北极狐GHR基因cDNA的克隆及序列分析

本文根据狗(AF133835)的GHR基因cDNA编码全序列设计了三对引物,利用RT-PCR方法克隆出北极狐GHR基因编码区全长cDNA序列(GenBank accession No.EU304325)。结果表明,北极狐GHR的ORF为1917bp,编码638个氨基酸的前体蛋白,由18个氨基酸的信号肽和620个氨基酸的成熟肽组成。通过同源性比较发现北极狐与狗的同源性最高,达到98%。另外,利用邻接法(NJ法)构建的分子系统进化树聚类结果表明,北极狐与狗先聚为一类,该聚类结果与传统的物种进化关系基本一致。另外,通过氨基酸对位序列比较发现,北极狐GHR在氨基酸序列上存在明显的特异性,如45和451位分别为A和E,而其它物种均分别为T(大鼠为K)和A(牛羊为V,鼠为T)。     

扩展青霉PF898碱性脂肪酶cDNA的克隆及序列分析

扩展青霉 (Penicilliumexpansum)PF898可产生一种具有工业价值的碱性脂肪酶 (PEL) .在测定了其N端 12个氨基酸残基序列的基础上 ,通过RT PCR、5′RACE、基因克隆及序列测定 ,获得了PEL完整的cDNA序列 (GenBank登录号为AF2 84 0 6 4 ) .cDNA全长 10 5 0bp ,包括PEL编码区、3′非翻译区和部分 5′非翻译区基因的序列 .编码区cDNA由 85 5个碱基组成 ,编码 1个由 2 85个氨基酸残基组成的酶蛋白 ,其信号肽及前肽部分由 2 7个氨基酸残基组成 ,成熟肽部分由 2 5 8个氨基酸残基组成 .根据氨基酸组成推导该脂肪酶蛋白的分子量为 2 7 3kD .该脂肪酶的氨基酸序列 130～ 134位上有各类脂肪酶中普遍存在的G X S X G保守序列     

绞股蓝鲨烯环氧酶基因的克隆与序列分析

根据已报道植物鲨烯环氧酶(squalene epoxidase,SE)基因cDNA序列的保守区域设计引物,利用RT-PCR和RACE技术,对绞股蓝SE基因进行克隆及序列分析.结果表明,绞股蓝SE基因cDNA全长为1 818 bp,编码一个由525个氨基酸残基组成的多肽.绞股蓝SE基因编码的氨基酸序列中含有52.4%的非极性疏水性氨基酸,26.1%极性中性氨基酸,9.0%酸性氨基酸,12.6%碱性氨基酸.Blast结果显示,绞股蓝SE基因核苷酸序列与其他已报道的植物SE基因相似性为73%～82%,推导的氨基酸序列相似性为63.2%～79.4%.SE氨基酸序列进化分析发现,绞股蓝SE与绿珊瑚、拟南芥亲缘关系较近.     

白鱀豚BDNF基因的扩增和序列分析

利用聚合酶链式反应,首次从白鱀豚基因组DNA 中扩增和克隆到脑源神经营养因子的编码区。在该段序列中含有一个长为747 bp 的开放阅读框,无内含子,编码一个由248 个氨基酸组成的蛋白质,预计分子量为27 953.7道尔顿。其中包括由18 个氨基酸残基组成的信号肽区,111 个氨基酸残基组成的前肽区及119 个氨基酸残基组成的成熟区。序列分析表明,白鱀豚脑源神经营养因子基因编码区的核苷酸序列与其它哺乳动物相似性超过90%,而与猪牛相似性相对较高（分别为95% 和94.7%）。氨基酸序列比较发现,白鱀豚BDNF 前体蛋白的氨基酸序列与其它哺乳动物具有94.5% ～99.5%的相似性,显示了极高的保守性。通过邻接法进行的系统发生分析中,鲸目和食肉目的物种分别聚为单系;与其它哺乳动物相比,鲸类与有蹄类的牛和猪的亲缘关系相对较近,这与鲸类和有蹄类之间具有相对较近的亲缘关系相符。
     

中华蜜蜂蜂毒镇静肽基因的cDNA克隆和表达

从中华蜜蜂 (Apisceranacerana)工蜂毒腺中快速抽提总RNA ,用RT PCR扩增得到大小约为2 5 0bp的cDNA片段 ,测序得到的片段长度为 2 34bp ,为蜂毒前镇静肽原 (preprosecapin)基因编码区的cDNA .以 3′RACE方法 ,扩增和测定了 3′端非编码区 2 19bp序列 .中蜂前镇静肽原cDNA序列与已报道的欧洲意蜂该基因cDNA序列具有 92 %同源性 ,氨基酸序列具有 87%同源性 .代表成熟肽镇静肽的最后 2 5个氨基酸序列 ,中蜂与意蜂同源性为 88% .3′端非编码区cDNA序列与欧洲意蜂序列有 73 1%同源性 .将中华蜜蜂蜂毒镇静肽成熟肽编码区与 3′非编码区部分克隆 ,构建了镇静肽与谷胱甘肽转移酶融合表达的载体pGEX AcSecapin .将载体转化大肠杆菌BL2 1(DE3)进行融合表达 .表达产物与抗GST抗体在 2 9kD处有很强的交叉反应 .大肠杆菌超声破碎后的上清液用SDS PAGE检测到表达的蛋白多为可溶性融合蛋白 ,通过亲和层析柱纯化和凝血酶的切割得到了镇静肽蛋白     

中国对虾蜕皮抑制激素全长cDNA的克隆及序列分析

对虾的蜕皮活动由蜕皮抑制激素和蜕皮激素调控,蜕皮抑制激素是甲壳动物CHH家族神经肽的成员之一,通过抑制Y器官蜕皮激素的合成而调节蜕皮,以中国对虾（Fennropenaeus chinensis）眼柄总RNA为材料,采用cDNA末端快速扩增（RACE）方法。首次得到蜕皮抑制激素的全长cDNA（GenBank登录号：AF469187）。该全长cDNA大小为697bp,是由320bp的3′RACE产物和468bp的5′RACE产物拼接而成,Blast搜索结果显示,该全长cDNA与甲壳动物的MIH基因序列具有较高的相似性,用Clustal X进行多序列比较结果表明,由该全长cDNA推导的氨基酸序列与对虾类的MIH的氨基酸序列同源性最高,其中与日本对虾,斑节对虾,刀额新对虾MIH的同源性分别为95.1%,83.1%,79.1%,根据以上数据,推断该697bp的全长cDNA为编码中国对虾MIH前体的cDNA。进一步序列分析表明,编码中国对虾MIH前体cDNA包括312bp的开放阅读框,81bp的3′UTR和302bp的5′UTR;编码103个氨基酸的MIH前体分子包括信号肽和成熟肽,信号肽由28个氨基酸组成,成熟肽由75个氨基酸组成,成熟肽中6个半胱氨酸非常保守。     

黄鳝cGnRH-Ⅱ的cDNA克隆与序列分析

促性腺激素释放激素（Conadotropin-releasing hormone,GnRH）是一个保守的十肽神经家族激素,在脊椎动物的性腺发育和繁殖功能的维持方面起着重要的调控作用。本文通过运用RACE和RT-PCR方法,从黄鳝脑组织中克隆得到cGnRH-ⅡcDNA全序列,其核苷酸序列长度为617bp。该cDNA编码的cGnRH-Ⅱ的前体氨基酸序列结构组成与其他物种的cGnRH-Ⅱ前体结构一致,其推导的蛋白前体长度为83个氨基酸,包括一个信号肽、cGnRH-Ⅱ十肽和一个由蛋白水解位点（Gly—Lys—Arg）连接的GnRH联接肽,其中信号肽和联接肽的长度分别为21和49个氨基酸。cGnRH-Ⅱ的氨基酸序列和其他相关物种cGnRH-Ⅱ氨基酸序列比较结果显示,cGnRH-Ⅱ cDNA的蛋白编码区高度保守,而非编码区的保守性程度很低。     

大熊猫及其近种活化素基因βA亚基成熟肽序列的克隆分析及其在分类地位上的应用

借鉴互联网中已经克隆到的Activin基因βA亚基成熟肽序列,设计并合成1对兼并引物,利用PCR技术从大熊猫,小熊猫,马来熊的基因组DNA中直接扩增目的基因片段,并分别克隆到大肠杆菌载体pBlueScript^ 当中,然后对培养产物进行行序列测定,DNA序列分析表明,三种物种的Activin基因βA亚基成熟肽序列长度均为359bp,无内含子,基因片段编码一个含有119个氨基酸残基的肽段。大熊猫,小熊猫,马来熊在该成熟肽核苷酸和氨基酸序列上表现出高度的同源性,其中核苷酸同源性为93.9%。氨基酸同源性高达99%以上,此外,3种动物的核酸限制性酶切图谱也高度相似,与GenBank中收录的其他物种Activin基因βA亚基成熟肽序列相比较,显示此片段在处于不同进化程度的物种之间仍具有高度保守性,运用系统发育与进化树软件包PHILIP,并结合克隆序列对大熊猫,小熊猫,马来熊进化与分类地位进行了探讨,采用不同的统计学分析方法,所得到的3个物种系统发育进化树的拓扑结构完全一致,相比较而言,大熊猫与马来熊有着较近的亲缘关系,而小熊猫与上述两个物种的亲缘关系相对疏远,结果支持将大熊猫与马来熊归为熊科,而将小熊猫单列成科的学术观点,这是首次以生殖相关的核基因作为研究对象,为大熊猫及其近种进行系统分类研究所提供的又一分子生物学证据。     

白桦肌动蛋白(Actin)基因全长cDNA克隆与序列分析

以白桦(Betula platyphylla Suk.)次生木质部为材料,用改良CTAB方法提取总RNA。根据植物肌动蛋白(Actin)基因编码区的保守序列设计引物后进行RT-PCR,并采用RACE技术扩增出Actin基因全长序列。该基因cDNA全长1 785 bp,序列分析表明,该基因编码区1 134 bp,编码377个氨基酸,5′非编码区157 bp,3′非编码区495 bp。所得序列与GenBank中注册的其它植物肌动蛋白核苷酸序列的相似性均在80%以上,氨基酸序列的相似性高达96%以上。此基因已在GenBank注册（EU588981）。根据高等植物肌动蛋白相似性构建了进化树,表明白桦肌动蛋白与蓖麻肌动蛋白之间的亲缘关系最为密切,在进化中分化时间最为接近。     

一种苦荞主要过敏原基因cDNA的克隆及序列分析

为了获得苦荞中主要过敏原的cDNA和由此推导的蛋白质序列 ,分析其结构特点 ,以苦荞幼根根尖为材料 ,提取总RNA并反转录mRNA为cDNA第一链 .通过RT PCR、3′RACE、基因克隆及序列测定 ,获得一种苦荞主要过敏蛋白基因的cDNA片段 (GenBank登录号为AY0 4 4918) .该cDNA片段由 76 8bp组成 ,包括 3′端非编码区 180个bp ,开放阅读框 5 88bp .可编码一个由 195个氨基酸残基组成的功能蛋白及一个终止密码 .苦荞主要过敏原基因与甜荞 2 2kD过敏蛋白、豆球类蛋白的核苷酸序列分别有 95 %和 93%的同源性 .其推导的氨基酸序列与甜荞球蛋白、刀豆蛋白、甜橙柠檬素分别有 93%、83%和 5 7%的同源性 .该过敏蛋白 183～ 188位氨基酸残基KEEEKE在多数不同过敏原中均存在 ,推测可能为其中的抗原决定簇序列     

Molecular Cloning of Giant Panda Pituitary Prolactin cDNA and Its Expression in Escherichia coli

cDNA encoding pituitary (PRL) of giant panda was obtained using RT-PCR and expressed in E. coli. The results revealed that panda PRL cDNA encodes a precursor protein of 229 amino acids including a putative signal peptide of 30 amino acids and a mature protein of 199 residues with one potential N-glycosylation site. Sequence comparison indicated that panda PRL shares a high degree of identity to other known PRL sequences ranging from 98% with mink PRL to about 50% with rodent PRL. Six cysteine residues and 29 conserved residues distributed in four domains (PD1, PD2, PD3, and PD4) of PRL were observed through multiple sequence alignment. Fourteen key residues of binding sites 1 and 2 involved in receptor binding are conserved in panda PRL. GST fused recombinant panda PRL protein was efficiently expressed with the form of insoluble inclusion bodies in E. coli BL21 transformed with a pGEX-4T-1 expression vector containing the DNA sequence encoding mature panda PRL. Western blot analysis indicated that GST-panda PRL recombinant protein could be recognized by antibody against human PRL. Our results would contribute to further elucidating the structural and functional characteristics of pituitary PRL and provide a basis for the production of recombinant panda prolactin for future use in the breeding of giant panda.     

cDNA cloning and expression of ghrelin in giant panda (<Emphasis Type="Italic">Ailuropoda melanoleuca</Emphasis>)

Ghrelin is an endogenous ligand for the growth hormone secretagogue receptor. It plays an important role in stimulating growth hormone secretion, food intake, body weight gain and gastric motility. cDNA sequences coding for ghrelin precursor protein (prepro-ghrelin) were isolated from the stomach of a giant panda. Two different mRNA sequences of ghrelin were obtained. The long open reading frame of ghrelin (354 bp) encodes a precursor protein of 117 amino acids with a 23 amino acid signal peptide. The short one (351 bp) encodes a precursor protein of 116 amino acids with the same 23 amino acid signal peptide. The presumed giant panda mature ghrelin proteins also had two forms. Comparative analysis showed that the first and the fourth amino acids (Gly and Phe) were completely conserved and the third amino acid (Ser) was also highly conserved in the mature ghrelin. RT-PCR analysis of giant panda ghrelin mRNA in various tissues revealed high level of expression in stomach, relative lower levels of expression in small intestine, liver and kidney, and no expression in thymus, spleen and heart.     

大熊猫酸性核糖体磷酸蛋白P1 基因cDNA 克隆及序列分析

运用RT-PCR 技术,从大熊猫的肌肉组织总RNA 中成功克隆了酸性核糖体磷酸蛋白P1 (RPLP1)基因的表达序列,并对其进行了测序及初步分析。结果表明:大熊猫RPLP1 基因的表达序列全长为448 bp,开放阅读框(ORF)为344 bp,编码114 个氨基酸的蛋白质,该蛋白的分子量为11.566 kDa,pI 为4.4,含有3 个酪蛋白激酶Ⅱ磷酸化位点和2 个N - 酰基化位点。进一步分析发现,大熊猫RPLP1 基因的表达序列及其编码的氨基酸序列与已报道的部分哺乳动物具有很高的相似性。      

Nucleotide Sequences of an Important Functional Gene hnRNPA2/B1 from Ailuropoda melanoleuca and Ursus thibetanus mupinensis and Its Potential Value in Phylogenetic Study

The cDNA fragments of hnRNPA2/B1 were cloned from the giant panda and black bear using RT-PCR method, which were, respectively, 1029bp and 1026bp in length encoding 343 and 341 amino acids. Analysis indicated the cDNA cloned from the giant panda encoded variant B1 while the cDNA cloned from black bear encoded variant A2.

Analyzing the hnRNPA2B1 peptide of the giant panda and black bear, 76 glycine residues and 86 glycine residues were, respectively, found, and moreover, most glycine are concentrated in the latter halves of the hnRNPA2B1 peptides. Functional sites prediction also showed many N-myristoylation sites existed in the glycine-rich domain, which is probably related to the role of telomere maintenance.

From base bias and substitution analysis, we can conclude that the ORF of hnRNPA2/B1 biased G while hated C, and transition of the third site did not achieve the level of saturation.

Orthology analysis indicated that both the nucleotide sequence and the deduced amino acid sequence showed high identity to other 26 hnRNPA2/B1 sequences from mammals and nonmammals reported. These sequences were used to construct phylogenetic trees employing the NJ method with 1000 bootstrap, and the obtained tree demonstrated similar topology with the classical systematics, which suggested the potential value of hnRNPA2/B1 in phylogenetic analysis.

This report will be the first step to the study function of hnRNPA2/B1 in the giant panda and black bear, and will provide a scientific basis to disease surveillance, captive breeding, and conservation of the endangered species.     

大熊猫辅酶Q-细胞色素C 氧化还原酶的辅酶Q连接蛋白基因cDNA 的克隆及序列比较

大熊猫（Ailuropoda melanoleuca）是世界上极其宝贵的自然历史遗产,具有重要的学术研究价值,其生存和保护现状为世人所关注。而从分子水平上对大熊猫开展研究逐渐成为国内外研究的重点。目前,对大熊猫基因的研究多集中于线粒体（Zhang and Ryder,1994）和部分基因的克隆与分析（周荣家等,1998）,而涉及众多功能基因及其生物学功能探索相对较少,     

Molecular cloning of giant panda pituitary prolactin cDNA and its expression in Escherichia coli

cDNA encoding pituitary (PRL) of giant panda was obtained using RT-PCR and expressed in E. coli. The results revealed that panda PRL cDNA encodes a precursor protein of 229 amino acids including a putative signal peptide of 30 amino acids and a mature protein of 199 residues with one potential N-glycosylation site. Sequence comparison indicated that panda PRL shares a high degree of identity to other known PRL sequences ranging from 98% with mink PRL to about 50% with rodent PRL. Six cysteine residues and 29 conserved residues distributed in four domains (PD1, PD2, PD3, and PD4) of PRL were observed. through multiple sequence alignment. Fourteen key residues of binding sites 1 and 2 involved in receptor binding are conserved in panda PRL. GST fused recombinant panda PRL protein was efficiently expressed with the form of insoluble inclusion bodies in E. coli BL21 transformed with a pGEX-4T-1 expression vector containing the DNA sequence encoding mature panda PRL. Western blot analysis indicated that GST-panda PRL recombinant protein could be recognized by antibody against human PRL. Our results would contribute to further elucidating the structural and functional characteristics of pituitary PRL and provide a basis for the production of recombinant panda prolactin for future use in the breeding of giant panda.     

大熊猫乳酸脱氢酶同工酶M_4胰酶水解后的HPLC肽谱分析

 比较了大熊猫与猪LDH-M_4用胰酶水解后的HPLC肽谱;对分离出的各个肽段测定了氨基酸组成与N-末端。经分析,在两者各有的35个肽段中,22个肽段有相同的氨基酸组成与N-末端且在HPLC图谱上有相同的保留时间。另外有13个肽段在氨基酸组成与保留时间上存在差异。对大熊猫LDH-M中部分肽段测定了氨基酸残基序列。结果表明,与结合NAD~+有关的12肽的序列与一级结构已知的猪LDH-M含有Cys165的相应肽段完全一样;在与底物结合部位含有His191的35肽中,两者只有一个氨基酸残基的差异。在N-端的21肽中,有3个残基出现差异;而在C-端的14肽中,仅出现一个残基的差异。     

Cloning, sequence, and function analyses of giant panda (Ailuropoda melanoleuca) CD9 gene

CD9 is a member of the tetraspanin family proteins and has recently been shown to be essential for sperm-oocyte fusion in mice. The giant panda (Ailuropoda melanoleuca) CD9 (gpCD9) cDNA was amplified for the first time by RT-PCR from ovary total RNA and cloned, sequenced and analyzed. The result revealed that the open reading frame (ORF) of gpCD9 was 681 bp, which has the same length as that of mouse. Sequence analysis and structure prediction displayed that the amino acid sequence of gpCD9 is over 80% identity to those of mammals with the conserved structures, including the four transmembrane domains (TM) and certain characteristic residues. The results of sperm-egg fusion experiments demonstrated that giant panda CD9 large extracellular loop (LEL) significantly inhibited (P < 0.05) the mouse gamete fusion when the recombinant protein was added. However, when three amino acid residues TVT (173-175) of the gpCD9 were mutated to AAA, the large extracellular loop (LELM) of mutated protein was rarely inhibiting the gamete fusion of mice. Our results may be useful in improving an insight into understanding the potential mechanism of gamete fusion and genetic characteristics of giant panda.