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ABSTRACT: Early preimplantation embryos are sensitive to external osmolarity and use novel mechanisms to accumulate organic osmolytes and thus control their cell volumes and maintain viability. However, these mechanisms are restricted to the cleavage stages of development, and it was unknown whether postcompaction embryos use organic osmolytes. Mouse embryos developing from the 8-cell stage formed blastocoel cavities in vitro at osmolarities up to 360 mOsM. Above this range, several putative organic osmolytes (alanine, glutamine, glycine, and beta-alanine) rescued blastocyst development, but several effective osmoprotectants in cleavage-stage embryos (such as betaine and proline) did not. At physiological osmolarities, each of these compounds resulted in significantly larger blastocysts. This was not due to increased cell numbers, which were unaffected in blastocysts by osmolarity in the range where blastocyst size was rescued by potential organic osmolytes, although cell number was decreased at higher osmolarities and was rescued by each osmolyte. The effective osmolytes were accumulated intracellularly by embryos developing in vitro from the 8-cell stage to blastocysts. However, unlike conventional organic osmolytes in somatic cells or those in cleavage-stage embryos, their intracellular concentrations were not increased with increasing external osmolarity. With the exception of beta-alanine, which is taken up via the beta-amino acid transport system, the effective osmolytes were transported by the B(0,+) system, which becomes highly active in blastocysts. The intracellular accumulation of these osmolytes in postcompaction embryos thus appears to support optimal development and blastocyst expansion at physiological osmolarities and may contribute to the embryo's ability to withstand stress.
Biology of Reproduction 12/2009; 82(4):769-77. · 4.01 Impact Factor
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ABSTRACT: Fertilized mouse eggs regulate their size principally by accumulating glycine as an intracellular osmolyte using the GLYT1 (SLC6A9) transporter, a mechanism of cell volume homeostasis apparently unique to early embryos before the morula stage. However, nothing was known of cell volume regulation in oocytes before fertilization. We show here that GLYT1 is quiescent in mouse germinal-vesicle-stage oocytes but becomes fully activated within hours after ovulation is triggered. This initiates accumulation of substantial amounts of intracellular glycine in oocytes during meiotic progression, reaching a maximal level in mature eggs. Measurements of endogenous free glycine showed that there were nearly undetectable levels in ovarian germinal-vesicle-stage oocytes, but high levels were present in mature ovulated eggs and in preimplantation embryos through the two-cell stage, but not in morulae. Furthermore, intracellular glycine was regulated in response to changes in external tonicity in eggs and embryos through the two-cell stage, but not in oocytes or embryos after the two-cell stage. Before activation of GLYT1, oocytes were unable to independently regulate their volume. As GLYT1 became active, however, oocyte volume decreased substantially and oocytes gained the ability to regulate their size, which required GLYT1 activity. Before ovulation, oocyte size was instead determined by a strong adhesion to the rigid extracellular matrix of the oocyte, the zona pellucida, which was released coincident with GLYT1 activation. The ability to acutely regulate cell size is thus acquired by the oocyte only after ovulation, when it first develops glycine-dependent cell volume regulation.
Development 08/2009; 136(13):2247-54. · 6.60 Impact Factor
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ABSTRACT: One-cell-stage embryos derived from most random-bred and inbred female mice exhibit an in vitro developmental block at the two-cell stage in classical embryo culture media. However, embryos derived from many F1 hybrids develop easily past the two-cell stage under the same conditions. This has given rise to the commonly accepted idea that there exist blocking and nonblocking types of female mice, with only the former being prone to a two-cell block. Recently, culture media have been improved to the point that even embryos prone to the two-cell block will develop past the block in vitro, making it possible to study its etiology. Here, we show that either increased osmolarity or increased glucose/phosphate levels induced the expected two-cell block in random-bred CF1 embryos and the two-cell block at increased osmolarities could be rescued by the organic osmolyte glycine. Surprisingly, one-cell embryos from B6D2F1 (BDF1) F1 hybrid females, considered to be nonblocking, also became blocked at the two-cell stage when osmolarity or glucose/phosphate levels were increased. They were also similarly rescued by glycine from the osmolarity-induced block. The most evident difference was that the purportedly nonblocking embryos became blocked at a higher threshold of osmolarity or glucose/phosphate level than those considered prone to this developmental block. Thus, both blocking and nonblocking embryos actually exhibit a similar two-cell block to development.
Biology of Reproduction 02/2005; 72(1):179-87. · 4.01 Impact Factor
