InBase, the Intein Database

InBase, the Intein Database (http://www.neb.com/neb/inteins.html ), is a comprehensive on-line resource that includes the Intein Registry. Inteins are protein splicing elements that mediate a self-catalytic protein splicing reaction. InBase presents general information as well as detailed data for each intein, including tabu-lated comparisons and a comprehensive bibliography.     

InBase, the New England Biolabs Intein Database.

Inteins are intervening sequences that splice as proteins, not RNA. InBase, the New England Biolabs Intein Database (http://www.neb. com/neb/inteins.html), is a comprehensive on-line database that includes the Intein Registry, along with detailed information about each intein and its host protein, tabulated comparisons and a comprehensive bibliography including papers in press.     

Structural and Dynamical Features of Inteins and Implications on Protein Splicing

Protein splicing is a posttranslational modification where intervening proteins (inteins) cleave themselves from larger precursor proteins and ligate their flanking polypeptides (exteins) through a multistep chemical reaction. First thought to be an anomaly found in only a few organisms, protein splicing by inteins has since been observed in microorganisms from all domains of life. Despite this broad phylogenetic distribution, all inteins share common structural features such as a horseshoe-like pseudo two-fold symmetric fold, several canonical sequence motifs, and similar splicing mechanisms. Intriguingly, the splicing efficiencies and substrate specificity of different inteins vary considerably, reflecting subtle changes in the chemical mechanism of splicing, linked to their local structure and dynamics. As intein chemistry has widespread use in protein chemistry, understanding the structural and dynamical aspects of inteins is crucial for intein engineering and the improvement of intein-based technologies.     

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.     

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。     

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.     

The ins and outs of protein splicing elements

Protein splicing involves the removal of an internal protein sequence from a precursor molecule and the ligation of the two flanking sequences to produce a mature protein product, in a post-translational event analogous to the removal of an intron from rRNA. Protein splicing introns, or‘inteins’appear to be a novel type of genetic element capable of mediating gene conversion of an‘intein-less’allele, and hence promoting their own dissemination. The mechanism by which protein splicing is achieved is probably entirety encoded within the internal protein sequence, or intein, and does not require other accessory molecules. Although the concept of protein splicing inteins as selfish genetic elements of no immediate consequence to the host organism has emerged, this interpretation is questioned by recent evidence that in at least one example there appears to have been selection for protein splicing.     

Protein splicing

Protein splicing is a posttranslational process that results in excision of an internal protein region (intein) and ligation of its flanking sequences (exteins). As distinguished from other variants of protein processing, protein splicing does not require cofactors of enzymes. Protein splicing is catalyzed by an internal domain (so-called Hint domain) of the intein itself. The review considers the main regularities and molecular mechanisms of the process, as well as the functions of Hint domains in other protein families (Hh proteins, bacterial BIL domains, etc.). Studies of protein splicing are of importance from both theoretical and applied viewpoints. For instance, comparisons of the inteins found in different domains of life illustrate the role of horizontal transfer in intein spreading. A possible role of inteins in regulating several cell processes is discussed on the basis of recent data.     

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.     

Protein splicing — the lengths some proteins will go to

We review the recently discovered phenomenon of protein splicing which is the excision of an internal protein sequence at the protein level rather than at the RNA level. The means by which examples of protein splicing have been identified are described, and the similarities of the internally spliced protein products (or inteins) are discussed. Comparisons are made between inteins and group I RNA introns. We describe the evidence supporting excision of intiens by a post-translational autocatalytic reaction of a full length polypeptide precursor, rather than by RNA splicing. An examination is made of some of the proposed mechanism schemes and the supporting them presented.     

Development of a positive genetic selection system for inhibition of protein splicing using mycobacterial inteins in Escherichia coli DNA gyrase subunit A

An intein-based positive genetic selection system was developed to study protein splicing and to provide a selection system with the potential for finding splicing inhibitors. Inteins can be novel antimicrobial targets when present in essential proteins since blocking splicing would kill the organism. For example, pathogenic mycobacteria encode inteins that interrupt DNA gyrase. The gyrase selection system exploits (1) splicing of inteins out of Gyrase A and (2) the dominant lethal effect of quinolone poisoning of DNA gyrase, which in turn blocks replication. The system was adapted for whole-cell high-throughput screening using green fluorescent protein as an automatable readout of viability. To demonstrate the efficacy of this system, mutations that blocked splicing of the Mycobacterium xenopi Gyrase A intein were isolated. Splicing was then assayed at a second temperature to identify inteins with a temperature-sensitive splicing phenotype. Mutations were mapped onto a structure-based sequence alignment, which led to the rational prediction of a temperature-sensitive splicing mutation. GyrA intein subdomain relationships also provided insight into intein evolution.     

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.     

An alternative protein splicing mechanism for inteins lacking an N-terminal nucleophile

Variations in the intein-mediated protein splicing mechanism are becoming more apparent as polymorphisms in conserved catalytic residues are identified. The conserved Ser or Cys at the intein N-terminus and the conserved intein penultimate His are absent in the KlbA family of inteins. These inteins were predicted to be inactive, since an N-terminal Ala cannot perform the initial reaction of the standard protein splicing pathway to yield the requisite N-terminal splice junction (thio)ester. Despite the presence of an N-terminal Ala and a penultimate Ser, the KlbA inteins splice efficiently using an alternative protein splicing mechanism. In this non-canonical pathway, the C-extein nucleophile attacks a peptide bond at the N-terminal splice junction rather than a (thio)ester bond, alleviating the need to form the initial (thio)ester at the N-terminal splice junction. The remainder of the two pathways is the same: branch resolution by Asn cyclization is followed by an acyl rearrangement to form a native peptide bond between the ligated exteins.     

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.     

Modular organization of inteins and C-terminal autocatalytic domains.

Analysis of the conserved sequence features of inteins (protein "introns") reveals that they are composed of three distinct modular domains. The N-terminal (N) and C-terminal (C) domains are predicted to perform different parts of the autocatalytic protein splicing reaction. An optional endonuclease domain (EN) is shown to correspond to different types of homing endonucleases in different inteins. The N domain contains motifs predicted to catalyze the first steps of protein splicing, leading to the cleavage of the intein N terminus from its protein host. Intein N domain motifs are also found in C-terminal autocatalytic domains (CADs) present in hedgehog and other protein families. Specific residues in the N domain of intein and CADs are proposed to form a charge relay system involved in cleaving their N-termini. The intein C domain is apparently unique to inteins and contains motifs that catalyze the final protein splicing steps: ligation of the intein flanks and cleavage of its C terminus to release the free intein and spliced host protein. All intein EN domains known thus far have dodecapeptide (DOD, LAGLI-DADG) type homing endonuclease motifs. This work identifies an EN domain with an HNH homing-endonuclease motif and two new small inteins with no EN domains. One of these small inteins might be inactive or a "pseudo intein." The results suggest a modular architecture for inteins, clarify their origin and relationship to other protein families, and extend recent experimental findings on the functional roles of intein N, C, and EN motifs.     

Bacteriophage-based genetic system for selection of nonsplicing inteins

A genetic selection system that detects splicing and nonsplicing activities of inteins was developed based on the ability to rescue a T4 phage strain with a conditionally inactive DNA polymerase. This phage defect can be complemented by expression of plasmid-encoded phage RB69 DNA polymerase. Insertion of an intein gene into the active site of the RB69 DNA polymerase gene renders polymerase activity and phage viability dependent on protein splicing. The effectiveness of the system was tested by screening for thermosensitive splicing mutants. Development of genetic systems with the potential of identifying protein splicing inhibitors is a first step towards controlling proliferation of pathogenic microbes harboring inteins in essential proteins.     

Cisplatin inhibits protein splicing, suggesting inteins as therapeutic targets in mycobacteria

Mycobacterium tuberculosis harbors three protein splicing elements, called inteins, in critical genes and their protein products. Post-translational removal of the inteins occurs autocatalytically and is required for function of the respective M. tuberculosis proteins. Inteins are therefore potential targets for antimycobacterial agents. In this work, we report that the splicing activity of the intein present in the RecA recombinase of M. tuberculosis is potently inhibited by the anticancer drug cisplatin (cis-diamminedichloro-platinum(II)). This previously unrecognized activity of cisplatin was established using both an in vitro intein splicing assay, which yielded an IC(50) of ～2 μM, and a genetic reporter for intein splicing in Escherichia coli. Testing of related platinum(II) complexes indicated that the inhibition activity is highly structure-dependent, with cisplatin exhibiting the best inhibitory effect. Finally, we report that cisplatin is toxic toward M. tuberculosis with a minimum inhibitory concentration of ～40 μM, and in genetic experiments conducted with the related Mycobacterium bovis bacillus Calmette-Guérrin (BCG) strain, we show that cisplatin toxicity can be mitigated by intein overexpression. We propose that cisplatin inhibits intein activity by modifying at least one conserved cysteine residue that is required for splicing. Together these results identify a novel active site inhibitor of inteins and validate inteins as viable targets for small molecule inhibition in mycobacteria.     

Study of protein splicing and intein-mediated peptide bond cleavage under high-cell-density conditions

Protein splicing elements (inteins), capable of catalyzing controllable peptide bond cleavage reactions, have been used to separate recombinant proteins from affinity tags during affinity purification. Since the inteins eliminate the use of a protease in the recovery process, the intein-mediated purification system has the potential to significantly reduce recovery costs for the industrial production of recombinant proteins. Thus far, the intein system has only been examined and utilized for expression and purification of recombinant proteins at the laboratory scale for cells cultivated at low cell densities. In this study, protein splicing and in vitro cleavage of intein fusion proteins expressed in high-cell-density fed-batch fermentations of recombinant Escherichia coli were examined. Three model intein fusion constructs were used to examine the stability and splicing/cleavage activities of the fusion proteins produced under high-cell-density conditions. The data indicated that the intein fusion protein containing the wild-type intein catalyzed efficient in vivo protein splicing during high-cell-density cultivation. Also, the intein fusion proteins containing modified inteins catalyzed efficient thiol-induced in vitro cleavage reactions. The results of this study demonstrated the potential feasibility of using the intein-mediated protein purification system for industrial-scale production of recombinant proteins.     

Bacteriophage-Based Genetic System for Selection of Nonsplicing Inteins

A genetic selection system that detects splicing and nonsplicing activities of inteins was developed based on the ability to rescue a T4 phage strain with a conditionally inactive DNA polymerase. This phage defect can be complemented by expression of plasmid-encoded phage RB69 DNA polymerase. Insertion of an intein gene into the active site of the RB69 DNA polymerase gene renders polymerase activity and phage viability dependent on protein splicing. The effectiveness of the system was tested by screening for thermosensitive splicing mutants. Development of genetic systems with the potential of identifying protein splicing inhibitors is a first step towards controlling proliferation of pathogenic microbes harboring inteins in essential proteins.     

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.