Intein harbouring large tandem repeats in replicative DNA helicase of Trichodesmium erythraeum

Protein splicing inteins can be small as approximately 130 aa or up to approximately 600 aa when harbouring an endonuclease domain. Here we report the identification and characterization of an unusually large intein, 1650 aa long and the largest of known inteins, encoded by the replicative DNA helicase gene dnaB of the oceanic N2-fixing cyanobacterium Trichodesmium erythraeum. This Ter DnaB-1 intein co-exists with a 177-aa mini-intein in the same host protein and harbours large tandem repeats in which an 84-aa sequence is repeated 16 times. Comparison between this tandem repeats and the recently reported tandem repeats of Ter DnaE-1 intein revealed differences and similarities. The two tandem repeats, residing in different inteins of different host proteins, differ by 50% in size and have little sequence similarity. Tandem repeats in the Ter DnaB-1 intein were required for the protein splicing activity when tested in Escherichia coli, in contrast to tandem repeats of the Ter DnaE-1 intein that inhibited protein splicing. On the other hand, tandem repeats of both inteins are located in the same corresponding region of the intein sequence and have the same number of repeating units. These suggest that the two tandem repeats could be related but have diverged greatly in size, sequence and effect on protein splicing. Alternatively, they could have independent origins but evolved certain similarities because of common constraints in structure and maintenance.     

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.     

Distribution of split DnaE inteins in cyanobacteria

Inteins are genetic elements found inside the coding regions of different host proteins and are translated in frame with them. The intein-encoded protein region is removed by an autocatalytic protein-splicing reaction that ligates the host protein flanks with a peptide bond. This reaction can also occur in trans with the intein and host protein split in two. After translation of the two genes, the two intein parts ligate their flanking protein parts to each other, producing the mature protein. Naturally split inteins are only known in the DNA polymerase III alpha subunit (polC or dnaE gene) of a few cyanobacteria. Analysing the phylogenetic distribution and probable genetic propagation mode of these split inteins, we conclude that they are genetically fixed in several large cyanobacterial lineages. To test our hypothesis, we sequenced parts of the dnaE genes from five diverse cyanobacteria and found all species to have the same type of split intein. Our results suggest the occurrence of a genetic rearrangement in the ancestor of a large division of cyanobacteria. This event fixed the dnaE gene in a unique two-genes one-protein configuration in the progenitor of many cyanobacteria. Our hypothesis, findings and the cloning procedure that we established allow the identification and acquisition of many naturally split inteins. Having a large and diverse repertoire of these unique inteins will enable studies of their distinct activity and enhance their use in biotechnology.     

Crystal structures of an intein from the split dnaE gene of Synechocystis sp. PCC6803 reveal the catalytic model without the penultimate histidine and the mechanism of zinc ion inhibition of protein splicing

The first naturally occurring split intein was found in the dnaE gene of Synechocystis sp. PCC6803 and belongs to a subclass of inteins without a penultimate histidine residue. We describe two high-resolution crystal structures, one derived from an excised Ssp DnaE intein and the second from a splicing-deficient precursor protein. The X-ray structures indicate that His147 in the conserved block F activates the side-chain N(delta) atom of the intein C-terminal Asn159, leading to a nucleophilic attack on the peptide bond carbonyl carbon atom at the C-terminal splice site. In this process, Arg73 appears to stabilize the transition state by interacting with the carbonyl oxygen atom of the scissile bond. Arg73 also seems to substitute for the conserved penultimate histidine residue in the formation of an oxyanion hole, as previously identified in other inteins. The finding that the precursor structure contains a zinc ion chelating the highly conserved Cys160 and Asp140 reveals the structural basis of Zn2+-mediated inhibition of protein splicing. Furthermore, it is of interest to observe that the carbonyl carbon atom of Asn159 and N(eta) of Arg73 are 2.6 angstroms apart in the free intein structure and 10.6 angstroms apart in the precursor structure. The orientation change of the aromatic ring of Tyr-1 following the initial acyl shift may be a key switching event contributing to the alignment of Arg73 and the C-terminal scissile bond, and may explain the sequential reaction property of the Ssp DnaE intein.     

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.     

Mutational analysis of protein splicing, cleavage, and self-association reactions mediated by the naturally split Ssp DnaE intein

The ability to separately purify the naturally split Synechocystis sp. PCC6803 (Ssp) DnaE intein domains has allowed detailed examination of both universal and Ssp DnaE intein-specific steps in the protein splicing pathway. By engineering substitutions at both the +1 and penultimate intein positions, we have further characterized intein reaction kinetics in this system. Replacement of the crucial +1Cys with serine decreased N-terminal cleavage and trans-splicing rates; however, this substitution did not prevent splicing or the ability of ZnCl2 to inhibit it. Substitution of the penultimate intein residue (alanine) with a typically conserved histidine did not increase the rate or extent of trans-splicing or cleavage under typical assay conditions. Despite the observation that this histidine aids in asparagine cyclization for other inteins, it did not encourage C-terminal cleavage for the Ssp DnaE intein or uncouple it from N-terminal cleavage. Both the +1Ser and Ala to His mutants were insensitive to ZnCl2 during trans-cleavage experiments, uncoupling a previously linked inhibition in asparagine cyclization from an inhibition in trans-thioesterification detected for the wild-type intein.     

Unprecedented rates and efficiencies revealed for new natural split inteins from metagenomic sources

Inteins excise themselves out of precursor proteins by the protein splicing reaction and have emerged as valuable protein engineering tools in numerous and diverse biotechnological applications. Split inteins have recently attracted particular interest because of the opportunities associated with generating a protein from two separate polypeptides and with trans-cleavage applications made possible by split intein mutants. However, natural split inteins are rare and differ greatly in their usefulness with regard to the achievable rates and yields. Here we report the first functional characterization of new split inteins previously identified by bioinformatics from metagenomic sources. The N- and C-terminal fragments of the four inteins gp41-1, gp41-8, NrdJ-1, and IMPDH-1 were prepared as fusion constructs with model proteins. Upon incubation of complementary pairs, we observed trans-splicing reactions with unprecedented rates and yields for all four inteins. Furthermore, no side reactions were detectable, and the precursor constructs were consumed virtually quantitatively. The rate for the gp41-1 intein, the most active intein on all accounts, was k = 1.8 ± 0.5 × 10(-1) s(-1), which is ～10-fold faster than the rate reported for the Npu DnaE intein and gives rise to completed reactions within 20-30 s. No cross-reactivity in exogenous combinations was observed. Using C1A mutants, all inteins were efficient in the C-terminal cleavage reaction, albeit at lower rates. C-terminal cleavage could be performed under a wide range of reaction conditions and also in the absence of native extein residues flanking the intein. Thus, these inteins hold great potential for splicing and cleavage applications.     

NMR resonance assignment of DnaE intein from Nostoc punctiforme

DnaE intein from Nostoc punctiforme (Npu) is one of naturally occurring split inteins, which has robust protein splicing activity. Highly efficient trans-splicing activity of NpuDnaE intein could widen various biotechnological applications. However, structural basis of the efficient protein splicing activity is poorly understood. As a first step toward better understanding of protein trans-splicing mechanism, we present the backbone and side-chain resonance assignments of a single chain variant NpuDnaE intein as determined by triple resonance experiments with [¹³C,¹⁵N]-labeled protein.     

Evaluation and comparison of protein splicing by exogenous inteins with foreign exteins in Escherichia coli

Protein splicing catalyzed by inteins has enabled various biotechnological applications such as protein ligation. Successful applications of inteins are often limited by splicing efficiency. Here, we report the comparison of protein splicing between 20 different inteins from various organisms in identical contexts to identify robust inteins with foreign exteins. We found that RadA intein from Pyrococcus horikoshii and an engineered DnaB intein from Nostoc punctiforme demonstrated an equally efficient splicing activity to the previously reported highly efficient DnaE intein from Nostoc punctiforme. The newly identified inteins with efficient cis-splicing activity can be good starting points for the further development of new protein engineering tools.     

Traceless Splicing Enabled by Substrate-Induced Activation of the Nostoc punctiforme Npu DnaE Intein after Mutation of a Catalytic Cysteine to Serine

Inteins self-catalytically cleave out of precursor proteins while ligating the surrounding extein fragments with a native peptide bond. Much attention has been lavished on these molecular marvels with the hope of understanding and harnessing their chemistry for novel biochemical transformations including coupling peptides from synthetic or biological origins and controlling protein function. Despite an abundance of powerful applications, the use of inteins is still hampered by limitations in our understanding of their specificity (defined as flanking sequences that permit splicing) and the challenge of inserting inteins into target proteins. We examined the frequently used Nostoc punctiforme Npu DnaE intein after the C-extein cysteine nucleophile (Cys+1) was mutated to serine or threonine. Previous studies demonstrated reduced rates and/or splicing yields with the Npu DnaE intein after mutation of Cys+1 to Ser+1. In this study, genetic selection identified extein sequences with Ser+1 that enabled the Npu DnaE intein to splice with only a 5-fold reduction in rate compared to the wild-type Cys+1 intein and without mutation of the intein itself to activate Ser+1 as a nucleophile. Three different proteins spliced efficiently after insertion of the intein flanked by the selected sequences. We then used this selected specificity to achieve traceless splicing in a targeted enzyme at a location predicted by primary sequence similarity to only the selected C-extein sequence. This study highlights the latent catalytic potential of the Npu DnaE intein to splice with an alternative nucleophile and enables broader intein utility by increasing insertion site choices.     

Herbicide resistance from a divided EPSPS protein: the split Synechocystis DnaE intein as an in vivo affinity domain

We report that the N- and C-terminal splicing domains of the intein found in the dnaE gene of Synechocystis sp. PCC6803 (Ssp DnaE intein) are capable of association in vivo and in vitro, even with key splicing residues changed to alanine (Cys(1), Asn(159), and Cys(+1) to Ala). These studies utilized the herbicide resistant form of 5-enolpyruvylshikimate-3-phosphate synthase (EPSPS) from Salmonella typhimurium and an Escherichia coli strain with the EPSPS gene deleted from its genome (E. coli strain ER2799). EPSPS was mapped to identify potential split sites using a facile Tn7 linker scanning procedure. Forty positions were found to tolerate a five amino acid insertion while 21 sites did not, as assayed by the rescue of growth of E. coli strain ER2799. Further characterization of these sites by inserting a full length Ssp DnaE intein identified residue 235 of EPSPS as the optimal position. The EPSPS gene was then divided into amino acids 1-235 and 236-427 which were fused to residues 1-123 and 124-159 of a splicing defective Ssp DnaE intein, respectively. Expression of the EPSPS-intein fusions from separate DNA molecules conferred resistance to the herbicide glyphosate, indicating that the intein splicing domains were bringing the EPSPS fragments together to generate activity. As a control the split EPSPS without the intein-affinity domain did not allow cell growth. The use of an intein as an in vivo affinity domain was termed intein-mediated protein complementation (IPC). Intein fragment assembly was verified in vitro by immobilizing the C-terminal splicing domain of the Ssp DnaE intein on a resin and demonstrating that the N-terminal 235 amino acids of EPSPS only bound to the resin when fused to the N-terminal splicing domain of the Ssp DnaE intein. As chloroplast DNA is not transmitted by pollen in plants such as corn and soybean, transgene spread via pollen may be controlled in the future by expressing inactive gene fragments from separate DNA locations, such as the nuclear and chloroplast genome, and using the split intein to generate protein activity.     

多种S1断裂内含肽的体内交叉反应

断裂内含肽含有两个独立分离的多肽片段(N端内含肽和C端内含肽),它催化蛋白质反式剪接反应,在蛋白质研究与蛋白质工程中已得到诸多实际应用.在蛋白质反式剪接过程中,内含肽的N端内含肽和C端内含肽通过结构互补特异性地非共价组合.然而,Ssp DnaX S1型断裂内含肽的较大C端内含肽片段近来被发现能够与源自其它内含肽的N端内含肽片段交叉反应,表明蛋白质内含子Ssp DnaX具有结构杂交特征.本研究对另外2种S1型内含肽Rma DnaB和Ssp GyrB的较大C端内含肽与不同S1型断裂内含肽的N 端内含肽交叉反应活性进行分析检测.目的是探讨S1型断裂内含肽的结构杂交特征是否具有普遍性.结果发现,Rma DnaB的S1 C端内含肽能够与Ssp GyrB的S1 N端内含肽交叉反应,却不能与Ssp DnaX的S1 N端内含肽交叉反应;与此相似,Ssp GyrB的S1 C端内含肽能够与Rma DnaB的 S1 N端内含肽交叉反应,却不能与Ssp DnaX的S1 N端内含肽交叉反应.此外,某些交叉反应表现出温度依赖性.这些结果对于内含肽的结构 功能关系以及S1型断裂内含肽的应用研究具有重要的意义.     

Characterization of a naturally occurring trans-splicing intein from Synechocystis sp. PCC6803

A naturally occurring trans-splicing intein from the dnaE gene of Synechocystis sp. PCC6803 (Ssp DnaE intein) was used to characterize the intein-catalyzed splicing reaction. Trans-splicing/cleavage reactions were initiated by combining the N-terminal splicing domain of the Ssp DnaE intein containing five native N-extein residues and maltose binding protein as the N-extein with the C-terminal Ssp DnaE intein splicing domain (E(C)) with or without thioredoxin fused in-frame to its carboxy terminus. Observed rate constants (k(obs)) for dithiothreitol-induced N-terminal cleavage, C-terminal cleavage, and trans-splicing were (1.0 +/- 0.5) x 10(-3), (1.9 +/- 0.9) x 10(-4), and (6.6 +/- 1.3) x 10(-5) s(-1), respectively. Preincubation of the intein fragments showed no change in k(obs), indicating association of the two splicing domains is rapid relative to the subsequent steps. Interestingly, when E(C) concentrations were substoichiometric with respect to the N-terminal splicing domain, the levels of N-terminal cleavage were equivalent to the amount of E(C), even over a 24 h period. Activation energies for N-terminal cleavage and trans-splicing were determined by Arrhenius plots to be 12.5 and 8.9 kcal/mol, respectively. Trans-splicing occurred maximally at pH 7.0, while a slight increase in the extent of N-terminal cleavage was observed at higher pH values. This work describes an in-depth kinetic analysis of the splicing and cleavage activity of an intein, and provides insight for the use of the split intein as an affinity domain.     

Engineered Ssp DnaX inteins for protein splicing with flanking proline residues

Inteins are internal protein sequences capable of catalyzing a protein splicing reaction by self-excising from a precursor protein and simultaneously joining the flanking sequences with a peptide bond. Split inteins have separate pieces (N-intein and C-intein) that reassemble non-covalently to catalyze a protein trans-splicing reaction joining two polypeptides. Protein splicing has become increasingly useful tools in many fields of biological research and biotechnology. However, natural and engineered inteins have failed previously to function when being flanked by proline residue at the −1 or +2 positions, which limits general uses of inteins. In this study, different engineered inteins were tested. We found that engineered Ssp DnaX mini-intein and split inteins could carry out protein splicing with proline at the +2 positions or at both −1 and +2 positions. Under in vivo conditions in E. coli cells, the mini-intein, S1 split intein, and S11 split intein spliced efficiently, whereas the S0 split intein did not splice with proline at both −1 and +2 positions. The S1 and S11 split inteins also trans-spliced efficiently in vitro with proline at the +2 positions or at both −1 and +2 positions, but the S0 split intein trans-spliced inefficiently with proline at the +2 position and did not trans-splice with proline at both −1 and +2 positions. These findings contribute significantly to the toolbox of intein-based technologies by allowing the use of inteins in proteins having proline at the splicing point.     

An Engineered Split Intein for Photoactivated Protein Trans-Splicing

Protein splicing is mediated by inteins that auto-catalytically join two separated protein fragments with a peptide bond. Here we engineered a genetically encoded synthetic photoactivatable intein (named LOVInC), by using the light-sensitive LOV2 domain from Avena sativa as a switch to modulate the splicing activity of the split DnaE intein from Nostoc punctiforme. Periodic blue light illumination of LOVInC induced protein splicing activity in mammalian cells. To demonstrate the broad applicability of LOVInC, synthetic protein systems were engineered for the light-induced reassembly of several target proteins such as fluorescent protein markers, a dominant positive mutant of RhoA, caspase-7, and the genetically encoded Ca²⁺ indicator GCaMP2. Spatial precision of LOVInC was demonstrated by targeting activity to specific mammalian cells. Thus, LOVInC can serve as a general platform for engineering light-based control for modulating the activity of many different proteins.     

定向进化提高微小蛋白质内含子Ter DnaE-3 剪接活性的研究

目前,蛋白质内含子在蛋白质工程领域中得到越来越广泛的应用。为提高微小蛋白质内含子Ter DnaE-3(Trichodesmium erythraeum)在异源宿主中的剪接活性,采用易错PCR技术,通过改变反应体系中dNTP、Mg2+、Mn2+的浓度等手段,借助依赖卡那霉素的蛋白质内含子筛选系统进行筛选。Western印迹结果表明:通过定向进化,其中5号突变体的剪接活性从原始的约20%提高至约85%;9号突变体能够避免发生剪接副反应,即N端断裂反应。氨基酸突变位点与剪接活性变化的相关性分析表明:参与α-helix形成的氨基酸的突变极有可能影响蛋白质内含子的断裂反应,参与β-sheet形成的氨基酸的突变则有可能影响蛋白质内含子结构的紧凑性。通过定向进化提高微小蛋白质内含子Ter DnaE-3在异源宿主中的剪接活性,进一步验证依赖卡那霉素抗性的筛选系统的可行性,为扩大蛋白质内含子的应用范围奠定基础。     

Solution structure of DnaE intein from Nostoc punctiforme: Structural basis for the design of a new split intein suitable for site-specific chemical modification

Naturally split DnaE intein from Nostoc punctiforme (Npu) has robust protein trans-splicing activity and high tolerance of sequence variations at the splicing junctions. We determined the solution structure of a single chain variant of NpuDnaE intein by NMR spectroscopy. Based on the NMR structure and the backbone dynamics of the single chain NpuDnaE intein, we designed a functional split variant of the NpuDnaE intein having a short C-terminal half (C-intein) composed of six residues. In vivo and in vitro protein ligation of model proteins by the newly designed split intein were demonstrated.     

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.     

Functional characterization of a naturally occurring trans-splicing intein from Synechococcus elongatus in a mammalian cell system

We have cloned and characterized a naturally occurring split mini-DnaE intein capable of protein trans-splicing in the cyanobacterium Synechococcus elongatus (Sel DnaE intein). Sel DnaE intein is homologous to Synechocystissp. PCC6803 (Ssp) DnaE intein and Nostoc punctiforme (Npu) DnaE intein, with a protein sequence identity of 60% for the N-terminal part of intein and 61% for the C-terminal part of intein. Our results demonstrate that the split reporters, split Renilla luciferase (Rluc) and enhanced green fluorescent protein (EGFP), can be reconstituted via Sel DnaE intein-mediated trans-splicing in mammalian cells. Based on Sel DnaE intein-mediated reconstitution of split Rluc, a human immunodeficiency virus (HIV) entry-mimicking cell-cell fusion assay was developed and validated as a useful assay for screening and pharmacologically characterizing potential HIV entry-targeting inhibitors.     

蛋白质内含子在特定氨基酸序列中的剪接

基因工程技术已经被广泛应用于抗体的生产。但是由于抗体的分子量较大,导致合成抗体较为困难。蛋白质内含子是前体蛋白质中的一段氨基酸序列,能够将自身剪切出来,并将两端的外显子连接形成成熟的蛋白质。将抗体的Fab(antigen binding fragment)和Fc(crystalline fragment)分别与蛋白质内含子(intein) 的N端(IN)和C端(IC)融合表达,利用蛋白质内含子的剪接功能,可形成完整的抗体分子。KSCDKTH是存在于抗体铰链区(hinge region)的一段氨基酸序列,如果在KSCDKTH序列中筛选到高效剪接的蛋白质内含子,即可通过蛋白质剪接,将抗体分子的Fab和Fc剪接形成完整抗体。本文筛选发现,Ssp DnaX的3种断裂蛋白质内含子(S0, S1, S11)具有在KSCDKTH序列中高效剪接的能力,这一研究结果为抗体的剪接合成提供了可行性。