Preorganized cyclic modules facilitate the self-assembly of protein nanostructures

The rational design of supramolecular assemblies aims to generate complex systems based on the simple information encoded in the chemical structure. Programmable molecules such as nucleic acids and polypeptides are particularly suitable for designing diverse assemblies and shapes not found in nature. Here, we describe a strategy for assembling modular architectures based on structurally and covalently preorganized subunits. Cyclization through spontaneous self-splicing of split intein and coiled-coil dimer-based interactions of polypeptide chains provide structural constraints, facilitating the desired assembly. We demonstrate the implementation of a strategy based on the preorganization of the subunits by designing a two-chain coiled-coil protein origami (CCPO) assembly that adopts a tetrahedral topology only when one or both subunit chains are covalently cyclized. Employing this strategy, we further design a 109 kDa trimeric CCPO assembly comprising 24 CC-forming segments. In this case, intein cyclization was crucial for the assembly of a concave octahedral scaffold, a newly designed protein fold. The study highlights the importance of preorganization of building modules to facilitate the self-assembly of higher-order supramolecular structures.

Molecular docking and MD simulations reveal protease inhibitors block the catalytic residues in Prp8 intein of Aspergillus fumigatus: a potential target for antimycotics

Resistance to azoles and amphotericin B especially in Aspergillus fumigatus is a growing concern towards the treatment of invasive fungal infection. At this critical juncture, intein splicing would be a productive, and innovative target to establish therapies against resistant strains. Intein splicing is the central event for the activation of host protein, essential for the growth and survival of various microorganisms including A. fumigatus. The splicing process is a four-step protease-like nucleophilic cascade. Thus, we hypothesise that protease inhibitors would successfully halt intein splicing and potentially restrict the growth of the aforementioned pathogen. Using Rosetta Fold and molecular dynamics simulations, we modelled Prp8 intein structure; resembling classic intein fold with horse shoe shaped splicing domain. To fully comprehend the active site of Afu Prp8 intein, C1, T62, H65, H818, N819 from intein sequences and S820, the first C-extein residue are selected. Molecular docking shows that two FDA-approved drugs, i.e. Lufotrelvir and Remdesivir triphosphate efficiently interact with Prp8 intein from the assortment of 212 protease inhibitors. MD simulation portrayed that Prp8 undergoes conformational change upon ligand binding, and inferred the molecular recognition and stability of the docked complexes. Per-residue decomposition analysis confirms the importance of F: block R802, V803, and Q807 binding pocket in intein splicing domain towards recognition of inhibitors, along with active site residues through strong hydrogen bonds and hydrophobic contacts. However, in vitro and in vivo assays are required to confirm the inhibitory action on Prp8 intein splicing; which may pave the way for the development of new antifungals for A. fumigatus.Communicated by Ramaswamy H. Sarma.

Protein Macrocyclization for Tertiary Structure Stabilization

Proteins possess unique molecular recognition capabilities and enzymatic activities, features that are usually tied to a particular tertiary structure. To make use of proteins for biotechnological and biomedical purposes, it is often required to enforce their tertiary structure in order to ensure sufficient stability under the conditions inherent to the application of interest. The introduction of intramolecular crosslinks has proven efficient in stabilizing native protein folds. Herein, we give an overview of methods that allow the macrocyclization of expressed proteins, discussing involved reaction mechanisms and structural implications.

Methods for generating and screening libraries of genetically encoded cyclic peptides in drug discovery

Drug discovery has traditionally focused on using libraries of small molecules to identify therapeutic drugs, but new modalities, especially libraries of genetically encoded cyclic peptides, are increasingly used for this purpose. Several technologies now exist for the production of libraries of cyclic peptides, including phage display, mRNA display and split-intein circular ligation of peptides and proteins. These different approaches are each compatible with particular methods of screening libraries, such as functional or affinity-based screening, and screening in vitro or in cells. These techniques allow the rapid preparation of libraries of hundreds of millions of molecules without the need for chemical synthesis, and have therefore lowered the entry barrier to generating and screening for inhibitors of a given target. This ease of use combined with the inherent advantages of the cyclic-peptide scaffold has yielded inhibitors of targets that have proved difficult to drug with small molecules. Multiple reports demonstrate that cyclic peptides act as privileged scaffolds in drug discovery, particularly against 'undruggable' targets such as protein-protein interactions. Although substantial challenges remain in the clinical translation of hits from screens of cyclic-peptide libraries, progress continues to be made in this area, with an increasing number of cyclic peptides entering clinical trials. Here, we detail the various platforms for producing and screening libraries of genetically encoded cyclic peptides and discuss and evaluate the advantages and disadvantages of each approach when deployed for drug discovery.

Self-cleavage of the Pseudomonas aeruginosa Cell-surface Signaling Anti-sigma Factor FoxR Occurs through an N-O Acyl Rearrangement

The Fox system of Pseudomonas aeruginosa is a cell-surface signaling (CSS) pathway employed by the bacterium to sense and respond to the presence of the heterologous siderophore ferrioxamine in the environment. This regulatory pathway controls the transcription of the foxA ferrioxamine receptor gene through the extracytoplasmic function sigma factor σ(FoxI). In the absence of ferrioxamine, the activity of σ(FoxI) is inhibited by the transmembrane anti-sigma factor FoxR. Upon binding of ferrioxamine by the FoxA receptor, FoxR is processed by a complex proteolytic cascade leading to the release and activation of σ(FoxI). Interestingly, we have recently shown that FoxR undergoes self-cleavage between the periplasmic Gly-191 and Thr-192 residues independent of the perception of ferrioxamine. This autoproteolytic event, which is widespread among CSS anti-sigma factors, produces two distinct domains that interact and function together to transduce the presence of the signal. In this work, we provide evidence that the self-cleavage of FoxR is not an enzyme-dependent process but is induced by an N-O acyl rearrangement. Mutation analysis showed that the nucleophilic side chain of the Thr-192 residue at +1 of the cleavage site is required for an attack on the preceding Gly-191, after which the resulting ester bond is likely hydrolyzed. Because the cleavage site is well preserved and the hydrolysis of periplasmic CSS anti-sigma factors is widely observed, we hypothesize that cleavage via an N-O acyl rearrangement is a conserved feature of these proteins.

A dual-intein autoprocessing domain that directs synchronized protein co-expression in both prokaryotes and eukaryotes

Being able to coordinate co-expression of multiple proteins is necessary for a variety of important applications such as assembly of protein complexes, trait stacking, and metabolic engineering. Currently only few options are available for multiple recombinant protein co-expression, and most of them are not applicable to both prokaryotic and eukaryotic hosts. Here, we report a new polyprotein vector system that is based on a pair of self-excising mini-inteins fused in tandem, termed the dual-intein (DI) domain, to achieve synchronized co-expression of multiple proteins. The DI domain comprises an Ssp DnaE mini-intein N159A mutant and an Ssp DnaB mini-intein C1A mutant connected in tandem by a peptide linker to mediate efficient release of the flanking proteins via autocatalytic cleavage. Essentially complete release of constituent proteins, GFP and RFP (mCherry), from a polyprotein precursor, in bacterial, mammalian, and plant hosts was demonstrated. In addition, successful co-expression of GFP with chloramphenicol acetyltransferase, and thioredoxin with RFP, respectively, further substantiates the general applicability of the DI polyprotein system. Collectively, our results demonstrate the DI-based polyprotein technology as a highly valuable addition to the molecular toolbox for multi-protein co-expression which finds vast applications in biotechnology, biosciences, and biomedicine.

A computational study of the glycylserine hydrolysis at physiological pH: a zwitterionic versus anionic mechanism

The hydrolysis of GlySer at physiological pH was investigated by modeling the most feasible reaction mechanisms in aqueous phase at the MP2/6-311+(2df,2p)//SMD-M06/6-311+(2df,2p) level of the theory. To refine the energies of the most relevant transition states along the reaction paths the cluster-continuum concept was adopted. The hydrolytic process could proceed through two competitive mechanisms involving either the zwitterionic or the anionic form of GlySer. The calculations suggest that at physiological pH the actual mechanism is most probably mixed, anionic-zwitterionic. In this reaction scheme the first stage of N→O acyl transfer involves the anionic form whereas the second stage, during which the resultant ester is hydrolyzed, most likely involves the zwitterionic ester form of GlySer. The energy requirement for the first reaction stage is estimated to be slightly lower than for the second one. The calculated activation parameters (e.g. ΔG(#) = 27.8 kcal mol(-1)) for the nucleophilic addition of a water molecule to the ester carbonyl group of the zwitterionic ester are in good agreement with the experimentally determined values at pD 7.4 (ΔG(#) = 28.7 kcal mol(-1)).

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.

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.

The Arthrobacter species FB24 Arth_1007 (DnaB) intein is a pseudogene

An Arthrobacter species FB24 gene (locus tag Arth_1007) was previously annotated as a putative intein-containing DnaB helicase of phage origin (Arsp-FB24 DnaB intein). However, it is not a helicase gene because the sequence similarity is limited to inteins. In fact, the flanking exteins total only 66 amino acids. Therefore, the intein should be referred to as the Arsp-FB24 Arth_1007 intein. The Arsp-FB24 Arth_1007 intein failed to splice in its native precursor and in a model precursor. We previously noted that the Arsp-FB24 Arth_1007 intein is the only putative Class 3 intein that is missing the catalytically essential Cys at position 4 of intein Motif F, which is one of the three defining signature residues of this class. Additionally, a catalytically essential His in position 10 of intein Motif B is also absent; this His is the most conserved residue amongst all inteins. Splicing activity was not rescued when these two catalytically important positions were 'reverted' back to their consensus residues. This study restores the unity of the Class 3 intein signature sequence in active inteins by demonstrating that the Arsp-FB24 Arth_1007 intein is an inactive pseudogene.

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.

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

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

Protein autoproteolysis: conformational strain linked to the rate of peptide cleavage by the pH dependence of the N --> O acyl shift reaction

Nucleophilic attack by a side chain nucleophile on the adjacent peptide bond followed by N --> O or N --> S acyl shift is the primary step in protein autoproteolysis. Precursor structures of autoproteolytic proteins reveal strained (or twisted) amides at the site of cleavage, and we previously showed that SEA domain autoproteolysis involves substrate destabilization by approximately 7 kcal/mol. However, the precise chemical mechanism by which conformational energy is converted into reaction rate acceleration has not been understood. Here we show that the pH dependence of autoproteolysis in a slow-cleaving mutant (1G) of the MUC1 SEA domain is consistent with a mechanism in which N --> O acyl shift proceeds after initial protonation of the amide nitrogen. Unstrained amides have pK(a) values of 0 with protonation on the oxygen, and autoproteolysis is therefore immeasurably slow at neutral pH. However, conformational strain forces the peptide nitrogen into a pyramidal conformation with a significantly increased pK(a) for protonation. We find that pK(a) values of approximately 4 and approximately 6, as in model compounds of twisted amides, reproduce the rate of autoproteolysis in the 1G and wild-type SEA domains, respectively. A mechanism involving strain, nitrogen protonation, and N --> O shift is also supported by quantum-chemical calculations. Such a reaction therefore constitutes an alternative to peptide cleavage that is utilized in autoproteolysis, as opposed to a classical mechanism involving a structurally conserved active site with a catalytic triad and an oxyanion hole, which are not present at the SEA domain cleavage site.

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.

Metal ions binding to recA inteins from Mycobacterium tuberculosis

Zinc has been found in the crystal structures of inteins and the zinc ion can inhibit intein splicing both in vitro and in vivo. The interactions between metal ions and three minimized recA inteins have been studied in this work. Isothermal titration calorimetry (ITC) results show that the zinc binding affinity to three inteins is in the order of DeltaI-SM > DeltaDeltaI(hh)-SM approximately DeltaDeltaI(hh)-CM, but is much weaker than to EDTA. These data explain the reversible inhibition and the presence of zinc only in the crystal structure of DeltaI-SM of recA intein. A positive correlation between binding constants and inhibition efficiency was observed upon the titration of different metal ions. Single-site binding modes were detected in all interactions, except DeltaDeltaI(hh)-CM which has two Zn sites. Zinc binding sites on DeltaDeltaI(hh)-CM were analyzed by NMR spectroscopy and ITC titration on inteins with chemical modifications. Results indicate that the Cys1 and His73 are the second zinc binding sites in DeltaDeltaI(hh)-CM. CD studies show the metal coordinations have negligible influence on protein structure. This work suggests that the mobility restriction of key residues from metal coordination is likely the key cause of metal inhibition of intein splicing.

Reflections on protein splicing: structures, functions and mechanisms

Twenty years ago, evidence that one gene produces two enzymes via protein splicing emerged from structural and expression studies of the VMA1 gene in Saccharomyces cerevisiae. VMA1 consists of a single open reading frame and contains two independent genetic information for Vma1p (a catalytic 70-kDa subunit of the vacuolar H(+)-ATPase) and VDE (a 50-kDa DNA endonuclease) as an in-frame spliced insert in the gene. Protein splicing is a posttranslational cellular process, in which an intervening polypeptide termed as the VMA1 intein is self-catalytically excised out from a nascent 120-kDa VMA1 precursor and two flanking polypeptides of the N- and C-exteins are ligated to produce the mature Vma1p. Subsequent studies have demonstrated that protein splicing is not unique to the VMA1 precursor and there are many operons in nature, which implement genetic information editing at protein level. To elucidate its structure-directed chemical mechanisms, a series of biochemical and crystal structural studies has been carried out with the use of various VMA1 recombinants. This article summarizes a VDE-mediated self-catalytic mechanism for protein splicing that is triggered and terminated solely via thiazolidine intermediates with tetrahedral configurations formed within the splicing sites where proton ingress and egress are driven by balanced protonation and deprotonation.

Protein splicing: its discovery and structural insight into novel chemical mechanisms

Protein splicing is a posttranslational cellular process, in which an intervening protein sequence (intein) is self-catalytically excised out from a nascent protein precursor and the two flanking sequences (N- and C-exteins) are ligated to produce two mature enzymes. This unique reaction was first discovered from studies of the structure and expression of the VMA1 gene in Saccharomyces cerevisiae. VMA1 consists of a single open reading frame and yet comprises two independent genetic information for Vma1p (a catalytic 70-kDa subunit of the vacuolar H+-ATPase) and VDE (a 50-kDa DNA endonuclease) as an in-frame spliced insert in the gene. Subsequent studies have demonstrated that protein splicing is not unique for the VMA1 precursor and there are many operons in nature, which implement genetic information editing at protein level. To elucidate its precise reaction mechanisms from a viewpoint of structure-directed chemistry, a series of crystal structural studies has been carried out with the use of splicing-inactive and slowly spliceable precursors of VMA1 recombinants. One precursor structure revealed that the N-terminal junction of the introduced extein polypeptide forms an intermediate containing a five-membered thiazolidine ring. The other precursor structures showed spliced products with a linkage between the N- and C-extein segments. This article summarizes biochemical and structural studies on a self-catalytic mechanism for protein splicing that is triggered and terminated solely via thiazolidine intermediates with tetrahedral configurations formed within the splicing sites where proton ingress and egress are driven by balanced protonation and deprotonation.

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.

Semisynthesis and application of carboxyfluorescein-labelled biologically active human interleukin-8

Human interleukin 8 (hIL-8), a neutrophil-activating and chemotactic cytokine, is known to play an important role in the pathogenesis of a large number of neutrophil-driven inflammatory diseases. This cytokine belongs to the family of CXC chemokines, mediating the response through binding to the seven-transmembrane helical G protein-coupled receptors CXCR1 and CXCR2. For the first time, we employed the expressed protein ligation (EPL) strategy to chemokine synthesis and subsequent modification. The ligation site was chosen with respect to the position of four cysteine residues within the hIL-8 sequence. Ligation with synthetic peptides that carry cysteine at their N-termini resulted in full-length hIL-8 and the specifically carboxyfluorescein-labelled analogue [K69(CF)]hIL-8(1-77). [K69(CF)]hIL-8(1-77) was fully active as shown by inhibition of cAMP production. Furthermore, this analogue was used to study receptor internalisation in human promyelotic HL60 cells that express CXCR1 and CXCR2 receptors. Binding and quenching studies were performed on HL60 membranes and suggest that the C-terminus of IL-8 is accessible to solvent in the receptor-bound state. Thus, we introduce here a powerful approach that allows the site-specific incorporation of chemical modifications into the sequence of chemokines, which opens new avenues for studying IL-8 function.

Mutational Analysis of Protein Splicing, Cleavage, and Self-Association Reactions Mediated by the Naturally SplitSspDnaE 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.

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 inteins with atypical glutamine and aspartate C-terminal residues

Inteins are protein-splicing domains present in many proteins. They self-catalyze their excision from the host protein, ligating their former flanks by a peptide bond. The C-terminal residue of inteins is typically an asparagine (Asn). Cyclization of this residue to succinimide causes the final detachment of inteins from their hosts. We studied protein-splicing activity of two inteins with atypical C-terminal residues. One having a C-terminal glutamine (Gln), isolated from Chilo iridescent virus (CIV), and another unique intein, first reported here, with a C-terminal aspartate, isolated from Carboxydothermus hydrogenoformans (Chy). Protein-splicing activity was examined in the wild-type inteins and in several mutants with N- and C-terminal amino acid substitutions. We demonstrate that both wild-type inteins can protein splice, probably by new variations of the typical protein-splicing mechanism. Substituting the atypical C-terminal residue to the typical Asn retained protein-splicing only in the CIV intein. All diverse C-terminal substitutions in the Chy intein (Asp(345) to Asn, Gln, Glu, and Ala) abolished protein-splicing and generated N- and C-terminal cleavage. The observed C-terminal cleavage in the Chy intein ending with Ala cannot be explained by cyclization of this residue. We present and discuss several new models for reactions in the protein-splicing pathway.

Zinc ion effects on individual Ssp DnaE intein splicing steps: regulating pathway progression

Use of the naturally split, self-splicing Synechocystis sp. PCC6803 DnaE intein permits separate purification of the N- and C-terminal intein domains. Otherwise spontaneous intein-mediated reactions can therefore be controlled in vitro, allowing detailed study of intein kinetics. Incubation of the Ssp DnaE intein with ZnCl(2) inhibited trans splicing, hydrolysis-mediated N-terminal trans cleavage, and C-terminal trans cleavage reactions. Maximum inhibition of the splicing reaction was achieved at equal molar concentrations of ZnCl(2) and intein domains, suggesting a 1:1 metal ion:intein binding stoichiometry. Mutation of the (+)1 cysteine residue to valine (C(+)1V) alleviated the inhibitory effects of ZnCl(2). Valine substitution in the absence of ZnCl(2) blocked trans splicing and decreased C-terminal cleavage kinetics in a manner similar to that of the native (+)1 cysteine in the presence of ZnCl(2). These data are consistent with Zn(2+)-mediated inhibition of the Ssp DnaE intein via chelation of the (+)1 cysteine residue. N-Terminal trans cleavage can occur via both spontaneous hydrolysis and nucleophilic (e.g., DTT) attack. Comparative examination of N-terminal cleavage rates using amino acid substitution (C(+)1V) and Zn(2+)-mediated inhibition permitted the maximum contribution of hydrolysis to overall N-terminal cleavage kinetics to be determined. Stable intermediates consisting of the associated intein domains were detected by PAGE and provided evidence of a rapid C-terminal cleavage step. Acute control of the C-terminal reaction was achieved by the rapid reversal of Zn(2+)-mediated inhibition by EDTA. By inhibiting both the splicing pathway and spontaneous hydrolysis with Zn(2+), reactants can be diverted from the trans splicing to the trans cleavage pathway where DTT and EDTA can regulate N- and C-terminal cleavage, respectively.

Crystal structures of glutaryl 7-aminocephalosporanic acid acylase: insight into autoproteolytic activation

Glutaryl 7-aminocephalosporanic acid acylase (GCA, EC 3.5.1.11) is a member of N-terminal nucleophile (Ntn) hydrolases. The native enzyme is an (alpha beta)(2) heterotetramer originated from an enzymatically inactive precursor of a single polypeptide. The activation of precursor GCA consists of primary and secondary autoproteolytic cleavages, generating a terminal residue with both a nucleophile and a base and releasing a nine amino acid spacer peptide. We have determined the crystal structures of the recombinant selenomethionyl native and S170A mutant precursor from Pseudomonas sp. strain GK16. Precursor activation is likely triggered by conformational constraints within the spacer peptide, probably inducing a peptide flip. Autoproteolytic site solvent molecules, which have been trapped in a hydrophobic environment by the spacer peptide, may play a role as a general base for nucleophilic attack. The activation results in building up a catalytic triad composed of Ser170/His192/Glu624. However, the triad is not linked to the usual hydroxyl but the free alpha-amino group of the N-terminal serine residue of the native GCA. Mutagenesis and structural data support the notion that the stabilization of a transient hydroxazolidine ring during autoproteolysis would be critical during the N --> O acyl shift. The autoproteolytic activation mechanism for GCA is described.

Mechanism of human S-adenosylmethionine decarboxylase proenzyme processing as revealed by the structure of the S68A mutant

S-Adenosylmethionine decarboxylase (AdoMetDC) is a pyruvoyl-dependent enzyme that catalyzes the formation of the aminopropyl group donor in the biosynthesis of the polyamines spermidine and spermine. The enzyme is synthesized as a protein precursor and is activated by an autocatalytic serinolysis reaction that creates the pyruvoyl group. The autoprocessing reaction proceeds via an N --> O acyl rearrangement, generating first an oxyoxazolidine anion intermediate followed by an ester intermediate. A similar strategy is utilized in self-catalyzed protein splicing reactions and in autoproteolytic activation of protein precursors. Mutation of Ser68 to alanine in human AdoMetDC prevents processing by removing the serine side chain necessary for nucleophilic attack at the adjacent carbonyl carbon atom. We have determined the X-ray structure of the S68A mutant and have constructed models of the proenzyme and the oxyoxazolidine intermediate. Formation of the oxyoxazolidine intermediate is promoted by a hydrogen bond from Cys82 and stabilized by a hydrogen bond from Ser229. These observations are consistent with mutagenesis studies, which show that the C82S and C82A mutants process slowly and that the S229A mutant does not process at all. Donation of a proton by His243 to the nitrogen atom of the oxyoxazolidine ring converts the oxyoxazolidine anion to the ester intermediate. The absence of a base to activate the hydroxyl group of Ser68 suggests that strain may play a role in the cleavage reaction. Comparison of AdoMetDC with other self-processing proteins shows no common structural features. Comparison to histidine decarboxylase and aspartate decarboxylase shows that these pyruvoyl-dependent enzymes evolved different catalytic strategies for forming the same cofactor.

Protein-splicing reaction via a thiazolidine intermediate: crystal structure of the VMA1-derived endonuclease bearing the N and C-terminal propeptides

Protein splicing excises an internal intein segment from a protein precursor precisely, and concomitantly ligates flanking N and C-extein polypeptides at the respective sides of the precursor. Here, a series of precursor recombinants bearing 11 N-extein and ten C-extein residues is prepared for the intein of the Saccharomyces cerevisiae VMA1-derived homing endonuclease referred to as VDE and as PI-SceI. The recombinant with replacements of C284S, H362N, N737S, and C738S is chosen as a spliceable precursor model and is then subjected to a 2.1A resolution crystallographic analysis. The crystal structure shows that the introduced extein polypeptides are located in the vicinity of the splicing site, and that each of their peptide bonds is in the trans conformation. The S284 O(gamma) atom located at a distance of 3.1A from the G283 C atom in the N-terminal junction suggests that a nucleophilic attack of the C284 S(gamma) atom on the G283 C atom forms a tetrahedral intermediate containing a five-membered thiazolidine ring. The tetrahedral intermediate is supposedly resolved into a thioester acyl group upon the cleavage of the linkage between the G283 C and C284 N atoms, and this thioester acyl formation completes the initial steps of Nright arrowS acyl shift at the junction between the N-extein and intein. The S738 O(gamma) atom in the C-terminal junction is placed in close proximity to the S284 O(gamma) atom at a distance of 3.6A, and is well suited for another nucleophilic attack on the resultant thioester acyl group that is then subjected to the transesterification in the next step. The reaction steps proposed for the acyl shift are driven entirely by protonation and deprotonation, in which proton ingress and egress is balanced within the splicing site.

Recent advances in chemical approaches to the study of biological systems

A number of novel chemical methods for studying biological systems have recently been developed that provide a means of addressing biological questions not easily studied with other techniques. In this review, examples that highlight the development and use of such chemical approaches are discussed. Specifically, strategies for modulating protein activity or protein-protein interactions using small molecules are presented. In addition, methods for generating and utilizing novel biomolecules (proteins, oligonucleotides, oligosaccharides, and second messengers) are examined.

The interrelationships of side-chain and main-chain conformations in proteins

The accurate determination of a large number of protein structures by X-ray crystallography makes it possible to conduct a reliable statistical analysis of the distribution of the main-chain and side-chain conformational angles, how these are dependent on residue type, adjacent residue in the sequence, secondary structure, residue-residue interactions and location at the polypeptide chain termini. The interrelationship between the main-chain (phi, psi) and side-chain (chi 1) torsion angles leads to a classification of amino acid residues that simplify the folding alphabet considerably and can be a guide to the design of new proteins or mutational studies. Analyses of residues occurring with disallowed main-chain conformation or with multiple conformations shed some light on why some residues are less favoured in thermophiles.

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.

The biosynthesis of coenzyme A in bacteria

Coenzyme A (I) and enzyme-bound phosphopantetheine (II) function as acyl carriers and as carbonyl activating groups for Claisen reactions as well as for amide-, ester-, and thioester-forming reactions in the cell. In so doing, these cofactors play a key role in the biosynthesis and breakdown of fatty acids and in the biosynthesis of polyketides and nonribosomal peptides. Coenzyme A is biosynthesized in bacteria in nine steps. The biosynthesis begins with the decarboxylation of aspartate to give beta-alanine. Pantoic acid is formed by the hydroxymethylation of alpha-ketoisovalerate followed by reduction. These intermediates are then condensed to give pantothenic acid. Phosphorylation of pantothenic acid followed by condensation with cysteine and decarboxylation gives 4'-phosphopantetheine. Adenylation and phosphorylation of 4'-phosphopantetheine completes the biosynthesis of coenzyme A. This review will focus on the mechanistic enzymology of coenzyme A biosynthesis in bacteria.

Protein-splicing intein: Genetic mobility, origin, and evolution

Intein is the protein equivalent of intron and has been discovered in increasing numbers of organisms and host proteins. A self-splicing intein catalyzes its own removal from the host protein through a posttranslational process of protein splicing. A mobile intein displays a site-specific endonuclease activity that confers genetic mobility to the intein through intein homing. Recent findings of intein structure and the mechanism of protein splicing illuminated how inteins work and yielded clues regarding intein's origin, spread, and evolution. Inteins can evolve into new structures and new functions, such as split inteins that do trans-splicing. The structural basis of intein function needs to be identified for a full understanding of the origin and evolution of this marvelous genetic element.

Protein engineering by expressed protein ligation

By allowing the controlled assembly of synthetic peptides and recombinant polypeptides, expressed protein ligation permits unnatural amino acids, biochemical probes, and biophysical probes to be specifically incorporated into semisynthetic proteins. A powerful feature of the method is its modularity; once the reactive recombinant pieces are in hand and the optimal ligation conditions have been developed, it is possible to quickly generate an array of semisynthetic analogs by simply attaching different synthetic peptide cassettes--in most cases the synthetic peptides will be small and easy to make. From a practical perspective, the rate-determining step in the process is usually not the ligation step (it is based on a simple and efficient chemical reaction), but rather the generation of the reactive polypeptide building blocks. In particular, optimizing the yields of recombinant polypeptide building blocks can require some initial effort. However, it should be noted that the initial investment in time required to optimize the production of the recombinant fragment is offset by the ease and speed with which one can produce the material thereafter. In the example described in this chapter, the yield of soluble intein fusion protein was slightly better using the GyrA intein than for the VMA intein, although in both cases significant amounts of fusion protein were present in the cell pellet. Studies are currently underway to identify optimal refolding conditions for GyrA fusion proteins solubilized from inclusion bodies.

Protein splicing and related forms of protein autoprocessing

Protein splicing is a form of posttranslational processing that consists of the excision of an intervening polypeptide sequence, the intein, from a protein, accompanied by the concomitant joining of the flanking polypeptide sequences, the exteins, by a peptide bond. It requires neither cofactors nor auxiliary enzymes and involves a series of four intramolecular reactions, the first three of which occur at a single catalytic center of the intein. Protein splicing can be modulated by mutation and converted to highly specific self-cleavage and protein ligation reactions that are useful protein engineering tools. Some of the reactions characteristic of protein splicing also occur in other forms of protein autoprocessing, ranging from peptide bond cleavage to conjugation with nonprotein moieties. These mechanistic similarities may be the result of convergent evolution, but in at least one case-hedgehog protein autoprocessing-there is definitely a close evolutionary relationship to protein splicing.

Characterization of a naturally occurring trans-splicing intein from Synechocystis sp. PCC6803

A naturally occurring trans-splicing intein from the dnaE gene of Synechocystis sp. PCC6803 (Ssp DnaE intein) was used to characterize the intein-catalyzed splicing reaction. Trans-splicing/cleavage reactions were initiated by combining the N-terminal splicing domain of the Ssp DnaE intein containing five native N-extein residues and maltose binding protein as the N-extein with the C-terminal Ssp DnaE intein splicing domain (E(C)) with or without thioredoxin fused in-frame to its carboxy terminus. Observed rate constants (k(obs)) for dithiothreitol-induced N-terminal cleavage, C-terminal cleavage, and trans-splicing were (1.0 +/- 0.5) x 10(-3), (1.9 +/- 0.9) x 10(-4), and (6.6 +/- 1.3) x 10(-5) s(-1), respectively. Preincubation of the intein fragments showed no change in k(obs), indicating association of the two splicing domains is rapid relative to the subsequent steps. Interestingly, when E(C) concentrations were substoichiometric with respect to the N-terminal splicing domain, the levels of N-terminal cleavage were equivalent to the amount of E(C), even over a 24 h period. Activation energies for N-terminal cleavage and trans-splicing were determined by Arrhenius plots to be 12.5 and 8.9 kcal/mol, respectively. Trans-splicing occurred maximally at pH 7.0, while a slight increase in the extent of N-terminal cleavage was observed at higher pH values. This work describes an in-depth kinetic analysis of the splicing and cleavage activity of an intein, and provides insight for the use of the split intein as an affinity domain.

Structural insights into the protein splicing mechanism of PI-SceI

PI-SceI is a member of a class of proteins (inteins) that excise themselves from a precursor protein and in the process ligate the flanking protein sequences (exteins). We report here the 2.1-A resolution crystal structure of a PI-SceI miniprecursor (VMA29) containing 10 N-terminal extein residues and 4 C-terminal extein residues. Mutations at the N- and C-terminal splicing junctions, blocking in vivo protein splicing, allowed the miniprecursor to be purified and crystallized. The structure reveals both the N- and C-terminal scissile peptide bonds to be in distorted trans conformations (tau approximately 100 degrees ). Modeling of the wild-type PI-SceI based on the VMA29 structure indicates a large conformational change (movement of >9 A) must occur to allow transesterification to be completed. A zinc atom was discovered at the C-terminal splicing junction. Residues Cys(455), His(453), and Glu(80) along with a water molecule (Wat(53)) chelate the zinc atom. The crystal structure of VMA29 has captured the intein in its pre-spliced state.

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.