Intein-containing chimeric protein construction and evaluation of its cleavage conditions

Protein splicing is a post-translational autocatalytic process that results in excision of internal peptide (intein) from a precursor protein and the ligation of the flanking protein sequences (exteins). High specificity of the intein-mediated excision of protein precursors allows the use of protein splicing in biotechnology. This work was aimed at the obtaining of human growth hormone with a native N-terminus in E. coli. Chimerical protein consisting of a short N-terminal peptide, Mxe GyrA intein and human growth hormone was created. During the translation formyl-methionine modified N-terminal peptide should have been removed by splicing. Intein was shown to mediate the cleavage of exteins, but their subsequent ligation was not observed. That allowed the preparation of human growth hormone with a native N-terminus. The effect of various factors on cleavage efficiency was studied. The most efficient cleavage of chimeric protein (60-80%) was achieved in the presence of inductor (100 mM beta-mercaptoethanol) upon the incubation for 4-6 days.     

Characterization of a self-splicing mini-intein and its conversion into autocatalytic N- and C-terminal cleavage elements: facile production of protein building blocks for protein ligation

The determinants governing the self-catalyzed splicing and cleavage events by a mini-intein of 154 amino acids, derived from the dnaB gene of Synechocystis sp. were investigated. The residues at the splice junctions have a profound effect on splicing and peptide bond cleavage at either the N- or C-terminus of the intein. Mutation of the native Gly residue preceding the intein blocked splicing and cleavage at the N-terminal splice junction, while substitution of the intein C-terminal Asn154 resulted in the modulation of N-terminal cleavage activity. Controlled cleavage at the C-terminal splice junction involving cyclization of Asn154 was achieved by substitution of the intein N-terminal cysteine residue with alanine and mutation of the native C-extein residues. The C-terminal cleavage reaction was found to be pH-dependent, with an optimum between pH6.0 and 7.5. These findings allowed the development of single junction cleavage vectors for the facile production of proteins as well as protein building blocks with complementary reactive groups. A protein sequence was fused to either the N-terminus or C-terminus of the intein, which was fused to a chitin binding domain. The N-terminal cleavage reaction was induced by 2-mercaptoethanesulfonic acid and released the 43kDa maltose binding protein with an active C-terminal thioester. The 58kDa T4 DNA ligase possessing an N-terminal cysteine was generated by a C-terminal cleavage reaction induced by pH and temperature shifts. The intein-generated proteins were joined together through a native peptide bond. This intein-mediated protein ligation approach opens up novel routes in protein engineering.     

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.     

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

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

Protein splicing 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 of the three Pyrococcus abyssi ribonucleotide reductase inteins

An intein is a polypeptide that interrupts the functional domains of a protein, called the exteins. The intein can facilitate its own excision from the exteins, concomitant with the ligation of the exteins, in a process called protein splicing. The alpha subunit of the ribonucleotide reductase of the extreme thermophile Pyrococcus abyssi is interrupted by three inteins in separate insertion sites. Each intein can facilitate protein splicing when over-expressed in Escherichia coli, with affinity domains serving as the exteins. The influence of the N-terminal flanking residue on the efficiency of splicing is specific to each intein. Each intein has a different downstream nucleophilic residue, and cannot tolerate substitution to a residue of lesser or equal nucleophilicity. The influence of the conserved penultimate His also differs between the inteins.     

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.     

Control of protein splicing by intein fragment reassembly.

Inteins are protein splicing elements that mediate their excision from precursor proteins and the joining of the flanking protein sequences (exteins). In this study, protein splicing was controlled by splitting precursor proteins within the Psp Pol-1 intein and expressing the resultant fragments in separate hosts. Reconstitution of an active intein was achieved by in vitro assembly of precursor fragments. Both splicing and intein endonuclease activity were restored. Complementary fragments from two of the three fragmentation positions tested were able to splice in vitro. Fragments resulting in redundant overlaps of intein sequences or containing affinity tags at the fragmentation sites were able to splice. Fragment pairs resulting in a gap in the intein sequence failed to splice or cleave. However, similar deletions in unfragmented precursors also failed to splice or cleave. Single splice junction cleavage was not observed with single fragments. In vitro splicing of intein fragments under native conditions was achieved using mini exteins. Trans-splicing allows differential modification of defined regions of a protein prior to extein ligation, generating partially labeled proteins for NMR analysis or enabling the study of the effects of any type of protein modification on a limited region of a protein.     

Intein-mediated ligation and cyclization of expressed proteins

Protein splicing is a posttranslational processing event that releases an internal protein sequence from a protein precursor. During the splicing process the internal protein sequence, termed an intein, embedded in the protein precursor self-catalyzes its excision and the ligation of the flanking protein regions, termed exteins. The dissection of the splicing pathway, which involves the precise cleavage and formation of peptide bonds, and the identification of key catalytic residues at the splice junctions have led to the modulation of the protein splicing process as a protein engineering tool. Novel strategies have been developed to use intein-catalyzed reactions for the production and manipulation of proteins and peptides. These new approaches have broken down the size limitation barrier of chemical synthetic methods and are less technically demanding. The purpose of this article is to describe how to use self-splicing inteins in protein semisynthesis and backbone cyclization. The first two sections of the article provide a brief review of the distinct chemical steps that underlie protein splicing and intein enabled technology.     

Reversible inhibition of protein splicing by zinc ion

Protein splicing involves the self-catalyzed excision of a protein-splicing element, the intein, from flanking polypeptides, the exteins, which are concomitantly joined by a peptide bond. Taking advantage of recently developed in vitro systems in which protein splicing occurs in trans to assay for protein-splicing inhibitors, we discovered that low concentrations of Zn(2+) inhibited splicing mediated both by the RecA intein from Mycobacterium tuberculosis and by the naturally split DnaE intein from Synechocystis sp. PCC6803. Inhibition by Zn(2+) was also observed with a cis-splicing system involving the RecA intein. In all experimental systems used, inhibition by Zn(2+) could be completely reversed by the addition of EDTA. Zinc ion also inhibited hydroxylamine-dependent N-terminal cleavage of the RecA intein. All other divalent transition metal ions tested were less effective as inhibitors than Zn(2+). The reversible inhibition by Zn(2+) should be useful in studies of the mechanism of protein splicing and allow structural studies of unmodified protein-splicing precursors.     

Utilization of protein splicing for purification of the human growth hormone

Developing simple and reliable methods to purify recombinant proteins is among the most important problems of modern biotechnology. It is of particular interest to take advantage of protein splicing for this purpose. Affinity tagging of inteins allows the use of regular protocols for protein purification. Autocatalytic excision of the tagged intein yields the pure protein lacking N-terminal formylmethionine. A new purification technique was developed on the basis of protein splicing for the human growth hormone. The Mxe GyrA intein with the histidine tag or cellulose-binding domain was used as a self-removable affinity unit. The resulting two-step purification protocol makes it possible to obtain the human growth hormone having the native N terminus with minimal losses.     

内含肽介导的生物学效应及其应用

蛋白质翻译产物在成熟过程中剪切释放出来的一段氨基酸序列称为“intein”---即内含肽。它与前体蛋白以框内融合的形式共同翻译,并内嵌于前体蛋白序列中。内含肽的解离以及内含肽两侧氨基酸序列的连接是在内含肽自身催化作用下完成的。本文将从内含肽的发现、结构特征和作用机理等方面对这种具有特殊意义的蛋白质成熟机制进行较为全面的论述,同时介绍了近年来发展起来的以内含肽介导的蛋白质剪接为基础的蛋白质纯化和改造技术。     

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.     

蛋白质剪切及其应用

蛋白质剪切是一种翻译后修饰事件 ,它将插入前体蛋白的中间的蛋白质肽段 (Intein ,internalproteinfrag ment)剪切出来 ,并用正常肽键将两侧蛋白质多肽链 (Extein ,flankingproteinfragments)连接起来。在此过程中不需要辅酶或辅助因子的作用 ,仅需四步分子内反应。Intein及其侧翼序列可以通过突变产生高度特异性的自我切割用于蛋白质纯化、蛋白质连接和蛋白质环化反应 ,在蛋白质工程方面有广泛的应用前景。     

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.     

Intein-mediated protein ligation: harnessing nature's escape artists

Inteins are naturally occurring proteins that are involved in the precise cleavage and formation of peptide bonds in a process known as protein splicing. Genetic engineering has allowed the controllable cleavage of peptide bonds at either the N- or C-terminus of the intein. Inteins displaying controllable cleavage have been used in the isolation of bacterially expressed proteins possessing either a C-terminal thioester or an N-terminal cysteine. The specific placement of these reactive groups has allowed either protein-protein or protein-peptide condensation through a native peptide bond. This review describes the methods used to specifically generate these reactive groups on bacterially expressed proteins and some applications of this technique, known as intein-mediated protein ligation. Furthermore, a versatile two intein (TWIN) system will be described which enables the circularization and polymerization of bacterially expressed proteins or peptides.     

Protein splicing mechanisms and applications

Inteins are protein splicing elements that employ standard enzyme strategies to excise themselves from precursor proteins and ligate the surrounding sequences (exteins). The protein splicing pathway consists of four nucleophilic displacements directed by the intein plus the first C-extein residue. The intein active site(s) are formed by folding of the intein within the precursor, which brings together the splice junctions and internal intein residues that assist catalysis. Inteins with non-canonical catalytic residues splice by modified pathways. Understanding intein proteolytic cleavage and ligation activities has led to the development of many novel applications in the fields of protein engineering, enzymology, microarray production, target detection and activation of transgenes in plants. Recent advances include intein-mediated attachment of proteins to solid supports for microarray or western blot analysis, linking nucleic acids to proteins and controllable splicing, which converts inteins into molecular switches.     

Faster Protein Splicing with the Nostoc punctiforme DnaE Intein Using Non-native Extein Residues

Inteins are naturally occurring intervening sequences that catalyze a protein splicing reaction resulting in intein excision and concatenation of the flanking polypeptides (exteins) with a native peptide bond. Inteins display a diversity of catalytic mechanisms within a highly conserved fold that is shared with hedgehog autoprocessing proteins. The unusual chemistry of inteins has afforded powerful biotechnology tools for controlling enzyme function upon splicing and allowing peptides of different origins to be coupled in a specific, time-defined manner. The extein sequences immediately flanking the intein affect splicing and can be defined as the intein substrate. Because of the enormous potential complexity of all possible flanking sequences, studying intein substrate specificity has been difficult. Therefore, we developed a genetic selection for splicing-dependent kanamycin resistance with no significant bias when six amino acids that immediately flanked the intein insertion site were randomized. We applied this selection to examine the sequence space of residues flanking the Nostoc punctiforme Npu DnaE intein and found that this intein efficiently splices a much wider range of sequences than previously thought, with little N-extein specificity and only two important C-extein positions. The novel selected extein sequences were sufficient to promote splicing in three unrelated proteins, confirming the generalizable nature of the specificity data and defining new potential insertion sites for any target. Kinetic analysis showed splicing rates with the selected exteins that were as fast or faster than the native extein, refuting past assumptions that the naturally selected flanking extein sequences are optimal for splicing.     

蛋白质剪接研究进展

蛋白质剪接是一个翻译后自催化加工过程,它不需要酶或其他辅助因子的参与。在这个过程中,前体蛋白的Intein(内含肽)被切离,其两侧的Extein(外显肽)连接在一起。Intein按结构可分为经典Intein和微型Intein,其中的经典Intein包括Hint结构域和中间的归巢内切酶结构域(该结构域在微型内含肽中不存在)。蛋白质剪接及其他具有Hint结构域的蛋白加工过程的起始步骤是N-S/O酰基重排反应,该反应是由Hint结构域催化的;Intein的剪接还分为顺式剪接和反式剪接,通过对Intein进行改造,可以阻断剪接过程,但不影响N端肽键或C端肽键的断裂;通过筛选突变体,可以获得温度敏感型、pH敏感型或小分子诱导型的内含肽。这些研究促进了Intein在多肽制备及其它方面的应用。     

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.