Nuclear proteins such as transcription and chromatin remodeling factors are required for initiation of transcription in early embryos before embryonic genome activation. The nuclear transport of these proteins is mediated by transport factors such as importins. Through analysis of expressed sequence tags from a bovine oocyte cDNA library, we identified a new member of the importin alpha family (named importin alpha8). The cloned cDNA for bovine importin alpha8 (KPNA7) is 1817 base pair in length, encoding a protein of 522 amino acids that contains a conserved importin beta-binding domain and seven armadillo motifs. The RT-PCR analysis revealed that KPNA7 mRNA is specifically expressed in ovaries and mature oocytes. Real-time PCR demonstrated that KPNA7 expression in germinal vesicle (GV) oocytes is 33 to 2396 times higher than that of other importin alpha genes and that KPNA7 mRNA is abundant in GV and metaphase II oocytes, as well as in early-stage embryos collected before embryonic genome activation, but is barely detectable in morula- and blastocyst-stage embryos. Similarly, expression of KPNA7 protein is very high in oocytes and early embryos but is low in blastocysts. A glutathione S-transferase pull-down assay revealed that KPNA7 has a strong binding affinity for the nuclear protein nucleoplasmin 2 relative to that of other importin alphas. RNA interference experiments demonstrated that knockdown of KPNA7 in early embryos results in a decreased proportion of embryos developing to the blastocyst stage. These results suggest that KPNA7 may have an important role in the transport of essential nuclear proteins required for early embryogenesis.
Previous studies established a positive relationship between oocyte competence and follistatin mRNA abundance. Herein, we used the bovine model to test the hypothesis that follistatin plays a functional role in regulation of early embryogenesis. Treatment of early embryos with follistatin during in vitro culture (before embryonic genome activation) resulted in a dose-dependent decrease in time to first cleavage, increased numbers of blastocysts, and increased blastocyst total and trophectoderm cell numbers. To determine the requirement of endogenous follistatin for early embryogenesis, follistatin ablation/replacement studies were performed. Microinjection of follistatin small interfering RNA into zygotes reduced follistatin mRNA and protein and was accompanied by a reduction in number of embryos developing to eight- to 16-cell and blastocyst stages and reduced blastocyst total and trophectoderm cell numbers. Effects of follistatin ablation were rescued by culture of follistatin small interfering RNA-injected embryos in the presence of exogenous follistatin. To investigate whether follistatin regulation of early embryogenesis is potentially mediated via inhibition of endogenous activin activity, the effects of treatment of embryos with exogenous activin, SB-431542 (inhibitor of activin, TGF-beta, and nodal type I receptor signaling) and follistatin plus SB-431542 were investigated. Activin treatment mimicked positive effects of follistatin on time to first cleavage and blastocyst development, whereas negative effects of SB-431542 treatment were observed. Stimulatory effects of follistatin on embryogenesis were not blocked by SB-431542 treatment. Results support a functional role for oocyte-derived follistatin in bovine early embryogenesis and suggest that observed effects of follistatin are likely not mediated by classical inhibition of activin activity.
The present study was undertaken to discover molecular markers in bovine cumulus cells predictive of oocyte competence and to elucidate their functional significance. Differences in RNA transcript abundance in cumulus cells harvested from oocytes of adult versus prepubertal animals (a model of poor oocyte quality) were identified by microarray analysis. Four genes of interest encoding for the lysosomal cysteine proteinases cathepsins B, S, K, and Z and displaying greater transcript abundance in cumulus cells surrounding oocytes harvested from prepubertal animals were chosen for further investigation. Greater mRNA abundance for such genes in cumulus cells of prepubertal oocytes was confirmed by real-time RT-PCR. Elevated transcript abundance for cathepsins B, S, and Z also was observed in cumulus cells surrounding adult metaphase II oocytes that developed to the blastocyst stage at a low percentage following parthenogenetic activation versus those that developed at a high percentage. Functional significance of cumulus cell cathepsin expression to oocyte competence was confirmed by treatment of cumulus-oocyte complexes during in vitro oocyte maturation with a cell-permeable cysteine proteinase (cathepsin) inhibitor. Inhibitor treatment decreased apoptotic nuclei in the cumulus layer and enhanced development of parthenogenetically activated and in vitro-fertilized adult oocytes to the blastocyst stage. Stimulatory effects of inhibitor treatment during meiotic maturation on subsequent embryonic development were not observed when oocytes were matured in the absence of cumulus cells. The present results support a functional role for cumulus cell cathepsins in compromised oocyte competence and suggest that cumulus cell cathepsin mRNA abundance may be predictive of oocyte quality.
Oocyte-specific gene products play a key role in regulation of fertility in mammals. Here, we describe the discovery, molecular characterization, and function of JY-1, a bovine oocyte-expressed gene shown to regulate both function of ovarian granulosa cells and early embryogenesis in cattle and characteristics of JY-1 loci in other species. The JY-1 gene encodes for a secreted protein with multiple mRNA transcripts containing an identical ORF but differing lengths of 3 UTR. JY-1 mRNA and protein are oocyte-specific and detectable throughout folliculogenesis. Recombinant JY-1 protein regulates function of follicle-stimulating hormone-treated ovarian granulosa cells, resulting in enhanced progesterone synthesis accompanied by reduced cell numbers and estradiol production. JY-1 mRNA of maternal origin is also present in early bovine embryos, temporally regulated during the window from meiotic maturation through embryonic genome activation, and is required for blastocyst development. The JY-1 gene has three exons and is located on bovine chromosome 29. JY-1-like sequences are present on syntenic chromosomes of other vertebrate species, but lack exons 1 and 2, including the protein-coding region, suggestive of species specificity in evolution and function of this oocyte-specific gene.T he oocyte is a key regulator of multiple aspects of female fertility, including ovarian follicular development and early embryogenesis (1). The advent of oocyte genomics and EST sequencing projects have led to a dramatic increase in our understanding about the identities and functions of oocytespecific genes in female reproduction (2, 3). However, inherent species-specific differences exist in the ovulation quota, follicular waves, duration of the ovarian cycle, and number of embryonic cell cycles required for embryonic genome activation (4) between the traditional animal model (polyovulatory mouse) versus monoovulatory species such as cattle and primates, including humans. Numerous examples suggest that oocytespecific genes identified in the mouse may not have identical functions in other species. For instance, Belclare and Cambridge ewes with naturally occurring heterozygous mutations in the GDF9 gene have an increased ovulation rate and litter size (5), but mice heterozygous for the GDF9 gene disruption exhibit no obvious phenotype (6). Similarly, Inverdale and Hanna strains of sheep with homozygous mutations in BMP15 are infertile (7, 8), whereas homozygous BMP15 mutant mice are subfertile with defects in ovulation and fertilization (9). Thus, comparative genomics approaches coupled to functional studies in nontraditional model systems are needed to address dissimilarities in transcriptome composition between model organisms and provide information on existence of genes or gene families that may play important regulatory roles in fertility in nonmurine models, including the human. With this goal in mind, we previously constructed a bovine oocyte cDNA library and sequenced a number of ESTs (2). A highly abundant transcript (designat...
BackgroundOocyte-derived maternal RNAs drive early embryogenesis when the newly formed embryo is transcriptionally inactive. Recent studies in zebrafish have identified the role of microRNAs during the maternal-to-embryonic transition (MET). MicroRNAs are short RNAs that bind to the 3' UTR of target mRNAs to repress their translation and accelerate their decay. Newborn ovary homeobox gene (NOBOX) is a transcription factor that is preferentially expressed in oocytes and essential for folliculogenesis in mice. NOBOX knockout mice are infertile and lack of NOBOX disrupts expression of many germ-cell specific genes and microRNAs. We recently reported the cloning and expression of bovine NOBOX during early embryonic development and our gene knockdown studies indicate that NOBOX is a maternal effect gene essential for early embryonic development. As NOBOX is a maternal transcript critical for development and NOBOX is depleted during early embryogenesis, we hypothesized that NOBOX is targeted by microRNAs for silencing and/or degradation.ResultsUsing an algorithm "MicroInspector", a potential microRNA recognition element (MRE) for miR-196a was identified in the 3' UTR of the bovine NOBOX mRNA. Expression analysis of miR-196a in bovine oocytes and during early embryonic development indicated that it is expressed both in oocytes and embryos and tends to increase at the four-cell and eight-cell stages. Ectopic expression of NOBOX and miR-196a in HeLa cells inhibited the expression of NOBOX protein compared to the control cells without miR-196a. Similarly, the activity of a luciferase construct containing the entire 3' UTR of bovine NOBOX was suppressed, and the regulation was abolished by mutations in the miR-196a binding site indicating that the predicted MRE is critical for the direct and specific binding of miR-196a to the NOBOX mRNA. Furthermore, ectopic expression of miR-196a mimic in bovine early embryos significantly reduced the NOBOX expression at the both mRNA and protein levels.ConclusionCollectively, our results demonstrate that miR-196a is a bona fide negative regulator of NOBOX during bovine early embryogenesis.
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