Assisted reproductive technology (ART) has resulted in more than 5 million births worldwide. However, mainstream ART techniques are not always successful for an estimated 30% of infertile patients in whom gametes are nonviable. Most patients would clearly prefer genetic parenthood, currently possible only via the use of donated gametes or, in future, via the clinical use of artificial gametes (AGs) incorporating parental DNA. Despite much recent progress in the derivation of AGs, significant obstacles remain. Although it is possible to create artificial cells exhibiting some of the molecular and physiological traits of human gametes, they do not yet exhibit the same level of functionality as their in vivo counterparts. Most current effort pays scant attention to confirmation of molecular integrity and clinical applicability of AGs. Here we discuss the various clinical parameters used to assess gamete and embryo viability and discuss markers of gamete function that may be used within future studies attempting to derive AGs. The use of AGs may prove controversial to some members of the general public, and, as such, there is significant need for an appropriate ethical and legal framework governing the clinical use of such cells. However, provided these issues can be successfully overcome, it is highly likely that AGs will represent powerful biological tools for reproductive science, a valuable training resource for embryologists and for potential use in the clinical treatment of human infertility.

WNT4 is required for normal ovarian follicle development and female fertility in mice, but how its signal is transduced remains unknown. Fzd1 encodes a WNT receptor whose expression is markedly induced in both mural granulosa cells and cumulus cells during the preovulatory period, in a manner similar to Wnt4. To study the physiological roles of FZD1 in ovarian physiology and to determine whether it serves as receptor for WNT4, Fzd1-null mice were created by gene targeting. Whereas rare Fzd1^−/− females were sterile because of uterine fibrosis and ovarian tubulostromal hyperplasia, most were subfertile, producing ≈1 fewer pup per litter on average relative to controls. Unlike WNT4-deficient mice, ovaries from Fzd1^−/− mice had normal weights, numbers of follicles, steroid hormone production, and WNT4 target gene expression levels. Microarray analyses of granulosa cells from periovulatory follicles revealed few genes whose expression was altered in Fzd1^−/− mice. However, gene expression analyses of cumulus-oocyte complexes (COCs) revealed a blunted response of both oocyte (Zp3, Dppa3, Nlrp5, and Bmp15) and cumulus (Btc, Ptgs2, Sema3a, Ptx3, Il6, Nts, Alcam, and Cspg2) genes to the ovulatory signal, whereas the expression of these genes was not altered in WNT4-deficient COCs from Wnt4^{tm1.1Boer/tm1.1Boer};Tg (CYP19A1-cre)1Jri mice. Despite altered gene expression, cumulus expansion appeared normal in Fzd1^−/− COCs both in vitro and in vivo. Together, these results indicate that Fzd1 is required for normal female fertility and may act in part to regulate oocyte maturation and cumulus cell function, but it is unlikely to function as the sole ovarian WNT4 receptor.

Ovarian growth (vitellogenesis) in most lower vertebrates is mediated by estradiol-17beta (E2) secreted by the follicles in response to follicle-stimulating hormone (Fsh), whereas oocyte maturation and ovulation are mediated by progestins, such as 17alpha,20beta-dihydroxypregn-4-en-3-one (17,20beta-P), produced in response to luteinizing hormone (Lh). In teleosts, follicular synthesis of 17,20beta-P at the time of maturation is due primarily to up-regulation of the enzymes P450c17-II (Cyp17a2) and 20beta-hydroxysteroid dehydrogenase (Cbr1). Here, we show that follicular cells associated with primary growth (previtellogenic) oocytes of the gilthead seabream also express cyp17a2 and cbr1, in addition to P450c17-I (cyp17a1) and aromatase (cyp19a1), enzymes required for E2 synthesis. Ovaries containing only oogonia and early primary ovarian follicles had a 60-fold higher concentration of 17,20beta-P than ovaries in the succeeding stages and had a higher expression of cbr1 and Fsh receptor (fshra). Stimulation of explants of primary follicles in vitro with recombinant piscine Fsh (rFsh), which specifically activates the seabream Fshra, promoted a rapid accumulation of 17,20beta-P, and synthesis was sustained by an external supply of 17alpha-hydroxyprogesterone. In the presence of Cbr1 inhibitors, rFsh-mediated 17,20beta-P production was reduced, with a concomitant increase in testosterone and E2 synthesis. In primary explants, rFsh up-regulated cyp17a2 and cbr1 transcription and simultaneously down-regulated cyp17a1 and cyp19a1 steady-state mRNA levels within 24 h. In contrast, in explants containing vitellogenic follicles, rFsh had no effect on cyp17a2 and cbr1 expression, but increased that of cyp17a1 and cyp19a1. These data suggest a functional Fshra-activated Cyp17a2/Cbr1 steroidogenic pathway in gilthead seabream primary ovarian follicles triggering the production of 17,20beta-P.

Reduced oocyte competence causes the lower fertility reported in domestic sows during the warm months of the year. Somatic cells express heat shock proteins (HSPs) to protect themselves from damage caused by thermal stress. HSPs are classified as molecular chaperones and control the correct folding of newly synthesized or damaged proteins. The present work performed a comprehensive survey of the different components of the heat shock chaperone machinery in the pig ovary, which included the HSP40, HSP70, HSP90, and HSP110 families, as well as heat shock factors (HSF) 1 and 2. Pig ovarian follicles constitutively expressed different members of these families; therefore, we examined their ability to respond to heat stress. In order to take into account the role of the complex follicular architecture, whole pig ovaries were exposed to 41.5°C for 1 h. This exposure significantly disrupted oocyte maturation and determined the upregulation of the HSP70, HSP40, HSPH1, HSPA4, HSPA4L, HSF1, and HFS2 genes, whereas expression levels of HSP90A and HSP90B, as well as those of genes unrelated to heat stress were not altered. Unexpectedly HSP and HSF expression levels changed only in oocytes but not in cumulus cells. Cumulus-oocyte complexes isolated from ovaries collected in summer showed the same pattern as those collected in winter. We conclude that the HSP chaperone machinery is constitutively fully operational in the pig ovary. However, following thermal stimuli or seasonal variations, cumulus cell HS-related gene expression remains unchanged, and only oocytes activate a response, suggesting why this mechanism is insufficient to preserve their competence both in vitro and in vivo.

Luteolysis is characterized by angioregression, luteal cell apoptosis, and remodeling of the extracellular matrix characterized by deposition of collagen 1. Transforming growth factor beta 1 (TGFB1) is a potent mediator of wound healing and fibrotic processes through stimulation of the synthesis of extracellular matrix components. We hypothesized that TGFB1 stimulates profibrotic activities of luteal fibroblasts. We examined the actions of TGFB1 on luteal fibroblast proliferation, extracellular matrix production, floating gel contraction, and chemotaxis. Fibroblasts were isolated from the bovine corpus luteum. Western blot analysis showed that luteal fibroblasts expressed collagen 1 and prolyl 4-hydroxylase but did not express markers of endothelial or steroidogenic cells. Treatment of fibroblasts with TGFB1 stimulated the phosphorylation of SMAD2 and SMAD3. [³H]thymidine incorporation studies showed that TGFB1 caused concentration-dependent reductions in DNA synthesis in luteal fibroblasts and significantly (P < 0.05) reduced the proliferative effect of FGF2 and fetal calf serum. However, TGFB1 did not reduce the viability of luteal fibroblasts. Treatment of luteal fibroblasts with TGFB1 induced the expression of laminin, collagen 1, and matrix metalloproteinase 1 as determined by Western blot analysis and gelatin zymography of conditioned medium. TGFB1 increased the chemotaxis of luteal fibroblasts toward fibronectin in a transwell system. Furthermore, TGFB1 increased the fibroblast-mediated contraction of floating bovine collagen 1 gels. These results suggest that TGFB1 contributes to the structural regression of the corpus luteum by stimulating luteal fibroblasts to remodel and contract the extracellular matrix.

This study tested the hypothesis that oocyte aging could be prevented for a longer time by reducing the culture temperature while supplementing the culture medium with more pyruvate. Newly ovulated mouse oocytes were cultured at various temperatures for various times in HCZB medium (Kimura and Yanagimachi, Biol Reprod 1995; 52:709–720) containing various concentrations of pyruvate before examining for aging parameters and developmental potential. The increase in susceptibility to activating stimuli was efficiently prevented when oocytes were cultured in HCZB with 10.27 mM pyruvate at 37°C for 6 h, 25°C for 24 h, 15°C for 96 h, and 5°C for 48 h. Satisfactory blastocyst development of both parthenotes and fertilized zygotes was achieved after oocyte culture in HCZB containing 10.27 mM pyruvate at 37°C for 6 h, 25°C for 24 h, 15°C for 36 h, and 5°C for 24 h. Transfer of two-cell embryos or blastocysts showed no difference between newly ovulated control oocytes and oocytes cultured at 15°C for 36 h in either term pregnancy, live young per pregnant recipient, live young/transferred embryos, or birth weight of young. Oocytes with impaired developmental potential after culture at 15°C for 96 h and at 5°C for 48 h showed unrecoverable decreases in the content of glutathione, the glutathione/oxidized glutathione ratio, the BCL2 content, and in the numbers of oocytes with normal spindles and cortical granule distribution, suggesting induction of oxidative stress, which caused oocyte apoptosis and cytoskeleton alterations by downregulating BCL2. Because oocytes cultured at 15°C for 36 h were activated or fertilized after a 6-h recovery culture, aging of ovulated mouse oocytes has been successfully prevented for 42 h without impairing their developmental potential.

The oxidative modification of gametes by a reactive oxygen species is a major deleterious factor that decreases the successful rate of in vitro fertilization. Superoxide dismutase 1 (SOD1) plays a pivotal role in antioxidation by scavenging the superoxide anion, and its deficiency causes infertility in female mice, but the significance of the enzyme in male mice remains unclear. In the present study, we characterized Sod1^−/− (Sod1-KO) male reproductive organs and compiled the first report of the impaired fertilizing ability of Sod1-KO sperm in in vitro fertilization. Insemination of wild-type oocytes with Sod1-KO sperm exhibited lower rates of fertility compared with insemination by wild-type sperm. The low fertilizing ability found for Sod1-KO sperm was partially rescued by reductant 2-mercaptoethanol, which suggested the oxidative modification of sperm components. The numbers of motile and progressive sperm decreased during the in vitro fertilization process, and a decline in ATP content and elevation in lipid peroxidation occurred in the Sod1-KO sperm in an incubation time-dependent manner. Tyrosine phosphorylation, which is a hallmark for sperm capacitation, was also impaired in the Sod1-KO sperm. These results collectively suggest that machinery involved in sperm capacitation and motility are vulnerable to oxidative damage during the in vitro fertilization process, which could increase the rate of inefficient fertilization.

Remodeling of the cervix is a critical early component of parturition and resembles an inflammatory process. Infiltration and activation of myeloid immune cells along with production of proinflammatory mediators and proteolytic enzymes are hypothesized to regulate cervical remodeling as pregnancy nears term. The present study standardized an approach to assess resident populations of immune cells and phenotypic markers of functional activities related to the mechanism of extracellular matrix degradation in the cervix in preparation for birth. Analysis of cells from the dispersed cervix of mice that were nonpregnant or pregnant (Days 15 and 18 postbreeding) by multicolor flow cytometry indicated increased total cell numbers with pregnancy as well as increased numbers of macrophages, the predominant myeloid cell, by Day 18, the day before birth. The number of activated macrophages involved in matrix metalloproteinase induction (CD147) and signaling for matrix adhesion (CD169) significantly increased by the day before birth. Expression of the adhesion markers CD54 and CD11b by macrophages decreased in the cervix by Day 18 versus that on Day 15 or in nonpregnant mice. The census of cells that expressed the migration marker CD62L was unaffected by pregnancy. The data suggest that remodeling of the cervix at term in mice is associated with recruitment and selective activation of macrophages that promote extracellular matrix degradation. Indices of immigration and activities by macrophages may thus serve as markers for local immune cell activity that is critical for ripening of the cervix in the final common mechanism for parturition at term.

The effectiveness of ex situ breeding programs for endangered species can be limited by challenges in mimicking mating competitions that naturally occur among multiple mates in the wild. The objective of this study was to evaluate the impact of timed natural matings and/or artificial inseminations in the context of the urinary estrogen surge on cub production in the giant panda (Ailuropoda melanoleuca). We used a large cohort of giant pandas, including 12 females and 17 males. DNA paternity exclusion was used to pinpoint accurately the interval during the estrogen surge that coincided with the ideal sperm deposition time to produce offspring. Of the 31 cubs (in 19 pregnancies), 22 (71.0%; 15 pregnancies) were produced from matings occurring on the day of or the day after the maximal urinary estrogen peak. Sixteen of the 19 pregnancies (84.2%) produced at least one offspring sired by the first male mating with the dam. There was a preponderance of twins (12 of 19; 63.2%), and dual paternities were discovered in 3 of 12 twin sets (25%). These findings indicate a strong relationship between the excreted estrogen surge and sperm deposition to achieve pregnancy in the giant panda. To ensure the production of the most genetically diverse young, it is imperative that the most appropriate male mate first and on the day of or the day after the highest detected estrogen value. There is no advantage to increasing the number of copulations or mating partners within 1 day of the estrogen peak on the incidence of twinning, although this practice may increase the prevalence of dual paternity in cases of multiple births.

Several studies have demonstrated that maternal undernutrition or overnutrition during pregnancy can have negative consequences for the health of children born to these pregnancies, but the physiological mechanisms by which this occurs are not completely understood. During periods of food restriction, concentrations of leptin decline, whereas leptin is elevated in obesity, suggesting that it may play a role in the response to altered nutrition during pregnancy. This study compares placental development and global placental gene expression profiles at Day 11.5 in pregnant control mice, mice that were undernourished, and mice that were undernourished but given leptin. Placentas from mothers exposed to food restriction preserved the placental labyrinth zone at the expense of the junctional zone, an effect abrogated in the restricted plus leptin group, which had a significant decrease in the labyrinth zone area compared with controls. Similarly, there were more significant differences in gene expression between placentas from control and restricted plus leptin mothers (1128 differentially expressed genes) than between placentas of control and restricted mothers (281 differentially expressed genes). We conclude that the presence of high concentrations of circulating leptin during food restriction disrupts the normal adaptive response of the placenta to reduced energy availability.

In species with endometrial decidualization and hemochorial placentation (humans, mice, and others), leukocytes localize to early implant sites and contribute to decidual angiogenesis, spiral arterial remodeling, and trophoblast invasion. Relationships between leukocytes, trophoblasts, and the decidual vasculature are not fully defined. Early C57BL/6J implant sites were analyzed by flow cytometry to define leukocyte subsets and by whole-mount immunohistochemistry to visualize relationships between leukocytes, decidual vessels, and trophoblasts. Ptprc (CD45 ) cells increased in decidua between Gestational Day (GD) 5.5 and GD 9.5. Uterine natural killer (uNK) cells that showed dynamic expression of Cd (CD) 69, an activating receptor, and Klrg1 (KLRG1), an inhibitory receptor, localized mesometrially and were the dominant CD45 cells between GD 5.5 and GD 7.5. At GD 8.5, immature monocytes that occurred throughout decidua exceeded uNK cells numerically and many leukocytes acquired irregular shapes, and leukocyte-leukocyte conjugates became frequent. Vessels were morphologically heterogeneous and regionally unique. Migrating trophoblasts were first observed at GD 6.5 and, at GD 9.5, breached endothelium, entered vascular lumens, and appeared to occlude some vessels, as described for human spiral arteries. No leukocyte-trophoblast conjugates were detected. Whole-mount staining gave unparalleled decidual vascular detail and cell-specific positional information. Its application across murine models of pregnancy disturbances should significantly advance our understanding of the maternal-fetal interface.

Growth hormone (GH) is important in maternal adaptation to pregnancy, and maternal circulating GH concentrations are reduced in human growth-restricted pregnancies. In the pig, maternal GH treatment throughout early to mid pregnancy increases fetal growth, despite constraining effects of adolescent and primiparous pregnancy, high litter size, and restricted maternal nutrition. Because GH cannot cross the placenta and does not increase placental weight, we hypothesized that its effects on fetal growth might be via improved placental structure or function. We therefore investigated effects of maternal GH treatment in pigs on structural correlates of placental function and placental expression of nutrient transporters important to fetal growth. Multiparous (sows) and primiparous pregnant pigs (gilts) were treated with GH (∼15 μg kg⁻¹ day⁻¹) or vehicle from Days 25–50 of gestation (n = 7–8 per group, term ∼115 days). Placentas were collected at Day 50 of gestation, and we measured structural correlates of function and expression of SLC2A1 (previously known as GLUT1) and SLC38A2 (previously known as SNAT2) nutrient transporters. Maternal GH treatment did not alter placental size or structure, increased protein expression of SLC2A1 in trophoblast ( 35%; P = 0.037) and on its basal membrane ( 44%; P = 0.011), and increased SLC38A2 protein expression in the basal ( 44%; P = 0.001) but not the apical cytoplasm of trophoblast. Our findings suggest that maternal GH treatment increases fetal growth, in part, by enhancing placental nutrient transporter protein expression and hence fetal nutrient supply as well as trophoblast proliferation and differentiation and may have the potential to ameliorate intrauterine growth restriction.

Beyond Mendelian inheritance, an understanding of the complexities and consequences of the transfer of nonhereditary information to successive generations is at an early stage. Such epigenetic functionality is exemplified by DNA methylation and, as genome-wide high-throughput methodologies emerge, is increasingly being considered in the context of conserved intragenic and intergenic CpG islands that function as alternate sites of transcription initiation. Here we characterize an intragenic CpG island in exon 2 of the protein-coding mouse Klf1 gene, from which clustered transcription initiation sites yield positive-strand, severely truncated, capped and spliced RNAs. Expression from this CpG island in the testis begins between Postnatal Days 14–20, increases during development, and is temporally correlated with the maturation of secondary spermatocytes as they become the dominant cell population in the seminiferous epithelium. Only full-length KLF1-encoding mRNAs are detected in the hematopoietic tissue, spleen; thus, expression from the exon 2 CpG island is both developmentally regulated and tissue restricted. DNA methylation analysis indicates that spatiotemporal expression from the Klf1 CpG island is not associated with hypermethylation. Finally, our computational analysis from multiple species confirms intragenic transcription initiation and indicates that the KLF1 CpG island is evolutionarily conserved. Currently we have no evidence that these truncated RNAs can be translated via nonconventional mechanisms such as in-frame, conserved non-AUG-dependent Kozak consensus sequences; however, high-quality carboxyl-terminal antibodies will more effectively address this issue.

Inflammation of the male reproductive tract is accepted as being an important etiological factor of infertility. Experimental autoimmune orchitis (EAO) is characterized by interstitial lymphomononuclear cell infiltration and severe damage of seminiferous tubules with germ cells that undergo apoptosis and sloughing. Because the blood-testis barrier (BTB) is relevant for the protection of haploid germ cells against immune attack, the aim of this study was to analyze BTB permeability and the expression of tight junction proteins (occludin, claudin 11, and tight junction protein 1 [TJP1]) in rats during development of autoimmune orchitis. The role of IL6 as modulator of tight junction dynamics was also evaluated because intratesticular content of this cytokine is increased in EAO rats. Orchitis was induced in Sprague-Dawley adult rats by active immunization with testicular homogenate and adjuvants. Control rats (C) were injected with saline solution and adjuvants. Untreated (N) rats were also studied. Concomitant with early signs of germ cell sloughing, a reduced expression of occludin and delocalization of claudin 11 and TJP1 were detected in the testes of rats with EAO compared to C and N groups. The use of tracers showed increased BTB permeability in EAO rats. Intratesticular injection of IL6 induced focal testicular inflammation, which is associated with damaged seminiferous tubules. Rat Sertoli cells cultured in the presence of IL6 exhibited a redistribution of tight junction proteins and reduced transepithelial electrical resistance. These data indicate the possibility that IL6 might be involved in the downregulation of occludin expression and in the modulation of BTB permeability that occur in rats undergoing autoimmune orchitis.

Cavernous smooth muscle cells are essential components in penile erection. In this study, we investigated effects of estrogen exposure on biomarkers for smooth muscle cell differentiation in the penis. Neonatal rats received diethylstilbestrol (DES), with or without the estrogen receptor (ESR) antagonist ICI 182,780 (ICI) or the androgen receptor (AR) agonist dihydrotestosterone (DHT), from Postnatal Days 1 to 6. Tissues were collected at 7, 10, or 21 days of age. The smooth muscle cell biomarker MYH11 was studied in depth because microarray data showed it was significantly down-regulated, along with other biomarkers, in DES treatment. Quantitative real time-PCR and Western blot analyses showed 50%–80% reduction (P ≤ 0.05) in Myh11 expression in DES-treated rats compared to that in controls; and ICI and DHT coadministration mitigated the decrease. Temporally, from 7 to 21 days of age, Myh11 expression was onefold increased (P ≥ 0.05) in DES-treated rats versus threefold increased (P ≤ 0.001) in controls, implying the long-lasting inhibitory effect of DES on smooth muscle cell differentiation. Immunohistochemical localization of smooth muscle alpha actin, another biomarker for smooth muscle cell differentiation, showed fewer cavernous smooth muscle cells in DES-treated animals than in controls. Additionally, DES treatment significantly up-regulated Esr1 mRNA expression and suppressed the neonatal testosterone surge by 90%, which was mitigated by ICI coadministration but not by DHT coadministration. Collectively, results provided evidence that DES treatment in neonatal rats inhibited cavernous smooth muscle cell differentiation, as shown by down-regulation of MYH11 expression at the mRNA and protein levels and by reduced immunohistochemical staining of smooth muscle alpha actin. Both the ESR and the AR pathways probably mediate this effect.

The prolonged incubation of human spermatozoa in vitro was found to induce a loss of motility associated with the activation of mitochondrial reactive oxygen species generation in the absence of any change in mitochondrial membrane potential. The increase in mitochondrial free radical production was paralleled by a loss of protein thiols and a concomitant rise in the formation of 4-hydroxynonenal, an electrophilic product of lipid peroxidation that was found to directly suppress sperm movement. These results prompted a search for nucleophiles that could counteract the action of such cytotoxic aldehydes, as a means of ensuring the long-term survival of spermatozoa in vitro. Four nucleophilic compounds were consequently assessed (penicillamine, homocysteine, N-acetylcysteine, and mercaptosuccinate) in three species (human, rat, and horse). The results of this analysis revealed drug and species specificity in the manner in which these compounds affected sperm function, with penicillamine conferring the most consistent, effective support. This prosurvival effect was achieved downstream of mitochondrial reactive oxygen species generation and was associated with the stabilization of 4-hydroxynonenal generation, the preservation of sperm thiols, and a reduction in 8-hydroxy-2′-deoxyguanosine formation. Theoretical calculations of Fe-S and Cu-S bond distances and corresponding binding energies suggested that the particular effectiveness of penicillamine may, in part, reflect the ability of this nucleophile to form stable complexes with transition metals that catalyze lipid peroxidation. The practical implications of these findings were indicated by the effective preservation of equine spermatozoa for 8 days at ambient temperature when the culture medium was supplemented with penicillamine.

Small RNA represent several unique noncoding RNA classes that have important function in the development of germ cells and early embryonic development. Deep sequencing was performed on small RNA from cumulus cells (recovered from germinal vesicle [GV] and metaphase II-arrested [MII] oocytes), GV and MII oocytes, in vitro fertilization-derived embryos at 60 h postfertilization (4- to 8-cell stage), and Day 6 blastocysts. Additionally, a heterologous miRNA microarray method was also used to identify miRNA expressed in the oocyte during in vitro maturation. Similar to the results of expression analysis of other species, these data demonstrate dynamic expression regulation of multiple classes of noncoding RNA during oocyte maturation and development to the blastocyst stage. Mapping small RNA to the pig genome indicates dynamic distribution of small RNA organization across the genome. Additionally, a cluster of miRNA and Piwi-interacting RNA (piRNA) was discovered on chromosome 6. Many of the small RNA mapped to annotated repetitive elements in the pig genome, of which the SINE/tRNA-Glu and LINE/L1 elements represented a large proportion. Two piRNA (piR84651 and piR16993) and seven miRNA (MIR574, MIR24, LET7E, MIR23B, MIR30D, MIR320, and MIR30C) were further characterized using quantitative RT-PCR. Secretory carrier membrane protein 4 (SCAMP4) was predicted to be subject to posttranscriptional gene regulation mediated by small RNA, by annotating small RNA reads mapped to exonic regions in the pig genome. Consistent with the prediction results, SCAMP4 was further confirmed to be differentially expressed at both transcriptional and translational levels. These data establish a small RNA expression profile of the pig cumulus-oocyte complex and early embryos and demonstrate their potential capacity to be utilized for predictions of functional posttranscriptional regulatory events.

Recent research has shown that nucleoli of oocytes at the germinal vesicle (GV) stage (GV nucleoli) are not necessary for oocyte maturation but are essential for early embryonic development. Nucleoli of 2-cell embryos (2-cell nucleoli) have morphology similar to that of nucleoli in oocytes at the GV stage. In this study, we examined the ability of 2-cell nucleoli to substitute for GV nucleoli in terms of supporting early embryonic development by nucleolus aspiration (enucleolation) and transfer into metaphase II (MII) oocytes or 2-cell embryos that were derived from enucleolated oocytes at the GV stage in the pig. When 2-cell embryos were centrifuged to move the lipid droplets to one side of the blastomere, multiple nucleoli in the nucleus fused into a single nucleolus. The nucleoli were then aspirated from the 2-cell embryos by micromanipulation. The injection of 2-cell nucleoli to GV enucleolated oocytes at the MII stage rescued the embryos from the early embryonic arrest, and the resulting oocytes developed to blastocysts. However, the injection of 2-cell and GV nucleoli to 2-cell embryos derived from GV enucleolated oocytes rarely restored the development to blastocysts. These results indicate that 2-cell nucleoli support early embryonic development as GV nucleoli and that the presence of nucleoli is essential for pig embryos before the 2-cell stage.

The ovarian hormones estrogen and progesterone promote uterine receptivity and successful pregnancy through their cognate receptors functioning in concert with context-dependent nuclear coregulators. Previously, we showed that the transcription factor Krüppel-like factor (KLF) 9 is a progesterone receptor (PGR) coactivator in the uterus and that mice null for Klf9 exhibit subfertility and reduced progesterone sensitivity. The highly related family member KLF13 displays increased expression in uteri of pregnant and nonpregnant Klf9 null mice and similarly regulates PGR-mediated transactivation in endometrial stromal cells. However, a uterine phenotype with loss of Klf13 has not been reported. In the present study, we demonstrate that Klf13 deficiency in mice did not compromise female fertility and pregnancy outcome. Klf13 null females had litter sizes, numbers of implanting embryos, uterine morphology, and ovarian steroid hormone production comparable to those of wild-type (WT) counterparts. Further, pregnant WT and Klf13 null females at Day Postcoitum (DPC) 3.5 had similar uterine Pgr, estrogen receptor, and Wnt-signaling component transcript levels. Nuclear levels of KLF9 were higher in Klf13 null than in WT uteri at DPC 3.5, albeit whole-tissue KLF9 protein and transcript levels did not differ between genotypes. The lack of a similar induction of nuclear KLF9 levels in uteri of virgin Klf13^(−/−) mice relative to WT uteri was associated with lower stromal PGR expression. In differentiating human endometrial stromal cells, coincident KLF9/KLF13 knockdown by small interfering RNA targeting reduced decidualization-associated PRL expression, whereas KLF9 and KLF13 knockdowns alone reduced transcript levels of WNT4 and BMP2, respectively. Results suggest that KLF9 and KLF13 functionally compensate in peri-implantation uterus for pregnancy success.

In mammals, successful pregnancy is dependent in part on the adaptation or regulation of the maternal immune system to prevent the rejection of the embryonic semiallograft. A modification in Th cell function and secretion is a requirement for the establishment and maintenance of pregnancy. Although there is strong evidence from studies in humans and mice linking successful pregnancy with the predominance of Th2-type immunity, the situation in cattle remains unclear. This study describes the characterization of the immune response of the bovine maternal endometrium to the presence of a developing embryo, with specific emphasis on the macrophage and dendritic cell populations and associated factors, using quantitative real-time PCR, in situ hybridization, and immunohistochemistry. Furthermore, in vivo and in vitro models were developed to investigate the potential role of progesterone and interferon-tau (IFNT) in the regulation of these immune factors. There was a marked increase in the population of CD14 cells and CD172a-CD11c cells in the endometrium in response to pregnancy, which was paralleled by increased mRNA expression of a number of non-Th-associated factors, including IL12B and IL15, and downregulation of IL18. In addition, we identified several novel IFNT- and progesterone-regulated factors, including IL12B, MCP1, MCP2, PTX3, RSAD2, and TNFA, whose regulation may be critical to pregnancy outcome. Our findings give center stage to non-Th cells, such as monocytes/macrophages and dendritic cells, in the bovine immune response to the semiallogenic embryo. In conclusion, we propose that in cattle, successful pregnancy establishment is associated with a dramatic regulation of the cytokine network, primarily by endometrial monocytes/macrophages and dendritic cells.

The objective of the present study was to determine how low progesterone (P4) affects the endometrial transcriptome, with specific emphasis on those changes that may impact conceptus elongation. Following estrous synchronization and detection (estrus = Day 0, n = 40), heifers were randomly assigned to a control group (n = 12) or a low P4 group (n = 28). Heifers in the low P4 group had consistently lower P4 concentrations compared to controls (P < 0.05). Microarray analysis of endometrial gene expression revealed low P4 altered the expression of 498 differentially expressed genes (DEGs; 215 up- and 283 down-regulated) on Day 7 and 351 DEGs (272 up- and 79 down-regulated) on Day 13. A similar number of temporal changes occurred between Day 7 and Day 13 in both groups (2212 in heifers with normal P4 compared with 2247 in heifers with low P4); of these DEGs, 1278 were common to both groups. Little overlap in the number of DEGs affected by high or low P4 was observed across days. Comparison of the temporal changes that occur during normal estrous cycle progression (i.e., from Day 7 to Day 13) to those affected by altered P4 found significant numbers of genes were modulated by elevated (4157) and decreased (809) P4 alone. Analysis of selected genes by quantitative real-time PCR and in situ hybridization revealed that expression of MEP1B, NID2, and PRSS23 increased on Day 13 compared to Day 7 (P < 0.05) and that the magnitude of increase was significantly diminished in heifers with low P4 compared to controls. MEP1B predominantly localized to the both the superficial and deep glandular epithelium (GE), NID2 localized to the deep GE, whereas PRSS23 localized only to the luminal epithelium. In conclusion, we have determined the global changes in the endometrial transcriptome induced by decreasing the output of P4 from the corpus luteum in vivo using a unique animal model. Placing these data into context with previous data in which P4 was supplemented or elevated after ovulation, we have identified a panel of genes that are truly regulated in the endometrium by circulating concentrations of P4 in vivo and that likely impact conceptus elongation.

In Nile tilapia, sex-specific expression of foxl2 and cyp19a1a in XX gonads and dmrt1 in XY gonads at 5–6 days after hatching (dah) is critical for differentiation of the gonads into either ovaries or testes. The factors triggering sexually dimorphic expression of these genes are unknown, and whether the gonadotropin hormones are involved in early gonadal sex differentiation of the Nile tilapia has been unclear. In the present study, we determined the precise timing of expression of follicle-stimulating hormone (FSH) and luteinizing hormone (LH) in the pituitary and that of their receptors (fshra and lhcgrbb) in the undifferentiated gonad in both XX and XY tilapia fry by quantitative RT-PCR and immunohistochemical analysis. Expression of fshb mRNA and Fsh protein in the pituitary was detected from the first sampling day (3 dah) to 25 dah in both XX and XY tilapia larvae without sexual dimorphism and increased gradually after 25 dah in the pituitary. fshra mRNA was expressed beginning 5 dah and was present at significantly higher levels in XX gonads than in the XY gonads at 6–25 dah. These results indicate that the level of Fsh protein in the pituitary was not critical for differentiation of gonads into ovaries or testes, but the expression level of its receptor, fshra, in undifferentiated gonads appeared to be involved in determining gonadal sexual differentiation. Based on these observations, it is likely that in XX gonads, up-regulation of fshra may be necessary to induce cyp19a1a expression, which stimulates estradiol-17beta (E₂) production and subsequent ovarian differentiation. On the other hand, lhb mRNA was not detected until 25 dah in the pituitaries of both sexes, and sexual dimorphism in lhcgrbb mRNA levels appeared later (10–25 dah) than that of fshra in the gonads, indicating the limited role of LH and lhcgrbb in gonadal differentiation of the Nile tilapia.

Environmental stress-induced alterations in oocyte mitochondria are suggested to deleteriously affect developmental competence of the ovarian pool of oocytes. We examined the association between seasonal effects on oocyte developmental competence and mitochondrial distribution, polarization, mitochondrial DNA (mtDNA) content, and RNA expression, and whether the incorporation of coenzyme Q10 (CoQ10) might improve these effects. Bovine oocytes were collected during the summer (June–August), fall (September–November), and winter (December–May), matured in vitro with or without 50 μM CoQ10, fertilized, and cultured for 8 days. The proportion of developed blastocysts was highest in the winter, intermediate in the fall, and lowest in the summer. Matured oocytes were classified into categories I–IV according to their mitochondrial distribution pattern (MitoTracker green). The proportion of high- and low-polarized mitochondria (JC-1 assay) differed between oocyte categories but was not affected by season. On the other hand, oocyte distribution into categories differed between seasons and was affected by CoQ10, with an increased proportion of category I oocytes in the fall. Oocyte mtDNA did not differ between seasons, but expression of mitochondrion-associated genes involved in the respiratory chain (ND2, SDHD, CYTB, COXII, ATP5B, and TFAM) did. Coenzyme Q10 increased the expression of CYTB, COXII, and ATP5B and the proportions of blastocysts developed in the fall. In summary, season-induced alterations in mitochondrial functions might explain, in part, the reduced oocyte developmental competence. It seems that in the fall, under modest harm, CoQ10 incorporation can alleviate these deleterious effects somewhat.