Abstract

The maternal pool of mRNA undergoes major changes during oocyte maturation and early embryonic development. Specific genes are activated or degraded in response to changes in poly-(A) tail length. However, little is known about how the oocyte targets specific transcripts for degradation or translation in a timely manner. The objective of this study was to determine how poly-(A) tail length of different transcripts is affected in bovine oocytes by time of in vitro maturation. Cyclin B1 and GDF-9 32 untranslated regions (UTRs) were cloned into modified p-GEM plasmids containing a poly-(A) tract of 60 or 0 adenosines (A60 or A0, respectively). Each 32 UTR was transcribed in vitro with (A60) or without (A0) a poly-(A) tail to generate UTP³²-labeled RNA. Transcriptions producing at least 200 000 counts per min (cpm) per µL were used for subsequent injections into denuded bovine oocytes. Cumulus-oocyte complexes (COCs) recovered from slaughterhouse-derived ovaries (n = 216) were vortexed to remove cumulus cells immediately after aspiration, after 3 h of in vitro maturation, or after 19 h of maturation in a chemically defined medium supplemented with FSH, LH, EGF, and cysteamine. After vortexing, denuded oocytes were injected and snap frozen, or matured in vitro for 1 or 3 h. Eight oocytes were injected with ~0.5 nL (~100 cpm/oocyte) labeled RNA at each time point in 3 replicates. Total RNA was isolated from injected oocyte pools and loaded onto a 5% denaturing acrylamide gel for size separation. Radiolabeled A0 was used as a control point of reference for deadenylation. Gels were dried, and RNA was visualized on a phosphoimager after 24 h exposure to a phosphor screen. Changes in polyadenylation status (transcript size) were evaluated by comparing shifts in bands from gene-specific A60