长白蝮蛇类凝血酶基因的克隆及分析

从长白蝮蛇（Agkistrodon halys Ussurin)毒腺中抽提总RNA,采用RT－PCR扩增其类凝血酶基因,经全序列测定,获得2个类凝血酶基因,ussurin和ussurase,它们全长分别为708和699个核苷酸,即分别编码236和233个氨基酸;根据同源性,推测它们的活性中心分别为His^43,Asp^88和Ser^182与His^40,Asp^85和Ser^179;二硫键分别为Cys^7-Cys^141,Cys^28-Cys^44,Cys^76-Cys^234,Cys^120-Cys^188,Cys^152-Cys^167和Cys^178-Cys^203;与Cys^7-Cys^138,Cys^25-Cys^41,Cys^73-Cys^231,Cys^117-Cys^185,Cys^149-Cys^164和Cys^175-Cys^200。该蛇毒类凝血酶cDNA序列及推导的氨基酸序列为首次报道。     

TPO的分子生物学研究进展

本文综述了人TPO的基因结构及表达、TPO的结构与功能的关系、TPO与其受体相互作用及信号传导等方面的研究进展。TPO基因和蛋白均存在有多态性,可能与基因的剪接方式有关。N端结构域的氨基酸有很高的保守性,含有两个与TPO受体结合的位点,这两个位点同时作用于两个TPO受体,使受体形成二聚体,受体胞内区的酪氨酸或丝氨酸的磷酸化,激活胞膜内G蛋白信号系统,从而激活其后的一系列信号传导。两对二硫键Cys^7-Cys^151和Cys^29-Cys^85对保证N端功能域的形成起重要作用。TPO的C端结构域氨基酸变异较大,富含丝氨酸、苏氨酸和脯氨酸,C端的功能为：调节TPO特异活性;调控TPO的循环半衰期;促进TPO生物合成和分泌。     

小菊锌指蛋白基因cDNA全长克隆及表达分析

目的：克隆菊花耐盐碱相关锌指蛋白基因,并进行盐胁迫和品种间差异的表达分析。方法：从大量菊花资源中筛选出抗盐碱品系小菊‘阳光’,利用RT—PCR从经150mmol／L碳酸钠处理的小菊‘阳光’叶片中分离得到一个锌指蛋白cDNA全长克隆,用Northern杂交检测其在不同盐处理和不同品种小菊中的表达。结果：获得了全长794bp的基因CmSTZF（GenBank接受号为DQ864730）,编码区为170个氨基酸残基。Blast分析表明,CmSTZF含有AN1型锌指结构,序列模式为C-X2-C—X（9—12）-C-X（1-2）-C-X4-C-X2-H-X5-H-X-C,由Cys^110-Cys^113-Cys^131-His^134及Cys^124-Cys^126-Cys^142-His^140分别围绕锌离子与其他氨基酸共同组成2个锌指四面体结构;在第67～76及第94～104氨基酸残基序列间存在核定位信号。同源性比较发现,CmSTZF与水稻OsISAPI具有54％的同源性,而二者的锌指保守区相似性达100％。Cluster分析表明,小菊CmSTZF锌指蛋白与水稻的2种逆境反应蛋白亲缘关系最近,归属同一类逆境功能蛋白。在150mmol／L碳酸钠胁迫下,耐盐小菊‘阳光’锌指蛋白表达量明显高于非耐盐小菊‘神韵’,表明CmSTZF锌指蛋白基因在盐碱胁迫下起重要的调控作用。结论：克隆了小菊耐盐碱相关的锌指蛋白基因CmSTZF,其在耐盐小菊‘阳光’中的表达量高于非耐盐小菊‘神韵’,这为小菊锌指蛋白基因CmSTZF耐盐碱功能分析奠定了基础。     

蝮蛇类凝血酶基因的分析及表达研究

从蝮蛇（ＡｇｋｉｓｔｒｏｄｏｎｈａｌｙｓＰａｌａｓ）毒腺中抽提总ＲＮＡ,经ＲＴＰＣＲ扩增该基因,克隆后经全序列测定,蝮蛇类凝血酶ｐａｌａｓｅ的ｃＤＮＡ长７０８个核苷酸,即编码２３６个氨基酸;根据同源性,推测该类凝血酶ｐａｌａｓｅ的活性中心为Ｈｉｓ４１、Ａｓｐ８６和Ｓｅｒ１８２;二硫键为Ｃｙｓ７Ｃｙｓ１３９、Ｃｙｓ２６Ｃｙｓ４２、Ｃｙｓ７４Ｃｙｓ２３４、Ｃｙｓ１１８Ｃｙｓ１８８、Ｃｙｓ１５０Ｃｙｓ１６７和Ｃｙｓ１７８Ｃｙｓ２０３;该蝮蛇毒类凝血酶ｃＤＮＡ序列及推导的氨基酸序列均为首次报道。构建Ｔ７启动子控制下的ｐａｌａｓｅ的大肠杆菌表达质粒,ＩＰＴＧ诱导ｐａｌａｓｅ获得表达。     

五步蛇蛇毒类凝血酶N端的部分氨基酸序列

从五步蛇蛇毒中纯化得到的类凝血酶,在SDS-PAGE及IEF均为一条带,且分子质量约38 ku,等电点约为4.0。测定该酶N端15个氨基酸的序列是VIGGVECDINEHRFL,与其他的蛇毒类凝血酶有高度同源性。     

尼罗鳄MHCⅡ类B基因第二外元的序列变异分析

利用一对简并引物扩增了尼罗鳄MHCⅡ类分子B基因第二外元的部分片段,并对PCR产物进行了克隆和测序,结果得到8种不同的序列,序列长度为166 bp;经分析,序列中有56个变异位点,核苷酸的非同义替换多于同义替换,造成30个位点氨基酸的改变,氨基酸的替换趋于集中在假定的抗原结合位点附近.核苷酸和氨基酸序列与已报道的扬子鳄和密河鳄的MHCⅡ类B基因第二外元序列有较高的同源性,利用PAUP4.0软件构建的NJ树显示,鳄类的MHCⅡ类B基因存在跨种多态性现象.     

长白山白眉蝮蛇乌苏里亚种类凝血酶（TLE）基因克隆及分析

目的为了获得长白山白眉蝮蛇乌苏里亚种类凝血酶基因。方法根据GeneBank自眉类凝血酶eDNA5．和3保守序列设计了引物,通过RT-PCR从白眉蝮蛇乌苏里亚种毒腺TotalRNA中扩增得到1条长714bp的特异cDNA片段,将该cDNA片段重组到SimpleTvector,转化进E．coliJM109competentcell,阳性克隆委托生物公司测序,利用生物信息学方法对测序结果进行分析。结果该特异性片段与蛇毒类凝血酶同源性为95％,它为一个开发阅读框架,其编码的蛋白质序列与其他蛇毒类凝血酶序列同源性为94％,与其他蛇毒类凝血亲缘关系非常近。结论本实验获得了一种新型白眉蝮蛇乌苏里亚种类凝血酶基因。     

早熟油菜成花相关基因LFY的克隆与分析

以甘蓝型油菜晚熟品种RG-8的早熟突变体RG-8M为材料,通过同源克隆法得到1个LEAFY(LFY)同源基因,命名为BnLFY。该基因cDNA全长为1 310bp,包含1个长为1 248bp的开放阅读框,编码415个氨基酸。序列分析表明,推测的氨基酸序列含双子叶植物LFY类蛋白特有的N端脯氨酸富集区、中央酸性区、亮氨酸拉链结构以及富含赖氨酸与精氨酸的碱性区;且与几种十字花科植物LFY类蛋白的氨基酸序列一致性均在84%以上。转录表达分析表明,BnLFY基因在油菜中为组成型表达。     

尖吻蝮毒液类凝血酶的克隆及序列分析

以类凝血酶的RT—PCR产物为模板,PCR扩增出其cDNA片断克隆尖吻蝮的毒液类凝血酶cDNA,分析其密码子运用的特点。用软件进行多序列比对并分析。克隆出多个尖吻蝮毒液类凝血酶的cDNA,得到其基因密码子运用的有关数据。结果表明尖吻蝮毒液类凝血酶同时存在着保守性与多样性,有着较明显的密码子偏好性,在进化中承受了碱基组成和自然选择的压力。     

cDNA cloning and expression of acutin

Acutin, a thrombin-like enzyme was purified from Agkistrodon acutus venom in three steps by DEAE-Sepharose CL-6B, Superose 12 column on FPLC and Mono-Q column chromatographies. Its first 15 N-terminal amino acid residues sequence was then determined and the acutin cDNA was isolated from venom gland total RNA using RT-PCR. Determination of its nucleotide sequence allowed elucidation of the amino acid sequence of mature peptide for the first time. The mature acutin has 233 amino acids and its amino acid sequence exhibits significant homology with those of thrombin-like enzymes from crotaline snakes venoms. Based on the homology, the catalytic residues and disulfide bridges of acutin were deduced to be as follows: catalytic residues, His41, Asp84 and Ser179; and disulfide bridges, Cys7-Cys139, Cys26-Cys42, Cys74-Cys231, Cys118-Cys185, Cys150-Cys164, Cys175-Cys200. The recombinant acutin has been expressed in E. coli and purified by affinity column. The renatured recombinant acutin is reported for the first time to have the activity of clotting fibrinogen and arginine-esterase.     

Molecular cloning and sequence analysis of cDNA for batroxobin, a thrombin-like snake venom enzyme

Determination of the nucleotide sequence of a cDNA for batroxobin, a thrombin-like enzyme from Bothrops atrox, moojeni venom, allowed elucidation of the complete amino acid sequence of batroxobin for the first time for a thrombin-like snake venom enzyme. The molecular weight of batroxobin is 25,503 (231 amino acids). The amino acid sequence of batroxobin exhibits significant homology with those of mammalian serine proteases (trypsin, pancreatic kallikrein, and thrombin), indicating that batroxobin is a member of the serine protease family. Based on this homology and enzymatic and chemical studies, the catalytic residues and disulfide bridges of batroxobin were deduced to be as follows: catalytic residues, His41, Asp86, and Ser178; and disulfide bridges, Cys7-Cys139, Cys26-Cys42, Cys74-Cys230, Cys118-Cys184, Cys150-Cys163, and Cys174-Cys199. The amino-terminal amino acid residue of batroxobin, valine, is preceded by 24 amino acids. This may indicate that the amino-terminal hydrophobic peptide (18 amino acids) is a prepeptide and that the hydrophilic peptide (6 amino acids), preceded by the putative prepeptide, is a propeptide.     

Importance of cysteine residues for the stability and catalytic activity of human pancreatic beta cell glucokinase

The low-affinity glucose phosphorylating enzyme glucokinase has the function of a physiological glucose sensor in pancreatic beta cells and in liver. In contrast to the high-affinity hexokinase types I-III glucokinase shows extraordinary sensitivity toward SH group oxidizing compounds. To characterize the function of sulfhydryl groups cysteine residues in the vicinity of the sugar binding site (Cys 213, Cys 220, Cys 230, Cys 233, and Cys 252) as well as cysteine residues a distance from the active site (Cys 364, Cys 371, and Cys 382), they were replaced in human beta cell glucokinase by serine through site-directed mutagenesis. Controlled proteolysis of wild-type glucokinase by proteinase K revealed that the SH group oxidizing agent alloxan can induce the formation of multiple intramolecular disulfide bridges corresponding to a double-band pattern of glucokinase protein in nonreducing sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The formation of intramolecular disulfide bridges altered the mobility of the protein. None of the cysteine mutations could prevent the formation of the 49-kDa glucokinase conformation after alloxan treatment. The cysteine mutants Cys 233, Cys 252, and Cys 382 showed nearly complete loss of catalytic activity, whereas the V(max) values of the Cys 213, Cys 220, Cys 364, and Cys 371 mutants were decreased by 30-60%. Only the Cys 230 mutant showed kinetic characteristics comparable to those of wild-type glucokinase. The sensitivity of the Cys 213, Cys 230, Cys 364, and Cys 371 mutants toward alloxan-induced inhibition of enzyme activity was up to 10-fold lower compared with wild-type glucokinase. d-Glucose and dithiotreitol provided protection against alloxan-induced inhibition of wild-type glucokinase and all catalytically active cysteine mutants. Conclusively our data demonstrate the functional significance of the cysteine residues of beta cell glucokinase for both structural instability of the enzyme and catalytic function. Knowledge of sensitive cysteine targets may help to develop strategies that improve glucokinase enzyme function under conditions of oxidative stress.     

Essential cysteine residues for human RNase κ catalytic activity

Human RNase κ is an endoribonuclease expressed in almost all tissues and organs and belongs to a highly conserved protein family bearing representatives in all metazoans. To gain insight into the role of cysteine residues in the enzyme activity or structure, a recombinant active form of human RNase κ expressed in Pichia pastoris was treated with alkylating agents and dithiothreitol (DTT). Our results showed that the human enzyme is inactivated by DDT, while it remains fully active in the presence of alkylating agents. The unreduced recombinant protein migrates on SDS/PAGE faster than the reduced form. This observation in combination with the above findings indicated that human RNase κ does not form homodimers through disulfide bridges, and cysteine residues are not implicated in RNA catalysis but participate in the formation of intramolecular disulfide bond(s) essential for its ribonucleolytic activity. The role of the cysteine residues was further investigated by expression and study of Cys variants. Ribonucleolytic activity experiments and SDS/PAGE analysis of the wild-type and mutant proteins under reducing and non-reducing conditions demonstrated that Cys7, Cys14 and Cys85 are not essential for RNase activity. On the other hand, replacement of Cys6 or Cys69 with serine led to a complete loss of catalytic activity, indicating the necessity of these residues for maintaining an active conformation of human RNase κ by forming a disulfide bond. Due to the absolute conservation of these cysteine residues, the Cys6-Cys69 disulfide bond is likely to exist in all RNase κ family members.     

Structure-function relationships in the carboxylic-ester-hydrolase superfamily. Disulfide bridge arrangement in porcine intestinal glycerol-ester hydrolase.

CNBr fragments from porcine intestinal glycerol-ester hydrolase were separated by SDS/PAGE under reducing and nonreducing conditions, and their amino-acid sequences were analysed. Two intra-chain disulfide bridges were identified, namely Cys70-Cys99 (loop A) and Cys256-Cys267 (loop B). As the Cys71 sulfhydryl group could not be alkylated with iodoacetamide, it is suggested that the residue is blocked rather than being present in the free form. The two disulfide bridges of intestinal glycerol-ester hydrolase are present in the cholinesterase family, although the enzyme showed only about 35% identity with these proteins. Furthermore, the finding that glycerol-ester hydrolase was partly inactivated under reducing conditions suggests that one or both disulfide bridges are important for the enzyme conformation. Lastly, glycerol-ester hydrolase was also found to hydrolyse cholinergic substrates, although residues Trp86 and Asp74 which are considered to be the main constituents of the 'anionic' subsite responsible for substrate binding in cholinesterases were absent from loop A. Other amino-acid residues in the glycerol-ester hydrolase may therefore be responsible for the binding of cholinergic substrates to the enzyme.     

Human surfactant polypeptide SP-B. Disulfide bridges, C-terminal end, and peptide analysis of the airway form.

Human hydrophobic surfactant polypeptide, SP-B, purified from lung tissue by exclusion chromatography in organic solvents, has been characterized. The polypeptide is 79 residues long, has a C-terminal methionine, and contains seven Cys residues. Native human SP-B lacks free thiol groups. Three intrachain disulfide bridges were defined, linking Cys8 to Cys77, Cys11 to Cys71 and Cys35 to Cys46. The remaining Cys48 is concluded to link the protein chains into homodimers via an interchain disulfide to its counterpart in a second SP-B polypeptide. These SS bridges are identical to those in the porcine form and confirm a consestant and unique disulfide pattern for SP-B polypeptides in general.     

Purification and primary structure of proteinous alpha-amylase inhibitor from Streptomyces chartreusis.

A new polypeptide inhibitor, AI-409, that inhibits human salivary alpha-amylase, was purified from a fermentation broth of Streptomyces chartreusis strain No. 409. This protein consists of a single-chain polypeptide of 78 amino acid residues, and includes two disulfide bridges. The primary structure of AI-409 and the locations of the disulfide bridges were identified by enzymatic digestion and the automatic Edman technique. Enzymatic digestion was done with trypsin, carboxypeptidase Y, and chymotrypsin. One of the disulfide bridges was between Cys(10) and Cys(26), and the other between Cys(44) and Cys(71).     

Purification and Primary Structure of Proteinous α-Amylase Inhibitor from Streptomyces chartreusis

A new polypeptide inhibitor, AI-409, that inhibits human salivary α-Amylase, was purified from a fermentation broth of Streptomyces chartreusis strain No. 409. This protein consists of a single-chain polypeptide of 78 amino acid residues, and includes two disulfide bridges. The primary structure of AI-409 and the locations of the disulfide bridges were identified by enzymatic digestion and the automatic Edman technique. Enzymatic digestion was done with trypsin, carboxypeptidase Y, and chymotrypsin. One of the disulfide bridges was between Cys(10) and Cys(26), and the other between Cys(44) and Cys(71).     

Cysteine cross-linking defines part of the dimer and B/C domain interface of the Escherichia coli mannitol permease

Part of the dimer and B/C domain interface of the Escherichia coli mannitol permease (EII(mtl)) has been identified by the generation of disulfide bridges in a single-cysteine EII(mtl), with only the activity linked Cys(384) in the B domain, and in a double-cysteine EII(mtl) with cysteines at positions 384 and 124 in the first cytoplasmic loop of the C domain. The disulfide bridges were formed in the enzyme in inside-out membrane vesicles and in the purified enzyme by oxidation with Cu(II)-(1,10-phenanthroline)(3), and they were visualized by SDS-polyacrylamide gel electrophoresis. Discrimination between possible disulfide bridges in the dimeric double-cysteine EII(mtl) was done by partial digestion of the protein and the formation of heterodimers, in which the cysteines were located either on different subunits or on one subunit. The disulfide bridges that were identified are an intersubunit Cys(384)-Cys(384), an intersubunit Cys(124)-Cys(124), an intersubunit Cys(384)-Cys(124), and an intrasubunit Cys(384)-Cys(124). The disulfide bridges between the B and C domain were observed with purified enzyme and confirmed by matrix-assisted laser desorption ionization-time of flight mass spectrometry. Mannitol did not influence the formation of the disulfide between Cys(384) and Cys(124). The close proximity of the two cysteines 124 was further confirmed with a separate C domain by oxidation with Cu(II)-(1,10-phenanthroline)(3) or by reactions with dimaleimides of different length. The data in combination with other work show that the first cytoplasmic loop around residue 124 is located at the dimer interface and involved in the interaction between the B and C domain.