烟草FIE和MSI1基因的克隆及序列分析

采用电子克隆与实验克隆结合的方法获得了烟草胚乳发育相关基因NTFIE和NTMSI1的cDNA序列,序列号分别为EU375458和EU375459.序列分析结果表明,这两个cDNA序列均含有完整的开放读码框,分别编码370和424个氨基酸,含有保守的WD基序.氨基酸序列比对和系统发育分析结果显示,不同物种之间FIE和MSI1基因编码氨基酸序列同源性都较高.组织表达分析结果表明,这两个基因均具有一定程度的组织表达特异性,NTFIE cDNA基因在花中的表达量最多,但在根和茎中未检测到表达,而NTMSI1 cDNA基因只在离体培养的细胞和根中特异性表达.     

小麦盐胁迫相关基因TabHLH13的克隆与分析

在对小麦全长cDNA克隆进行大规模测序及转录因子功能研究过程中,筛选到一个与盐胁迫相关的bHLH转录因子基因,将其命名为TabHLH13。TabHLH13的全长cDNA序列为1072 bp,开放阅读框为720 bp,编码一个具有240个氨基酸残基的bHLH转录因子;对TabHLH13的基因组和cDNA序列比较分析表明该基因包括5个外显子和4个内含子;同源序列分析发现,TabHLH13与来自大麦和短柄草中的bHLH蛋白序列相似性最高,分别为96.2%和90.5%;电子定位发现TabHLH13位于小麦第7同源群的7DL上;亚细胞定位结果表明,TabHLH13编码一个定位在细胞核中的蛋白;组织表达特性分析表明该基因在小麦根、茎、叶、颖壳、雌蕊和花药中均有较强的表达;半定量RT-PCR与qRT-PCR结果表明TabHLH13是一个受盐胁迫诱导表达的基因。     

与胡萝卜胚胎发生相关的胚性细胞蛋白63cDNA分离及其基因表达研究

以胡萝卜(Daucus carota L.)鱼雷形胚状体为材料,以λgt10噬菌体为载体,构建了一个含有6.0×10~8个重组子的cDNA文库。用PCR法扩增的长度为1.1kb的胚性细胞蛋白(ECP)63 DNA片段作探针,从cDNA文库中筛选出一个完整的ECP63 cDNA克隆。ECP63 cDNA核苷酸序列总长为1989bp,编码1个含569个氨基酸残基的蛋白质,分子量为62kD。以ECP63 cDNA全长作探针的Northern分子杂交结果表明,ECP63基因在胚性细胞和不同发育时期的胚状体中高度表达,但在幼苗和非胚性细胞中不表达。在转录水平上,ECP63基因在合子胚胎发生后期大量表达。     

内蒙古白绒山羊翻译控制肿瘤蛋白(TCTP)基因克隆及组织表达特性分析

旨在克隆内蒙古白绒山羊翻译控制肿瘤蛋白(Translationally controlled tumor protein,TCTP)基因并分析其表达模式。采用RT-PCR技术扩增TCTP基因编码区cDNA序列,将得到的基因cDNA序列及其编码的氨基酸序列进行生物信息学分析,利用定量RT-PCR方法检测TCTP基因在绒山羊不同组织中的表达特异性。获得的内蒙古白绒山羊TCTP基因编码区cDNA序列全长519 bp,包含了完整的ORF,编码172个氨基酸残基组成的蛋白质。核苷酸序列与绵羊、牛、猪、人、猴及大鼠的同源性在99%-95%之间。生物信息学分析表明,编码的蛋白质理论分子质量19.6 kD,等电点(pI)4.673,含有一个N端糖基化位点,一个蛋白激酶C磷酸化位点,3个酪蛋白激酶Ⅱ磷酸化位点,定位于细胞质中。定量RT-PCR方法检测表明,TCTP基因在绒山羊肾脏、肌肉、胰腺、肝脏、睾丸和脑组织中均有表达,其中在肝脏中的表达量较高,在脑中表达量较低。     

绞股蓝法呢基焦磷酸合酶基因的克隆及其序列分析

目的:克隆并分析绞股蓝法呢基焦磷酸合酶(FPS)基因的全长序列。方法:参照罗汉果法呢基焦磷酸合酶基因,设计扩增绞股蓝FPS基因的3′RACE引物,采用3'RACE和5'RACE法克隆绞股蓝FPS基因全长cDNA。结果:获得绞股蓝FPS基因全长cDNA序列共1288个核苷酸,包含一个1026核苷酸的开放读框,编码342个氨基酸残基,推断该蛋白的相对分子质量为3.94×104。NCBI Blast结果显示绞股蓝FPS基因编码蛋白的氨基酸序列与已知的植物FPS氨基酸序列的同源性为91%~74%,核酸序列的同源性为88%~78%。结论:克隆了绞股蓝FPS基因全长cDNA序列,为进一步研究绞股蓝FPS基因的表达及三萜皂苷合成通路关键酶分子的进化奠定了基础。     

内蒙古白绒山羊IGF-IR基因cDNA克隆及组织表达特异性分析

旨在克隆内蒙古白绒山羊IGF-IR基因并分析其基本表达模式.采用RT-PCR克隆基因,将得到的IGF-IR基因cDNA片段的核苷酸序列及其编码的氨基酸序列进行生物信息学分析.半定量RT-PCR进行组织特异性表达检测.获得了内蒙古白绒山羊IGF-IR基因3’端编码区2118 bp的cDNA序列(JN200823),编码705个氨基酸残基.核苷酸序列与牛的IGF-IR( XM606794.3)基因同源性为98％,相应的氨基酸序列同源性为99％.SMART分析表明,推导出的编码蛋白具有跨膜域,酪氨酸激酶催化域.半定量RT-PCR检测表明,IGF-IR基因在绒山羊脑、胰腺、肝、肾组织中均有表达.     

黄秋葵查尔酮合成酶基因AeCHS的克隆与表达分析

采用同源序列克隆和RT-PCR技术,首次克隆得到黄秋葵查尔酮合成酶基因(CHS)cDNA全长序列。序列分析表明,该序列全长1175 bp,包括一个1170 bp的完整ORF,编码389个氨基酸,命名为AeCHS。生物信息学分析表明,本研究所获得的AeCHS氨基酸序列与同科植物黄蜀葵和陆地棉的同源性较高,分别达99.23%和97.44%,AeCHS推断的氨基酸序列含有CHS蛋白的标签序列GFGPG以及4个保守活性位点Cys164、Phe215、His303、Asn336。实时荧光定量PCR分析黄秋葵果实、花、叶片不同发育时期AeCHS基因的表达量,结果表明AeCHS基因在上述植物材料中表现出不同的表达模式:花>果实>叶片,具体到不同植物组织,AeCHS基因在生长6 d的果实、盛开的花朵以及植株顶端第4片叶子中的表达量较高。     

内蒙古白绒山羊TSC2基因克隆与表达模式分析

旨在克隆内蒙古白绒山羊TSC2基因cDNA并分析其特性及基本表达模式.利用RT-PCR分段克隆TSC2基因cDNA片段并测序,将得到的cDNA各片段核苷酸序列拼接后获得绒山羊TSC2基因编码区全长序列(HQ684023)并进行生物信息学分析.半定量RT-PCR方法检测TSC2基因在不同组织中的表达特异性.结果表明内蒙古白绒山羊TSC2基因cDNA编码区核苷酸序列为5184 bp,包含了编码1727个氨基酸残基的全长ORF.核苷酸序列与牛、猪、马、大熊猫、犬、恒河猴、人、小鼠及大鼠的同源性分别为97％、90％、89％、88％、87％、87％、87％、86％和86％.NCBI CDD程序预测该基因编码的蛋白质有一个Tuberin结构域和一个Rap-GAP结构域;Psite程序分析有5个N糖基化位点、2个cAMP和cGMP依赖蛋白激酶磷酸化位点、16个蛋白激酶C磷酸化位点、25个酪蛋白激酶磷酸化位点.PSORT程序预测其定位于胞内体膜.TSC2基因在内蒙古白绒山羊的睾丸、脑、肝脏、肺、乳腺、脾和肾脏等组织中都有表达,mRNA丰度在睾丸中较高,乳腺中较低.     

内蒙古白绒山羊VEGF164基因cDNA克隆及组织表达特异性分析

旨在克隆内蒙古白绒山羊血管内皮生长因子(vascular endothelial growth factor,VEGF164)基因并分析其基本表达模式。采用RT-PCR技术克隆基因,将得到的基因cDNA序列及其编码的氨基酸序列进行生物信息学分析。利用半定量RT-PCR方法进行组织表达检测。获得了内蒙古白绒山羊VEGF164基因编码区cDNA全长序列,扩增片段全长573 bp,包含了完整的ORF,编码190个氨基酸残基。核苷酸序列与绵羊的VEGF164(EU857623.1)基因同源性为99%,相应的氨基酸序列同源性为99%。SMART程序分析表明,ORF编码的蛋白质具有信号肽序列及血小板衍生和血管内皮生长因子家族(PDGF,VEGF)结构域。Psite程序分析表明,有1个蛋白激酶C磷酸化位点,4个酪蛋白激酶磷酸化位点。ProtComp Version 9.0程序分析将其定位于细胞外。RT-PCR检测表明,VEGF164基因在绒山羊脑、心脏、睾丸、胰腺、脾、肾和肺组织中均有表达。     

悬钩子属植物肌动蛋白基因片段的克隆与表达

目的:克隆悬钩子属植物肌动蛋白基因(actin),为研究该物种中其他基因的表达和调控提供内标基因.方法:利用一对特异性引物从黑莓、悬钩子杂种和树莓品种中克隆actin cDNA片段,对其进行序列分析和半定量RT-PCR表达分析.结果:从3个品种中均获得一条783 bp actin cDNA片段,编码260个氨基酸,3条actin片段与其他植物核苷酸序列的同源性都在82%以上,与其他植物氨基酸序列同源性也均在95%以上;树莓和悬钩子杂种品种的actin核苷酸和氨基酸序列同源性均达99%,系统进化分析也发现两者亲缘关系较近些;表达分析发现actin基因在各品种不同组织中均有一定的表达量.结论:首次克隆了悬钩子属植物肌动蛋白基因actin,将来自黑莓和树莓品种的序列登录在GenBank,登录号分别为HQ439556和HQ439557.     

New epidermal keratin genes from Xenopus laevis: hormonal and regional regulation of their expression during anuran skin metamorphosis

Xenopus larval keratin (XLK) was isolated by gel electrophoresis of proteins of tadpole skin. Screening of an expression cDNA library of tail tissues by specific polyclonal antibodies against XLK produced XLK cDNA (xlk). Its complete nucleotide and predicted amino acid sequences revealed that XLK was a new member of type II keratin. Screening of a cDNA library of adult Xenopus skin using an oligonucleotide probe which had been designed from well-conserved N-terminal amino acid sequences of the rod domain of type I keratin produced two cDNAs, xak-a and xak-b, which were found to be new members of type I keratin gene. Northern blot analysis showed that xlk was expressed exclusively in the larval skin whereas xak-a and xak-b were expressed exclusively in the adult skin. Their expression level was regulated in a region- and metamorphic stage- dependent manner during larval skin development. mRNA in situ hybridization experiments identified the cells that expressed xlk, and xak-a and xak-b as larva- specific epidermal cells (skein cells and basal cells), and adult suprabasal epidermal cells, respectively. These three genes were found to be late responsive to thyroid hormone. Phylogenetic relationships of these keratins with known ones are discussed.     

Cloning and sequence analysis reveal structural variation among related zein genes in maize

We have isolated a gene encoding one of the 19,000 dalton zein proteins from a maize genomic library constructed in Charon 4A. This gene occurs on a 7.7 kb Eco RI fragment, and based on Southern hybridization analysis, represents one of several homologous sequences present in the maize genome. The nucleotide sequence of the gene predicts a protein composed of 235 amino acids, including a signal peptide of 21 amino acids. There are no intervening sequences in the gene. By comparing the nucleotide sequence of this gene with that of a homologous cDNA clone, we have identified a basis for microheterogeneity within the gene family. The 5′ nucleotide sequences of the genomic and cDNA clones are identical, but they differ in the center of the protein, where repeated amino acid sequences occur. A nucleotide sequence encoding a conserved peptide of 20 amino acids is repeated nine times in the center of both of these clones.     

Identification of a novel gene SRG4 expressed at specific stages of mouse spermatogenesis

Spermatogenesis is a complex process. Duringspermatogenesis, the production of sperm occurs withinthe testicular seminiferous tubules through three separatedphases. First of all, diploid germ cells, primitivespermatogonia, will self renew to amplify and producetypes A and B spermatogonia. Type B spermatogonia willdifferentiate into primary spermatocytes. Then, meioticdivisions of spermatocytes will produce round spermatids.Finally, after a series of biochemical and morphologicalchanges, sper…     

Cloning of cDNA Sequences Encoding the Calcium-Binding Protein, Calmodulin, from Barley (Hordeum vulgare L.)

Full- and partial-length cDNAs encoding calmodulin mRNA have been cloned and sequenced from barley (Hordeum vulgare L.). Barley leaf mRNA, size-fractionated in sucrose density gradients, was used to synthesize double-stranded cDNA. The cDNA was cloned in λgt10 and screened with a synthetic, 14-nucleotide oligonucleotide probe, which was designed using the predicted coding sequences of the carboxy termini of spinach and wheat calmodulin proteins. The primary structure of barley calmodulin, predicted from DNA sequencing experiments, consists of 148 amino acids and differs from that of wheat calmodulin in only three positions. In two of the three positions, the amino acid changes are conservative, while the third change consists of an apparent deletion/insertion. The overall nucleotide sequence similarity between the amino acid coding regions of barley and vertebrate calmodulin mRNAs is approximately 77%. However, a region encoding 11 amino acids of the second Ca²⁺-binding domain is very highly conserved at the nucleotide level compared with the rest of the coding sequences (94% sequence identity between barley and chicken calmodulin mRNAs). Genomic Southern blots reveal that barley calmodulin is encoded by a single copy gene. This gene is expressed as a single size class of mRNA in all tissues of 7-day-old barley seedlings. In addition, these analyses indicate that a barley calmodulin cDNA coding region subclone is suitable as a probe for isolating calmodulin genes from other plants.