Hostname: page-component-586b7cd67f-t8hqh Total loading time: 0 Render date: 2024-11-23T00:52:40.133Z Has data issue: false hasContentIssue false

Neo-oogenesis in mammals

Published online by Cambridge University Press:  07 August 2017

Tania Janeth Porras-Gómez
Affiliation:
Department of Cell Biology and Physiology, Instituto de Investigaciones Biomédicas, Universidad Nacional Autónoma de México, Ciudad Universitaria, Apartado Postal 70228, México D.F. 04510, México.
Norma Moreno-Mendoza*
Affiliation:
Department of Cell Biology and Physiology, Instituto de Investigaciones Biomédicas, Universidad Nacional Autónoma de México, Ciudad Universitaria, Apartado Postal 70228 México, D.F. 04510México.
*
All correspondence to: Norma Moreno-Mendoza. Department of Cell Biology and Physiology, Instituto de Investigaciones Biomédicas, Universidad Nacional Autónoma de México, Ciudad Universitaria, Apartado Postal 70228 México, D.F. 04510México. Tel: +52 55 56 22 38 66. E-mail: [email protected]
Rights & Permissions [Opens in a new window]

Summary

Recently, the existence of a mechanism for neo-oogenesis in the ovaries of adult mammals has generated much controversy within reproductive biology. This mechanism, which proposes that the ovary has cells capable of renewing the follicular reserve, has been described for various species of mammals. The first evidence was found in prosimians and humans. However, these findings were not considered relevant because the predominant dogma for reproductive biology at the time was that of Zuckerman. This dogma states that female mammals are born with finite numbers of oocytes that decline throughout postnatal life. Currently, the concept of neo-oogenesis has gained momentum due to the discovery of cells with mitotic activity in adult ovaries of various mammalian species (mice, humans, rhesus monkeys, domestic animals such as pigs, and wild animals such as bats). Despite these reports, the concept of neo-oogenesis has not been widely accepted by the scientific community, generating much criticism and speculation about its accuracy because it has been impossible to reproduce some evidence. This controversy has led to the creation of two positions: one in favour of neo-oogenesis and the other against it. Various animal models have been used in support of both camps, including both classic laboratory animals and domestic and wild animals. The aim of this review is to critically present the current literature on the subject and to evaluate the arguments pro and contra neo-oogenesis in mammals.

Type
Research Article
Copyright
Copyright © Cambridge University Press 2017 

Introduction

The ovaries are the female sex glands that produce hormones responsible for ensuring the proper functioning of all sexual organs in females. During their development, the ovaries fulfill two fundamental processes: (1) oogenesis, in which female germ cells (oocytes) are formed and mature; and (2) folliculogenesis, in which somatic cells (granulosa and theca) surround the oocyte and form ovarian follicles. Because of cellular interactions that take place between the oocyte and somatic cells and hormonal influences, the ovary becomes endowed with a finite number of germ cells at birth that diminishes with age, once the reproductive stage begins, and eventually disappears (Zuckerman, Reference Zuckerman1951). In contrast, several studies have suggested that the adult mammalian ovary is not provided with a finite number of oocytes, as has been asserted for so long. Classic and current evidence indicates that the adult mammalian ovary possesses self-renewing germline stem cells (GSCs) that form a reserve of oocytes that maintains a stable number of germ cells. This idea, in opposition to the established dogma in reproductive biology, has generated much controversy, which has intensified over the past 2 decades, creating opinions for and against the existence of a mechanism of neo-oogenesis in the adult mammalian ovary (Gosden, Reference Gosden2013).

In mammals, the existence of GSCs has caused great controversy. Several research groups have argued that GSCs do not exist in adult mammalian ovaries and are present only in the testes, in which sperm production is derived from a population of self-renewing cells known as spermatogonial stem cells (SSCs) that are present in males of all species studied (Regaud, Reference Regaud1901; Brinster, Reference Brinster2007). Considering that females ovulate only a few hundred oocytes during a portion of their life, evolutionarily, they do not require these cells (Monget et al., Reference Monget, Bobe, Gougeon, Fabre, Monniaux and Dalbies-Tran2012), contrary to invertebrates and fish, which require a pool of renewable GSCs due to their high reproduction rates throughout the year.

Primordial germ cells

The primordial germ cells (PGCs) are the first population of germ cells established during development and are the precursor cells of oocytes and sperm in the ovaries and testes, respectively. In mice, PGCs are first identified by their affinity for alkaline phosphatase at 7.25 embryonic day (E7.25) emerging from the posterior primitive streak in extraembryonic mesoderm (Chiquoine, Reference Chiquoine1954; Ginsburg et al., Reference Ginsburg, Snow and McLaren1990; Leitch et al., Reference Leitch, Tang and Surani2013). Subsequently, PGCs migrate through the region in which the gonads are forming passing through the hindgut endoderm around E7.75 to the dorsal mesentery around E9.5 and colonizing the genital ridges at E10.5 (Saitou & Yamaji, Reference Saitou and Yamaji2012). Molyneaux and colleagues (Reference Molyneaux, Stallock, Schaible and Wylie2001) described distinct phases of PGCs migration, the first, until E9.0–E9.5, PGCs are already highly mobile, but do not leave the gut. Second, in the E9.0–E9.5 period, before the mesentery forms, PGCs very rapidly exit the gut, but do not migrate towards the genital ridges. Third, during the E10.0–E10.5 period, PGCs migrate directionally from the dorsal body wall into the genital ridges. Finally, at E11.5, PGCs are slowing and the direction of movement is dependent on the sex of the embryo. PGCs proliferate as they migrate, rapidly increasing in number to approximately 100 cells at E8.5 and to 25,000 at E13.5 (Ewen & Koopman, Reference Ewen and Koopman2010).

Sex-specific differences in the gonads are evident by E12.5 and this represents a convenient endpoint of PGCs development (Sasaki & Matsui, Reference Sasaki and Matsui2008). In female embryos, PGCs begin the process of meiosis to reduce their genetic material. Notably, PGCs are unable to divide mitotically once they enter the first phase of meiotic division (Hilscher et al., Reference Hilscher, Hilscher, Bulthoff-Ohnolz, Kramer, Birke, Pelzer and Gauss1974; Speed, Reference Speed1982). These cells undergo considerable epigenetic reprogramming, including chromatin modification, allowing the downregulation of genes from somatic cells such as those from the HOX family (Hoxa1, Hoxb1, Lim1 and Evx1), which are repressed in cells destined to become germ cells (Saitou et al., Reference Saitou, Barton and Surani2002). This downregulation permits both pluripotency in genes and activation of genes characteristic of the germ cell lineage, in particular Prdm1 (also known as Blimp1) and Prdm14. During their specification and migration, PGCs are highly pluripotent and are characterized by the expression of genes such as Oct-4, Sox2 and Nanog, but during ovarian development, these genes are substantially downregulated around E13.5 (Western et al., Reference Western, van den Bergen, Miles and Sinclair2010), just before entry into meiosis.

Oogenesis

The onset of meiosis is crucial for ovarian morphogenesis, which involves folliculogenesis and oogenesis. The onset of meiosis is executed by the action of retinoic acid (RA), which is present in the gonadal environment and activates pre-meiotic gene expression of Stra8 (Stimulated by Retinoic Acid 8) in ovarian germ cells (Koubova et al., Reference Koubova, Menke, Zhou, Capel, Griswold and Page2006; Bowles & Koopman, Reference Bowles and Koopman2007; Griswold et al., Reference Griswold, Hogarth, Bowles and Koopman2012; Mu et al., Reference Mu, Wen, Guo, Wang, Li, Wang, Wang, Teng, Cui and Xia2013). Recently, it has become apparent that a second gene called Rec8 (meiotic recombination protein), which encodes a component of the cohesin complex, is essential for meiosis; it has been thought that Rec8 is another target of RA and is activated independently of Stra8 (Koubova et al., Reference Koubova, Hu, Bhattacharyya, Soh, Gill, Goodheart, Hogarth, Griswold and Page2014).

Once meiosis begins, a layer of granulosa cells begins to enclose the oocytes, forming primordial follicles. Many oocytes that are not surrounded by somatic cells undergo apoptosis, determining the pool of primordial follicles (Sanchez & Smitz, Reference Sanchez and Smitz2012). These follicles become primary follicles when granulosa cells become columnar and undergo mitotic division to form a multi-layered stratum granulosum and oocytes grow to more than 20 microns in size. At this stage of folliculogenesis, numerous genes are activated, such as the transcription factor Figla, which is expressed exclusively in germ cells and regulates the transcription of zona pellucida genes (ZP1, ZP2 and ZP3) (Liang et al., Reference Liang, Soyal and Dean1997), and Nobox, which restricts oocyte growth and limits the development of granulosa cells to seven layers, although primordial follicles appear histologically normal, as evidenced from mouse knockouts (Rajkovic et al., Reference Rajkovic, Pangas, Ballow, Suzumori and Matzuk2004). During folliculogenesis, the oocyte responds to luteinizing hormone, resuming meiosis and completing maturation. Reactivation of meiosis and promotion through metaphase involves a complex signaling cascade based on epidermal growth factor (Park et al., Reference Park, Su, Ariga, Law, Jin and Conti2004). The mitogen-activated protein kinase pathway is activated in the granulosa cells of the pre-ovulatory follicle to maintain the oocyte in a state of arrest (Downs, Reference Downs2010) while regulating the permeability of cyclic guanosine monophosphate through junctions between granulosa cells and the oocyte (Norris et al., Reference Norris, Freudzon, Mehlmann, Cowan, Simon, Paul, Lampe and Jaffe2008). Oocyte maturation is completed after arrest in metaphase II, and completion of meiosis occurs exclusively with fertilization and extrusion of the second polar body, leaving a haploid female pronucleus (Li & Albertini, Reference Li and Albertini2013).

Dogma of reproductive biology

During the 1920s, Pearl and Schoppe asserted that the number of oocytes does not increase during the life of an individual (Pearl & Schoppe, Reference Pearl and Schoppe1921), an idea that was later corroborated by the British zoologist Sir Solomon Zuckerman. In Reference Zuckerman1951, Zuckerman published a report that provided a careful review of the oocyte numbers of various animal species (rat, mouse, rhesus monkey, rabbit, dog, guinea pig and human) at various ages and noted that the number of oocytes of each species decreased with increasing age. This report led to the basic doctrine of reproductive biology, which argues that during fetal development, female mammals have the potential to generate a limited stock of oocytes, which are surrounded by somatic cells (granulosa cells) and form follicles that are unable to divide (Zuckerman, Reference Zuckerman1951; Zuckerman & Baker, Reference Zuckerman, Baker and Zuckerman1977). Likewise, another group reached the same conclusion, showing that oocyte formation in mouse ovaries takes place only during the fetal period of life, decreases with female age and is depleted in menopause (Peters et al., Reference Peters, Leavy and Crone1962).

Currently, the central dogma of reproductive biology has been questioned because experimental evidence suggests the existence of stem cells with germ cell characteristics and mitotic activity in the ovarian surface epithelium (OSE) of the adult ovary (Johnson et al., Reference Johnson, Canning, Kaneko, Pru and Tilly2004). The function of these cells is to form a small reserve of undifferentiated cells that are capable of self-renewal to maintain a constant number of oocytes, a mechanism that has been called neo-oogenesis. Accordingly, there are two main stances: one that is sceptical of neo-oogenesis and supports the idea of the existence of a fixed number of oocytes established before birth (the classic idea in reproductive biology) and a second that strongly supports the existence of germ stem cells (GSCs) with mitotic activity in the germinal epithelium of adult ovaries that maintain a stable number of oocytes (neo-oogenesis). It has also been indicated in various sources that a reservoir of GSCs that migrate to the ovary exists, an assertion that has added controversy by creating greater discord concerning this hypothesis.

Evidence of neo-oogenesis

The first report to discuss the existence of a renewable source of adult stem cells in the ovaries was presented by Heinrich Waldeyer-Hartz a German anatomist and physiologist (1870). While not firmly accepting the existence of GSCs, the report indicated that the OSE is active for a limited period. Subsequently, Kingery (Reference Kingery1917) reaffirmed this idea, stating that the oocytes degenerated during fetal life are restored by oocytes that develop in the germinal epithelium of the adult ovary. These findings were used to argue that new oocytes emerge from the germinal epithelium as a result of the mitotic division of undifferentiated cells (Allen, Reference Allen1923; Allen & Creadick, Reference Allen and Creadick1937; Esmaeilian et al., Reference Esmaeilian, Atalay and Erdemli2015). Moreover, classic histological works have showed oogonia with mitotic activity and oocytes in the early stages of meiotic prophase in adult ovaries of lower primates Galago senegalensis (Gerard, Reference Gerard1920, Reference Gerard1932; Gerard & Herlant, Reference Gerard and Herlant1953; Herlant, Reference Herlant1961; Petter-Rousseaux, Reference Petter-Rousseaux1962; Butler, Reference Butler, Felts and Harrison1964), G. crassicaudatus (Gerard & Herlant, Reference Gerard and Herlant1953), G. demidoffi (Gerard, Reference Gerard1932; Gerard & Herlant, Reference Gerard and Herlant1953; Petter-Rousseaux, Reference Petter-Rousseaux1962), and Perodicticus potto (Gerard & Herlant, Reference Gerard and Herlant1953), a prosimian lemuroide Loris tardigradus lydekkerianus (Rao, Reference Rao1927; Brambell, Reference Brambell1930) and in Daubentonia madagascariensis (Petter-Rousseaux & Bourliere, Reference Petter-Rousseaux and Bourliere1965). It has also been argued that new germ cells are formed by direct transformation of somatic cells of the germinal epithelium of the ovary (Gerard, Reference Gerard1920, Reference Gerard1932; Gerard & Herlant, Reference Gerard and Herlant1953; Rao, Reference Rao1927).

Later, in 1967, Ioannou examined ovaries from adult prosimians and noted that oogonia at interphase or in various stages of mitosis undoubtedly occurred in adult female Loris and Perodicticus species of Galago (Ioannou, Reference Ioannou1967). These findings and studies by Anand Kumar (Reference Anand Kumar1966) suggest that although few signs of mitotic activity were observed in ovaries from adult Loris, an examination of numerous ovaries from mature specimens of this species have shown that germ cells occur at all stages of mitosis. Oocytes at the successive stages of meiosis up to diplotene are also present, often in great numbers. While oogonia may occasionally be observed in the germinal epithelium, there is no reason to believe that such cells are derived from transformed epithelial cells. It is more likely that all germ cells in the adult prosimian ovary are derived from daughter cells of pre-existing oogonia, as is known to be the case for all other mammals studied (Franchi et al., Reference Franchi, Mandl, Zuckerman and Zuckerman1962). However, these findings are not currently relevant and are regarded as an exception to the rule.

The concept of neo-oogenesis resurfaced when the Johnson group proposed that mitotically active germ cells, which are capable of replacing oocytes lost through atresia and ovulation, are found in the ovaries of young and adult mice, thereby maintaining a stable pool of follicles (Johnson et al., Reference Johnson, Canning, Kaneko, Pru and Tilly2004). By counting follicles using mathematical models, it was estimated that up to 33% of immature follicles in adult mice are atretic at any given moment, which depletes the ovarian reserve in a shorter time than usually occurs. This discrepancy between the rate of follicle loss and the mouse reproductive life suggest the existence of an alternative source of oocytes. Using the Vasa markers MVH or Ddx4 (DEAD-box helicase 4), which are characteristic of the germline in all vertebrates, and SCP3 (synaptonemal complex protein 3), a marker of meiotic cells in the ovaries of young and adult mice, cells were identified in the OSE. Some MVH-positive cells were also positive for bromodeoxyuridine (BrdU), a synthetic nucleoside that is incorporated into the newly synthesized DNA of replicating cells and indicates cell division rather than DNA repair, suggesting that these cells may be able to support follicular renewal. Treatment with busulphan, a chemical widely used to specifically deplete germinal cells in their migration stage, revealed ovaries possess fewer than 5% of the primordial follicle pool present in non-treated ovaries. In addition, busulphan-exposed ovaries showed healthy maturing follicles with non-degenerative oocytes and corpus luteum indicative of ovulation. Finally, ovarian fragments of wild-type mice grafted into the ovarian cavity of transgenic mice expressing the reporter gene GFP (green fluorescent protein) resulted in oocytes that express GFP surrounded by wild-type granulosa cells not positive for GFP. Taken together, these results suggest the existence of GSCs in the adult mammalian ovary that maintain folliculogenesis during postnatal life (Johnson et al., Reference Johnson, Canning, Kaneko, Pru and Tilly2004; Skaznik-Wikiel et al., Reference Skaznik-Wikiel, Tilly, Lee, Niikura, Kaneko-Tarui, Johnson and Tilly2007; Hanna & Hennebold, Reference Hanna and Hennebold2014). Similarly, it has been demonstrated that an injection of the histone deacetylase trichostatin A rapidly and significantly increases the number of primordial follicles in young mice, young adults and adult females. These data identify epigenetic modification of chromatin structure as a key regulator for postnatal mammalian oogenesis. Furthermore, receptor signaling of RA and histone acetylation cooperatively interact to influence Stra8, which induces the expression of genes in meiosis that promote the formation of oocytes in adult mice (Wang & Tilly, Reference Wang and Tilly2010).

Using morphological characteristics, gene expression profiles and oestradiol synthesis, an in vitro study of embryonic stem cells (ESCs) from transgenic mice that express GFP indicated spontaneous generation of oocytes that remain enclosed within structures similar to developing ovarian follicles (Hübner et al., Reference Hubner, Fuhrmann, Christenson, Kehler, Reinbold, De La Fuente, Wood, Strauss, Boiani and Scholer2003). Subsequent work confirmed these findings, revealing that oocytes fail to progress through meiosis and are therefore incompetent for fertilization (Novak et al., Reference Novak, Lightfoot, Wang, Eriksson, Mahdy and Höög2006). Despite these results, the failure to overcome the defect in meiosis may be resolved in a matter of time, and these experiments establish a starting point, as the possibility of deriving viable sperm from ESCs has been reported (Nayernia et al., Reference Nayernia, Nolte, Michelmann, Lee, Rathsack, Drusenheimer, Dev, Wulf, Ehrmann, Elliott, Okpanyi, Zechner, Haaf, Meinhardt and Engel2006).

Various research groups have corroborated the hypothesis of neo-oogenesis through the detection of key markers associated with pluripotency (Oct-3/4, Sox2 and Nanos), proliferation (BrdU), germline cells (Vasa, Fragillis, Stella, and Blimp1), and meiosis (DMCI: disrupted meiotic cDNA and SCP3) in cell groups in the peripheral region of the ovary. MVH protein localization identified the presence of GSCs in the OSE of mouse ovaries. In evaluating the potential proliferation of MVH-positive cells in 5-day-old neonatal and adult mice using BrdU markers, double-positive BrdU-MVH-stained cells were observed in the surface epithelium of the ovary. Based on this result, the double-positive cells were immuno-magnetically isolated and cultured for more than 15 months and cells from adult ovaries for more than 6 months. These cells were observed to retain high telomerase activity and normal karyotype activity during long-term culture; to express germline markers such as Oct-4, MVH, Dazl, Blimp-1, Fragillis, Stella and Rex-1; and not to express markers specific to oocytes such as c-Kit, Figla, Sox-1, Nanog, SCP1–3 and ZP3. The GSCs were labeled with a reporter gene (GFP) and were transplanted into mouse ovaries depleted of germ cells; GSCs experiencing oogenesis were detected and produced offspring expressing the GFP transgene (Zou et al., Reference Zou, Yuan, Yang, Luo, Sun, Zhou, Xiang, Shi, Yu, Zhang, Hou and Wu2009). Moreover, another report showed a population of pre-meiotic germ cells with elevated expression of the Stra8 and Dazl genes in the ovaries of OSE mice. Isolated cells marked with the GFP reporter gene retain the capacity to transform into oocytes after being transplanted into the ovaries of juvenile mice, thus increasing the expression of genes such as Oct-4, c-Kit, MVH and SSEA-1 (Niikura et al., Reference Niikura, Niikura and Tilly2009).

The purification and characterization of GSCs has been reported using transgenic mice that express GFP under the control of the Oct-4 promoter. Two cell populations were identified based on their distribution and size. The first population was composed of small cells (10–15 μm) in the OSE, and the second was observed to have larger cells (50–60 μm) morphologically similar to oocytes (oocyte-like cells, OLCs) enclosed by follicular structures. Cells from the first group, or ovarian GSCs, maintained stem cell character and formed embryoid bodies presenting high telomerase activity and normal karyotypes after several stages (Pacchiarotti et al., Reference Pacchiarotti, Maki, Ramos, Marh, Howerton, Wong, Pham, Anorve, Chow and Izadyar2010). In addition to this, small round cells of unknown origin were observed among epithelial cells of OSE in adult human ovaries (Bukovsky et al., Reference Bukovsky, Svetlikova and Caudle2005; Virant-Klun et al., Reference Virant-Klun, Zech, Rozman, Vogler, Cvjeticanin, Klemenc, Malicev and Meden-Vrtovec2008). Later, these findings were confirmed in rabbit, sheep, monkey and menopausal women, in which were identified two populations of putative stem cells (PSCs), based on their distribution and size. The smaller cells (1–3 μm) expressed factors for pluripotency as Oct-4 and SSEA-4; whereas bigger cells (4–7 μm) showed cytoplasmic localization of Oct-4 and minimal expression of SSEA-4. The small cells were called very small embryonic-like stem cells (VSELs) because these cells express gene pluripotency (Oct-4A, Nanog, Sox2, TERT and Stat-3). After culture, these cells were able to differentiate into structures similar to oocytes (OLCs) and expressed c-Kit, Dazl, GDF-9, VASA and ZP4 (Ratajczak et al., Reference Ratajczak, Machalinski, Wojakowski, Ratajczak and Kucia2007; Parte et al., Reference Parte, Bhartiya, Telang, Daithankar, Salvi, Zaveri and Hinduja2011). VSELs are considered to be the descendants of embryonic epiblast derived pluripotency PGCs that while migrating along the dorsal mesentery to the genital ridge, also gets deposited in various somatic tissues (Ratajczak et al., Reference Ratajczak, Zuba-Surma, Wojakowski, Suszynska, Mierzejewska, Liu, Ratajczak, Shin and Kucia2014; Bhartiya et al., Reference Bhartiya, Parte, Patel, Sriraman, Zaveri and Hinduja2016), as in adult ovaries, bone marrow, peripheral blood and umbilical cord blood (Virant-Klun, Reference Virant-Klun2015). Follicle-stimulating hormone (FSH) stimulates the VSELs, leading to upregulation in Oct-4A and Nanog expression and promoting the proliferation of these cells in the OSE (Parte et al., Reference Parte, Bhartiya, Manjramkar, Chauhan and Joshi2013).

The search for a mechanism of neo-oogenesis in mammals has extended to domestic animals. In the pig model, experiments have suggested that skin cells from fetal pigs maintained in vitro can generate oocytes contained in small follicle-like structures (Dyce & Li, Reference Dyce and Li2006). These presumed germ cells, formed from stem cells in the skin, manifest a meiotic blockage but coordinate the formation of follicular structures capable of secreting significant levels of oestradiol in basal conditions and in response to FSH treatment. Previous studies have also reported that potential oocytes expelled from the follicle-like structures have very similar characteristics to those of ovulated oocytes, with a structure much like the zona pellucida and the interaction and penetration of sperm (Dyce et al., Reference Dyce, Wen and Li2006). Another report mentioned that it is possible to isolate oogonial stem cells (OSCs), named for their expression of transcription factors such as Oct-3/4, Nanog and Sox2, among newborn piglets. In vitro, these cells showed a high capacity to differentiate into oocytes and OLCs, which express Vasa, Dazl and ZPC (Song et al., Reference Song, Kumar, Kang, Lee, Kim, Ock, Lee, Jeon and Rho2011). In female adult pigs, putative stem cells (PSCs) in the ovary were isolated and characterized based on their capacity for in vitro proliferation and differentiation. PSCs are found in a heterogeneous population in terms of size and have affinity for pluripotent stem cell markers, such as Oct-4 and SSEA4, and germ cell markers, such as Fragillis and c-Kit. Molecular analysis of PSCs indicated that these cells undergo a cytoplasmic–nuclear translocation of Oct-4 similarly to gonadal PGCs. Thus, the cells with PGCs characteristics are present or generated in the ovaries of adult pigs, maintain their identity as germ cells under in vitro conditions, and reach a difference in OLCs in appropriate culture conditions (Bui et al., Reference Bui, Van Thuan, Kwon, Choi, Kang, Han, Kim and Kim2014). The authors also suggest that PSCs can be generated from VSELs stem cells as proposed by others.

Isolated ovarian GSCs from neonatal and adult mouse ovaries and expanded them in the same culture conditions as embryonic stem cells (ESCs), were called female germline stem cells (FGSC). The FGSCs formed compact round colonies with unclear borders, maintained ESC characteristics and alkaline phosphatase (AP) activity, expressing germ cell marker Vasa, and stem cell markers: Oct4, Klf4, C-myc, Nanog, CD49f, Sox2, CD133, SSEA1 and SSEA4. These cells had the ability to form embryoid bodies (EBs), which expressed specific markers for all three germ layers. Then it was induced EBs to differentiate into neurons, cardiomyocytes, pancreatic cells and germ cells, which showed the expression of specific markers, β-III-tubulin, cardiac a-actin, Pdx1 and Zps respectively (Hu et al., Reference Hu, Bai, Chu, Wang, Wang, Yu and Hua2012).

The presence of GSCs with mitotically activity has found in adult mouse ovaries and human ovarian cortical tissue in which a gene expression profile is consistent with pluripotency primitive germ cells (Blimp1, Stella, Fragillis, Ddx4 and Dazl, Oct-4, Nanog, and Sox2). In vitro, these cells can be expanded for months and spontaneously generate oocytes. Injection of the human germline cells, engineered to stably express GFP, into human ovarian cortical biopsies leads to formation of follicles containing GFP-positive oocytes after xenotransplantation into immunodeficient female mice. Thus, ovaries of reproductive-age women, similar to adult mice, possess rare mitotically active germ cells that can be propagated in vitro as well as generate oocytes in vitro and in vivo (White et al., Reference White, Woods, Takai, Ishihara, Seki and Tilly2012).

Esmaeilian and colleagues reported in ovaries from pre-puberty and adult old mice, the expression of Sox2, Nanog and Oct-4 genes. Oct-4 and Nanog were found to be significantly differentiated between 2-week-old and 8-week-old old mice, whereas no significant difference was observed in the expression level of Sox2. However, the positive expression of Sox2 and Oct-4 protein was detected in the cytoplasm of ovarian epithelial cells, granulosa cells, oocytes and theca cells. Meanwhile, Nanog protein was observed only in the nucleus of the oocytes and it expression was higher in old ovaries. Thus, the authors suggest that pre-puberty and adult mice ovaries harboring cells with stem cells features arguing that the cytoplasmic expression of Oct-4 and Sox2 are translocated into the cytoplasm to the nucleus using a nuclear localization sequence and proceed in the opposite direction through the nuclear export sequence (Whiteside & Goodbourn, Reference Whiteside and Goodbourn1993; Esmaeilian et al., Reference Esmaeilian, Gur Dedeoglu, Atalay and Erdemli2012; Esmaeilian et al., Reference Esmaeilian, Atalay and Erdemli2015).

Wild animals have also been used as study models for defining the existence of the neo-oogenesis mechanism. A report on three species of phyllostomid bats (Artibeus jamaicensis, Glossophaga soricina and Sturnira lilium) revealed that the ovarian morphology in the three species is similar, clearly distinguishing a cortical region towards the exterior formed by a dense stroma of connective tissue that contains the ovarian follicles in various stages of development, each containing an oocyte and an internal medullar region formed of blood vessels supplying the ovary and mesenchymal cells. A small group of cells identified in the cortical region showed very similar characteristics to PGCs, including expression of specific cell markers of the germline (Fragillis, Stella, Vasa and c-Kit), stem cells (Oct-4) and cell proliferation (pH3). Thus, these cells have been called adult cortical germ cells (ACGCs). These results suggest that progenitor cells from the germline form the adult ovary in the phyllostomid bats and that the self-renewal of the germline is a possible function of progenitor cells (Antonio-Rubio et al., Reference Antonio-Rubio, Porras-Gómez and Moreno-Mendoza2013).

Human OSE, previously known as germinal epithelium, as this site was thought to serve as the origin of germ cells during embryonic development, has become very important for identifying GSCs. It was thought that the OSE might be the reservoir of undifferentiated cells capable of developing new cells. In this respect, the formation of new primordial follicles has been reported to develop with the accumulation of oocytes with nests of primitive granulosa cells in the ovarian cortex.

Research by Virant-Klun has provided surprising results and much encouragement for women who have fertility problems. This research described the presence of cells with characteristics similar to germline cells in the OSE of infertile women without oocytes and therefore without follicles. In these experiments, OSE of postmenopausal women and young women with premature ovarian failure were scraped, and PSCs with characteristics of germline OLCs that spontaneously generated the capacity to form blastocyst-like structures in vitro were isolated (Virant-Klun et al., Reference Virant-Klun, Zech, Rozman, Vogler, Cvjeticanin, Klemenc, Malicev and Meden-Vrtovec2008, Reference Virant-Klun, Rozman, Cvjeticanin, Vrtacnik-Bokal, Novakovic, Rülicke, Dovc and Meden-Vrtovec2009). The authors also mentioned that these cells express some pluripotency markers, such as Oct-4, Sox2, Nanog, SSEA-4, Klf4 and c-Myc, just after scraping and during cultivation (Virant-Klun et al., Reference Virant-Klun, Skutella, Stimpfel and Sinkovec2011a). In the OSE of adult women diagnosed with serous papillary adenocarcinoma, the expression of pluripotency (SSEA-4 and Sox2) and germline (Vasa and ZP2) markers was detected (Virant-Klun et al., Reference Virant-Klun, Skutella, Cvjeticanin, Stimpfel and Sinkovec2011b). Later, this same group published a report on the isolation of SSEA-4-positive cells from the OSE of adult females using two strategies: magnetic activated cell sorting and FACS (Virant-Klun et al., Reference Virant-Klun, Skutella, Hren, Gruden, Cvjeticanin, Vogler and Sinkovec2013a; Virant-Klun et al., Reference Virant-Klun, Stimpfel, Cvjeticanin, Vrtacnik-Bokal and Skutella2013b). Immunohistochemistry showed that these small PSCs express the major markers of pluripotency (Oct-4A, Sox2, SSEA-4, Sall4, Cdh1 and Lefty1) and PGC markers (Prdm1, Prdm14 and Dppa3). The finding of Prdm1 is critical because is the determining gene for PGCs, plays an important role in tandem with Prdm14 for specifying the PGCs in the epiblast and is critical to the maintenance of unipotent germ cells (Bao et al., Reference Bao, Leitch, Gillich, Nichols, Tang, Kim, Lee, Zwaka, Li and Surani2012; Esmaeilian et al., Reference Esmaeilian, Atalay and Erdemli2015). In vitro, these cells develop as OLCs in the presence of follicular fluid and express marker characteristics for oocytes (ZP3, SCP3 and c-Kit) (Virant-Klun et al., Reference Virant-Klun, Skutella, Hren, Gruden, Cvjeticanin, Vogler and Sinkovec2013a, Reference Virant-Klun, Skutella, Kubista, Vogler, Sinkovec and Meden-Vrtovec2013c).

Despite evidence indicating the existence of GSCs and thus the capacity of the ovaries to produce and maintain a stable number of oocytes throughout adulthood, a question remains: why do women go through menopause? It is thought that women enter menopause when the finite supply of oocytes is exhausted. However, the existence of GSCs and the concept of neo-oogenesis do not match what happens physiologically in adult women. The justification for this discrepancy is that GSCs, like many other cells, undergo an aging process and thus lose their capacity to regenerate and differentiate. Other alternatives to this idea have been proposed. One of these arguments is that there must be some fault in the cascade of genetic and/or hormonal signaling that does not permit GSCs to differentiate into oocytes. Other alternatives are that the differentiated somatic environment does not provide the right atmosphere to trigger the development of oocytes, the GSCs do not work properly, or that no environment allows their proper differentiation (Monget et al., Reference Monget, Bobe, Gougeon, Fabre, Monniaux and Dalbies-Tran2012). Another is that GSCs do not exist in the adult ovary. This last explanation has had more recognition, and greater numbers of arguments demonstrate this point, as we shall see in the next section.

In summary, this evidence suggests the existence of stem cells of the germline in the postnatal mammalian ovary. However physiological relevance, ovarian function and its possible role in maintaining fertility are still unclear, and it leaves major questions to be determined. Although controversy still exists today on the biological significance of these cells, identification and isolation clearly represents a significant advance for reproductive biology, running as an attractive method for infertility (Hummitzsch et al., Reference Hummitzsch, Anderson, Wilhelm, Ji Wu, Telfer, Russell, Robertson, Raymond and Rodgers2015).

Arguments against neo-oogenesis

Despite the reports that corroborate the mechanism of neo-oogenesis, there are those that deny its existence because of an inability to identify and/or corroborate the published data supporting neo-oogenesis. In this regard, recent research has opened perspectives to discuss the importance of the initial follicle pool in fertility in female adult mammals. Utilizing a mathematical model of the dynamics of follicle progression, the Bristol-Gould group examined whether the initial follicle pool is sufficient for adult fertility through reproductive senescence in mice. Establishing two mechanisms: an initial pool of primordial follicles as the only follicle source (fixed pool model) and an initial primordial follicle pool supplemented by GSCs (stem cell model), they found that the stem cell model failed to describe the observed decreases in follicles over time and did not parallel the accumulation and subsequent reduction in primary follicles during the early fertile lifespan of the mouse. Thus, they concluded that the initial endowment of ovarian follicles is not supplemented by an appreciable number of stem cells; rather, the initial pool of oocytes is sufficient to ensure the fertility of the adult female mouse, and that the loss of follicle in mouse ovary is not a stochastic process regulated both prior to puberty and again in the adult life (Bristol-Gould et al., Reference Bristol-Gould, Kreeger, Selkirk, Kilen, Mayo, Shea and Woodruff2006). Faddy & Gosden showed that female mammals produce a limited number of oocytes, however the authors mention that the absence of evidence is not evidence of absence, the inference that total and primordial follicle numbers behave postnatally as if there is no renewal and only depletion would seem entirely reasonable, is what the statistics say (Faddy & Gosden, Reference Faddy and Gosden2009).

Likewise, the absence of expression of early genes of meiosis, such as Spo11, Prdm9, SCP1–3, and DMC1, for germ cell development Oct-3/4, c-Kit, Vasa and Nobox and for proliferation TERT, PCNA and Ki-67, in healthy human ovaries between 28 and 53 years has been reported, concluding that neo-oogenesis does not take place in the adult human ovary (Liu et al., Reference Liu, Wu, Lyu, Yang, Albertini, Keefe and Liu2007). Other studies that were designed to confirm the circulation of oocyte stem cells in the blood and their capacity to migrate to the ovary and form new follicles have not produced evidence to support this hypothesis (Begum et al., Reference Begum, Papaioannou and Gosdem2008). Similarly, the Zhang group reported that it was not possible to identify the presence of Ddx4-positive germ cells or gene transcription related to SCP1, SCP3 and Spo11 meiotic activity in the OSE of adult rats (Zhang et al., Reference Zhang, Lv and Xing2010). Later, this same group showed Ddx4-expressing cells in postnatal mouse ovaries; however, these cells were not able to divide mitotically or contribute to oocyte formation, arguing against previous results (Zhang et al., Reference Zhang, Zheng, Shen, Adhikari, Ueno and Liu2012). In this respect and in support of the arguments against neo-oogenesis, it has also been reported that it is not possible to confirm the existence of GSCs through histological studies or the expression of markers of pluripotent cells and germ cells (SSEA-4, Oct-4 and Nanog) in the postnatal human ovary during the first 2 years of life (Byskov et al., Reference Byskov, Høyer, Yding Andersen, Kristensen, Jespersen and Møllgård2011). Similarly, reports by Kerr and colleagues investigated the hypothesis that adult mice have the capacity to generate new oocytes by monitoring primordial follicle numbers throughout postnatal life and following depletion of the primordial follicle reserve by exposure to doxorubicin (DXR), trichostatin A (TSA), or whole-body γ-irradiation, in adult C57BL/6 mice between the ages of 25 and 100 days. After 2 days of treatment, primordial follicle numbers had declined to 65 with DXR and 51% with TSA, with no restoration of follicle numbers evident after 7 days for either treatment. The ovaries from mice sterilizing with γ-irradiation (0.45 or 4.5 Gy) revealed complete ablation of all primordial follicles 5 days after treatment, no indication of follicular renewal. Finally, we conclude that neo-folliculogenesis does not occur following chemical or γ-irradiation mediated depletion of the primordial follicle reserve (Kerr et al., Reference Kerr, Brogan, Myers, Hutt, Mladenovska, Ricardo, Hamza, Scott, Strasser and Findlay2012).

Other studies denying the existence of GSCs and neo-oogenesis in vivo, except in adult mouse ovaries, were made by Lei & Spradling (Reference Lei and Spradling2013). They measured the follicular stability in mice at 4 weeks of age by administering low doses of tamoxifen (Tmx) and analysing the ovaries at various periods by cutting them into series at each time point and estimating the total number of follicles. All germ cells appeared to be oocytes within follicles based on morphological criteria, clarifying that morphology was insufficient to rule out primordial follicles and germ cells in a state of pre-follicular development. They also calculated the volume of follicles by plotting Log10 [primordial follicles yellow fluorescent protein (YFP) +/ovary] over time. The slope indicated that individual follicles are slowly flushed out within a half-life (t½) of 11 months, confirming that the pool of primordial follicles together manifests stably with a half-life of 10 months. This finding suggested that there is a marked follicular stability between primordial follicles and the total number of primordial follicles and no significant production of new primordial follicles. Subsequently, the ovaries of females treated with Tmx were analysed. The number of YFP-positive cells was assessed in comparison with E10.5 embryos, in which 100% of PGCs were proliferating, and with adult male mice 4 weeks of age, in which 100% of testes showed clusters of cells marked with YFP (CGSs, spermatogonial germ cells). However, after evaluating 1000 germ cells in adult females treated with Tmx, germ cells marked on or adjacent to the surface of the ovary were never observed, indicating that the marking system functioned properly, as somatic (granulosa) cells were observed to be YFP-positive. They concluded that, together, these experimental results rule out the existence of GSCs in adult ovaries because direct measurements showed that the primordial follicles are highly stable and invalidate the inference that thousands of adult primordial follicles flow out each month. They also claimed that marked follicles are lost at the same rate as total follicles, negating the existence of a source of new follicles in adulthood. Finally, as additional evidence, they referred to the follicles produced during fetal development, which are sufficiently stable to meet all requirements in adult life (Lei & Spradling, Reference Lei and Spradling2013). Parallel to these investigations, Yuan and colleagues did not identify proliferating cells or gene expression of pluripotency markers, such as Sox2 and Lin28, or the germline markers Vasa and Dazl in adult ovaries of rhesus monkeys and mice. Unexpectedly, cells with characteristics of somatic stem cells but not germline cells were found in adult ovaries (Yuan et al., Reference Yuan, Zhang, Wang, Liu, Mao, Yin, Ye, Liu, Han, Gao, Cheng, Keefe and Liu2013).

With the continued publication of reports for and against possible neo-oogenesis, a final consensus on whether the mechanism of neo-oogenesis or, likewise, GSCs exist in the ovaries of adult mammals has not yet been reached. The existence of this mechanism remains unknown and still requires much more work to fully prove or disprove the notion that mammalian ovaries have cells with characteristics similar to the PGCs that can be stimulated to enter a differentiation process for the generation of new oocytes.

Studies that support and reject the role of an extra-gonadal source of germline stem cells in neo-oogenesis during adulthood

It has been suggested that GSCs that cause oocytes to emerge in postnatal stages reside in extra-gonadal reservoirs, meaning that these cells originate outside the ovary, then migrate in an undifferentiated state and when they reach the adult ovary they begin their process of differentiation and commitment towards oocytes, thus compensating for any follicles lost during each ovulatory cycle.

Reports published so far have suggested that the bone marrow acts as the GSC reservoir. This idea was derived from the fact that during early embryogenesis the hematopoietic cells and germ cells originate in the same region, so in adult life they can be found in the same niche (Johnson et al., Reference Johnson, Bagley, Skaznik-Wikiel, Lee, Adams, Niikura, Tschudy, Tilly, Cortes, Forkert, Spitzer, Iacomini, Scadden and Tilly2005b; Hanna & Hennebold, Reference Hanna and Hennebold2014). The expression of germline markers has been localized, such as Ddx4, Dazl, Stella and Fragillis in bone marrow cells and interestingly Ddx4 expression appears to fluctuate in coordination with the estral cycle of the individual and is absent in ovariectomized females. Experiments on the ovarian follicles of chemically depleted mice, subject to bone marrow transplantation, revealed follicle formation after treatment. These results were confirmed employing Atm mutant mice (mutated ataxia telangiectasia), which are infertile as they do not have the ability to produce mature germ cells, and thus do not develop oocytes. Once bone marrow transplantation had been performed, the formation of follicles was identified. These findings led to the hypothesis that GSCs reside in the bone marrow and travel through the peripheral blood to colonize the ovary (Johnson et al., 2005). To test this theory, this group used Atm mice and mice that were germ cell deficient, due to chemotherapy. Both models were given a peripheral blood transfusion from a transgenic mouse (GFP), resulting in the detection of MVH-expressing GFP oocytes (Vasa homolog gene), HDAC6 (histone deacetylase 6) and NOBOX (homeobox protein NOBOX, also known as newborn ovary homeobox protein), concluding that the GSCs are derived from the bone marrow and circulate via blood.

An analogous work derived from the same Johnson group showed that germ cell conditioned mice and monthly infusions of bone marrow-derived cells from young adult females bearing the GFP reporter gene were able to sustain the fertility potential of the recipient individual, extending its timespan until reproductive senescence (Selesniemi et al., Reference Selesniemi, Lee, Niikura and Tilly2009). Contrastingly, when evaluating the reproductive capacity of females treated with cytotoxic chemicals to eliminate germ cells, they observed that mice that were undergoing chemotherapy were infertile. In contrast, mice that received a bone marrow transplant achieved term pregnancies. In comparison, there was a slight reduction in the number of offspring per litter among mice undergoing non-lethal treatment (busulfan 12 mg/kg, cyclophosphamide 120 mg/kg) plus transplantation compared with untreated controls. Although bone marrow transplantation reactivated long-term fertility in treated organisms, all offspring produced by these animals were derived from the recipient's own germ cells as all offspring were GFP negative. Therefore, the effects of bone marrow transplantation do not appear to have any positive effects on the re-establishment of germ cells, the authors proposed that the transplant acted as a chemotherapy protector and not as an activator of neo-oogenesis (Lee et al., Reference Lee, Selesniemi, Niikura, Niikura, Klein, Dombkowski and Tilly2007). These results further increased mistrust in the theory of neo-ovogenesis, and criticisms soon emerged. One of the first works that questioned the results obtained by Johnson and colleagues (2005), which related bone marrow transplantation to restoration of fertility, was that of Eggan et al. (Reference Eggan, Jurga, Gosden, Min and Wagers2006). This study involved parabiosis experiments with wild-type mice and GFP transgenic mice to determine whether circulating GSCs derived from bone marrow could cause oocytes to originate in the ovary. By surgically joining blood vessels at around 4–8 weeks of age, they observed that the highest level of peripheral blood chimerism is 65% for GFP-positive leukocytes on both sides, 6–8 months post-surgery. Although ovulation occurred in both groups, no chimeric oocytes were detected, although GFP-positive cells were occasionally observed in the wild-type mouse group. Following treatment with cyclophosphamide and busulfan, administered 1 day prior to surgical union of blood vessels in wild-type mice, they observed a high leukocyte chimerism in blood and bone marrow but not in oocytes; however these mice manifested ovulation at around 2 weeks or 2 months after surgery. They therefore concluded that any fertility post- treatment could be attributed to follicles not affected by chemotherapy that made it possible to re-establish the number of follicles. This was corroborated by mice that were treated but surgically unattached, which showed the presence of follicles in reduced numbers, indicating incomplete oocyte ablation (Eggan et al., Reference Eggan, Jurga, Gosden, Min and Wagers2006).

In order to test if oocyte progenitor cells circulate in the blood and are able to migrate to the ovary and form new follicles, they performed a positive GFP blood transfusion in wild-type ovaries. An examination of oocytes present in ovarian grafts found no evidence to support this hypothesis (Begum et al., Reference Begum, Papaioannou and Gosdem2008). Finally, a further report (Santiquet et al., Reference Santiquet, Vallières, Pothier, Sirard, Robert and Richard2012) that refuted the presence of GSCs in bone marrow and peripheral blood was obtained for SCDI mice, treated with chemical agents. When analysing embryonic ovarian cortex grafts there was no evidence that transplanted bone marrow cells resulted in new oocytes. However, they suggested that transplanted bone marrow cells improve fertility in SCID mice, positively influencing ovarian physiology.

The role of epigenetic mechanisms during oogenesis and neo-oogenesis

With the advent of epigenetics, some of the biochemical and cellular pathways that led to some developmental abnormalities caused by changes in chromatin have been determined that in turn control differential gene expression by DNA methylations and histone alterations. Currently, the epigenetic pathways that regulate the development of ovogenesis have been described, and disturbances associated with this process have been shown to damage postnatal health causing infertility (Bromfield et al., Reference Bromfield, Messamore and Albertini2008).

Epigenetics has reinforced the idea of a Lamarckian evolutionary principle because environmental conditions have led to marked changes in gene expression during mammalian development (Bromfield et al., Reference Bromfield, Messamore and Albertini2008). Any stress factor that affects the embryo during development may influence gene expression and thus disrupt competency for embryo development. Changes in the state of intracellular redox will alter the expression of oxygen-sensitive genes (Harvey et al., Reference Harvey, Kind and Thompson2007), while exposure to environmental toxins will alter gene expression and capacity for embryonic developmental (Susiarjo et al., Reference Susiarjo, Hassold, Freeman and Hunt2007).

The production of fertility-competent oocytes results from good coordination between folliculogenesis and ovogenesis, a good balance of cellular interactions between the somatic and germinal components, as well as hormonal interactions and growth factors involved in the pituitary–hypothalamic–gonad axis (Combelles et al., Reference Combelles, Carabatsos, Kumar, Matzuk and Albertini2004). However, alterations in somatic physiology can affect the quality of the oocytes depending on the stage of development affected; fetal, prepubertal or adult (Bromfield et al., Reference Bromfield, Messamore and Albertini2008). Considering epigenetic regulation at a more subtle but equally important level, molecular mediators have been identified to fulfill a crucial catabolic function, in many systems. Relevant epigenetic factors in oocytes include: cMOS (r), which participates in the arrest of meiosis II and whose absence deregulates the cell cycle; E-cadherin (p), which is involved in the compaction of chromatin, whose absence causes damage to lineage assignment; NMP2 (p), which influences pronuclear maturation, whose absence causes delay in the cell cycle; and Dmnt1o (p), which is important for the methylation of chromatin and whose deficiency causes modifications in methylation; and γ-tubulin (P), also important for mitosis, as its absence results in arrest of the cell cycle. Key factors in the cell cycle assume a non-random location in order to generate fast and complete effects, ensuring the synchronized activation of the kinase and ubiquitination, for an opportune entry into the M cell phase and to ensure its exit. In contrast, the centrosomes work by limiting the diffusion capacity of components involved in the progression of the cell cycle, as the complexity of these factors or molecules are directed and maintained in the centers of microtubule organization (COMT). Finally, the spindle serves to harbor and stabilize many factors that are involved in timely cyclin degradation that provokes the metaphase–anaphase transition, during the M phase (Carmo-Fonseca et al., Reference Carmo-Fonseca, Mendes-Soares and Campos2000). Specific interactions between the cytoskeleton and other organelles, mRNAs and proteins can be localized and stabilized together for post-translational modification (revised by Bromfield et al., Reference Bromfield, Messamore and Albertini2008). Advancement in this developing area has led to the proposal of epigenetic mechanisms that may possibly be associated with neo-ovogenesis process.

It has been suggested that ovogenesis can be induced in adult females with the inhibitors histone deacetylases (HDAC) and trichostatin A (tSA), indicating that the acetylation status of histones can determine whether germ cells enter meiosis (Johnson et al., Reference Johnson, Bagley, Skaznik-Wikiel, Lee, Adams, Niikura, Tschudy, Tilly, Cortes, Forkert, Spitzer, Iacomini, Scadden and Tilly2005b). This work provided a precept for further investigation into epigenetic regulation and how this may influence the production of oocytes during adult life. It is generally known that the meiotic cell cycle is activated by the expression of Stra8, which is induced by retinoic acid (RA) in fetal stages of development. The suppression of meiosis in male germ cells is caused by the expression of CYP26B1. When male embryonic germ cells were exposed to the class I/II inhibitors histone deacetylases (HDAC) and trichostatin A (tSA), premature activation of Stra8 was induced and therefore entry into meiosis without altering expression of CYP26B1 took place. However, the most important finding in terms of neo-ovogenesis was the physiological detection of Stra8 in ovaries of adult mice.

The induction of ovogenesis in adult females using TSA is associated with the activation of Stra8, enabling reproduction of the results with the use of HDAC inhibitor, suberoilanilida of hydroxamic acid (SAHA). This finding indicates that retinoic acid receptor and histone acetylation signaling interact cooperatively to influence Stra8 expression, which promotes the formation of oocytes in adult mice. The ability of RA to induce Stra8 expression is epigenetically controlled by co-activators upstream of RARE. Finally, the authors conclude that these events not only coordinate entry of meiosis during embryogenesis, but also contribute significantly to the regulation of ovogenesis in adult mammalian females (Wang & Tilly, Reference Wang and Tilly2010). Another explanation of how epigenetics can influence the production of oocytes, maintaining a stable number in adult life, indicates that this is a function of the ovarian reserve. Primordial or non-growth follicles (NGFs) are the functional unit for reproduction, constituting the ovarian reserve (OR). The dynamics of the reserve are determined by the number of NGFs formed and their subsequent destinations. During reproductive life, OR progressively decreases due to follicular atresia, as well as recruitment, maturation and ovulation. OR depletion is controlled by the menopause, when the number of primordial follicles falls below a threshold of ~1000. It is thus important to know the genes and processes involved in the development of OR (Pelosi et al., Reference Pelosi, Forabosco and Schlessinger2015).

Studies have shown that OR increases dramatically from 15 weeks post-conception to 34 weeks, remaining constant, with an average of 680,000 NGF, up to the first 2 years after birth (Block, Reference Block1953; Forabosco & Sforza, Reference Forabosco and Sforza2007; Hansen et al., Reference Hansen, Knowlton, Thyer, Charleston, Soules and Klein2008). In postnatal life, data show considerable variability between 7 and 12 years, thus no figure has been established, although limited reduction has been observed. An average of ~460,000 follicles are still present at puberty; between 12 and 14 years of age (Block, Reference Block1952; Hansen et al., Reference Hansen, Knowlton, Thyer, Charleston, Soules and Klein2008). From this moment, OR reduce continually until menopause down to <1000 NGF (Block, Reference Block1952; Richardson et al., Reference Richardson, Senikas and Nelson1987; Gougeon et al, Reference Gougeon, Ecochard and Thalabard1994; Hansen et al., Reference Hansen, Knowlton, Thyer, Charleston, Soules and Klein2008) revised by Pelosi et al. (Reference Pelosi, Forabosco and Schlessinger2015). Changes in follicular dynamics may result from the influence of genetic and/or environmental factors that modify the formation of new NGF or the recruitment of NGF for maturation or atresia (Kerr et al, Reference Kerr, Myers and Anderson2013).

Conclusions

The controversy surrounding the existence of GSCs in adult mammals continues, thus accurate and reproducible results are necessary to demonstrate the existence of the mechanism of neo-oogenesis. If results are attained, GSCs could be used in a clinical context, promoting their isolation, growth and differentiation to provide a novel method for treating female infertility. Finally, after the review of positions both for and against the existence of a mechanism of neo-oogenesis (Table 1 and 2), whether there are cells capable of producing new oocytes in adult mammalian ovaries remains unknown. Therefore, the debate concerning the existence of GSCs in the ovary is not resolved. Before accepting or denying the existence of a mechanism of neo-oogenesis, several pieces of evidence must be provided: irrefutable results showing the existence of GSCs in the adult mammalian ovary, an indication of whether this phenomenon is a generality or represents only certain exceptions in nature; determination of whether this condition is beneficial or detrimental in evolutionary terms; and scientific characterization of GSC existence by their morphology and genetics to determine whether these GSCs play an important physiological role.

Table 1 Experimental works that uphold the existence of a mechanism of neo-ovogenesis in adult mammalian females

Table 2 Experimental works that refute the existence of a mechanism of neo-ovogenesis in adult mammalian females

Abbreviations

ACGCs, adult cortical germ cells; AR, retinoic acid; BrdU, 5-bromo-2-bromodesoxiuridina; ESCs, embryonic stem cells; FACS, fluorescence activated cell sorting; FSH, follicle-stimulating hormone; GFP, green fluorescent protein; GREL, gonadal ridge epithelial-like; GSCs, germ stem cells; OLCs, oocyte-like cells; OSCs, oogonial stem cells; OSE, ovarian surface epithelium; PCNA, proliferating cell nuclear antigen; PGCs, primordial germ cells; PSCs, putative stem cells; SSCs, spermatogonial stem cells; Tmx, tamoxifen; VSELs, very small embryonic-like stem cells; YFP, yellow fluorescent protein.

Acknowledgements

This paper was supported by UNAM-DGAPA-PAPIIT IN205515.

Competing interests

The authors declare that they have no competing interests.

Author contributions

Both authors contributed to design of the study, manuscript writing and conception and final design.

References

Allen, E. (1923). Ovogenesis during sexual maturity. Am. J. Anat. 31, 439–81.CrossRefGoogle Scholar
Allen, E. & Creadick, R.N. (1937). Ovogenesis during sexual maturity. The first stage, mitosis in the germinal epithelium, as shown by the colchicine technique. Anat. Rec. 69, 191–5.Google Scholar
Anand Kumar, T.C. (1966). Effects of sex-steroids on the reproductive organs of the female Loris. (Abstract.) Proceedings of the Second International Congress on Hormonal Steroids, Milan.Google Scholar
Antonio-Rubio, N.R., Porras-Gómez, T.J. & Moreno-Mendoza, N. (2013). Identification of cortical germ cells in adult ovaries from three phyllostomid bats: Artibeus jamaicensis, Glossophaga soricina and Sturnira lilium . Reprod. Fertil. Dev. 25, 825–36.Google Scholar
Bao, S., Leitch, H.G., Gillich, A., Nichols, J., Tang, F., Kim, S., Lee, C., Zwaka, T., Li, H. & Surani, M.A. (2012). The germ cell determinant Blimp1 is not required for derivation of pluripotent stem cells. Cell. Stem Cell. 11, 110–7.CrossRefGoogle Scholar
Begum, S., Papaioannou, V.E. & Gosdem, R.G. (2008). The oocyte population is not renewed in transplanted or irradiated adult ovaries. Hum. Reprod. 23, 2326–30.Google Scholar
Bhartiya, D., Sriraman, K., Gunjal, P. & Modak, H. (2012). Gonadotropin treatment augments postnatal oogenesis and primordial follicle assembly in adult mouse ovaries? J. Ova. Res. 5, 32.Google Scholar
Bhartiya, D., Sriraman, K., Parte, S. & Patel, H. (2013). Ovarian stem cells: absence of evidence is not evidence of absence. J. Ova. Res. 6, 65.CrossRefGoogle Scholar
Bhartiya, D., Parte, S., Patel, H., Sriraman, K., Zaveri, K. & Hinduja, I. (2016). Novel action of FSH on stem cells in adult mammalian ovary induces postnatal oogenesis and primordial follicle assembly. Stem Cells Int. 2016, doi: 10.1155/2016/5096596. Epub ahead of print.Google Scholar
Block, E. (1952). Quantitative morphological investigations of the follicular system in women; variations at different ages. Acta Anat. 14, 108–23.Google Scholar
Block, E. (1953). Quantitative morphological investigations of the follicular system in newborn female infants. Acta Anat. 17, 201–6.Google Scholar
Bowles, J. & Koopman, P. (2007). Retinoic acid, meiosis and germ cell fate in mammals. Development 134, 3401–11.CrossRefGoogle ScholarPubMed
Brambell, F.W.R. (1930). The Development of Sex in Vertebrates. London: Sidgwick and Jackson.Google Scholar
Brinster, R.L. (2007). Male germline stem cells: from mice to men. Science 316, 404–5.Google Scholar
Bristol-Gould, S.K., Kreeger, P.K., Selkirk, C.G., Kilen, S.M., Mayo, K.E., Shea, L.D. & Woodruff, T.K. (2006). Fate of the initial follicle pool: empirical and mathematical evidence supporting its sufficiency for adult fertility. Dev. Biol. 298, 149–54.Google Scholar
Bromfield, J., Messamore, W., Albertini, D.F. (2008). Epigenetic regulation during mammalian oogenesis. Reprod. Fertil. Dev. 20, 7480.Google Scholar
Bui, H.T., Van Thuan, N., Kwon, D.N., Choi, Y.J., Kang, M.H., Han, J.W., Kim, T. & Kim, J.H. (2014). Identification and characterization of putative stem cells in the adult pig ovary. Development 141, 2235–44.CrossRefGoogle ScholarPubMed
Bukovsky, A. & Caudle, M.R. (2012). Immunoregulation of follicular renewal, selection, POF, and menopause in vivo, vs. neo-oogenesis in vitro, POF and ovarian infertility treatment, and a clinical trial. Reprod. Biol. Endocrinol. 10, 97.Google Scholar
Bukovsky, A., Caudle, M.R., Svetlikova, M. & Upadhyaya, N.B. (2004). Origin of germ cells and formation of new primary follicles in adult human ovaries. Reprod. Biol. Endocrinol. 2, 20.Google Scholar
Bukovsky, A., Svetlikova, M. & Caudle, R. (2005). Oogenesis in cultures derived from adult human ovaries. Reprod. Biol. Endocrinol. 3, 17.Google Scholar
Butler, H. (1964). The reproductive tract of a strepsirhine (Galago senegalensis senegalensis). In International Review of General and Experimental Zoology, vol. I (eds Felts, W.J.L. & Harrison, R.J.). New York and London: Academic Press.Google Scholar
Byskov, A.G., Høyer, P.E., Yding Andersen, C., Kristensen, S.G., Jespersen, A. & Møllgård, K. (2011). No evidence for the presence of oogonia in the human ovary after their final clearance during the first two years of life. Hum. Reprod. 26, 2129–39.Google Scholar
Carmo-Fonseca, M., Mendes-Soares, L. & Campos, I. (2000). To be or not to be in the nucleolus. Nat. Cell Biol. 2, E107–12.Google Scholar
Chiquoine, A.D. (1954). The identification, origin and migration of the primordial germ cells in the mouse embryo. Anat. Rec. 118, 135–46.CrossRefGoogle ScholarPubMed
Combelles, C.M., Carabatsos, M.J., Kumar, T.R., Matzuk, M.M. & Albertini, D.F. (2004). Hormonal control of somatic cell oocyte interactions during ovarian follicle development. Mol. Reprod. Dev. 69, 347–55.Google Scholar
Crone, M., Levy, E. & Peters, H. (1965). The duration of the premeiotic DNA synthesis in mouse oocytes. Exp. Cell. Res. 39, 678–88.CrossRefGoogle ScholarPubMed
David, G.F., Anand Kumar, T.C. & Baker, T.G. (1974). Uptake of tritiated thymidine by primordial germinal cells in the ovaries of the adult slender Loris . J. Reprod. Fertil. 41, 447651.Google Scholar
Ding, X., Liu, G., Xu, B., Wu, C., Hui, N., Ni, X., Wang, J., Du, M., Teng, X. & Wu, J. (2016). Human GV oocytes generated by mitotically active germ cells obtained from follicular aspirates. Sci. Rep. 6, 28218.Google Scholar
Downs, S.M. (2010). Regulation of the G2/M transition in rodent oocytes. Mol. Reprod. Dev. 77, 566–85.CrossRefGoogle ScholarPubMed
Duke, K.L. (1967). Ovogenetic activity of the fetal-type in the ovary of the adult slow loris, Nycticebus coucang. Folia primatologica; Inter. J. Primatol. 7, 150254.Google Scholar
Dyce, P.W. & Li, J. (2006). From skin cells to ovarian follicles? Cell Cycle 5, 1371–5.Google Scholar
Dyce, P.W., Wen, L. & Li, J. (2006). In vitro germline potential of stem cells derived from fetal porcine skin. Nat. Cell Biol. 8, 384–90.Google Scholar
Eggan, K., Jurga, S., Gosden, R., Min, I.M., Wagers, A.J. (2006). Ovulated oocytes in adult mice derive from non-circulating germ cells. Nature 441, 1109–14.Google Scholar
Esmaeilian, Y., Gur Dedeoglu, B., Atalay, A. & Erdemli, E. (2012). Investigation of stem cells in adult and prepuberal mouse ovaries. Adv. Biosci. Biotechnol. 3, 936–44.Google Scholar
Esmaeilian, Y., Atalay, A. & Erdemli, E. (2015). Post-natal oogenesis: a concept for controversy that intensified during the last decade. Zygote. 23, 315–26.CrossRefGoogle ScholarPubMed
Ewen, K.A, & Koopman, P. (2010). Mouse germ cell development: from specification to sex determination. Mol. Cell. Endocrinol. 323, 7693.Google Scholar
Faddy, M. & Gosden, R. (2009). Let's not ignore the statistics. Biol. Reprod. 81, 231–2.Google Scholar
Forabosco, A. & Sforza, C. (2007). Establishment of ovarian reserve: a quantitative morphometric study of the developing human ovary. Fertil. Steril. 88, 675–83.Google Scholar
Franchi, L.L., Mandl, A.M. & Zuckerman, S. (1962). The development of the ovary and the process of oogenesis. In The Ovary (ed. Zuckerman, S.), pp. 188. London: Academic Press.Google Scholar
Gerard, P. (1920). Contribution à l'etude de l'ovaire des mammiferes. L'ovaire de Galago mossambicus (Young). Archs. Biol. 20, 357–91.Google Scholar
Gerard, P. (1932). Etudes sur l'ovogenese et Tontogenese chez les lemuriens du genre Galago. Archs. Biol. 43, 93151.Google Scholar
Gerard, P. & Herlant, M. (1953). Persistence of phenomena of oogenesis in adult lemurians. Archs. Biol. 64, 97111.Google Scholar
Ginsburg, M., Snow, M.H. & McLaren, A. (1990). Primordial germ cells in the mouse embryo during gastrulation. Development 110, 521–8.Google Scholar
Gong, S.P., Lee, S.T., Lee, E.J., Kim, D.Y., Lee, G., Chi, S.G., Ryu, B.K., Lee, C.H., Yum, K.E., Lee, H.J., Han, J.Y., Tilly, J.L. & Lim, J.M. (2010). Embryonic stem cell-like cells established by culture of adult ovarian cells in mice. Fertil. Steril. 93, 2594–601.Google Scholar
Gosden, R.G. (2013). Oocyte development and loss. Semin. Reprod. Med. 3, 393–8.Google Scholar
Gougeon, A., Ecochard, R. & Thalabard, J.C. (1994). Age-related changes of the population of human ovarian follicles: increase in the disappearance rate of non-growing and early-growing follicles in aging women. Biol. Reprod. 50, 653–63.Google Scholar
Griswold, M.D., Hogarth, C.A., Bowles, J. & Koopman, P. (2012). Initiating meiosis: the case for retinoic acid. Biol. Reprod. 86, 35.Google Scholar
Guo, K., Li, CH., Wang, X.Y., He, D.J. & Zheng, P. (2016). Germ stem cells are active in postnatal mouse ovary under physiological conditions. Mol. Hum. Reprod. 22, 316– 28.Google Scholar
Hanna, C.B. & Hennebold, J.D. (2014). Ovarian germline stem cells: an unlimited source of oocytes? Fertil. Steril. 101, 2030.Google Scholar
Hansen, K.R., Knowlton, N.S., Thyer, A.C., Charleston, J.S., Soules, M.R. & Klein, N.A. (2008). A new model of reproductive aging: the decline in ovarian non-growing follicle number from birth to menopause. Hum. Reprod. 23, 699708.Google Scholar
Harvey, A.J., Kind, K.L. & Thompson, J.G. (2007). Regulation of gene expression in bovine blastocysts in response to oxygen and the iron chelator desferrioxamine. Biol. Reprod. 77, 93101.Google Scholar
Herlant, M. (1961). L'activite genitale chez la femelle de Galago senegalensis moholi (Geoffr.) et ses rapports avec la persistance de phenomenes d'ovogenese chez l'adulte. Ann. Soc. Roy. Zool. 91, 115.Google Scholar
Hilscher, B., Hilscher, W., Bulthoff-Ohnolz, B., Kramer, U., Birke, A., Pelzer, H. & Gauss, G. (1974). Kinetics of gametogenesis. I. Comparative histological and autoradiographic studies of oocytes and transitional prospermatogonia during oogenesis and prespermatogenesis. Cell Tissue Res. 154, 443–70.Google Scholar
Hu, Y., Bai, Y., Chu, Z., Wang, J., Wang, L., Yu, M. & Hua, J. (2012). GSK3 inhibitor-BIO regulates proliferation of female germline stem cells from the postnatal mouse ovary. Cell. Prolif. 45, 287–98.Google Scholar
Hubner, K., Fuhrmann, G., Christenson, L.K., Kehler, J., Reinbold, R., De La Fuente, R., Wood, J., Strauss, J.F. 3rd, Boiani, M. & Scholer, H.R. (2003). Derivation of oocytes from mouse embryonic stem cells. Science 300, 1251–6.CrossRefGoogle ScholarPubMed
Hummitzsch, K., Anderson, R.A., Wilhelm, D., Ji Wu, J., Telfer, E.E., Russell, D.L., Robertson, S.A. & Raymond, J. Rodgers, R.J. (2015). Stem cells, progenitor cells, and lineage decisions in the ovary. Endocr. Rev. 36, 6591.Google Scholar
Ioannou, J.M. (1967). Oogenesis in adult prosimians. J. Embryol. Exp. Morphol. 17, 139–45.Google Scholar
Johnson, J., Canning, J., Kaneko, T., Pru, J.K. & Tilly, J.L. (2004). Germline stem cells and follicular renewal in the postnatal mammalian ovary. Nature. 428, 145–50.Google Scholar
Johnson, J., Skaznik-Wikiel, M., Lee, H.J., Niikura, Y., Tilly, J.C. & Tilly, J.L. (2005a). Setting the record straight on data supporting postnatal oogenesis in female mammals. Cell Cycle 4, 1471–7.Google Scholar
Johnson, J., Bagley, J., Skaznik-Wikiel, M., Lee, H-J., Adams, G.B., Niikura, Y., Tschudy, K.S., Tilly, J.C., Cortes, M.L., Forkert, R., Spitzer, T, Iacomini, J., Scadden, D.T. & Tilly, J.L. (2005b). Oocyte generation in adult mammalian ovaries by putative germ cells derived from bone marrow and peripheral blood. Cell 122, 303– 15.Google Scholar
Kehler, J., Hübner, K. & Schöler, H.R. (2006). Derivation of germ cells from embryonic stem cells. Ernst Schering Res. Found Workshop. 2006, 125–42.Google Scholar
Kerr, J.B., Duckett, R., Myers, M., Britt, K.L., Mladenovska, T. & Findlay, J.K. (2006). Quantification of healthy follicles in the neonatal and adult mouse ovary: evidence for maintenance of primordial follicle supply. Reproduction 132, 95109.Google Scholar
Kerr, J.B., Brogan, L., Myers, M., Hutt, K.J., Mladenovska, T., Ricardo, S., Hamza, K., Scott, C.L., Strasser, A. & Findlay, J.K. (2012). The primordial follicle reserve is not renewed after chemical or γ-irradiation mediated depletion. Reproduction 143, 469–76.Google Scholar
Kerr, J. B., Myers, M. & Anderson, R.A. (2013). The dynamics of the primordial follicle reserve. Reproduction 146, R205–15.CrossRefGoogle ScholarPubMed
Kingery, H.M. (1917). Oogenesis in the white mouse. J. Morphol. 30, 261315.CrossRefGoogle Scholar
Koubova, J., Menke, D.B., Zhou, Q., Capel, B., Griswold, M.D. & Page, D.C. (2006). Retinoic acid regulates sex-specific timing of meiotic initiation in mice. Proc. Natl. Acad. Sci. USA 103, 2474–9.CrossRefGoogle ScholarPubMed
Koubova, J., Hu, Y.C., Bhattacharyya, T., Soh, Y.Q., Gill, M.E., Goodheart, M.L., Hogarth, C.A., Griswold, M.D. & Page, D, C. (2014). Retinoic acid activates two pathways required for meiosis in mice. PLoS Genet. 10, e1004541.Google Scholar
Lee, H.J., Selesniemi, K., Niikura, Y., Niikura, T., Klein, R., Dombkowski, D.M. & Tilly, J.L. (2007). Bone marrow transplantation generates immature oocytes and rescues long-term fertility in a preclinical mouse model of chemotherapy-induced premature ovarian failure. J. Clin. Oncol. 25, 3198–204.Google Scholar
Lei, L. & Spradling, A.C. (2013). Female mice lack adult germ-line stem cells but sustain oogenesis using stable primordial follicles. Proc. Natl. Acad. Sci. USA 110, 8585–90.Google Scholar
Leitch, H.G., Tang, W.W. & Surani, M.A. (2013). Primordial germ-cell development and epigenetic reprogramming in mammals. Curr. Top. Dev. Biol. 104, 149–87.Google Scholar
Li, R. & Albertini, D.F. (2013). The road to maturation: somatic cell interaction and self-organization of the mammalian oocyte. Nat. Rev. Mol. Cell. Biol. 14, 141–52.Google Scholar
Liang, L., Soyal, S.M. & Dean, J. (1997). FIGalpha a germ cell specific transcription factor involved in the coordinate expression of the zona pellucida genes. Development 124, 4939–47.Google Scholar
Liu, Y., Wu, C., Lyu, Q., Yang, D., Albertini, D.F., Keefe, D.L. & Liu, L. (2007). Germline stem cells and neo-oogenesis in the adult human ovary. Dev. Biol. 306,112–20.Google Scholar
Molyneaux, K.A., Stallock, J., Schaible, K. & Wylie, C. (2001). Time-lapse analysis of living mouse germ cell migration. Dev. Biol. 240, 488–98.CrossRefGoogle ScholarPubMed
Monget, P., Bobe, J., Gougeon, A., Fabre, S., Monniaux, D. & Dalbies-Tran, R. (2012). The ovarian reserve in mammals: a functional and evolutionary perspective. Mol. Cell. Endocrinol. 356, 212.Google Scholar
Mu, X., Wen, J., Guo, M., Wang, J., Li, G., Wang, Z., Wang, Y., Teng, Z., Cui, Y. & Xia, G. (2013). Retinoic acid derived from the fetal ovary initiates meiosis in mouse germ cells. J. Cell. Physiol. 228, 627–39.Google Scholar
Nayernia, K., Nolte, J., Michelmann, H.W., Lee, J.H., Rathsack, K., Drusenheimer, N., Dev, A., Wulf, G., Ehrmann, I.E., Elliott, D.J., Okpanyi, V., Zechner, U., Haaf, T., Meinhardt, A., Engel, W. (2006). In vitro-differentiated embryonic stem cells give rise to male gametes that can generate offspring in mice. Dev. Cell. 11, 125–32.CrossRefGoogle Scholar
Niikura, Y., Niikura, T. & Tilly, J.L. (2009). Aged mouse ovaries possess rare premeiotic germ cells that can generate oocytes following transplantation into a young host environment. Aging 1, 971–8.Google Scholar
Norris, R.P., Freudzon, M., Mehlmann, L.M., Cowan, A.E., Simon, A.M., Paul, D.L., Lampe, PD, & Jaffe, L.A. (2008). Luteinizing hormone causes MAP kinase-dependent phosphorylation and closure of connexin 43 gap junctions in mouse ovarian follicles: one of two paths to meiotic resumption. Development 135, 3229–38.Google Scholar
Novak, I., Lightfoot, D.A., Wang, H., Eriksson, A., Mahdy, E. & Höög, C. (2006). Mouse embryonic stem cells form follicle-like ovarian structures but do not progress through meiosis. Stem Cells 24, 1931–6.Google Scholar
Oatley, J. & Hunt, P.A. (2012). Of mice and (WO) men: purified oogonial stem cells from mouse and human ovaries. Biol. Reprod. 86, 196.Google Scholar
Pacchiarotti, J., Maki, C., Ramos, T., Marh, J., Howerton, K., Wong, J., Pham, J, Anorve, S., Chow, Y.C. & Izadyar, F. (2010). Differentiation potential of germ line stem cells derived from the postnatal mouse ovary. Differentiation 79, 159–70.Google Scholar
Park, J.Y., Su, Y.Q., Ariga, M., Law, E., Jin, S.L. & Conti, M. (2004). EGF-like growth factors as mediators of LH action in the ovulatory follicle. Science 303, 682–4.Google Scholar
Park, E.S., Woods, D.C. & Tilly, J.L. (2013) Bone morphogenetic protein 4 promotes mammalian oogonial stem cell differentiation via Smad1/5/8 signaling. Fertil. Steril. 100, 1468–75.Google Scholar
Parte, S., Bhartiya, D., Telang, J., Daithankar, V., Salvi, V., Zaveri, K. & Hinduja, I. (2011). Detection, characterization, and spontaneous differentiation in vitro of very small embryonic-like putative stem cells in adult mammalian ovary. Stem Cell Dev. 20, 1451–64.CrossRefGoogle ScholarPubMed
Parte, S., Bhartiya, D., Manjramkar, D.D., Chauhan, A. & Joshi, A. (2013). Stimulation of ovarian stem cells by follicle stimulating hormone and basic fibroblast growth factor during cortical tissue culture. J. Ova. Res. 6, 20.CrossRefGoogle ScholarPubMed
Patel, H., Bhartiya, D., Parte, S., Gunjal, P., Yedurkar, S. & Bhatt, M. (2013). Follicle stimulating hormone modulates ovarian stem cells through alternatively spliced receptor variant FSH-R3. J. Ova. Res. 6, 52.Google Scholar
Pearl, R. & Schoppe, W.F. (1921). Studies on the physiology of reproduction in the domestic fowl. XVIII. Further observations on the anatomical basis of fecundity. J. Exp. Zool. 34, 100–18.Google Scholar
Pelosi, E., Forabosco, A. & Schlessinger, D. (2015). Genetics of the ovarian reserve. Front. Genet. 6, 308.CrossRefGoogle ScholarPubMed
Peters, H., Leavy, E. & Crone, M. (1962). Deoxyribonucleic acid synthesis in oocytes of mouse embryos. Nature 195, 915–6.Google Scholar
Petter-Rousseaux, A. (1962). Recherches sur la biologie de la reproduction des primates inferieurs. Mammalia 26, 187.Google Scholar
Petter-Rousseaux, A. & Bourliere, F. (1965). Persistance des phenomenes d'ovogenese chez l'adulte de Daubentonia madagascariensis (Prosimii, Lemuriformes). Folia Primat. 3, 241–5.Google Scholar
Rajkovic, A., Pangas, S.A., Ballow, D., Suzumori, N. & Matzuk, M.M. (2004). NOBOX deficiente disrupts early folliculogenesis and oocyte-specification gene expression. Science 305, 1157–9.Google Scholar
Ratajczak, M.Z., Machalinski, B., Wojakowski, W., Ratajczak, J. and Kucia, M.A. (2007). A hypothesis for an embryonic origin of pluripotent Oct4-4+ stem cells in adult bone marrow and other tissues. Lukemia 21, 860–67.Google Scholar
Ratajczak, M.Z., Zuba-Surma, E., Wojakowski, W., Suszynska, M., Mierzejewska, K., Liu, R., Ratajczak, J., Shin, D.M. and Kucia, M. (2014). Very small embryonic-like stem cells (VSELs) represent a real challenge in stem cell biology: recent pros and cons in the midst of a lively debate. Leukemia 28, 473–84.Google Scholar
Rao, C.R.N. (1927). On the structure of the ovary and ovarian ovum of Loris lydekkerianus . Quart. J. Micr. Sci. 71, 5774.Google Scholar
Regaud, C. (1901). Etudes sur la structure des tubes seminiferes et sur la spermatogenese chez les mammiferes. Part 1.Archives d'Anatomie microscopiques et de Morphologie experimentale. 4, 101–56.Google Scholar
Richardson, S.J., Senikas, V. & Nelson, J.F. (1987). Follicular depletion during the menopausal transition: evidence for accelerated loss and ultimate exhaustion. J. Clin. Endocrinol. Metab. 65, 1231–7.CrossRefGoogle ScholarPubMed
Saitou, M. & Yamaji, M. (2012). Primordial germ cells in mice. Cold Spring Harb. Perspect. Biol. 4, pii: a008375 Google Scholar
Saitou, M., Barton, S.C. & Surani, M.A. (2002). A molecular programme for the specification of germ cell fate in mice. Nature 418, 293300.Google Scholar
Sanchez, F. & Smitz, J. (2012). Molecular control oogenesis. Biochim. Biophys. Acta 12, 1896–912.Google Scholar
Santiquet, N., Vallières, L., Pothier, F., Sirard, M.A., Robert, C. & Richard, F. (2012). Transplanted bone marrow cells do not provide new oocytes but rescue fertility in female mice following treatment with chemotherapeutic agents. Cell Reprogram. 14, 123–9.CrossRefGoogle Scholar
Sasaki, H. & Matsui, Y. (2008). Epigenetic events in mammalian germ-cell development: reprogramming and beyond. Nat. Rev. Genet. 9, 129–40.Google Scholar
Selesniemi, K., Lee, H.J., Niikura, T. & Tilly, J.L. (2009). Young adult donor bone marrow infusions into female mice postpone age-related reproductive failure and improve offspring survival. Aging (Albany NY). 1, 4957.Google Scholar
Skaznik-Wikiel, M., Tilly, J.C, Lee, H.J, Niikura, Y., Kaneko-Tarui, T., Johnson, J. & Tilly, J.L. (2007). Serious doubts over ‘Eggs forever? Differentiation. 75, 93–9.Google Scholar
Song, S.H., Kumar, B.M., Kang, E.J., Lee, Y.M., Kim, T.H., Ock, S.A., Lee, S.L., Jeon, B.G. & Rho, G.J. (2011). Characterization of porcine multipotent stem/stromal cells derived from skin, adipose and ovarian tissues and their differentiation in vitro into putative oocyte-like cells. Stem Cell Dev. 20, 1359–70.Google Scholar
Speed, R.M. (1982). Meiosis in the foetal mouse ovary. I. An analysis at the light microscope level using surface-spreading. Chromosoma 85, 427–37.Google Scholar
Sriraman, K., Bhartiya, D., Anand, S. & Bhutda, S. (2015). Mouse ovarian very small embryonic-like stem cells resist chemotherapy and retain ability to initiate oocyte-specific differentiation. Reprod. Sci. 22, 884903 Google Scholar
Stimpfel, M., Skutella, T., Cvjeticanin, B., Meznaric, M., Dovc, P., Novakovic, S., Cerkovnik, P., Vrtacnik-Bokal, E. & Virant-Klun, I. (2013). Isolation, characterization and differentiation of cells expressing pluripotent/multipotent markers from adult human ovaries. Cell Tissue Res. 354, 593607 Google Scholar
Susiarjo, M., Hassold, T.J., Freeman, E. & Hunt, P.A. (2007). Bisphenol A exposure in utero disrupts early oogenesis in the mouse. PLoS Genet. 3, e5.Google Scholar
Szotek, P.P., Chang, H.L., Brennand, K., Fujino, A., Pieretti-Vanmarcke, R., Lo Celso, C., Dombkowski, D., Preffer, F., Cohen, K.S., Teixeira, J. & Donahoe, P.K. (2008). Normal ovarian surface epithelial label-retaining cells exhibit stem/progenitor cell characteristics. Proc. Natl. Acad. Sci. USA 105, 12469–73.Google Scholar
Vanni, V.S., Viganò, P., Papaleo, E., Mangili, G., Candiani, M. & Giorgione, V. (2017). Advances in improving fertility in women through stem cell-based clinical platforms. Expert Opin. Biol. Ther. 17, 585–93.Google Scholar
Virant-Klun, I. (2015). Postnatal oogenesis in humans: a review of recent findings. Stem Cell Cloning 20, 4960.Google Scholar
Virant-Klun, I., Zech, N., Rozman, P., Vogler, A., Cvjeticanin, B., Klemenc, P., Malicev, E. & Meden-Vrtovec, H. (2008). Putative stem cells with an embryonic character isolated from the ovarian surface epithelium of women with no naturally present follicles and oocytes. Differentiation 76, 843–56.Google Scholar
Virant-Klun, I., Rozman, P., Cvjeticanin, B., Vrtacnik-Bokal, E., Novakovic, S., Rülicke, T., Dovc, P. & Meden-Vrtovec, H. (2009). Parthenogenetic embryo-like structures in the human ovarian surface epithelium cell culture in postmenopausal women with no naturally present follicles and oocytes. Stem Cells Dev. 18, 137–49.Google Scholar
Virant-Klun, I., Skutella, T., Stimpfel, M. & Sinkovec, J. (2011a). Ovarian surface epithelium in patients with severe ovarian infertility: a potential source of cells expressing markers of pluripotent/multipotent stem cells. J. Biomed. Biotechnol. 2011, 381928.Google Scholar
Virant-Klun, I., Skutella, T., Cvjeticanin, B., Stimpfel, M. & Sinkovec, J. (2011b) Serous papillary adenocarcinoma possibly related to the presence of primitive oocytes-like cell in the adult ovarian Surface epithelium: a case report. J. Ova. Res. 4, 13.Google Scholar
Virant-Klun, I., Skutella, T., Hren, M., Gruden, K., Cvjeticanin, B., Vogler, A. & Sinkovec, J. (2013a). Isolation of small SSEA-4-positive putative stem cells from the ovarian surface epithelium of adult human ovaries by two different methods. Biomed. Res. Int. 2013, 690415.Google Scholar
Virant-Klun, I., Stimpfel, M., Cvjeticanin, B., Vrtacnik-Bokal, E. & Skutella, T. (2013b). Small SSEA-4-positive cells from human ovarian cell cultures: related to embryonic stem cells and germinal lineage? J. Ova. Res. 6, 24.Google Scholar
Virant-Klun, I., Skutella, T., Kubista, M., Vogler, A., Sinkovec, J. & Meden-Vrtovec, H. (2013c) Expression of pluripotency and oocyte-related genes in single putative stem cells from human adult ovarian surface epithelium cultured in vitro in the presence of follicular fluid. Biomed. Res. Int. 2013, 861460.Google Scholar
Waldeyer-Hartz, W.V. (1980). Eierstock und Ei Ein Beitrag zur Anatomie und Entwicklungsgeschichte der Sexualorgane. Leipzig: Engelmann. [In German].Google Scholar
Wang, N. & Tilly, J.L. (2010). Epigenetic status determines germ cell meiotic commitment in embryonic and postnatal mammalian gonads. Cell Cycle 9, 339–49.CrossRefGoogle ScholarPubMed
Western, P.S., van den Bergen, J.A., Miles, D.C. & Sinclair, A.H. (2010). Male fetal germ cell differentiation involves complex repression of the regulatory network controlling pluripotency. FASEB J. 24, 3026–35.Google Scholar
White, Y.A., Woods, D.C., Takai, Y., Ishihara, O., Seki, H. & Tilly, J.L. (2012). Oocyte formation by mitotically active germ cells purified from ovaries of reproductive-age women. Nat. Med. 18, 413–21.Google Scholar
Whiteside, S.T. & Goodbourn, S. (1993). Signal transduction and nuclear targeting: regulation of transcriptional factor activity by subcellular localization. J. Cell. Sci. 1993 104, 949–55.Google Scholar
Yuan, J., Zhang, D., Wang, L., Liu, M., Mao, J., Yin, Y., Ye, X., Liu, N., Han, J., Gao, Y., Cheng, T., Keefe, D.L. & Liu, L. (2013). No evidence for neo-oogenesis may link to ovarian senescence in adult monkey. Stem Cells 31, 2538–50.Google Scholar
Zhang, D., Fouad, H., Zoma, W.D., Salama, S.A., Wentz, M.J. & Al-Hendy, A. (2008). Expression of stem and germ cell markers within nonfollicle structures in adult mouse ovary. Reprod. Sci. 15, 139–46.CrossRefGoogle ScholarPubMed
Zhang, P, Lv, L.X. & Xing, W.J. (2010). Early meiotic specific protein expression in post-natal rat ovaries. Reprod. Domest. Anim. 45, e447–53.Google Scholar
Zhang, H., Zheng, W., Shen, Y., Adhikari, D., Ueno, H. & Liu, K. (2012). Experimental evidence showing that no mitotically active female germline progenitors exist in postnatal mouse ovaries. Proc. Natl. Acad. Sci. USA 109, 12580–5.Google Scholar
Zhang, H., Liu, L., Li, X., Busayavalasa, K., Shen, Y., Hovatta, O., Gustafsson, J.Å. & Liu, K. (2014). Life-long in vivo cell-lineage tracing shows that no oogenesis originates from putative germline stem cells in adult mice. Proc. Natl. Acad. Sci. USA 111, 17983–8.Google Scholar
Zhang, H., Panula, S., Petropoulos, S., Edsgärd, D., Busayavalasa, K., Liu, L., Li, X., Risal, S., Shen, Y., Shao, J., Liu, M., Li, S., Zhang, D., Zhang, X., Gerner, R.R., Sheikhi, M., Damdimopoulou, P., Sandberg, R., Douagi, I., Gustafsson, J.Å., Liu, L., Lanner, F., Hovatta, O. & Liu, K. (2015). Adult human and mouse ovaries lack DDX4-expressing functional oogonial stem cells. Nat. Med. 21, 1116–8.Google Scholar
Zou, K., Yuan, Z., Yang, Z., Luo, H., Sun, K., Zhou, L., Xiang, J., Shi, L., Yu, Q, Zhang, Y., Hou, R. & Wu, J. (2009). Production of offspring from a germline stem cell line derived from neonatal ovaries. Nat. Cell. Biol. 11, 631–6.Google Scholar
Zuckerman, S. (1951). The number of oocytes in the mature ovary. Recent Prog. Horm. Res. 6, 63108.Google Scholar
Zuckerman, S. & Baker, T.G. (1977). The development of the ovary and the process of oogenesis. In The Ovary (ed. Zuckerman, S.), ch. 2, pp. 4159. London: Academic Press.Google Scholar
Figure 0

Table 1 Experimental works that uphold the existence of a mechanism of neo-ovogenesis in adult mammalian females

Figure 1

Table 2 Experimental works that refute the existence of a mechanism of neo-ovogenesis in adult mammalian females