硒蛋白合成的特殊机制

硒蛋白含有一种特殊氨基酸－硒代半胱氨酸。在翻译阶段,该氨基酸从硒蛋白ｍＲＮＡ编码区的ＵＧＡ密码子处掺入多肽链。已证明它由丝氨酸和活性硒供体分子合成。一种独特的ｔＲＮＡ,某些特殊蛋白质因子以及硒蛋白ｍＲＮＡ的特殊二级结构是ＵＧＡ解读为硒代半胱氨酸所必需的。     

谷胱甘肽过氧化物酶的硒代半胱氨酸插入元件

真核生物将硒代半胱氨酸插入蛋白质必需硒代半胱氨酸插入元件（ＳＥＣＩＳ）的参与,后者位于硒蛋白ｍＲＮＡ的３′非翻译区．采用ＲＮＡ折叠程序对１５个谷胱甘肽过氧化物酶基因进行计算机处理发现,其可能的ＳＥＣＩＳ中都具有３段保守碱基ＡＵＧＡ－Ａ（Ｇ）ＡＡ－ＧＡ．根据Ａ（Ｇ）ＡＡ位于顶环或者顶环上游５′臂的突环上,可将ＳＥＣＩＳ分为Ⅰ型和Ⅱ型结构     

生物合成硒蛋白机制的研究进展

作为第 2 1种氨基酸 ,硒代半胱氨酸在翻译阶段由核糖体介导 ,在mRNA编码区的UGA密码子处参入多肽链。研究表明硒代半胱氨酸的参入需要一个顺式作用元件SECIS和 4个基因产物 :SelA、SelB、SelC、SelD。原核生物和真核生物的SECIS在mRNA中的位置和结构特征差异显著。在利用Escherichiacoli硒代半胱氨酸的参入机制合成硒蛋白方面 ,研究人员进行了有益的探索。     

硒蛋白P的研究进展

硒蛋白P（SeP)是从大鼠和人血浆中分离,纯化得到的一种糖蛋白,每个硒蛋白P多肽含有10个硒代半胱氨酸,硒蛋白P中的硒含量占大鼠和人血浆中硒含量的50%以上,在其mRNA开放阅读框架中克隆的cDNA的序列含有10个UGA密码子。硒代半胱氨酸在一个UGA密码子处嵌入蛋白的一级结构,尽管对硒蛋白P功能还没有彻底了解,它的一种非常可能的作用是作为一种胞外抗氧化剂,大鼠血浆中的硒蛋白P在体内实验中对Diquat诱导的脂质过氧化和肝损坏具有保护作用,人血浆中的硒蛋白P在体外实验中显示减少内作为一存活促进因子。     

mRNA的3′非翻译区控制硒代半胱氨酸参入多肽链

ｍＲＮＡ的３′非翻译区控制硒代半胱氨酸参入多肽链刘定干（中国科学院上海生物化学研究所,上海２０００３１）关键词ｍＲＮＡ３′非翻译区硒代半胱氨酸多肽链真核生物ｍＲＮＡ的３′非翻译区是决定各个ｍＲＮＡ专有功能特征的调控元件。３′非翻译区除能决定ｍＲＮＡ的...     

硒蛋白P的研究进展

硒蛋白P(SeP)是从大鼠和人血浆中分离、纯化得到的一种糖蛋白 ,每个硒蛋白P多肽含有10个硒代半胱氨酸。硒蛋白P中的硒含量占大鼠和人血浆中硒含量的 5 0 %以上。在其mRNA开放阅读框架中克隆的cDNA的序列含有 10个UGA密码子。硒代半胱氨酸在一个UGA密码子处嵌入蛋白的一级结构 ,尽管对硒蛋白P功能还没有彻底了解 ,它的一种非常可能的作用是作为一种胞外抗氧化剂。大鼠血浆中的硒蛋白P在体内实验中对Diquat诱导的脂质过氧化和肝损坏具有保护作用 ,人血浆中的硒蛋白P在体外实验中显示减少内毒素过氧化硝酸盐和磷脂氢过氧化物的活性。牛血浆中的硒蛋白P在神经细胞的培养中作为一存活促进因子。     

富硒产品中硒的形态分析及化学评分模式的建立

采用微波水解、HPLC-HG-AFS法测定了硒蛋白粉、硒蛋白片、肽粉、富硒原料等19种硒产品中的总硒、硒代氨基酸和亚硒酸根离子[Se(IV)],分析了硒代氨基酸、Se(IV)和其他形态硒占总硒的百分比及不同形态硒代氨基酸的组成比例。以此为依据,将硒产品分为硒蛋白型、单一硒代氨基酸型、其它形态硒型及有机无机硒混合型。根据DBS42/002-2014规定建立了富有机硒产品评分模式,其中18种为富有机硒产品;根据适硒地区母乳中硒代氨基酸的组成比例提出了硒代氨基酸的化学评分模式,评分结果显示13种以蛋白态硒为主的硒产品中硒代氨基酸的组成比例均与母乳相差甚远,不利于人体平衡吸收利用,其中10种SeMet含量远远超过人体所需,SeCys_2为限制硒代氨基酸。该评分模式的建立对硒产品的开发具有指导意义。     

大肠杆菌中一种对NF—IL63‘UTR专一的结合蛋白

在大肠杆菌ＴＧ１中,发现了一种与人白介素６核转录因子ｍＲＮＡ的３’非翻译区专一结合的蛋白,其Ｎ－端氨基酸序列为Ａｌａ－Ｔｈｒ－Ａｒｇ－Ｉｌｕ－Ｐｈｅ－Ｈｉｓ－Ｇｌｙ－Ｃｙｓｓ（？）－Ｇｌｙ。对数据库检索未发现完全同源的蛋白。对于在大肠杆菌中发现真核ｍＲＮＡ专一结合蛋白的意义做了讨论。     

富硒酵母中硒赋态的研究

硒是人体必需的一种微量元素,参与合成硒代半胱氨酸、硒代甲硫氨酸以及多种硒代蛋白(酶),具有抗肿瘤、抗氧化、增强人体免疫等多种生物学活性,与人体的健康有着密切关系.硒以不同的形式存在于自然界中,大致可分为无机硒和有机硒两种,其生物活性与毒性也各有不同.富硒酵母作为补充硒元素的主要形式之一,具有生物利用度高、食用安全、毒性低等优点.研究富硒酵母中的硒的赋态,对合理摄取硒元素,促进人体健康具有重要意义,因此成为近年来研究的热点.     

化学修饰单克隆抗体模拟谷胱甘肽过氧化物酶

化学修饰具有底物谷胱甘肽（ＧＳＨ）结合部位的单克隆抗体（４Ａ４）,使其结合部位上的丝氨酸（Ｓｅｒ）转变成谷胱甘肽过氧化物酶（ＧＰＸ）的催化基团硒代半胱氨酸（Ｓｅ－Ｃｙｓ）,因而产生高活力的含硒抗体酶（Ｓｅ－ａｂｚｙｍｅ）．突变的４Ａ４（ｍ４Ａ４）的ＧＰＸ活力达到了天然酶活力的１９％,并对ｍ４Ａ４的酶学性质和动力学性质进行了研究;硒代谷胱甘肽（ＧＳｅＨ）连到４Ａ４结合部位,其ＧＰＸ活力由３．８６Ｕ／μｍｏｌ提高到５９８．９Ｕ／μｍｏｌ用黄嘌呤氧化酶／次黄嘌呤为中心的心肌线粒体自由基损伤模型证明Ｓｅ－ａｂｚｙｍｅ（ｍ４Ａ４）可减轻活性氧对线粒体的损伤。     

Thyroid hormone deiodinases revisited: insights from lungfish: a review

In vertebrates, hormones released from the thyroid gland travel in the circulation to target tissues where they may be processed by deiodinating enzymes into more active or inactive iodothyronines. In mammals, there are three deiodinating enzymes described. Type1 (D1), which primarily occurs in the liver, converts reverse T3 into T2 for clearance. It also converts T4 into T3. This production of T3 is believed to contribute to the bulk of circulating T3 in mammals. The type2 (D2) enzyme may be found in many other tissues where it converts T4 to T3, which is then transferred to the receptors in the nucleus of the same cell, i.e. does not contribute to the circulating T3. The type3 (D3) enzyme converts T3 into T2. The expression of the genes for these three enzymes and/or the activity of the enzymes have been studied in several non-mammalian groups of vertebrates. From agnathans to birds, D2 and D3 appear to occur universally, with the possible exception of squamate reptiles (lack D2?). D1 has not been found in amphibians, lungfish or agnathans. All three enzymes are selenoproteins, in which a selenocysteine is found in the active centre. The nucleotide code for translation of a selenocysteine is UGA, which under normal circumstances is a stop codon. In order for UGA to code for selenocysteine, there must be a SECIS element in the 3′UTR of the mRNA. Any disruption of the SECIS will result in a truncated protein in the region of its active centre. It is suggested that such alternative splicing may be a mode of altering the expression of deiodinases in particular tissues to change the response of such tissues to thyroid hormones under differing circumstances such as stages of development.     

Selenocysteine insertion or termination: factors affecting UGA codon fate and complementary anticodon:codon mutations.

Translation of UGA as selenocysteine instead of termination occurs in numerous proteins, and the process of recording UGA requires specific signals in the corresponding mRNAs. In eukaryotes, stem-loops in the 3' untranslated region of the mRNAs confer this function. Despite the presence of these signals, selenocysteine incorporation is inefficient. To investigate the reason for this, we examined the effects of the amount of deiodinase cDNA on UGA readthrough in transfected cells, quantitating the full-length and UGA terminated products by Western blotting. The gene for the selenocysteine-specific tRNA was also cotransfected to determine if it was limiting. We find that the concentrations of both the selenoprotein DNA and the tRNA affect the ratio of selenocysteine incorporation to termination. Selenium depletion was also found to decrease readthrough. The fact that the truncated peptide is synthesized intracellularly demonstrates unequivocally that UGA can serve as both a stop and a selenocysteine codon in a single mRNA. Mutation of UGA to UAA (stop) or UUA (leucine) in the deiodinase mRNA abolishes deiodinase activity; but activity is partially restored when selenocysteine tRNAs containing complementary mutations are contransfected. Thus, UGA is not essential for selenocysteine incorporation in mammalian cells, provided that codon:anticodon complementarity is maintained.     

Nitrate-inducible formate dehydrogenase in Escherichia coli K-12. II. Evidence that a mRNA stem-loop structure is essential for decoding opal (UGA) as selenocysteine

fdnG, encoding the selenopeptide of Escherichia coli formate dehydrogenase-N, contains an in-frame opal (UGA) codon at amino acid position 196 that directs selenocysteine incorporation. We have identified sequences that contribute to the mRNA context required for decoding this UGA as selenocysteine. We identified a potential stem-loop structure immediately downstream of UGA196 that is comparable in size and structure to a stem-loop predicted to form in fdhF, which encodes the selenopeptide of E. coli formate dehydrogenase-H. Mutational analysis of the fdnG stem-loop structure suggests that it is critical for decoding UGA196 as selenocysteine. Our data indicate that both stability and specific nucleotide sequences of the stem-loop likely contribute to the appropriate mRNA context for selenocysteine incorporation into the fdnG gene product.     

Coding from a distance: dissection of the mRNA determinants required for the incorporation of selenocysteine into protein.

Incorporation of selenocysteine into proteins is directed by specifically 'programmed' UGA codons. The determinants for recognition of the selenocysteine codon have been investigated by analysing the effect of mutations in fdhF, the gene for formate dehydrogenase H of Escherichia coli, on selenocysteine incorporation. It was found that selenocysteine was also encoded when the UGA codon was replaced by UAA and UAG, provided a proper codon-anticodon interaction was possible with tRNA(Sec). This indicates that none of the three termination codons can function as efficient translational stop signals in that particular mRNA position. The discrimination of the selenocysteine 'sense' codon from a regular stop codon has previously been shown to be dependent on an RNA secondary structure immediately 3' of the UGA codon in the fdhF mRNA. It is demonstrated here that the correct folding of this structure as well as the existence of primary sequence elements located within the loop portion at an appropriate distance to the UGA codon are absolutely required. A recognition sequence can be defined which mediates specific translation of a particular codon inside an mRNA with selenocysteine and a model is proposed in which translation factor SELB interacts with this recognition sequence, thus forming a quaternary complex at the mRNA together with GTP and selenocysteyl-tRNA(Sec).     

Eukaryotic selenocysteine incorporation follows a nonprocessive mechanism that competes with translational termination

The synthesis of eukaryotic selenoproteins involves the recoding of an internal UGA codon as a site for selenocysteine incorporation. This recoding event is directed by a selenocysteine insertion sequence in the 3'-untranslated region. Because UGA also functions as a signal for peptidyl-tRNA hydrolysis, we have investigated how the rates of translational termination and selenocysteine incorporation relate to cis-acting elements in the mRNA as well as to trans-acting factors in the cytoplasm. We used cis-elements from the phospholipid glutathione peroxidase gene as the basis for this work because of its relatively high efficiency of selenocysteine incorporation. The last two codons preceding the UGA were found to exert a far greater influence on selenocysteine incorporation than nucleotides downstream of it. The efficiency of selenocysteine incorporation was generally much less than 100% but could be partially enhanced by concomitant overexpression of the tRNA(Sec) gene. The combination of two or three UGA codons in one reading frame led to a dramatic reduction in the yield of full-length protein. It is therefore unlikely that multiple incorporations of selenocysteine are processive with respect to the mode of action of the ribosomal complex binding to the UGA site. These observations are discussed in terms of the mechanism of selenoprotein synthesis and its ability to compete with termination at UGA codons.     

哺乳动物硒蛋白的研究进展

硒是哺乳动物和人必需的微是元素。硒的生物学功能主要是以硒蛋白的形式表现的。到目前为止,已经克隆并测定ｃＤＮＡ顺序的哺乳动物硒蛋白有９种停,它们是细胞内谷胱甘肽过氧化物酶、细胞外谷胱甘肽过氧化物酶、磷脂氢谷胱甘肽过氧化物酶、胃肠谷胱甘肽过氧化物酶、Ｉ型碘化甲状腺原氨酸５′脱碘酶、Ⅱ型碘化甲状腺原氨酸５′脱磺酶、Ⅲ型碘化甲状腺原氨酸５′脱碘酶、硒蛋白Ｐ和硒蛋白Ｗ。这些硒蛋白中硒参入到蛋白分子是通过硒半     

Targeted insertion of selenocysteine into the alpha subunit of formate dehydrogenase from Methanobacterium formicicum.

Selenocysteine incorporation into proteins is directed by an opal (UGA) codon and requires the existence of a stem-loop structure in the mRNA flanking the UGA at its 3' side. To analyze the sequence and secondary-structure requirements for UGA decoding, we have introduced mutations into the fdhA gene from Methanobacterium formicicum, which codes for the alpha subunit of the F420-reducing formate dehydrogenase. The M. formicicum enzyme contains a cysteine residue at the position where the Escherichia coli formate dehydrogenase H carries a selenocysteine moiety. The codon (UGC) for this cysteine residue was changed into a UGA codon, and mutations were successively introduced at the 5' and 3' sides to generate a stable secondary structure of the mRNA and to approximate the sequence of the predicted E. coli fdhF mRNA hairpin structure. It was found that introduction of the UGA and generation of a stable putative stem-loop structure were not sufficient for decoding with selenocysteine. Efficient selenocysteine incorporation, however, was obtained when the loop and the immediately adjacent portion of the putative stem had a sequence identical to that present in the E. coli fdhF mRNA structure.     

Dynamics and efficiency in vivo of UGA-directed selenocysteine insertion at the ribosome

The kinetics and efficiency of decoding of the UGA of a bacterial selenoprotein mRNA with selenocysteine has been studied in vivo. A gst-lacZ fusion, with the fdhF SECIS element ligated between the two fusion partners, gave an efficiency of read-through of 4-5%; overproduction of the selenocysteine insertion machinery increased it to 7-10%. This low efficiency is caused by termination at the UGA and not by translational barriers at the SECIS. When the selenocysteine UGA codon was replaced by UCA, and tRNASec with anticodon UGA was allowed to compete with seryl-tRNASer1 for this codon, selenocysteine was found in 7% of the protein produced. When a non-cognate SelB-tRNASec complex competed with EF-Tu for a sense codon, no effects were seen, whereas a non-cognate SelB-tRNASec competing with EF-Tu-mediated Su7-tRNA nonsense suppression of UGA interfered strongly with suppression. The induction kinetics of beta-galactosidase synthesis from fdhF'-'lacZ gene fusions in the absence or presence of SelB and/or the SECIS element, showed that there was a translational pause in the fusion containing the SECIS when SelB was present. The results show that decoding of UGA is an inefficient process and that using the third dimension of the mRNA to accommodate an additional amino acid is accompanied by considerable quantitative and kinetic costs.