Effect of insulin on the secretion of VEGF and its receptor in serum-free cultured bovine thoracic aortic endothelial cells

AIM: This study was designed to investigate the secretion of VEGF and its receptor (flt-1 or flk-1/KDR) protein by cultured bovine thoracic aortic endothelial cells treated with various insulin concentrations. METHODS: Endothelial cells was isolated from bovine thoracic aorta, and cultured in serum-free medium, then incubated with different insulin concentrations (30 mU/L, 300 mU/L, 3 000 mU/L). The level of VEGF and its receptor (flt-1 or flk-1/KDR) protein were detected by immunohistochemical staining. RESULTS: As compared with no insulin group, the expression of VEGF protein in low insulin concentration (30 mU/L and 300 mU/L) groups were significantly increased (P＜0.01). The expression of VEGF protein in high insulin concentration (3 000 mU/L) group was significantly decreased (P＜0.05). Howerer, no difference of the expression of VEGF receptor (flt-1 or flk-1/KDR) protein among all groups (P＞0.05) was observed. CONCLUSION: Low concentration insulin up-regulates the VEGF protein expression while high concentration insulin down-regulates the VEGF protein expression in bovine thoracic aortic endothelial cells, but insulin had no directly effect on the VEGF receptor (flt-1 or flk-1/KDR) protein expression in bovine thoracic aortic endothelial cells.     

体外培养条件对延边黄牛受精卵体外发育的影响

从延边黄牛卵巢中采集未成熟的卵母细胞进行体外成熟培养、体外受精及受精卵体外培养。结果表明 :1将卵子用 2种不同的培养液进行体外成熟培养和受精卵体外培养 ,TCM199组的卵裂率 (5 6 .3% )极显著高于 D- PBS组(33.6 % ) (P<0 .0 1) ;TCM199组的囊胚发育率和孵化率 (15 .1%、13.7% )虽高于 D- PBS组 (10 .5 %、8.7% ) ,但 2个组之间无显著差异 (P>0 .0 5 )。2以 TCM199作为基础培养液 ,分别用含激素培养液和不含激素培养液进行成熟培养和受精卵体外培养 ,添加激素组的卵裂率、囊胚发育率及囊胚孵化率 (81.2 %、17.5 %、15 .3% )高于没有添加激素的对照组 (75 .8%、12 .1%、10 .5 % ) ,但 2个组之间无显著差异 (P>0 .0 5 )。 3体外受精卵与单层颗粒细胞共培养组的卵裂率、囊胚发育率及囊胚孵化率 (78.0 %、11.5 %、9.9% )显著高于非共培养组 (6 8.1%、5 .4 %、3.6 % ) (P<0 .0 5 )。     

动物胚胎工程技术研究进展

动物胚胎生物工程是用人工方法对动物卵母细胞或胚胎进行改造的技术,在育种中可使优良的种质特性和遗传潜力得到充分发挥,是家畜繁殖领域的一次技术革命.论述了目前国内外胚胎生物工程的研究成果.     

鸡抗球虫药的体外筛选综述

抗鸡球虫药的筛选分为体内筛选和体外筛选。体外筛选具有简易、迅速、准确和经济的优点。本文在前人大量工作的基础上，总结了体外筛选的全过程，并分述了细胞培养筛选法和鸡胚培养筛选法。     

山羊孤雌胚胎的体外培养

系统地研究了培养液微滴的大小、培养液体系及血清浓度对山羊孤雌胚胎早期体外发育的影响。结果表明，培养液微滴以较大体积(200～500μL)的培养效果较好；在3种培养液中，添加10％的NGS对山羊孤雌胚胎的体外发育效果较好，囊胚率分别可达62．79％(81／129)、53．52％(38／71)、13．64％(12／88)；mCRlaa组囊胚发育率和囊胚细胞数显著低于SOFaa组和CRlaa组，SOFaa组优于CRlaa组，尽管SOFaa组和CRlaa组间无显著差异。在本试验条件下，以SOFaa培养液，山羊孤雌胚胎体外培养72h时加入10％的NGs，500μL微滴培养，其发育效果较好，囊胚率可达62．79％。     

添加不同酵母培养物对瘤胃纤维分解菌群和纤维素酶活的影响

用3种酵母培养物(YC- 1、YC 2和YC- 3)分别饲喂4头带有永久性瘤胃瘘管的肉牛,研究培养物对瘤胃发酵、纤维分解酶活性和3种纤维分解菌数量的影响,结果表明:YC 2处理的乙酸、丙酸、丁酸和总 VFA浓度显著高于对照组(P<0 .05),YC 1和YC 3处理的乙酸/丙酸比例显著降低(P<0 .01);各处理均能显著提高瘤胃内羧甲基纤维素酶、水杨苷酶和木聚糖酶的活性(P<0 .01);各处理都显著提高黄化瘤胃球菌的相对比例(P<0 .01),16SrRNA特异性寡聚核苷酸探针杂交法分析测定结果表明 3 种纤维分解菌在瘤胃细菌中所占比例为 3. 80%±0 .2%。     

北京油鸡胚胎成纤维细胞系建立与生物学特性研究

采取组织块直接培养法，对北京油鸡胚胎组织进行原代和继代培养，成功地建立了成纤维细胞系。并对培养细胞进行了形态学、细胞生长动力学观察，以及核型和乳酸脱氢酶、苹果酸脱氢酶的同工酶分析。结果表明，该细胞系的群体倍增时间(PDT)为24h；细胞染色体中二倍体占主体，为76％～88％；乳酸脱氢酶、苹果酸脱氢酶同工酶电泳图谱与本室其它细胞系有明显差别；细菌、真菌、病毒、支原体检测呈阴性。该细胞系的建立，使北京油鸡这一国家重要种质资源在细胞水平上保存下来，也为基因组文库和体细胞克隆等研究提供了理想的生物材料。     

母牛一胎双犊技术的研究

选择9头母牛先行人工授精、7天后再移植冷冻胚胎以生产双犊。试验结果表明,母牛产双犊达44.44%(P<0.01)。提示:采用A(I人工授精)+ET(胚胎移植)是提高母牛双犊率的有效技术措施之一。     

Differential gene expression of Eph‐ephrin A1 and LEPR‐LEP with high or low number of embryos in pigs during implantation

The objective of this study was to ascertain whether mRNA and protein expressions of implantation‐related genes (erythropoietin‐producing hepatocellular receptor–ligand A1, Eph‐ephrin A1 and leptin receptor–leptin, LEPR‐LEP) differed between pigs with high and low number of embryos, and whether these differences in gene expression might affect embryo implantation. Experimental pig groups (n = 24) for high and low number of embryos were prepared by altering the number of eggs ovulated in pre‐pubertal gilts treated with 1.5 × (High) or 1.0 × (Low) PG600 ([400 IU PMSG + 200 IU hCG]/dose, AKZO‐NOBEL). Gilts expressing oestrus were artificially inseminated twice and maintained in breeding and gestation until the reproductive tract was collected on day 22 of pregnancy. At slaughter, the reproductive tracts from each pregnant gilt from each treatment were immediately processed to collect samples for RNA and protein analysis. Within each gilt, three conceptus points were sampled, one from each horn and then a random conceptus within the tract. At each conceptus point, endometrial attachment site, chorion–allantois and embryo were collected and immediately frozen in liquid nitrogen. Number of corpus luteum (CL) (35.4 vs. 12.6) and total embryo number (18.8 vs. 10.2) were greater in the high‐embryo compared to the low‐embryo group, respectively (p < .05). Real‐time qPCR results showed that Eph‐ephrin A1 mRNA expression was less in the high‐embryo (p < .05) compared to the low‐embryo group. In addition, Western blotting analysis indicated that Eph‐ephrin A1 and LEP protein expression at endometrial attachment site in high‐embryo was less (p < .05) compared to low‐embryo group. It was also noted that mRNA expression of Eph‐ephrin A1 and LEPR‐LEP was greater in pregnant than non‐pregnant gilts (p < .05). Moreover, mRNA expression of Eph‐ephrin A1 (p < .05) and LEPR‐LEP was greatest at endometrial attachment site among all three tissues. There was a positive correlation between expressions of Eph‐ephrin A1, LEPR‐LEP and embryo length with the correlation coefficient 0.31–0.59. For Eph‐ephrin A1, the highest correlation coefficient appeared between Eph A1 expression and normal embryo number, between ephrin A1 expression and embryo length. For LEPR‐LEP, the highest correlation coefficient appeared between LEPR‐LEP expression and ovary weight (0.79 for both, p < .05), followed by embryo length and weight. The results of this study suggest that low expression of Eph‐ephrin A1 and LEPR‐LEP is somehow related to increased embryo number during implantation and that endometrial attachment site might be the main target tissue of these gene products. Yet, the increased expression of Eph‐ephrin A1 and LEPR‐LEP appeared associated with increased embryo growth (length and weight) and ovary weight, Eph‐ephrin A1 and LEPR‐LEP might play roles in the regulation of embryo implantation in pigs.