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.     

Characteristics of protein splicing in trans mediated by a semisynthetic split intein

Protein splicing in trans results in the ligation of two protein or peptide segments linked to appropriate intein fragments. We have characterized the trans-splicing reaction mediated by a naturally expressed, approximately 100-residue N-terminal fragment of the Mycobacterium tuberculosis intein and a synthetic peptide containing the 38 C-terminal intein residues, and found that the splicing reaction was very versatile and robust. The efficiency of splicing was nearly independent of temperature between 4 and 37 degrees C and pH between 6.0 and 7.5, with only a slight decline at pH values as high as 8.5. In addition, there was considerable flexibility in the choice of the C-terminal intein fragment, no significant difference in protein ligation efficiency being observed between reactions utilizing the N-terminal fragment and either the naturally expressed 107-residue C-terminal portion of the intein, much smaller synthetic peptides, or the 107-residue C-terminal intein fragment modified by fusion of a maltose binding protein domain to its N-terminus. The ability to use different types of the C-terminal intein fragments and a broad range of reaction conditions make protein splicing in trans a versatile tool for protein ligation.     

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 Mycobacterium xenopi GyrA protein splicing element: characterization of a minimal intein.

The 198-amino-acid in-frame insertion in the gyrA gene of Mycobacterium xenopi is the smallest known naturally occurring active protein splicing element (intein). Comparison with other mycobacterial gyrA inteins suggests that the M. xenopi intein underwent a complex series of events including (i) removal of 222 amino acids that encompass most of the central intein domain, and (ii) addition of a linker of unrelated residues. This naturally occurring genetic rearrangement is a representative characteristic of the taxon. The deletion process removes the conserved motifs involved in homing endonuclease activity. The linker insertion represents a structural requirement, as its mutation resulted in failure to splice. The M. xenopi GyrA intein thus provides a paradigm for a minimal protein splicing element.     

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.     

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).     

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.     

Sequence requirements for splicing by the Cne PRP8 intein

The dependence of protein splicing on conserved residues of the Cne PRP8 intein was assessed by alanine scanning mutagenesis in a foreign protein context. Corroboration was obtained for the involvement of residues at the splice junctions and of the conserved threonine and histidine of motif B. Five additional residues were identified as absolutely required for splicing. Variant W151A displayed premature C-terminal cleavage, not seen with other Cne PRP8 mutants. We propose a model whereby W151 acts to prevent premature C-terminal cleavage, favoring complete splicing as opposed to two disjointed cleavage events.     

Kinetic analysis of the individual steps of protein splicing for the Pyrococcus abyssi PolII intein

Protein splicing involves the excision of an intervening polypeptide, the intein, from flanking polypeptides, the exteins, concomitant with the specific ligation of the exteins. The intein that interrupts the DNA polymerase II DP2 subunit in Pyrococcus abyssi can be overexpressed and purified as an unspliced precursor, which allows for a detailed in vitro kinetic analysis of the individual steps of protein splicing. The first order rate constant for splicing of this intein, which has a non-canonical Gln at its C terminus, is 9.3 x 10(-6) s(-1) at 60 degrees C. The rate constant for splicing increases 3-fold with substitution of Asn for the C-terminal Gln. The pseudo first order rate constant of dithiothreitol-dependent N-terminal cleavage is 1 x 10(-4) s(-1). The first order rate constant of C-terminal cleavage is 1.2 x 10(-5) s(-1) with Gln at the C-terminal position, 2.8 x 10(-4) s(-1) with Asn, and decreases significantly with mutation of the penultimate His of the intein to Ala. N-terminal cleavage is most efficient between pH 7 and 7.5 and decreases at both more acidic and alkaline pH values, whereas C-terminal cleavage and splicing are both efficient over a broader range of pH values.     

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

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

Canonical protein splicing of a class 1 intein that has a class 3 noncanonical sequence motif

A Thermobifida fusca intein has two characteristics of class 3 inteins: a noncontiguous covariant Trp-Cys-Thr triplet and a Ser flanking its C terminus. However, it has Cys at position one, characteristic of class 1 inteins. Splicing does not require the internal Cys, which may instead coordinate the active site. Therefore, the intein is class 1.     

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

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

Reactivity of the cysteine residues in the protein splicing active center of the Mycobacterium tuberculosis RecA intein

Protein splicing involves the self-catalyzed excision of an intervening polypeptide segment, an intein, from a precursor protein. The first two steps in the protein splicing process lead to the formation of ester intermediates through nucleophilic attacks by the side chains of cysteine, serine, or threonine residues adjacent to the splice junctions. Since both nucleophilic residues in the Mycobacterium tuberculosis RecA intein are cysteine, their reactivities could be compared by sulfhydryl group titration. This was accomplished by using fusion proteins containing a truncated RecA intein modified by mutation to prevent protein splicing, in which the cysteines at the splice junctions were the only sulfhydryl groups. The ability to undergo hydroxylamine-induced cleavage at the upstream splice junction showed that the modified intein was not impaired in the ability to form ester intermediates. Sulfhydryl titration with iodoacetamide, monitored by quantitating the residual thiols after reaction with a maleimide derivative of biotin, revealed a striking difference in the apparent pK(a) values of the cysteines at the two splice junctions. The apparent pK(a) of the cysteine at the upstream splice junction, which initiates the N-S acyl rearrangement leading to the linear ester intermediate, was approximately 8.2, whereas that of the cysteine residue at the downstream splice junction, which initiates the transesterification reaction converting the linear ester to the branched ester intermediate, was about 5.8. This suggests that the transesterification step is facilitated by an unusually low pK(a) of the attacking thiol group. Comparison of the rates of cleavage of the linear ester intermediates derived from the M. tuberculosis RecA and the Saccharomyces cerevisiae VMA inteins by dithiothreitol and hydroxylamine revealed that the former reacted relatively more slowly with dithiothreitol, suggesting that the RecA intein has diverged in the course of evolution to react preferentially with thiolate anions and thus lacks the basic groups that may facilitate nucleophilic attack by thiols in other inteins.     

Protein splicing of a Pyrococcus abyssi intein with a C-terminal glutamine

Protein splicing involves the excision of an intervening polypeptide sequence, the intein, from a precursor protein and the concomitant ligation of the flanking polypeptides, the exteins, by a peptide bond. Most reported inteins have a C-terminal asparagine residue, and it has been shown that cyclization of this residue is coupled to peptide bond cleavage between the intein and C-extein. We show that the intein interrupting the DNA polymerase II DP2 subunit in Pyrococcus abyssi, which has a C-terminal glutamine, is capable of facilitating protein splicing. Substitution of an asparagine for the C-terminal glutamine moderately improves the rate and extent of protein splicing. However, substitution of an alanine for the penultimate histidine residue, with either asparagine or glutamine in the C-terminal position, prevents protein splicing and facilitates cleavage at the intein N terminus. The intein facilitates in vitro protein splicing only at temperatures above 30 degrees C and can be purified as a nonspliced precursor. This temperature dependence has enabled us to characterize the optimal in vitro splicing conditions and determine the rate constants for splicing as a function of temperature.     

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.     

Chemical dissection and reassembly of amyloid fibrils formed by a peptide fragment of transthyretin

We have examined the chemical dissection and subsequent reassembly of fibrils formed by a ten-residue peptide to probe the forces that drive the formation of amyloid. The peptide, TTR(10-19), encompasses the A strand of the inner beta-sheet structure that lines the thyroid hormone binding site of the human plasma protein transthyretin. When dissolved in water under low pH conditions the peptide readily forms amyloid fibrils. Electron microscopy of these fibrils indicates the presence of long (>1000 nm) rigid structures of uniform diameter (approximately 14 nm). Addition of urea (3 M) to preformed fibrils disrupts these rigid structures. The partially disrupted fibrils form flexible ribbon-like arrays, which are composed of a number of clearly visible protofilaments (3-4 nm diameter). These protofilaments are highly stable, and resist denaturation in 6 M urea at 75 degrees C over a period of hours. High concentrations (>50%, v/v) of 2,2,2-trifluoroethanol also dissociate TTR(10-19) fibrils to the constituent protofilaments, but these slowly dissociate to monomeric, soluble peptides with extensive alpha-helical structure. Dilution of the denaturant or co-solvent at the stage when dissociation to protofilaments has occurred results in the efficient reassembly of fibrils. These results indicate that assembly of fibrils from protofilaments involves relatively weak and predominantly hydrophobic interactions, whereas assembly of peptides into protofilaments involves both electrostatic and hydrophobic forces, resulting in a highly stable and compact structures.     

SufB intein splicing in Mycobacterium tuberculosis is influenced by two remote conserved N-extein histidines

Inteins are auto-processing domains that implement a multistep biochemical reaction termed protein splicing, marked by cleavage and formation of peptide bonds. They excise from a precursor protein, generating a functional protein via covalent bonding of flanking exteins. We report the kinetic study of splicing and cleavage reaction in [Fe–S] cluster assembly protein SufB from Mycobacterium tuberculosis (Mtu). Although it follows a canonical intein splicing pathway, distinct features are added by extein residues present in the active site. Sequence analysis identified two conserved histidines in the N-extein region; His-5 and His-38. Kinetic analyses of His-5Ala and His-38Ala SufB mutants exhibited significant reductions in splicing and cleavage rates relative to the SufB wildtype (WT) precursor protein. Structural analysis and molecular dynamics (MD) simulations suggested that Mtu SufB displays a unique mechanism where two remote histidines work concurrently to facilitate N-terminal cleavage reaction. His-38 is stabilized by the solvent-exposed His-5, and can impact N–S acyl shift by direct interaction with the catalytic Cys1. Development of inteins as biotechnological tools or as pathogen-specific novel antimicrobial targets requires a more complete understanding of such unexpected roles of conserved extein residues in protein splicing.     

Zinc inhibition of protein trans-splicing and identification of regions essential for splicing and association of a split intein*

Two important aspects of protein splicing were investigated by employing the trans-splicing intein from the dnaE gene of Synechocystis sp. PCC6803. First, we demonstrated that both protein splicing and cleavage at the N-terminal splice junction were inhibited in the presence of zinc ion. The trans-splicing reaction was partially blocked at a concentration of 1-10 microm Zn(2+) and completely inhibited at 100 microm Zn(2+); the inhibition by zinc was reversed in the presence of ethylenediaminetetraacetic acid. We propose that inactivation of Cys(160) at the C-terminal splice junction by the chelation of zinc affects both the N-S acyl rearrangement and the transesterification steps in the splicing pathway. Furthermore, in vivo and in vitro assays were established for the determination of intein residues and regions required for splicing or association between the N- and C-terminal intein halves. N-terminal truncation of the intein C-terminal segment inhibited both splicing and association activities, suggesting this region is crucial for the formation of an interface between the two intein halves. The replacement of conserved residues in blocks B and F with alanine abolished splicing but allowed for association. This is the first evidence showing that the conserved residues in block F are required for protein splicing.     

A conserved threonine spring‐loads precursor for intein splicing

Protein splicing is an autocatalytic process where an “intein” self‐cleaves from a precursor and ligates the flanking N‐ and C‐“extein” polypeptides. Inteins occur in all domains of life and have myriad uses in biotechnology. Although the reaction steps of protein splicing are known, mechanistic details remain incomplete, particularly the initial peptide rearrangement at the N‐terminal extein/intein junction. Recently, we proposed that this transformation, an N‐S acyl shift, is accelerated by a localized conformational strain, between the intein's catalytic cysteine (Cys1) and the neighboring glycine (Gly‐1) in the N‐extein. That proposal was based on the crystal structure of a catalytically competent trapped precursor. Here, we define the structural origins and mechanistic relevance of the conformational strain using a combination of quantum mechanical simulations, mutational analysis, and X‐ray crystallography. Our results implicate a conserved, but largely unstudied, threonine residue of the Ssp DnaE intein (Thr69) as the mediator of conformational strain through hydrogen bonding. Further, the strain imposed by this residue is shown to position the splice junction in a manner that enhances the rate of the N‐S acyl shift substantially. Taken together, our results not only provide fundamental understanding of the control of the first step of protein splicing but also have important implications in various biotechnological applications that require precursor manipulation.