Molecular characterization of an ecdysone inducible gene E75 of Chinese shrimp Fenneropenaeus chinensis and elucidation of its role in molting by RNA interference

Ecdysone inducible gene. E75 is a primary target of ecdysone receptor (EcR). and is found to play a critical role in the molting process of arthropods In this study, a cDNA encoding the E75 of Chinese shrimp Fenneropenaeus chinensis (FcE75) was cloned using RT-PCR and RACE techniques FcE75 cDNA was 3611 bp in length with an ORF of 2394 bp. The deduced amino acid sequence of FcE75 had the highest sequence identity to E75 from a land crab Gecarcinus lateral's and E75 of the shrimp Metapenaeus crisis Quantitative real-time PCR revealed a prominently high expression of FcE75 mRNA in the whole body RNA extract of late premolt period (D3) juvenile shrimp. The role of E75 in the process of shrimp molting was investigated using the RNA interference technique Long double-stranded RNA corresponding to the FcE75 (dsE75) efficiently silenced the FcE75 transcript levels in juvenile F. chinensis. Further, injection with dsE75 completely arrested the molting process in experimental shrimp which eventually caused death Setogenic analysis of the uropods from molt-arrested shrimp, showed defective epidermal retraction, poor development of setae and new cuticle. These results indicate that E75 might be related to the molting process and is essential for proper molting and survival of shrimp This is the first report demonstrating the use of double stranded RNA to elucidate the possible role of E75 in the molting of decapod crustaceans (C) 2010 Elsevier Inc All rights reserved

中华绒螯蟹（Eriocheir sinensis）cDNA文库的构建、EST分析及其酚氧化酶系统关键基因的研究

中华绒螯蟹（Eriocheir sinensis）是我国的特色物种，具有重要的经济和科研价值。酚氧化酶系统作为节肢动物特有的免疫机制，在中华绒螯蟹的免疫反应中发挥重要作用。本研究构建了一个中华绒螯蟹的cDNA文库，利用表达序列标签 (Expressed Sequence Tag，EST) 技术，对中华绒螯蟹表达序列进行了大规模测序分析，并利用cDNA末端快速扩增（rapid amplification of cDNA ends，RACE）、实时定量PCR、原核重组和RNAi等技术研究了其酚氧化酶免疫系统的分子基础及其相应功能。 用鳗弧菌和金黄色葡萄球菌同时感染中华绒螯蟹，提取血细胞的RNA构建了一个库容为3.3×106 克隆cDNA文库。随机测序后获得7535条高质量的EST序列，其中在GenBank数据库中未发现同源序列的为4593 条，而具有较高同源性2942条可以分为20个功能类别，参与了23个生物学反应。 进一步分析发现，969 条（32.9% ）EST与免疫相关，可拼接成221个免疫基因。这个比例高于其它任何一个已公布的甲壳动物cDNA文库。在免疫相关EST中，抗菌肽比例最高，约占总数的20.1%（195条EST）。免疫基因的高比例和抗菌肽的高表达，证明细菌刺激是提高cDNA 文库中免疫基因丰度的有效方法。 EST序列的获得和免疫基因的富集，丰富了中华绒螯蟹的基因组信息，初步了解了中华绒螯蟹固有免疫系统的概况, 为进一步克隆和研究中华绒螯蟹免疫防御功能基因提供了序列基础。 本研究在EST分析的基础上，克隆获得了中华绒螯蟹酚氧化酶系统10个基因的cDNA全长序列, 它们分别是前酚氧化酶（EsproPO），丝氨酸蛋白酶同源物（EsSPH), 丝氨酸蛋白酶抑制剂pacifastin, serpin, PAPII (EsPLC, Es serpin, EsPAPII), 模式识别丝氨酸蛋白酶（EsPRSP），peroxinectin (Esperoxinectin)和3个前酚氧化酶激活酶 (EsPAP1, 2, 3)。它们与相近物种的酚氧化酶系统相应基因均具有较高同源性，并含有胰酶催化结构域，CLIP结构域，PLD结构域，KAZAL结构域，Serpin结构域以及酚氧化酶结构域等酚氧化酶系统相应基因典型的特征结构域。分析发现，PAPs的CLIP结构域和PRSP，Pacifastin，Proxinectin，proPO基因是节肢动物特有的，是酚氧化酶系统作为节肢动物特有免疫机制的分子基础。本研究从多个基因的3′UTR区发现了调控元件，如15-LOX-DICE，K-box和 Brd-Box。在所推断的蛋白中，EsPAP3和EsPAPII的等电点呈碱性，Esperoxinetin的为中性，而EsPRSP，EsSPH，EsproPO, EsPAPII, Esserpin，EsPAP1的等电点在酸性区间。健康中华绒螯蟹 EsPAP1，EsPAP2，EsPAPII基因在肌肉中的表达量最高，而在血细胞中的表达量相对较低；EsPAP3，EsproPO，EsPLC基因在血细胞中表达量较高，在肌肉中的表达量最低。其中，EsPAP3在血细胞中的表达量是其在肌肉组织中表达量的526.35倍。调控元件和多种激活酶与抑制剂的存在、组织分布和等电点的差异，说明中华绒螯蟹酚氧化酶系统在转录、翻译、激活等多个层次上受到了调控。在中华绒螯蟹受到鳗弧菌刺激后，EsPAP1，EsPAP2，EsPAP3，EsPLC和EsPAPII基因的表达量呈上升或下降的趋势，但表达量的极限值均出现在2小时和12小时，这一规律与EsproPO应激后的mRNA表达和酶比活力的变化特点相吻合，说明中华绒螯蟹酚氧化酶系统各因子相互协调共同参与中华绒螯蟹对入侵细菌的防御反应。同时EsPAP2，EsPAP3，EsproPO，EsPAPII，EsPLC在中华绒螯蟹受到鳗弧菌刺激后的表达呈现反复多次上升，表明酚氧化酶系统可能参与了多种免疫反应。研究还发现EsPAP1参与中华绒螯蟹血液凝集过程，而EsPAP3是蟹血细胞中的有效的前酚氧化酶激活因子。研究结果初步揭示了中华绒螯蟹酚氧化酶系统的分子基础、对微生物的响应机制及其调控机制和演化趋势，为节肢动物固有免疫系统研究奠定了良好基础。

Sensitive and Rapid Detection of Genetic Modified Soybean (Roundup Ready) by Loop-Mediated Isothermal Amplification

Using the LAMP method, a highly specific and sensitive detection system for genetically modified soybean (Roundup Ready) was designed. In this detection system, a set of four primers was designed by targeting the exogenous 35S epsps gene. Target DNA was amplified and visualized on agarose gel within 45 min under isothermal conditions at 65 degrees C. Without gel electrophoresis, the LAMP amplicon was visualized directly in the reaction tube by the addition of SYBR Green I for naked-eye inspection. The detection sensitivity of LAMP was 10-fold higher than the nested PCR established in our laboratory. Moreover, the LAMP method was much quicker, taking only 70 min, as compared with 300 min for nested PCR to complete the analysis of the GM soybean. Compared with traditional PCR approaches, the LAMP procedure is faster and more sensitive, and there is no need for a special PCR machine or electrophoresis equipment. Hence, this method can be a very useful tool for GMO detection and is particularly convenient for fast screening.

cDNA cloning and overexpression of acidic ribosomal phosphoprotein P1 gene (RPLP1) from the Giant Panda

RPLP1 is one of acidic ribosomal phosphoproteins encoded by RPLP1 gene, which plays an important role in the elongation step of protein synthesis. The cDNA of RPLP1 was cloned successfully for the first time from the Giant Panda (Ailuropoda melanoleuca) using RT-PCR technology, which was also sequenced, analyzed preliminarily and expressed in E. coli. The cDNA fragment cloned is 449bp in size, containing an open reading frame of 344bp encoding 114 amino acids. Alignment analysis indicated that the nucleotide sequence and the deduced amino acid sequence are highly conserved to other five species studied, including Homo sapiens, Mus musculus, Rattus norvegicus, Bos Taurus and Sus scrofa. The homologies for nucleotide sequences of Giant Panda PPLP1 to that of these species are 92.4%, 89.8%, 89.0%, 91.3% and 87.5%, while the homologies for amino acid sequences are 96.5%, 94.7%, 95.6%, 96.5% and 88.6%. Topology prediction showed there are three Casein kinase II phosphorylation sites and two N-myristoylation sites in the RPLP1 protein of the Giant Panda (Ailuropoda melanoleuca). The RPLP1 gene was overexpressed in E. coli and the result indicated that RPLP1 fusion with the N-terminally His-tagged form gave rise to the accumulation of an expected 18kDa polypeptide, which was in accordance with the predicted protein and could also be used to purify the protein and study its function.

Molecular systematics and biogeography of Crawfurdia, Metagentiana and Tripterospermum (Gentianaceae) based on nuclear ribosomal and plastid DNA sequences

Background and Aims The systematic position of the genus Metagentiana and its phylogenetic relationships with Crawfurdia, Gentiana and Tripterospermum have not been explicitly addressed. These four genera belong to one of two subtribes (Gentianinae) of Gentianeae. The aim of this paper is to examine the systematic position of Crawfurdia, Metagentiana and Tripterospermum and to clarify their phylogenetic affinities more clearly using ITS and trnL intron sequences.Methods Nucleotide sequences from the internal transcribed spacers (ITS) of nuclear ribosomal DNA and the plastid DNA trnL (UAA) intron were analysed phylogenetically. Ten of fourteen Metagentiana species were sampled, together with 40 species of other genera in the subtribe Gentianinae.Key Results The data support several previously published conclusions relating to the separation of Metagentiana from Gentiana and its closer relationships to Crawfurdia and Tripterospermum based on studies of gross morphology, floral anatomy, chromosomes, palynology, embryology and previous molecular data. The molecular clock hypothesis for the tested sequences in subtribe Gentianinae was not supported by the data (P < 0.05), so the clock-independent non-parametric rate smoothing method was used to estimate divergence time. This indicates that the separation of Crawfurdia, Metagentiana and Tripterospermum from Gentiana occurred about 11.4-21.4 Mya (million years ago), and the current species of these three genera diverged at times ranging from 0.4 to 6.2 Mya.Conclusions The molecular analyses revealed that Crawfurdia, Metagentiana and Tripterospermum do not merit status as three separate genera, because sampled species of Crawfurdia and Tripterospermum are embedded within Metagentiana. The speciation and rapid radiation of these three genera is likely to have occurred in western China as a result of upthrust of the Himalayas during the late Miocene and the Pleistocene.