Blastocoel

A blastocoel (/ˈblæstəˌsl/),[2][3] also spelled blastocoele and blastocele, and also called blastocyst cavity[4] (or cleavage or segmentation cavity) is a fluid-filled cavity that forms in the blastula (blastocyst) of early amphibian and echinoderm embryos, or between the epiblast and hypoblast of avian, reptilian, and mammalian blastoderm-stage embryos.

Blastocoel
Mammalian blastocoel[1]

Schematic diagram showing the blastocyst, with its embryoblast (inner cell mass) and its trophoblast layer, alongside the surface of the endometrium.[1]
Details
Carnegie stage3
Days5
Precursormorula[1]
Gives rise togastrula,[1]
primitive yolk sac[1]
Anatomical terminology

It results from cleavage of the oocyte (ovum) after fertilization.[5][6] It forms during embryogenesis,[6] as what has been termed a "Third Stage" after the single-celled fertilized oocyte (zygote, ovum[1]) has divided into 16-32 cells,[5] via the process of mitosis.[7] It can be described as the first cell cavity formed as the embryo enlarges,[7] the essential precursor for the differentiated, topologically distinct, gastrula.[1]

Amphibian blastocoel

An amphibian embryo in the 128- cell stage is considered a blastula as the blastocoel in the embryo becomes apparent during this stage. The fluid-filled cavity forms in the animal hemisphere of the frog. However, the early formation of the blastocoel has been traced back to the very first cleavage furrow. It was demonstrated in the frog embryo that the first cleavage furrow widens in the animal hemisphere creating a small intercellular cavity that is sealed off via tight junctions.[6] As cleavage continues, the cavity expands to become the developed blastocoel. The blastocoel is a crucial component of amphibian embryo development. It permits cell migration during gastrulation and prevents the cells beneath the blastocoel from interacting prematurely with the cells above the blastocoel. For instance, the blastocoel prevents the vegetal cells destined to become endoderm from coming in contact with those cells in the ectoderm fated to give rise to the skin and nerves.[8]

Damage to blastocoel

The blastocoel can be damaged and abolished if the adhesion between blastomeres, provided by cell adhesion molecules like EP-cadherin, is destroyed as mRNA by oligonucleotides. If the mRNA is destroyed, then there’s no EP-cadherin, little to no blastomere adhesion and the blastocoel is non-existent.[7] During the next stage of embryonic development, amphibian gastrulation, the blastocoel is displaced by the formation of the archenteron, during mid-gastrulation. At the end of gastrulation, the blastocoel has been obliterated.[9]

Sea urchin blastocoel

At the 120- cell stage, the sea urchin embryo is considered a blastula because of its developed blastocoel, which every embryonic cell surrounds and touches. Every cell is in contact with the proteinaceous fluid of the blastocoel on the inside and touches the hyaline layer on the outside. The loosely connected blastomeres are now tightly connected because of tight junctions that create a seamless epithelium that completely encircles the blastocoel.[10] Even as the blastomeres continue to divide, the blastula remains one-cell thick and thins out as the embryo expands outward. This is accomplished in part due to the influx of water that expands the blastocoel and pushes the cells surrounding it outwards. At this point, the cells have become specified and are ciliated on the opposite side of the blastocoel. The vegetal plate and animal hemisphere develop and secrete a hatching enzyme that digests the fertilization envelope and allows the embryo to now become a free-swimming hatched blastula.[11]

Development of primary mesenchyme

Important to the sea urchin blastula is the ingression of the primary mesenchyme. After the blastula hatches from the fertilization envelope, the vegetal side of the blastula begins to flatten and thicken as a small cluster of these cells develop long, thin processes called filopodia. These cells then dissociate and ingress into the blastocoel and are called the primary mesenchyme. The cells move randomly along the inside of the blastocoel, until they become localized in the ventrolateral region of the blastocoel.[11][10]

Mammalian blastocoel

After fertilization, the mammalian cells, called blastomeres, undergo rotational cleavage until they are at the 16-cell stage called the morula. The morula has a small group of internal cells surrounded by a larger group of external cells. These internal cells are called the inner cell mass (ICM) and will go on to become the actual embryo. The external, surrounding cells develop into the trophoblast cells. However, at this stage there is no cavity within the morula; the embryo is still a ball of dividing cells. In a process called cavitation, the trophoblast cells secrete fluid into the morula to create a blastocoel, the fluid-filled cavity. The membranes of the trophoblast cells contain sodium (Na+) pumps, Na+/K+- ATPase and Na+/H+ exchangers, that pump sodium into the centrally forming cavity. The accumulation of sodium pulls in water osmotically, creating and enlarging the blastocoel within the mammalian embryo.[5][6][12] The oviduct cells stimulate these trophoblast sodium pumps as the fertilized egg travels down the fallopian tube towards the uterus.[12] As the embryo further divides, the blastocoel expands and the inner cell mass is positioned on one side of the trophoblast cells forming a mammalian blastula, called a blastocyst.

Avian blastocoel

Similar to mammals, fertilization of the avian ovum occurs in the oviduct. From there the blastodisc, a small cluster of cells in the animal pole of the egg, then undergoes discoidal meroblastic cleavage. The blastoderm develops into the epiblast and hypoblast and it is between these layers that the blastocoel will form. The shape and formation of the avian blastodisc differs from amphibian, fish, and echinoderm blastulas, but the overall spatial relationship of the blastocoel remains the same.[1]

Formation of primitive streak

The avian blastocoel is important during the development of the primitive streak. The ingression of the endodermal precursor cells form the epiblast into the blastocoel and the migration of lateral cells of the posterior epiblast towards the center form the early primitive streak. As these cells converge inward, a depression forms called the primitive groove and functions as an opening through which cells travel into the blastocoel. As cells migrate into the blastocoel, they undergo an epithelial-to-mesenchymal transformation.[1]

Zebrafish: a special case

Unlike amphibian, echinoderm, mammalian, and avian embryos, zebrafish do not have a defined blastocoel. Rather, they have small, irregular extracellular spaces that are formed between the cells of the blastodisc sitting atop the yolk.[13]

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See also

Notes

References

  • Borland, Raymond Michael (1977). "Transport processes in the mammalian blastocyst". Development in Mammals. 1: 31–67.CS1 maint: ref=harv (link)
  • Cherr, Gary N.; Baldwin, John D.; Summers, Robert G.; Morrill, John B. (1992). "Preservation and visualization of the sea urchin embryo blastocoelic extracellular matrix". Microscopy Research and Technique. 22 (1): 11–22. doi:10.1002/jemt.1070220104. PMID 1617206.CS1 maint: ref=harv (link)
  • Galileo, Deni S.; Morrill, John B. (1985). "Patterns of cells and extracellular material of the sea urchinLytechinus variegatus (Echinodermata; Echinoidea) embryo, from hatched blastula to late gastrula". Journal of Morphology. 185 (3): 387–402. doi:10.1002/jmor.1051850310.CS1 maint: ref=harv (link)
  • Gilbert, Scott F. (2010). Developmental Biology (9th ed.). Sunderland, MA: Sinauer Associates. ISBN 978-0-87893-384-6.CS1 maint: ref=harv (link)
  • Heasman, Janet; Crawford, Aaron; Goldstone, Kim; Garner-Hamrick, Peggy; Gumbiner, Barry; McCrea, Pierre; Kintner, Chris; Noro, Chikako Yoshida; Wylie, Chris (1994). "Overexpression of cadherins and underexpression of β-catenin inhibit dorsal mesoderm induction in early Xenopus embryos". Cell. 79 (5): 791–803. doi:10.1016/0092-8674(94)90069-8. PMID 7528101.CS1 maint: ref=harv (link)
  • Kalt, Marvin R. (1971). "The relationship between cleavage and blastocoel formation in Xenopus laevis. I. Light microscopic observations". Journal of Embryology and Experimental Morphology. 26 (1): 37–49. PMID 5565077.CS1 maint: ref=harv (link)
  • Kimmel, Charles B.; Ballard, William W.; Kimmel, Seth R.; Ullmann, Bonnie; Schilling, Thomas F. (1995). "Stages of embryonic development of the zebrafish". Developmental Dynamics. 203 (3): 253–310. doi:10.1002/aja.1002030302. PMID 8589427.CS1 maint: ref=harv (link)
  • Nieuwkoop, PD (1973). "The organization center of the amphibian embryo: its origin, spatial organization, and morphogenetic action". Advances in Morphogenesis. 10: 1–39. PMID 4581327.CS1 maint: ref=harv (link)
  • Purcell, SM; Keller, R (1993). "A different type of amphibian mesoderm morphogenesis in Ceratophrys ornata". Development. 117 (1): 307–17. PMID 8223254.CS1 maint: ref=harv (link)
  • Senn, A.; Achoni-Affolter, F.; Dubuis-Grieder, C.; Strauch, E. (April 25, 2007). Ade-Damiano, Manuele (ed.). "Synoptic table of the Carnegie stages 1 - 6". Cours d'embryologie en ligne à l'usage des étudiants et étudiantes en médecine.CS1 maint: ref=harv (link)
  • Wiley, Lynn M. (1984). "Cavitation in the mouse preimplantation embryo: and the origin of nascent blastocoele fluid". Developmental Biology. 105 (2): 330–42. doi:10.1016/0012-1606(84)90290-2. PMID 6090240.CS1 maint: ref=harv (link)

Further reading


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