The identification of biomarkers of a living tissues is essentially required to understand specific functions of the cells. In previous study, we reported IGFBP 3 as one of the putative biomarkers, by showing specific expression at porcine spermatogonial stem cells (SSCs) of early stage of porcine testis. In this study, we analyzed the expression of seven members of IGFBP family (IGFBPs) in SSCs and histological expression pattern of pregnancy-associated plasma protein-A (PAPP-A), which plays a role on the growth promoting enzyme by cleavage of IGFBPs in testis of 5 days old pig. RT-PCR analysis showed that IGFBP 1, 2, 3, 4, and 6 were expressed at high level specifically in porcine SSCs compared with whole testis. We performed immunohisotochemical staining of testis sections with PAPP-A and protein gene product 9.5 (PGP9.5) which are the known biomarkers for SSCs. We were not able to find co-expression of PAPP-A and PGP9.5; PAPP-A was expressed only in Sertoli cells and PGP9.5 expression was confirmed in spermatogonium. Additionally, we were able to confirm the GATA4 expression in Sertoli and Leydig cells as a regulator of Sertoli cell function was not detected PGP9.5 expressing cells, indicating indirect evidence of that cytolocalization of PAPP-A expression is limited in Sertoli cells. These results suggested that the PAPP-A expressed in Sertoli cells may play role on regulation of development and differentiation of testicular cells through the IGF axis in neonatal porcine testis.

Recent findings indicate that Type 2 taste receptors (T2Rs) are expressed outside the gustatory system, including in the gastrointestinal tracts and the exocrine glands, such as the submandibular (SM), parotid (P), lacrimal (L) glands and pancreas (PC). Specifically, T2Rs are found in some of the gastrointestinal endocrine cells, and these cells secreted peptide hormones in response to stimulation by bitter-tasting compounds. The results show that T2Rs may have significant physiological roles besides bitter taste reception. The functions of the T2Rs in the exocrine glands remain poorly understood. An expression levels analysis of T2Rs will help to determine those functions in the exocrine glands. The expression levels of the T2Rs in the exocrine glands were discovered via the qPCR. C57BL/6J mice of 42~60-day-old were used. Messenger RNAs were extracted from S, P, L and PC. Cloned DNAs were synthesized by reverse transcription. Quantitative PCRs were performed using the SYBR Green method. The expression levels of the T2Rs were calculated as relative expression levels to that of the GAPDH. The statistical significance among the observed exocrine glands was tested using the variance analysis (ANOVA test). Tas2r108, out of murine 35 T2Rs, was the most highly expressed in every observed exocrine gland. This finding was similar to previous results from tongue papillae, but the expression levels were lower than those of the tongue papillae. Tas2r137 of SM, P, L and PC were expressed a little lower than that of tongue papillae. The T2Rs in the exocrine glands may play slightly different roles from those in the tongue. We suggest that physiological studies such as a patch clamp and functional Ca2+ imaging of acinar cells are necessary for understanding the Tas2r108 functions.

Through data mining of the Cordyceps militaris genome, a lectin-encoding gene, CMLec3, was identified. In this study, the CMLec3 sequence was analyzed using bioinformatics approaches, and the gene was heterologously expressed in Escherichia coli BL21 cells. The biological activity of the product was examined. In addition, CMLec3 gene expression levels were assessed. The results showed that the CMLec3 protein contained a lectin domain structure and was successfully expressed. The CMLec3 protein partly inhibited HeLa cell proliferation. CMLec3 exhibited the highest gene expression in the primordium at a level 5.19 times that of the mycelium and 1.35 times that of the fruiting body. This suggests that the gene may be related to fruiting body development.

The nature of molecular mechanisms governing embryo development is largely unknown, but recent reports have demonstrated that proper execution of programmed cell death is crucial for this process. The main objective of this study is to examine the mode of programmed cell death during nuclear transfer embryos development in porcine. In particular, the relative employment of two major pathways in programmed cell death; e.g. apoptosis (type I) and autophagy (type II) was compared. Oocytes use in the study was matured in vitro in the presence of 10% FBS maturation medium. After nuclear transfer embryos were cultured for each programmed cell death control factor [Cysteamine(Cyst : 0.4mM), 3-methyladenine(3MA : 2.5mM) and Rapamycin(RP : 100nM)] in TCM-199 medium supplemented with 0.1% BSA. In this study results of among the blastocysts development in 3MA; PCNA, MAP1LC3A and ATG5 RNA gene expression level increased in the order of IVF<Cyst < 3MA < RP. However Casp-3 and TNF-r RNA gene expression level decreased in the order of IVF < 3MA and RP< Cyst. The expression of mTOR showed a pattern opposite to that of MAP1LC3A. That is, its expression was the lowest in Cyst group. And next experiments analysis of MMP expression patterns. Analysed this MMPs enzyme activation to evaluate the effectiveness of high quality brastocyst culture in porcine. In this results of the enzymatic activity of MMP-2 and MMP-9 was assessed in culture, the level of active MMP-9 was higher expression in the medium of each 3MA and RP treatment group, with the level of another treatment group being relatively higher. These results suggest that the autophagy activation culture medium is more effective for stable and innovative nuclear transfer embryos development.

The coat color of mammals is determined by the melanogenesis pathway, which is responsible for maintaining the balance between black-brown eumelanin and yellow-reddish pheomelanin. The melanogenesis-associated genes controlling pigmentation act as a complex and interact with each other to cause phenotypic and genotypic variations in cattle. That the MC1R genotype of Korean native cattle with dark muzzle was e/e or E+/e, while the genotype of Korean native cattle with light muzzle was E+/E+, which is a variant of the MC1R genotype in the Korean native cattle. Especially, the MC1R expression type is shows how much pigmentation, important factor in deciding its status in the coat and nose colours. However, information regarding the coat or nose colours-associated gene regulation of korean cattle is not yet unknown. Therefore, in this study was to investigate the expression patterns of melanogenesis-associated genes in black dot nose(korea brindle cattle) and normal nose(korea native cattle). Using microarray clustering and real-time polymerase chain reaction techniques, we analysed that the expression of genes involved in the mitogen-activated protein kinase (MAPK) and Wnt signaling pathways is distinctively regulated in the dark and light muzzle tissues. Differential expression of tyrosinase was also noticed, although the difference was not as distinct as those of MAPK and Wnt. We hypothesize that emphasis on the MAPK pathway in the Korea brindle cattle induces eumelanin synthesis through the activation of cAMP response elementbinding protein and tyrosinase, while activation of Wnt signaling counteracts this process and raises the amount of pheomelanin in the native cattle. Regarding the increasing interest in the genetic diversity of cattle stocks, genes we identified for differential expression in the brindle cattle vs. native cattle may serve as novel markers for genetic diversity among cows based on the coat and muzzle color phenotype.