Rat: An Interesting Model to Study Oocyte Meiosis in Mammals

In most of the mammalian species, oocyte meiosis takes very long time and passes through several stop/go channels to generate female gamete [1-3]. Within the ovarian follicles, oocytes are normally arrested at diplotene stage of first meiotic prophase for a long time. Meiotic resumption from diplotene stage in follicular oocytes takes place after pituitary gonadotropins surge. Oocytes then progress through metaphase-I (M-I stage) to metaphase-II (M-II stage) just prior to ovulation in several mammalian species. Meiotic resumption from diploete arrest to M-II arrest is a very important period because follicular oocyteachieves meiotic competency during this period. The M-II arrest is a physiological arrest in preovulatory oocytes and exit from M-II arrest normally occurs due to sperm triggering at the time of fertilization in most of the mammalian species including human. Studies carried out in last two decades suggest that the rat is an interesting and peculiar animal model among mammals to analyse meiotic cell cycle regulation in oocytes within the ovarian follicle and even after ovulation [3,4].

Meiotic cell cycle in rat oocyte starts during foetal life and gets arrested for the first time at diplotene stage of prophase-I, which can be identified by the presence of germinal vesicle (GV) within the follicular oocytes [1,4,5]. The diplotene arrest is a longest phase in rat oocyte and may last for few months to several years in follicular microenvironment [6-9]. At the time of puberty, pituitary gonadotropins surge triggers resumption of meiosis from diplotene arrest, which is morphologically characterized by germinal vesicle breakdown (GVBD) [1]. These oocytes are further arrested at M-I stage for a short time (few hours) [1]. The organization of spindle during M-I stage in oocytes leads to the formation of metaphase plate that initiate extrusion of first polar body (PB-I) [3,10,11]. The complete release of PB-I leads to conversion of diploid oocyte into haploid egg just prior to ovulation. The freshly ovulated eggs are arrested at M-II stage of meiotic cell cycle possessing PB-I [3,10-16]. These M-II arrested eggs are the right choice for successful fertilization in vivo as well as in vitro in several mammalian species including human [17].

Rat is an interesting animal model to study meiotic cell cycle in oocytes because of two peculiarities [3]. The first peculiar reason is that the diplotene-arrested oocytes undergo spontaneous resumption of meiosis if isolated from ovarian follicles and are cultured under in vitro conditions for extended period [1,3,4] but they are unable to extrude PB-I and remain arrested at M-I stage of meiotic cell cycle under in vitro culture conditions [1,3,6,18]. The second peculiar reason involves the unique feature of spontaneous exit from M-II arrest in ovulated eggs [3,10,11,13-16,19-24]. Recent studies suggest that the ovulated M-II arrested rat eggs do not wait for fertilization and initiation of extrusion of second polar body (PB-II) has been observed in vivo as well as under in vitro culture conditions. This is an atypical conditions and even freshly ovulated eggs undergo spontaneous exit from M-II arrest, so called abortive spontaneous egg activation (SEA) [3,13-15,21,22,25]. Although initiation of extrusion of PB-II occurs but it never gets completely extruded [3,13-15,22,25]. Meiotic status of these eggs suggest that the chromosomes are scattered throughout the cytoplasm, unable to form metaphase plate and further arrested at metaphase-III (M-III) like stage without forming pronuclei [13,14,22]. These eggs are of deteriorated quality and cannot be used for fertilization in vivo or during several assisted reproductive technologies (ARTs) programs in vitro [17]. Due to depletion of adenosine triphosphate ATP, these eggs undergo apoptosis resulting in compromised reproductive outcome under in vivo as well as in vitro. Due to abortive SEA, it is very challenging to clone a rat following somatic cell nuclear transfer protocol [2,10].

Studies from our laboratory using rat as an experimental model explored the possible reasons behind spontaneous exit from diplotene as well as M-II arrests. Reports suggest that when diplotene arrested oocytes are removed from ovary and cultured under in vitro conditions, they encounter decrease in the level of cyclic 3', 5' –adenosine monophosphate (cAMP) and generation of reactive oxygen species (ROS) such as hydrogen peroxide (H₂O₂) that results in oxidative stress (OS) in oocytes [26-30]. The OS modulates mitochondrial membrane potential (MMP), increases cytosolic free calcium (Ca²⁺) level, triggers maturation promoting factor (MPF) destabilization, which results in spontaneous resumption of meiosis from diplotene arrest [3,30-33]. These oocytes although resume meiosis from diplotene stage but never extrude PB-I under in vitro culture conditions. They remain arrested at M-I stage and due to depletion of energy resources leads to the generation of OS that induces oocyte apoptosis [10].

The M-I arrest has not been reported in rat under in vivo conditions and oocytes are converted into egg by releasing PB-II. However, studies suggest that freshly ovulated eggs immediately experiences postovulatory aging under both in vivo as well as in vitro conditions that causes spontaneous resumption of meiosis [13,14,22]. Postovulatory aging in vivo as well as in vitro conditions cause molecular changes such as generation of ROS leading to OS in aged eggs. The OS modulate MMP thereby increasing Ca²⁺ level [32,34,35]. These changes trigger destabilization of MPF resulting in spontaneous exit from M-II arrest and further deteriorates egg quality by inducing apoptosis [2-4,13-16,32].

Hence, rat can be treated as interesting model due to M-I arrest under in vitro culture conditions and abortive SEA in vivo as well as in vitro. These peculiar features results in poor quality oocytes/eggs that are not suitable for in vivo fertilization as well as for various ARTs programs. These peculiarities make rat oocytes/eggs as interesting cell model to study meiotic cell cycle progression from diplotene arrest to M-II arrest, a period that decides the achievement of meiotic competency required for successful fertilization, early embryonic development and expected reproductive outcome. Further studies are required to explore the underlying causes that could be responsible for these peculiarities in oocyte meiosis in rat.

References

1. Pandey AN, et al. Reactive oxygen and nitrogen species during meiotic resumption from diplotene arrest in mammalian oocytes.J Cell Biochem. 2010;111:521-528.
2. Tiwari M, et al. Apoptosis in mammalian oocytes: A review. Apoptosis. 2015;20:1019-1025.
3. Prasad S, et al. Changes in signal molecules and maturation promoting factor levels associate with spontaneous resumption of meiosis in rat oocytes. Cell Biol Int. 2015;39:759-769.
4. Tiwari M, et al. Involvement of reactive oxygen species in meiotic cell cycle regulation and apoptosis in mammalian oocytes. Reactive Oxygen Species. 2016;1:110-116.
5. Chaube SK. Role of meiotic maturation regulatory factors in developmental competence of mammalian oocytes. HPPI 2001;24:218-231.
6. Wassarman PM and Albertini DF. The mammalian ovum. In: Knobil E, Neill JD (eds.), The physiology of reproduction. 2nd edn. Physiol. Reprod., Raven Press, New York, 1994;1:79122.
7. Sirard MA. Resumption of meiosis: mechanism involved in meiotic progression and its relation with developmental competency. Theriogenology 2001;55:1241-1254.
8. Trounson A, et al. Maturation of human oocytes in vitro and their developmental competence. Reproduction 2001;121:51-75.
9. Mehlmann LM. Stops and starts in mammalian oocytes: Recent advances in understanding the regulation of meiotic arrest and oocyte maturation. Reproduction 2005;130:791-799.
10. Prasad S, et al. Morphological, cellular and molecular changes during postovulatory aging in mammals.J Biomed Sci. 2015;22:36.
11. Tripathi A, et al. Meiotic cell cycle arrest in mammalian oocytes. J Cell Physiol. 2010;223:592-600.
12. Chaube SK, et al. Verapamil reversibly inhibits spontaneous parthenogenetic activation in aged rat eggs cultured in vitro. Cloning Stem Cells. 2007;9:608-617.
13. Prasad S, et al. Involvement of cyclin-dependent kinase 1 during postovulatory aging-mediated abortive spontaneous egg activation in rat eggs cultured in vitro. Cell Reprogram. 2016;18:96-107.
14. Prasad S, et al. Maturation promoting factor destabilization facilitates postovulatory aging-mediated abortive spontaneous egg activation in rat. Develop Growth Differ. 2016;58:293-302.
15. Prasad S and Chaube SK. S-nitroso-N-acetyl penicillamine inhibits spontaneous exit from metaphase-II arrest in rat eggs cultured in vitro. Biomed Pharmacother.2016;84:680-686.
16. Prasad S and Chaube SK. Increased telomerase reverse transcriptase expression associates with spontaneous exit from M-II arrest in rat eggs. Cell Reprogram. 2016.
17. Miao YL, et al. Oocyte aging: Cellular and molecular changes, developmental potential and reversal possibility. Hum Reprod. 2009;5:573-585.
18. Chaube SK. Effects of pentoxifylline and caffeine on spontaneous maturation of rat oocytes. HPPI 2000;23:177–189.
19. Ross PJ, et al. Oocyte spontaneous activation in different rat strains. Cloning Stem Cells. 2006;8:275-282.
20. Galat V, et al. Overcoming M-III arrest from spontaneous activation in cultured rat oocytes. Cloning Stem Cells. 2007;9:303-314.
21. Chebotareva T,et al. Rat eggs cannot wait: Spontaneous exit from meiotic metaphase-II arrest. Mol Reprod Dev. 2011;78:795-807.
22. Premkumar KV and Chaube SK. An insufficient increase of cytosolic free calcium level results postovulatory aging-induced abortive spontaneous egg activation in rat. J Assist Reprod Genet. 2013;30:117-123.
23. Premkumar KV and Chaube SK. RyR channel-mediated increase of cytosolic free calcium level signals cyclin B1 degradation during abortive spontaneous egg activation in rat. In Vitro Cell Dev. Biol Anim. 2014;50:640-647.
24. Chaube SK, et al. Abortive spontaneous egg activation: A limiting factor for reproductive outcome in mammals. Res Rev J Zool Sci 2016;4:1-2.
25. Premkumar KV and Chaube SK. Nitric oxide signals postovulatory aging-induced abortive spontaneous egg activation in rats. Redox Rep. 2015;20:184-192.
26. Chaube SK, et al. Hydrogen peroxide modulates meiotic cell cycle and induces morphological features characteristics of apoptosis in rat oocytes cultured in vitro. Apoptosis 2005;10:863-874.
27. Chaube SK, et al. Calcium ionophore-induced egg activation and apoptosis are associated with the generation of intracellular hydrogen peroxide. Free Radic. Res. 2008;42:212-220.
28. Chaube SK, et al. Neem leaf extract deteriorates oocyte quality by inducing ROS-mediated apoptosis in mammals.SpringerPlus 2014;3:464.
29. Tripathi A, et al. Intracellular levels of hydrogen peroxide and nitric oxide in oocytes at various stages of meiotic cell cycle and apoptosis. Free Rad Res 2009;43:287-294.
30. Pandey AN and Chaube SK. A moderate increase of hydrogen peroxide level is beneficial for spontaneous resumption of meiosis from diplotene arrest in rat oocytes cultured in vitro. Biores. Open Access. 2014;3:183-191.
31. Pandey AN and Chaube SK. Reduction of nitric oxide level leads to spontaneous resumption of meiosis in diplotene-arrested rat oocytes cultured in vitro. Exp Biol Med. 2015;240:15-25.
32. Tiwari M, et al. Calcium signaling during meiotic cell cycle regulation and apoptosis in mammalian oocytes.J Cell Physiol. 2016.
33. Gupta A, et al. Role of cyclic nucleotide phosphodiesterases during meiotic resumption from diplotene arrest in mammalian oocytes.J Cell Biochem. 2016.
34. Tripathi A andChaube SK. High level of cytosolic free calcium signals apoptosis through the mitochondria-caspase mediated pathway in rat eggs cultured in vitro. Apoptosis 2012;17:439-448.
35. Premkumar KV and Chaube SK. Increased level of reactive oxygen species persuades postovulatory aging-mediated spontaneous egg activation in rat eggs cultured in vitro. In Vitro Cell Dev Biol Anim. 2016;52:576-588.