Ealy AD, Pennington KA, Rodina TM. Interferon-tau Polymorphisms and Their Potential Functions in Ruminants. ARBS Annu Rev Biomed Sci 2006;8:9-18. In ruminants, the establishment and maintenance of pregnancy requires production of a Type I interferon, termed IFN-ô. This protein is synthesized by the developing conceptus and interacts with the uterus to promote continued secretion of progesterone. Multiple genes encode IFN-ô, and a majority of these genes are transcribed during early pregnancy. The proteins possess divergent biological activities, including the ability to prevent the corpus luteum from regressing at the end of a normal estrous cycle. In all likelihood multiple IFN-ô isoforms are produced during early pregnancy to ensure that sufficient quantities of bioactive IFN-ô are present to modulate uterine biology during early pregnancy. Although IFN-ô has evolved to serve as the pregnancy recognition hormone in ruminants, other Type I IFNs, such as IFN-á and IFN-ù, are capable of producing a uterine response similar to that of IFN-ô. Hence, the polymorphic nature of IFN-ô genes appear to have generated new and potentially more active forms of the hormone, but the unique expression pattern for IFN-ô is likely the preeminent feature ensuring its use as the maternal recognition of pregnancy factor in ruminants.
Most of the current culture procedures used for bovine in vitro embryo production terminates at the blastocyst stage. Developing procedures for extending embryo lifespan beyond this phase will provide a valuable tool for understanding events that occur during the second week of pregnancy in cattle. The overall objective of the present studies was to identify culture conditions required to support bovine blastocyst development beyond its initial formation. In the first study, individual day 8 blastocysts (day 0 = day of IVF) were cultured until day 11 in 30 µL microdrops of Potassium Simplex Optimized Medium-Bovine Embryo 2 containing 0.1 mm non-essential amino acids or Tissue Culture Medium 199 (M199). Both media were supplemented with 5% [v/v] fetal bovine serum (FBS) and incubations were in an atmosphere of either 5 or 21% (v/v) oxygen. A medium by oxygen interaction (P = 0.007) occurred when assessing cell number on day 11. Blastocysts cultured in M199 and in a 5% O2 environment had greater (P < 0.002) cell numbers (536 � 49) than blastocysts incubated in other conditions (339 � 28). Conditioned medium from blastocysts incubated in 21% O2 contained greater (P < 0.05) concentrations of bioactive interferon-tau (IFNT) than blastocysts incubated in 5% O2 regardless of medium type (70.5 � 28 v. 17.2 � 2.6 ng mL–1). In a follow-up study, blastocysts could remain morphologically viable through day 11 in M199 containing at least 2.5% FBS. To examine whether oxidative stress was responsible for the increase in IFNT production under 21% O2, blastocysts were incubated under a 5% O2 atmosphere in M199 containing 2.5% FBS and increasing concentrations of tert-butylhydroperoxide (tBH), a membrane-permeable oxidative agent. Addition of e3 nm tBH decreased cell numbers but did not increase IFNT concentrations in conditioned medium. To examine whether blastocysts could survive beyond day 11 in culture, day 11 blastocysts were transferred to 400 �L of M199 with 20% FBS under 5% oxygen and cultured from day 11 to 20–21 post-IVF. Half of the medium was replaced every 2–3 days. On day 13–14, 16.6 � 6.1% of blastocysts showed initial signs of degeneration. A portion of blastocysts (32.9 � 9.6%) began attaching to plates on days 13–15 and produced outgrowths that appeared viable on days 20–21. All of the non-attached blastocysts degenerated by day 17–18. No blastocyst elongation was detected. In conclusion, a culture system was developed that sustains blastocyst viability and IFNT production in vitro to day 11. Although this culture system allowed blastocyst survival until day 14, normal conceptus development (i.e. elongation/filamentation) was not achieved. Nonetheless, the culture system provides a useful tool for examining the initial stages of blastocyst development and IFNT production from individual bovine embryos.
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