Crystal structure of a mini-intein reveals a conserved catalytic module involved in side chain cyclization of asparagine during protein splicing

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.

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.

Intramolecular disulfide bond between catalytic cysteines in an intein precursor

Protein splicing is a self-catalyzed and spontaneous post-translational process in which inteins excise themselves out of precursor proteins while the exteins are ligated together. We report the first discovery of an intramolecular disulfide bond between the two active-site cysteines, Cys1 and Cys+1, in an intein precursor composed of the hyperthermophilic Pyrococcus abyssi PolII intein and extein. The existence of this intramolecular disulfide bond is demonstrated by the effect of reducing agents on the precursor, mutagenesis, and liquid chromatography-mass spectrometry (LC-MS) with tandem MS (MS/MS) of the tryptic peptide containing the intramolecular disulfide bond. The disulfide bond inhibits protein splicing, and splicing can be induced by reducing agents such as tris(2-carboxyethyl)phosphine (TCEP). The stability of the intramolecular disulfide bond is enhanced by electrostatic interactions between the N- and C-exteins but is reduced by elevated temperature. The presence of this intramolecular disulfide bond may contribute to the redox control of splicing activity in hypoxia and at low temperature and point to the intriguing possibility that inteins may act as switches to control extein function.

Probing intein-catalyzed thioester formation by unnatural amino acid substitutions in the active site

Inteins are single-turnover catalysts that splice themselves out of a precursor polypeptide chain. For most inteins, the first step of protein splicing is the formation of a thioester through an N-S acyl shift at the upstream splice junction. However, the mechanism by which this reaction is achieved and the impact of mutations in and close to the active site remain unclear on the atomic level. To investigate these questions, we have further explored a split variant of the Ssp DnaB intein by introducing substitutions with unnatural amino acids within the short synthetic N-terminal fragment. A previously reported collapse of the oxythiazolidine anion intermediate into a thiazoline ring was found to be specificially dependent on the methyl side chain of the flanking Ala(-1). The stereoisomer d-Ala and the constitutional isomers β-Ala and sarcosine did not lead to this side reaction but rather supported splicing. Substitution of the catalytic Cys1 with homocysteine strongly inhibited protein splicing; however, thioester formation was not impaired. These results argue against the requirement of a base to deprotonate the catalytic thiol group prior to the N-S acyl shift, because it should be misaligned for optimal proton abstraction. A previously described mutant intein evolved for more general splicing in different sequence contexts could even rather efficiently splice with this homocysteine. Our findings show the large impact of some subtle structural changes on the protein splicing pathway, but also the remarkable tolerance toward other changes. Such insights will also be important for the biotechnological exploitation of inteins.

Mechanism of C-terminal intein cleavage in protein splicing from QM/MM molecular dynamics simulations

Protein splicing is a post-translational process in which a biologically inactive protein is activated by the release of a segment denoted as an intein. The process involves four steps. In the third, the scission of the intein takes place after the cyclization of the last amino acid of the segment, an asparagine. Little is known about the chemical reaction necessary for this cyclization. Experiments demonstrate that two histidines (the penultimate amino acid of the intein, and a histidine located 10 amino acids upstream) are relevant in the cyclization of the asparagine. We have investigated the mechanism and determinants of reaction in the GyrA intein focusing on the requirements for asparagine activation for its cyclization. First, the influence that the protonation states of these two histidines have on the orientation of the asparagine side chain is investigated by means of molecular dynamics simulation. Molecular dynamics simulations using the CHARMM27 force field were carried out on the three possible protonation states for each of these two histidines. The results indicate that the only protonation state in which the conformation of the system is suitable for cyclization is when the penultimate histidine is fully protonated (positively charged), and the upstream histidine is in the His(ε) neutral tautomeric form. The free energy profile for the reaction in which the asparagine is activated by a proton transfer to the upstream histidine is presented, computed by hybrid quantum mechanics/molecular mechanics (QM/MM) umbrella sampling molecular dynamics at the SCCDFTB/CHARMM27 level of theory. The calculated free energy barrier for the reaction is 19.0 kcal mol(-1). B3LYP/6-31+G(d) QM/MM single-point calculations give a qualitatively a similar energy profile, although with somewhat higher energy barriers, in good agreement with the value derived from experiment of 25 kcal mol(-1) at 60 °C. QM/MM molecular dynamics simulations of the reactant, activated reactant and intermediate states highlight the importance of the Arg181-Val182-Asp183 segment in catalysing the reaction. Overall, the results indicate that nucleophilic activation of the asparagine for its cyclization by the upstream histidine acting as the base is a plausible mechanism for the C-terminal cleavage in protein splicing.

Structural and mutational studies of a hyperthermophilic intein from DNA polymerase II of Pyrococcus abyssi

Protein splicing is a precise self-catalyzed process in which an intein excises itself from a precursor with the concomitant ligation of the flanking polypeptides (exteins). Protein splicing proceeds through a four-step reaction but the catalytic mechanism is not fully understood at the atomic level. We report the solution NMR structures of the hyperthermophilic Pyrococcus abyssi PolII intein, which has a noncanonical C-terminal glutamine instead of an asparagine. The NMR structures were determined to a backbone root mean square deviation of 0.46 Å and a heavy atom root mean square deviation of 0.93 Å. The Pab PolII intein has a common HINT (hedgehog intein) fold but contains an extra β-hairpin that is unique in the structures of thermophilic inteins. The NMR structures also show that the Pab PolII intein has a long and disordered loop in place of an endonuclease domain. The N-terminal Cys-1 amide is hydrogen bonded to the Thr-90 hydroxyl in the conserved block-B TXXH motif and the Cys-1 thiol forms a hydrogen bond with the block F Ser-166. Mutating Thr-90 to Ala dramatically slows N-terminal cleavage, supporting its pivotal role in promoting the N-S acyl shift. Mutagenesis also showed that Thr-90 and His-93 are synergistic in catalyzing the N-S acyl shift. The block F Ser-166 plays an important role in coordinating the steps of protein splicing. NMR spin relaxation indicates that the Pab PolII intein is significantly more rigid than mesophilic inteins, which may contribute to the higher optimal temperature for protein splicing.

An improved particle bombardment for the generation of transgenic plants by direct immobilization of relleasable Tn5 transposases onto gold particles

We have developed a modified particle bombardment method for plant transgenesis. An intein-tag and a 6×Cys-tag were successively fused to the N-terminus of a hyperactive Tn5 transposase. The modified transposase was immobilized on bare gold microscopic particles via covalent binding of a 6×Cys-tag sulfydryl groups to the gold surface. The tethered transposase can bind the transposon DNA in vitro to form the transposome in the absence of Mg²⁺ ions. After bombardment of the gold particles carrying the transposomes into the plant cells, the transposomes will be released from the carrier due to the activated self-cleavage function of intein-tag. Our data showed this procedure integrated foreign DNA into the plant genome with an increased transformation frequency as compared to the conventional particle bombardment method. A single copy insertion can also be obtained by decreasing of the assembled transposon DNA amount in relation to plant cell biomass.

Intein lacking conserved C-terminal motif G retains controllable N-cleavage activity

A split-intein consists of two complementary fragments (N-intein and C-intein) that can associate to carry out protein trans-splicing. The Ssp GyrB S11 split-intein is an engineered unconventional split-intein consisting of a 150-amino-acid N-intein and an extremely small six-amino-acid C-intein, which comprises the conserved intein motif G. Here, we show that fusion proteins containing the 150-amino-acid N-intein could be triggered to undergo controllable N-cleavage in vitro when the six-amino-acid C-intein or a derivative thereof was added as a synthetic peptide in trans. More importantly, we discovered, unexpectedly, that the 150-amino-acid N-intein could be induced by strong nucleophiles to undergo N-cleavage in vitro, and in Escherichia coli cells, in the absence of the motif G-containing six-amino-acid C-intein. This finding indicated that the first step of the protein splicing mechanism (acyl shift) could occur in the absence of the entire motif G. Extensive kinetic analyses revealed that both the motif G residues and the Ser+1 residue positively influenced N-cleavage rate constants and yields. The 150-amino-acid N-intein could also tolerate various unrelated sequences appended to its C-terminus without disruption of the N-cleavage function, suggesting that the catalytic pocket of the intein has considerable structural flexibility. Our findings reveal interesting insights into intein structure-function relationships, and demonstrate a new and potentially more useful method of controllable, intein-mediated N-cleavage for protein engineering 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.

Spontaneous C-cleavage of a mini-intein without its conserved N-terminal motif A

Previously, the C-terminal fragment of a split intein was known to undergo controllable C-cleavage at its C-terminus only when the N-terminal fragment of the intein was added. Here we constructed a similar split intein from the Ssp DnaX intein, but we unexpectedly observed that its C-terminal 136-aa fragment could undergo spontaneous C-cleavage without the N-terminal fragment that was up to 15 aa long and contained the conserved intein motif A. This C-cleavage activity was significantly decreased by a mutation of the conserved Thr residue in the conserved intein motif B. These findings suggest a robust intein structure in the absence of motif A and a larger role of motif B in the third step of the protein splicing mechanism.

An intein with genetically selectable markers provides a new approach to internally label proteins with GFP

BACKGROUND

Inteins are proteins that catalyze their own removal from within larger precursor proteins. In the process they splice the flanking protein sequences, termed the N-and C-terminal exteins. Large inteins frequently have a homing endonuclease that is involved in maintaining the intein in the host. Splicing and nuclease activity are independent and distinct domains in the folded structure. We show here that other biochemical activities can be incorporated into an intein in place of the endonuclease without affecting splicing and that these activities can provide genetic selection for the intein. We have coupled such a genetically marked intein with GFP as the N-terminal extein to create a cassette to introduce GFP within the interior of a targeted protein.

RESULTS

The Pch PRP8 mini-intein of Penicillium chrysogenum was modified to include: 1) aminoglycoside phosphotransferase; 2) imidazoleglycerol-phosphate dehydratase, His5 from S. pombe ; 3) hygromycin B phosphotransferase; and 4) the transcriptional activator LexA-VP16. The proteins were inserted at the site of the lost endonuclease. When expressed in E. coli, all of the modified inteins spliced at high efficiency. Splicing efficiency was also greater than 96% when expressed from a plasmid in S. cerevisiae. In addition the inteins conferred either G418 or hygromycin resistance, or histidine or leucine prototropy, depending on the inserted marker and the yeast genetic background. DNA encoding the marked inteins coupled to GFP as the N-terminal extein was PCR amplified with ends homologous to an internal site in the yeast calmodulin gene CMD1. The DNA was transformed into yeast and integrants obtained by direct selection for the intein's marker. The His5-marked intein yielded a fully functional calmodulin that was tagged with GFP within its central linker.

CONCLUSIONS

Inteins continue to show their flexibility as tools in molecular biology. The Pch PRP8 intein can successfully tolerate a variety of genetic markers and still retain high splicing efficiency. We have shown that a genetically marked intein can be used to insert GFP in one-step within a target protein in vivo.

pK(a) coupling at the intein active site: implications for the coordination mechanism of protein splicing with a conserved aspartate

Protein splicing is a robust multistep posttranslational process catalyzed by inteins. In the Mtu RecA intein, a conserved block-F aspartate (D422) coordinates different steps in protein splicing, but the precise mechanism is unclear. Solution NMR shows that D422 has a strikingly high pK(a) of 6.1, two units above the normal pK(a) of aspartate. The elevated pK(a) of D422 is coupled to the depressed pK(a) of another active-site residue, the block-A cysteine (C1). A C1A mutation lowers the D422 pK(a) to normal, while a D422G mutation increases the C1 pK(a) from 7.5 to 8.5. The pK(a) coupling and NMR structure determination demonstrate that protonated D422 serves as a hydrogen bond donor to stabilize the C1 thiolate and promote the N-S acyl shift, the first step of protein splicing. Additionally, in vivo splicing assays with mutations of D422 to Glu, Cys, and Ser show that the deprotonated aspartate is essential for splicing, most likely by deprotonating and activating the downstream nucleophile in transesterification, the second step of protein splicing. We propose that the sequential protonation and deprotonation of the D422 side chain is the coordination mechanism for the first two steps of protein splicing.

Protein trans-splicing as a protein ligation tool to study protein structure and function

Protein trans-splicing (PTS) exerted by split inteins is a protein ligation reaction which enables overcoming the barriers of conventional heterologous protein production. We provide an overview of the current state-of-the-art in split intein engineering, as well as the achievements of PTS technology in the realm of protein structure-function analyses, including incorporation of natural and artificial protein modifications, controllable protein reconstitution, segmental isotope labeling and protein cyclization. We further discuss factors crucial for the successful implementation of PTS in these protein engineering approaches, and speculate on necessary future endeavours to make PTS a universally applicable protein ligation tool.

Electronic structure of neighboring extein residue modulates intein C-terminal cleavage activity

Protein splicing is an autocatalytic reaction where an intervening element (intein) is excised and the remaining two flanking sequences (exteins) are joined. The reaction requires specific conserved residues, and activity may be affected by both the intein and the extein sequence. Predicting how sequence will affect activity is a challenging task. Based on first-principles density functional theory and multiscale quantum mechanics/molecular mechanics, we report C-terminal cleavage reaction rates for five mutations at the first residue of the C-extein (+1), and describe molecular properties that may be used as predictors for future mutations. Independently, we report on experimental characterization of the same set of mutations at the +1 residue resulting in a wide range of C-terminal cleavage activities. With some exceptions, there is general agreement between computational rates and experimental cleavage, giving molecular insight into previous claims that the +1 extein residue affects intein catalysis. These data suggest utilization of attenuating +1 mutants for intein-mediated protein manipulations because they facilitate precursor accumulation in vivo for standard purification schemes. A more detailed analysis of the "+1 effect" will also help to predict sequence-defined effects on insertion points of the intein into proteins of interest.

Split intein facilitated tag affinity purification for recombinant proteins with controllable tag removal by inducible auto-cleavage

Purification tags are robust tools that can be used to purify a variety of target proteins. However, tag removal remains an expensive and significant issue that must be resolved. Based on the affinity and the trans-splicing activity between the two domains of Ssp DnaB split-intein, a novel approach for tag affinity purification of recombinant proteins with controllable tag removal by inducible auto-cleavage has been developed. This system provides a new affinity method and avoids premature splicing of the intein fused proteins expressed in host cells. The affinity matrix can be reused. In addition, this method is compatible with his-tag affinity purification technique. Our methods provide the insights for establishing a novel recombinant protein preparation system.

Spontaneous proton transfer to a conserved intein residue determines on-pathway protein splicing

The discovery of inteins, which are protein-splicing elements, has stimulated interest for various applications in chemical biology, bioseparations, drug delivery, and sensor development. However, for inteins to effectively contribute to these applications, an increased mechanistic understanding of cleavage and splicing reactions is required. While the multistep chemical reaction that leads to splicing is often explored and utilized, it is not clear how the intein navigates through the reaction space. The sequence of reaction steps must progress in concert in order to yield efficient splicing while minimizing off-pathway cleavage reactions. In this study, we demonstrate that formation of a previously identified branched intermediate is the critical step for determining splicing over cleavage products. By combining experimental assays and quantum mechanical simulations, we identify the electrostatic interactions that are important to the dynamics of the reaction steps. We illustrate, via an animated simulation trajectory, a proton transfer from the first C-terminal extein residue to a conserved aspartate, which synchronizes the multistep enzymatic reaction that is key to splicing. This work provides new insights into the complex interplay between critical active-site residues in the protein splicing mechanism, thereby facilitating biotechnological application while shedding light on multistep enzyme activity.

Mechanism of protein splicing of the Pyrococcus abyssi lon protease intein

Protein splicing is a post-translational process by which an intervening polypeptide, the intein, excises itself from the flanking polypeptides, the exteins, coupled to ligation of the exteins. The lon protease of Pyrococcus abyssi (Pab) is interrupted by an intein. When over-expressed as a fusion protein in Escherichia coli, the Pab lon protease intein can promote efficient protein splicing. Mutations that block individual steps of splicing generally do not lead to unproductive side reactions, suggesting that the intein tightly coordinates the splicing process. The intein can splice, although it has Lys in place of the highly conserved penultimate His, and mutants of the intein in the C-terminal region lead to the accumulation of stable branched-ester intermediate.

Branched intermediate formation stimulates peptide bond cleavage in protein splicing

Protein splicing is a posttranslational modification in which an intein domain excises itself out of a host protein. Here, we investigate how the steps in the splicing process are coordinated so as to maximize the production of the final splice products and minimize the generation of undesired cleavage products. Our approach has been to prepare a branched intermediate (and analogs thereof) of the Mxe GyrA intein using protein semi-synthesis. Kinetic analysis of these molecules indicates that the high fidelity of this protein splicing reaction results from the penultimate step in the process (intein-succinimide formation) being rate-limiting. NMR experiments indicate that formation of the branched intermediate affects the local structure around the amide bond cleaved during succinimide formation. We propose that this structural change reflects a re-organization of the catalytic apparatus to accelerate succinimide formation at the C-terminal splice junction.

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.

Controllable protein cleavages through intein fragment complementation

Intein-based protein cleavages, if carried out in a controllable way, can be useful tools of recombinant protein purification, ligation, and cyclization. However, existing methods using contiguous inteins were often complicated by spontaneous cleavages, which could severely reduce the yield of the desired protein product. Here we demonstrate a new method of controllable cleavages without any spontaneous cleavage, using an artificial S1 split-intein consisting of an 11-aa N-intein (I(N)) and a 144-aa C-intein (I(C)). In a C-cleavage design, the I(C) sequence was embedded in a recombinant precursor protein, and the small I(N) was used as a synthetic peptide to trigger a cleavage at the C-terminus of I(C). In an N-cleavage design, the short I(N) sequence was embedded in a recombinant precursor protein, and the separately produced I(C) protein was used to catalyze a cleavage at the N-terminus of I(N). These N- and C-cleavages showed >95% efficiency, and both successfully avoided any spontaneous cleavage during expression and purification of the precursor proteins. The N-cleavage design also revealed an unexpected and interesting structural flexibility of the I(C) protein. These findings significantly expand the effectiveness of intein-based protein cleavages, and they also reveal important insights of intein structural flexibility and fragment complementation.

Protein C-terminal labeling and biotinylation using synthetic peptide and split-intein

Background

Site-specific protein labeling or modification can facilitate the characterization of proteins with respect to their structure, folding, and interaction with other proteins. However, current methods of site-specific protein labeling are few and with limitations, therefore new methods are needed to satisfy the increasing need and sophistications of protein labeling.

Methodology

A method of protein C-terminal labeling was developed using a non-canonical split-intein, through an intein-catalyzed trans-splicing reaction between a protein and a small synthetic peptide carrying the desired labeling groups. As demonstrations of this method, three different proteins were efficiently labeled at their C-termini with two different labels (fluorescein and biotin) either in solution or on a solid surface, and a transferrin receptor protein was labeled on the membrane surface of live mammalian cells. Protein biotinylation and immobilization on a streptavidin-coated surface were also achieved in a cell lysate without prior purification of the target protein.

Conclusions

We have produced a method of site-specific labeling or modification at the C-termini of recombinant proteins. This method compares favorably with previous protein labeling methods and has several unique advantages. It is expected to have many potential applications in protein engineering and research, which include fluorescent labeling for monitoring protein folding, location, and trafficking in cells, and biotinylation for protein immobilization on streptavidin-coated surfaces including protein microchips. The types of chemical labeling may be limited only by the ability of chemical synthesis to produce the small C-intein peptide containing the desired chemical groups.

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.

Rapid selection of cyclic peptides that reduce alpha-synuclein toxicity in yeast and animal models

Phage display has demonstrated the utility of cyclic peptides as general protein ligands but cannot access proteins inside eukaryotic cells. Expanding a new chemical genetics tool, we describe the first expressed library of head-to-tail cyclic peptides in yeast (Saccharomyces cerevisiae). We applied the library to selections in a yeast model of alpha-synuclein toxicity that recapitulates much of the cellular pathology of Parkinson's disease. From a pool of 5 million transformants, we isolated two related cyclic peptide constructs that specifically reduced the toxicity of human alpha-synuclein. These expressed cyclic peptide constructs also prevented dopaminergic neuron loss in an established Caenorhabditis elegans Parkinson's model. This work highlights the speed and efficiency of using libraries of expressed cyclic peptides for forward chemical genetics in cellular models of human disease.

Highly conserved histidine plays a dual catalytic role in protein splicing: a pKa shift mechanism

Protein splicing is a precise autocatalytic process in which an intein excises itself from a precursor with the concomitant ligation of the flanking sequences. Protein splicing occurs through acid-base catalysis in which the ionization states of active site residues are crucial to the reaction mechanism. In inteins, several conserved histidines have been shown to play important roles in protein splicing, including the most conserved "B-block" histidine. In this study, we have combined NMR pK(a) determination with quantum mechanics/molecular mechanics (QM/MM) modeling to study engineered inteins from Mycobacterium tuberculosis (Mtu) RecA intein. We demonstrate a dramatic pK(a) shift for the invariant B-block histidine, the most conserved residue among inteins. The B-block histidine has a pK(a) of 7.3 +/- 0.6 in a precursor and a pK(a) of <3.5 in a spliced intein. The pK(a) values and QM/MM data suggest that the B-block histidine has a dual role in the acid-base catalysis of protein splicing. This histidine likely acts as a general base to initiate splicing with an acyl shift and then as a general acid to cause the breakdown of the scissile bond at the N-terminal splicing junction. The proposed pK(a) shift mechanism accounts for the biochemical data supporting the essential role for the B-block histidine and for the near absolute sequence conservation of this residue.

Traceless protein splicing utilizing evolved split inteins

Split inteins are parasitic genetic elements frequently found inserted into reading frames of essential proteins. Their association and excision restore host protein function through a protein self-splicing reaction. They have gained an increasingly important role in the chemical modification of proteins to create cyclical, segmentally labeled, and fluorescently tagged proteins. Ideally, inteins would seamlessly splice polypeptides together with no remnant sequences and at high efficiency. Here, we describe experiments that identify the branched intermediate, a transient step in the overall splicing reaction, as a key determinant of the splicing efficiency at different splice-site junctions. To alter intein specificity, we developed a cell-based selection scheme to evolve split inteins that splice with high efficiency at different splice junctions and at higher temperatures. Mutations within these evolved inteins occur at sites distant from the active site. We present a hypothesis that a network of conserved coevolving amino acids in inteins mediates these long-range effects.

Modeling protein splicing: reaction pathway for C-terminal splice and intein scission

Protein splicing is a post-translational process where a biologically inactive protein is activated after the release of a so-called intein domain. In spite of the importance of this type of process, the specific molecular mechanism for the catalysis is still uncertain. In this work, we present a computational study of one of the key steps in protein splicing: the release of the intein due to the cyclization of an asparagine, the last amino acid of the intein. Density functional theory (DFT) calculations using the B3LYP functional in conjunction with the polarizable continuum model (PCM) were used to study the main stationary points along various possible reaction pathways. The results are compared with other DFT functionals and the MP2 ab initio method. In the first part of this work, the Asn-Thr dipeptide is analyzed with the aim of determining the specific requirements for the activation of the intrinsically slow Asn cyclization. The results show that the nucleophilic activation of the Asn side chain by removing one of its proton decreases the free energy barrier by approximately 20 kcal/mol. A full pathway of the reaction was also characterized in a larger model, including two imidazole molecules and two water molecules. The proposed reaction mechanism consists of two main steps: Asn side chain activation by a proton transfer to one of the imidazole groups, and cleavage of the peptide bond upon protonation of its nitrogen atom by the other imidazole. The overall free energy barrier in solution was determined to be 29.3 kcal/mol, in reasonable agreement with the apparent experimental barrier in the enzyme. The proposed mechanism suggests that the penultimate histidine stabilizes the tetrahedral intermediate and protonates the nitrogen of the scissile peptide bond, while a second histidine (located 10 amino acids upstream) activates the Asn side chain by deprotonating it.

In vivo and in vitro protein ligation by naturally occurring and engineered split DnaE inteins

Background

Protein trans-splicing by naturally occurring split DnaE inteins is used for protein ligation of foreign peptide fragments. In order to widen biotechnological applications of protein trans-splicing, it is highly desirable to have split inteins with shorter C-terminal fragments, which can be chemically synthesized.

Principal Findings

We report the identification of new functional split sites in DnaE inteins from Synechocystis sp. PCC6803 and from Nostoc punctiforme. One of the newly engineered split intein bearing C-terminal 15 residues showed more robust protein trans-splicing activity than naturally occurring split DnaE inteins in a foreign context. During the course of our experiments, we found that protein ligation by protein trans-splicing depended not only on the splicing junction sequences, but also on the foreign extein sequences. Furthermore, we could classify the protein trans-splicing reactions in foreign contexts with a simple kinetic model into three groups according to their kinetic parameters in the presence of various reducing agents.

Conclusion

The shorter C-intein of the newly engineered split intein could be a useful tool for biotechnological applications including protein modification, incorporation of chemical probes, and segmental isotopic labelling. Based on kinetic analysis of the protein splicing reactions, we propose a general strategy to improve ligation yields by protein trans-splicing, which could significantly enhance the applications of protein ligation by protein trans-splicing.

Semisynthesis of proteins using split inteins

Protein splicing is an autocatalytic reaction in which an internal protein domain, the intein, excises itself out of a precursor protein and concomitantly links the two flanking sequences, the exteins, with a native peptide bond. In split inteins, the intein domain is divided into two parts that undergo fragment association followed by protein splicing in trans. Thus, the extein sequences joined in the process originate from two separate molecules. The specificity and sequence promiscuity of split inteins make this approach a generally useful tool for the preparation of semisynthetic proteins. To this end, the recombinant part of the protein of interest is expressed as a fusion protein with one split intein fragment. The synthetic part is extended by the other, complementary fragment of the split intein. A recently introduced split intein, in which the N-terminal fragment consists of only 11 native amino acids, has greatly facilitated preparation of the synthetic part by solid-phase peptide synthesis. This intein enables the chemoenzymatic synthesis of N-terminally modified semisynthetic proteins. The reaction can be performed under native conditions and at protein and peptide concentrations in the low micromolar range. In contrast to chemical ligation procedures like native chemical ligation and expressed protein ligation, the incorporation of a thioester group and an aminoterminal cysteine into the two polypeptides to be linked is not necessary. We discuss properties of useful inteins, design rules for split inteins and intein insertion sites and we describe selected examples in detail.

Interaction studies and alanine scanning analysis of a semi-synthetic split intein reveal thiazoline ring formation from an intermediate of the protein splicing reaction

We recently reported an artificially split intein based on the Ssp DnaB mini-intein that consists of a synthetic N-terminal intein fragment (Int(N)) and a recombinant C-terminal part (Int(C)), which are 11 and 143 amino acids in length, respectively. This intein holds great promise for the preparation of semi-synthetic proteins by protein trans-splicing. In this work we synthesized a set of Int(N) peptide variants to investigate their structure-function relationship with regard to fragment association and promotion of protein trans-splicing. A further truncation of the Int(N) sequence below 11 amino acids resulted in loss of activity, whereas C-terminal extensions were tolerated. Alanine scanning analysis identified three essential hydrophobic residues, whereas substitutions at other positions were tolerated. We developed assays to monitor association of Int(N) with an Int(C) mutant blocked in protein splicing by native PAGE and fluorescence anisotropy. The kinetic parameters of intein complex formation were K(d) = 1.1 mum, k(on) = 16.8 m(-1) s(-1), and k(off) = 1.8 x 10(-5) s(-1) for the native Int(N11) sequence. Intriguingly, a G(-1)A substitution, previously known to significantly impair protein splicing, was revealed to result in thiazoline ring formation involving the catalytic Cys-1, likely by aberrant dehydration of a oxythiazolidine intermediate. This finding provides experimental evidence for the postulated intermediate during the initial N/S acyl shift and underlines the delicate spatial and temporal alignment required in the intein active site to prevent side reactions of the protein-splicing pathway.

Structural analysis of the essential self-cleaving type III secretion proteins EscU and SpaS

During infection by Gram-negative pathogenic bacteria, the type III secretion system (T3SS) is assembled to allow for the direct transmission of bacterial virulence effectors into the host cell. The T3SS system is characterized by a series of prominent multi-component rings in the inner and outer bacterial membranes, as well as a translocation pore in the host cell membrane. These are all connected by a series of polymerized tubes that act as the direct conduit for the T3SS proteins to pass through to the host cell. During assembly of the T3SS, as well as the evolutionarily related flagellar apparatus, a post-translational cleavage event within the inner membrane proteins EscU/FlhB is required to promote a secretion-competent state. These proteins have long been proposed to act as a part of a molecular switch, which would regulate the appropriate chronological secretion of the various T3SS apparatus components during assembly and subsequently the transported virulence effectors. Here we show that a surface type II beta-turn in the Escherichia coli protein EscU undergoes auto-cleavage by a mechanism involving cyclization of a strictly conserved asparagine residue. Structural and in vivo analysis of point and deletion mutations illustrates the subtle conformational effects of auto-cleavage in modulating the molecular features of a highly conserved surface region of EscU, a potential point of interaction with other T3SS components at the inner membrane. In addition, this work provides new structural insight into the distinct conformational requirements for a large class of self-cleaving reactions involving asparagine cyclization.

Biosynthesis of Staphylococcus aureus autoinducing peptides by using the synechocystis DnaB mini-intein

The Agr quorum-sensing system of Staphylococcus aureus modulates the expression of virulence factors in response to autoinducing peptides (AIPs). The peptides are seven to nine residues in length and have the C-terminal five residues constrained in a thiolactone ring. We have developed a new method to generate AIP structures using an engineered DnaB mini-intein from Synechocystis sp. strain PCC6803. In the method, an oligonucleotide encoding the AIP is ligated to the intein and the fusion protein is expressed and purified by affinity chromatography. To produce the correct AIP structure, intein splicing is interrupted, allowing the cysteine side chain to catalyze thiolactone ring formation and release AIP from the resin. The technique is simple and robust, and we have successfully produced the three main classes of AIPs using the intein system. The intein-generated AIPs possessed the correct thiolactone ring modification based on biochemical analysis, and, importantly, all the samples were bioactive against S. aureus. The AIP activity was confirmed through Agr interference and activation profiling with developed S. aureus reporter strains. The simplicity of the method, benefits of DNA encoding, and scalable nature enable the production of S. aureus AIPs for many biological applications.

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.

Protein splicing in cis and in trans

Intein-mediated protein splicing is a self-catalytic process in which the intervening intein sequence is removed from a precursor protein and the flanking extein segments are ligated with a native peptide bond. Splice junction proximal residues and internal residues within the intein direct these reactions. The identity of these residues varies in each intein, as groups of related residues populate conserved motifs. Although the basics of the four-step protein splicing pathway are known, mechanistic details are still unknown. Structural and kinetic analyses are beginning to shed some light. Several structures were reported for precursor proteins with mutations in catalytic residues, which stabilize the precursors for crystallographic study. Progress is being made despite limitations inherent in using mutated precursors. However, no uniform mechanism has emerged. Kinetic parameters were determined using conditional trans-splicing (splicing of split precursor fragments after intein reassembly). Several groups concluded that the rate of the initial acyl rearrangement step is rapid and Asn cyclization (step 3) is slow, suggesting that this latter step is rate limiting. Understanding the protein splicing pathway has allowed scientists to harness inteins for numerous applications.

[Recombinant oxyntomodulin]

An artificial gene encoding oxyntomodulin was obtained using chemical and enzymatic methods and cloned into Escherichia coli. A recombinant plasmid was constructed containing a hybrid oxyntomodulin gene and Ssp dnaB intein from Synechocystis sp. The expression of the resulting hybrid gene in E. coli, its properties, and the conditions of its autocatalytic cleavage to oxyntomodulin were studied.

Trans-splicing of an artificially split fungal mini-intein

Inteins are internal protein domains found inside the coding region of different proteins. They can autocatalytically self-excise from their host protein and ligate the protein flanks, called exteins, with a peptide bond via a post-translational process called protein cis-splicing. In contrast, protein trans-splicing involves inteins split into an N- and a C-terminal domain. Both domains are synthesized as two separate components and each joined to an extein; the intein domains can reassemble and link the joined exteins into one functional protein. In this study, we introduced three split sites into the PRP8 mini-intein of Penicillium chrysogenum and demonstrated for the first time trans-splicing of a fungal PRP8 intein. Two of the sites introduced allowed splicing to occur in trans while the third was not functional.

Crystallographic and mutational studies of Mycobacterium tuberculosis recA mini-inteins suggest a pivotal role for a highly conserved aspartate residue

The 440 amino acid Mtu recA intein consists of independent protein-splicing and endonuclease domains. Previously, removal of the central endonuclease domain of the intein, and selection for function, generated a 168 residue mini-intein, DeltaI-SM, that had splicing activity similar to that of the full-length, wild-type protein. A D422G mutation (DeltaI-CM) increased C-terminal cleavage activity. Using the DeltaI-SM mini-intein structure (presented here) as a guide, we previously generated a highly active 139 residue mini-intein, DeltaDeltaI(hh)-SM, by replacing 36 amino acid residues in the residual endonuclease loop with a seven-residue beta-turn from the autoprocessing domain of Hedgehog protein. The three-dimensional structures of DeltaI-SM, DeltaDeltaI(hh)-SM, and two variants, DeltaDeltaI(hh)-CM and DeltaDeltaI(hh), have been determined to evaluate the effects of the minimization on intein integrity and to investigate the structural and functional consequences of the D422G mutation. These structural studies show that Asp422 is capable of interacting with both the N and C termini. These interactions are lacking in the CM variant, but are replaced by contacts with water molecules. Accordingly, additional mutagenesis of residue 422, combined with mutations that isolate N-terminal and C-terminal cleavage, showed that the side-chain of Asp422 plays a role in both N and C-terminal cleavage, thereby suggesting that this highly conserved residue regulates the balance between the two reactions.

Mechanism for intein C-terminal cleavage: a proposal from quantum mechanical calculations

Inteins are autocatalytic protein cleavage and splicing elements. A cysteine to alanine mutation at the N-terminal of inteins inhibits splicing and isolates the C-terminal cleavage reaction. Experiments indicate an enhanced C-terminal cleavage reaction rate upon decreasing the solution pH for the cleavage mutant, which cannot be explained by the existing mechanistic framework. We use intein crystal structure data and the information about conserved amino acids to perform semiempirical PM3 calculations followed by high-level density functional theory calculations in both gas phase and implicit solvent environments. Based on these calculations, we propose a detailed "low pH" mechanism for intein C-terminal cleavage. Water plays an important role in the proposed reaction mechanism, acting as an acid as well as a base. The protonation of the scissile peptide bond nitrogen by a hydronium ion is an important first step in the reaction. That step is followed by the attack of the C-terminal asparagine side chain on its carbonyl carbon, causing succinimide formation and simultaneous peptide bond cleavage. The computed reaction energy barrier in the gas phase is approximately 33 kcal/mol and reduces to approximately 25 kcal/mol in solution, close to the 21 kcal/mol experimentally observed at pH 6.0. This mechanism is consistent with the observed increase in C-terminal cleavage activity at low pH for the cleavage mutant of the Mycobacterium tuberculosis RecA mini-intein.

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.

Engineering an affinity tag for genetically encoded cyclic peptides

Peptide expression libraries are valuable probes of cellular function. SICLOPPS technology merges the principal advantages of both genetic methods and small-molecule approaches in yielding superior library sizes of operationally stable, structurally well-defined entities with an established biological and medicinal record. Here, we describe development, application, and the first-generation library implementation of an expressed affinity tag for a library of cyclic peptides. A tripeptide streptavidin-binding motif (HPQ) proved to be compatible with presentation from a backbone cyclized template. A resulting peptide was employed as a sensitive indicator of peptide splicing, expression, and recovery as well as an affinity tag for one-step purification. Specific recognition of the tag by streptavidin was also critical for an analysis of intein mutants. Finally, the initially identified probe was used as a template for design of a streptavidin-responsive cyclic peptide library.

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.