Book contents
- In-Vitro Fertilization
- In-Vitro Fertilization
- Copyright page
- Contents
- Preface
- Acknowledgments
- Chapter 1 Review of Cell and Molecular Biology
- Chapter 2 Endocrine Control of Reproduction
- Chapter 3 Gametes and Gametogenesis
- Chapter 4 Gamete Interaction
- Chapter 5 First Stages of Development
- Chapter 6 Implantation and Early Stages of Fetal Development
- Chapter 7 Stem Cell Biology
- Chapter 8 The Clinical In-Vitro Fertilization Laboratory
- Chapter 9 Quality Management in the IVF Laboratory
- Chapter 10 Sperm and ART
- Chapter 11 Oocyte Retrieval and Embryo Culture
- Chapter 12 Cryopreservation of Gametes and Embryos
- Chapter 13 Micromanipulation Techniques
- Chapter 14 Preimplantation Genetic Diagnosis
- Chapter 15 Epigenetics and Human Assisted Reproduction
- Index
- References
Chapter 3 - Gametes and Gametogenesis
Published online by Cambridge University Press: 24 December 2019
Book contents
- In-Vitro Fertilization
- In-Vitro Fertilization
- Copyright page
- Contents
- Preface
- Acknowledgments
- Chapter 1 Review of Cell and Molecular Biology
- Chapter 2 Endocrine Control of Reproduction
- Chapter 3 Gametes and Gametogenesis
- Chapter 4 Gamete Interaction
- Chapter 5 First Stages of Development
- Chapter 6 Implantation and Early Stages of Fetal Development
- Chapter 7 Stem Cell Biology
- Chapter 8 The Clinical In-Vitro Fertilization Laboratory
- Chapter 9 Quality Management in the IVF Laboratory
- Chapter 10 Sperm and ART
- Chapter 11 Oocyte Retrieval and Embryo Culture
- Chapter 12 Cryopreservation of Gametes and Embryos
- Chapter 13 Micromanipulation Techniques
- Chapter 14 Preimplantation Genetic Diagnosis
- Chapter 15 Epigenetics and Human Assisted Reproduction
- Index
- References
Summary
After a blastocyst has implanted in the uterus and begins to differentiate into the three primary germ layers, a special population of cells develops as primordial germ cells (PGCs). These are destined to become the gametes of the new individual: future reproduction of the organism is absolutely dependent upon the correct development of these unique populations of cells. They originate immediately behind the primitive streak in the extraembryonic mesoderm of the yolk sac; toward the end of gastrulation they move into the embryo via the allantois, and temporarily settle in the mesoderm and endoderm of the primitive streak. In humans, PGCs can be identified at about 3 weeks of gestation, close to the yolk sac endoderm at the root of the allantois.
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- Chapter
- Information
- In-Vitro Fertilization , pp. 53 - 76Publisher: Cambridge University PressPrint publication year: 2020
References
Primary Sources
Antczak, M, Van Blerkom, J (1997) Oocyte influences on early development: the regulatory proteins leptin and STAT3 are polarized in mouse and human oocytes and differentially distributed within the cells of the preimplantation stage embryo. Molecular Human Reproduction 3: 1067–1086.CrossRefGoogle Scholar
Bachvarova, R (1985) Gene expression during oogenesis and oocyte development in mammals. In: Browder, LW (ed.) Developmental Biology. A Comprehensive Synthesis, Vol. 1: Oogenesis. Plenum, New York, pp. 453–524.Google Scholar
Bellve, A, O’Brien, D (1983) The mammalian spermatozoon: structure and temporal assembly. In: Hartmann, JF (ed.) Mechanism and Control of Animal Fertilization. Academic Press, New York, pp. 56–140.Google Scholar
Braun, RE (2000) Temporal control of protein synthesis during spermatogenesis. International Journal of Andrology 23(Suppl. 2): 92–94.CrossRefGoogle ScholarPubMed
Briggs, D, Miller, D, Gosden, R (1999) Molecular biology of female gametogenesis. In: Fauser BCJM, Rutherford AJ, Strauss JF, Van Steirteghem A (eds.) Molecular Biology in Reproductive Medicine. Parthenon Press, New York, pp. 251–267.Google Scholar
Buccione, R, Schroeder, AC, Eppig, JJ (1990) Interactions between somatic cells and germ cells throughout mammalian oogenesis. Biology of Reproduction 43: 543–547.Google Scholar
Byskov, AG, Andersen, CY, Nordholm, L, et al. (1995) Chemical structure of sterols that activate oocyte meiosis. Nature 374: 559–562.CrossRefGoogle ScholarPubMed
Canipari, R (2000) Oocyte-granulosa cell interactions. Human Reproduction Update 6: 279–289.CrossRefGoogle ScholarPubMed
Canipari, R, Epifano, O, Siracusa, G, Salustri, A (1995) Mouse oocytes inhibit plasminogen activator production by ovarian cumulus and granulosa cells. Developmental Biology 167: 371–378.CrossRefGoogle ScholarPubMed
Cho, WK, Stern, S, Biggers, JD (1974) Inhibitory effect of dibutyryl cAMP on mouse oocyte maturation in vitro. Journal of Experimental Zoology 187: 383–386.CrossRefGoogle ScholarPubMed
Choo, YK, Chiba, K, Tai, T, Ogiso, M, Hoshi, M (1995) Differential distribution of gangliosides in adult rat ovary during the oestrous cycle. Glycobiology 5: 299–309.CrossRefGoogle ScholarPubMed
Clarkson, MJ, Harley, VR (2002) Sex with two SOX on: SRY and SOX9 in testis development. Trends in Endocrinology and Metabolism 13(3): 106–111.CrossRefGoogle ScholarPubMed
Dale, B (1996) Fertilization. In: Greger, R, Windhorst, U (eds.) Comprehensive Human Physiology. Springer-Verlag, Heidelberg, pp. 2265–2275CrossRefGoogle Scholar
Dekel, N (1996) Protein phosphorylation/dephosphorylation in the meiotic cell cycle of mammalian oocytes. Reviews of Reproduction 1: 82–88.Google Scholar
Dong, J, Albertini, DF, Nishimori, K, Kumar, TR, Lu, N, Matzuk, MM (1996) Growth differentiation factor-9 is required during early ovarian folliculogenesis. Nature 383: 531–535.CrossRefGoogle ScholarPubMed
Eddy, EM (1998) Regulation of gene expression during spermatogenesis. Seminars in Cell and Developmental Biology 9: 451–457.CrossRefGoogle ScholarPubMed
Edwards, RG, Beard, H (1997) Oocyte polarity and cell determination in early mammalian embryos. Molecular Human Reproduction 3: 868–905.CrossRefGoogle ScholarPubMed
Elder, K, Elliott, T (eds.) (1998) The use of epididymal and testicular sperm in IVF. Worldwide Conferences in Reproductive Biology 2. Ladybrook Publications, Australia.Google Scholar
Epifano, O, Dean, J (2002) Genetic control of early folliculogenesis in mice. Trends in Endocrinology and Metabolism 13(4): 169–173.CrossRefGoogle ScholarPubMed
Eppig, JJ, O’Brien, MJ (1996) Development in vitro of mouse oocytes from primordial follicles. Biology of Reproduction 54: 197–207.Google Scholar
Faddy, MJ, Gosden, RG (1995) A mathematical model for follicle dynamics in human ovaries. Human Reproduction 10: 770–775.CrossRefGoogle Scholar
Faddy, MJ, Gosden, RG (1996) Ovary and ovulation: a model conforming the decline in follicle numbers to the age of menopause in women. Human Reproduction 11(7): 1484–1486.Google Scholar
Fulka, J Jr., First, N, Moor, RM (1998) Nuclear and cytoplasmic determinants involved in the regulation of mammalian oocyte maturation. Molecular Human Reproduction 4(1): 41–49.CrossRefGoogle ScholarPubMed
Gardner, R (1999) Polarity in early mammalian development. Current Opinion in Genetics and Development 9(4): 417–421.CrossRefGoogle ScholarPubMed
Gosden, R (1995) Ovulation 1: oocyte development throughout life. In: Grudzinskas, JG, Yovich, JL (eds.) Gametes: The Oocyte. Cambridge University Press, Cambridge, UK, pp. 119–149.Google Scholar
Gosden, RG, Boland, NI, Spears, N, et al. (1993) The biology and technology of follicular oocyte development in vitro. Reproductive Medicine Reviews 2: 129–152.CrossRefGoogle Scholar
Gosden, RG, Bownes, M (1995) Cellular and molecular aspects of oocyte development. In: Grudzinskas, JG, Yovich, JL (eds.) Cambridge Reviews in Human Reproduction, Gametes – The Oocyte. Cambridge University Press, Cambridge, UK, pp. 23–53.Google Scholar
Gougeon, A (1996) Regulation of ovarian follicular development in primates: facts and hypotheses. Endocrine Reviews 17: 121–155.CrossRefGoogle ScholarPubMed
Griswold, MD (2016) Spermatogenesis: the commitment to meiosis. Physiological Reviews 96: 1–17.Google Scholar
Gurdon, JB (1967) On the origin and persistence of a cytoplasmic state inducing nuclear DNA synthesis in frog’s eggs. Proceedings of the National Academy of Sciences of the USA 58: 545–552.Google Scholar
Henderson, SA, Edwards, RG (1968) Chiasma frequency and maternal age in mammals. Nature 217(136): 22–28.Google Scholar
Hess, RA (1999) Spermatogenesis, overview. In: Knobil, E, Neill, JD (eds.) Encyclopedia of Reproduction, vol. 4. Academic Press, New York, pp. 539–545.Google Scholar
Hillier, SG, Whitelaw, PF, Smyth, CD (1994) Follicular oestrogen synthesis: the ‘two-cell, two-gonadotrophin’ model revisited. Molecular and Cellular Endocrinology 100: 51–54.CrossRefGoogle ScholarPubMed
Hirshfield, AN (1991) Development of follicles in the mammalian ovary. International Review of Cytology 124: 43–100.CrossRefGoogle ScholarPubMed
Hutt, KJ, Albertini, DF (2007). An oocentric view of folliculogenesis and embryogenesis Reproductive BioMedicine Online 14(6): 758–764.Google Scholar
Johnson, J, Bagley, J, Skaznik-Wikiel, M, et al. (2005) Oocyte generation in adult mammalian ovaries by putative germ cells in bone marrow and peripheral blood. Cell 122: 303–315.Google Scholar
Jones, R (1998) Spermiogenesis and sperm maturation in relation to development of fertilizing capacity. In: Lauria, A, Gandolfi, F, Enne, G, Giannaroli, I, et al. (eds.) Gametes: Development and Function. Serono Symposia, Rome, pp. 205–218.Google Scholar
Kobayashi, M, Nakano, R, Ooshima, A (1990) Immunohistochemical localization of pituitary gonadotrophins and gonadal steroids confirms the ‘two-cell, two-gonadotrophin’ hypothesis of steroidogenesis in the human ovary. Journal of Endocrinology 126(3): 483–488.Google Scholar
Kramer, JA, McCarrey, JR, Djakiew, D, Krawetz, SA (1998) Differentiation: the selective potentiation of chromatin domains. Development 125: 4749–4755.CrossRefGoogle ScholarPubMed
MacLaren, A (2003) Primordial germ cells in the mouse. Developmental Biology 262(1): 1–15.Google Scholar
Masui, Y (1985) Meiotic arrest in animal oocytes. In: Metz, CB, Monroy, A (eds.) Biology of Fertilization. Academic Press, New York, pp. 189–219.Google Scholar
Matzuk, MM, Burns, KH, Viveiros, MM, Eppig, JJ (2002) Intercellular communication in the mammalian ovary: oocytes carry the conversation. Science 296 (5576): 2178–2180.CrossRefGoogle ScholarPubMed
McNatty, KP, Fidler, AE, Juengel, JL, et al. (2000) Growth and paracrine factors regulating follicular formation and cellular function. Molecular and Cellular Endocrinology 163: 11–20.Google Scholar
Merchant-Larios, H, Moreno-Mendoza, N (2001) Onset of sex differentiation: dialog between genes and cells. Archives of Medical Research 32(6): 553–558.CrossRefGoogle ScholarPubMed
Moore, HDM (1996) The influence of the epididymis on human and animal sperm maturation and storage. Human Reproduction 11(Suppl.): 103–110.Google Scholar
Nurse, P (1990) Universal control mechanisms resulting in the onset of M-phase. Nature 344: 503–508.Google Scholar
Oatley, JM, Brinster, RL (2012) The germline stem cell niche unit in mammalian testes. Physiological Reviews 92: 577–595.Google Scholar
Oktay, K, Schenken, RS, Nelson, JF (1995) Proliferating cell nuclear antigen marks the initiation of follicular growth in the rat. Biology of Reproduction 53(2): 295–301.Google Scholar
Pereda, J, Zorn, T, Soto-Suazo, M (2006) Migration of human and mouse primordial germ cells and colonization of the developing ovary: an ultrastructural and cytochemical study. Microscopy Research and Technique 69(6): 386–395.Google Scholar
Perez, GI, Trbovich, AM, Gosden, RG, Tilly, JL (2000) Mitochondria and the death of oocytes. Nature 403(6769): 500–501.Google Scholar
Picton, HM, Briggs, D, Gosden, RG (1998) The molecular basis of oocyte growth and development. Molecular and Cellular Endocrinology 145: 27–37.CrossRefGoogle ScholarPubMed
Reynard, K, Driancourt, MA (2000) Oocyte attrition. Molecular and Cellular Endocrinology 163: 101–108.Google Scholar
Rosner, MH, Vigano, MA, Ozato, K, et al. (1990) A POU-domain transcription factor in early stem cells and germ cells of the mammalian embryo. Nature 345(6277): 686–692.Google Scholar
Sagata, N (1996) Meiotic metaphase arrest in animal oocytes: its mechanisms and biological significance. Trends in Cell Biology 6: 22–28.Google Scholar
Saitou, M, Payer, B, O’Carroll, D, Ohinata, Y, Surani, MA (2005). Blimp1 and the emergence of the germ line during development in the mouse. Cell Cycle 4: 1736–1740.Google Scholar
Schatten, H, Sun, QY (2009) The role of centrosomes in mammalian fertilization and its significance for ICSI. Molecular Human Reproduction 15(9): 531–538.Google Scholar
Spears, N, Boland, NI, Murray, AA, Gosden, RG (1994) Mouse oocytes derived from in vitro grown primary ovarian follicles are fertile. Human Reproduction 9: 527–532.Google Scholar
Starz-Gaiano, M, Lehmann, R (2001) Moving towards the next generation. Mechanisms of Development 105(1–2): 5–18.Google Scholar
Sutovsky, P, Fléchon, JE, Fléchon, B, et al. (1993) Dynamic changes of gap junctions and cytoskeleton in in vitro culture of cattle oocyte cumulus complexes. Biology of Reproduction 49: 1277–1287.Google Scholar
Swain, A, Lovell-Badge, R (1999) Mammalian sex determination: a molecular drama. Genes and Development 13(7): 755–767.Google Scholar
Taylor, CT, Johnson, PM (1996) Complement-binding proteins are strongly expressed by human preimplantation blastocysts and cumulus cells as well as gametes. Molecular Human Reproduction 2: 52–59.Google Scholar
Telfer, EE (1996) The development of methods for isolation and culture of preantral follicles from bovine and porcine ovaries. Theriogenology 45: 101–110.CrossRefGoogle Scholar
Telfer, EE, McLaughlin, M (2007) Natural history of the mammalian oocyte. Reproductive BioMedicine Online 15(3): 288–295.Google Scholar
Van Blerkom, J, Motta, P (1979) The Cellular Basis of Mammalian Reproduction. Urban and Schwarzenberg, Baltimore.Google Scholar
Ward, WS (1993) Deoxyribonucleic acid loop domain tertiary structure in mammalian spermatozoa. Biology of Reproduction 48(6): 1193–1201.Google Scholar
Ward, WS, Coffey, DS (1991) DNA packaging and organization in mammalian spermatozoa: comparison with somatic cells. Biology of Reproduction 44(4): 569–574.Google Scholar
Wassarman, PM (1996) Oogenesis. In: Adashi, EY, Rock, JA, Rosenwaks, Z (eds.) Reproductive Endocrinology, Surgery and Technology, vol. 1. Lippincott-Raven Publishers, Philadelphia, pp. 341–359.Google Scholar
Wassarman, PM, Liu, C, Litscher, ES (1996) Constructing the mammalian egg zona pellucida: some new pieces of an old puzzle. Journal of Cell Science 109: 2001–2004.Google Scholar
Yanagamachi, R (1994) Mammalian fertilization. In: Knobil, E, Neill, J (eds.) The Physiology of Reproduction. Raven Press, New York, pp. 189–317.Google Scholar
Secondary Sources
Balhorn, R (1982) A model for the structure of chromatin in mammalian sperm. Journal of Cell Biology 93: 298–305.Google Scholar
Balhorn, R, Gledhill, BL, Wyrobek, AJ (1977) Mouse sperm chromatin proteins: quantitative isolation and partial characterization. Biochemistry 16: 4074–4080.CrossRefGoogle ScholarPubMed
Bench, G, Corzett, MH, DeYebra, L, Oliva, R, Balhorn, R (1998) Protein and DNA contents in sperm from an infertile human male possessing protamine defects that vary over time. Molecular Reproduction and Development 50: 345–353.3.0.CO;2-3>CrossRefGoogle ScholarPubMed
Cho, C, Willis, WD, Goulding, EH, et al. (2001) Haploinsufficiency of protamine-1 or -2 causes infertility in mice. Nature Genetics 28: 82–86.Google Scholar
Gardiner-Garden, M, Ballesteros, M, Gordon, M, Tam, PP (1998) Histone- and protamine-DNA association: conservation of different patterns within the beta-globin domain in human sperm. Molecular and Cellular Biology 18: 3350–3356.Google Scholar
Gatewood, JM, Cook, GR, Balhorn, R, Bradbury, EM, Schmid, CW (1987) Sequence-specific packaging of DNA in human sperm chromatin. Science 236: 962–964.Google Scholar
Gatewood, JM, Cook, GR, Balhorn, R, Schmid, CW, Bradbury, EM (1990) Isolation of 4 core histones from human sperm chromatin representing a minor subset of somatic histones. Journal of Biological Chemistry 265: 20662–20666.Google Scholar
Miller, D (2000) Analysis and significance of messenger RNA in human ejaculated spermatozoa. Molecular Reproduction and Development 56: 259–264.Google Scholar
Miller, D, Ostermeier, GC (2006) Towards a better understanding of RNA carriage by ejaculate spermatozoa. Human Reproduction Update 12: 757–767.Google Scholar
Wykes, SM, Krawetz, SA (2003) The structural organization of sperm chromatin. Journal of Biological Chemistry 278: 29471–29477.Google Scholar
Miller, D (2004) Sex determination: insights from the human and animal models suggest that the mammalian Y chromosome is uniquely specialised for the male’s benefit. Journal of Men’s Health and Gender 1: 170–181.Google Scholar
Morais da Silva, S, Hacker, A, Harley, V, et al. (1996) Sox9 expression during gonadal development implies a conserved role for the gene in testis differentiation in mammals and birds. Nature Genetics 14: 62–68.Google Scholar
Sekido, R, Bar, I, Narvaez, V, Penny, G, Lovell-Badge, R (2004) SOX9 is up-regulated by the transient expression of SRY specifically in Sertoli cell precursors. Developmental Biology 274: 271–279.Google Scholar
Sekido, R, Lovell-Badge, R (2008) Sex determination involves synergistic action of SRY and SF1 on a specific Sox9 enhancer. Nature 453: 930–934.Google Scholar