Jump to content

Oocyte

From Wikipedia, the free encyclopedia
(Redirected from Primary oocytes)
Oocyte
Identifiers
MeSHD009865
FMA18644
Anatomical terminology

An oocyte (UK: /ˈəst/, US: /ˈ-/), oöcyte, or ovocyte is a female gametocyte or germ cell involved in reproduction. In other words, it is an immature ovum, or egg cell. An oocyte is produced in a female fetus in the ovary during female gametogenesis. The female germ cells produce a primordial germ cell (PGC), which then undergoes mitosis, forming oogonia. During oogenesis, the oogonia become primary oocytes. An oocyte is a form of genetic material that can be collected for cryoconservation.

Formation

[edit]
Diagram showing the reduction in number of the chromosomes in the process of maturation of the ovum; the process is known as meiosis.

The formation of an oocyte is called oocytogenesis, which is a part of oogenesis.[1] Oogenesis results in the formation of both primary oocytes during fetal period, and of secondary oocytes after it as part of ovulation.

Cell type ploidy/chromosomes chromatids Process Time of completion
Oogonium diploid/46(2N) 2C Oocytogenesis (mitosis) third trimester
primary Oocyte diploid/46(2N) 4C Ootidogenesis (meiosis I) (Folliculogenesis) Dictyate in prophase I for up to 50 years
secondary Oocyte haploid/23(1N) 2C Ootidogenesis (meiosis II) Halted in metaphase II until fertilization
Ootid haploid/23(1N) 1C Ootidogenesis (meiosis II) Minutes after fertilization
Ovum haploid/23(1N) 1C

Characteristics

[edit]

Cytoplasm

[edit]

Oocytes are rich in cytoplasm, which contains yolk granules to nourish the cell early in development.

Nucleus

[edit]

During the primary oocyte stage of oogenesis, the nucleus is called a germinal vesicle.[2]

The only normal human type of secondary oocyte has the 23rd (sex) chromosome as 23,X (female-determining), whereas sperm can have 23,X (female-determining) or 23,Y (male-determining).

Nest

[edit]

The space within an ovum or immature ovum is located is the cell-nest.[3]

Cumulus-oocyte complex

[edit]

The cumulus-oocyte complex contains layers of tightly packed cumulus cells surrounding the oocyte in the Graafian follicle. The oocyte is arrested in Meiosis II at the stage of metaphase II and is considered a secondary oocyte. Before ovulation, the cumulus complex goes through a structural change known as cumulus expansion. The granulosa cells transform from tightly compacted to an expanded mucoid matrix. Many studies show that cumulus expansion is critical for the maturation of the oocyte because the cumulus complex is the oocyte's direct communication with the developing follicle environment. It also plays a significant role in fertilization, though the mechanisms are not entirely known and are species specific.[4][5][6]

Maternal contributions

[edit]
diagram of an oocyte with its vegetal and animal hemispheres identified
Oocyte poles

In order for an oocyte to become fertilized and ultimately grow into a fully functioning organism, it must be able to regulate multiple cellular and developmental processes. The oocyte, a large and complex cell, must be able to direct the growth of the embryo and control cellular activities. As the oocyte is a product of female gametogenesis, the maternal contribution to the oocyte and consequently the newly fertilized egg, is enormous. There are many types of molecules that are maternally supplied to the oocyte, which will direct various activities within the growing zygote.

Avoidance of damage to germ-line DNA

[edit]

The DNA of a cell is vulnerable to the damaging effect of oxidative free radicals produced as byproducts of cellular metabolism. DNA damage occurring in oocytes, if not repaired, can be lethal and result in reduced fecundity and loss of potential progeny. Oocytes are substantially larger than the average somatic cell, and thus considerable metabolic activity is necessary for their provisioning. If this metabolic activity were carried out by the oocyte's metabolic machinery, the oocyte genome would be exposed to the reactive oxidative by-products generated. Thus it appears that a process evolved to avoid this vulnerability of germline DNA. It was proposed that, in order to avoid damage to the DNA genome of the oocytes, the metabolism contributing to the synthesis of much of the oocyte's constituents was shifted to other maternal cells that then transferred these constituents to oocytes.[7][8] Thus, oocytes of many organisms are protected from oxidative DNA damage while storing up a large mass of substances to nurture the zygote in its initial embryonic growth.

mRNAs and proteins

[edit]

During the growth of the oocyte, a variety of maternally transcribed messenger RNAs, or mRNAs, are supplied by maternal cells. These mRNAs can be stored in mRNP (message ribonucleoprotein) complexes and be translated at specific time points, they can be localized within a specific region of the cytoplasm, or they can be homogeneously dispersed within the cytoplasm of the entire oocyte.[9] Maternally loaded proteins can also be localized or ubiquitous throughout the cytoplasm. The translated products of the mRNAs and the loaded proteins have multiple functions; from regulation of cellular "house-keeping" such as cell cycle progression and cellular metabolism, to regulation of developmental processes such as fertilization, activation of zygotic transcription, and formation of body axes.[9] Below are some examples of maternally inherited mRNAs and proteins found in the oocytes of the African clawed frog.

Name Type of maternal molecule Localization Function
VegT[10] mRNA Vegetal hemisphere Transcription factor
Vg1[11] mRNA Vegetal hemisphere Transcription factor
XXBP-1[12] mRNA Not known Transcription factor
CREB[13] Protein Ubiquitous Transcription factor
FoxH1[14] mRNA Ubiquitous Transcription factor
p53[15] Protein Ubiquitous Transcription Factor
Lef/Tcf[16] mRNA Ubiquitous Transcription factor
FGF2[17] Protein Nucleus Not known
FGF2, 4, 9 FGFR1[16] mRNA Not known FGF signaling
Ectodermin[18] Protein Animal hemisphere Ubiquitin ligase
PACE4[19] mRNA Vegetal hemisphere Proprotein convertase
Coco[20] Protein Not known BMP inhibitor
Twisted gastrulation[16] Protein Not known BMP/Chordin binding protein
fatvg[21] mRNA Vegetal hemisphere Germ cell formation and cortical rotation
a diagram of the Xenopus laevis oocyte and its maternal determinants
Maternal determinants in Xenopus laevis oocyte

Mitochondria

[edit]

The oocyte receives mitochondria from maternal cells, which will go on to control embryonic metabolism and apoptotic events.[9] The partitioning of mitochondria is carried out by a system of microtubules that will localize mitochondria throughout the oocyte. In certain organisms, such as mammals, paternal mitochondria brought to the oocyte by the spermatozoon are degraded through the attachment of ubiquitinated proteins. The destruction of paternal mitochondria ensures the strictly maternal inheritance of mitochondria and mitochondrial DNA (mtDNA).[9]

Nucleolus

[edit]

In mammals, the nucleolus of the oocyte is derived solely from maternal cells.[22] The nucleolus, a structure found within the nucleus, is the location where rRNA is transcribed and assembled into ribosomes. While the nucleolus is dense and inactive in a mature oocyte, it is required for proper development of the embryo.[22]

Ribosomes

[edit]

Maternal cells also synthesize and contribute a store of ribosomes that are required for the translation of proteins before the zygotic genome is activated. In mammalian oocytes, maternally derived ribosomes and some mRNAs are stored in a structure called cytoplasmic lattices. These cytoplasmic lattices, a network of fibrils, protein, and RNAs, have been observed to increase in density as the number of ribosomes decrease within a growing oocyte[23] and mutation in them have been linked to infertility.[24][25]

Prophase I arrest

[edit]

Female mammals and birds are born possessing all the oocytes needed for future ovulations, and these oocytes are arrested at the prophase I stage of meiosis.[26] In humans, as an example, oocytes are formed between three and four months of gestation within the fetus and are therefore present at birth. During this prophase I arrested stage (dictyate), which may last for many years, four copies of the genome are present in the oocytes. The arrest of ooctyes at the four genome copy stage appears to provide the informational redundancy needed to repair damage in the DNA of the germline.[26] The repair process used likely involves homologous recombinational repair.[26][27][28] Prophase arrested oocytes have a high capability for efficient repair of DNA damages.[27] In particular, DNA double-strand breaks can be repaired during the period of prophase arrest by homologous recombinational repair and by non-homologous end joining.[29] DNA repair capability appears to be a key quality control mechanism in the female germ line and a critical determinant of fertility.[27]

Paternal contributions

[edit]

The spermatozoon that fertilizes an oocyte will contribute its pronucleus, the other half of the zygotic genome. In some species, the spermatozoon will also contribute a centriole, which will help make up the zygotic centrosome required for the first division. However, in some species, such as in the mouse, the entire centrosome is acquired maternally.[30] Currently under investigation is the possibility of other cytoplasmic contributions made to the embryo by the spermatozoon.

During fertilization, the sperm provides three essential parts to the oocyte: (1) a signalling or activating factor, which causes the metabolically dormant oocyte to activate; (2) the haploid paternal genome; (3) the centrosome, which is responsible for maintaining the microtubule system. See anatomy of sperm

Abnormalities

[edit]

See also

[edit]

References

[edit]
  1. ^ answers.com
  2. ^ "Germinal vesicle". Biology Articles, Tutorials & Dictionary Online. 2019-10-07. Retrieved 2022-04-09.
  3. ^ Grier HJ, Uribe MC, Parenti LR (April 2007). "Germinal epithelium, folliculogenesis, and postovulatory follicles in ovaries of rainbow trout, Oncorhynchus mykiss (Walbaum, 1792) (Teleostei, protacanthopterygii, salmoniformes)". Journal of Morphology. 268 (4): 293–310. doi:10.1002/jmor.10518. PMID 17309079. S2CID 23482731.
  4. ^ Yokoo M, Sato E (2004). "Cumulus-oocyte complex interactions during oocyte maturation". International Review of Cytology. 235: 251–91. doi:10.1016/S0074-7696(04)35006-0. ISBN 978-0-12-364639-2. PMID 15219785.
  5. ^ Tanghe S, Van Soom A, Nauwynck H, Coryn M, de Kruif A (March 2002). "Minireview: Functions of the cumulus oophorus during oocyte maturation, ovulation, and fertilization". Molecular Reproduction and Development. 61 (3): 414–24. doi:10.1002/mrd.10102. PMID 11835587. S2CID 5728551.
  6. ^ Huang Z, Wells D (October 2010). "The human oocyte and cumulus cells relationship: new insights from the cumulus cell transcriptome". Molecular Human Reproduction. 16 (10): 715–25. doi:10.1093/molehr/gaq031. PMID 20435609.
  7. ^ Bernstein C (1993). "Sex as a response to oxidative DNA damage. Chapter 10". In Halliwell B, Aruoma OI (eds.). DNA and Free Radicals. Great Britain: Ellis Horwood Limited. pp. 204–205. ISBN 978-0-13-222035-4.
  8. ^ Bernstein C (1998). "Sex as a response to oxidative DNA damage. Chapter 4". In Aruoma OI, Halliwell B (eds.). DNA and Free Radicals: Techniques, Mechanisms & Applications. Saint Lucia and London: OICA International. pp. 112–113. ISBN 976-8056169.
  9. ^ a b c d Mtango NR, Potireddy S, Latham KE (2008). "Oocyte quality and maternal control of development". International Review of Cell and Molecular Biology. 268: 223–90. doi:10.1016/S1937-6448(08)00807-1. PMID 18703408.
  10. ^ Zhang J, King ML (December 1996). "Xenopus VegT RNA is localized to the vegetal cortex during oogenesis and encodes a novel T-box transcription factor involved in mesodermal patterning". Development. 122 (12): 4119–29. doi:10.1242/dev.122.12.4119. PMID 9012531. S2CID 28462527.
  11. ^ Heasman J, Wessely O, Langland R, Craig EJ, Kessler DS (December 2001). "Vegetal localization of maternal mRNAs is disrupted by VegT depletion". Developmental Biology. 240 (2): 377–86. doi:10.1006/dbio.2001.0495. PMID 11784070.
  12. ^ Zhao H, Cao Y, Grunz H (May 2003). "Xenopus X-box binding protein 1, a leucine zipper transcription factor, is involved in the BMP signaling pathway". Developmental Biology. 257 (2): 278–91. doi:10.1016/s0012-1606(03)00069-1. PMID 12729558.
  13. ^ Sundaram N, Tao Q, Wylie C, Heasman J (September 2003). "The role of maternal CREB in early embryogenesis of Xenopus laevis". Developmental Biology. 261 (2): 337–52. doi:10.1016/s0012-1606(03)00303-8. PMID 14499645.
  14. ^ Kofron M, Puck H, Standley H, Wylie C, Old R, Whitman M, Heasman J (October 2004). "New roles for FoxH1 in patterning the early embryo". Development. 131 (20): 5065–78. doi:10.1242/dev.01396. PMID 15459100.
  15. ^ Takebayashi-Suzuki K, Funami J, Tokumori D, Saito A, Watabe T, Miyazono K, et al. (September 2003). "Interplay between the tumor suppressor p53 and TGF beta signaling shapes embryonic body axes in Xenopus". Development. 130 (17): 3929–39. doi:10.1242/dev.00615. PMID 12874116.
  16. ^ a b c Heasman J (February 2006). "Maternal determinants of embryonic cell fate". Seminars in Cell & Developmental Biology. 17 (1): 93–8. doi:10.1016/j.semcdb.2005.11.005. PMID 16426874.
  17. ^ Song J, Slack JM (December 1994). "Spatial and temporal expression of basic fibroblast growth factor (FGF-2) mRNA and protein in early Xenopus development". Mechanisms of Development. 48 (3): 141–51. doi:10.1016/0925-4773(94)90055-8. PMID 7893598. S2CID 20281053.
  18. ^ Dupont S, Zacchigna L, Cordenonsi M, Soligo S, Adorno M, Rugge M, Piccolo S (April 2005). "Germ-layer specification and control of cell growth by Ectodermin, a Smad4 ubiquitin ligase". Cell. 121 (1): 87–99. doi:10.1016/j.cell.2005.01.033. hdl:11577/2439217. PMID 15820681. S2CID 16628152.
  19. ^ Birsoy B, Berg L, Williams PH, Smith JC, Wylie CC, Christian JL, Heasman J (February 2005). "XPACE4 is a localized pro-protein convertase required for mesoderm induction and the cleavage of specific TGFbeta proteins in Xenopus development". Development. 132 (3): 591–602. doi:10.1242/dev.01599. PMID 15634697.
  20. ^ Bell E, Muñoz-Sanjuán I, Altmann CR, Vonica A, Brivanlou AH (April 2003). "Cell fate specification and competence by Coco, a maternal BMP, TGFbeta and Wnt inhibitor". Development. 130 (7): 1381–9. doi:10.1242/dev.00344. PMID 12588853.
  21. ^ Chan AP, Kloc M, Larabell CA, LeGros M, Etkin LD (May 2007). "The maternally localized RNA fatvg is required for cortical rotation and germ cell formation". Mechanisms of Development. 124 (5): 350–63. doi:10.1016/j.mod.2007.02.001. PMC 2435194. PMID 17376659.
  22. ^ a b Ogushi S, Palmieri C, Fulka H, Saitou M, Miyano T, Fulka J (February 2008). "The maternal nucleolus is essential for early embryonic development in mammals". Science. 319 (5863): 613–6. doi:10.1126/science.1151276. PMID 18239124. S2CID 7799743.
  23. ^ Yurttas P, Vitale AM, Fitzhenry RJ, Cohen-Gould L, Wu W, Gossen JA, Coonrod SA (August 2008). "Role for PADI6 and the cytoplasmic lattices in ribosomal storage in oocytes and translational control in the early mouse embryo". Development. 135 (15): 2627–36. doi:10.1242/dev.016329. PMC 2708103. PMID 18599511.
  24. ^ Jentoft, Ida M.A.; Bäuerlein, Felix J.B.; Welp, Luisa M.; Cooper, Benjamin H.; Petrovic, Arsen; So, Chun; Penir, Sarah Mae; Politi, Antonio Z.; Horokhovskyi, Yehor; Takala, Iina; Eckel, Heike; Moltrecht, Rüdiger; Lénárt, Peter; Cavazza, Tommaso; Liepe, Juliane (November 2023). "Mammalian oocytes store proteins for the early embryo on cytoplasmic lattices". Cell. 186 (24): 5308–5327.e25. doi:10.1016/j.cell.2023.10.003. PMID 37922900.
  25. ^ Vaidyanathan, Gayathri (2023-11-02). "New explanation for infertility: eggs lacking a mysterious 'lattice'". Nature. doi:10.1038/d41586-023-03415-6. PMID 37919411. S2CID 264972543.
  26. ^ a b c Mira A (September 1998). "Why is meiosis arrested?". Journal of Theoretical Biology. 194 (2): 275–87. Bibcode:1998JThBi.194..275M. doi:10.1006/jtbi.1998.0761. PMID 9778439.
  27. ^ a b c Stringer JM, Winship A, Zerafa N, Wakefield M, Hutt K (May 2020). "Oocytes can efficiently repair DNA double-strand breaks to restore genetic integrity and protect offspring health". Proceedings of the National Academy of Sciences of the United States of America. 117 (21): 11513–11522. Bibcode:2020PNAS..11711513S. doi:10.1073/pnas.2001124117. PMC 7260990. PMID 32381741.
  28. ^ He, Da-Jian; Wang, Lin; Zhang, Zhi-Bi; Guo, Kun; Li, Jing-Zheng; He, Xie-Chao; Cui, Qing-Hua; Zheng, Ping (2018-11-18). "Maternal gene Ooep may participate in homologous recombination-mediated DNA double-strand break repair in mouse oocytes". Zoological Research. 39 (6): 387–395. doi:10.24272/j.issn.2095-8137.2018.067. PMC 6085769. PMID 29955025.
  29. ^ Leem J, Lee C, Choi DY, Oh JS. Distinct characteristics of the DNA damage response in mammalian oocytes. Exp Mol Med. 2024 Feb 14. doi:10.1038/s12276-024-01178-2. Epub ahead of print. PMID 38355825
  30. ^ Sutovsky P, Schatten G (2000). "Paternal contributions to the mammalian zygote: fertilization after sperm-egg fusion". International Review of Cytology. 195: 1–65. doi:10.1016/s0074-7696(08)62703-5. ISBN 978-0-12-364599-9. PMID 10603574.

Sources

[edit]
  • Purves WK, Orians GH, Sadava D, Heller HC (2004). Life: The Science of Biology (7th ed.). Freeman, W. H. & Company. pp. 823–824. ISBN 978-0-7167-9856-9.
[edit]
Preceded by
None
Stages of human development
Sperm + Oocyte
Succeeded by