硒蛋白的生物合成与调控

硒蛋白是硒以硒半胱氨酸(Sec)形式参入形成的蛋白质。Sec作为参入蛋白质的第21种氨基酸,由硒蛋白mRNA上的UGA编码。在原核生物中,Sec参入硒蛋白的相关因子及其参入机制已基本阐明,Sec在SELA、SELB、SELC、SELD及Sec插入序列(SECIS)等的共同作用下参入到蛋白质中。在真核生物中,Sec参入硒蛋白的可能途径是：Ser-tRNA‘^[Ser]Sec。通过磷酸丝氨酰-tRNA^[Ser]Sec。最终转变为Sec-tRNA^[Ser]Sec,并在延伸因子及相关蛋白质因子的作用下参入到硒蛋白中。硒蛋白的合成在翻译前水平、mRNA水平、供硒水平等都受到相应的调控。     

硒蛋白的分子生物学研究进展

已有35种硒蛋白被分离和表征,但许多硒蛋白及其功能仍未完全阐明.硒半胱氨酸(Sec)作为参入蛋白质的第21种氨基酸,由硒蛋白mRNA上的UGA编码.在原核生物,Sec参入硒蛋白的复杂机制已经较为明确,需要四种基因产物（SELA、SELB、SELC和SELD）和一个存在于硒蛋白mRNA上的被称为Sec插入序列(SECIS)的茎环(stem loop)样二级结构.在真核生物,硒蛋白生物合成途径可能在SECIS的结构和位置、特异的延伸因子及其他RNA-RNA或RNA-蛋白质因子之间的相互作用等方面与原核生物不同.另外,哺乳动物硒蛋白mRNA上的UGA翻译为Sec的过程低效,特定位点的UGA密码子不同功能(终止密码和Sec密码)的调控可能是硒蛋白表达低效的关键.     

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。     

疟蚊基因组中新硒蛋白的计算机识别

硒蛋白的生物合成取决于硒代半胱氨酸插入蛋白质的过程. TGA码既是终止码、又可翻译成硒代半胱氨酸, 这使普通基因注释软件无法正确预测硒蛋白, 导致现有数据库中许多物种的硒蛋白被错误注释或丢失. 本研究基于已公布的疟蚊基因组预测信息、采用PERL语言编程, 对疟蚊基因组中的硒蛋白进行了计算机检索与分析. 结果表明: 以TGA码终止的基因有11365条, 其中具有SECIS结构的基因有918条, 同时具有半胱氨酸同源类似物的基因58条. 再经Sec侧翼序列比对, 最终检索到具有硒蛋白全部特点的基因7条. 从硒蛋白的基本生物功能推测, 冈比亚疟蚊基因组中存在的新硒蛋白可能与疟蚊的氧化耐受特性及其相关蛋白的调控相关联. 因此, 研究疟蚊硒蛋白将为干涉疟蚊带菌能力、从蚊媒传播途径防止疟疾提供理论基础.     

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。     

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。     

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。     

大肠杆菌tRNASec关键核苷酸位点

在原核生物中,硒蛋白合成需要tRNA~(Sec) (SelC)与硒代半胱氨酸合成(Sec synthase, SelA)、硒代半胱氨酸特异性延伸因子(Sec-specificelongationfactor,SelB)之间相互作用。【目的】基于大肠杆菌掺硒机器,寻找tRNA~(Sec)骨架上关键核苷酸位点,为解决硒蛋白目前面临的掺硒效率较低、产量低的问题提供新思路。【方法】以大鼠细胞质型硫氧还蛋白还原酶(thioredoxinreductase1,TrxR1)为掺硒模式蛋白为定点突变tRNA~(Sec),转化至BL21 (DE3) gor-获得阳性重组菌株(携带pET-TRSter/pSUABC’),用于表达大鼠硒蛋白TrxR1,然后使用2￠,5￠ADP-Sepharose亲和层析和凝胶过滤两步法分离纯化TrxR1,最后利用经典硒依赖型DTNB还原反应测定TrxR1的酶活,分析关键核苷酸位点,评价掺硒效率。【结果】在存在SECIS元件的前提下,当SelA、SelB、tRNA~(Sec)共表达时,与野生型相比,携带突变型tRNA~(Sec)所共表达的TrxR1酶活力呈现不同程度的降低,其中E.colitRNA~(Sec)的G18、G19这两个位点的所有的TrxR1酶活远低于野生型(10%);然而,a26和b7的酶活相对较高。【结论】E. coli tRNA~(Sec)骨架上G18和G19位点对于维持tRNA稳定性和灵活性发挥了关键作用,位点突变引起tRNA结构变化会影响tRNA~(Sec)与掺硒元件的互作,因此有望通过改造tRNA核苷酸位点来提高硒蛋白的掺硒效率。     

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

微量元素硒 (Ｓｅ)作为许多具有重要生物功能的硒酶的活性中心 ,不但与机体的免疫应答及抗氧化作用等生理功能密切相关 ,而且能够降低癌症的发生率[1,2 ] 。在流行病学和临床研究中 ,常用血浆或全血中Ｓｅ浓度作为衡量Ｓｅ状态的指标 ,而且血浆浓度能比全血浓度更迅速地反映Ｓｅ状态的变化。在哺乳动物血浆中 ,Ｓｅ主要结合在 3种蛋白质中 :硒蛋白Ｐ、胞外谷胱甘肽过氧化物酶和清蛋白。其中硒蛋白Ｐ所含Ｓｅ大约占血浆中全部Ｓｅ浓度的 5 0 %。硒蛋白Ｐ不同于目前所鉴定的所有其他硒蛋白 ,因为它含有 10～ 12个硒代半胱氨酸 (ＳｅＣｙｓ)残…     

Efficient incorporation of multiple selenocysteines involves an inefficient decoding step serving as a potential translational checkpoint and ribosome bottleneck

Selenocysteine is incorporated into proteins via "recoding" of UGA from a stop codon to a sense codon, a process that requires specific secondary structures in the 3' untranslated region, termed selenocysteine incorporation sequence (SECIS) elements, and the protein factors that they recruit. Whereas most selenoprotein mRNAs contain a single UGA codon and a single SECIS element, selenoprotein P genes encode multiple UGAs and two SECIS elements. We have identified evolutionary adaptations in selenoprotein P genes that contribute to the efficiency of incorporating multiple selenocysteine residues in this protein. The first is a conserved, inefficiently decoded UGA codon in the N-terminal region, which appears to serve both as a checkpoint for the presence of factors required for selenocysteine incorporation and as a "bottleneck," slowing down the progress of elongating ribosomes. The second adaptation involves the presence of introns downstream of this inefficiently decoded UGA which confer the potential for nonsense-mediated decay when factors required for selenocysteine incorporation are limiting. Third, the two SECIS elements in selenoprotein P mRNA function with differing efficiencies, affecting both the rate and the efficiency of decoding different UGAs. The implications for how these factors contribute to the decoding of multiple selenocysteine residues are discussed.     

SECIS-SBP2 interactions dictate selenocysteine incorporation efficiency and selenoprotein hierarchy

Selenocysteine incorporation at UGA codons requires cis-acting mRNA secondary structures and several specialized trans-acting factors. The latter include a selenocysteine-specific tRNA, an elongation factor specific for this tRNA and a SECIS-binding protein, SBP2, which recruits the elongation factor to the selenoprotein mRNA. Overexpression of selenoprotein mRNAs in transfected cells results in inefficient selenocysteine incorporation due to limitation of one or more of these factors. Using a transfection-based competition assay employing overexpression of selenoprotein mRNAs to compete for selenoprotein synthesis, we investigated the ability of the trans-acting factors to overcome competition and restore selenocysteine incorporation. We report that co-expression of SBP2 overcomes the limitation produced by selenoprotein mRNA overexpression, whereas selenocysteyl-tRNA and the selenocysteine-specific elongation factor do not. Competition studies indicate that once bound to SECIS elements, SBP2 does not readily exchange between them. Finally, we show that SBP2 preferentially stimulates incorporation directed by the seleno protein P and phospholipid hydroperoxide glutathione peroxidase SECIS elements over those of other selenoproteins. The mechanistic implications of these findings for the hierarchy of selenoprotein synthesis and nonsense-mediated decay are discussed.     

The nature of the minimal 'selenocysteine insertion sequence' (SECIS) in Escherichia coli.

The UGA codon, usually a stop codon, can also direct the incorporation into a protein of the modified amino acid selenocysteine. This UGA decoding process requires a cis -acting mRNA element called 'selenocysteine insertion sequence' (SECIS) that can form a stem-loop structure. In Escherichia coli the SECIS of the selenoprotein formate dehydrogenase (FdhH) mRNA has been previously described to consist of at least 40 nucleotides following the UGA codon. Here we determined the nature of the minimal SECIS required for the in vivo UGA-directed selenocysteine incorporation in E.coli . Our study is based on extensive mutational analysis of the fdhF SECIS DNA located in a lac' Z fusion. We found that the whole stem-loop RNA structure of the E.coli fdhF SECIS previously described is not required for the UGA-directed selenocysteine incorporation in vivo . Rather, only its upper stem-loop structure of 17 nucleotides is necessary on the condition that it is located in a proper distance (11 nucleotides) from the UGA codon. Based on these observations, we present a new model for the minimal E.coli SECIS.     

Novel structural determinants in human SECIS elements modulate the translational recoding of UGA as selenocysteine

The selenocysteine insertion sequence (SECIS) element directs the translational recoding of UGA as selenocysteine. In eukaryotes, the SECIS is located downstream of the UGA codon in the 3′-UTR of the selenoprotein mRNA. Despite poor sequence conservation, all SECIS elements form a similar stem-loop structure containing a putative kink-turn motif. We functionally characterized the 26 SECIS elements encoded in the human genome. Surprisingly, the SECIS elements displayed a wide range of UGA recoding activities, spanning several 1000-fold in vivo and several 100-fold in vitro. The difference in activity between a representative strong and weak SECIS element was not explained by differential binding affinity of SECIS binding Protein 2, a limiting factor for selenocysteine incorporation. Using chimeric SECIS molecules, we identified the internal loop and helix 2, which flank the kink-turn motif, as critical determinants of UGA recoding activity. The simultaneous presence of a GC base pair in helix 2 and a U in the 5′-side of the internal loop was a statistically significant predictor of weak recoding activity. Thus, the SECIS contains intrinsic information that modulates selenocysteine incorporation efficiency.     

Selenocysteine incorporation in eukaryotes: insights into mechanism and efficiency from sequence, structure, and spacing proximity studies of the type 1 deiodinase SECIS element.

SECIS elements are stem-loop structures located in the 3' untranslated regions (UTRs) of eukaryotic selenoprotein mRNAs that are required for directing cotranslational selenocysteine incorporation at UGA codons. In prokaryotes, stem-loops mediating selenocysteine incorporation are located immediately downstream of the UGA selenocysteine codon, in the coding region. Previous characterization studies of the mammalian SECIS elements of type 1 deiodinase, glutathione peroxidase, and selenoprotein P showed that conserved nucleotides in the loops and unpaired bulges, and base pairing in the stems are required for SECIS function. These initial studies utilized approximately 175-230-nt segments of the 3'UTRs of the selenoprotein mRNAs. Here we define the minimal functional rat type 1 deiodinase SECIS element, a 45-nt segment, the 5' boundary of which corresponds precisely to the 5'-most critical conserved nucleotide identified previously. We also define base pairing requirements in the stem of this element. In view of the presence of SECIS elements in the open reading frames (ORFs) of bacterial selenoproteins, we examine the effects in the type 1 deiodinase of extending the ORF into the SECIS element, and find that this dramatically inhibits SECIS function. Finally, we define a minimal spacing requirement of 51-111 nt between a eukaryotic UGA selenocysteine codon and SECIS element.     

A single homozygous point mutation in a 3'untranslated region motif of selenoprotein N mRNA causes SEPN1-related myopathy

Mutations in the SEPN1 gene encoding the selenoprotein N (SelN) have been described in different congenital myopathies. Here, we report the first mutation in the selenocysteine insertion sequence (SECIS) of SelN messenger RNA, a hairpin structure located in the 3' untranslated region, in a patient presenting a classical although mild form of rigid spine muscular dystrophy. We detected a significant reduction in both mRNA and protein levels in the patient's skin fibroblasts. The SECIS element is crucial for the insertion of selenocysteine at the reprogrammed UGA codon by recruiting the SECIS-binding protein 2 (SBP2), and we demonstrated that this mutation abolishes SBP2 binding to SECIS in vitro, thereby preventing co-translational incorporation of selenocysteine and SelN synthesis. The identification of this mutation affecting a conserved base in the SECIS functional motif thereby reveals the structural basis for a novel pathological mechanism leading to SEPN1-related myopathy.     

Evolutionary history of selenocysteine incorporation from the perspective of SECIS binding proteins

Background  

The co-translational incorporation of selenocysteine into nascent polypeptides by recoding the UGA stop codon occurs in all domains of life. In eukaryotes, this event requires at least three specific factors: SECIS binding protein 2 (SBP2), a specific translation elongation factor (eEFSec), selenocysteinyl tRNA, and a cis -acting selenocysteine insertion sequence (SECIS) element in selenoprotein mRNAs. While the phylogenetic relationships of selenoprotein families and the evolution of selenocysteine usage are well documented, the evolutionary history of SECIS binding proteins has not been explored.     

Recoding elements located adjacent to a subset of eukaryal selenocysteine-specifying UGA codons

Incorporation of the 21st amino acid, selenocysteine, into proteins is specified in all three domains of life by dynamic translational redefinition of UGA codons. In eukarya and archaea, selenocysteine insertion requires a cis-acting selenocysteine insertion sequence (SECIS) usually located in the 3'UTR of selenoprotein mRNAs. Here we present comparative sequence analysis and experimental data supporting the presence of a second stop codon redefinition element located adjacent to a selenocysteine-encoding UGA codon in the eukaryal gene, SEPN1. This element is sufficient to stimulate high-level (6%) translational redefinition of the SEPN1 UGA codon in human cells. Readthrough levels further increased to 12% when tested in the presence of the SEPN1 3'UTR SECIS. Directed mutagenesis and phylogeny of the sequence context strongly supports the importance of a stem loop starting six nucleotides 3' of the UGA codon. Sequences capable of forming strong RNA structures were also identified 3' adjacent to, or near, selenocysteine-encoding UGA codons in the Sps2, SelH, SelO, and SelT selenoprotein genes.     

New selenoproteins identified in silico from the genome of Anopheles gambiae

Selenoprotein is biosynthesized by the incorporation of selenocysteine into proteins,where the TGA codon in the open reading frame does not act as a stop signal but is translated into selenocysteine.The dual functions of TGA result in mis-annotation or lack of selenoproteins in the sequenced genomes of many species.Available computational tools fail to correctly predict selenoproteins.Thus,we devel-oped a new method to identify selenoproteins from the genome of Anopheles gambiae computationally.Based on released genomic information,several programs were edited with PERL language to identify selenocysteine insertion sequence(SECIS)element,the coding potential of TGA codons,and cys-teine-containing homologs of selenoprotein genes.Our results showed that 11365 genes were termi-nated with TGA codons,918 of which contained SECIS elements.Similarity search revealed that 58 genes contained Sec/Cys pairs and similar flanking regions around in-frame TGA codons.Finally,7 genes were found to fully meet requirements for selenoproteins,although they have not been anno-tated as selenoproteins in NCBI databases.Deduced from their basic properties,the newly found se-lenoproteins in the genome of Anopheles gambiae are possibly related to in vivo oxidation tolerance and protein regulation in order to interfere with anopheles' vectorial capacity of Plasmodium.This study may also provide theoretical bases for the prevention of malaria from anopheles transmission.