Hostname: page-component-586b7cd67f-t7czq Total loading time: 0 Render date: 2024-11-25T22:12:35.179Z Has data issue: false hasContentIssue false

A rare case of intra-ovarian oocyte maturation

Published online by Cambridge University Press:  03 June 2024

Sara Jobson*
Affiliation:
Department of Ocean Sciences, Memorial University, St. John’s, Newfoundland and Labrador, Canada
Jean-François Hamel
Affiliation:
Society for the Exploration and Valuing of the Environment, St. Philips, Newfoundland and Labrador, Canada
Annie Mercier
Affiliation:
Department of Ocean Sciences, Memorial University, St. John’s, Newfoundland and Labrador, Canada
*
Corresponding author: Sara Jobson; Email: [email protected]
Rights & Permissions [Opens in a new window]

Summary

The intra-ovarian presence of ootids, i.e. female gametes that have completed meiosis, is considered exceptional in the animal kingdom. The present study explores the first such case to be reported in a sea cucumber (Echinodermata: Holothuroidea). In the overwhelming majority of animals, including holothuroids, oocytes (i.e. immature female gametes) that are developing in the ovary undergo a primary arrest at the prophase stage of meiosis, which may last from days to decades. In free-spawning taxa, this arrest is normally lifted only during or shortly before transit in the gonoduct, when gamete release (spawning) is imminent. However, oocytes of the holothuroid Chiridota laevis were discovered to have resumed the second meiotic division including the completion of germinal vesicle breakdown and polar-body expulsion inside the ovary, effectively reaching the ootid stage concomitantly with ovulation (i.e. escape from follicle cells) prior to spawning. The potential drivers and significance of this exceptionally rare case of full intra-ovarian oogenic maturation are discussed.

Type
Short Communication
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
© The Author(s), 2024. Published by Cambridge University Press

Introduction

The term oocyte refers to an immature female reproductive cell. Oocytes are generally embedded in follicle cells (FCs; which modulate both the hormonal control of meiotic maturation and nutrient requirements of growing oocytes), and they possess a germinal vesicle (GV), also called nucleus, surrounded by a nuclear envelope. The GV is large and spherical, containing chromatin (DNA) and a nucleolus (or several nucleoli). Primary oocytes are stored in the ovary while arrested in the first meiotic prophase in almost all animal species (Iwashita et al., Reference Iwashita, Hayano and Sagata1998). They can maintain this primary meiotic arrest for a period of days in insects to decades in humans while they grow and accumulate the necessary maternal products to support the eventual completion of meiosis, fertilization, and early development. Following this first pause in meiotic division, there is generally a subsequent arrest, which coordinates the completion of meiosis with fertilization, sometimes referred to as “egg activation”. Although the meiotic stage of this secondary arrest and the signalling pathways behind it vary among animal species (Delroisse et al., Reference Delroisse, Léonet, Alexandre and Eeckhaut2021; Jessus et al., Reference Jessus, Munro and Houliston2020; Russo et al., Reference Russo, Bilotto, Ciarcia and Tosti2009; Von Stetina and Orr-Weaver, Reference Von Stetina and Orr-Weaver2011), it is normally lifted by cues that are dependent on the presence of spermatozoa or fertilization itself (Nishiyama et al., Reference Nishiyama, Tachibana and Kishimoto2010). Hence, the universal pathway entails a long pause in the ovary where the oocyte grows, followed by a succession of quick maturation steps that unfold in a matter of minutes or hours when fertilization is imminent, whereby the oocyte is released from its matrix into the oviduct (ovulation) and final maturation halts again, briefly, until fertilization is completed (Figure 1A).

Figure 1. (A) Schematic illustration of the phases of oogenic maturation that are universal to most animals: primary oocytes are stored in the ovary where they grow (green rectangle); the onset of gamete release brings on cues that lift the first meiotic arrest, triggering GV breakdown (GVBD) and ovulation (transit into the oviduct; blue rectangle); a brief second meiotic arrest (occurring at various stages depending on the species, but commonly in metaphase of meiosis II) is lifted by presence of sperm or fertilization (purple rectangle). (B) Illustration of how the timing of oogenic maturation differs in echinoids, and now in C. laevis: the first and second meiotic arrests are lifted and GVBD occurs independently of spawning so that ovulated ootids are stored inside the ovary (green rectangle) long before release into the oviduct (blue rectangle) and fertilization (purple rectangle).

Unsurprisingly, the complex successive cellular and molecular mechanisms responsible for keeping meiotic progression on hold in females of most animals have fuelled prolific research (e.g. Filatov et al., Reference Filatov, Khramova and Semenova2018; Grossman et al., Reference Grossman, Har-Paz, Gindi, Levi, Miller, Nevo, Galiani, Dekel and Shalgi2017; Jessus et al., Reference Jessus, Munro and Houliston2020; Sen and Caiazza, Reference Sen and Caiazza2013; Von Stetina and Orr-Weaver, Reference Von Stetina and Orr-Weaver2011). While variants abound, true exceptions to this broadly defined oogenic pattern have only rarely been evidenced so far, such as the absence of secondary arrest in a terrestrial nematode (Von Stetina and Orr-Weaver, Reference Von Stetina and Orr-Weaver2011). The most fundamental known exception, which occurs in the echinoderm class Echinoidea (sea urchins), pertains to the timing of full oogenic maturation, i.e. the stage at which the female gametes are stored in the ovary prior to their release in the oviduct (Figure 1). Rather than primary oocytes with a prominent GV, the ripe ovary of females holds fully mature oocytes (i.e. ootids; Burke and Bouland, Reference Burke and Bouland1989) displaying the characteristic GV breakdown (GVBD). This characteristic allows investigators access to competent ootids that can be used in fertilization assays, which has made sea urchins easy to rear for studies in developmental biology (Mercier and Hamel, Reference Mercier and Hamel2009).

In the class Holothuroidea, as in most animal species, the primary oocytes are arrested naturally in the first meiotic prophase (Iwashita et al., Reference Iwashita, Hayano and Sagata1998), and resume maturation in response to mechanical (Hamel and Mercier, Reference Hamel and Mercier2007) and hormonal stimuli (Burke and Bouland, Reference Burke and Bouland1989; Masui, Reference Masui1985; Sagata, Reference Sagata1996) associated with the onset of a natural spawning event. Sequential in vivo study of the reproductive tract of a model species (Holothuria leucospilota) during natural spawning showed that ovulation occurred in the ovarian tubules at the onset of spawning and that the first sign of GVBD appeared during transit in the oviduct. The oocytes accumulated just underneath the genital papilla, in a bulge, and only became fully mature (fertilizable) after exposure to seawater (Hamel and Mercier, Reference Hamel and Mercier2007). In the context of sea cucumber aquaculture programmes, the need to bypass the vagaries of natural spawning to obtain ootids has emerged (Eriksson et al., Reference Eriksson, Robinson, Slater and Troell2012; Han et al., Reference Han, Keesing and Liu2016; Mercier and Hamel, Reference Mercier and Hamel2009; Purcell et al., Reference Purcell, Hair and Mills2012). Several factors, including temperature shocks, and exposure to phytoplankton, or air, have more or less effectively stimulated a proportion of exposed individuals (both males and females) to release their gametes, allowing researchers to have access to competent ootids to begin cultures (Battaglene et al., Reference Battaglene, Seymour, Ramofafia and Lane2002; Huang et al., Reference Huang, Huo, Yu, Ren, Jiang, Luo, Chen and Hu2018; Mercier and Hamel, Reference Mercier and Hamel2009; Morgan, Reference Morgan2000). Some investigators have tested various natural and synthetic compounds to induce the in vitro maturation of oocytes, replacing the necessity to wait for spawning altogether to obtain pools of fertilizable ootids (Burke and Bouland, Reference Burke and Bouland1989; Guerrier and Néant, Reference Guerrier and Néant1986; Hodin et al., Reference Hodin, Heyland, Mercier, Pernet, Cohen, Hamel, Allen, McAlister, Byrne, Cisternas and George2019; Iwashita et al., Reference Iwashita, Hayano and Sagata1998; Mercier and Hamel, Reference Mercier and Hamel2009; Néant et al., Reference Néant, Charbonneau and Guerrier1989).

Meanwhile, the occurrence of internally brooding echinoderms has raised questions related to the timing of GVBD and maturation to the ootid stage in these species, especially in intra-ovarian brooders of the Apodida order. For instance, Sewell (Reference Sewell1994) mentioned that unless fertilization in the brooding apodid Leptosynapta clarki was explored, its complete life-history strategy would not be understood. Turner (Reference Turner1973) had already suggested that fertilization in Synaptula hydriformis could either occur in the gonad or in the perivisceral cavity. Estabrooks (Reference Estabrooks1984) occasionally noted developing young in the gonad tubules, suggesting that fertilizable ootids were held in the same tubule as developing oocytes. But where and when GVBD occurs naturally, leading to the development of ootids, has remained unconfirmed. The present study provides evidence of complete oogenic maturation inside the ovary prior to spawning in the free-spawning apodid holothuroid Chiridota laevis. This report documents the first case of intra-ovarian oocyte maturation outside the echinoid class. The possible drivers and implications of this currently unique pathway are explored.

Materials and methods

Collection and holding

Adults of Chiridota laevis (Figure 2A) were collected in fall 2021–2023 in Tappers Cove, Newfoundland and Labrador, eastern Canada (47°38’59.61°N, 52°42’53.09°W). Individuals were hand-collected by divers at subtidal depths (5–7 m) and to minimize stress were transported at low densities inside large coolers filled with seawater. Individuals of C. leavis were held in 20 litre tanks (267 X 394 X 216 mm) covered with about 3 cm of mud to mimic the natural environment. Flow rate in the tanks was set to approximately 42 L h-1 allowing the water temperature to fluctuate naturally over the annual cycle between 0 and 9 °C, at a salinity around 35 psu, under natural photoperiod. Light intensity was kept below ≤200 lux and was provided through large windows. All individuals fed on naturally deposited particulate organic matter provided by the ambient unfiltered seawater.

Figure 2. (A) The sea cucumber Chiridota laevis. (B-C) Primary vitellogenic oocytes still in the ovarian tubules of C. laevis showing the germinal vesicle (GV) and nucleoli (N) as well as the follicle cells (FC). (D) Ootids in the ovarian tubules with completed ovulation, GV breakdown and expulsion of polar bodies. These ootids also demonstrate a clearly developed embryonic coating (E). (E) Ootids in the ovarian tubule, with the surrounding embryonic coating clearly visible (E) and no FCs. The scale bar represents 9 mm in A, 100 µm in B and 50 µm in C−E.

Dissection and microscopy

To assess their reproductive status, individuals of C. laevis (n = 25) were dissected in each season throughout the year with a particular focus during their suspected spawning season of late winter. Individuals were opened longitudinally, and the gonad tufts were removed at the base. To visualize gametes, several subsamples of gonad (n = 3−5) measuring ∼10 mm in length were placed on a microscope slide and examined under a stereoscope (Leica M205 using LASX software and a Leica DFC 7000T camera) and a compound light microscope (Nikon Eclipse 80i coupled to a digital Olympus DP73 camera).

Histology

To further assess the stage of gamete maturity, the rest of the gonad (not used for microscopy) was preserved in neutrally buffered formalin (4%) and processed for histology. Preserved tissues were washed in ethanol at three successive concentrations (70, 80 and 90%) and embedded in methacrylate resin. The methacrylate was left to polymerize for 12 h at 4°C. The methacrylate-embedded tissues were then sectioned (3 µm) using a Leica RM2165 automated microtome. Seven tissue sections were placed on each slide and stained with celestine-blue and eosin-phloxine. This resulted in the nuclei being stained blue and cytoplasmic inclusions being stained pink. To identify various stages of gametogenesis the slides were then viewed and photographed under a light microscope (Nikon Eclipse 80i) coupled to a digital camera (Olympus DP73).

Results and discussion

Sequential sampling of female gametes in the ovarian tubules of the apodid holothuroid Chiridota laevis revealed that ovulation, GVBD (Figure 1B; Figure 2B–E) and polar-body expulsions (Figure 2D) were all completed before the onset of spawning in this species. Immature oocytes were found in some individuals all year round, predominantly from March to July. Mature vitellogenic oocytes surrounded by FCs and with GV were visible in the ovary from July to January, whereas ovulation had occurred and ootids were present in February (Figure 2D–E). Residual unspawned ootids at different stages of degradation remained between March and September. Together, these findings indicate that, uncharacteristically, oocytes can reach full maturity and competency inside the ovary in the days to weeks prior to spawning. This intra-ovarian oogenic maturation strategy may have developed to allow fertilization to occur before the thick protective sticky coating solidifies just minutes after ootid expulsion (Figure 2D–E), following which external fertilization likely becomes impossible.

The present study suggests that the long arrest of oocyte maturation at the prophase stage of meiosis inside the ovary, followed by shorter secondary arrest in the oviduct or outside the body, is not as universal as previously documented. Intra-ovarian final maturation, despite not having been described outside Echinoidea, may in fact be more common than expected and deserves further investigation. No evidence supporting GVBD and polar-body expulsion had previously been presented in brooding holothuroids, or in free-spawning species like C. laevis. It would be valuable to verify whether the same occurs in some species of asteroids (sea stars) known to undergo fertilization directly in the ovary (Byrne and Cerra, Reference Byrne and Cerra1996) and in more species where female gametes develop a protective coating at the moment they are released into the environment.

Since the final meiotic maturation of oocytes in both echinoids and C. leavis occurs in the ovary, the primary triggers are likely internal factors (i.e. hormones or proteins; Hunt, Reference Hunt1989, Kanatani and Hiramoto, Reference Kanatani and Hiramoto1970, Kishimoto, Reference Kishimoto2011, Mayes, Reference Mayes2002). In contrast, other taxa of marine invertebrates (like most animals) have been shown to require the additional presence of external stimuli like spermatozoa or seawater (Goudeau and Goudeau, Reference Goudeau and Goudeau2002, Miller et al., Reference Miller, Nguyen, Lee, Kosinski, Schedl, Caprioli and Greenstein2001). There is also little known about the time frame of meiotic maturation in marine invertebrates, especially broadcast spawners like C. laevis and many echinoids. In broadcast-spawning species that rely on external cues, the final phase of oocyte maturation seemingly occurs in a relatively short time (e.g. 1–2 h in some asteroid species; Hunt, Reference Hunt1989, Voronina, Reference Voronina2003). In sea urchins that store pools of ootids, the delay between the lifting of meiotic arrest and the ootid has been shown to be 8 or more hours (Voronina, Reference Voronina2003). Here, the retrieval of gonad samples from individuals of C. laevis over several weeks leading up to the spawning season revealed ovarian tubules containing both mature oocytes with a prominent GV and ootids having completed meiotic maturation. This suggests that the final oocyte maturation process takes place over the span of weeks in the ovary, and that it may thus be more asynchronous than in echinoids, though the duration of an individual oocyte-ootid transition in C. laevis remains undetermined. In addition, the evolutionary implications of this asynchronous meiotic maturation strategy currently remain unclear and will require further research.

In closing, it should be noted that the uniqueness of the oogenic pathway described herein may not be immediately apparent due to inconsistent terminology used in reproductive biology, especially the (mis)use of the word egg/ovum. Case in point, reproductive research on humans and other mammals (chiefly the mouse model) commonly uses a different nomenclature where “egg” simply describes a cell found in the oviduct that can be fertilized to produce an embryo. This functional definition is deemed necessary to circumvent the fact that female mammals would otherwise not possess eggs (1N 1C cells), since fertilization is necessary to complete meiosis, i.e. the female haploid cell already contains the sperm genome (Duncan et al., Reference Duncan, Schindler, Schultz, Blengini, Stein, Stricker, Wessel and Williams2020). It has been suggested that the lack of a truly haploid phase in female mammals and the tight coupling between completion of oocyte meiosis and fertilization may be advantageous from an evolutionary perspective to reduce parthenogenesis (Duncan et al., Reference Duncan, Schindler, Schultz, Blengini, Stein, Stricker, Wessel and Williams2020). This may be equally true in most sexually reproducing animals. Thus, one interesting avenue of research for a unique pathway like the one seen in C. laevis, where true female haploid cells are produced long before fertilization, may be to explore its possible evolutionary link with self-fertilization in hermaphrodites and with modes of asexual reproduction like parthenogenesis.

Acknowledgements

We want to thank the divers of the Ocean Sciences Centre for their help with collections, as well as many members of the Mercier Lab for logistical support.

Author contributions

SJ contributed to the design, data collection, analysis and writing of the paper. J-FH contributed to the design, analysis and writing of the paper. AM contributed to the design, analysis and writing of the paper.

Funding

This work was conducted with the support of the Natural Sciences and Engineering Research Council of Canada in the form of a Discovery Grant to AM and doctoral scholarship to SJ.

Competing interests

All authors declare no competing interests.

Ethical standards

None.

References

Battaglene, S.C., Seymour, J.E., Ramofafia, C. and Lane, I. (2002) Spawning induction of three tropical sea cucumbers, Holothuria scabra, H. fuscogilva and Actinopyga mauritiana . Aquaculture 207, 2947.CrossRefGoogle Scholar
Burke, R.D. and Bouland, C. (1989) Pigmented follicle cells and the maturation of oocytes in the sand dollar Dendraster excentricus . Development, Growth & Differentiation 31, 431437.CrossRefGoogle ScholarPubMed
Byrne, M. and Cerra, A. (1996) Evolution of intragonadal development in the diminutive asterinid sea stars Patiriella vivipara and P. parvivipara with an overview of development in the Asterinidae. The Biological Bulletin 191, 1726.CrossRefGoogle Scholar
Delroisse, J.A., Léonet, A., Alexandre, H. and Eeckhaut, I. (2021) Intracellular pathways of holothuroid oocyte maturation induced by the Thioredoxin Trx-REES. Antioxidants 10, 12011216.CrossRefGoogle Scholar
Duncan, F.E., Schindler, K., Schultz, R.M., Blengini, C.S., Stein, P., Stricker, S.A., Wessel, G.M. and Williams, C.J. (2020) Unscrambling the oocyte and the egg: clarifying terminology of the female gamete in mammals. Molecular Human Reproduction 26, 797800.CrossRefGoogle Scholar
Eriksson, H., Robinson, G., Slater, M.J. and Troell, M. (2012) Sea cucumber aquaculture in the western Indian Ocean: challenges for sustainable livelihood and stock improvement. AMBIO 41, 109121.CrossRefGoogle Scholar
Estabrooks, W. (1984) Structure of the ovotestis and release of gametes of a coelomic-brooding sea cucumber, Synaptula hydriformis (Lesueur, 1824) (Echinodermata: Holothuroidea). Dissertation, Florida Institute of Technology, Melbourne, Florida.Google Scholar
Filatov, M., Khramova, Y. and Semenova, M. (2018) Molecular mechanisms of prophase I meiotic arrest maintenance and meiotic resumption in mammalian oocytes. Reproductive Sciences 26, 15191537.CrossRefGoogle Scholar
Goudeau, M. and Goudeau, H. (2002) Hg2+ affects the intracellular free Ca2+ oscillatory pattern and the correlated membrane conductance changes in Mg2+-stimulated oocytes of the prawn Palaemon serratus . Journal of Experimental Zoology 293, 111.CrossRefGoogle Scholar
Grossman, H., Har-Paz, E., Gindi, N., Levi, M., Miller, I., Nevo, N., Galiani, D., Dekel, N. and Shalgi, R. (2017) Regulation of GVBD in mouse oocytes by miR-125a-3p and Fyn kinase through modulation of actin filaments. Scientific Reports 7, 22382253.CrossRefGoogle ScholarPubMed
Guerrier, P. and Néant, I. (1986) Metabolic cooperation following fusion of starfish ootid and primary oocyte restores meiotic-phase-promoting activity. Proceedings of the National Academy of Sciences 83, 48144818.CrossRefGoogle ScholarPubMed
Hamel, J.-F. and Mercier, A. (2007) In vivo investigation of oocyte transit and maturation in a broadcast-spawning holothurian. Invertebrate Biology 126, 8189.CrossRefGoogle Scholar
Han, Q., Keesing, J.K. and Liu, D. (2016) A review of sea cucumber aquaculture, ranching, and stock enhancement in China. Reviews in Fisheries Science & Aquaculture 24, 326341.CrossRefGoogle Scholar
Hodin, J., Heyland, A., Mercier, A., Pernet, B., Cohen, D.L., Hamel, J.-F., Allen, J.D., McAlister, J.S., Byrne, M., Cisternas, P. and George, S.B. (2019) Culturing echinoderm larvae through metamorphosis. Methods in Cell Biology 150, 125196.CrossRefGoogle ScholarPubMed
Huang, W., Huo, D., Yu, Z., Ren, C., Jiang, X., Luo, P., Chen, T. and Hu, C. (2018) Spawning, larval development and juvenile growth of the tropical sea cucumber Holothuria leucospilota . Aquaculture 488, 2229.CrossRefGoogle Scholar
Hunt, T. (1989) Maturation promoting factor, cyclin and the control of M-phase. Current Opinion in Cell Biology 1, 268274.CrossRefGoogle Scholar
Iwashita, J., Hayano, Y. and Sagata, N. (1998) Essential role of germinal vesicle material in the meiotic cell cycle of Xenopus oocytes. Proceedings of the National Academy of Sciences 95, 43924397.CrossRefGoogle Scholar
Jessus, C., Munro, C. and Houliston, E. (2020) Managing the oocyte meiotic arrest: lessons from frogs and jellyfish. Cells 9, 1150–1186.CrossRefGoogle Scholar
Kanatani, H. and Hiramoto, Y. (1970) Site of action of 1-methyladenine in inducing oocyte maturation in starfish. Experimental Cell Research 61, 280284.CrossRefGoogle Scholar
Kishimoto, T. (2011) A primer on meiotic resumption in starfish oocytes: the proposed signaling pathway triggered by maturation-inducing hormone. Molecular Reproduction and Development 78, 704707.CrossRefGoogle Scholar
Masui, Y. (1985) Meiotic arrest in animal oocytes. In Metz, C. B. and Monroy (eds.), Biology of fertilization: model systems and oogenesis. Orlando, Florida: University of Michigan.CrossRefGoogle Scholar
Mayes, M. (2002) The arrest of bovine oocytes. Dissertation, University of Laval, Quebec.Google Scholar
Mercier, A. and Hamel, J.-F. (2009) Endogenous and exogenous control of gametogenesis and spawning in echinoderms. Advances in Marine Biology 55, 1291.CrossRefGoogle Scholar
Miller, M.A., Nguyen, V.Q., Lee, M.-H., Kosinski, M., Schedl, T., Caprioli, R.M. and Greenstein, D. (2001) A sperm cytoskeletal protein that signals oocyte meiotic maturation and ovulation. Science 291, 21442147.CrossRefGoogle ScholarPubMed
Morgan, A.D. (2000) Induction of spawning in the sea cucumber Holothuria scabra (Echinodermata: Holothuroidea). Journal of the world Aquaculture Society 31, 186194.CrossRefGoogle Scholar
Néant, I., Charbonneau, M. and Guerrier, P. (1989) A requirement for protein phosphorylation in regulating the meiotic and mitotic cell cycles in echinoderms. Developmental Biology 132, 304314.CrossRefGoogle Scholar
Nishiyama, T., Tachibana, K. and Kishimoto, T. (2010) Cytostatic arrest: post-ovulation arrest until fertilization in metazoan oocytes. In Verlhac, M.-H. and Villeneuve, A. (eds), Oogenesis: the universal process. Chichester, West Sussex: John Wiley & Sons.CrossRefGoogle Scholar
Purcell, S.W., Hair, C.A. and Mills, D.J. (2012) Sea cucumber culture, farming and sea ranching in the tropics: progress, problems and opportunities. Aquaculture 368, 6881.CrossRefGoogle Scholar
Russo, G.L., Bilotto, S., Ciarcia, G. and Tosti, E. (2009) Phylogenetic conservation of cytostatic factor related genes in the ascidian Ciona intestinalis . Gene 429, 104111.CrossRefGoogle Scholar
Sagata, N. (1996) Meiotic metaphase arrest in animal oocytes: its mechanisms and biological significance. Trends in Cell Biology 6, 2228.CrossRefGoogle Scholar
Sen, A. and Caiazza, F. (2013) Oocyte maturation: a story of arrest and release. Frontiers in Bioscience 5, 451477.CrossRefGoogle Scholar
Sewell, M.A. (1994) Birth, recruitment and juvenile growth in the intraovarian brooding sea cucumber Leptosynapta clarki . Marine Ecology Progress Series 114, 149156.CrossRefGoogle Scholar
Turner, R. (1973) Release mechanisms for gametes and juveniles of the hermaphroditic coelom-brooder Synaptula hydriformis (Echinodermata: Holothuroidea). American Zooologist 13, 13371338.Google Scholar
Von Stetina, J.R. and Orr-Weaver, T.L. (2011) Developmental control of oocyte maturation and egg activation in metazoan models. Cold Spring Harbour Perspectives in Biology 3, a005553.Google Scholar
Voronina, E. (2003) Regulation of oocyte maturation. Dissertation, Brown University, Rhode Island.CrossRefGoogle Scholar
Figure 0

Figure 1. (A) Schematic illustration of the phases of oogenic maturation that are universal to most animals: primary oocytes are stored in the ovary where they grow (green rectangle); the onset of gamete release brings on cues that lift the first meiotic arrest, triggering GV breakdown (GVBD) and ovulation (transit into the oviduct; blue rectangle); a brief second meiotic arrest (occurring at various stages depending on the species, but commonly in metaphase of meiosis II) is lifted by presence of sperm or fertilization (purple rectangle). (B) Illustration of how the timing of oogenic maturation differs in echinoids, and now in C. laevis: the first and second meiotic arrests are lifted and GVBD occurs independently of spawning so that ovulated ootids are stored inside the ovary (green rectangle) long before release into the oviduct (blue rectangle) and fertilization (purple rectangle).

Figure 1

Figure 2. (A) The sea cucumber Chiridota laevis. (B-C) Primary vitellogenic oocytes still in the ovarian tubules of C. laevis showing the germinal vesicle (GV) and nucleoli (N) as well as the follicle cells (FC). (D) Ootids in the ovarian tubules with completed ovulation, GV breakdown and expulsion of polar bodies. These ootids also demonstrate a clearly developed embryonic coating (E). (E) Ootids in the ovarian tubule, with the surrounding embryonic coating clearly visible (E) and no FCs. The scale bar represents 9 mm in A, 100 µm in B and 50 µm in C−E.