猪链球菌重组GDH蛋白间接ELISA检测方法的建立

为建立猪链球菌快速诊断方法,本研究以纯化的原核表达的猪链球菌谷氨酸脱氢酶蛋白(GDH)为抗原,建立了检测猪链球菌抗体的间接ELISA诊断方法。实验确定了最佳抗原包被浓度为6μg/mL,待检血清最佳稀释倍数为1∶100,其作用时间为60min,兔抗猪酶标抗体的最佳稀释倍数为1∶2000,其作用时间为60min;判定标准为S/P值≥0.210时判为阳性,S/P值≤0.166时判为阴性,介于两者之间的判为可疑。实验结果表明该方法特异性、敏感性和重复性均较好,适用于猪链球菌所有亚型的抗体检测,为猪链球菌的流行病学调查提供了一种简便快速的血清学检测方法。

猪链球菌WC-SS7株GDH基因的表达及GDH蛋白单克隆抗体的制备

目的原核表达猪链球菌7型临床分离株WC-SS7的GDH蛋白,制备抗GDH蛋白的单克隆抗体(mAb)。方法将临床分离的猪链球菌7型WC-SS7株的GDH基因克隆入表达载体pET-30a,转入大肠杆菌中,用IPTG诱导表达,用Ni化琼脂糖柱(Pierce)纯化的GDH蛋白免疫BALB/c小鼠,取鼠脾细胞与SP2/0骨髓瘤细胞融合,通过间接ELISA方法筛选阳性克隆,对抗WC-SS7GDH蛋白单克隆抗体进行特异性鉴定及亚型鉴定。结果表达产物经SDS-PAGE凝胶电泳分析后,在约为52KD处可见一条明显的诱导表达带,说明GDH蛋白得到了正确的表达;细胞融合后检测为阳性的细胞株经过3次单克隆筛选,最终得到了6株能和GDH蛋白反应的能稳定分泌单抗的阳性细胞克隆,这些单抗通过Western鉴定结果显示其具有良好的特异性,6株单克隆抗体亚型鉴定结果显示其亚型均为IgG1型,且轻链均为κ链。结论本研究成功表达了WC-SS7的GDH蛋白,并获得了6株能和GDH蛋白反应的、能稳定分泌单抗的阳性细胞克隆,所获得的重组GDH蛋白及特异性单克隆抗体能用于猪链球菌结构和功能的研究,为猪链球菌临床感染血清学诊断方法的建立奠定基础。

动物组织中GLUD1基因表达与GDH蛋白结构分析

[目的]研究动物不同组织中GLUD1基因的表达情况,比较不同物种中GDH蛋白的结构差异,明晰GLUD1基因的表达模式与GDH蛋白的功能。[方法]分别采集大鼠、绵羊、梅花鹿的肝脏、肾脏、皮肤、脂肪和肌肉5种新鲜组织样品。以β-actin为内参基因,采用荧光定量PCR法(qRT-PCR)分析3种动物不同组织中GLUD1基因的表达情况;利用无重复双因素分析方法表征GLUD1基因在不同组织中的表达量差异。比较人、小鼠、大鼠、山羊、绵羊、牛和猪7个物种GDH蛋白氨基酸序列,模拟这7个物种的GDH蛋白三维空间结构。[结果]GLUD1基因在大鼠、绵羊和梅花鹿的5个组织中均有表达,在肝脏中的表达量均高于其他组织;该基因在大鼠和梅花鹿肝脏组织中的表达量极显著(P<0.01)高于绵羊肝脏组织中的表达量,在大鼠肾脏组织中的表达量极显著(P<0.01)高于梅花鹿肾脏组织中的表达量。人GDH蛋白的氨基酸序列与猪、牛、山羊和绵羊的序列相似度较高,而大鼠与小鼠GDH蛋白的氨基酸序列相似度达到99.10%。大鼠、人、猪的GDH蛋白氨基酸序列中分别存在2个(第8位丙氨酸→缬氨酸、第40位丙氨酸→缬氨酸)、1个(第23位丙氨酸→丝氨酸)、2个(第33位丙氨酸→苏氨酸、第39位丙氨酸→苏氨酸)物种特异性突变位点。小鼠、大鼠、人的GDH蛋白预测为三聚体结构,山羊、绵羊、牛和猪的GDH蛋白预测为同源六聚体结构。[结论]GLUD1基因在大鼠、绵羊、梅花鹿不同组织中的表达量存在差异,在肝脏中都有较高水平的表达。不同物种GDH蛋白的氨基酸序列相似度较高,但依旧存在一定的序列差异性,并且存在数个对应物种特异性的氨基酸突变位点。

He-Ne激光对小麦幼苗增强UV-B辐射损伤的修复研究

分别采用5mW·mm-2He-Ne激光辐照和增强UV-B辐射(10.08kJ·m-2·d-1)及其二者组合对晋麦8号小麦幼苗进行处理,5d后测定各处理幼苗叶片可溶性蛋白、硝酸还原酶和谷氨酸脱氢酶活性的变化以分析He-Ne激光对小麦幼苗受增强UV-B损伤的修复作用.结果显示:He-Ne激光辐照可使UV-B辐射后小麦幼苗叶片的可溶性蛋白含量增加,谷氨酸脱氢酶活性增强,而使硝酸还原酶活性先升高后降低.表明小麦幼苗叶片可溶性蛋白、谷氨酸脱氢酶、硝酸还原酶的变化同小麦幼苗损伤修复的能力相关,一定剂量的He-Ne激光辐照可部分修复增强UV-B对小麦幼苗氮代谢水平的辐射损伤.

Using the RNA synthetic activity of glutamate dehydrogenase to illuminate the natural role of the enzyme

Glutamate Dehydrogenase (GDH;EC 1.4.1.2) catalyzes the reversible amination of α-ketoglutarate to glutamate, and the polymerization of nucleoside triphosphate(s) to RNA. But the natural role of the reversible amination reaction is the subject of an expanding conversation. The aim was to illuminate the natural role of GDH through its RNA synthetic activity. Stoichiometric combinations of mineral salts that targeted the GDH subunit compositions were applied to field-cultivated peanuts. GDH of seeds were made to synthesize RNA in the deamination and then in the amination direction. Free amino acids were analyzed by HPLC. Glutamate synthase (GOGAT) was assayed by photometry. Free amino acid yields in-creased from the control’s lowest (9.8 kg·ha–1) and amination-deamination ratio (0.05) through 12.0 - 23.0 kg·ha–1 in the K-, N+K+P+S-, Pi-, N+S-, S-treated peanuts with amination-deamination ratios between 0.6 and 10.0 until at the P+K-treated peanut which had the highest amino acid yield (52.4 kg·ha–1) and the highest amination-deamination ratio (61). The Km and Vmax values of GOGAT were within the normal range. Yields of free amino acids resulting from GDH aminating activity increased from <1.0 kg·ha–1 in the control, through 2.2 in the N+S-, 6.84 in the P+N-, 17.3 in the N-, to 42.6 kg·ha–1 in the P+K- treated peanut. These results show that the natural role of the GDH amination activity is to assimilate escalating multiples of the quantities of NH4+ ion as assimilated via the GS-GOGAT pathway. Peanut protein yields increased in parallel with GDH aminating activities and free amino acid yields such that the control peanut had the lowest protein (<26.0 kg·ha–1) and the yields increased exponentially (500 - 600 kg·ha–1) through the K-, P+S-, Pi-, N-treated to 910 kg·ha–1 in the P+K-treated peanut with the highest aminating activity of GDH. The ability of GDH aminating activity to escalate protein yields of food crops could be employed to address proteinenergy malnutrition syndrome of developing nations.