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.     

NMR resonance assignment of DnaE intein from Nostoc punctiforme

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

An Engineered Palette of Metal Ion Quenchable Fluorescent Proteins

Many fluorescent proteins have been created to act as genetically encoded biosensors. With these sensors, changes in fluorescence report on chemical states in living cells. Transition metal ions such as copper, nickel, and zinc are crucial in many physiological and pathophysiological pathways. Here, we engineered a spectral series of optimized transition metal ion-binding fluorescent proteins that respond to metals with large changes in fluorescence intensity. These proteins can act as metal biosensors or imaging probes whose fluorescence can be tuned by metals. Each protein is uniquely modulated by four different metals (Cu²⁺, Ni²⁺, Co²⁺, and Zn²⁺). Crystallography revealed the geometry and location of metal binding to the engineered sites. When attached to the extracellular terminal of a membrane protein VAMP2, dimeric pairs of the sensors could be used in cells as ratiometric probes for transition metal ions. Thus, these engineered fluorescent proteins act as sensitive transition metal ion-responsive genetically encoded probes that span the visible spectrum.     

Structure–activity studies on the upstream splice junction of a semisynthetic intein

Protein trans-splicing by split inteins holds great potential for the chemical modification and semisynthesis of proteins. However, the structural requirements of the extein sequences immediately flanking the intein are only poorly understood. This knowledge is of particular importance for protein labeling, when synthetic moieties are to be attached to the protein of interest as seamlessly as possible. Using the semisynthetic Ssp DnaB intein both in form of its wild-type sequence and its evolved M86 mutant, we systematically varied the sequence upstream of the short synthetic Int^N fragment using both proteinogenic amino acids and unnatural building blocks. We could show for the wild-type variant that the native N-extein sequence could be reduced to the glycine residue at the (?1) position directly flanking the intein without significant loss of activity. The glycine at this position is strongly preferred over building blocks containing a phenyl group or extended alkyl chain adjacent to the scissile amide bond of the N-terminal splice junction. Despite their negative effects on the splicing yields, these unnatural substrates were well processed in the N–S acyl shift to form the respective thioesters and did not result in an increased decoupling of the asparagine cyclization step at the C-terminal splicing junction. Therefore, the transesterification step appeared to be the bottleneck of the protein splicing pathway. The fluorophore 7-hydroxycoumarinyl-4-acetic acid as a minimal N-extein was efficiently ligated to the model protein, in particular with the M86 mutant, probably because of its higher resemblance to glycine with an aliphatic c-α carbon atom at the (?1) position. This finding indicates a way for the virtually traceless labeling of proteins without inserting extra flanking residues. Due to its overall higher activity, the M86 mutant appears most promising for many protein labeling and chemical modification schemes using the split intein approach.     

Molecular dissection of the Mycobacterium tuberculosis RecA intein: design of a minimal intein and of a trans-splicing system involving two intein fragments

Most protein-splicing elements (inteins) function both as catalysts of protein splicing and as homing endonucleases. In order to identify the domains of inteins that are essential for protein splicing, the intein sequence embedded in the recA gene of Mycobacterium tuberculosis was genetically dissected. The effect of various modifications of the intein on the ability to mediate splicing was studied in Escherichia coli transformed with plasmids in which the coding sequence for the RecA intein was inserted in-frame between coding regions for the E. coli maltose-binding protein and a polypeptide containing a hexahistidine sequence as the N- and C-exteins, respectively. One type of genetic alteration of the RecA intein involved deletion of the the central region encoding 229 amino acids (aa), representing the entire homing endonuclease homology domain. The residual intein (211 aa plus an undecapeptide spacer) was able to promote protein splicing as efficiently as the wild-type intein, indicating that the homing endonuclease domain plays no role in the protein-splicing process and that the protein-splicing active center is confined to the N- and C-terminal segments of the intein, less than 110 aa each. Another type of alteration involved the introduction of overlapping translation termination and initiation codons in-frame into the intein coding region. The modified RecA intein, although synthesized as two separate components, could nevertheless mediate protein splicing, indicating that the N- and C-terminal protein-splicing domains can interact with sufficient affinity and specificity to allow protein-splicing to occur in trans. The efficiency of trans-splicing was much enhanced when the homing endonuclease domain was entirely deleted so that the length of the interacting N- and C-terminal intein fragments was only about 110 aa each.     

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

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

Structural stability and endonuclease activity of a PI-SceI GFP-fusion protein

Homing endonucleases are site-specific and rare cutting endonucleases often encoded by intron or intein containing genes. They lead to the rapid spread of the genetic element that hosts them by a process termed 'homing'; and ultimately the allele containing the element will be fixed in the population. PI-SceI, an endonuclease encoded as a protein insert or intein within the yeast V-ATPase catalytic subunit encoding gene (vma1), is among the best characterized homing endonucleases. The structures of the Sce VMA1 intein and of the intein bound to its target site are known. Extensive biochemical studies performed on the PI-SceI enzyme provide information useful to recognize critical amino acids involved in self-splicing and endonuclease functions of the protein. Here we describe an insertion of the Green Fluorescence Protein (GFP) into a loop which is located between the endonuclease and splicing domains of the Sce VMA1 intein. The GFP is functional and the additional GFP domain does not prevent intein excision and endonuclease activity. However, the endonuclease activity of the newly engineered protein was different from the wild-type protein in that it required the presence of Mn(2+) and not Mg(2+) metal cations for activity.     

Regulation of protein activity with small-molecule-controlled inteins

Inteins are the protein analogs of self-splicing RNA introns, as they post-translationally excise themselves from a variety of protein hosts. Intein insertion abolishes, in general, the activity of its host protein, which is subsequently restored upon intein excision. These protein elements therefore have the potential to be used as general molecular "switches" for the control of arbitrary target proteins. Based on rational design, an intein-based protein switch has been constructed whose splicing activity is conditionally triggered in vivo by the presence of thyroid hormone or synthetic analogs. This modified intein was used in Escherichia coli to demonstrate that a number of different proteins can be inactivated by intein insertion and then reactivated by the addition of thyroid hormone via ligand-induced splicing. This conditional activation was also found to occur in a dose-dependent manner. Rational protein engineering was then combined with genetic selection to evolve an additional intein whose activity is controlled by the presence of synthetic estrogen ligands. The ability to regulate protein function post-translationally through the use of ligand-controlled intein splicing will most likely find applications in metabolic engineering, drug discovery and delivery, biosensing, molecular computation, as well as many additional areas of biotechnology.     

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

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

Post-translational environmental switch of RadA activity by extein–intein interactions in protein splicing

Post-translational control based on an environmentally sensitive intervening intein sequence is described. Inteins are invasive genetic elements that self-splice at the protein level from the flanking host protein, the exteins. Here we show in Escherichia coli and in vitro that splicing of the RadA intein located in the ATPase domain of the hyperthermophilic archaeon Pyrococcus horikoshii is strongly regulated by the native exteins, which lock the intein in an inactive state. High temperature or solution conditions can unlock the intein for full activity, as can remote extein point mutations. Notably, this splicing trap occurs through interactions between distant residues in the native exteins and the intein, in three-dimensional space. The exteins might thereby serve as an environmental sensor, releasing the intein for full activity only at optimal growth conditions for the native organism, while sparing ATP consumption under conditions of cold-shock. This partnership between the intein and its exteins, which implies coevolution of the parasitic intein and its host protein may provide a novel means of post-translational control.     

Protein Trans-Splicing of Multiple Atypical Split Inteins Engineered from Natural Inteins

Protein trans-splicing by split inteins has many uses in protein production and research. Splicing proteins with synthetic peptides, which employs atypical split inteins, is particularly useful for site-specific protein modifications and labeling, because the synthetic peptide can be made to contain a variety of unnatural amino acids and chemical modifications. For this purpose, atypical split inteins need to be engineered to have a small N-intein or C-intein fragment that can be more easily included in a synthetic peptide that also contains a small extein to be trans-spliced onto target proteins. Here we have successfully engineered multiple atypical split inteins capable of protein trans-splicing, by modifying and testing more than a dozen natural inteins. These included both S1 split inteins having a very small (11–12 aa) N-intein fragment and S11 split inteins having a very small (6 aa) C-intein fragment. Four of the new S1 and S11 split inteins showed high efficiencies (85–100%) of protein trans-splicing both in E. coli cells and in vitro. Under in vitro conditions, they exhibited reaction rate constants ranging from ∼1.7×10⁻⁴ s⁻¹ to ∼3.8×10⁻⁴ s⁻¹, which are comparable to or higher than those of previously reported atypical split inteins. These findings should facilitate a more general use of trans-splicing between proteins and synthetic peptides, by expanding the availability of different atypical split inteins. They also have implications on understanding the structure-function relationship of atypical split inteins, particularly in terms of intein fragment complementation.     

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

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

Protein Trans-Splicing of an Atypical Split Intein Showing Structural Flexibility and Cross-Reactivity

Inteins catalyze a protein splicing reaction to excise the intein from a precursor protein and join the flanking sequences (exteins) with a peptide bond. In a split intein, the intein fragments (I_N and I_C) can reassemble non-covalently to catalyze a trans-splicing reaction that joins the exteins from separate polypeptides. An atypical split intein having a very small I_N and a large I_C is particularly useful for joining synthetic peptides with recombinant proteins, which can be a generally useful method of introducing site-specific chemical labeling or modifications into proteins. However, a large I_C derived from an Ssp DnaX intein was found recently to undergo spontaneous C-cleavage, which raised questions regarding its structure-function and ability to trans-splice. Here, we show that this I_C could undergo trans-splicing in the presence of I_N, and the trans-splicing activity completely suppressed the C-cleavage activity. We also found that this I_C could trans-splice with small I_N sequences derived from two other inteins, showing a cross-reactivity of this atypical split intein. Furthermore, we found that this I_C could trans-splice even when the I_N sequence was embedded in a nearly complete intein sequence, suggesting that the small I_N could project out of the central pocket of the intein to become accessible to the I_C. Overall, these findings uncovered a new atypical split intein that can be valuable for peptide-protein trans-splicing, and they also revealed an interesting structural flexibility and cross-reactivity at the active site of this intein.     

Expression of antibodies using single‐open reading frame vector design and polyprotein processing from mammalian cells

We describe a novel polyprotein precursor‐based approach to express antibodies from mammalian cells. Rather than expressing heavy and light chain proteins from separate expression units, the antibody heavy and light chains are contained in one single‐open reading frame (sORF) separated by an intein gene fused in frame. Inside mammalian cells this ORF is transcribed into a single mRNA, and translated into one polypeptide. The antibody heavy and light chains are separated posttranslationally, assembled into the functional antibody molecule, and secreted into culture medium. It is demonstrated that Pol I intein from P. horikoshii mediates protein splicing and cleavage reactions in mammalian cells, in the context of antibody heavy and light chain amino acid sequences. To allow the separation of antibody heavy chain, light chain, and the intein, we investigated a number of intein mutations designed to inhibit intein‐mediated splicing but preserve cleavage reactions. We have also designed constructs in which the signal peptide downstream from intein has altered hydrophobicity. The use of some of these mutant constructs resulted in more efficient antibody secretion, highlighting areas that can be further explored in improving such an expression system. An antibody secreted using one of the sORF constructs was characterized. This antibody has correct N‐terminal sequences for both of its heavy and light chains, correct heavy and light chain MW as well as intact MW as measured by mass spectrometry. Its affinity to antigen, as measured by surface plasmon resonance (SPR), is indistinguishable from that of the same antibody produced using conventional method. © 2009 American Institute of Chemical Engineers Biotechnol. Prog., 2009     

Backbone Dynamics and Global Effects of an Activating Mutation in Minimized Mtu RecA Inteins

Inteins mediate protein splicing, which has found many applications in biotechnology and protein engineering. A single valine-to-leucine mutation (V67L) can globally enhance splicing and related cleavage reactions in minimized Mycobacterium tuberculosis RecA inteins. However, V67L mutation causes little change in crystal structures. To test whether protein dynamics contribute to activity enhancement in the V67L mutation, we have studied the conformations and dynamics of the minimized and engineered intein ΔΔIhh-V67CM and a single V67L mutant, ΔΔIhh-L67CM, by solution NMR. Chemical shift perturbations established that the V67L mutation causes global changes, including changes at the N-terminus and C-terminus of the intein, which are active sites for protein splicing. The single V67L mutation significantly slows hydrogen-exchange rates globally, indicating a shift to more stable conformations and reduction in ensemble distribution. Whereas the V67L mutation causes little change for motions on the picosecond-to-nanosecond timescale, motions on the microsecond-to-millisecond timescale affect a region involving the conserved F-block histidine and C-terminal asparagine, which are residues important for C-terminal cleavage. The V67L mutation is proposed to activate splicing by reducing the ensemble distribution of the intein structure and by modifying the active sites.     

1H, 13C, and 15N NMR assignments of the Pyrococcus abyssi DNA polymerase II intein

Protein splicing is a precise post-translational process mediated by inteins. Inteins are intervening proteins that cleave themselves from a precursor protein while joining the flanking sequences. Here we report the ¹⁵N, ¹³C, and ¹H chemical shift assignments of the intein from DNA polymerase II of Pyrococcus abyssi (Pab PolII intein), which has been recombinantly overexpressed and isotopically labeled. The NMR assignments of Pab PolII intein are essential for solution structure determination and protein dynamics study.     

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.     

Degeneration of a homing endonuclease and its target sequence in a wild yeast strain

Mobile introns and inteins self-propagate by ‘homing’, a gene conversion process initiated by site-specific homing endonucleases. The VMA intein, which encodes the PI-SceI endonuclease in Saccharomyces cerevisiae, is present in several different yeast strains. Surprisingly, a wild wine yeast (DH1-1A) contains not only the intein⁺ allele, but also an inteinless allele that has not undergone gene conversion. To elucidate how these two alleles co-exist, we characterized the endonuclease encoded by the DH1-1A intein⁺ allele and the target site in the intein^– allele. Sequence analysis reveals seven mutations in the 31 bp recognition sequence, none of which occurs at positions that are individually critical for activity. However, binding and cleavage of the sequence by PI-SceI is reduced 10-fold compared to the S.cerevisiae target. The PI-SceI analog encoded by the DH1-1A intein⁺ allele contains 11 mutations at residues in the endonuclease and protein splicing domains. None affects protein splicing, but one, a R417Q substitution, accounts for most of the decrease in DNA cleavage and DNA binding activity of the DH1-1A protein. Loss of activity in the DH1-1A endonuclease and target site provides one explanation for co-existence of the intein⁺ and intein^– alleles.     

Generation of Metal-Binding Staphylococci through Surface Display of Combinatorially Engineered Cellulose-Binding Domains

Ni²⁺-binding staphylococci were generated through surface display of combinatorially engineered variants of a fungal cellulose-binding domain (CBD) from Trichoderma reesei cellulase Cel7A. Novel CBD variants were generated by combinatorial protein engineering through the randomization of 11 amino acid positions, and eight potentially Ni²⁺-binding CBDs were selected by phage display technology. These new variants were subsequently genetically introduced into chimeric surface proteins for surface display on Staphylococcus carnosus cells. The expressed chimeric proteins were shown to be properly targeted to the cell wall of S. carnosus cells, since full-length proteins could be extracted and affinity purified. Surface accessibility for the chimeric proteins was demonstrated, and furthermore, the engineered CBDs, now devoid of cellulose-binding capacity, were shown to be functional with regard to metal binding, since the recombinant staphylococci had gained Ni²⁺-binding capacity. Potential environmental applications for such tailor-made metal-binding bacteria as bioadsorbents in biofilters or biosensors are discussed.     

Split dnaE genes encoding multiple novel inteins in Trichodesmium erythraeum

Three inteins were found when analyzing a pair of split dnaE genes encoding the catalytic subunit of DNA polymerase III in the oceanic N2-fixing cyanobacterium Trichodesmium erythraeum. The three inteins (DnaE-1, DnaE-2, and DnaE-3) were clustered in a 70-amino acid (aa) region of the predicted DnaE protein. The DnaE-1 intein is 1258 aa long and three times as large as a typical intein, due to the presence of large tandem repeats in which a 57-aa sequence is repeated 17 times. The DnaE-2 intein has a more typical size of 428 aa with putative protein splicing and endonuclease domains. The DnaE-3 intein is a split intein consisting of a 102-aa N-terminal part and a 36-aa C-terminal part encoded on the first and second split dnaE genes, respectively. Synthesis of a mature DnaE protein is predicted to involve expression of two split dnaE genes followed by two protein cis-splicing reactions and one protein trans-splicing reaction. Tandem repeats in the DnaE-1 intein inhibited the protein splicing activity of this intein when tested in Escherichia coli cells and may potentially regulate DnaE synthesis in vivo.