Graphene-based sensors have emerged as significant tools for biosensing applications due to their unique electrical, mechanical, and thermal properties. In this study, we have developed an innovative and sensitive aptasensor based on the surfacemodified graphene for the detection of lung cancer biomarker CA125. The sensor leverages the combination of graphene surface and gold nanoparticles (AuNPs) electrodeposition to achieve a high level of sensitivity and selectivity for the biomarker detection. A noticeable decrease in electron transfer resistance was observed upon the AuNPs deposition, demonstrating the enhancement of electrochemical performance. Our experimental findings showed a strong linear relationship between the sensor response and CA125 concentrations, ranging from 0.2 to 15.0 ng/mL, with a detection limit of 0.085 ng/ mL. This study presents a novel approach to lung cancer detection, surpassing the traditional methods in terms of invasiveness, cost, and accuracy. The results from this work could pave the way for the development of graphene-based sensors in various other biosensing applications.

Many transcription factors are involved in directing the growth of porcine oocytes. The localization and expression level of a given transcription factor often differ at each stage of early embryonic growth, which spans from fertilization to the formation of the blastocyst. A hallmark of the blastocyst stage is the separation of the endodermal and mesodermal ectoderm. The embryo's medium and its effects are known to be crucial during early development compared to the other developmental stages, and thus require a lot of caution. Therefore, in many experiments, early development is divided into the quality of oocyte and cumulus cells and used in experiments. We thought that we were also heavily influenced by genetic reasons. Here, we examined the expression patterns of five key transcription factors (CDX2, OCT4, SOX2, NANOG, and E-CADHERIN) during porcine oocyte development whose expression patterns are controversial in the pig to the literature. Antibodies against these transcription factors were used to determine the expression and localization of them during the early development of pig embryos. These results indicate that the expressions of key transcription factors are generally similar in mouse and pig early developing embryos, but NANOG and SOX2 expression appears to show species-specific differences between pig and mouse developing embryos. This work helps us better understand how the expression patterns of transcription factors translate into developmental effects and processes, and how the expression and localization of different transcription factors can crucially impact oocyte growth and downstream developmental processes.

The embryonic genome activation (EGA) is genetically activated states that embryos make the materials such as growth factors for using themselves. EGA is various because they have many materials, different site, different stage, also different species. At this time, transcription factors are expressed. Transcription factors bind to specific DNA region, and regulate the gene expression. Thus, we check the expression of transcription factors, we can know that embryo development is very well or not. The development stages of embryos are basically the stages from fertilization to blastocyst. So, we check the embryos oocyte to blastocyst. In our experiments, we focus the early developmental transcription factors such as Cdx2, Oct4, Sox2, Nanog and E-Cadherin. Above antibody factors showed different expression sites, and there were many differentiated parts from other animal species. In addition, we compared the SCNT and parthenogenetic activation (PA) because these are same methods using electrical activation among the embryo production methods. Our results showed not only similar patterns but also different patterns between pig and mouse. Therefore, we have to investigate that different patterns of transcription factors play a role in pigs, and why occur.

In porcine production, porcine litter size is a quantitative trait and its heritability is especially low. So it is necessary to identify porcine reproductive gene and protein. The establishment of pregnancy requires performance of a receptive endometrium and ovary. The endometrium and ovary go through transformations in response to physiological changes initiated by local factors including ovarian hormones and uterine environment that make it for possible pregnancy. The endometrium and ovary secrete a wide array of growth factors, cytokines and proteins. Based on these background, we analyzed the endometrial tissue protein of porcine and would find out biomarker proteins related to porcine litter size. We sorted the two groups according to litter size of porcine: a small litter size group (SLSG) (n=2) and a large litter size group (LLSG) (n=2). The porcine endometrial tissue and ovary samples were preprocessed for proteomic analysis. In order to comparison, samples of each 2mg endometrium protein and ovary protein were separated form pI and molecular weight in the same conditions by applying a pH 3.0-10.0 IPG gels for the first dimension and then 8-16% SDS-PAGE gel for the second dimension. After proteins were visualized by staining with Commassie brilliant blue (CBB), image analysis was performed with Image Master detect variations in protein spots between large litter size group and small litter size group endometrium. And then differential proteins were identified using MALDI-TOF analysis. The master images of 2-DE gel images obtained from 2mg samples of large litter size group and small litter size group endometrial proteins at pH 3.0-10.0 revealed more than 400 protein spots in pH 3.0-10.0 range. When we analyzed the levels of expression of proteins that protein spots appeared more than 1.5-fold difference in endometrial tissue from porcine. In comparison of SLSG(small litter size group) with LLSG(large litter size group), a total of 18 protein spots differentially expressed on porcine endometrial tissue 2-DE gels, among which 9 spots were up-regulated proteins as retinol dehydrogenase 16-like isoform 1, Acrosin-binding protein, alpha-N-acetylgalactosaminidase. phosphoglycerate kinase 2, Acrosin-binding protein in LLSG. And 8 spots were up-regulated proteins as phosphoglycerate kinase 2, prenylcysteine oxidase in SLSG.

Until now, problems related to shortage of organ for transplantation have been continuing. Pigs are the most suitable animal for xenotransplantation. Although primates are most similar to humans, they are not suitable because they have low productivity. Pigs are more productive than primates, and their organ size and physiological characteristics are similar to humans, with the exception of primates. In this study, we breeding the transgenic minipigs using natural mating to produce transgenic pigs. And, transgenic pigs has transmission rate that follow mendel’s rule. There are 20% hDAF gene, 20% US11 gene and 50% both hDAF and US11 gene in transgenic offsprings. Furthermore, transgenic pigs followed normal litter size, and piglets also has normal sex ratio. To suppress the immune function, experiments were performed using porcine ear fibroblast that transfected with hDAF and US11gene. In Cytotoxicity experiment against human complement, hDAF gene and double transgenic cell with both hDAF and US11 gene showed effect to reduce cytotoxicity rate in all of human complement condition. US11 gene and double transgenic cell were significantly reduce the cytotoxicity ratio in human NK cell. Besides, hDAF gene transgenic cell also reduce immune response in 10:1 concentration of human NK cell. In conclusion, natural mating was efficient method for breeding transgenic pigs. And, hDAF and US11 genes has effect for reduce cytotoxicity against human NK cell and human complement conditions.

Xenotransplantation is proposed as a solution to the problem of organ shortage. However, transplantation of xenogeneic organs induces an antigen-antibody reaction in α-1,3-gal structure that are not present in humans and primates, and thus complement is also activated and organs die within minutes or hours. In this study, we used FasL gene, which is involved in the immune response of NK cell, and US11, which suppresses MHC Class I cell membrane surface expression, to inhibit cell mediated rejection in the interspecific immunity rejection, and also hDAF(CD55) was introduced to confirm the response to C3 complement. These genes were tranfeced into Korean native pig fetal fibroblasts using pCAGGS vector. And cytotoxicity of NK cell and human complement was confirmed in each cell line. The US11 inhibited the cytotoxicity of NK cell and, in addition, the simultaneous expression of US11 and Fas ligand showed excellent suppress to T-lymphocyte cytotoxicity, hDAF showed weak resistance to cytotoxicity of natural killer cell but not in CD8+ CTLs. Cytotoxicity study with human complement showed that hDAF was effective for reducing complement reaction. In this studies have demonstrated that each gene is effective in reducing immune rejection.

Embryo development is very important in reproductive physiology of domestic animal experiments. Therefore, in the above experiment, we want to provide a lot of important information with regard to fertilization breeding by looking at the expression of transcription factor by early embryo development. It is known that mice affect early embryonic development of many transcription factors, many experiments are underway. Different types of mammals showed different expression patterns, thus, we used pigs, which are known to be the most similar to humans, to observe the expression of transcription factors in early embryonic development. Transcription factors were observed using CDX2, OCT4 and E-CADHERIN. CDX2 was expressed in 2 cells, OCT4 and E-CADHERIN were expressed in blastocyst. OCT4 was expressed specifically in ICM (inner cell mass) in blastocyst, and E-CADHERIN was expressed in cell wall and junction of blastocyst. These results show that CDX2, OCT4 and E-CADHERIN play an important role in early embryonic development in pigs.

Porcine litter size is a quantitative trait and its heritability is especially low. So it is necessary to identify porcine reproductive gene and protein. The establishment of pregnancy requires performance of a receptive endometrium. We analyzed the endometrial tissue protein of porcine and would find out biomarker proteins related to porcine litter size. We sorted the two groups according to litter size of porcine: a small litter size group (SLSG) (n=2) and a large litter size group (LLSG) (n=2). The porcine endometrial tissue samples were analyzed separately using 2-dimensional electrophoresis (2-DE) within the isoelectric point ranges of 3.0 to 10.0, and then differential proteins were identified using MALDI-TOF analysis. In comparison of SLSG(small litter size group) with LLSG(large litter size group), a total of 9 protein spots differentially expressed on porcine endometrial tissue 2-DE gels, among which 5 spots were up-regulated proteins as retinol dehydrogenase 16-like isoform 1, Acrosin-binding protein, alpha-N-acetylgalactosaminidase. phosphoglycerate kinase 2, Acrosin-binding protein in LLSG. And 4 spots were up-regulated proteins as phosphoglycerate kinase 2, prenylcysteine oxidase in SLSG.

α-solanine is toxic to human health by disturbing digestive and central nervous systems. However, little information has been focused on investigated with respect to α-solanine influence in mammal oocyte maturation and quality. In this study, we investigated the effects of α-solanine on oocyte maturation, quality and possible molecular mechanisms in a pig model. Porcine Cumulus-oocyte complexes (COCs) were treated with increasing concentration (0, 1, 10, 20, 50 μM) of α-solanine subjected to further in vitro maturation culture. The result showed that α-solanine significantly inhibited cumulus cells expansion and increased oocyte death rates when the concentration of α-solanine more than 10 μM. After cell cycle and cytoskeleton analysis, the results showed that α-solanine (10 μM) disturbed meiotic resumption, increased abnormal spindle formation and cortical granules (CGs) distribution rates when compared with the untreated group. α-solanine (10 μM) triggered autophagy by increasing the expression of autophagy-related genes (LC3, ATG7, LAMP2) and accumulation of LC3-specific puncta (an autophagy maker). TUNEL staining assay showed that α-solanine significantly increased apoptosis in porcine oocytes confirmed by up-regulated the levels of BAX and CAPS3 genes. Further study revealed that exposure α-solanine (10 μM) to porcine oocytes induced ROS generation, reduced mitochondrial membrane potential. In addition, our results suggested that α-solanine (10 μM) significantly increased the levels of H3K36me3 and H3K27me3 in porcine oocytes. Taken together, these data indicated that α-solanine toxic impaired oocyte maturation and quality by inhibited cumulus cells expansion, increased abnormal spindle and CGs distribution rates, triggered autophagy/apoptosis occur, accumulated ROS, decreased mitochondrial membrane potential, and changed epigenetic modifications.

In pig, more than half of the recovered cumulus cell-oocyte complexes (COCs) have one or two layers of cumulus cells and are considered morphologically poor. If we could take full advantage of these poor quality COCs, we could potentially improve the efficiency of in vitro embryo production. During in vitro maturation, although some maturation factors are transmitted bidirectionally between the oocyte and cumulus cells of the same COC, transmission also occurs between different COCs. We hypothesized that morphologically poor COCs fail to undergo complete oocyte maturation due to their insufficient secretion of maturation factors. Here, we investigated whether co-culture with morphologically good COCs (having three or more layers of cumulus cells) could improve the maturation and utilization rates of morphologically poor COCs. Our results revealed that the oocyte maturation rate, glutathione level, embryo development capacity, blastocyst quality, and cumulus cell gene expression levels of BCL-2 and PCNA were similar in the co-culture and good quality-groups, and that these levels were all significantly higher than those in the poor quality-group. Our results strongly suggest that the co-culture strategy greatly improved the utilization rate of morphologically poor COCs without reducing their capacity for maturation and subsequent development.

Early pregnancy results in th production of various signal molecules such as steroids, prostaglandins, and many protein factors. The proteins especially produced by the placenta have been used to detect pregnancy for many years in other species. More recently, pregnancy-specific protein B, which is a placental glycoprotein can be measured by RIA or proteomic methods in serum of pregnant cow. And 2D Fluorescence difference gel electrophoresis (DIGE) is an emerging technique for comparative proteomics, which improves the reproducibility and reliability of differential protein expression analysis between samples. For this reason, we are analyzed serum of bovine. The purpose of this study was to apply DIGE technique for identification of bovine pregnancy-specific proteins using bovine pregnant and non-pregnant serum samples. Serums of 2 pregnant Holstein dairy cattle at day 21 after AI and those of 2 non-pregnant were used in this study. The molecular weight and charge matched cyanine dyes enable pre-electrophoretic labeling of non-pregnancy and pregnant serum proteins which are then mixed and labeled with Cy2 were used as an internal standard. Two pools of proteins are labeled with Cy3 and Cy5 fluorescent dyes, respectively. Labeled proteins with Cy2, Cy3 and Cy5 mixed together and separated in same gel and then were detected by fluorescence image analyzer. The 2D DIGE analysis using fluorescence CyDye flour showed higher sensitivity and better reproducible results than conventional 2D gel electrophoresis. Approximately 1,500 protein spots were detected by 2D DIGE. The differentially expressed proteins were identified by MALDI-TOF Mass spectrometer. Total 16 protein spots differentially expressed in the pregnant serum were detected, among which 7 spots were up-regulated proteins identified as conglutinin precursor, modified bovine fibrinogen, IgG1 etc, and 6 spots were down-regulated proteins identified as hemoglobin, complement component 3, bovine fibrinogen, IgG2a etc. These results indicated that DIGE system could be advantageous for the analysis of serum proteomics diversified by physiological conditions.

Pigs are considered an ideal source of human disease model due to their physiological similarities to humans. However, the low efficiency of in vitro embryo production (IVP) is still a major barrier in the production of pig offspring with gene manipulation. Despite ongoing advances in the associated technologies, the developmental capacity of IVP pig embryos is still lower than that of their in vivo counterparts, as well as IVP embryos of other species (e.g., cattle and mice). The efficiency of IVP can be influenced by many factors that affect various critical steps in the process. The previous relevant reviews have focused on the in vitro maturation system, in vitro culture conditions, in vitro fertilization medium, issues with polyspermy, the utilized technologies, etc. In this review, we concentrate on factors that have not been fully detailed in prior reviews, such as the oocyte morphology, oocyte recovery methods, denuding procedures, first polar body morphology and embryo quality.

Embryonic genome activation (EGA) is a highly complex phenomenon that is controlled at various levels. New studies have ascertained some molecular mechanisms that control EGA in several species; it is apparent that these same mechanisms regulate EGA in all species. Protein phosphorylation, DNA methylation and histone modification regulate transcriptional activities, and mechanisms such as ubiquitination, SUMOylation and microRNAs post-tran-scriptionally regulate development. Each of these regulations is highly dynamic in the early embryo. A better under-standing of these regulatory strategies can provide the possibility to improve the reproductive properties in mammals such as pigs, to develop methods of generating high-quality embryos in vitro, and to find markers for selecting de-velopmentally competent embryos.

The objective of the present study was to investigate the effects of different concentrations of sorbitol supplementation for in vitro maturation medium and in vitro culture medium, on porcine cumulus oocyte complexe(COC) maturation and subsequent developmental capacity after parthenogenetic activation. Porcine COC were cultured for 44 h(0～ 22 h termed MI stage and 22～44 h termed MII stage) in TCM199 without(— ) or with(+) sorbitol (20 μM, 100 μM, 200 μM), and the resultant metaphase II oocytes cultured in PZM-3 for 7 days following activation. Our results showed that supplementation with appropriate concentrations of sorbitol (20 μM) during full term maturation culture(MI+/MII+) significantly(p<0.05) improved blastocyst formation rates and total cell number. When the concentration of sorbitol were increased to 100 μM and 200 μM during maturation culture, the maturation rate of COC were significantly reduced compared with 20 μΜ or control groups. Also blastocyst formation rates significantly(p<0.05) reduced with increasing concentration of sorbitol(200 μM). Supplementation with sorbitol(20 μM, 50 μM, 100 μM) into PZM-3 for in vitro culture significantly(p<0.05) inhibited blastocyst formation compared with control group. However, the blastocyst formation rates start to rise again when 50 μ M sorbitol was used for the first 48 hours and then cultured in PZM-3 without sorbitol. There was no significant difference in cell number between control and sorbitol treated groups. When the activated oocytes were cultured in PZM-3 for 48h and then cultured in PZM-3 with sorbitol, interestingly, the blastocyst formation rate was similar to that of PZM-3 with sorbitol for in vitro culture and significantly lower than control group. These results suggest that addition of low concentrations of sorbitol(20 μM) during oocyte maturation is beneficial for subsequent blastocyst development and improved embryo quality. However, treatment with sorbitol supplementation during in vitro culture medium is negative effect to blastocyst formation.

Epigenetic status of the genome of a donor nucleus has an important effect on the developmental potential of cloned embryos produced by somatic cell nuclear transfer (SCNT). In our previous study has results showed that the donor cells treated with 5-aza-2’- deoxyctidine (5-aza-dC, DNA methylation inhibitors) and Trichostatin A (TSA, histone deacetylase inhibitors) could improve the development of porcine nuclear transfer embryos in vitro. In this study we want to investigate why these two drugs treatment with the donor cell can improve the cloning efficiency, whether they can alter the epigenetic status of the genome of the donor nucleus. This study included 6 groups: control group, the donor cell (porcine fetal fibroblast cell) with no treatment; 2.5 nM 5-aza-dC group, the donor cells treated with 2.5 nM 5-aza-dC for 1h; 5-aza-dC group, the donor cells treated with 5 nM 5-aza-dC for 1h; TSA group, the donor cells treated with 50 nM TSA for 1h; 2.5 nM 5-aza-dC+TSA group, the donor cells treated with 2.5 nM 5-aza-dC for 1h and subsequently treated with 50 nM TSA for another 1h; 5-aza-dC+TSA group, the donor cells treated with 5 nM 5-aza-dC and 50 nM TSA together for 1h. The first experiment detected the DNA methylation status in the different groups. After treatment with these two drugs, the DNA methylation level of the donor cells decreased, however there is no significant difference among the groups. This result indicated that the donor cell treatment with 5-aza-dC and TSA can partially alter the DNA methylation status of the donor cells. The second experiment checked the histone acetylation level of the donor cells treated with these two drugs by western blot. TSA, 2.5 nM 5-aza-dC+TSA, 5 nM 5-aza-aC+TSA, these three groups can significantly improve the hisone acetylation level compared with control and 5-aza-dC groups, there is no significant difference among these three groups. The results of this study suggest that the donor cells treated with 5-aza-dC and TSA can partially decrease DNA methylation and can significantly improve the histone acetylation level of the donor cells, these alterations of the epigenetic modification maybe can improve the clonging efficiency.

5‐aza‐2’‐deoxyctidine (5‐aza‐dC) is DNA methylation inhibitor and Trichostatin A (TSA) is histone deacytlase inhibitor, both of them can alter the level of the epigenetic modification of cells. The objective of this study was to investigate the effects of treatment with 5‐aza‐dC and TSA into fetal fibroblasts on the development of porcine nuclear transfer (NT) embryos. In this study, experiments were performed in order to modify epigenetic status in donor cells and evaluate developmental potential of NT embryos. 5‐ aza‐dC or TSA or combining treatment of TSA and 5‐aza‐dC was treated into growing donor cells for 1 h exposure and development of NT embryos was evaluated. Experiment was performed with 3 groups: control group (donor cells without treatment); TSA group (donor cell treated with 50 nM TSA for 1 h); TSA + 5‐aza‐dC group (donor cells were treated with 50 nM TSA and 5 nM 5‐aza‐dC for 1 h); TSA+1/2(5‐aza‐dC) group (donor cells were treated with 50 nM TSA for 1h and subsequently treated with 2.5 nM 5‐aza‐dC for another 1h). When donor cells were individually treated with 5 nM 5‐aza‐dC or 50 nM TSA for 1h, the blastocyst rate of NT embryos increased significantly compared with control group [18.8% vs 13.4% (5 nM 5‐aza‐dC group vs control group), and 26.2% vs 11.8% (50 nM TSA group vs control group), p<0.05]. However, the blastocyst rate in combining treatment group (50 nM TSA + 5 nM 5‐aza‐dC) did not increase compare with control group (12.3% vs 11.8%, p>0.05). When the donor cell were individually treated with 50nM TSA for 1 h firstly and then treated with 2.5 nM 5‐aza‐dC for another 1h, the blastocyst rate was significantly improved compared with control and TSA group (28% vs 10.2% and 23.7%, p<0.05). The present study suggested that donor cells treated with TSA or low concentration of TSA+5‐azadC in short time exposure may enhance the development of porcine NT embryo.