Protein splicing of the three Pyrococcus abyssi ribonucleotide reductase inteins

An intein is a polypeptide that interrupts the functional domains of a protein, called the exteins. The intein can facilitate its own excision from the exteins, concomitant with the ligation of the exteins, in a process called protein splicing. The alpha subunit of the ribonucleotide reductase of the extreme thermophile Pyrococcus abyssi is interrupted by three inteins in separate insertion sites. Each intein can facilitate protein splicing when over-expressed in Escherichia coli, with affinity domains serving as the exteins. The influence of the N-terminal flanking residue on the efficiency of splicing is specific to each intein. Each intein has a different downstream nucleophilic residue, and cannot tolerate substitution to a residue of lesser or equal nucleophilicity. The influence of the conserved penultimate His also differs between the inteins.     

Inteins, valuable genetic elements in molecular biology and biotechnology

Inteins are internal protein elements that self-excise from their host protein and catalyze ligation of the flanking sequences (exteins) with a peptide bond. They are found in organisms in all three domains of life, and in viral proteins. Intein excision is a posttranslational process that does not require auxiliary enzymes or cofactors. This self-excision process is called protein splicing, by analogy to the splicing of RNA introns from pre-mRNA. Protein splicing involves only four intramolecular reactions, and a small number of key catalytic residues in the intein and exteins. Protein-splicing can also occur in trans. In this case, the intein is separated into N- and C-terminal domains, which are synthesized as separate components, each joined to an extein. The intein domains reassemble and link the joined exteins into a single functional protein. Understanding the cis- and trans-protein splicing mechanisms led to the development of intein-mediated protein-engineering applications, such as protein purification, ligation, cyclization, and selenoprotein production. This review summarizes the catalytic activities and structures of inteins, and focuses on the advantages of some recent intein applications in molecular biology and biotechnology.     

Minimization of a eukaryotic mini-intein

Inteins are internal protein splicing elements that can autocatalytically self-excise from their host protein and ligate the protein flanks (exteins) with a peptide bond. Large inteins comprise independent protein splicing and endonuclease domains whereas mini-inteins lack the central endonuclease domain. To identify mini-intein domains that are essential for protein splicing, deletions were introduced at different sites of the 157-aa PRP8 mini-intein of Penicillium chrysogenum. The removal of eight and six amino acids at two different sites resulted in a functional eukaryotic mini-intein of only 143 aa.     

Engineering artificially split inteins for applications in protein chemistry: biochemical characterization of the split Ssp DnaB intein and comparison to the split Sce VMA intein

In protein trans-splicing, an intein domain split into two polypeptide chains mediates linkage of the flanking amino acid sequences, the N- and C-terminal exteins, with a native peptide bond. This process can be exploited to assemble proteins from two separately prepared fragments, e.g., for the segmental labeling with isotopes for NMR studies or the incorporation of chemical and biophysical probes. Split inteins can be artificially generated by genetic means; however, the purified inteinN and inteinC fragments usually require a denaturation and renaturation treatment to fold into the active intein, thus preventing their application to proteins that cannot be refolded. Here, we report that the purified fragments of the artificially split DnaB helicase of Synechocystis spp. PCC6803 (Ssp DnaB) intein are active under native conditions. The first-order rate constant of the protein trans-splicing reaction was 7.1 x 10(-4) s(-1). The previously described split vacuolar ATPase of Saccharomyces cerevisiae (Sce VMA) intein is the only other artificially split intein that is active under native conditions; however, it requires induced complex formation of the intein fragments by auxiliary dimerization domains for efficient protein trans-splicing. In contrast, fusion of the dimerization domains to the split Ssp DnaB intein fragments had no effect on activity. This difference was also reflected by a higher thermostability of the split Ssp DnaB intein. Further investigations of the split Sce VMA intein under optimized conditions revealed a first-order rate constant of 9.4 x 10(-4) s(-1) for protein trans-splicing and 1.7 x 10(-3) s(-1) for C-terminal cleavage involving a Cys1Ala mutant. Finally, we show that the two split inteins are orthogonal, suggesting further applications for the assembly of proteins from more than two parts.     

Synthetic two-piece and three-piece split inteins for protein trans-splicing

Inteins are protein-intervening sequences that can self-excise and concomitantly splice together the flanking polypeptides. Two-piece split inteins capable of protein trans-splicing have been found in nature and engineered in laboratories, but they all have a similar split site corresponding to the endonuclease domain of the intein. Can inteins be split at other sites and do trans-splicing? After testing 13 split sites engineered into a Ssp DnaB mini-intein, we report the finding of three new split sites that each produced a two-piece split intein capable of protein trans-splicing. These three functional split sites are located in different loop regions between beta-strands of the intein structure, and one of them is just 11 amino acids from the beginning of the intein. Because different inteins have similar structures and similar beta-strands, these new split sites may be generalized to other inteins. We have also demonstrated for the first time that a three-piece split intein could function in protein trans-splicing. These findings have implications for intein structure-function, evolution, and uses in biotechnology.     

Highly efficient protein trans-splicing by a naturally split DnaE intein from Nostoc punctiforme

Protein trans-splicing by the naturally split intein of the gene dnaE from Nostoc punctiforme (Npu DnaE) was demonstrated here with non-native exteins in Escherichia coli. Npu DnaE possesses robust trans-splicing activity with an efficiency of > 98%, which is superior to that of the DnaE intein from Synechocystis sp. strain PCC6803 (Ssp DnaE). Both the N- and C-terminal parts of the split Npu DnaE intein can be substituted with the corresponding fragment of Ssp DnaE without loss of trans-splicing activity. Protein splicing with the Npu DnaEN is also more tolerant of amino acid substitutions in the C-terminal extein sequence.     

Highly efficient and more general cis- and trans-splicing inteins through sequential directed evolution

Inteins are internal protein sequences that post-translationally self-excise and splice together the flanking sequences, the so-called exteins. Natural and engineered inteins have been used in many practical applications. However, inteins are often inefficient or inactive when placed in a non-native host protein and may require the presence of several amino acid residues of the native exteins, which will then remain as a potential scar in the spliced protein. Thus, more general inteins that overcome these limitations are highly desirable. Here we report sequential directed evolution as a new approach to produce inteins with such properties. Random mutants of the Ssp (Synechocystis sp. PCC 6803) DnaB mini-intein were inserted into the protein conferring kanamycin resistance at a site where the parent intein was inactive for splicing. The mutants selected for splicing activity were further improved by iterating the procedure for two more cycles at different positions in the same protein. The resulting improved inteins showed high activity in the positions of the first rounds of selection, in multiple new insertion sites, and in different proteins. One of these inteins, the M86 mutant, which accumulated 8 amino acid substitutions, was also biochemically characterized in an artificially split form with a chemically synthesized N-terminal intein fragment consisting of 11 amino acids. When compared with the unevolved split intein, it exhibited an ～60-fold increased rate in the protein trans-splicing reaction and a K(d) value for the interaction of the split intein fragments improved by an order of magnitude. Implications on the intein structure-function, practical application, and evolution are discussed.     

蛋白质剪接研究进展

蛋白质剪接是一个翻译后自催化加工过程,它不需要酶或其他辅助因子的参与。在这个过程中,前体蛋白的Intein(内含肽)被切离,其两侧的Extein(外显肽)连接在一起。Intein按结构可分为经典Intein和微型Intein,其中的经典Intein包括Hint结构域和中间的归巢内切酶结构域(该结构域在微型内含肽中不存在)。蛋白质剪接及其他具有Hint结构域的蛋白加工过程的起始步骤是N-S/O酰基重排反应,该反应是由Hint结构域催化的;Intein的剪接还分为顺式剪接和反式剪接,通过对Intein进行改造,可以阻断剪接过程,但不影响N端肽键或C端肽键的断裂;通过筛选突变体,可以获得温度敏感型、pH敏感型或小分子诱导型的内含肽。这些研究促进了Intein在多肽制备及其它方面的应用。     

Circular permutation prediction reveals a viable backbone disconnection for split proteins: an approach in identifying a new functional split intein

Split-protein systems have emerged as a powerful tool for detecting biomolecular interactions and reporting biological reactions. However, reliable methods for identifying viable split sites are still unavailable. In this study, we demonstrated the feasibility that valid circular permutation (CP) sites in proteins have the potential to act as split sites and that CP prediction can be used to search for internal permissive sites for creating new split proteins. Using a protein ligase, intein, as a model, CP predictor facilitated the creation of circular permutants in which backbone opening imposes the least detrimental effects on intein folding. We screened a series of predicted intein CPs and identified stable and native-fold CPs. When the valid CP sites were introduced as split sites, there was a reduction in folding enthalpy caused by the new backbone opening; however, the coincident loss in entropy was sufficient to be compensated, yielding a favorable free energy for self-association. Since split intein is exploited in protein semi-synthesis, we tested the related protein trans-splicing (PTS) activities of the corresponding split inteins. Notably, a novel functional split intein composed of the N-terminal 36 residues combined with the remaining C-terminal fragment was identified. Its PTS activity was shown to be better than current reported two-piece intein with a short N-terminal segment. Thus, the incorporation of in silico CP prediction facilitated the design of split intein as well as circular permutants.     

Functional analysis of the split Synechocystis DnaE intein in plant tissues by biolistic particle bombardment

The DnaE intein of Synechocystis sp. PCC6803 (Ssp DnaE intein) is the first split intein identified in nature. Its N-terminal fragment (Int-n) is attached to the end of the N-terminal half of the DnaE protein (DnaE-n) to form the precursor DnaE-n/Int-n, while the C-terminal fragment (Int-c) precedes the C-terminal half of the DnaE protein (DnaE-c) to form the precursor Int-c/DnaE-c. Int-n and Int-c fragments in the separate precursors catalyze, in concert, a protein trans-splicing process to splice the flanking DnaE-n and DnaE-c into a functional catalytic subunit of DNA polymerase III. They then release themselves from the precursors. Previously, the Ssp DnaE intein has been used to reconstitute a protein trans-splicing mechanism in stably transformed Arabidopsis thaliana, resulting in successful reassembly of an intact and functional GUS from two halves of a split GUS protein. In this report, transient expression using a biolistic particle bombardment approach is described for functional analysis of Ssp DnaE intein. Analyses confirmed that the Ssp DnaE intein could catalyze protein trans-splicing not only in model plants but also in monocot and dicot crops. It also demonstrated that when up to 45 amino acid residues were removed from the C-terminus of the Int-n fragment, the Int-n fragment was still able to function in the protein trans-splicing process.     

断裂蛋白质内含子的剪接机制、起源和进化

蛋白质内含子(intein)是具有自我催化活性的蛋白质. 翻译后,通过蛋白质剪接从蛋白质前体中去掉,并以肽键连接两侧蛋白质外显子(extein)形成成熟蛋白质. 断裂蛋白质内含子(split intein)在蛋白质内含子中部区域特定位点发生断裂,形成N端片段和C端片段,分别由基因组上相距较远的两个基因编码. 现在已知,它仅分布于蓝细菌和古细菌中. 断裂蛋白质内含子的N端片段和C端片段通过非共价键(如静电作用)相互识别,重建催化活性中心,介导蛋白质反式剪接. 断裂蛋白质内含子的发现进一步深化了人们对基因表达和蛋白质翻译后成熟过程复杂性的认识,而且它在蛋白质工程、蛋白质药物开发和蛋白质结构与功能研究等方面有非常广泛的应用. 本文试图综述断裂蛋白质内含子的分布、结构特征和剪接机制,并分析其可能的起源和进化途径.     

An intein-cassette integration approach used for the generation of a split TEV protease activated by conditional protein splicing

Ligand-induced conditional protein splicing (CPS) using a split intein allows the covalent reconstitution of a protein from two polypeptide fragments. The small molecule rapamycin binds to the fused FKBP and FRB dimerizer domains and thereby induces folding of the split intein, which then removes itself in the trans-splicing reaction. CPS has great potential for the experimental control of protein activity in living cells, however, only one such example was reported yet. This discrepancy is due to the challenging reconstitution of a protein from two inactive fragments because of folding, stability, and solubility issues. Moreover, in CPS the split intein must be active in the specific sequence context. We here report the novel concept, design, and application of a CPS cassette for facile target gene modification to identify active split intein insertion sites. The CPS cassette encodes the split intein and dimerizer domain gene fragments as well as a selectable genetic marker for yeast. The addition of short sequences in the PCR-amplification of the CPS cassette allowed its site-specific insertion into the target gene by homologous recombination. Our approach thus avoids the extensive DNA cloning steps typically required. By this strategy, we identified two CPS variants of the tobacco etch virus (TEV) protease that are conditionally activated by rapamycin in yeast and we show their potential for the manipulation of intracellular proteins through proteolysis events. Our results suggest that more proteins will be amenable to CPS control and that intein cassette integration is a powerful tool for the development of such conditional variants as well as for other application of cis- and trans-splicing inteins.     

异源生物中筛选高剪接活性Intein系统的建立

原始物种体内蛋白质内含子（intein）介导的自催化蛋白剪接反应以100%效率进行.当这些蛋白质内含子被克隆入异源物种时,其剪接效率往往大大降低,绝大多数甚至完全失去剪接能力.本研究根据蛋白质内含子剪接活性与蛋白质外显子（extein）C端第1个保守氨基酸直接相关的特点,设计含有所有这些保守氨基酸的多个短的蛋白质外显子序列,通过PCR引入到卡那霉素抗性蛋白（KanR）的不同位点中,在此外显子中克隆入相应的蛋白质内含子,构建在大肠杆菌中依赖卡那霉素抗性来筛选高剪接活性蛋白质内含子的系统.结果显示,卡那霉素平板上菌落生长的结果与Western印迹检测的结果基本一致.说明建立的筛选高剪接活性蛋白质内含子系统成功.这种含有可选择蛋白质外显子的筛选系统,将蛋白质剪接与卡那霉素抗性相结合,直接从平板上观测剪接结果,成为快速、稳定筛选在异源物种中具有剪接活性蛋白内含子的新手段.     

DNA展示系统介导的断裂蛋白质内含子体外定向进化方法的研究

蛋白质内含子对于外显子的选择性限制了它的应用范围。目前,已经建立的卡那霉素定向进化系统适用于微小蛋白质内含子,但不适用于断裂蛋白质内含子。为了研究适用于断裂蛋白质内含子的定向进化的方法,我们引入了DNA展示系统。在该系统中,生物素化基因在人工细胞中与其表达的融合蛋白（内含子C端-外显子-生物素结合蛋白）形成DNA 蛋白质连接体。只有能与后续加入的N端蛋白质内含子前体（Flag-内含子N端）发生剪接反应的DNA 蛋白质连接体,才能被加上旗帜标签（Flag）,从而被抗旗帜标签抗体纯化柱（Anti Flag antibody M2 agarose）筛选富集。为了验证该系统的可行性,实验构建了2个基因,即含有具剪接活性的蛋白质内含子的阳性基因IRC和含有不具剪接活性的蛋白质内含子的阴性基因IRCM。实验首先通过Western印迹和琼脂糖凝胶电泳证明,人工细胞中的体外转录翻译系统不仅可高表达500个氨基酸的蛋白质,而且表达的蛋白中内含子仍保持原有的剪接能力。生物素结合蛋白能结合95%的DNA,并且形成的DNA 蛋白质连接体可以被筛选富集,最终证明了该系统用于断裂蛋白质内含子定向进化筛选的可行性。随后,为了检测系统的富集效率,制备了人为的基因“突变库”,即将基因IRC和IRCM以摩尔比1:10的比例混合,经过2轮筛选后,阳性基因IRC可以被10倍富集,进一步证明了体外筛选方法的可行性。该方法为后续针对不同宿主进化出不同的断裂蛋白质内含子提供筛选方法支持,也为断裂蛋白质内含子的在生物技术和研究领域的应用奠定了基础。     

Protein trans-splicing and cyclization by a naturally split intein from the dnaE gene of Synechocystis species PCC6803

A naturally occurring split intein from the dnaE gene of Synechocystis sp. PCC6803 (Ssp DnaE intein) has been shown to mediate efficient in vivo and in vitro trans-splicing in a foreign protein context. A cis-splicing Ssp DnaE intein construct displayed splicing activity similar to the trans-splicing form, which suggests that the N- and C-terminal intein fragments have a high affinity interaction. An in vitro trans-splicing system was developed that used a bacterially expressed N-terminal fragment of the Ssp DnaE intein and either a bacterially expressed or chemically synthesized intein C-terminal fragment. Unlike artificially split inteins, the Ssp DnaE intein fragments could be reconstituted in vitro under native conditions to mediate splicing as well as peptide bond cleavage. This property allowed the development of an on-column trans-splicing system that permitted the facile separation of reactants and products. Furthermore, the trans-splicing activity of the Ssp DnaE intein was successfully applied to the cyclization of proteins in vivo. Also, the isolation of the unspliced precursor on chitin resin allowed the cyclization reaction to proceed in vitro. The Ssp DnaE intein thus represents a potentially important protein for in vivo and in vitro protein manipulation.     

NMR and crystal structures of the Pyrococcus horikoshii RadA intein guide a strategy for engineering a highly efficient and promiscuous intein

In protein splicing, an intervening protein sequence (intein) in the host protein excises itself out and ligates two split host protein sequences (exteins) to produce a mature host protein. Inteins require the involvement for the splicing of the first residue of the extein that follows the intein (which is Cys, Ser, or Thr). Other extein residues near the splicing junctions could modulate splicing efficiency even when they are not directly involved in catalysis. Mutual interdependence between this molecular parasite (intein) and its host protein (exteins) is not beneficial for intein spread but could be advantageous for intein survival during evolution. Elucidating extein-intein dependency has increasingly become important since inteins are recognized as useful biotechnological tools for protein ligation. We determined the structures of one of inteins with high splicing efficiency, the RadA intein from Pyrococcus horikoshii (PhoRadA). The solution NMR structure and the crystal structures elucidated the structural basis for its high efficiency and directed our efforts of engineering that led to rational design of a functional minimized RadA intein. The crystal structure of the minimized RadA intein also revealed the precise interactions between N-extein and the intein. We systematically analyzed the effects at the -1 position of N-extein and were able to significantly improve the splicing efficiency of a less robust splicing variant by eliminating the unfavorable extein-intein interactions observed in the structure. This work provides an example of how unveiling structure-function relationships of inteins offer a promising way of improving their properties as better tools for protein engineering.     

NMR structure of a KlbA intein precursor from Methanococcus jannaschii

Certain proteins of unicellular organisms are translated as precursor polypeptides containing inteins (intervening proteins), which are domains capable of performing protein splicing. These domains, in conjunction with a single residue following the intein, catalyze their own excision from the surrounding protein (extein) in a multistep reaction involving the cleavage of two intein-extein peptide bonds and the formation of a new peptide bond that ligates the two exteins to yield the mature protein. We report here the solution NMR structure of a 186-residue precursor of the KlbA intein from Methanococcus jannaschii, comprising the intein together with N- and C-extein segments of 7 and 11 residues, respectively. The intein is shown to adopt a single, well-defined globular domain, representing a HINT (Hedgehog/Intein)-type topology. Fourteen beta-strands are arranged in a complex fold that includes four beta-hairpins and an antiparallel beta-ribbon, and there is one alpha-helix, which is packed against the beta-ribbon, and one turn of 3(10)-helix in the loop between the beta-strands 8 and 9. The two extein segments show increased disorder, and form only minimal nonbonding contacts with the intein domain. Structure-based mutation experiments resulted in a proposal for functional roles of individual residues in the intein catalytic mechanism.     

Reversible inhibition of protein splicing by zinc ion

Protein splicing involves the self-catalyzed excision of a protein-splicing element, the intein, from flanking polypeptides, the exteins, which are concomitantly joined by a peptide bond. Taking advantage of recently developed in vitro systems in which protein splicing occurs in trans to assay for protein-splicing inhibitors, we discovered that low concentrations of Zn(2+) inhibited splicing mediated both by the RecA intein from Mycobacterium tuberculosis and by the naturally split DnaE intein from Synechocystis sp. PCC6803. Inhibition by Zn(2+) was also observed with a cis-splicing system involving the RecA intein. In all experimental systems used, inhibition by Zn(2+) could be completely reversed by the addition of EDTA. Zinc ion also inhibited hydroxylamine-dependent N-terminal cleavage of the RecA intein. All other divalent transition metal ions tested were less effective as inhibitors than Zn(2+). The reversible inhibition by Zn(2+) should be useful in studies of the mechanism of protein splicing and allow structural studies of unmodified protein-splicing precursors.     

Preceding hydrophobic and beta-branched amino acids attenuate splicing by the CnePRP8 intein

As the Cne PRP8 intein is active and exists in an essential gene of an important fungal pathogen, inhibitors of splicing and assays for intein activity are of interest. The self-splicing activity of Cne PRP8, the intein from the Prp8 gene of Cryptococcus neoformans, was assessed in different heterologous fusion proteins expressed in Escherichia coli. Placement of a putatively inactive variant of the intein adjacent to the alpha-complementation peptide abolished the peptide's ability to restore beta-galactosidase activity, while an active variant allowed complementation. This alpha-complementation peptide therefore provides a facile assay of splicing which can be used to test potential inhibitors. When placed between two heterologous protein domains, splicing was impaired by a beta-branched amino acid immediately preceding the intein, while splicing occurred only with a hydroxyl or thiol immediately following the intein. Both these assays sensitively report impairment of splicing and provide information on how context constrains the splicing ability of Cne PRP8.     

Post-translational environmental switch of RadA activity by extein–intein interactions in protein splicing

Post-translational control based on an environmentally sensitive intervening intein sequence is described. Inteins are invasive genetic elements that self-splice at the protein level from the flanking host protein, the exteins. Here we show in Escherichia coli and in vitro that splicing of the RadA intein located in the ATPase domain of the hyperthermophilic archaeon Pyrococcus horikoshii is strongly regulated by the native exteins, which lock the intein in an inactive state. High temperature or solution conditions can unlock the intein for full activity, as can remote extein point mutations. Notably, this splicing trap occurs through interactions between distant residues in the native exteins and the intein, in three-dimensional space. The exteins might thereby serve as an environmental sensor, releasing the intein for full activity only at optimal growth conditions for the native organism, while sparing ATP consumption under conditions of cold-shock. This partnership between the intein and its exteins, which implies coevolution of the parasitic intein and its host protein may provide a novel means of post-translational control.