精胺对牛肝tRNA^lle氨基酰化的刺激作用

本实验用纯化的牛肝异亮氨酸ｔＲＮＡ（ｔＲＮＡ＾Ｉｌｅ）和异亮氨酰ｔＲＮＡ合成酶,研究了精胺对Ｉｌｅ－ｔＲＮＡ复合物形成及ＩｌｅＲＳ活性的作用。结果表明：精胺能特异地促使牛肝ｔＲＮＡ＾Ｉｌｅ氨基酰化反应;对ＩｌｅＲＳ活性无影响;能明显地增加形成Ｉｌｅ－ｔＲＮＡ复合物反应的Ｖｍａｘ和ｔＲＮＡ＾Ｉｌｅ的Ｋｍ值。     

中华蟾蜍肝苯丙氨酸tRNA的纯化及其生物活性

本文介绍一种改进的酚抽法制备蟾蜍肝总tRNA和BD纤维素柱纯化tRNA~(pbe)的简便方法。270g蟾蜍肝可制备466mg总tRNA。总tRNA的产率是未改进的酚抽法的8—11倍。总tRNA经两根BD纤维素柱纯化所得tRNA~(pbe)的酰化活力达1,354pmoles苯丙氨酸/A_(260)tRNA,它的荧光光谱测定表明,这个tRNA分子存在Y碱基。     

大鼠肝tRNA~(He)基因化学合成及克隆

tRNA在蛋白质生物合成中的主要作用是转运氨基酸,此外,tRNA与第二套密码的研究及与多胺的作用亦受到重视。传统的专一tRNA制备方法,不仅步骤繁多且收获量极少(6.5 mg/4000g肝组织),难于满足进一步用NMR,ESR等技术研究的需要。利用基因工程的手段,在细胞中表达专一的tRNA可以克服传统制备方法的不足。为此我们设计合成了大鼠肝tRNA~(Ile)基因。合成的基因全长120bp,将其中U,Ψ,D核苷酸换成T,I换成G。为了方     

精胺和Mg~（2＋）对tRNA~（Ile）圆二向色谱的影响

由于精胺（ｓｐｅｒｍｉｎｅ）能特异地刺激哺乳动物ｔＲＮＡ~（Ｉｌｅ）的氨基酰化,本文用纯化的牛肝ｔＲＮＡ~（Ｉｌｅ）观察了精胺和Ｍｇ（２＋）对ｔＲＮＡ~（Ｉｌｅ）ＣＤ光谱的影响。结果显示：Ｍｇ（２＋）可使牛肝ｔＲＮＡ~（Ｉｌｅ）ＣＤ光谱峰向短波方向偏移２ｎｍ,波峰为２６３ｎｍ,峰值被增大约１０％,ΔθＭｇ（２＋）＝２．３×１０３ｄｅｇ·ｃｍ２／ｄｍｏｌ;而精胺使牛肝ｔＲＮＡ~（Ｉｌｅ）ＣＤ光谱峰减少４０％,Δθｓｐｅｒｍｉｎｅ＝１×１０（－４）ｄｅｇ·ｃｍ２／ｄｍｏｌ;精胺和Ｍｇ（２＋）对肝ｔＲＮＡ~（Ｉｌｅ）－ＩｌｅＲＳ复合物或ＩｌｅＲＳ的ＣＤ光谱基本无影响。表明Ｍｇ（２＋）和精胺可影响牛肝ｔＲＮＡ~（Ｉｌｅ）的构象。实验同时以酵母ｔＲＮＡ（Ｐｈｅ）和Ｅ·ｃｏｌｉｔＲＮＡ~（Ｉｌｅ）作为对照。     

E.coli tRNA~(Leu)的提纯

本文报道一种E.coli tRNA~(Leu)简便而稳定的纯化方法。粗tRNA经过BD-Cellulose柱层析和聚丙烯酰胺凝胶电泳两个步骤即可得到亮氨酸接受能力为1400pmol/A_(260)单位的tRNA~(Leu)。     

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。     

酵母 tRNA~(ala)密码子GpCpU的酶促合成

tRNA主要有两种生物学功能:一是接受(相应的氨基酸。二是将此氨基酸转移到多肽链中。在后一功能中,tRNA通过其反密码子同mRNA上相应的密码子形成互补碱基间的氢键配对,从而使氨基酸转移到由mRNA碱基顺序决定的多肽序列中。本工作合成酵母tRNA~(ala)密码子GpCpU,将用于测验该tRNA的转移活性,即检查该tRNA能否通过其反密码子3＇CpGpI5＇同已结合在核糖体上的密码子5＇GpCpU3＇形成氢键配对而实现转移丙氨酸的功能。迄今报道的关于制备寡核苷酸的方法,主要有三种:化学合成、酶解天然核酸和酶促合成。本工作用最后一种方法,用RN_(ase)N_1和     

鲤鱼线粒体tRNA~(Cys)基因和轻链复制起始区的结构分析

我们测定了鲤鱼线粒体半胱氮酸tRNA 基因和轻链(L 链)复制起始区的核苷酸序列,绘制了半胱氨酸tRNA 三叶草形的二级结构以及L 链复制区的茎环结构。通过五种脊椎动物tRNA~(cya)基因的核苷酸序列分析发现,鲤鱼线粒体tRNA~(cya)基因有许多不同于细胞质tRNA~(cya)基因的不寻常的结构特点。鲤鱼线粒体L 链复制起始区含有36个碱基,复制起始区茎环结构中的茎含有11对碱基,而环则是由14个碱基组成。同其它10种脊椎动物L-链复制起始区的核苷酸序列比较发现,鲤鱼茎环结构中的茎序列是非常保守的,而环的序列及环的长度则变化较大。茎环结构可能在轻链复制中起着重要的作用。     

蛋白质合成中的核糖核酸蛋白质复合物

细胞中的RNA和RNA结合蛋白质(RNA-binding proteins,RBPs)相互作用形成核糖核酸蛋白质(ribonucleoprotein,RNP)复合物。RNP复合物分布广泛,功能众多。蛋白质生物合成包括转录及其调控、mRNA加工转运、tRNA传递、翻译及其调控等,是核酸编码的遗传信息流向活性蛋白质的过程。多种RNA分子参与这一过程,有的与对应的RNA结合蛋白质形成RNP复合物。RNP复合物的多样性和重要功能在此得到了最好的体现。该文以其中起核心作用的RNA分子为主线,对蛋白质合成中的RNP复合物进行了综述。     

精胺和Mg^2＋对tRNA^Ile圆二向色谱的影响

由于精胺能特异异地刺激哺乳动物ｔＲＮＡ＾Ｉｌｅ的氨基酰化,本文用纯化的牛肝ｔＲＮＡ＾Ｉｌｅ观察了精胺和Ｍｇ＾２＋对ｔＲＮＡ＾ＩｌｅＣＤ光谱的影响。结果显示：Ｍｇ＾２＋可使牛肝ｔＲＮＡ＾ＩｌｅＣＤ光谱峰向短波方向偏移２ｎｍ,波峰为２６３ｎｍ,峰值被增大约１０％ΔθＭｇ＾２＋＝２．３×１０＾３ｄｅｇ．ｃｍ＾２／ｄｍｏｌ;而精胺使牛肝ｔＲＮＡ＾ＩｌｅＣＤ兴谱峰减少４０％,Δθｓｐｅｒｍｉｎｅ＝１×１０＾     

Responsibility of tRNA(Ile) for spermine stimulation of rat liver Ile-tRNA formation

To determine whether tRNA or aminoacyl-tRNA synthetase is responsible for spermine stimulation of rat liver Ile-tRNA formation, homologous and heterologous Ile-tRNA formations were carried out with Escherichia coli and rat liver tRNA(Ile) and their respective purified Ile-tRNA synthetases. Spermine stimulation was observed only when tRNA from the rat liver was used. Spermine bound to rat liver tRNA(Ile) but not to the purified aminoacyl-tRNA synthetase complex. Kinetic analysis of Ile-tRNA formation revealed that spermine increased the Vmax and Km values for rat liver tRNA(Ile). The Km value for ATP and isoleucine did not change significantly in the presence of spermine. Furthermore, higher concentrations of rat liver tRNA(Ile) tended to inhibit Ile-tRNA formation if spermine was absent. Spermine restored isoleucine-dependent PPi-ATP exchange in the presence of rat liver tRNA(Ile), an inhibitor of this exchange. The nucleotide sequence of rat liver tRNA(Ile) was determined and compared with that of E. coli tRNA(Ile). Differences in nucleotide sequences of the two tRNAs(Ile) were observed mainly in the acceptor and anticodon stems. Limited ribonuclease V1 digestion of the 3'-32P-labeled rat liver tRNA(Ile) showed that both the anticodon and acceptor stems were structurally changed by spermine, and that the structural change by spermine was different from that by Mg2+. The influence of spermine on the ribonuclease V1 digestion of E. coli tRNA(Ile) was different from that of rat liver tRNA(Ile). The results suggest that the interaction of spermine with the acceptor and anticodon stems may be important for spermine stimulation of rat liver Ile-tRNA formation.     

Correlation between spermine stimulation of rat liver Ile-tRNA formation and structural change of the acceptor stem by spermine

We have recently reported that the interaction of spermine with the acceptor and anticodon stems may be important for spermine stimulation of rat liver Ile-tRNA formation [Peng, Z. et al. (1990) Arch. Biochem. Biophys. 279, 138-145]. To pinpoint which interaction of spermine is more important for spermine stimulation of Ile-tRNA formation, Ile-tRNA formation and ribonuclease V1 sensitivity of tRNA(Ile) were studied using purified tRNAs(Ile) from rat liver, wheat germ, brewer's yeast, torula yeast and Escherichia coli. The results indicate that spermine stimulation of rat liver Ile-tRNA formation correlated with the structural change of the acceptor stem by spermine. The nucleotide sequence of wheat germ tRNA(Ile) was also determined.     

Crystal structures of the CP1 domain from Thermus thermophilus isoleucyl-tRNA synthetase and its complex with L-valine

Isoleucyl-tRNA synthetase (IleRS) links tRNA(Ile) with not only its cognate isoleucine but also the nearly cognate valine. The CP1 domain of IleRS deacylates, or edits, the mischarged Val-tRNA(Ile). We determined the crystal structures of the Thermus thermophilus IleRS CP1 domain alone, and in its complex with valine at 1.8- and 2.0-A resolutions, respectively. In the complex structure, the Asp(328) residue, which was shown to be critical for the editing reaction against Val-tRNA(Ile) by a previous mutational analysis, recognizes the valine NH(3)(+) group. The valine side chain binding pocket is only large enough to accommodate valine, and the placement of an isoleucine model in this location revealed that the additional methylene group of isoleucine would clash with His(319). The H319A mutant of Escherichia coli IleRS reportedly deacylates the cognate Ile-tRNA(Ile) in addition to Val-tRNA(Ile), indicating that the valine-binding mode found in this study represents that in the Val-tRNA(Ile) editing reaction. Analyses of the Val-tRNA(Ile) editing activities of T. thermophilus IleRS mutants revealed the importance of Thr(228), Thr(229), Thr(230), and Asp(328), which are coordinated with water molecules in the present structure. The structural model for the Val-adenosine moiety of Val-tRNA(Ile) bound in the IleRS editing site revealed some interesting differences in the substrate binding and recognizing mechanisms between IleRS and T. thermophilus leucyl-tRNA synthetase. For example, the carbonyl oxygens of the amino acids are located opposite to each other, relative to the adenosine ribose ring, and are differently recognized.     

A present-day aminoacyl-tRNA synthetase with ancestral editing properties

Leucyl-, isoleucyl-, and valyl-tRNA synthetases form a subgroup of related aminoacyl-tRNA synthetases that attach similar amino acids to their cognate tRNAs. To prevent amino acid misincorporation during translation, these enzymes also hydrolyze mischarged tRNAs through a post-transfer editing mechanism. Here we show that LeuRS from the deep-branching bacterium Aquifex aeolicus edits the complete set of aminoacylated tRNAs generated by the three enzymes: Ile-tRNA(Ile), Val-tRNA(Ile), Val-tRNA(Val), Thr-tRNA(Val), and Ile-tRNA(Leu). This unusual enlarged editing property was studied in a model of a primitive editing system containing a composite minihelix carrying the triple leucine, isoleucine, and valine identity mimicking the primitive tRNA precursor. We found that the freestanding LeuRS editing domain can edit this precursor in contrast to IleRS and ValRS editing domains. These results suggest that A. aeolicus LeuRS carries editing properties that seem more primitive than those of IleRS and ValRS. They suggest that the A. aeolicus editing domain has preserved the ambiguous editing property from the ancestral common editing domain or, alternatively, that this plasticity results from a specific metabolic adaptation.     

The C-terminal domain of the archaeal leucyl-tRNA synthetase prevents misediting of isoleucyl-tRNA(Ile)

In the archaeal leucyl-tRNA synthetase (LeuRS), the C-terminal domain recognizes the long variable arm of tRNA(Leu) for aminoacylation, and the so-called editing domain deacylates incorrectly formed Ile-tRNA(Leu). We previously reported, for Pyrococcus horikoshii LeuRS, that a deletion mutant lacking the C-terminal domain (LeuRS_delta(811-967)) retains normal editing activity, but has severely reduced aminoacylation activity. In this study, we found that LeuRS_delta(811-967), but not the wild-type LeuRS, exhibited surprisingly robust deacylation activity against Ile-tRNA(Ile), correctly formed by isoleucyl-tRNA synthetase ("misediting"). Structural superposition of tRNA(Ile) onto the LeuRS x tRNA(Leu) complex indicated that Ile911, Lys912, and Glu913 of the LeuRS C-terminal domain clash with U20 of tRNA(Ile), which is bulged out as compared to the corresponding nucleotide of tRNA(Leu). The deletion of amino acid residues 911-913 of LeuRS enhanced the Ile-tRNA(Ile) deacylation activity, without affecting the Ile-tRNA(Leu) deacylation activity. These results demonstrate that the clashing between U20 of tRNA(Ile) and residues 911-913 of the LeuRS C-terminal domain is the structural mechanism that prevents misediting. In contrast, the deletion of the C-terminal domains of the isoleucyl- and valyl-tRNA synthetases impaired both the aminoacylation (Ile-tRNA(Ile) and Val-tRNA(Val) formation, respectively) and editing (Val-tRNA(Ile) and Thr-tRNA(Val) deacylation, respectively) activities, and did not cause misediting (Val-tRNA(Val) and Thr-tRNA(Thr) deacylation, respectively) activity. Thus, the requirement of the C-terminal domain for misediting prevention is unique to LeuRS, which does not recognize the anticodon of the cognate tRNA, unlike the common aminoacyl-tRNA synthetases.     

Increase in fidelity of rat liver Ile-tRNA formation by both spermine and the aminoacyl-tRNA synthetase complex

To examine the polyamine effects on the fidelity at the aminoacylation level and the physiological significance of the existence of the aminoacyl-tRNA synthetase complex (ARSC) in animal cells, a single-chain Ile-tRNA synthetase (IRSS) was isolated from the complex by treatment with trypsin. Ile-tRNA formation by IRSS was strongly stimulated by spermine, similar to the results with ARSC. Two misacylations (Val-tRNAIle and Ile-tRNAiMet formation) by IRSS were measured. The error frequency was higher in Ile-tRNAiMet formation (tRNA misacylation) than in Val-tRNAIle formation (amino acid misacylation). Spermine did not influence significantly Ile-tRNAiMet formation, but it stimulated Val-tRNAIle formation by IRSS. Accordingly, spermine decreased the error frequency of tRNA misacylation, but not amino acid misacylation. These results suggest that the conformational changes of individual tRNA by spermine differ from each other, meaning that spermine influences the interaction between individual tRNA and aminoacyl-tRNA synthetase variously. When the aminoacylations of tRNAIle from rat liver, yeast, and Escherichia coli were compared with ARSC and IRSS, the relative speed of Ile-tRNA formation with tRNAIle from other species was faster with IRSS than with ARSC. This indicates that ARSC can recognize tRNAIle from the same species more specifically than IRSS. These results show that both spermine and ARSC are involved in the increase of fidelity of rat liver Ile-tRNA formation.     

Selective structural change by spermidine in the bulged-out region of double-stranded RNA and its effect on RNA function

Polyamines play important roles in cell growth mainly through their interaction with RNA. We have previously reported that polyamines stimulate the synthesis of oligopeptide-binding protein OppA in Escherichia coli and the formation of Ile-tRNA in rat liver (Igarashi, K., and Kashiwagi, K. (2000) Biochem. Biophys. Res. Commun. 271, 559-564). These effects involve an interaction of polyamines with the bulged-out region of double-stranded RNA in the initiation region of OppA mRNA and in the acceptor stem of rat liver tRNA(Ile). In this study, the effects of polyamines on E. coli OppA synthesis and rat liver Ile-tRNA formation were compared using OppA mRNA and tRNA(Ile) with or without the bulged-out region of double-stranded RNA. The results indicate that the bulged-out region is involved in polyamine stimulation of OppA synthesis and Ile-tRNA formation. A selective structural change by spermidine in the bulged-out region of double-stranded RNA was confirmed by circular dichroism.     

Interaction of pseudomonic acid A with Escherichia coli B isoleucyl-tRNA synthetase.

Sodium pseudomonate was shown to be a powerful competitive inhibitor of Escherichia coli B isoleucyl-tRNA synthetase (Ile-tRNA synthetase). The antibiotic competitively inhibits (Ki 6 nM; cf. Km 6.3 microM), with respect top isoleucine, the formation of the enzyme . Ile approximately AMP complex as measured by the pyrophosphate-exchange reaction, and has no effect on the transfer of [14C]isoleucine from the enzyme . [14C]Ile approximately AMP complex to tRNAIle. The inhibitory constant for the pyrophosphate-exchange reaction was of the same order as that determined for the inhibition of the overall aminoacylation reaction (Ki 2.5 nM; cf. Km 11.1 microM). Sodium [9'-3H]pseudomonate forms a stable complex with Ile-tRNA synthetase. Gel-filtration and gel-electrophoresis studies showed that the antibiotic is only fully released from the complex by 5 M-urea treatment or boiling in 0.1% sodium dodecyl sulphate. The molar binding ratio of sodium [9'-3H]pseudomonate to Ile-tRNA synthetase was found to be 0.85:1 by equilibrium dialysis. Aminoacylation of yeast tRNAIle by rat liver Ile-tRNA synthetase was also competitively inhibited with respect to isoleucine, Ki 20 microM (cf. Km 5.4 microM). The Km values for the rat liver and E. coli B enzymes were of the same order, but the Ki for the rat liver enzyme was 8000 times the Ki for the E. coli B enzyme. This presumably explains the low toxicity of the antibiotic in mammals.