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Embryonic Diapause

Year 2021, Volume: 6 Issue: 1, 34 - 40, 30.04.2021
https://doi.org/10.24880/maeuvfd.835288

Abstract

Embryonic diapause or temporary cessation of embryonic development is a common phenomenon in the plant and animal species. Embryonic diapause is a temporary cessation of the development of embryogenesis in the blastocyst stage and is a reproductive strategy characterized by delayed implantation in the uterus. It is defined in over 130 species of mammals. It occurs obligate or facultative in cases where the development of the embryo from the blastocyst stage to later stages is not appropriate (eg, during environmental conditions or lactation). The embryonic diapause begins with the blastocyst entering the metabolic and proliferative state of silence so reduction or interruption of mitosis in the embryo. When exit from the diapause, reactivation, and blastocyst returns to active metabolism, mitotic activity restarts and with cell proliferation, the implantation process begins in the uterus. Embryonic diapause is a protective phenomenon, it represents an important developmental advantage for species survival and should be evolutionarily maintained.

Project Number

YOKTUR

References

  • 1. Bulut-Karslioglu A, Biechele S, Jin H, Macrae TA, Hejna M, Gertsentein M, et al. Inhibition of mTOR induces a paused pluripotent state. Nature. 2016; 540: 119-123.
  • 2. Deng L, Li C, Chen L, Liu Y, Hou R, Zhou X, et al. Research advances on embryonic diapause in mammals. Animal Reproduction Science. 2018; 198: 1-10.
  • 3. Desmarais JA, Bordignon V, Lopes FL, Smith LC, Murphy BD. The escape of the mink embryo from obligate diapause. Biology of Reproduction. 2004; 70 (3): 662-670.
  • 4. Enders AC, Schlafke S, Hubbard NE, Mead RA. Morphological changes in the blastocyst of the western spotted skunk during activation from delayed implantation. Biology of Reproduction. 1986; 34(2): 423-437.
  • 5. Fenelon JC, Banerjee A, Lefèvre P, Gration F, Murphy BD. Polyamine-mediated effects of prolactin dictate emergence from mink obligate embryonic diapause. Biology of Reproduction. 2016; 95(1): 1-13.
  • 6. Fenelon JC, Lefèvre P, Banerjee A, Murphy BD. Regulation of diapause in carnivore. Reproduction in Domestic Animals. 2016; 51(3): 1-6.
  • 7. Fenelon JC, Banerjee A, Murphy BD. Embryonic diapause: development on hold. International Journal of Developmental Biology. 2014; 58(2-3-4): 163-174.
  • 8. Fenelon JC, Renfree MB. The history of the discovery of embryonic diapause in mammals. Biology of Reproduction. 2018; 99(1): 242-251.
  • 9. Hamatani T, Daikoku T, Wang H, Matsumoto H, Carter MG, Ko MSH et al. Global gene expression analysis identifies molecular pathways distinguishing blastocyst dormancy and activation. Proceedings of the National Academy of Sciences. 2004; 101(28): 10326-10331.
  • 10. Harper MJK. Sperm and egg transport. Germ cells and fertilization, Edn 2, Cambridge University Press, Cambridge. 1982.
  • 11. Harvey MB, Leco KJ, Arcellana-Panlilio MY, Zhang X, Edwards DR, Schultz GA. Endocrinology and paracrinology: Roles of growth factors during peri-implantation development. Human Reproduction. 1995; 10(3): 712-718.
  • 12. Hondo E, Stewart CL. Profiling gene expression in growth-arrested mouse embryos in diapause. Genome Biology. 2005; 6(1): 1-4.
  • 13. Hussein AM, Wang Y, Mathieu J, Margaretha L, Song C, Jones DC et al. Metabolic control over mTOR-dependent diapause-like state. Developmental Cell. 2020; 52(2): 236-250.
  • 14. Kane MT, Morgan PM, Coonan C. Peptide growth factors and preimplantation development. Human Reproduction Update. 1997; 3(2): 137-157.
  • 15. Kondoh E, Okamoto T, Higuchi T, Tatsumi K, Baba T, Murphy SK et al. Stress affects uterine receptivity through an ovarian-independent pathway. Human Reproduction. 2009; 24(4): 945-953.
  • 16. Leese HJ, Baumann CG, Brison DR, McEvoy TG, Sturmey RG. Metabolism of the viable mammalian embryo: quietness revisited. Molecular Human Reproduction. 2008; 14(12): 667-672.
  • 17. Lefevre PL, Palin MF, Chen G, Turecki G, Murphy. Polyamines are implicated in the emergence of the embryo from obligate diapause. Endocrinology. 2011; 152(4): 1627-1639.
  • 18. Liu WM, Pang RT, Cheong AWY, Ng EHY, Kaiqin L, Kai-Fai L et al. Involvement of microRNA lethal-7a in the regulation of embryo implantation in mice. PloS One. 2012: 7(5): e37039.
  • 19. Lopes FL, Desmarais JA, Murphy BD. Embryonic diapause and its regulation. Reproduction. 2004; 128(6): 669-678.
  • 20. Massague J, Obenauf AC. Metastatic colonization by circulating tumour cells. Nature. 2016; 529(7586): 298-306.
  • 21. Mead RA. Delayed implantation in mustelids, with special emphasis on the spotted skunk. Journal of Reproduction and Fertility. 1981; 29: 11-24.
  • 22. Mead RA. Embryonic diapause in vertebrates. Journal of Experimental Zoology. 1993; 266(6): 629-641.
  • 23. Murphy BD. Progress and challenges in the physiology of reproduction in furbearing carnivores (A review). Norwegian Journal of Agricultural Sciences. 1992.
  • 24. Murphy BD. Embryonic Diapause: Advances in Understanding the Enigma of Seasonal Delayed Implantation. Reproduction in Domestic Animals. 2012; 47: 121-124.
  • 25. Pritchett‐Corning KR, Clifford CB, Festing MF. The effects of shipping on early pregnancy in laboratory rats. Birth Defects Research Part B: Developmental and Reproductive Toxicology. 2013; 98(2): 200-205.
  • 26. Ptak GE, Modlinski JA, Loi P. Embryonic diapause in humans: time to consider? Reproductive Biology and Endocrinology. 2013; 11(1): 1-4.
  • 27. Ptak GE, Tacconi E, Czernik M, Toschi P, Jacek AM, Pasqualino L. Embryonic diapause is conserved across mammals. PloS One. 2012; 7(3): e33027.
  • 28. Renfree MB. Proteins in the uterine secretions of the marsupial Macropusm eugeneii. Developmental Biology. 1973; 32(1): 41-49.
  • 29. Renfree MB. Embryonic diapause in marsupials. Journal of Reproduction and Fertility. 1981; 29: 67-78.
  • 30. Renfree MB, Fenelon JC. The enigma of embryonic diapause. Development. 2017; 144(18): 3199-3210.
  • 31. Renfree MB, Shaw G. Diapause. Annual Review of Physiology. 2000; 62(1): 353-375.
  • 32. Saadeldin IM. Fertilized embryo diapause, revisited. Journal of Assisted Reproduction and Genetics. 2020; 1-2.
  • 33. Sandell M. The evolution of seasonal delayed implantation. The Quarterly Review of Biology. 1990; 65(1): 23-42.
  • 34. Sherman MI, Barlow PW. Deoxyribonucleic acid content in delayed mouse blastocysts. Reproduction. 1972; 29(1): 123-126.
  • 35. Winkle LJ, Tesch JK, Shah A, Campione AL. System B0, amino acid transport regulates the penetration stage of blastocyst implantation with possible long-term developmental consequences through adulthood. Human Reproduction Update. 2006; 12(2): 145-157.
  • 36. Yoshinaga K, Adams CE. Delayed implantation in the spayed, progesterone treated adult mouse. Reproduction. 1966; 12(3): 593-595.
  • 37. Zhang C, Murphy BD. Progesterone is critical for the development of mouse embryos. Endocrine. 2014; 46(3): 615-623.
Year 2021, Volume: 6 Issue: 1, 34 - 40, 30.04.2021
https://doi.org/10.24880/maeuvfd.835288

Abstract

Supporting Institution

YOKTUR

Project Number

YOKTUR

Thanks

YOKTUR

References

  • 1. Bulut-Karslioglu A, Biechele S, Jin H, Macrae TA, Hejna M, Gertsentein M, et al. Inhibition of mTOR induces a paused pluripotent state. Nature. 2016; 540: 119-123.
  • 2. Deng L, Li C, Chen L, Liu Y, Hou R, Zhou X, et al. Research advances on embryonic diapause in mammals. Animal Reproduction Science. 2018; 198: 1-10.
  • 3. Desmarais JA, Bordignon V, Lopes FL, Smith LC, Murphy BD. The escape of the mink embryo from obligate diapause. Biology of Reproduction. 2004; 70 (3): 662-670.
  • 4. Enders AC, Schlafke S, Hubbard NE, Mead RA. Morphological changes in the blastocyst of the western spotted skunk during activation from delayed implantation. Biology of Reproduction. 1986; 34(2): 423-437.
  • 5. Fenelon JC, Banerjee A, Lefèvre P, Gration F, Murphy BD. Polyamine-mediated effects of prolactin dictate emergence from mink obligate embryonic diapause. Biology of Reproduction. 2016; 95(1): 1-13.
  • 6. Fenelon JC, Lefèvre P, Banerjee A, Murphy BD. Regulation of diapause in carnivore. Reproduction in Domestic Animals. 2016; 51(3): 1-6.
  • 7. Fenelon JC, Banerjee A, Murphy BD. Embryonic diapause: development on hold. International Journal of Developmental Biology. 2014; 58(2-3-4): 163-174.
  • 8. Fenelon JC, Renfree MB. The history of the discovery of embryonic diapause in mammals. Biology of Reproduction. 2018; 99(1): 242-251.
  • 9. Hamatani T, Daikoku T, Wang H, Matsumoto H, Carter MG, Ko MSH et al. Global gene expression analysis identifies molecular pathways distinguishing blastocyst dormancy and activation. Proceedings of the National Academy of Sciences. 2004; 101(28): 10326-10331.
  • 10. Harper MJK. Sperm and egg transport. Germ cells and fertilization, Edn 2, Cambridge University Press, Cambridge. 1982.
  • 11. Harvey MB, Leco KJ, Arcellana-Panlilio MY, Zhang X, Edwards DR, Schultz GA. Endocrinology and paracrinology: Roles of growth factors during peri-implantation development. Human Reproduction. 1995; 10(3): 712-718.
  • 12. Hondo E, Stewart CL. Profiling gene expression in growth-arrested mouse embryos in diapause. Genome Biology. 2005; 6(1): 1-4.
  • 13. Hussein AM, Wang Y, Mathieu J, Margaretha L, Song C, Jones DC et al. Metabolic control over mTOR-dependent diapause-like state. Developmental Cell. 2020; 52(2): 236-250.
  • 14. Kane MT, Morgan PM, Coonan C. Peptide growth factors and preimplantation development. Human Reproduction Update. 1997; 3(2): 137-157.
  • 15. Kondoh E, Okamoto T, Higuchi T, Tatsumi K, Baba T, Murphy SK et al. Stress affects uterine receptivity through an ovarian-independent pathway. Human Reproduction. 2009; 24(4): 945-953.
  • 16. Leese HJ, Baumann CG, Brison DR, McEvoy TG, Sturmey RG. Metabolism of the viable mammalian embryo: quietness revisited. Molecular Human Reproduction. 2008; 14(12): 667-672.
  • 17. Lefevre PL, Palin MF, Chen G, Turecki G, Murphy. Polyamines are implicated in the emergence of the embryo from obligate diapause. Endocrinology. 2011; 152(4): 1627-1639.
  • 18. Liu WM, Pang RT, Cheong AWY, Ng EHY, Kaiqin L, Kai-Fai L et al. Involvement of microRNA lethal-7a in the regulation of embryo implantation in mice. PloS One. 2012: 7(5): e37039.
  • 19. Lopes FL, Desmarais JA, Murphy BD. Embryonic diapause and its regulation. Reproduction. 2004; 128(6): 669-678.
  • 20. Massague J, Obenauf AC. Metastatic colonization by circulating tumour cells. Nature. 2016; 529(7586): 298-306.
  • 21. Mead RA. Delayed implantation in mustelids, with special emphasis on the spotted skunk. Journal of Reproduction and Fertility. 1981; 29: 11-24.
  • 22. Mead RA. Embryonic diapause in vertebrates. Journal of Experimental Zoology. 1993; 266(6): 629-641.
  • 23. Murphy BD. Progress and challenges in the physiology of reproduction in furbearing carnivores (A review). Norwegian Journal of Agricultural Sciences. 1992.
  • 24. Murphy BD. Embryonic Diapause: Advances in Understanding the Enigma of Seasonal Delayed Implantation. Reproduction in Domestic Animals. 2012; 47: 121-124.
  • 25. Pritchett‐Corning KR, Clifford CB, Festing MF. The effects of shipping on early pregnancy in laboratory rats. Birth Defects Research Part B: Developmental and Reproductive Toxicology. 2013; 98(2): 200-205.
  • 26. Ptak GE, Modlinski JA, Loi P. Embryonic diapause in humans: time to consider? Reproductive Biology and Endocrinology. 2013; 11(1): 1-4.
  • 27. Ptak GE, Tacconi E, Czernik M, Toschi P, Jacek AM, Pasqualino L. Embryonic diapause is conserved across mammals. PloS One. 2012; 7(3): e33027.
  • 28. Renfree MB. Proteins in the uterine secretions of the marsupial Macropusm eugeneii. Developmental Biology. 1973; 32(1): 41-49.
  • 29. Renfree MB. Embryonic diapause in marsupials. Journal of Reproduction and Fertility. 1981; 29: 67-78.
  • 30. Renfree MB, Fenelon JC. The enigma of embryonic diapause. Development. 2017; 144(18): 3199-3210.
  • 31. Renfree MB, Shaw G. Diapause. Annual Review of Physiology. 2000; 62(1): 353-375.
  • 32. Saadeldin IM. Fertilized embryo diapause, revisited. Journal of Assisted Reproduction and Genetics. 2020; 1-2.
  • 33. Sandell M. The evolution of seasonal delayed implantation. The Quarterly Review of Biology. 1990; 65(1): 23-42.
  • 34. Sherman MI, Barlow PW. Deoxyribonucleic acid content in delayed mouse blastocysts. Reproduction. 1972; 29(1): 123-126.
  • 35. Winkle LJ, Tesch JK, Shah A, Campione AL. System B0, amino acid transport regulates the penetration stage of blastocyst implantation with possible long-term developmental consequences through adulthood. Human Reproduction Update. 2006; 12(2): 145-157.
  • 36. Yoshinaga K, Adams CE. Delayed implantation in the spayed, progesterone treated adult mouse. Reproduction. 1966; 12(3): 593-595.
  • 37. Zhang C, Murphy BD. Progesterone is critical for the development of mouse embryos. Endocrine. 2014; 46(3): 615-623.
There are 37 citations in total.

Details

Primary Language English
Subjects Health Care Administration
Journal Section Reviews
Authors

Mesut Çevik 0000-0002-0754-6116

Merve Deniz Genç This is me 0000-0002-7822-2100

Project Number YOKTUR
Publication Date April 30, 2021
Submission Date December 3, 2020
Published in Issue Year 2021 Volume: 6 Issue: 1

Cite

APA Çevik, M., & Genç, M. D. (2021). Embryonic Diapause. Veterinary Journal of Mehmet Akif Ersoy University, 6(1), 34-40. https://doi.org/10.24880/maeuvfd.835288