Background: Despite considerable technological advancements, polyspermy remains a significant challenge in in vitro fertilization (IVF) procedures in pigs, disrupting normal embryonic development. Here, we aimed to determine whether optimal fertilization conditions reduce the polyspermy incidence in pigs. Methods: In vitro -matured oocytes were co-incubated with sperm according to a modified two-step culture system. Results: In the first experiment, oocytes were briefly co-incubated with sperm, washed in IVF medium, and then moved to fresh IVF medium for 5 or 6 h. Although the 6 h sperm-free cultured group had a higher penetration rate than the 5 h cultured group, the polyspermy rate significantly increased in the 6 h sperm-free cultured group. The gamete co-incubation period was either 20 or 40 min. The 40 min cultured group had a higher rate of blastocyst formation and number of total cells in blastocysts than the 20 min cultured group. In experiment 2, oocytes were inseminated with sperm separated by Pecroll treatment. Percoll treatment increased the rate of oocyte penetration and blastocyst formation compared to the control. In experiment 3, fertilized oocytes were cultured in 25 μL microdroplets (10 gametes/drop) or 500 μL (100 gametes/well) of culture medium in 4-well plates. The large volume of medium significantly reduced the number of dead oocytes and increased the rate of blastocyst formation compared to the small volume. Conclusions: Collectively, these results demonstrate that various fertilization conditions, including modified co-culture period, active sperm separation, and culture medium volume, enhance fertilization efficiency and subsequent embryonic development by decreasing polyspermy occurrence.

Alpha-linolenic acid is an important polyunsaturated fatty acid that exhibits anticancer, anti-inflammatory, and antioxidative effects. In this study, we investigated the protective effects of alpha-linolenic acid on the cell proliferation and differentiation of C2C12 cells under essential amino acid-deficient conditions. Different concentrations of alpha-linolenic acid and essential amino acids were added to the growth and differentiation media. The concentrations of 10 μM of alphalinolenic acid and 2% essential amino acid were chosen for subsequent experiments. Supplementation with alpha-linolenic acid and essential amino acids improved the proliferation and differentiation of C2C12 cells and significantly increased the mRNA levels of catalase, superoxide dismutase, B-cell lymphoma-2, and beclin-1 as well as the protein levels of PPARγ coactivator-1α compared to those in the controls. Moreover, supplementation with alpha-linolenic acid and essential amino acids reduced the levels of phosphorylated H2A.X variant histone, Bcl-2-associated X, p53, and light chain 3 during C2C12 cell proliferation, and increased the expression levels of myogenic factors 4 (myogenin) and 5 during C2C12 cell differentiation. Overall, we determined that alpha-linolenic acid and essential amino acids maintained the cell proliferation and differentiation of C2C12 cells via their anti-oxidative, anti-apoptotic, and anti-autophagic effects.

Using first-principles theory, this work investigated the Cu-doping behavior on the N-vacancy of the C3N monolayer and simulated the adsorption performance of Cu-doped C3N (Cu–C3N) monolayer upon two dissolved gases ( H2 and C2H2). The calculations meant to explore novel candidate for sensing application in the field of electrical engineering evaluating the operation status of the transformers. Our results indicated that the Cu dopant could be stably anchored on the N- vacancy with the Eb of − 3.65 eV and caused a magnetic moment of 1 μB. The Cu–C3N monolayer has stronger performance upon C2H2 adsorption than H2 give the larger Ead, QT and change in electronic behavior. The frontier molecular orbital (FMO) theory indicates that Cu–C3N monolayer has the potential to be applied as a resistance-type sensor for detection of such two gases, while the work function analysis evidences its potential as a field-effect transistor sensor as well. Our work can bring beneficial information for exploration of novel sensing material to be applied in the field of electrical engineering, and provide guidance to explore novel nano-sensors in many fields.

Nitric oxide (NO)-induced protein S-nitrosylation triggers mitochondrial dysfunction and was related to cell senescence. However, the exact mechanism of these damages is not clear. In the present study, to investigate the relationship between in vitro aging and NO-induced protein S-nitrosylation, oocytes were treated with sodium nitroprusside dihydrate (SNP), and the resultant S-nitrosylated proteins were detected through biotin-switch assay. The results showed that levels of protein S-nitroso thiols (SNO)s and expression of S-nitrosoglutathione reductase (GSNOR) increased, while activity and function of mitochondria were impaired during oocyte aging. Addition of SNP, a NO donor, to the oocyte culture led to accelerated oocyte aging, increased mitochondrial dysfunction and damage, apoptosis, ATP deficiency, and enhanced ROS production. These results suggested that the increased NO signal during oocyte aging in vitro, accelerated oocyte degradation due to increased protein S-nitrosylation, and ROS-related redox signaling.

Cell adhesion plays an important role in the differentiation of the morphogenesis and the trophectoderm epithelium of the blastocyst. In the porcine embryo, CDH1 mediated adhesion initiates at compaction before blastocyst formation, regulated post-translationally via protein kinase C and other signaling molecules. Here we focus on muscle RAS oncogene homolog (M-RAS), which is the closest relative to the RAS related proteins and shares most regulatory and effector interactions. To characterize the effects of M-RAS on embryo compaction, we used gain- and loss-of-function strategies in porcine embryos, in which M-RAS gene structure and protein sequence are conserved. We showed that knockdown of M-RAS in zygotes reduced embryo development abilities and CDH1 expression. Moreover, the phosphorylation of ERK was also decreased in M-RAS KD embryos. Overexpression of M-RAS allows M-RAS KD embryos to rescue the embryo compaction and blastocyst formation. Collectively, these results highlight novel conserved and multiple effects of M-RAS during porcine embryo development.

Connexin 43 (Cx43) is one of the gap junction proteins which are compounds of transmembrane proteins and transports the small-molecular-weight chemicals up to 2 kDa. Lacking of Cx43 influences the junctional protein, induces autophagy and apoptosis in somatic cells. However, the function of Cx43 in porcine early embryos is still unknown. Aim to find out the molecular mechanism of Cx43 on the developmental competence in early porcine embryos, Cx43 dsRNA (1 ㎍/㎕) was microinjected into the parthenogenetically activated porcine zygotes. Blastocyst rate (treatment, 8.8±1.6% vs. control, 38.6±4.3%) and total cell numbers in the blastocyst (treatment, 20.7±3.5 vs. control, 39.8±4.1) were significantly reduced following Cx43 knocking down. Results from FITC-dextran and Western blot assay show that knock down (KD) of Cx43 significantly increased membrane permeability through down regulation of genes which are component of both adherence and tight junction in the porcine blastocyst. Reactive oxygen species (ROS) was significantly increased in the Cx43 KD group compared to control. In addition, KD of Cx43 activated Caspase 3 and significantly increased ATG8 expression, induced autophagy and apoptosis. Results suggest that KD of Cx43 influences preimplantation porcine embryo development via increasing membrane permeability and ROS generation, and inducing autophagy and apoptosis.

Melatonin (N-aceyl-5-methoxytryptamine) is the major hormone of the pineal gland. Melatonin and its metabolic derivatives possess extensive free-radical scavenging abilities and played critical roles in antioxidative stress, resisting apoptotic cell death. Melatonin also could enhance mitochondrial biogenesis in rats with carbon tetrachloride-induced liver fibrosis. In addition, melatonin attenuates myocardial ischemia/reperfusion injury by reducing oxidative stress damage via activation of SIRT1 signaling in a melatonin receptor 2-dependent manner. Activation or overexpression of SIRT1 could enhance mitochondrial biogenesis and function by inducing PGC-1α expression and deacetylation. The aim of this study was to investigate if melatonin enhances mitochondrial biogenesis and function via activation of melatonin receptor 2/SIRT1/PGC1-α Pathway. The results showed that Melatonin rescued rotenone-induced impairment of porcine embryo development. Treatment with rotenone could increase oxidative stress and apoptosis. Rotenone impaired mitochondrial functions by disrupting mitochondrial membrane potential, reducing mitochondrial DNA copy number and ATP production. Melatonin could improve SIRT1 and PGC-1α expression, inducing mitochondrial biogenesis. Rotenone-induced mitochondrial dysfunction and ATP deficiency was rescued by melatonin treatment, the oxidative stress and apoptosis was significantly decreased. Inhibition of melatonin receptor 2 or Knockdown of SIRT1 abolished the protective effects of melatonin on rotenone-induced impairments. Therefore, melatonin enhanced mitochondrial biogenesis and function, protected against rotenone-induced impairments.

Thiamethoxam (TMX) is a neonicotinoid insecticide. Residues of TMX have been detected in various crops. Although it has specific high toxicity to insects and is designed to exterminate them, the toxicity has also found in mammals recently. Differ from acetylcholine toxicity, TMX has peroxide toxicity in mammals. Matured oocytes have the capacity of fertilization, but oocytes own abundant mitochondria and its maturation is vulnerable to reactive oxygen species (ROS). Excessive production of reactive oxygen species (ROS) can override antioxidant defenses, produce oxidative stress and DNA damage that triggers apoptosis and necrosis in organisms. However little is known about the harm of ROS induced by TMX during oocytes maturation. Here, bovine germ-vesicle (GV) oocytes were cultured to metaphase of the second meiosis (MII) stage in vitro with or without TMX. During this process, oocytes were evaluated by various methods. Microscopic examination showed that 1.6 mM TMX significantly inhibited the maturation process in which oocytes were arrested before MI stage or between MI and MII stage. Correspond to this two periods, immunofluorescence staining and enzyme activity analysis showed that active CDC25 and CDC2 reduced in TMX group compared to control; time lapse and immunofluorescence staining gave results that Cyclin B could not be degraded, actin cap could not form, and Bub3 could not be removed from kinetochores. In addition, MII oocytes exposed to TMX showed disordered chromosomes and spindle. To study further, oocytes cultured for 24 h were analyzed. On the one hand, these oocytes in TMX group accumulated more ROS and produced significantly decreased mitochondrial membrane potential and increased apoptotic signal compared to control by methods of quantities for dichlorodihydrofluorescein diacetate (DCHFDA), 5,5′,6,6′-Tetrachloro-1,1′,3,3′-tetraethyl-imidacarbocyanine iodide and Annexin-V, but the level of γH2AX protein in TMX group did not decline significantly compared with control. On the another hand, these oocytes were activated to be parthenogenetic embryos and cultured. Assessment for embryo development showed decreased rates of cleavage, morula and blastocyst in TMX group compared to control in vitro. In conclusion, these results suggest that ROS induced by TMX results in dysfunction of mitochondria and apoptosis, which block bovine oocytes to MI stage, trap them at AI/TI stage and trigger disordered chromosomes and spindle at MII stage. Additionally, MII oocytes with poor qualities result from TMX lose abilities to cleavage and develop to be morulae and blastocysts.

The porcine zygotic genome activation occurs along with global epigenetic remolding at the 4-cell stage. The histone acetylation, regulating DNA transcription, replication and so on, requires adequate acetyl-CoA. Acetyl-CoA produced by translocated pyruvate dehydrogenase in the nucleus of mammalian cells has been reported, which is commonly considered locating in the mitochondria. To find out whether the nuclear pyruvate dehydrogenase regulating the histone acetylation by controlling generation of acetyl-CoA, a multiple sgRNAs-CRISPR/Cas9 targeting strategy was employed to generate a pyruvate dehydrogenase E1 alpha1 (Pdha1) knockout (KO) parthenogenetic embryo model. Results showed that the targeting efficiency of Pdha1 reached more than 90%. Hence, this model was used in the subsequent experiments. Furthermore, a translocation of Pdha1 during zygotic genome activation was found by immunofluorescent staining and was significantly inhibited by Pdha1 KO. Meanwhile, the 8-cell stage embryo rate significantly decreased after 72 h (24.19% vs 12.53%, control vs Pdha1 KO), indicating a 4-cell arrest. In addition, the nuclear histone acetylation level significantly decreased when Pdha1 was KO. To determine whether the zygotic genome transcription was affected, the qPCR was performed and showed that the mRNA level of Eif1A, Acly, Sqle and Pdha1 all dropped significantly in the Pdha1 KO group compared to the control. In conclusion, the translocated Pdha1 generates acetyl-CoA for histone acetylation inside the nucleus of porcine embryos, which promotes the zygotic genome activation of porcine embryos.

The acetyltransferase Tip60 (Kat5) is a member of the MYST family of HATs that was initially identified as a cellular protein. TIP60 acetylates histone and non-histone proteins, and is involved in diverse biological processes, including apoptosis, cell cycle, and DNA damage responses. In this study, a specific inhibitor of TIP60, Nu 9056, was used to study the function and its regulatory mechanism of Tip60 in the porcine preimplantation embryonic development. The results showed that inhibition of TIP60 impaired the embryonic development due to induce DNA damage through ATM-p53-p21 pathway, it was evidenced by expression of γH2A in the nuclei of blastocysts. In addition, TIP60 inhibition decreased efficiency of DNA repair by regulating P53 binding protein 1 expression. Furthermore, autophagy was induced following TIP60 inhibition through modulating microtubule-associated protein 1A/1B-light chain 3 expression. In conclusion, the results suggest that TIP60 plays a critical role in early embryonic development via regulation of DNA damage and its repairs.

Fatty acid synthesis (FASN) is an enzyme responsible for the de novo synthesis of long-chain fatty acids. During oncogenesis, FASN plays a role in growth and survival rather than acting within the energy storage pathways. Here, the function of FASN during early embryonic development was studied using its specific inhibitor C75. We found that the presence of the inhibitor reduced blastocyst hatching. FASN inhibition decreased Cpt1 expression, leading to a reduction in mitochondrial copy numbers and ATP content. This inhibition of FASN results in the down-regulation of the AKT pathway, thereby triggering apoptosis through the activation of the p53 pathway. Activation of the apoptotic pathways also leads to increased accumulation reactive oxygen species and autophagy. In addition, the FASN inhibitor can impair cell proliferation, a parameter of blastocyst quality for outgrowth. The level of OCT4, an important factor in embryonic development, decreased after treatment with the FASN inhibitor. These results show that FASN exerts an effect on the early embryonic development by regulation of both fatty acid oxidation and the AKT pathway in pigs.

PP2A-B55α, a regulatory subunit of PP2A plays an important roles in regulating cell proliferation and survival. However, the functions for PP2A-B55α in mouse early embryo development is not clear. The objective of present were to investigate the expression patterns and to explore its biological function during mouse early development. Thetranscripts of PP2A-B55α were detected at all developmental stages in mouse embryo and decreased during embryo development. Immunostaining revealed that PP2A-B55α was present in both the nucleus and cytoplasm in early cleavage stage embryos. In the late embryonic development, PP2A-B55α was predominantly located in the cytoplasm. Knockdown (KD) of PP2A-B55α using double strand RNA not affect the proportion of cleaved embryos, but resulted in significantly decreased development to blastocyst stage and reduced total cell number in blastocyst. KD PP2A-B55α is able to induce sustained DNA damage and reduced the transcripts of non-homologous end joining (NHEJ) or homologous recombination (HR) pathways relative genes in mouse early embryo. KD PP2A-B55αcaused apoptosis and increase the transcripts of pro-apoptotic genes in blastocyst. Furthermore, The KDPP2A-B55α showed significantly lower cell proliferating rates (from 5-Bromo-deoxyuridineassayresults) in blastocysts and to talareas of out growth potential was decreased. These observation provide novel in sight into PP2A-B55α expression patterns in mouse early embryos and down-regulation of PP2A-B55α negatively impacted blastocyst development, total cell number, DNA damage, apoptosis, and proliferation and post-hatchingevents.

Spindlin1(Spin1), a meiotic spindle-binding protein that is highly expressed in cancer cells. Spindle-binding was dependent on its phosphorylation status, which was partially regulated by Mos/MAP kinase pathway. Nevertheless, the biologic roles of Spin1 in oocytes maturation are still largely unknown. For exploring the function of Spin1 in porcine oocyte maturation, Knockdown and overexpression methods were employed to the present study. Spin1 mRNA were enriched in maternal stages, from germinal vesicle - to 2 cell - stage, but sharply decreased after 4 cell stage, zygotic genome activation. Protein of SPIN1 was localized in spindle-chromatin complex during the metaphase I and metaphase II stages. Knockdown of Spin1 did not affect the first polar body extrusion, however, Spin1 depletion caused mitotic spindle defects, chromosome instability and pronuclear formation in metaphase II stage. Percentage of 2cell, 4cell embryos and blastocyst formation were significantly reduced in knockdown group compared with control, but cell numbers in blastocyst were no difference between control and knockdown groups. Another hand, Oocyte failed to maturation and induced metaphase I arrest following Spin1 over-expression. In conclusion, Spin1 is involved in the spindle formation and maintenance during oocytes meiotic maturation in pigs.

By adopting regression and time series analysis, this article tries to quantify people’s enthusiasm towards beauty based on sales performance of cosmetics product in previous years in China. The basic assumption in this paper is that people’s attitude towards beauty is positively associated with their purchase behavior of cosmetics product.

We adopt a semi-grounded theory approach to investigate the impact of different review manipulation tactics. Shoppers take a negative view toward seller manipulations, but the degree of negativity varies across different tactics. Moreover, different manipulations tactics vary in the ease of detection, perceived unethicality, and the effect on consumer perceptions.

The shortest path problem is one of network optimization problems. This paper considers a shortest path problem under the situation where lengths of arcs in a network include both uncertainty and randomness, and focuses on the case that the lengths of arcs are expressed by uncertain random variables. This paper presents a new type of model: relative entropy model of shortest path. By the definition of relative entropy of the uncertain random variables, relative entropy model of shortest path problem is proposed to find the shortest path which fully reflects uncertain and random information. This model is formulated to find a shortest path whose chance distribution minimizes the difference from the ideal one. A numerical example is given to illustrate the model’s effectiveness.

The present study assessed the effect of FSH and LH on oocyte meiotic, cytoplasmic maturation and on the expression level and polyadenylation status of several maternal genes. Cumulus-oocyte complexes were cultured in the presence of FSH, LH, or the combination of FSH and LH. Significant cumulus expansion and nuclear maturation was observed upon exposure to FSH alone and to the combination of FSH and LH. The combination of FSH and LH during entire IVM increased the mRNA level of four maternal genes, C-mos, Cyclin B1, Gdf9 and Bmp15, at 28 h. Supplemented with FSH or LH significantly enhanced the polyadenylation of Gdf9 and Bmp15; and altered the expression level of Gdf9 and Bmp15. Following parthenogenesis, the exposure of oocytes to combination of FSH and LH during IVM significantly increased cleavage rate, blastocyst formation rate and total cell number, and decreased apoptosis. In addition, FSH and LH down-regulated the autophagy gene Atg6 and upregulated the apoptosis gene Bcl-xL at the mRNA level in blastocysts. These data suggest that the FSH and LH enhance meiotic and cytoplasmic maturation, possibly through the regulation of maternal gene expression and polyadenylation. Overall, we show here that FSH and LH inhibit apoptosis and autophagy and improve parthenogenetic embryo competence and development.