Protein splicing in the yeast Vma1 protozyme: evidence for an intramolecular reaction

Amide Activation in Ground and Excited States

Not all amide bonds are created equally. The purpose of the present paper is the reinterpretation of the amide group by means of two concepts: amidicity and carbonylicity. These concepts are meant to provide a new viewpoint in defining the stability and reactivity of amides. With the help of simple quantum-chemical calculations, practicing chemists can easily predict the outcome of a desired process. The main benefit of the concepts is their simplicity. They provide intuitive, but quasi-thermodynamic data, making them a practical rule of thumb for routine use. In the current paper we demonstrate the performance of our methods to describe the chemical character of an amide bond strength and the way of its activation methods. Examples include transamidation, acyl transfer and amide reductions. Also, the method is highly capable for simple interpretation of mechanisms for biological processes, such as protein splicing and drug mechanisms. Finally, we demonstrate how these methods can provide information about photo-activation of amides, through the examples of two caged neurotransmitter derivatives.

Structural Basis for the Persistence of Homing Endonucleases in Transcription Factor IIB Inteins

Inteins are mobile genetic elements that are spliced out of proteins after translation. Some inteins contain a homing endonuclease (HEN) responsible for their propagation. Hedgehog/INTein (HINT) domains catalyzing protein splicing and their nested HEN domains are thought to be functionally independent because of the existence of functional mini-inteins without HEN domains. Despite the lack of obvious mutualism between HEN and HINT domains, HEN domains are persistently found at one specific site in inteins, indicating their potential functional role in protein splicing. Here we report crystal structures of inactive and active mini-inteins derived from inteins residing in the transcription factor IIB of Methanococcus jannaschii and Methanocaldococcus vulcanius, revealing a novel modified HINT fold that might provide new insights into the mutualism between the HEN and HINT domains. We propose an evolutionary model of inteins and a functional role of HEN domains in inteins.

Quantitative differential proteomics of yeast extracellular matrix: there is more to it than meets the eye

Background

Saccharomyces cerevisiae multicellular communities are sustained by a scaffolding extracellular matrix, which provides spatial organization, and nutrient and water availability, and ensures group survival. According to this tissue-like biology, the yeast extracellular matrix (yECM) is analogous to the higher Eukaryotes counterpart for its polysaccharide and proteinaceous nature. Few works focused on yeast biofilms, identifying the flocculin Flo11 and several members of the HSP70 in the extracellular space. Molecular composition of the yECM, is therefore mostly unknown. The homologue of yeast Gup1 protein in high Eukaryotes (HHATL) acts as a regulator of Hedgehog signal secretion, therefore interfering in morphogenesis and cell-cell communication through the ECM, which mediates but is also regulated by this signalling pathway. In yeast, the deletion of GUP1 was associated with a vast number of diverse phenotypes including the cellular differentiation that accompanies biofilm formation.

Methods

S. cerevisiae W303-1A wt strain and gup1∆ mutant were used as previously described to generate biofilm-like mats in YPDa from which the yECM proteome was extracted. The proteome from extracellular medium from batch liquid growing cultures was used as control for yECM-only secreted proteins. Proteins were separated by SDS-PAGE and 2DE. Identification was performed by HPLC, LC-MS/MS and MALDI-TOF/TOF. The protein expression comparison between the two strains was done by DIGE, and analysed by DeCyder Extended Data Analysis that included Principal Component Analysis and Hierarchical Cluster Analysis.

Results

The proteome of S. cerevisiae yECM from biofilm-like mats was purified and analysed by Nano LC-MS/MS, 2D Difference Gel Electrophoresis (DIGE), and MALDI-TOF/TOF. Two strains were compared, wild type and the mutant defective in GUP1. As controls for the identification of the yECM-only proteins, the proteome from liquid batch cultures was also identified. Proteins were grouped into distinct functional classes, mostly Metabolism, Protein Fate/Remodelling and Cell Rescue and Defence mechanisms, standing out the presence of heat shock chaperones, metalloproteinases, broad signalling cross-talkers and other putative signalling proteins. The data has been deposited to the ProteomeXchange with identifier PXD001133.

Conclusions

yECM, as the mammalian counterpart, emerges as highly proteinaceous. As in higher Eukaryotes ECM, numerous proteins that could allow dynamic remodelling, and signalling events to occur in/and via yECM were identified. Importantly, large sets of enzymes encompassing full antagonistic metabolic pathways, suggest that mats develop into two metabolically distinct populations, suggesting that either extensive moonlighting or actual metabolism occurs extracellularly. The gup1∆ showed abnormally loose ECM texture. Accordingly, the correspondent differences in proteome unveiled acetic and citric acid producing enzymes as putative players in structural integrity maintenance.

Intramolecular disulfide bond between catalytic cysteines in an intein precursor

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

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

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

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.

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.

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 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.

The protein splicing domain of the homing endonuclease PI-sceI is responsible for specific DNA binding

The homing endonuclease PI- Sce I consists of a protein splicing domain (I) and an endonucleolytic domain (II). To characterize the two domains with respect to their contribution to DNA recognition we cloned, purified and characterized the isolated domains. Both domains have no detectable endonucleolytic activity. Domain I binds specifically to the PI- Sce I recognition sequence, whereas domain II displays only weak non-specific DNA binding. In the specific complex with domain I the DNA is bent to a similar extent as observed with the initial complex formed between PI- Sce I and DNA. Our results indicate that protein splicing domain I is also involved in recognition of the DNA substrate.

Protein splicing in trans by purified N- and C-terminal fragments of the Mycobacterium tuberculosis RecA intein

Protein splicing involves the self-catalyzed excision of protein splicing elements, or inteins, from flanking polypeptide sequences, or exteins, leading to the formation of new proteins in which the exteins are linked directly by a peptide bond. To study the enzymology of this interesting process we have expressed and purified N- and C-terminal segments of the Mycobacterium tuberculosis RecA intein, each approximately 100 amino acids long, fused to appropriate exteins. These fragments were reconstituted into a functional protein splicing element by renaturation from 6 M urea. When renaturation was carried out in the absence of thiols, the reconstituted splicing element accumulated as an inactive disulfide-linked complex of the two intein fragments, which could be induced to undergo protein splicing by reduction of the disulfide bond. This provided a useful tool for separately investigating the requirements for the reconstitution of the intein fragments to yield a functional protein splicing element and for the protein splicing process per se. For example, the pH dependence of these processes was quite different, with reconstitution being most efficient at pH 8.5 and splicing most rapid at pH 7.0. The availability of such an in vitro protein splicing system opens the way for the exploration of intein structure and the unusual enzymology of protein splicing. In addition, this trans-splicing system is a potential protein ligase that can link any two polypeptides fused to the N- and C-terminal intein segments.