The Thermococcus kodakaraensis Tko CDC21-1 intein activates its N-terminal splice junction in the absence of a conserved histidine by a compensatory mechanism

Inteins and other self-catalytic enzymes, such as glycosylasparaginases and hedgehog precursors, initiate autocleavage by converting a peptide bond to a (thio)ester bond when Ser, Thr, or Cys undergoes an N-[S/O] acyl migration assisted by residues within the precursor. Previous studies have shown that a His at position 10 in intein Block B is essential for this initial acyl migration and N-terminal splice junction cleavage. This His is present in all inteins identified to date except the Thermococcus kodakaraensis Tko CDC21-1 intein orthologs and the inactive Arthrobacter species FB24 Arth_1007 intein. This study demonstrates that the Tko CDC21-1 intein is fully active and has replaced the lost catalytic function normally provided by the Block B His using a compensatory mechanism involving a conserved ortholog-specific basic residue (Lys(58)) present outside the standard intein conserved motifs. We propose that Lys(58) catalyzes the initial N-S acyl migration by stabilizing the thiazolidine-tetrahedral intermediate, allowing it to be resolved by water-mediated hydrolysis rather than by protonating the leaving group as His is theorized to do in many other inteins. Autoprocessing enzymes may have more flexibility in evolving catalytic variations because high reaction rates are not required when performing single-turnover reactions on "substrates" that are covalently attached to the enzyme. Consequently, inteins have more flexibility to sample catalytic mechanisms, providing insight into various strategies that enzymes use to accomplish catalysis.     

The Deinococcus radiodurans Snf2 intein caught in the act: Detection of the Class 3 intein signature Block F branched intermediate

Inteins are the protein equivalent of introns. They are remarkable and robust single turnover enzymes that splice out of precursor proteins during post‐translational maturation of the host protein (extein). The Deinococcus radiodurans Snf2 intein is the second member of the recently discovered Class 3 subfamily of inteins to be characterized. Class 3 inteins have a unique sequence signature: (a) they start with residues other than the standard Class 1 Cys, Ser or Thr, (b) have a noncontiguous, centrally located Trp/Cys/Thr triplet, and (c) all but one have Ser or Thr at the start of the C‐extein instead of the more common Cys. We previously proposed that Class 3 inteins splice by a variation in the standard intein‐mediated protein splicing mechanism that includes a novel initiating step leading to the formation of a previously unrecognized branched intermediate. In this mechanism defined with the Class 3 prototypic Mycobacteriophage Bethlehem DnaB intein, the triplet Cys attacks the peptide bond at the N‐terminal splice junction to form the class specific branched intermediate after which the N‐extein is transferred to the side chain of the Ser, Thr, or Cys at the C‐terminal splice junction to form the standard intein branched intermediate. Analysis of the Deinococcus radiodurans Snf2 intein confirms this splicing mechanism. Moreover, the Class 3 specific Block F branched intermediate was isolated, providing the first direct proof of its existence.     

The Mycobacterium avium-intracellulare complex dnaB locus and protein intein splicing

Intein is a protein sequence mebedded in-frame within a precursor protein and is posttranslationally excised by a self-catalytic protein splicing process. Protein splicing is believed to follow a pathway requiring Cys, Ser, or Thr residues at the intein N-terminus and substitutions other than Cys, Ser, or Thr residues prevent splicing. We show that the dnaB locus in some strains of M. avium-intracellulare complex (MAC) contains intein and that the intein N-terminal amino acid is Ala [Ala-type]. We demonstrate that the M. avium DnaB precursor protein undergoes posttranslational proteolytic processing producing proteins corresponding to the sizes of the DnaB and intein. Further, by Western analysis we detect a protein corresponding to the size of the spliced DnaB protein in MAC cell extracts. Together, these results indicate that the Ala-type MAC DnaB inteins can splice and provide another example that points to an interesting alternative splicing mechanism (Southworth, M. W., Benner, J., and Perler, F. B., EMBO J. 19, 5019-5026, 2000).     

Expanding the definition of class 3 inteins and their proposed phage origin

Inteins are the protein equivalent of introns. Their protein splicing activity is essential for the host protein's maturation and function. Inteins are grouped into three classes based on sequence signature and splicing mechanism. The sequence signature of the recently characterized class 3 inteins is a noncontiguous Trp-Cys-Thr (WCT) motif and the absence of the standard class 1 Cys1 or Ser1 N-terminal nucleophile. The intein N-terminal Cys1 or Ser1 residue is essential for splicing in class 1 inteins. The mycobacteriophage Catera Gp206, Nocardioides sp. strain JS614 TOPRIM, and Thermobifida fusca YX Tfu2914 inteins have a mixture of class 1 and class 3 motifs. They carry the class 3 Trp-Cys-Thr motif and have the standard class 1 N-terminal Ser1 or Cys1. This study determined which class the mycobacteriophage Catera Gp206 and Nocardioides sp. JS614 TOPRIM inteins belong to based on catalytic mechanism. The mycobacteriophage Catera Gp206 intein (starting with Ser1) is a class 3 intein, and its Ser1 residue is not required for splicing. Based on phylogenetic analysis, we propose that class 3 inteins arose from a single mutated intein that was spread by phage into predominantly helicase genes in various phages and their hosts.     

Protein splicing in the absence of an intein penultimate histidine

Protein splicing is a self-catalytic process in which an intervening sequence, termed an intein, is excised from a protein precursor, and the flanking polypeptides are religated. The conserved intein penultimate His facilitates this reaction by assisting in Asn cyclization, which results in C-terminal splice junction cleavage. However, many inteins do not have a penultimate His. Previous splicing studies with 2 such inteins yielded contradictory results. To resolve this issue, the splicing capacity of 2 more inteins without penultimate His residues was examined. Both the Methanococcus jannaschii phosphoenolpyruvate synthase and RNA polymerase subunit A' inteins spliced. Splicing of the phosphoenolpyruvate synthase intein improved when its penultimate Phe was changed to His, but splicing of the RNA polymerase subunit A' intein was inhibited when its penultimate Gly was changed to His. We propose that inteins lacking a penultimate His (i) arose by mutation from ancestors in which a penultimate His facilitated splicing, (ii) that loss of this His inhibited, but may not have blocked, splicing, and (iii) that selective pressure for efficient expression of the RNA polymerase yielded an intein that utilizes another residue to assist Asn cyclization, changing the intein active site so that a penultimate His now inhibits splicing.     

Compilation and analysis of intein sequences.

We have compiled a list of all the inteins (protein splicing elements) whose sequences have been published or were available from on-line sequence databases as of September 18, 1996. Analysis of the 36 available intein sequences refines the previously described intein motifs and reveals the presence of another intein motif, Block H. Furthermore, analysis of the new inteins reshapes our view of the conserved splice junction residues, since three inteins lack the intein penultimate His seen in prior examples. Comparison of intein sequences suggests that, in general, (i) inteins present in the same location within extein homologs from different organisms are very closely related to each other in paired sequence comparison or phylogenetic analysis and we suggest that they should be considered intein alleles; (ii) multiple inteins present in the same gene are no more similar to each other than to inteins present in different genes; (iii) phylogenetic analysis indicates that inteins are so divergent that trees with statistically significant branches cannot be generated except for intein alleles.     

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.     

A topA intein in Pyrococcus furiosus and its relatedness to the r-gyr intein of Methanococcus jannaschii

A new intein coding sequence was found in a topA (DNA topoisomerase I) gene by cloning and sequencing this gene from the hyperthermophilic Archaeon Pyrococcus furiosus. The predicted Pfu topA intein sequence is 373 amino acids long and located two residues away from the catalytic tyrosine of the topoisomerase. It contains putative intein sequence blocks (C, E, and H) associated with intein endonuclease activity, in addition to intein sequence blocks (A, B, F, and G) that are necessary for protein splicing. This DNA topoisomerase I intein is most related to a reverse gyrase intein from the methanogenic Archaeon Methanococcus jannaschii. These two inteins share 31% amino acid sequence identity and, more importantly, have the same insertion sites in their respective host proteins. It is suggested that these two inteins are homologous inteins present in structurally related, but functionally distinct, proteins, with implications on intein evolution and intein homing.     

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.     

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.     

Splicing of the Mycobacteriophage Bethlehem DnaB Intein: IDENTIFICATION OF A NEW MECHANISTIC CLASS OF INTEINS THAT CONTAIN AN OBLIGATE BLOCK F NUCLEOPHILE*?

Inteins are single turnover enzymes that splice out of protein precursors during maturation of the host protein (extein). The Cys or Ser at the N terminus of most inteins initiates a four-step protein splicing reaction by forming a (thio)ester bond at the N-terminal splice junction. Several recently identified inteins cannot perform this acyl rearrangement because they do not begin with Cys, Thr, or Ser. This study analyzes one of these, the mycobacteriophage Bethlehem DnaB intein, which we describe here as the prototype for a new class of inteins based on sequence comparisons, reactivity, and mechanism. These Class 3 inteins are characterized by a non-nucleophilic N-terminal residue that co-varies with a non-contiguous Trp, Cys, Thr triplet (WCT) and a Thr or Ser as the first C-extein residue. Several mechanistic differences were observed when compared with standard inteins or previously studied atypical KlbA Ala¹ inteins: (a) cleavage at the N-terminal splice junction in the absence of all standard N- and C-terminal splice junction nucleophiles, (b) activation of the N-terminal splice junction by a variant Block B motif that includes the WCT triplet Trp, (c) decay of the branched intermediate by thiols or Cys despite an ester linkage at the C-extein branch point, and (d) an absolute requirement for the WCT triplet Block F Cys. Based on biochemical data and confirmed by molecular modeling, we propose roles for these newly identified conserved residues, a novel protein splicing mechanism that includes a second branched intermediate, and an intein classification with three mechanistic categories.     

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.     

aroA-In融合基因载体的构建、表达及对烟草的转化

PCR扩增突变的5’-烯醇丙酮酸莽草酸-3-磷酸合成酶(5’-enolpyruvylshikimate-3-phosphate synthetase,EPSPS)cDNA全长序列,插入pLitmus28得到pLEPSPS,进而通过反向PCR在EPSPS235／236aa之间将其打断为无功能的片段。选用人工构建的具有顺式和反式剪接功能的mini型蛋白内含子Ssp DnaB和Rma DnaB,插入被打断的aroA(抗除草剂基因),构建了质粒pLEBC、pLEBT、pLERC和pLERT。将4种重组质粒中的aroA-In(蛋白内含子Intein插入aroA)融合基因插入pET-32得到表达载体pETLEBC、pETLEBT、pETLERC和pETLERT,lPTG诱导后,SDS-PAGE分析显示其能在DE。中有效表达并发生相应的蛋白剪接。将aroA-cis Ssp DnaB和aroA-cis Rma DnaB融合基因分别插入pLYM中进一步构建成植物表达载体,农杆菌叶盘法转化烟草。基因组PCR分析表明融合基因整合入植物核基因组;RT-PCR分析显示其可在高等植物细胞中成功表达。结果说明蛋白内含子基因可以转化高等真核细胞,蛋白剪接技术可应用于高等植物细胞,从而为防止植物转基因扩散提供了一条新的途径。     

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.     

The nuclear-encoded inteins of fungi

An intein is a protein sequence embedded within a precursor protein that is excised during protein maturation. Inteins were first found encoded in the VMA gene of Saccharomyces cerevisiae. Subsequently, they have been found in diverse organisms (eukaryotes, archaea, eubacteria and viruses). The VMA intein has been found in various saccharomycete yeasts but not in other fungi. Different inteins have now been found widely in the fungi (ascomycetes, basidiomycetes, zygomycetes and chytrids) and in diverse proteins. A protein distantly related to inteins, but closely related to metazoan hedgehog proteins, has been described from Glomeromycota. Many of the newly described inteins contain homing endonucleases and some of these are apparently active. The enlarged fungal intein data set permits insight into the evolution of inteins, including the role of horizontal transfer in their persistence. The diverse fungal inteins provide a resource for biotechnology using their protein splicing or homing endonuclease capabilities.     

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.     

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.     

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.     

Alternative nucleophilic residues in intein catalysis of protein splicing

Protein-splicing inteins are widespread in nature and have found many applications in protein research and engineering. The mechanism of protein splicing typically requires a nucleophilic amino acid residue at both position 1 (first residue of intein) and position +1 (first residue after intein), however it was not clear whether or how the three different nucleophilic residues (Cys, Ser, and Thr) would work differently at these two positions. To use intein in a target protein of interest, one needs to choose an intein insertion site to have a nucleophilic residue at position +1, therefore it is desirable to know what nucleophilic residue(s) are preferred by different inteins. In this study we began with a statistical analysis of known inteins, which showed an unequal distribution of the three nucleophilic residues at positions 1 and +1, and then subjected six different mini-inteins to site-directed mutagenesis to systematically test the functionality of the three nucleophilic residues at the two positions. At position 1, most natural inteins had Cys and none had Thr. When the Cys at position 1 of the six inteins was mutated to Ser and Thr, the splicing activity was abolished in all except one case. At position +1, Cys and Ser were nearly equally abundant in natural inteins, and they were found to be functionally interchangeable in the six inteins of this study. When the two positions were studied as 1/+1 combination, the Cys/Ser combination was abundant in natural inteins, whereas the Ser/Cys combination was conspicuously absent. Similarly, all of the six inteins of this study spliced with the Cys/Ser combination, whereas none spliced with the Ser/Cys combination. These findings have interesting implications on the mechanism of splicing and the selection of intein insertion sites, and they also produced two rare mini-inteins that could splice with Thr at position +1.