Abstract
Global cattle genetic market is experiencing a change of strategy, large genetic companies, traditionally recognized in the artificial insemination field, have also begun to operate in the embryo market. Consequently, the demand for in vitro produced (IVP) embryos has grown. However, the overall efficiency of the biotechnology process remains low. Additionally, the lack of homogeneity of post-cryopreservation survival results of IVP embryos still impairing a massive dissemination of this biotechnology in the field. A great challenge for in vitro production labs is to increase the amount of embryos produced with exceptional quality after each round of in vitro fertilization. Herein, we discuss the molecular and cellular features associated with the competence and cryosurvival of IVP embryos. First, morphofunctional, cellular and molecular competence of the embryos were addressed and a relationship between embryo developmental ability and quality were established with cryosurvival and pregnancy success. Additionally, determinant factors of embryo competence and cryosurvival were discussed including the following effects: genotype, oocyte quality and follicular microenvironment, in vitro production conditions, and lipids and other determining molecules. Finally, embryo cryopreservation aspects were addressed and an embryo-focused approach to improve cryosurvival was presented.
Keywords:
in vitro production of embryos; bovine; embryo quality; cryopreservation; cryotolerance; pregnancy success
Introduction
In the last few years, the importance of in vitro production of embryos (IVPE) has increased within the reproductive biotechnologies applied in dairy and beef cattle. As a consequence, for the first time in the last two decades, the number of in vitro produced (IVP) surpassed the number of in vivo derived (IVD) embryos globally (Fig. 1A).
Total number, in vivo derived (IVD) and in vitro produced (IVP) bovine embryos in the world over the last 20 years (A). Number of cryopreserved IVD and IVP bovine embryos in the world in the last 20 years (B). Source: Data retrieval committee, International embryo technology society – IETS (https://www.iets.org/comm_data.asp?autotry=true&ULnotkn=true, accessed June 2019; and Perry, 2017Perry G. 2016 Statistics of embryo collection and transfer in domestic farm animals. International embryo technology society. 2017. Available from: https://www.iets.org/pdf/comm_data/IETS_Data_Retrieval_Report_2016_v2.pdf. Accessed in: May 10th. 2019.
https://www.iets.org/pdf/comm_data/IETS_... ).
However, despite the favorable scenario associated with the IVPE, it is important to highlight that even with great effort of the scientific community aimed to improve embryo development and competence in the last decades, the overall efficiency of the biotechnology process remains low (Lonergan et al., 2016Lonergan P, Fair T, Forde N, Rizos D. 2016. Embryo development in dairy cattle. Theriogenology, 86:270-277.; Sudano et al., 2019Sudano MJ, Marinho LSR, Silveira JC, Basso AC, Bohrer R, Lamberti GSE, Watanabe YF, Seneda MM, Meirelles FV. Evolução aplicada da produção in vitro de embriões bovinos. In Gonçalves PBD, Figueiredo JR, Gasperin BG. (Ed.) Biotécnicas aplicadas à reprodução animal, 2019, 3 ed. Grupo Gen, in press.).
Additionally, embryos derived from in vitro production process generally present a reduced quality compared with the in vivo counterparts (Rizos et al., 2002Rizos D, Ward F, Duffy P, Boland MP, Lonergan P. 2002. Consequences of bovine oocyte maturation, fertilization or early embryo development in vitro versus in vivo: Implications for blastocyst yield and blastocyst quality. Mol Reprod Dev, 61:234-248.; Sudano et al., 2012Sudano MJ, Santos VG, Tata A, Ferreira CR, Paschoal DM, Machado R, Buratini J, Eberlin MN, Landim-Alvarenga FDC. 2012. Phosphatidylcholine and Sphingomyelin Profiles Vary in Bos taurus indicus and Bos taurus taurus In Vitro- and In Vivo-Produced Blastocysts. Biol Reprod, 87:1-11.). Consequently, even with important advances in the last years, the cryopreservation of IVP embryos remains as one of the most challenges areas of the embryo technologies since the homogeneity of the achieved results is still not satisfactory. These results impact directly in the reduced number of IVP embryos cryopreserved and transferred to recipients, in relation to the total transferred, when compared with the IVD embryos in the world over the last two decades (Fig. 1B).
Therefore, the objective of this work was to address: i) morphofunctional, cellular and molecular competence of embryos; ii) determinant factors of embryo competence and cryosurvival, including the following effects: genotype, oocyte quality and follicular microenvironment, in vitro production conditions, and lipids and other determining molecules; and iii) embryo cryopreservation aspects and an embryo-focused approach to improve cryosurvival.
Embryo Competence
It is commonly accepted that in vitro produced (IVP) bovine embryos have lower developmental ability and quality than in vivo-derived (IVD) embryos (Hasler et al., 1995Hasler JF, Henderson WB, Hurtgen PJ, Jin ZQ, McCauley AD, Mower SA, Neely B, Shuey LS, Stokes JE, Trimmer SA. 1995. Production, freezing and transfer of bovine IVF embryos and subsequent calving results. Theriogenology, 43:141-152.; Sudano et al., 2013aSudano MJ, Caixeta ES, Paschoal DM, Martins A, Machado R, Buratini J, Landim-Alvarenga FDC.2013a. Cryotolerance and global gene-expression patterns of Bos taurus indicus and Bos taurus taurus in vitro- and in vivo-produced blastocysts. Reprod Fertil Dev, 26:1129-1141.). The embryo developmental ability and quality are two crucial variables associated with cryosurvival, pregnancy establishment and maintenance that can be explained by morphofunctional, cellular and molecular competence of the embryos.
At the present review, the term embryo competence is used to describe the ability of the embryo to develop properly and with an exceptional quality that facilitates cryosurvival and/or pregnancy establishment.
Embryo morphofunctional competence
Since the establishment of the biotechniques used in assisted reproduction in mammals, a good relationship between morphological evaluation of the embryo quality and pregnancy success after transfer has been established (Lindner and Wright, 1983Lindner GM, Wright RW, Jr. 1983. Bovine embryo morphology and evaluation. Theriogenology, 20:407-416.; Overström, 1996Overström EW. 1996. In vitro assessment of embryo viability. Theriogenology, 45:3-16.). In most mammalian species, the morphological evaluation of the embryo is the most used method to select embryos suitable for transfer, mainly in cattle andhumans (Lindner and Wright, 1983Lindner GM, Wright RW, Jr. 1983. Bovine embryo morphology and evaluation. Theriogenology, 20:407-416.; Van Soom et al., 2001Van Soom A, Mahmoudzadeh AR, Christophe A, Ysebaert MT, de Kruif A. 2001. Silicone oil used in microdrop culture can affect bovine embryonic development and freezability. Reprod Domest Anim, 36:169-176.). Currently the embryo evaluation system recommended by the International Embryo Technology Society (IETS) is described by Bó and Mapletoft (2013)Bó G, Mapletoft RJ. 2013. Evaluation and classification of bovine embryos. Anim Reprod, 10:344-348., which classifies the embryos into four quality rankings: (1) excellent or good, (2) regular, (3) bad or (4) dead or degenerate. Drastic changes in embryo’s morphology can directly affect its competence.
Assisted reproductive technologies such as in vitro production, nuclear transfer and gene transfer sheds light that imperceptible modifications in embryo structure can seriously compromise its quality. Two classical examples could be cited to illustrate this issue: the silicon/oil used to cover the microdrop culture affects the development of bovine embryos and their cryosurvival according to the product batch; however, embryos produced or not with this oil are morphologically similar. Another example is the parthenogenetic embryo, incapable of producing a successful pregnancy but impossible to be morphologic selected in the blastocyst stage from fertilized embryos (Van Soom et al., 2001Van Soom A, Mahmoudzadeh AR, Christophe A, Ysebaert MT, de Kruif A. 2001. Silicone oil used in microdrop culture can affect bovine embryonic development and freezability. Reprod Domest Anim, 36:169-176.).
Since embryos are mostly evaluated when it still confined in zona pellucida (ZP), this structure and the perivitelline space have some importance to discuss. The zona pellucida is a glycoprotein layer produced during oocyte growth phase surrounding the mammalian embryo between the zygote and the blastocyst stage. In average the thickness of ZP in mammals is 10 μm and its ultrastructure characteristics at oocytes (number and diameter of the pores) and embryos (thickness) can be associated with developmental competence (Santos et al., 2008Santos P, Chaveiro A, Simões N, Moreira da Silva F. 2008. Bovine oocyte quality in relation to ultrastructural characteristics of zona pellucida, polyspermic penetration and developmental competence. Reprod Domest Anim., 43:685-689.; Báez et al., 2019Báez F, Camargo A, Reyes AL, Márquez A, Paula-Lopes F, Viñolese C. 2019. Time-dependent effects of heat shock on the zona pellucida ultrastructure and in vitro developmental competence of bovine oocytes. Reprod Biol, 19:195-203.) and hatching ability (Hoelker et al., 2006Hoelker M, Schmoll F, Schneider H, Rings F, Gilles M, Tesfaye D, Jennen D, Tholen E, Griese J, Schellander K. 2006. Bovine blastocyst diameter as amorphological tool to predict embryo cell counts, embryo sex, hatching ability and developmental characteristics after transfer to recipients. Reprod Fertil Dev, 18:551-557.), respectively. It’s well known that, the ZP thickness decrease further the embryo development (Van Soom et al., 2003Van Soom A, Mateusen B, Leroy J, De Kruif A. 2003. Assessment of mammalian embryo quality: what can we learn from embryo morphology? Reprod Biomed Online, 7:664-670.) and the average diameter of the ZP is significantly smaller at hatching for IVD versus IVP blastocysts (Holm et al., 2002Holm P, Booth PJ, Callesen H. 2002. Kinetics of early in vitro development of bovine in vivo- and in vitro-derived zygotes produced and/or cultured in chemically defined or serum-containing media. Reproduction, 123:553-565.). Although no relationship between ZP thickness and embryo viability after transfer to recipients was established (Hoelker et a., 2006Hoelker M, Schmoll F, Schneider H, Rings F, Gilles M, Tesfaye D, Jennen D, Tholen E, Griese J, Schellander K. 2006. Bovine blastocyst diameter as amorphological tool to predict embryo cell counts, embryo sex, hatching ability and developmental characteristics after transfer to recipients. Reprod Fertil Dev, 18:551-557.), the ZP remains crucial for embryo handling before transfer to recipients in the majority of reproductive technologies, and especially, during embryo cryopreservation. Another parameter to be evaluated is the perivitelline space (PS), because it has been recognized that IVD embryos have larger PS than IVP embryos, possibly by the swelling of the blastomeres in the latter. The reduction in size of the PS could be associated with lower embryo quality and related with problems during the morula compaction stage (Van Soom et al., 2003Van Soom A, Mateusen B, Leroy J, De Kruif A. 2003. Assessment of mammalian embryo quality: what can we learn from embryo morphology? Reprod Biomed Online, 7:664-670.).
Specifically, in the embryo itself, Merton (2002)Merton S, 2002. Morphological Evaluation of Embryos in Domestic Species. In: Van Soom A, Boerjan M. (Ed.) Assessment of Mammalian Embryo Quality. Springer Science+Business Media Dordrecht, pp429. pointed out some important variables to be considered in the global morphological evaluation, which included: size and shape of blastomeres, presence of extruded or fragmented cells, compaction, color and stage of development which is reached at a certain time after fertilization.
In comparison to humans and mice, all ruminants have a larger accumulation of lipid droplets in the embryo, which cause a quite dark cytoplasm, even darker in pigs, cats and dogs (Van Soom et al., 2003Van Soom A, Mateusen B, Leroy J, De Kruif A. 2003. Assessment of mammalian embryo quality: what can we learn from embryo morphology? Reprod Biomed Online, 7:664-670.). This opacity disturbs the possibility of quantification of number of pronuclei at the zygote stages and thus select against triploids, parthenotes or unfertilized embryos an excellent method for selecting human embryos with high implantation potential (Lundqvist et al., 2001Lundqvist M, Johansson U, Lundkvist O, Milton K, Westin C, Simberg N. 2001. Does pronuclear morphology and/or early cleavage rate predict embryo implantation potential? Reprod Biomed Online, 2:12-16.). Besides that, a polarized distribution of the pronuclei during pronuclear alignment is related to chromosomally normal embryos in humans (Coskun et al., 2003Coskun S, Hellani A, Jaroudi K, Al-Mayman H, Al-Kabra M, Qeba M. 2003. Nucleolar precursor body distribution in pronuclei is correlated to chromosomal abnormalities in embryos. Reprod Biomed Online, 7:86-90.).
Studies show that the presence of serum in the culture medium can induce accumulation of cytoplasmic lipid droplets in bovine embryos. These fluctuations of cytoplasmic lipid droplets make darker embryos and lesser cryotolerant. The Sudan Black staining method has been vastly used for identifying embryos with increased numbers of lipid droplets (Abe et al., 2002Abe H, Yamashita S, Satoh T, Hoshi H. 2002. Accumulation of cytoplasmic lipid droplets in bovine embryos and cryotolerance of embryos developed in different culture systems using serum-free or serum-containing media. Mol Reprod Dev, 61:57-66.; Sudano et al., 2011Sudano MJ, Paschoal DM, da Silva Rascado T, Magalhães LCO, Crocomo LF, de Lima-Neto JF, da Cruz Landim-Alvarenga F. 2011. Lipid content and apoptosis of in vitro-produced bovine embryos as determinants of susceptibility to vitrification. Theriogenology, 75:1211-1220.). Serum also affects the duration from maximal compaction to blastulation, shortening 12h in comparison to IVD embryos. This short compaction period and early blastulation in embryos coincided with perturbed allocation of cells to the inner cell mass and trophectoderm and is caused by decreased expression of transcripts that are involved in the construction of tight junctions, all this together decreased cryosurvival of the subsequently formed blastocysts (Van Soom et al., 1997Van Soom A, Ysebaert MT, de Kruif A. 1997. Relationship between timing of development, morula morphology, and cell allocation to inner cell mass and trophectoderm in in vitro-produced bovine embryos. Mol Reprod Dev, 47:47-56.; Miller et al., 2003Miller DJ, Eckert JJ, Lazzari G, Duranthon-Richoux V, Sreenan J, Morris D, Galli C, Renard JP, Fleming TP. 2003. Tight junction messenger RNA expression levels in bovine embryos are dependent upon the ability to compact and in vitro culture methods. Biol Reprod, 68:1394-1402.).
Timing of blastocyst formation is a good marker for embryo quality as well early cavitating embryos are superior in comparison with the latter cavitating embryos in regard to total cell number, allocation of inner cell mass and trophectoderm cells, and cryosurvival (Mahmoudzadeh et al., 1995Mahmoudzadeh AR, Van Soom A, Bols P, Ysebaert MT, de Kruif A. 1995. Optimization of a simple vitrification procedure for bovine embryos produced in vitro: effect of developmental stage, two-step addition of cryoprotectant and sucrose dilution on embryonic survival. J Reprod Fertil, 103:33-39.; Van Soom et al., 1997Van Soom A, Ysebaert MT, de Kruif A. 1997. Relationship between timing of development, morula morphology, and cell allocation to inner cell mass and trophectoderm in in vitro-produced bovine embryos. Mol Reprod Dev, 47:47-56.). Although, reliable morphological predictors at the blastocyst stage for competence after embryo transfer are still lacking. Nevertheless, there is a consensus by many research groups and commercial companies that the greatest results of pregnancy rates are generally achieved after the transfer of bovine day 7 expanded blastocysts regardless of whether they were fresh or cryopreserved (Hasler 2000Hasler JF. 2000. In vitro culture of bovine embryos in Menezo’s B2 medium with or without coculture and serum: the normalcy of pregnancies and calves resulting from transferred embryos. Anim Reprod Sci, 60-61:81-91.; Xu et al., 2006Xu J, Guo Z, Su L, Nedambale TL, Zhang J, Schenk J, Moreno JF, Dinnyes A, Ji W, Tian XC, Yang X, Du F. 2006. Developmental potential of vitrified holstein cattle embryos fertilized in vitro with sex-sorted sperm. J Dairy Sci, 89:2510-2518.; Block et al., 2009Block J, Bonilla L, Hansen PJ. 2009. Effect of addition of hyaluronan to embryo culture medium on survival of bovine embryos in vitro following vitrification and establishment of pregnancy after transfer to recipients. Theriogenology, 71:1063-1071.; Sanches et al., 2013Sanches BV, Marinho LS, Filho BD, Pontes JH, Basso AC, Meirinhos ML, Silva-Santos KC, Ferreira CR, Seneda MM. 2013. Cryosurvival and pregnancy rates after exposure of IVF-derived bos indicus embryos to forskolin before vitrification. Theriogenology, 80:372-377.; Munoz et al., 2014Munoz M, Uyar A, Correia E, Diez C, Fernandez-Gonzalez A, Caamano JN, Martinez-Bello D, Trigal B, Humblot P, Ponsart C, Guyader-Joly C, Carrocera S, Martin D, Marquant Le Guienne B, Seli E, Gomez E. 2014. Prediction of pregnancy viability in bovine in vitro-produced embryos and recipient plasma with Fourier transform infrared spectroscopy. J Dairy Sci, 97:5497-5507.; Mogas, 2019Mogas T. 2019. Update on the vitrification of bovine oocytes and in vitro-produced embryos. Reprod Fertil Dev, 31:105-117.).
Embryos suffer considerable morphofunctional damage when they are cryopreserved. The challenge during the process of vitrification/freezing followed by warming/thawing is enormous, which includes osmotic, thermic and mechanical stress. The extent of the cryopreservation injuries depends on factors such as the membrane permeability, size and shape of the cells, and quality and sensitivity of the blastomeres (Vajta and Kuwayama, 2006Vajta G, Kuwayama M. 2006. Improving cryopreservation systems. Theriogenology, 65:236-244.). In order to obtain greater cryosurvival results, therefore, it is sound to cryopreserve following transfer expanded blastocysts of extraordinary superior quality. No signs of degeneration in the morphological evaluation of embryos would be recommended (Hasler 2000Hasler JF. 2000. In vitro culture of bovine embryos in Menezo’s B2 medium with or without coculture and serum: the normalcy of pregnancies and calves resulting from transferred embryos. Anim Reprod Sci, 60-61:81-91.; Xu et al., 2006Xu J, Guo Z, Su L, Nedambale TL, Zhang J, Schenk J, Moreno JF, Dinnyes A, Ji W, Tian XC, Yang X, Du F. 2006. Developmental potential of vitrified holstein cattle embryos fertilized in vitro with sex-sorted sperm. J Dairy Sci, 89:2510-2518.; Block et al., 2009Block J, Bonilla L, Hansen PJ. 2009. Effect of addition of hyaluronan to embryo culture medium on survival of bovine embryos in vitro following vitrification and establishment of pregnancy after transfer to recipients. Theriogenology, 71:1063-1071.; Sanches et al., 2013Sanches BV, Marinho LS, Filho BD, Pontes JH, Basso AC, Meirinhos ML, Silva-Santos KC, Ferreira CR, Seneda MM. 2013. Cryosurvival and pregnancy rates after exposure of IVF-derived bos indicus embryos to forskolin before vitrification. Theriogenology, 80:372-377.; Munoz et al., 2014Munoz M, Uyar A, Correia E, Diez C, Fernandez-Gonzalez A, Caamano JN, Martinez-Bello D, Trigal B, Humblot P, Ponsart C, Guyader-Joly C, Carrocera S, Martin D, Marquant Le Guienne B, Seli E, Gomez E. 2014. Prediction of pregnancy viability in bovine in vitro-produced embryos and recipient plasma with Fourier transform infrared spectroscopy. J Dairy Sci, 97:5497-5507.; Mogas, 2019Mogas T. 2019. Update on the vitrification of bovine oocytes and in vitro-produced embryos. Reprod Fertil Dev, 31:105-117.).
Embryo cellular competence
The initial development of embryos in mammals has unique physiological characteristics andmechanisms of regulation. Modifications in the properties of cytoplasmic organelles, such as location, morphology and biochemical activity must occur to achieve high quality during development (Sirard et al., 2006Sirard MA, Richard F, Blondin P, Robert C. 2006. Contribution of the oocyte to embryo quality. Theriogenology, 65:126-136.; Mao et al., 2014Mao L, Lou H, Lou Y, Wang N, Jin F. 2014. Behaviour of cytoplasmic organelles and cytoskeleton during oocyte maturation. Reprod Biomed Online, 28:284-299.).
Initially, mitochondria constitute the powerhouses of cells, responsible for energy to boost all cellular functions. This organelle has an important role in calcium homoeostasis, fatty acid oxidation and apoptosis (Lledo et al., 2018Lledo B, Ortiz JA, Morales R, García-Hernández E, Ten J, Bernabeu A, Llácer J, Bernabeu R. 2018. Comprehensive mitochondrial DNA analysis and IVF outcome. Hum Reprod Open, 4:1-9.). The embryo only starts to replicate it at hatched blastocyst stage, so all stages before depends on the mitochondrias pre-existent in the oocyte (Spikings et al., 2006Spikings EC, Alderson J, St John JC. 2006. Transmission of mitochondrial DNA following assisted reproduction and nuclear transfer. Hum Reprod Update, 12:401-415.). Alterations in normal mitochondrial functions can lead to metabolic diseases affecting the preimplantation development (Van Blerkom, 2004Van Blerkom J. 2004. Mitochondria in human oogenesis and preimplantation embryogenesis: engines of metabolism, ionic regulation and developmental competence. Reproduction, 128:269-280.; Schaefer et al., 2008Schaefer AM, McFarland R, Blakely EL, He L, Whittaker RG, Taylor RW, Chinnery PF, Turnbull DM. 2008. Prevalence of mitochondrial DNA disease in adults. Ann Neurol, 63:35-39.). In the early cell division cycle, the embryo has a greater amount of mitochondrias in storage, which is diluted as the divisions progress. This is the reason for blastocysts have few copies per cell, considered the mechanism for high quality transmission by the bottle neck theory (Lee et al., 2012Lee HS, Ma H, Juanes RC, Tachibana M, Sparman M, Woodward J, Ramsey C, Xu J, Kang EJ, Amato P, Mair G, Steinborn R, Mitalipov S. 2012. Rapid mitochondrial DNA segregation in primate preimplantation embryos precedes somatic and germline bottleneck. Cell Rep, 1:506-515.). Therefore, just only at the implantation period the embryo is capable of replicate mitochondrial DNA (mtDNA) (Thouas et al., 2005Thouas GA, Trounson AO, Jones GM. 2005. Effect of female age on mouse oocyte developmental competence following mitochondrial injury. Biol Reprod, 73:366-373.; St John et al., 2010St John JC, Facucho-Oliveira J, Jiang Y, Kelly R, Salah R. 2010. Mitochondrial DNA transmission, replication and inheritance: a journey from the gamete through the embryo and into offspring and embryonic stem cells. Hum Reprod Update, 16:488-509.).
The initial production of energy in the early stages of embryonic development occurs through aerobic and anaerobic respiration (Thouas et al., 2005Thouas GA, Trounson AO, Jones GM. 2005. Effect of female age on mouse oocyte developmental competence following mitochondrial injury. Biol Reprod, 73:366-373.; El Shourbagy et al., 2006El Shourbagy SH, Spikings EC, Freitas M, St John JC. 2006. Mitochondria directly influence fertilisation outcome in the pig. Reproduction, 131:233-245.; Spikings et al., 2007Spikings EC, Alderson J, St John JC. 2007. Regulated mitochondrial DNA replication during oocyte maturation is essential for successful porcine embryonic development. Biol Reprod, 76:327-335.), and is critical in several species. Human (May-Panloup et al., 2005May-Panloup P, Chretien MF, Jacques C, Vasseur C, Malthiery Y, Reynier P. 2005. Low oocyte mitochondrial DNA content in ovarian insufficiency. Hum Reprod, 20:593-597.), murine (Liu et al., 2000Liu L, Trimarchi JR, Keefe DL. 2000. Involvement of mitochondria in oxidative stress-induced cell death in mouse zygotes. Biol Reprod, 62:1745-1753.; Thouas et al., 2004Thouas GA, Trounson AO, Wolvetang EJ, Jones GM. 2004. Mitochondrial dysfunction in mouse oocytes results in preimplantation embryo arrest in vitro. Biol Reprod, 71:1936-1942.), bovine (Chiaratti et al., 2011Chiaratti MR, Ferreira CR, Perecin F, Meo SC,Sangalli JR, Mesquita LG, de Carvalho Balieiro JC, Smith LC, Garcia JM, Meirelles FV. 2011. Ooplast-mediated developmental rescue of bovine oocytes exposed to ethidium bromide. Reprod Biomed Online, 22:172-183.), and porcine (Spikings et al., 2007Spikings EC, Alderson J, St John JC. 2007. Regulated mitochondrial DNA replication during oocyte maturation is essential for successful porcine embryonic development. Biol Reprod, 76:327-335.) studies have shown that problems in mitochondrial function lead to reduced cleavage rates and aneuploidy occurrence. In addition, low production of ATP and decrease of mtDNA copies are related with poor quality embryos (Wai et al., 2010Wai T, Ao A, Zhang X, Cyr D, Dufort D, Shoubridge EA. 2010. The role of mitochondrial DNA copy number in mammalian fertility. Biol Reprod, 83:52-62.; Wakefield et al., 2011Wakefield SL, Lane M, Mitchell M. 2011. Impaired mitochondrial function in the preimplantation embryo perturbs fetal and placental development in the mouse. Biol Reprod, 84:572-580.). Another important change is the remodelling of mitochondrial features, turning into a complex structure that includes development of cristae, denser matrix and elongated form. These transitions are crucial to change from glycolytic to aerobic metabolism (Schatten et al., 2014Schatten H, Sun QY, Prather R. 2014. The impact of mitochondrial function/dysfunction on IVF and new treatment possibilities for infertility. Reprod Biol Endocrinol, 12:111.).
Response to exogenous stress is a crucial part of cellular physiology. The main mechanism to start the cellular stress response pathway is located in the endoplasmic reticulum (ER). This organelle is responsible for secreting various proteins involved in several biological processes and its quality control is responsible for detecting failures to maintain the functioning of the cells which include processes of cell division, homeostasis, and differentiation (Latham, 2015Latham KE. 2015. Endoplasmic reticulum stress signaling in mammalian oocytes and embryos: Life in the balance. Int Rev Cell Mol Biol, 316:227-265.). Disturbance in the endoplasmic reticulum stress signalling, especially in the GRP78 / BiP protein, leads to problems in the pre-implantation period, failure in blastocyst hatching and defects in cell division and apoptosis of the inner cell mass (Luo et al., 2006Luo S, Mao C, Lee B, Lee AS. 2006. GRP78/BiP is required for cell proliferation and protecting the inner cell mass from apoptosis during early mouse embryonic development. Mol Cell Biol, 26:5688-5697.).
Another cellular component is the structure of the cytoskeleton, essential in diverse cellular functions and embryonic development. The cytoskeleton is composed of microfilaments, intermediate filaments and microtubules. Damage to the cytoskeleton adversely affects cell viability and can cause disruption in development and survival, given the support for intracellular content to be organized (Mao et al., 2014Mao L, Lou H, Lou Y, Wang N, Jin F. 2014. Behaviour of cytoplasmic organelles and cytoskeleton during oocyte maturation. Reprod Biomed Online, 28:284-299.). In Damiman et al (2013) study, the comparison between slow-freezing and non-cryopreserved embryos showed a decrease of tubulin, actin and nucleus structures in each stage compared in mouse, indicating that may the vitrification technique would cause less damage on cytoskeleton (Dasiman et al., 2013Dasiman R, Rahman NSA, Othman S, Mustafa MF, Mohd Yusoff NJ, Jusof WHW, Rajikin MH, Froemming GRA, Khan N. 2013. Cytoskeletal alterations in different developmental stages of in vivo cryopreserved preimplantation murine embryos. Med Sci Monit Basic Res, 19:258-266.). The IVPE can also modify the cytoskeleton leading, in some cases, to aberrant actin organization that is responsible for decreased development in IVP embryos (Mao et al., 2014Mao L, Lou H, Lou Y, Wang N, Jin F. 2014. Behaviour of cytoplasmic organelles and cytoskeleton during oocyte maturation. Reprod Biomed Online, 28:284-299.). It was described in the literature that the supplementation of melatonin, a cytoskeletal modulator, reverse the damage in actin organization related genes, such as Rho/Rac guanine nucleotide exchange factor 2 (Arhgef2), BCL2 apoptosis regulator (Bcl2), coronin 2B (Coro2b), filamin C (Flnc), and palladin cytoskeletal associated protein (Palld), providing a target to optimize existing in vitro production systems (Tan et al., 2015Tan K, An L, Wang SM, Wang XD, Zhang ZN, Miao K, Sui LL, He SZ, Nie JZ, Wu ZH, Tian JH. 2015. Actin Disorganization Plays a Vital Role in Impaired Embryonic Development of In Vitro-Produced Mouse Preimplantation Embryos. PLoS One, 10:e0130382.).
Membrane damage and DNA fragmentation are the most commonly injury caused by cryopreservation (Sudano et al., 2012Sudano MJ, Santos VG, Tata A, Ferreira CR, Paschoal DM, Machado R, Buratini J, Eberlin MN, Landim-Alvarenga FDC. 2012. Phosphatidylcholine and Sphingomyelin Profiles Vary in Bos taurus indicus and Bos taurus taurus In Vitro- and In Vivo-Produced Blastocysts. Biol Reprod, 87:1-11.). Both injuries are associated with the reduction in the total cell number after cryopreservation and also the disturbance in the proportion of inner cell mass (ICM) / trophectoderm (TE) cells ratio (Sudano et al., 2012Sudano MJ, Santos VG, Tata A, Ferreira CR, Paschoal DM, Machado R, Buratini J, Eberlin MN, Landim-Alvarenga FDC. 2012. Phosphatidylcholine and Sphingomyelin Profiles Vary in Bos taurus indicus and Bos taurus taurus In Vitro- and In Vivo-Produced Blastocysts. Biol Reprod, 87:1-11.; Gomez, 2009Gomez E, Munoz M, Rodriguez A, Caamano JN, Facal N, Diez C. 2009. Vitrification of bovine blastocysts produced in vitro inflicts selective damage to the inner cell mass. Reprod Domest Anim, 44:194-199.). The proper ICM/TE ratio and cells number is crucial for embryo development and pregnancy establishment (Van Soom et al., 1996Van Soom A, Boerjan M, Ysebaert MT, De Kruif A. 1996. Cell allocation to the inner cell mass and the trophectoderm in bovine embryos cultured in two different media. Mol Reprod Dev, 45:171-182.; Leese et al., 1998Leese HJ, Donnay I, Thompson JG. 1998. Human assisted conception: a cautionary tale. Lessons from domestic animals. Hum Reprod, 13:184-202.). These cryoinjuries can severe reduce embryo survival and the ability for the pregnancy success.
Many ultrastructural damages are commonly related to embryo cryopreservation, including: plasma membrane disruption, abnormal mitochondrial cristae, matrix swelling of the endoplasmic reticulum, poorly developed desmosome, reduced number of microvilli, disintegrations of cell adhesion among TE cells, and increase incidence of cell death (Overstrom et al., 1993Overstrom EW, Duby RT, Dobrinsky JR, Robb JM, Baguisi A, Lonergan P. 1993. Cytoskeletal damage in vitrified or frozen bovine embryos. Theriogenology, 39:276.; Vajta et al., 1997; Fair et al., 2001Fair T, Lonergan P, Dinnyes A, Cottell DC, Hyttel P, Ward FA, Boland MP. 2001. Ultrastructure of bovine blastocysts following cryopreservation: effect of method of blastocyst production. Mol Reprod Dev, 58:186-195.).
Nevertheless, many of this cryoinjury can be avoided by a proper cryopreservation methodology and rigorous application of technique assuring correct time of exposure and temperature of the cryopreservation steps. Additionally, cryopreserve exceptional quality embryos tend to reduce cryoinjuries, and clear signs of regeneration and reorganization of embryonic structures are expected after warming/thawing and re-culture, including re-establishment of tight-junctions between TE cells and the return of normal mitochondrial morphology (Vajta et al., 1997).
Embryo molecular competence
Beyond morphological analyses, other techniques that reflect the functional and physiological state of the embryo have been proposed, such as the molecular analysis. Basically we can evaluate the embryos based into three groups of different stages of cellular functioning: (1) production of transcripts and proteins from specific genes of cellular products, (2) final products of cellular processes (metabolites) and (3)gene expression regulatory transcripts, the so-called small non-coding RNAs (ncRNAs), such as: interference RNA (siRNA), micro RNAs (miRNA) and antisense RNA (Phillips, 2008Phillips T. 2008. Non-coding RNA and Gene Expression. Nature Education, 1:115.; Rodgaard et al., 2015Rodgaard T, Heegaard PM, Callesen H. 2015. Non-invasive assessment of in-vitro embryo quality to improve transfer success. Reprod Biomed Online, 31:585-592.). The present review focused on mRNA transcripts evaluation and discussed briefly other molecular aspects.
Morphological embryonic development events as first cleavages, compaction and blastulation are accompanied by a loss of pluripotency and formation of lineages of trophectoderm and inner cell mass to further development of the three primary germ layers: endoderm, mesoderm and ectoderm (Stephenson et al., 2012Stephenson RO, Rossant J, Tam PP. 2012. Intercellular Interactions, Position, and Polarity in Establishing Blastocyst Cell Lineages and Embryonic Axes. Cold Spring Harb Perspect Biol, 4:a008235.; Schrode et al., 2013Schrode N, Xenopoulos P, Piliszek A, Frankenberg S, Plusa B, Hadjantonakis AK. 2013. Anatomy of a blastocyst: cell behaviors driving cell fate choice and morphogenesis in the early mouse embryo. Genesis, 51:219-233.). During this period, not only embryo morphology undergoes modifications, changes in the transcripts levels for genes associated with early embryo development dynamic occur. Transcription factors required for maintenance of pluripotency, such as POU class 5 homeobox 1 (POU5F1/Oct4), SRY-box transcription factor 2 (SOX2) and Nanog homeobox (NANOG), expressed strictly in ICM cells, mediated by the action of the caudal type homeobox 2 (CDX2) gene product expressed on trophectoderm cells (Chambers et al., 2003Chambers I, Colby D, Robertson M, Nichols J, Lee S, Tweedie S, Smith A. 2003. Functional expression cloning of Nanog, a pluripotency sustaining factor in embryonic stem cells. Cell, 113:643-655.; Ralston and Rossant, 2008Ralston A, Rossant J. 2008. Cdx2 acts downstream of cell polarization to cell-autonomously promote trophectoderm fate in the early mouse embryo. Dev Biol, 313:614-629.) have been widely described.
During the embryo pre-implantation period, there is a massive degradation of the maternal RNA/proteins stored inside the oocyte and the gradual activation of the embryonic genome. Studies that inhibit RNA polymerase II have demonstrated that the time of the embryonic genome activation (EGA) is related to the rate of embryonic development. In bovine, EGA occurs between 8-16 cells and is associated with early differentiation, embryo implantation success, and fetal development. However, the regulation of the gene expression of bovine embryos remains an unresolved biological issue (Misirlioglu et al., 2006Misirlioglu M, Page GP, Sagirkaya H, Kaya A, Parrish JJ, First NL, Memili E. 2006. Dynamics of global transcriptome in bovine matured oocytes and preimplantation embryos. Proc Natl Acad Sci U S A, 50:18905-18910.; Graf et al., 2014Graf A, Krebs S, Zakhartchenko V, Schwalb B, Blum H, Wolf E. 2014. Fine mapping of genome activation in bovine embryos by RNA sequencing. Proc Natl Acad Sci U S A, 111:4139-4144.).
A correlation between EGA with increased abundances of mature forms of miR30a and miR-21, and the primary form of miR-130a from 1-cell to 8-cell zygotes have been described (Mondou et al., 2012Mondou E, Dufort I, Gohin M, Fournier E, Sirard MA. 2012. Analysis of microRNAs and their precursors in bovine early embryonic development. Mol Hum Reprod, 18:425-434.). Tripurani et al (2013)Tripurani SK, Wee G, Lee KB, Smith GW, Wang L Jianboyao. 2013. MicroRNA-212 post-transcriptionally regulates oocyte-specific basic-helix-loop-helix transcription factor, factor in the germline alpha (FIGLA), during bovine early embryogenesis. PLoS One, 8:e76114. pointed to another miRNA with increased expression in 2- to 8-cell embryos, miR-212, possibly a suppressor of the maternal factor in the germ line at the transition of transcripts and maternal proteins to those of the embryo, called the maternal-embryonic transition. Although specific mechanisms of EGA are poorly defined, some factors involved such as maternal cyclin A2 (CCNA2), retinoblastoma protein (RB1), catalytic subunit of the SWI/SNF-related chromatin remodelling complex (BRG1), and the SRY-box transcription factor 2 (SOX2) have recently been suggested in an EGA model in mice (Tripurani et al., 2013Tripurani SK, Wee G, Lee KB, Smith GW, Wang L Jianboyao. 2013. MicroRNA-212 post-transcriptionally regulates oocyte-specific basic-helix-loop-helix transcription factor, factor in the germline alpha (FIGLA), during bovine early embryogenesis. PLoS One, 8:e76114.). Embryos that do not properly undergo genome activation fail in the further development.
It has already been described that biopsies derived from IVP blastocysts that resulted in calf delivery were enriched with transcripts necessary for implantation (cytochrome c oxidase subunit II, COX2 and caudal type homeobox 2, CDX2), carbohydrate metabolism (arachidonate 15-lipoxygenase, ALOX15), growth factor (bone morphogenetic protein 15, BMP15), signal transduction by plasminogen activator urokinase (plasminogen activator urokinase, PLAU) and placenta (placenta–specific 8, PLAC8). Transcripts involved in protein phosphorylation (keratin 8, KRT8), plasma membrane (occludin, OCLN) and glucose metabolism (phosphoglycerate kinase 1, PGK1 and aldo-keto reductase family 1 member B1, AKR1B1) were enriched in reabsorbed embryos. Embryos that did not resulted in pregnancy presented enriched transcripts involved with inflammatory cytokines (tumor necrosis factor, TNF), amino acid binding protein (eukaryotic translation elongation factor 1 alpha 1, EEF1A1), transcription factors (msh bomeobox 1, MSX1, and PTTG1 regulator of sister chromatid separation securing, PTTG1), glucose metabolism (phosphoglycerate kinase 1, PGK1 and aldo-keto reductase family 1 member B1, AKR1B1), and implantation inhibitor (CD9 molecule, CD9) (El-Sayed et al., 2006El-Sayed A, Hoelker M, Rings F, Salilew D, Jennen D, Tholen E, Sirard MA, Schellander K, Tesfaye D. 2006. Large-scale transcriptional analysis of bovine embryo biopsies in relation to pregnancy success after transfer to recipients. Physiol Genomics, 28:84-96.).
Despite great improvement of the information availability of embryo competence, this knowledge was not enough to avoid pregnancy loss observed in all mammalian species, in which cause serious issues such as reproductive wastage in farm animals. It is generally expected pregnancy loss in cattle in 40% of the cases between day 8 and 18 (Diskin and Sreenan, 1980Diskin MG, Sreenan JM. 1980. Fertilization and embryonic mortality rates in beef heifers after artificial insemination. J Reprod Fertil, 59:463-468.). This embryo mortality is caused by a series of events that includes intrinsic embryo’s defects, unsatisfactory maternal environment and failure to synchronization between the cow and embryo.
Ghanem et al. (2011)Ghanem N, Salilew-Wondim D, Gad A, Tesfaye D, Phatsara C, Tholen E, Looft C, Schellander K, Hoelker M. 2011. Bovine blastocysts with developmental competence to term share similar expression of developmentally important genes although derived from different culture environments. Reproduction, 142:551-564. identified 41 and 43 differently expressed genes between IVD blastocysts which resulted in no pregnancy vs. calf delivery and pregnancy loss vs. calf delivery, respectively. In general, genes related to placental development and maternal-embryo interaction (placenta–specific 8, PLAC8) were upregulated in embryos that had pregnancy to term. On the other hand, embryo’s biopsies that did not end in successful pregnancy presented enriched transcripts related to mitochondrial transcripts (Bos taurus isolate FL405 mitochondrion, Fl405) and stress genes (heat shock protein family D (Hsp60) member 1, HSPD1). However, both biopsies presented similar gene expression related to preimplantation development of embryo.
Another study also evaluating the molecular signatures of IVD embryo biopsies which resulted in no pregnancy and calf delivery identified 70 differently expressed genes: 32 transcripts levels were upregulated in the biopsies from calf delivery-derived embryos, such as sperm associated antigen 17 (SPAG17/PF6), ubiquitin conjugating enzyme E2 D3 (UBE2D3P), deafness autosomal recessive 31 (DFNB31), S-adenosylmethionine decarboxylase 1 (AMD1), dystrobrevin binding protein 1 (DTNBP1), and adp-ribosylation factor-like 8B (ARL8B); whereas 38 transcripts levels including RING1 and YY1 binding protein (RYBP), ring finger protein 34 (RNF34), karyopherin alpha 4 (KPNA4), and WD repeat domain 13 (WDR13) were increased in the biopsies of the no pregnancy-derived embryos indicating that the embryos are molecularly distinguishable (Salilew-Wondim et al., 2010Salilew-Wondim D, Holker M, Rings F, Ghanem N, Ulas-Cinar M, Peippo J, Tholen E, Looft C, Schellander K, Tesfaye D. 2010. Bovine pretransfer endometrium and embryo transcriptome fingerprints as predictors of pregnancy success after transfer. Physiological Genomics, 42:201-218.). The biopsy transcriptional profiles from cryopreserved blastocysts that resulted in calf delivery, no pregnancy, and pregnancy loss are still lacking.
Our group have recently evaluated the transcriptional profiles of IVP bovine embryos with high and low post-cryopreservation survival. Blastocysts with high cryosurvival were enriched in 27 genes associated with the following top five biological processes: a) predicted to be activated: organismal survival, cell death and survival, cellular growth and proliferation; and b) predicted to be inhibited: cellular movement and cell-to-cell signalling (data not published).
A favourable transcriptional profile for pregnancy establishment and maintenance, therefore, could be used as a marker of embryo competence. In addition, each gene and/or genes involved pathway should be studied in order to design strategies applied to the in vitro embryo production system to improve embryo quality, cryosurvival and embryo-derived pregnancy.
Determinant effects of embryo competence and cryosurvival
Early embryo development period is complex, conserved, and well-orchestrated process involving dynamic molecular and structures changes. Embryos must undergo important events, such as fertilization, cleavage, epigenetic reprogramming, compaction, differentiation, and blastulation, for proper development and pregnancy establishment (Sudano et al., 2016aSudano MJ, Rascado TD, Tata A, Belaz KR, Santos VG, Valente RS, Mesquita FS, Ferreira CR, Araujo JP, Eberlin MN, Landim-Alvarenga FD. 2016a. Lipidome signatures in early bovine embryo development. Theriogenology, 86:472-484.; Jiang et al., 2014Jiang Z, Sun J, Dong H, Luo O, Zheng X, Obergfell C, Tang Y, Bi J, O'Neill R, Ruan Y, Chen J, Tian XC. 2014. Transcriptional profiles of bovine in vivo pre-implantation development. BMC Genomics, 15:1-15.).
Several factors can disrupt competence during this period and result in variations of the embryo phenotypes, including genotype and environmental effects. Because of this reason, a rigorous quality control should be used to perform all the steps involved in the IVPE in order to mimic as much as possible the in vivo environment conditions and reduce possible genotype effect. A putative model addressing cellular and molecular events required for acquisition of embryonic developmental competence and cryosurvival is presented at Figure 2.
Cellular and molecular events required for embryonic developmental competence acquisition and its impact on cryosurvival. Interconnected steps (blue dashed arrows, from the left to the right) to in vitro produce an embryo of superior quality and improved embryo cryosurvival success. Overall environmental and genetic effects on embryo competence acquisition (Black Box). Determinant variables associated with the in vitro production of superior embryo quality (Gold Box, in detail fresh IVP blastocysts with great quality). Successful resumption of development after cryopreservation and cryopreservation technique effects (Green Box, in detail re-expanded IVP blastocysts after warming). All Box events (Black, Gold and Green) impact embryo cryosurvival.
Genotype effect
It is well documented in the literature the great variation in the developmental competence of IVP bovine embryos according to the sire (Brackett and Zuelke, 1993Brackett BG, Zuelke KA. 1993. Analysis of factors involved in the in vitro production of bovine embryos. Theriogenology, 39:43-64.; Galli and Lazzari, 1996Galli C, Lazzari G. 1996. Practical aspects of IVM/IVF in cattle. Anim Reprod Sci, 42:371-379.). Variables like cleavage and blastocyst production rates of a specific bull and/or semen batch (with unknow IVF results) are generally previously evaluated in vitro before the vastly use of this semen in the IVPE routine. Nevertheless, there are considerable variations of pregnancy rates observed after the embryo transfer according to the sire used for both fresh and cryopreserved embryos.
Our group recently evaluated the sire effect in the pregnancy rates following the transfer of fresh (N = 40,200) or cryopreserved (N = 9,858) IVP embryos. Pregnancy rates varying among 28.3 to 52.5% (for fresh) and 7.7 to 61.6% (for cryopreserved) were recorded after transfer IVP embryos derived from different bulls. We also have observed a variation according the cow, breeding, subspecies, and breed on pregnancy rates (Sudano et al., 2019Sudano MJ, Marinho LSR, Silveira JC, Basso AC, Bohrer R, Lamberti GSE, Watanabe YF, Seneda MM, Meirelles FV. Evolução aplicada da produção in vitro de embriões bovinos. In Gonçalves PBD, Figueiredo JR, Gasperin BG. (Ed.) Biotécnicas aplicadas à reprodução animal, 2019, 3 ed. Grupo Gen, in press.). However, despite great amount of the variation was attributed to the genotype effect in this evaluation, it is also important to considerate the environmental effect in the determination of the reason of variation.
Variations in the membrane lipid profiles of phosphatidylcholine and sphingomyelin between Bos taurus indicus (Nellore) and Bos taurus taurus (Simmental) embryos and its impact on the embryo’s cryosurvival have already been reported (Sudano et al., 2012Sudano MJ, Santos VG, Tata A, Ferreira CR, Paschoal DM, Machado R, Buratini J, Eberlin MN, Landim-Alvarenga FDC. 2012. Phosphatidylcholine and Sphingomyelin Profiles Vary in Bos taurus indicus and Bos taurus taurus In Vitro- and In Vivo-Produced Blastocysts. Biol Reprod, 87:1-11.; 2013aSudano MJ, Caixeta ES, Paschoal DM, Martins A, Machado R, Buratini J, Landim-Alvarenga FDC.2013a. Cryotolerance and global gene-expression patterns of Bos taurus indicus and Bos taurus taurus in vitro- and in vivo-produced blastocysts. Reprod Fertil Dev, 26:1129-1141.). After vitrification the evaluation of the percentage of structures hatching revealed results superior to B. taurus taurus (34.6%) compared to B. taurus indicus (20.2%) embryos (Sudano et al., 2013aSudano MJ, Caixeta ES, Paschoal DM, Martins A, Machado R, Buratini J, Landim-Alvarenga FDC.2013a. Cryotolerance and global gene-expression patterns of Bos taurus indicus and Bos taurus taurus in vitro- and in vivo-produced blastocysts. Reprod Fertil Dev, 26:1129-1141.). Arreseigor et al. (1998)Arreseigor CJ, Sisul A, Arreseigor AE, Stahringe RC. 1998. Effect of cryoprotectant, thawing method, embryo grade and breed on pregnancy rates of cryopreserved bovine embryos. Theriogenology, 49:160. also showed this difference between subspecies in the pregnancy rate. It seems that factors including the phospholipid cell membrane composition are associated with the determination of the physicochemical properties such as fluidity, permeability and thermal phase behavior, which are determinants for cryotolerance (Van Meer et al., 2008Van Meer G, Voelker DR, Feigenson GW. 2008. Membrane lipids: Where they are and how they behave. Nat Rev Mol Cell Biol, 9:112-124.).
Oocyte quality and the follicular environment effects
The production of competent oocytes is dependent on complete nuclear and cytoplasmic maturation. The oocyte during its development undergoes rearrangements that make it capable of supporting fertilization and early embryonic development. During the nuclear maturation process, oocyte chromosomes go through diplotene of prophase I to metaphase II of meiosis. Among the main changes in cytoplasmic maturation are carbohydrate and lipid metabolism, mitochondrial function and location, reduction of oxygen radicals, epigenetic reprogramming, bidirectional communication between the cumulus-oocyte complexes (COC) and its secretion of growth factors (Brevini Gandolfi and Gandolfi, 2001Brevini Gandolfi TAL, Gandolfi F. 2001. The maternal legacy to the embryo: Cytoplasmic components and their effects on early development. Theriogenology, 55:1255-1276.). All this events are crucial for a proper oocyte competence acquisition.
In the commercial IVPE programs, the ultrasound-guided follicular aspiration (OPU) is routinely used for oocyte recovery, this biotechnology allows access a large number of female gametes inmono-ovulatory species favoring the multiplication of animals with exponentially genetic merit (Nagai et al., 2015Nagai K, Yanagawa Y, Katagiri S, Nagano M. 2015. Fertilizability of oocytes derived from Holstein cows having different antral follicle counts in ovaries. Anim Reprod Sci, 163:172-178.; Nagano, 2019Nagano M. 2019. Acquisition of developmental competence and in vitro growth culture of bovine oocytes. J Reprod Dev, in press.). Investigations on the influence of the follicle microenvironment and size in the establishment of competent embryos have been conducted (Annes et al., 2018Annes K, Müller DB, Vilela JAP, Valente RS, Caetano DP, Cibin FWS, Milazzotto MP, Mesquita FS, Belaz KRA, Eberlin MN, Sudano MJ. 2018. Influence of follicle size on bovine oocyte lipid composition, follicular metabolic and stress markers, embryo development and blastocyst lipid content. Reprod Fertil Dev, 31:462-472.; Labrecque et al., 2016Labrecque R, Fournier E, Sirard MA. 2016. Transcriptome analysis of bovine oocytes from distinct follicle sizes: Insights from correlation network analysis. Mol Reprod Dev, 83:558-569.; Lonergan et al., 2016Lonergan P, Fair T, Forde N, Rizos D. 2016. Embryo development in dairy cattle. Theriogenology, 86:270-277.).
There is considerable effect of follicle conditions in the oocyte and embryo competence. Oocyte origin is the main factor affecting blastocyst yield (Rizos et al., 2002Rizos D, Ward F, Duffy P, Boland MP, Lonergan P. 2002. Consequences of bovine oocyte maturation, fertilization or early embryo development in vitro versus in vivo: Implications for blastocyst yield and blastocyst quality. Mol Reprod Dev, 61:234-248.). Any type of stress conditions that oocytes face can potentially disrupts embryo development. Differences in the morphology (Nagai et al., 2015Nagai K, Yanagawa Y, Katagiri S, Nagano M. 2015. Fertilizability of oocytes derived from Holstein cows having different antral follicle counts in ovaries. Anim Reprod Sci, 163:172-178.; Nagano, 2019Nagano M. 2019. Acquisition of developmental competence and in vitro growth culture of bovine oocytes. J Reprod Dev, in press.), lipid composition, transcriptome, and embryo development (Labrecque et al., 2016Labrecque R, Fournier E, Sirard MA. 2016. Transcriptome analysis of bovine oocytes from distinct follicle sizes: Insights from correlation network analysis. Mol Reprod Dev, 83:558-569.; Annes et al., 2018Annes K, Müller DB, Vilela JAP, Valente RS, Caetano DP, Cibin FWS, Milazzotto MP, Mesquita FS, Belaz KRA, Eberlin MN, Sudano MJ. 2018. Influence of follicle size on bovine oocyte lipid composition, follicular metabolic and stress markers, embryo development and blastocyst lipid content. Reprod Fertil Dev, 31:462-472.) had already been described in the oocytes recovery from different follicle sizes. The bovine oocytes used for IVPE are recovered from follicles with 2 to 8 mm of diameter, before follicle divergence. Generally, oocytes recovered from large follicles (> 6mm) present a greater potential of reaching blastocysts compared to oocytes recovered from follicles of 2 to 6 mm (Rizos et al., 2002Rizos D, Ward F, Duffy P, Boland MP, Lonergan P. 2002. Consequences of bovine oocyte maturation, fertilization or early embryo development in vitro versus in vivo: Implications for blastocyst yield and blastocyst quality. Mol Reprod Dev, 61:234-248.; Fair, 2003Fair T. 2003. Follicular oocyte growth and acquisition of developmental competence. Anim Reprod Sci, 78:203-216.; Labrecque et al., 2016Labrecque R, Fournier E, Sirard MA. 2016. Transcriptome analysis of bovine oocytes from distinct follicle sizes: Insights from correlation network analysis. Mol Reprod Dev, 83:558-569.; Annes et al, 2018Annes K, Müller DB, Vilela JAP, Valente RS, Caetano DP, Cibin FWS, Milazzotto MP, Mesquita FS, Belaz KRA, Eberlin MN, Sudano MJ. 2018. Influence of follicle size on bovine oocyte lipid composition, follicular metabolic and stress markers, embryo development and blastocyst lipid content. Reprod Fertil Dev, 31:462-472.).
Despite embryo culture conditions is crucial for embryo quality and cryosurvival determination (Rizos et al., 2002Rizos D, Ward F, Duffy P, Boland MP, Lonergan P. 2002. Consequences of bovine oocyte maturation, fertilization or early embryo development in vitro versus in vivo: Implications for blastocyst yield and blastocyst quality. Mol Reprod Dev, 61:234-248.), blastocysts that originate from oocytes matured in vitro result in lower rates of gestation compared to their in vivo counterparts (Peterson and Lee, 2003Peterson AJ, Lee RS. 2003. Improving successful pregnancies after embryo transfer. Theriogenology, 59:687-97.). Additionally, we recently identified a relationship between the cytoplasmic lipid content of oocytes and the lipid deposit of expanded blastocysts (Annes et al., 2018Annes K, Müller DB, Vilela JAP, Valente RS, Caetano DP, Cibin FWS, Milazzotto MP, Mesquita FS, Belaz KRA, Eberlin MN, Sudano MJ. 2018. Influence of follicle size on bovine oocyte lipid composition, follicular metabolic and stress markers, embryo development and blastocyst lipid content. Reprod Fertil Dev, 31:462-472.), i.e., oocytes derived from large follicles and containing greater amount of lipid droplets, originated day 7 expanded blastocysts, after IVPE, with increased lipid deposit. An experiment evaluating the cryosurvival of these blastocysts is still lacking, however, it is fair to speculate that this increased lipid deposit negatively impact embryo cryosurvival (Abe et al., 2002Abe H, Yamashita S, Satoh T, Hoshi H. 2002. Accumulation of cytoplasmic lipid droplets in bovine embryos and cryotolerance of embryos developed in different culture systems using serum-free or serum-containing media. Mol Reprod Dev, 61:57-66.).
This results collaborate in the selection of follicles/oocytes of greater potential, since key events for embryonic development are dependent of oocyte status (Fair, 2010Fair T. 2010. Mammalian oocyte development: checkpoints for competence. Reprod Fertil Dev, 22:13-20.). A properly embryo developmental competence, therefore, could be increased in an oocyte focused manner.
In vitro production conditions effects
It is commonly accepted that IVP embryos have a reduced competence compared with the in vivo counterparts. In vitro production of embryos is a three-step procedure involving oocyte maturation, fertilization, and in vitro culture of embryos. The in vitro environment directly influences the embryonic phenotypes and results. It is very important, therefore, to mimic the conditions found in vivo in order to allow all events inherent to the early embryonic development occur (for review, see Sudano et al., 2012Sudano MJ, Santos VG, Tata A, Ferreira CR, Paschoal DM, Machado R, Buratini J, Eberlin MN, Landim-Alvarenga FDC. 2012. Phosphatidylcholine and Sphingomyelin Profiles Vary in Bos taurus indicus and Bos taurus taurus In Vitro- and In Vivo-Produced Blastocysts. Biol Reprod, 87:1-11.; 2013aSudano MJ, Caixeta ES, Paschoal DM, Martins A, Machado R, Buratini J, Landim-Alvarenga FDC.2013a. Cryotolerance and global gene-expression patterns of Bos taurus indicus and Bos taurus taurus in vitro- and in vivo-produced blastocysts. Reprod Fertil Dev, 26:1129-1141.; 2013bSudano MJ, Paschoal DM, Maziero RRD, Rascado TS, Guastali MD, Crocomo LF, Magalhães LCO, Monteiro BA, Martins Jr A, Machado R, Landim-Alvarenga FDC. 2013b. Improving postcryopreservation curvival capacity: an embryo-focused approach. Anim Reprod, 10:160-167).
Since the first notice of a calf delivery from a completely IVP embryo (in vitro maturation, fertilization and culture; Lu et al., 1987Lu KH, Gordon I, Gallagher M, Mcgovern H. 1987. Pregnancy established in cattle by transfer of embryos derived from invitro fertilization of oocytes matured in vitro. Vet Rec, 121:259-260.) the in vitro production systems still have challenging outcomes. Despite 80 to 90% of oocytes submitted to in vitro maturation have the germinal vesicle breaks down from prophase I to metaphase II, and 80% cleave after fertilization, only 20 to 40% of the oocytes develop to the blastocyst stage, and 50% of transferred IVP blastocysts establish pregnancy, i.e., just only 10 to 20% of the recovered oocytes submitted to in vitro production will result in pregnancy (Lonergan et al., 2016Lonergan P, Fair T, Forde N, Rizos D. 2016. Embryo development in dairy cattle. Theriogenology, 86:270-277., 2006Lonergan P, Fair T, Corcoran D, Evans ACO. 2006. Effect of culture environment on gene expression and developmental characteristics in IVF-derived embryos. Theriogenology, 65:137-152.; Rizos et al., 2008Rizos D, Clemente M, Bermejo-Alvarez P, De La Fuente J, Lonergan P, Gutiérrez-Adán A. 2008. Consequences of in vitro culture conditions on embryo development and quality. Reprod Domest Anim, 43:44-50.; Wrenzycki and Stinshoff, 2013Wrenzycki C, Stinshoff H. 2013. Maturation environment and impact on subsequent developmental competence of bovine oocytes. Reprod Domest Anim, 48:38-43.; Sudano et al., 2019Sudano MJ, Marinho LSR, Silveira JC, Basso AC, Bohrer R, Lamberti GSE, Watanabe YF, Seneda MM, Meirelles FV. Evolução aplicada da produção in vitro de embriões bovinos. In Gonçalves PBD, Figueiredo JR, Gasperin BG. (Ed.) Biotécnicas aplicadas à reprodução animal, 2019, 3 ed. Grupo Gen, in press.).
In vivo, oocyte maturation occurs during follicle development, a period that oocytes produce and storage mRNAs and protein molecules necessary to supply the first embryonic activities (Brevini Gandolfi and Gandolfi, 2001Brevini Gandolfi TAL, Gandolfi F. 2001. The maternal legacy to the embryo: Cytoplasmic components and their effects on early development. Theriogenology, 55:1255-1276.). In vitro, the maturation medium and in vitro process are responsible to provide conditions to the oocytes undergo nuclear (reach metaphase II of meiosis), cytoplasmic (re-distribution of organelles such as the mitochondria and the cortical granules) and molecular (accumulation of specific molecules, largely unidentified, which prepare the oocyte for post-fertilization events) maturation (Sirard et al., 2006Sirard MA, Richard F, Blondin P, Robert C. 2006. Contribution of the oocyte to embryo quality. Theriogenology, 65:126-136.). However, the in vitro maturation conditions are still not so much efficient. It was reported that blastocyst production from oocytes matured in vitro is lower than in vivo (39.2% vs. 58.2%, respectively; Rizos et al., 2002Rizos D, Ward F, Duffy P, Boland MP, Lonergan P. 2002. Consequences of bovine oocyte maturation, fertilization or early embryo development in vitro versus in vivo: Implications for blastocyst yield and blastocyst quality. Mol Reprod Dev, 61:234-248.). Even if different supplements like grown factors and hormones were supplemented during IVM, the blastocyst development rate was not higher compared with the serum-supplemented medium highlighting the importance of the initial status of the oocyte (Ward et al., 2002Ward F, Enright B, Rizos D, Boland M, Lonergan P. 2002. Optimization of in vitro bovine embryo production: effect of duration of maturation, length of gamete co-incubation, sperm concentration and sire. Theriogenology, 57:2105-2117.; Hoelker et al., 2014Hoelker M, Held E, Salilew-Wondim D, Schellander K, Tesfaye D. 2014. Molecular signatures of bovine embryo developmental competence. Reprod Fertil Dev, 26:22-36.).
In this context, there are some investigative approach studies describing a greater gene expression pattern correspondent to cytoplasmic maturation involved genes in oocytes with higher blastocyst production (Räty et al., 2011Räty M, Ketoja E, Pitkänen T, Ahola V, Kananen K, Peippo J. 2011. In vitro maturation supplements affect developmental competence of bovine cumulus-oocyte complexes and embryo quality after vitrification. Cryobiology, 63:245-255.) and also a greater expression for apoptosis activating related genes to non-competent structures (Warzych et al., 2007Warzych E, Wrenzycki C, Peippo J, Lechniak D. 2007. Maturation medium supplements affect transcript level of apoptosis and cell survival related genes in bovine blastocysts produced in vitro. Mol Reprod Dev, 74:280-289.). This kind of works and a better understanding of in vivo oocyte maturation could improve the development of the maturation medium that produces viable embryos (Wrenzycki and Stinshoff, 2013Wrenzycki C, Stinshoff H. 2013. Maturation environment and impact on subsequent developmental competence of bovine oocytes. Reprod Domest Anim, 48:38-43.).
In the literature, there is a consensus that improvements in oocyte quality is crucial for the proportion of oocytes developing to blastocysts stage, whereas the post-fertilization environment period is the major aspect determining the blastocyst quality and competence, including post-cryopreservation survival (Rizos et al., 2002Rizos D, Ward F, Duffy P, Boland MP, Lonergan P. 2002. Consequences of bovine oocyte maturation, fertilization or early embryo development in vitro versus in vivo: Implications for blastocyst yield and blastocyst quality. Mol Reprod Dev, 61:234-248.; Lonergan et al., 2003Lonergan P, Rizos D, Gutierrez-Adan A, Fair T, Boland MP. 2003. Oocyte and embryo quality: Effect of origin, culture conditions and gene expression patterns. Reprod Domest Anim, 38:259-267.; Hoelker et al., 2014Hoelker M, Held E, Salilew-Wondim D, Schellander K, Tesfaye D. 2014. Molecular signatures of bovine embryo developmental competence. Reprod Fertil Dev, 26:22-36.).
In vivo, fertilization and early embryonic development take place at the oviduct due to the ability of this microenvironment to support embryogenesis, providing nutrients, growth factors, antioxidants, sexhormones, proteases, and other regulatory molecules of gametes and embryos. Furthermore, the cellular structure of this reproductive organ allows the transport of embryos to the uterus (Li and Winuthayanon, 2017Li S, Winuthayanon W. 2017. Oviduct: Roles in fertilization and early embryo development. J Endocrinol, 232:1-26.; Rizos et al., 2008Rizos D, Clemente M, Bermejo-Alvarez P, De La Fuente J, Lonergan P, Gutiérrez-Adán A. 2008. Consequences of in vitro culture conditions on embryo development and quality. Reprod Domest Anim, 43:44-50., 2002Rizos D, Ward F, Duffy P, Boland MP, Lonergan P. 2002. Consequences of bovine oocyte maturation, fertilization or early embryo development in vitro versus in vivo: Implications for blastocyst yield and blastocyst quality. Mol Reprod Dev, 61:234-248.). Mimic in vivo environment is very difficult and somehow we generally failed in this task. Unbalanced in vitro culture conditions itself impacts directly embryo competence, since it has a significant effect on the cellular metabolism (D’Souza et al., 2018D’Souza F, Uppangala S, Asampille G, Salian SR, Kalthur G, Talevi R, Atreya HS, Adiga SK. 2018. Spent embryo culture medium metabolites are related to the in vitro attachment ability of blastocysts. Sci Rep, 8:1-10.; Khurana and Niemann, 2000Khurana NK, Niemann H. 2000. Energy metabolism in preimplantation bovine embryos derived in vitro or in vivo. Biol Reprod, 62:847-856.; Rizos et al., 2002Rizos D, Ward F, Duffy P, Boland MP, Lonergan P. 2002. Consequences of bovine oocyte maturation, fertilization or early embryo development in vitro versus in vivo: Implications for blastocyst yield and blastocyst quality. Mol Reprod Dev, 61:234-248.) quality and quantity of lipids (Sudano et al., 2016aSudano MJ, Rascado TD, Tata A, Belaz KR, Santos VG, Valente RS, Mesquita FS, Ferreira CR, Araujo JP, Eberlin MN, Landim-Alvarenga FD. 2016a. Lipidome signatures in early bovine embryo development. Theriogenology, 86:472-484.), gene expression patterns (Lonergan et al., 2006Lonergan P, Fair T, Corcoran D, Evans ACO. 2006. Effect of culture environment on gene expression and developmental characteristics in IVF-derived embryos. Theriogenology, 65:137-152.), and on modifications in epigenetic markers, which can continue after birth (Ramos-Ibeas et al., 2019Ramos-Ibeas P, Heras S, Gómez-Redondo I, Planells B, Fernández-González R, Pericuesta E, Laguna-Barraza R, Pérez-Cerezales S, Gutiérrez-Adán A. 2019. Embryo responses to stress induced by assisted reproductive technologies. Mol Reprod Dev, 1-15.).
However, despite the great diversity of culture media and systems available and used for IVPE with research purpose and commercially, they generally are associated with a relative good developmental potential which sheds light to the embryo plasticity, i.e., the capacity to fetch survival and adapt to adverse conditions even in an environment that do not supply or exacerbate their physiological needs (Khurana and Niemann, 2000Khurana NK, Niemann H. 2000. Energy metabolism in preimplantation bovine embryos derived in vitro or in vivo. Biol Reprod, 62:847-856.; Lonergan et al., 2006Lonergan P, Fair T, Corcoran D, Evans ACO. 2006. Effect of culture environment on gene expression and developmental characteristics in IVF-derived embryos. Theriogenology, 65:137-152.). For example, the capacity of switching energy consumption source according nutrient availability. In mice, this plasticity was represented by the significant increase of the consumption of pyruvate, due to lack of glucose in the used medium (Gardner and Leese, 1988Gardner DK, Leese HJ. 1988. The role of glucose and pyruvate transport in regulating nutrient utilization by preimplantation mouse embryos. Development, 104:423-429.).
At molecular level, the great plasticity and tolerance to distinct culture conditions/systems including temperature, gas atmosphere, medium composition, embryo density per drop, and many other situations, are associated with an exacerbate gene expression pattern on IVP embryos compared with the in vivo counterparts (Corcoran et al., 2006Corcoran D, Fair T, Park S, Rizos D, Patel OV, Smith GW, Coussens PM, Ireland JJ, Boland MP, Evans AC, Lonergan P. 2006. Suppressed expression of genes involved in transcription and translation in in vitro- compared with in vivo-cultured bovine embryos. Reproduction, 131:651-660.; Côté et al., 2011Côté I, Vigneault C, Laflamme I, Laquerre J, Fournier É, Gilbert I, Scantland S, Gagné, D, Blondin P, Robert C. 2011. Comprehensive cross-production system assessment of the impact of in vitro microenvironment on the expression of messengers and long non-coding RNAs in the bovine blastocyst. Reproduction, 142:99-112.; Sudano et al., 2013aSudano MJ, Caixeta ES, Paschoal DM, Martins A, Machado R, Buratini J, Landim-Alvarenga FDC.2013a. Cryotolerance and global gene-expression patterns of Bos taurus indicus and Bos taurus taurus in vitro- and in vivo-produced blastocysts. Reprod Fertil Dev, 26:1129-1141.).
However, this embryo plasticity can cause some severe damage to its competence and offspring; e.g. the large offspring syndrome in cattle (McEvoy et al., 2000McEvoy TG, Sinclair KD, Young LE, Wilmut I, Robinson JJ. 2000. Large offspring syndrome and other consequences of ruminant embryo culture in vitro: Relevance to blastocyst culture in human ART. Hum Fertil, 3:238-246.; Rizos et al., 2008Rizos D, Clemente M, Bermejo-Alvarez P, De La Fuente J, Lonergan P, Gutiérrez-Adán A. 2008. Consequences of in vitro culture conditions on embryo development and quality. Reprod Domest Anim, 43:44-50.) and the overweighting newborns in humans (Li and Winuthayanon, 2017Li S, Winuthayanon W. 2017. Oviduct: Roles in fertilization and early embryo development. J Endocrinol, 232:1-26.). In bovines, this anomaly is associated with a protein source used in the culture media, the fetal calf serum (FCS), characterized by abnormal fetal and placental size, increased myogenesis, dystocia, abnormal neonatal lung activity, and increased post-neonatal mortality (McEvoy et al., 2000McEvoy TG, Sinclair KD, Young LE, Wilmut I, Robinson JJ. 2000. Large offspring syndrome and other consequences of ruminant embryo culture in vitro: Relevance to blastocyst culture in human ART. Hum Fertil, 3:238-246.; Walker et al., 1996Walker SK, Hartwich KM, Seamark RF. 1996. The production of unusually large offspring following embryo manipulation: Concepts and challenges. Theriogenology, 45:111-120.). In addition, as previously cited in this review, the FCS supplementation was also associated with increased cytoplasmic lipid deposit and reduced cryosurvival of the embryos (Abe et al., 2002Abe H, Yamashita S, Satoh T, Hoshi H. 2002. Accumulation of cytoplasmic lipid droplets in bovine embryos and cryotolerance of embryos developed in different culture systems using serum-free or serum-containing media. Mol Reprod Dev, 61:57-66.; Sudano., 2011). In a previous work of our group, the cytoplasmic lipid droplets fluctuation observed on IVP embryos was closed related with FCS concentration supplemented to the culture media (Sudano et al., 2011Sudano MJ, Paschoal DM, da Silva Rascado T, Magalhães LCO, Crocomo LF, de Lima-Neto JF, da Cruz Landim-Alvarenga F. 2011. Lipid content and apoptosis of in vitro-produced bovine embryos as determinants of susceptibility to vitrification. Theriogenology, 75:1211-1220.) and with the mRNA levels for ACSL3 (Sudano et al. 2016aSudano MJ, Rascado TD, Tata A, Belaz KR, Santos VG, Valente RS, Mesquita FS, Ferreira CR, Araujo JP, Eberlin MN, Landim-Alvarenga FD. 2016a. Lipidome signatures in early bovine embryo development. Theriogenology, 86:472-484.).
Taking all these studies together, culture conditions dramatically affect embryo developmental potential, quality, and further ability to survive after cryopreservation, and establish and maintain pregnancy. Despite many knowledge of the in vitro production systems have been produced over the past decades, efficiency improvements in the biotechnology process of the bovine IVPE is still needed in order to increase blastocyst yield of an exceptional quality.
Lipids and other determining molecules for embryo competence
The morphological transitions performed by embryos during the early development until implantation are accompanied by changes in the substrate requirements due to the embryo metabolism demand during this period. In vivo, at the reproductive tract, where embryo development takes place, sources of amino acids, proteins, lactate, pyruvate, glucose, antioxidants, ions, growth factors, hormones, and lipids are dynamically available with variations in concentration according to species, estrous cycle period and location (Di Paolo and De Camilli, 2006Di Paolo G, De Camilli P. 2006. Phosphoinositides in cell regulation and membrane dynamics. Nature, 443:651-657).
The measurement of embryonic metabolism can be used as an important tool in the analysis of molecular and cellular competence (Thompson et al., 2016Thompson JG, Brown HM, Sutton-McDowall ML. 2016. Measuring embryo metabolism to predict embryo quality. Reprod Fertil Dev, 28:41-50.). Hamatani et al. (2004)Hamatani T, Daikoku T, Wang H, Matsumoto H, Carter MG, Ko MS, Dey SK. 2004. Global gene expression analysis identifies molecular pathways distinguishing blastocyst dormancy and activation. Proc Natl Acad Sci, 101:10326-31. described two different physiological profiles of blastocysts (dormancy and activation) according to the global expression of genes involved in cell cycle control, cell signaling, and energy metabolism. In a total of 18 genes associated with metabolism, 13 were expressed in blastocysts on activation and 5 in blastocysts on dormancy. These metabolism variations contributed to the further hypothesis of “quiet embryos”, which describes the metabolic efficiency of competent embryos with the lower need of substrate for development as a result of a lower percentage of cell damage based in the comparison of IVD and IVP embryos (Leese et al., 2008Leese HJ, Baumann CG, Brison DR, McEvoy TG, Sturmey RG. 2008. Metabolism of the viable mammalian embryo: Quietness revisited. Mol Hum Reprod, 14:667-672., 2007Leese HJ, Sturmey RG, Baumann CG, McEvoy TG. 2007. Embryo viability and metabolism: Obeying the quiet rules. Hum Reprod, 22:3047-3050.).
When analyzing the energy metabolism during early embryonic development, energy consumption is relatively low until pre-compaction stage and the main source of ATP is derived from pyruvate through oxidative phosphorylation, whereas with blastocyst formation and cavitation process a significant increase on energy demand and consumption of glucose, pyruvate and oxygen are expected. Additionally, after formation of the blastocyst, other sources of energy are required in greater proportion, including: glucose, amino acids and lipids (D’Souza et al., 2018D’Souza F, Uppangala S, Asampille G, Salian SR, Kalthur G, Talevi R, Atreya HS, Adiga SK. 2018. Spent embryo culture medium metabolites are related to the in vitro attachment ability of blastocysts. Sci Rep, 8:1-10.; Hu and Yu, 2017Hu K, Yu Y. 2017. Metabolite availability as a window to view the early embryo microenvironment in vivo. Mol Reprod Dev, 84:1027-1038.).
Because of the various formulations of medium used by IVF laboratories, the understanding of metabolic spent during IVPE helps in directing compositions that structure viable embryos to the establishment of pregnancy (Thompson et al., 2016Thompson JG, Brown HM, Sutton-McDowall ML. 2016. Measuring embryo metabolism to predict embryo quality. Reprod Fertil Dev, 28:41-50.). Recent studies showed a higher energetic requirement of pyruvate and lactate, during culture, for non-competent embryos (D’Souza et al., 2018D’Souza F, Uppangala S, Asampille G, Salian SR, Kalthur G, Talevi R, Atreya HS, Adiga SK. 2018. Spent embryo culture medium metabolites are related to the in vitro attachment ability of blastocysts. Sci Rep, 8:1-10.). The influence of the culture medium on the embryonicdevelopment and the production of healthy animals is already well established, so research that identifies the potential of energy supplements used in the bovine IVPE prevents the multiplication of inappropriate phenotypes (De Souza et al., 2015De Souza DK, Salles LP, Rosa E Silva A. 2015. Aspects of energetic substrate metabolism of in vitro and in vivo bovine embryos. Braz J Med Biol Res, 48:191-197.).
Additionally, lipids are an important source of ATP for cell development and actively participates in embryonic metabolic pathways (Hu and Yu, 2017Hu K, Yu Y. 2017. Metabolite availability as a window to view the early embryo microenvironment in vivo. Mol Reprod Dev, 84:1027-1038.). Lipids are responsible for the cross-talk between embryo, oviduct and uterus. This event is necessary in the synchronization of molecular and cellular events during the pregnancy establishment.
Studies demonstrated the lipid importance in signaling and coordination of biological events by mediating lipids such as phosphatidylinositols, sphingolipids, and eicosanoids (Di Paolo and De Camilli, 2006Di Paolo G, De Camilli P. 2006. Phosphoinositides in cell regulation and membrane dynamics. Nature, 443:651-657; Wang and Dey, 2005Wang H, Dey SK. 2005. Lipid signaling in embryo implantation. Prostaglandins and Other Lipid Mediators, 77:84-102.). Lipids are essential cellular biomolecules for plasma membrane and membranes of several organelles (Di Paolo and De Camilli, 2006Di Paolo G, De Camilli P. 2006. Phosphoinositides in cell regulation and membrane dynamics. Nature, 443:651-657). In bovine embryos, a stage-specific dynamic lipid fluctuation was observed during early embryo development (Sudano et al., 2016aSudano MJ, Rascado TD, Tata A, Belaz KR, Santos VG, Valente RS, Mesquita FS, Ferreira CR, Araujo JP, Eberlin MN, Landim-Alvarenga FD. 2016a. Lipidome signatures in early bovine embryo development. Theriogenology, 86:472-484.). In addition, our group identified an increase in the mRNA levels for ELOVL5 and ELOVL6 (two transcripts of the ELOVLs family, responsible for fatty acids elongation) at the morula stage preceding an increase in membrane phospholipids containing elongated saturated, monosaturated and polysaturated fatty acids (16, 18 and 20 carbons) at the blastocyst stage (Sudano et al., 2016aSudano MJ, Rascado TD, Tata A, Belaz KR, Santos VG, Valente RS, Mesquita FS, Ferreira CR, Araujo JP, Eberlin MN, Landim-Alvarenga FD. 2016a. Lipidome signatures in early bovine embryo development. Theriogenology, 86:472-484.).
Cells can synthesize simple fatty acids due to their biological functions. In this sense, lipid elongation facilitates the formation of complex biomolecules for specific activities (Guillou et al., 2010Guillou H, Zadravec D, Martin PGP, Jacobsson A. 2010. The key roles of elongases and desaturases in mammalian fatty acid metabolism: Insights from transgenic mice. Prog Lipid Res, 49:186-199.). We have recently observed the involvement of the ELOVL5 in the lipid metabolism of IVP embryos by regulating the cytoplasmic lipid deposit and the abundance of phosphatidylcholines, phosphatidylethanolamines and triacylglycerol (data not published).
All these findings demonstrate the importance of understanding the mechanisms involved in energy metabolism and embryo lipids composition in order to optimize in vitro culture conditions to allow the production of embryos with superior quality and greater cryosurvival.
Embryo cryopreservation
Embryo cryopreservation is a nitrogen (N2) based conservation biotechnology that aims to maintain the cells in quiescent state, prolong the viability for long periods of time and enable their use in a timely manner (Fig. 3 3). In the area of assisted reproduction, primordial germ cells, gametes and embryos can be cryopreserved. It is considered a strategy to overcome logistical problems associated with the transfer of a large number of fresh embryos and mainly for the expansion of the commercialization of embryos between countries (Sudano et al., 2013bSudano MJ, Paschoal DM, Maziero RRD, Rascado TS, Guastali MD, Crocomo LF, Magalhães LCO, Monteiro BA, Martins Jr A, Machado R, Landim-Alvarenga FDC. 2013b. Improving postcryopreservation curvival capacity: an embryo-focused approach. Anim Reprod, 10:160-167). Among the advantages are the optimization of reproductive biotechnologies such as IVPE and transfer of embryos in order to preserve surplus embryos, conservation of the genetic material of endangered species, prevention of problems arising from the transport of live animals and adaptations of the calving season.
Vitrified in vitro produced bovine embryos immediately after warming (A), and following 6 h (B) and 12 h (re-expanded and hatched blastocysts, respectively for C and D) of re-culture.
The first success report on the survival of embryos (mice) subjected to freezing/thawing was recorded by Whittingham et al. (1972)Whittingham D, Leibo S, Mazur P. 1972. Survival of mouse embryos frozen to-196 and-269 C. Science, 178:411-414.. In the following years, the technique was also applied successfully in different species and embryo cryopreservation started to be applied commercially. In Brazil, the majority of the IVP embryos are still transferred fresh, but the percentage of frozen (33.7%) follows a growth trend, and among the embryos produced in vivo, the slow freezing is the preferred option (62.1% of the total) (Viana, 2018Viana JH. 2018. A produção de embriões bovinos em 2017: o mercado em stand-by. Jornal o embrião, 62:6-10.). The principle of cryopreservation consists of maximum removal of water from the interior of the cells before freezing, avoiding the formation of large ice crystals that cause cell damage, which allows the resumption of cellular metabolism after storage at low temperatures. For this reason, cryopreservation strategies are based on two main factors: cooling/warming rates and choice of suitable cryoprotectants (CPA) (Vajta and Kuwayama, 2006Vajta G, Kuwayama M. 2006. Improving cryopreservation systems. Theriogenology, 65:236-244.).
According to Mazur (1980)Mazur P. 1980. Fundamental aspects of the freezing of cells, with emphasis on mammalian ova and embryos. In: International Congress on Animal Reproduction and Artificial Insemination. Proceedings of International Congress of Animal Reproduction and Artificial Insemination, pp.99-114. there is a correlation between the cooling rate and the appearance of cell lesions, i.e. as the freezing rate increases, the survival after thawing also increases, until an ideal maximum index is reached from which the higher freezing speed also leads to greater damage and lower embryo survival. In addition to the freezing rate curve, the use of CPA is essential to provide cellular protection against temperature drop. Although CPA are absolutely necessary and widely used in cryopreservation protocols, the mechanisms that confer protection of the biological material as well as the toxicity and cellular metabolism of these agents are not fully elucidated and addressed in the literature (Castro et al., 2011Castro S, de Andrade Carvalho A, Gomes da Silva CM, Rocha Faustino L, de Figueiredo JR, Ribeiro Rodrigues AP. 2011. Agentes crioprotetores intracelulares: características e utilização na criopreservação de tecido ovariano e oócitos. Acta Scientiae Veterinariae, 39:1-17.). For review all cryobiology principles involved on embryo cryopreservation, please see Sudano et al. (2016b)Sudano MJ, Marinho LSR, Costa CB, Cancian R. 2016b. Cryopreservation of Bovine Embryos. In: Seneda MM, Silva-Santos KC, Marinho LSR (Ed.). Biotechnology of Animal Reproduction. Hauppauge, NY, USA: Nova Science Publishers. p.1-33.
It is known, at least partially, that the CPA protective effect comes from the reduction of the solidification point of the solutions and the ability on intermediating intracellular water removal/restauration. According to their ability to penetrate cell membranes, CPA are divided into two groups: permeable (e.g. glycerol, ethylene glycol and propylene glycol) and impermeable (e.g. sucrose, galactose, polyethylene glycol and polyvinylpyrrolidone). In addition, there are two major cryopreservation methodology currently applied for bovine embryos, slow freezing and vitrification.
Cryopreservation techniques
Slow or classic freezing is one of the most widespread embryo cryopreservation techniques and is based on the use of glycerol or ethylene glycol as a CPA. The main advantage of this technique is the reduced cellular toxicity through the use of low concentrations of CPA, however, slow freezing still allows the formation of ice crystals that could lead to cellular damage. After a period of previous CPA exposure, the embryos are loaded in straws together with the CPA solution, which will be allocated in programmable freezing devices for cooling. The temperature drop is controlled by keeping a constant curve until the temperature reaches -32°C, when the straws containing the embryos are immersed in the liquid nitrogen. After thawing, the embryos must be placed in petri dishes where the CPA solution will be diluted by successive washes in dilution solutions. Alternatively, Leibo (1983)Leibo S. 1983. A one-step in situ dilution method for frozen thawed bovine embryos. Cryo-letters, 4:387-400. developed the One-Step method where dilution of the CPA still occurs in the straw after thawing, letting the transfer to recipients be without previous microscopic evaluation.
Although slow freezing is the most widely used method for the cryopreservation of IVD embryos, vitrification has emerged as an alternative to IVP embryos. When comparing the cryosurvival and pregnancy results of both procedures considering the production method, IVD embryos present similar results, for both slow freezing and vitrification, whereas IVP embryos present more satisfactory results with vitrification (Tab. 1 and 2). However, slow-freezing also can be a good option to cryopreserve IVP embryos, Sanches et al. (2016)Sanches BV, Lunardelli PA, Tannura JH, Cardoso BL, Pereira MH, Gaitkoski D, Basso AC, Arnold DR, Seneda MM. 2016. A new direct transfer protocol for cryopreserved IVF embryos. Theriogenology, 85:1147-1151. reported similar pregnancy rates on Day 60 after the transfer of IVP embryo cryopreserved by slow-freezing (34.7%, n = 311) or vitrification (31.2%, n = 234).
Post-cryopreservation survival of in vitro produced bovine embryos following slow-freezing and vitrification.
Post-cryopreservation survival of in vivo produced bovine embryos following slow-freezing and vitrification.
Vitrification eradicates the damage caused by the formation of ice crystals during the cooling process. The cryopreservation medium undergoes a direct passage from the liquid state to a vitrified and amorphous state without the crystallization of the medium occurring, which it is possible due to the high viscosity of the cryopreservation medium and the high freezing rate (>20.000°C/min) by direct immersion in N2, from room temperature (Fahy et al., 1984Fahy GM, MacFarlane D, Angell C, Meryman H. 1984. Vitrification as an approach to cryopreservation. Cryobiology, 21:407-426.). The technique is extremely fast and does not require the use of freezing devices; however, it requires more training and technical skills from the technician. Among the disadvantages are the difficulty of direct transfer and the need to use high concentrations of CPA that can cause cellular toxicity. As a result, several combinations with different CPA, concentrations and period of exposure have already been proposed. In order to ensure a rapid cooling rate, the use of the minimum volume of solution per sample is adopted in order to provide immediate contact with the N2. For this purpose, specific tools have been developed for packaging the embryos into microdrops, such as Open Pulled Straw (OPS) (Vajta et al., 1998Vajta G, Holm P, Kuwayama M, Booth PJ, Jacobsen H, Greve T, Callesen H. 1998. Open pulled straw (OPS) vitrification: a new way to reduce cryoinjuries of bovine ova and embryos. Mol Reprod Dev, 51:53-58. Vajta G, Hyttel P, Callesen H. 1997. Morphological changes of in-vitro-produced bovine blastocysts after vitrification, in-straw direct rehydration, and culture. Mol Reprod Dev, 48, 9-17.), Cryoloop (Lane et al., 1999Lane M, Schoolcraft WB, Gardner DK, Phil D. 1999. Vitrification of mouse and human blastocysts using a novel cryoloop container-less technique. Fertility and sterility, 72:1073-1078.) and Cryotop (Kuwayama, 2007Kuwayama M. 2007. Highly efficient vitrification for cryopreservation of human oocytes and embryos: the Cryotop method. Theriogenology, 67:73-80.). More recently, a new automated vitrification methodology has been proposed (Arav et al., 2018Arav A, Natan Y, Kalo D, Komsky-Elbaz A, Roth Z, Levi-Setti PE, Leong M, Patrizio P. 2018. A new, simple, automatic vitrification device: preliminary results with murine and bovine oocytes and embryos. J Assist Reprod Genet, 35:1161-1168.), which may facilitate and optimize the standardization of the technique.
Despite great results were achieved with enhancements of the cryopreservation methodology over the last decades; an embryo-focused approach to improve cryosurvival has been recommended.
An embryo-focused approach to improve cryosurvival
The effect of cryopreservation on mammalian embryos reduces survival rates, leading to considerable morphological and functional damage. However, the extent of cryoinjury is highly variable and dependent on the species, stage of development and origin of the embryo (produced in vivo or in vitro) at the time of cryopreservation (Dalcin and Lucci, 2010Dalcin L, Lucci C. 2010. Criopreservação de embriões de animais de produção: princípios criobiológicos e estado atual. Rev Bras Reprod Anim, 34:149-159.).
There is a consensus in the literature that IVP embryos present lesser cryoresistance compared with IVD embryos. Ultrastructural and biochemical characteristics such as increased lipid content, reduced intercellular junctions, fewer mitochondria and microvilli, larger perivitelline space and more cell debris are generally associated with the reduced cryosurvival of IVP embryos (Fair et al., 2001Fair T, Lonergan P, Dinnyes A, Cottell DC, Hyttel P, Ward FA, Boland MP. 2001. Ultrastructure of bovine blastocysts following cryopreservation: effect of method of blastocyst production. Mol Reprod Dev, 58:186-195.; Abe et al., 2002Abe H, Yamashita S, Satoh T, Hoshi H. 2002. Accumulation of cytoplasmic lipid droplets in bovine embryos and cryotolerance of embryos developed in different culture systems using serum-free or serum-containing media. Mol Reprod Dev, 61:57-66., Rizos et al. 2002Rizos D, Ward F, Duffy P, Boland MP, Lonergan P. 2002. Consequences of bovine oocyte maturation, fertilization or early embryo development in vitro versus in vivo: Implications for blastocyst yield and blastocyst quality. Mol Reprod Dev, 61:234-248.). Additional variables associated with embryo cryosurvival are presented on Table 3. Thus, some strategies can be used to increase the cryotolerance of IVP embryos, such as culture under a low oxygen atmosphere system to minimize oxidative stress, addition of antioxidants to the culture medium, and the use of apoptosis inhibitors (Lin et al., 2018Lin T, Lee JE, Kang JW, Oqani RK, Cho ES, Kim SB, Il Jin D. 2018. Melatonin supplementation during prolonged in vitro maturation improves the quality and development of poor‐quality porcine oocytes via anti‐oxidative and anti‐apoptotic effects. Mol Reprod Dev, 85:665-681.; Pero et al., 2018Pero ME, Zullo G, Esposito L, Iannuzzi A, Lombardi P, De Canditiis C, Neglia G, Gasparrini B. 2018. Inhibition of apoptosis by caspase inhibitor Z-VAD-FMK improves cryotolerance of in vitro derived bovine embryos. Theriogenology, 108:127-135.).
Features positively or negatively associated with cryosurvival evaluated so far by our group.
As already mentioned, excessive lipid droplets accumulation of IVP embryos during development, especially of embryos cultured in serum-supplemented medium, is commonly associated with reduced cryosurvival and lower pregnancy rate (Rizos et al., 2008Rizos D, Clemente M, Bermejo-Alvarez P, De La Fuente J, Lonergan P, Gutiérrez-Adán A. 2008. Consequences of in vitro culture conditions on embryo development and quality. Reprod Domest Anim, 43:44-50.; Sudano et al., 2011Sudano MJ, Paschoal DM, da Silva Rascado T, Magalhães LCO, Crocomo LF, de Lima-Neto JF, da Cruz Landim-Alvarenga F. 2011. Lipid content and apoptosis of in vitro-produced bovine embryos as determinants of susceptibility to vitrification. Theriogenology, 75:1211-1220.). The exact mechanism for this increased lipid content on IVP embryos remains unknown. It seems that serum lipids could be absorbed by embryonic cells (Sata et al., 1999Sata R, Tsujii H, Abe H, Yamashita S, Hoshi H. 1999. Fatty acid composition of bovine embryos cultured in serum-free and serum-containing medium during early embryonic development. J Reprod Dev, 45:97-103.), altering the function of mitochondrial β-oxidation (Abe et al., 2002Abe H, Yamashita S, Satoh T, Hoshi H. 2002. Accumulation of cytoplasmic lipid droplets in bovine embryos and cryotolerance of embryos developed in different culture systems using serum-free or serum-containing media. Mol Reprod Dev, 61:57-66.) and promoting the incorporation of saturated fatty acids and cholesterol in the cell membranes, which make them less permeable (Barceló-Fimbres and Seidel Jr, 2007Barceló‐Fimbres M, Seidel Jr G. 2007. Effects of fetal calf serum, phenazine ethosulfate and either glucose or fructose during in vitro culture of bovine embryos on embryonic development after cryopreservation. Mol Reprod Dev, 74:1395-1405.). All these factors together also could explain the greater susceptibility of the IVP embryos to cryopreservation.
In fact, it is possible to produce embryos with a greater cryosurvival through manipulations of the culture medium. We have already demonstrated that only the reduction of the serum concentration in the developmental medium was capable of decrease thelipid content and increase embryo survival after cryopreservation (Sudano et al., 2011Sudano MJ, Paschoal DM, da Silva Rascado T, Magalhães LCO, Crocomo LF, de Lima-Neto JF, da Cruz Landim-Alvarenga F. 2011. Lipid content and apoptosis of in vitro-produced bovine embryos as determinants of susceptibility to vitrification. Theriogenology, 75:1211-1220.). Recently, our group participate in the development of a serum-free culture medium of IVP embryos that reach similar results of embryo quality and pregnancy rate compared with a serum-supplemented medium (data not published).
Alternatively, chemical substances that act as a delipidant or lipolytic agents, such as Forskolin (Sanches et al., 2013Sanches BV, Marinho LS, Filho BD, Pontes JH, Basso AC, Meirinhos ML, Silva-Santos KC, Ferreira CR, Seneda MM. 2013. Cryosurvival and pregnancy rates after exposure of IVF-derived bos indicus embryos to forskolin before vitrification. Theriogenology, 80:372-377.; Paschoal et al., 2014Paschoal DM, Sudano MJ, Guastali MD, Dias Maziero RR, Crocomo LF, Ona Magalhaes LC, da Silva Rascado T, Martins A, da Cruz Landim-Alvarenga F. 2014. Forskolin effect on the cryosurvival of in vitro-produced bovine embryos in the presence or absence of fetal calf serum. Zygote 22:146-157.), L-carnitine (Held-Hoelker et al., 2017Held-Hoelker E, Klein S, Rings F, Salilew-Wondim D, Saeed-Zidane M, Neuhoff C, Tesfaye D, Schellander K, Hoelker M. 2017. Cryosurvival of in vitro produced bovine embryos supplemented with l-Carnitine and concurrent reduction of fatty acids. Theriogenology, 96:145-152.), and 10t,12c-CLA (Pereira et al., 2007Pereira RM, Baptista MC, Vasques MI, Horta AE, Portugal PV, Bessa RJ, Silva JC, Pereira MS, Marques CC. 2007. Cryosurvival of bovine blastocysts is enhanced by culture with trans-10 cis-12 conjugated linoleic acid (10t,12c CLA). Anim Reprod Sci, 98:293-301.) have been commonly adopted in the attempt to reduce the embryonic lipid content and improve cryosurvival. In addition, embryo delipidation after centrifugation and subsequent micromanipulation has already been proposed (Ushijima et al., 1999Ushijima H, Yamakawa H, Nagashima H. 1999. Cryopreservation of bovine pre-morula-stage in vitro matured/in vitro fertilized embryos after delipidation and before use in nucleus transfer. Biol Reprod, 60:534-539.), however, considering this is an invasive and time-consuming technique, this approach had become impracticable for large scale application and was limited for scientific purpose.
An additional strategy to improve cryosurvival of IVP embryos is the preincubation with grow-stimulating factors before cryopreservation. Beneficial effects of insulin-like growth factor 1 and leukaemia inhibitory factor were observed in the post-cryopreservation survival of bovine blastocysts (Kocyigit and Cevik, 2015Kocyigit A, Cevik M. 2015. Effects of leukemia inhibitory factor and insulin-like growth factor-I on the cell allocation and cryotolerance of bovine blastocysts. Cryobiology, 71:64-69.).
Final considerations
Embryo developmental competence and quality are crucial for cryosurvival and pregnancy success. Many variables can impair embryo competence and cryosurvival such as genotype, oocyte quality and follicular microenvironment, in vitro production conditions, and lipids and other determining molecules. A great quality control of all steps of IPVE and the use of exceptional quality embryos are recommended to improve and achieve homogenous results. A promising scenario for the next few years is expected for the use of the IVP embryos in the reproductive management of beef and dairy cattle. However, it is essential that further research efforts focus on improvements of the efficiency of producing a greater amount of embryos of superior quality, per oocytes recovered and round of in vitro fertilization, to be cryopreserved following transferred in order to reduce costs and justify the activity economically.
Acknowledgments and Funding disclosure statement
The present work was carried out with the support of CNPq, National Council of Scientific and Technological Development – Brazil - grants (MJS) 446647/2014-4; (RSV) 165496/2017-7; and Coordenação de Aperfeiçoamento de Pessoal de Nível Superior – Brasil (CAPES) - financial code 1 (TVM and JC).
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Publication Dates
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Publication in this collection
28 Nov 2019 -
Date of issue
Jul-Sep 2019
History
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Received
28 May 2019 -
Accepted
29 July 2019