The fatty acid binding protein 4 (FABP4) gene plays an important role in lipid metabolism and homeostasis in adipocytes. The objective of this study was to analyze the association between a single nucleotide polymorphism (SNP), g.7516G>C, in the FABP4 gene and economic traits of Korean native cattle, Hanwoo. Primers were designed to target a region of the FABP4 gene between nucleotides 7417 and 7868 (AAFC01136716). The SNP, which was detected by polymerase chain reaction-based restriction fragment length polymorphism (PCR-RFLP) method using restriction enzyme MspA1I, was genotyped in 319 animals of Hanwoo steer population. Statistical analysis showed that the SNP genotype of the FABP4 gene significantly affected carcass weight (CW, p<0.01), longissimus muscle area (LMA, p<0.001), and marbling score (MS, p<0.001). GG allele of the SNP on 246 animals in a Wagyu × Limousin F2 reference population showed a higher MS (p<0.05) and subcutaneous fat depth (p<0.05) in previous report. But CC allele of the SNP showed greater values for MS, LMA, and CW in Hanwoo steers. These results suggest that the g.7516G>C SNP located in the FABP4 gene may affected differently depending on the cattle breed and can be used as a genetic selection marker in Korean native cattle.

G protein-coupled receptors (GPCRs) belong to cell membrane protein family, which regulate various physiological process such as reproduction, behavior and immune etc. In other to identify the GPCRs in pheromone gland of Maruca vitrata, we carried out transcriptome analysis from both females. Transcriptome analysis in the pheromone gland yielded approximately 22Gb and 47,528 transcripts showed positive FPKM value. 48 Genes involved in GPCRs were identified such as pheromone biosynthesis activating neuropeptide receptor (PBANr), prostaglandin receptors, neuropeptide receptor, 5-hydroxytryptamine receptor, galanin receptor, calcitonin gene-related peptide receptor, diuretic hormone receptor, gonadotropin-releasing hormone receptor, frizzled and orphan receptors, etc. Various expression of GPCRs in the pheromone gland indicates the role of pheromone gland may not be limited to the production of pheromone.

Insect blood cells, hemocytes, inhibit spreading behavior upon bacterial challenge to perform cellular immune responses. Hemocyte spreading is accomplished by cytoskeleton rearrangement, which is activated by various immune mediators, such as biogenic monoamins, plasmatocyte-spreading peptide(psp), and eicosanoids. However, little is known how these, immune mediators. acitvate hemocyte spreading behavior. A small G protein, Rac1, gene was identified in hemocytes of Spodoptera exiqua. Its expressed in most developmental stages accept egg and expecially expresses in hemocytes and fat body of Larval stage. In response to bacterial challenge, its expression was segnificantly up-regulated. However, RNA inteference (RNAi) of Rac1 expression inhibited hemocyte spreading behavior. under RNAi condition of Rac1, octopamine and psp failed to activate hemocyte spreading behavior. Interestingly, as addition of prostaglandinE2 to the RNAiconditioned Larval rescued the mediation of octopamine and psp. These results indicate that Rac1 is required for mediation of octopamine and psp on hemocytespreading behavior and suggest that Rac1 may activate eicosanoid biosnthesis.

Palatal development is one of the crucial events in craniofacial morphogenesis, according to the significant signaling pathway including the out growth, elevation, and fusion of palatal shelves. In the fusion of palatal shelves, epithelial to mesenchymal transition (EMT) is a fundamental process to achieve the proper morphogenesis of palate. Mechanisms of EMT have been reported as the processes of migration, apoptosis or general EMT through the modulations through various signalling molecules. Rgs19, known as a regulator of G protein signaling (RGS) family through GTPase activity, showed the interesting epithelial expression patterns in various organogeneses including the significant expression patterns of Rgs19 in palatal development. To evaluate the precise function of Rgs19 in palatogenesis, we employed the gain and loss of function studies using ASODN treatments and gene electroporations while in vitro palate organ cultivations. Knockdown of Rgs19 using treatments of AS-ODN showed the retarded palatal fusion with the decreased patterns of apoptosis in mesial epithelium edge (MEE). In addition, alteration patterns of related genes were examined with the qRT-PCR. And epithelial mesenchyme transition (EMT) process was delayed in medial edge epithelium (MEE) throught immunohistochemistry of pancytokeratin, which known as epithelial cell marker. Morphological changes were observed with the three dimensional reconstruction method. These results show that expression of Rgs19 in MEE has crucial role of EMT, also Rgs19 affects to palatal fusion by regulation of apoptosis through the signalling modulations.

Palatal development is one of the crucial events in craniofacial morphogenesis, according to the significant signaling pathway. In the fusion of palatal shelves, EMT is a fundamental process to achieve the proper morphogenesis of palate. Mechanisms of EMT have been reported as the processes of migration, apoptosis or general EMT through the modulations through various signalling molecules. Rgs19, known as a RGS family through GTPase activity, showed the interesting epithelial expression patterns in various organogenesis including the significant expression patterns of Rgs19 in palatal development. To evaluate the precise function of Rgs19 in palatogenesis, we employed the loss of function studies using AS-ODN treatments while in vitro palate organ cultivations. Knock-down of Rgs19 using treatments of AS-ODN showed the retarded palatal fusion with the decreased patterns of apoptosis in mesial epithelium edge (MEE). In addition, alteration patterns of related genes were examined with the qRT-PCR. And EMT process was delayed in MEE throught staining of pancytokeratin, which known as epithelial cell marker. These results show that expression of Rgs19 in MEE has crucial role of EMT, also Rgs19 affects to palatal fusion by regulation of apoptosis through the signalling modulations. Palatal development is one of the crucial events in craniofacial morphogenesis, according to the significant signaling pathway. In the fusion of palatal shelves, EMT is a fundamental process to achieve the proper morphogenesis of palate. Mechanisms of EMT have been reported as the processes of migration, apoptosis or general EMT through the modulations through various signalling molecules. Rgs19, known as a RGS family through GTPase activity, showed the interesting epithelial expression patterns in various organogenesis including the significant expression patterns of Rgs19 in palatal development. To evaluate the precise function of Rgs19 in palatogenesis, we employed the loss of function studies using AS-ODN treatments while in vitro palate organ cultivations. Knock-down of Rgs19 using treatments of AS-ODN showed the retarded palatal fusion with the decreased patterns of apoptosis in mesial epithelium edge (MEE). In addition, alteration patterns of related genes were examined with the qRT-PCR. And EMT process was delayed in MEE throught staining of pancytokeratin, which known as epithelial cell marker. These results show that expression of Rgs19 in MEE has crucial role of EMT, also Rgs19 affects to palatal fusion by regulation of apoptosis through the signalling modulations.

Hatching occurred in the time dependent manners and strictly controlled. Although, the hatching processes are under the control of muti-embryotrophic factors and the expressed G proteins of cell generate integrated activation, the knowledge which GPCRs are expressed during hatching stage embryos are very limited. In the present study, which G proteins are involved was examined during blastocyst development to the hatching stage. The early-, expanded-, and lobe-stage blastocysts were treated with various activators and H series inhibitors, and examined developmental patterns. Pertusis toxin (PTX) improved the hatching rate of the early-stage blastocyst and lobe-formed embryos. Cholera toxin (CTX) suppressed the hatching of the early-stage blastocyst and expanded embryos. The effects of toxins on hatching and embryo development were changed by the H7 and H8. These results mean that PTX mediated GPCRs activation is signaling generator in the nick or pore formation in the ZP. In addition, PTX mediated GPCR activation induces the locomotion of trophectoderm for the escaping. CTX mediate GPCRs activation is the cause of suppression of hatching processes. Based on these data, it is suggested that various GPCRs are expressed in the periimplantation stage embryos and the integration of the multiple signals decoding of various signals in a spatial and temporal manner regulate the hatching process.

스테로이드 호르몬의 합성은 콜레스테롤로부터 시작되고 Steroidogenic acute regulatory protein(StAR)은 스테로이드의 합성과정에서 콜레스테롤을 미토콘드리아의 안으로 신속하게 운반하는 역할을 한다. 스테로이드 호르몬은 난소, 부신, 고환에서 합성되며 본 연구에서는 흰쥐 난소와 부신에서 StAr mRNA의 발현 양상을 in situ hybridization 기법을 이용하여 조사하였다. 난소의 경우 StAR mRNa는 프로게스테론