytes: Preliminary results. Theriogenology 39, 295.CrossRefGoogle Scholar
Reichenbach, HD, Wiebke, NH, Mödl, J, Zhu, J and Brem, G 1994. Laparoscopy through the vaginal fornix of cows for the repeated aspiration of follicular oocytes. Veterinary Record 135, 353536.CrossRefGoogle ScholarPubMed
Rizos, D, Carter, F, Besenfelder, U, Havlicek, V and Lonergan, P 2010a. Contribution of the female reproductive tract to low fertility in postpartum lactating dairy cows. Journal of Dairy Science 93, 10221029.CrossRefGoogle ScholarPubMed
Rizos, D, Fair, T, Papadopoulos, S, Boland, MP and Lonergan, P 2002. Developmental, qualitative, and ultrastructural differences between ovine and bovine embryos produced in vivo or in vitro. Molecular Reproduction and Development 62, 320327.CrossRefGoogle ScholarPubMed
Rizos, D, Ramirez, MA, Pintado, B, Lonergan, P and Gutierrez-Adan, A 2010b. Culture of bovine embryos in intermediate host oviducts with emphasis on the isolated mouse oviduct. Theriogenology 3, 777785.CrossRefGoogle Scholar
Ruckebusch, Y and Bayard, F 1975. Motility of the oviduct and uterus of the cow during the oestrous cycle. Journal of Reproduction and Fertility 43, 2332.CrossRefGoogle ScholarPubMed
Salilew-Wondim, D, Saeed-Zidane, M, Hoelker, M, Gebremedhn, S, Poirier, M, Pandey, HO, Tholen, E, Neuhoff, C, Held, E, Besenfelder, U, Havlicek, V, Rings, F, Fournier, E, Gagné, D, Sirard, MA, Robert, C, Gad, A, Schellander, K and Tesfaye, D 2018. Genome-wide DNA methylation patterns of bovine blastocysts derived from in vivo embryos subjected to in vitro culture before, during or after embryonic genome activation. BMC Genomics 19, 424. doi: 10.1186/s12864-018-4826-3.CrossRefGoogle ScholarPubMed
Sartori, R, Bastos, MR and Wiltbank, MC 2010. Factors affecting fertilisation and early embryo quality in single- and superovulated dairy cattle. Reproduction Fertility and Development 22, 151158. doi: 10.1071/RD09221.CrossRefGoogle ScholarPubMed
Sinowatz, F, Töpfer-Petersen, E, Kölle, S and Palma, G 2001. Functional morphology of the zona pellucida. Anatomia, Histologia, Embryologia 30, 257263.CrossRefGoogle ScholarPubMed
Sirard, MA and Lambert, RD 1985. In vitro fertilization of bovine follicular oocytes obtained by laparoscopy. Biology of Reproduction 33, 487494.CrossRefGoogle ScholarPubMed
Smits, K, De Coninck, DIM, Van Nieuwerburgh, F, Govaere, J, Van Poucke, M, Peelman, L, Deforce, D and Van Soom, A 2016. The equine embryo influences immune-related gene expression in the oviduct. Biology of Reproduction 94, 36. doi: 10.1095/biolreprod.115.136432CrossRefGoogle ScholarPubMed
Stojkovic, M, Wolf, E, Büttner, M, Berg, U, Charpigny, G, Schmitt, A and Brem, G 1995. Secretion of biologically active interferon tau by in vitro-derived bovine trophoblastic tissue. Biology of Reproduction 53, 15001507.CrossRefGoogle ScholarPubMed
Trounson, AO, Willadsen, SM, Rowson, LE and Newcomb, R 1976. The storage of cow eggs at room temperature and at low temperatures. Journal of Reproduction and Fertility 46, 173178.CrossRefGoogle ScholarPubMed
Tšuiko, O, Catteeuw, M, Zamani Esteki, M, Destouni, A, Bogado Pascottini, O, Besenfelder, U, Havlicek, V, Smits, K, Kurg, A, Salumets, A, D’Hooghe, T, Voet, T, Van Soom, A and Vermeesch, RJ 2017. Genome stability of bovine in vivo-conceived cleavage-stage embryos is higher compared to in vitro-produced embryos. Human Reproduction 23, 110. doi: 10.1093/humrep/dex286.Google Scholar
Van Eetvelde, M, Heras, S, Leroy, JLMR, Van Soom, A and Opsomer, G 2017. The Importance of the periconception period: Immediate effects in cattle breeding and in assisted reproduction such as artificial insemination and embryo transfer. In Periconception in physiology and medicine. Advances in Experimental Medicine and Biology (eds. Fazeli, A and Holt, W), pp. 4168. Springer, Cham, Switzerland.CrossRefGoogle Scholar
Viana, J 2018. 2017 Statistics of embryo production and transfer in domestic farm animals. Embryo Technology Newsletter of the International Embryo Technology Society 36, 825.Google Scholar
Viuff, D, Hendriksen, PJ, Vos, PL, Dieleman, SJ, Bibby, BM, Greve, T, Hyttel, P and Thomsen, PD 2001. Chromosomal abnormalities and developmental kinetics in in vivo-developed cattle embryos at days 2 to 5 after ovulation. Biology of Reproduction 65, 204208.CrossRefGoogle ScholarPubMed
Viuff, D, Rickords, L, Offenberg, H, Hyttel, P, Avery, B, Greve, T, Olsaker, I, Williams, JL, Callesen, H and Thomsen, PD 1999. A high proportion of bovine blastocysts produced in vitro are mixoploid. Biology of Reproduction 60, 12731278.CrossRefGoogle ScholarPubMed
Weber, JA, Freeman, DA, Vanderwall, DK and Woods, GL 1991. Prostaglandin E2 hastens oviductal transport of equine embryos. Biology of Reproduction 45, 544546.CrossRefGoogle ScholarPubMed
Wolf, E, Arnold, GJ, Bauersachs, S, Beier, HM, Blum, H, Einspanier, R, Fröhlich, T, Herrler, A, Hiendleder, S, Kölle, S, Prelle, K, Reichenbach, HD, Stojkovic, M, Wenigerkind, H and Sinowatz, F 2003. Embryo-maternal communication in bovine—strategies for deciphering a complex cross-talk. Journal of Reproduction in Domestic Animals 38, 276289.CrossRefGoogle ScholarPubMed
Yániz, JL, Lopez-Gatius, F, Santolaria, P and Mullins, KJ 2000. Study of the functional anatomy of bovine oviductal mucosa. Anatomical Record 260, 268278.3.0.CO;2-L>CrossRefGoogle ScholarPubMed
Young, LE, Sinclair, KD and Wilmut, I 1998. Large offspring syndrome in cattle and sheep. Reviews of Reproduction 3, 155163.CrossRefGoogle ScholarPubMed
Zebeli, Q, Ghareeb, K, Humer, E, Metzler-Zebeli, BU and Besenfelder, U 2015. Nutrition, rumen health and inflammation in the transition period and their role on overall health and fertility in dairy cows. Research in Veterinary Science 103, 126–36. doi: 10.1016/j.rvsc.2015.09.020.CrossRefGoogle ScholarPubMed
Figure 0

Figure 1 Access to the bovine oviduct for transfer or for flushing. Embryo transfer via a glass capillary after single ovulation (a) or flushing after superovulation (b) can be performed in the same way. Slightly lifting the ovary allows the presentation of the adjacent oviduct ((c) presentation of the infundibulum and the ampulla). Once the entry can be gained into the oviduct ((d) see the capillary parallel to the first part of the ampulla), a capillary can be introduced along this route ((e) and (f)).