Non-canonical inteins

Conditional protein splicing triggered by SUMO protease

Conditional protein splicing is a powerful biotechnological tool that can be used to post-translationally control the activity of target proteins. Here we demonstrated a novel conditional protein splicing approach in which the small ubiquitin-like modifier (SUMO) protease induced the splicing of an atypical split intein. The engineered Ter DnaE-3 S11 split intein which has a small C-intein segment with only 6 amino acids was used in this study. A SUMO tag was fused to the N-terminus of the C-intein to inhibit the protein trans-splicing in vitro. The splicing products could be detected in 15 min with the addition of SUMO protease by western blotting and the splicing efficiency was ∼4-fold higher than the control without SUMO protease for overnight reaction. This engineered Ter DnaE-3 S11 split intein-mediated protein trans-splicing had been further shown to be triggered by SUMO protease in different exteins in vitro. Our study provides new insights into the regulation of protein splicing and is a promising tool for the control of protein structure and function in vitro.

Protein Splicing of Inteins: A Powerful Tool in Synthetic Biology

Inteins are protein segments that are capable of enabling the ligation of flanking extein into a new protein, a process known as protein splicing. Since its discovery, inteins have become powerful biotechnological tools for applications such as protein engineering. In the last 10 years, the development in synthetic biology has further endowed inteins with enhanced functions and diverse utilizations. Here we review these efforts and discuss the future directions.

Cyanobacterial multi-copy chromosomes and their replication

While the model bacteria Escherichia coli and Bacillus subtilis harbor single chromosomes, which is known as monoploidy, some freshwater cyanobacteria contain multiple chromosome copies per cell throughout their cell cycle, which is known as polyploidy. In the model cyanobacteria Synechococcus elongatus PCC 7942 and Synechocystis sp. PCC 6803, chromosome copy number (ploidy) is regulated in response to growth phase and environmental factors. In S. elongatus 7942, chromosome replication is asynchronous both among cells and chromosomes. Comparative analysis of S. elongatus 7942 and S. sp. 6803 revealed a variety of DNA replication mechanisms. In this review, the current knowledge of ploidy and DNA replication mechanisms in cyanobacteria is summarized together with information on the features common with plant chloroplasts. It is worth noting that the occurrence of polyploidy and its regulation are correlated with certain cyanobacterial lifestyles and are shared between some cyanobacteria and chloroplasts.

ABBREVIATIONS

NGS: next-generation sequencing; Repli-seq: replication sequencing; BrdU: 5-bromo-2'-deoxyuridine; TK: thymidine kinase; GCSI: GC skew index; PET: photosynthetic electron transport; RET: respiration electron transport; Cyt b₆f complex: cytochrome b₆f complex; PQ: plastoquinone; PC: plastocyanin.

Structure-based engineering and comparison of novel split inteins for protein ligation

Protein splicing is an autocatalytic process involving self-excision of an internal protein domain, the intein, and concomitant ligation of the two flanking sequences, the exteins, with a peptide bond. Protein splicing can also take place in trans by naturally split inteins or artificially split inteins, ligating the exteins on two different polypeptide chains into one polypeptide chain. Protein trans-splicing could work in foreign contexts by replacing the native extein sequences with other protein sequences. Protein ligation using protein trans-splicing increasingly becomes a useful tool for biotechnological applications such as semi-synthesis of proteins, segmental isotopic labeling, and in vivo protein engineering. However, only a few split inteins have been successfully applied for protein ligation. Naturally split inteins have been widely used, but they are cross-reactive to each other, limiting their applications to multiple-fragment ligation. Based on the three-dimensional structures including two newly determined intein structures, we derived 21 new split inteins from four highly efficient cis-splicing inteins, in order to develop novel split inteins suitable for protein ligation. We systematically compared trans-splicing of 24 split inteins and tested the cross-activities among them to identify orthogonal split intein fragments that could be used in chemical biology and biotechnological applications.

Protein trans-splicing of an atypical split intein showing structural flexibility and cross-reactivity

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

Protein trans-splicing as a protein ligation tool to study protein structure and function

Protein trans-splicing (PTS) exerted by split inteins is a protein ligation reaction which enables overcoming the barriers of conventional heterologous protein production. We provide an overview of the current state-of-the-art in split intein engineering, as well as the achievements of PTS technology in the realm of protein structure-function analyses, including incorporation of natural and artificial protein modifications, controllable protein reconstitution, segmental isotope labeling and protein cyclization. We further discuss factors crucial for the successful implementation of PTS in these protein engineering approaches, and speculate on necessary future endeavours to make PTS a universally applicable protein ligation tool.

Assembly of a fragmented ribonucleotide reductase by protein interaction domains derived from a mobile genetic element

Ribonucleotide reductase (RNR) is a critical enzyme of nucleotide metabolism, synthesizing precursors for DNA replication and repair. In prokaryotic genomes, RNR genes are commonly targeted by mobile genetic elements, including free standing and intron-encoded homing endonucleases and inteins. Here, we describe a unique molecular solution to assemble a functional product from the RNR large subunit gene, nrdA that has been fragmented into two smaller genes by the insertion of mobE, a mobile endonuclease. We show that unique sequences that originated during the mobE insertion and that are present as C- and N-terminal tails on the split NrdA-a and NrdA-b polypeptides, are absolutely essential for enzymatic activity. Our data are consistent with the tails functioning as protein interaction domains to assemble the tetrameric (NrdA-a/NrdA-b)(2) large subunit necessary for a functional RNR holoenzyme. The tails represent a solution distinct from RNA and protein splicing or programmed DNA rearrangements to restore function from a fragmented coding region and may represent a general mechanism to neutralize fragmentation of essential genes by mobile genetic elements.

Fractured genes: a novel genomic arrangement involving new split inteins and a new homing endonuclease family

Inteins are genetic elements, inserted in-frame into protein-coding genes, whose products catalyze their removal from the protein precursor via a protein-splicing reaction. Intein domains can be split into two fragments and still ligate their flanks by a trans-protein-splicing reaction. A bioinformatic analysis of environmental metagenomic data revealed 26 different loci with a novel genomic arrangement. In each locus, a conserved enzyme coding region is broken in two by a split intein, with a free-standing endonuclease gene inserted in between. Eight types of DNA synthesis and repair enzymes have this ‘fractured’ organization. The new types of naturally split-inteins were analyzed in comparison to known split-inteins. Some loci include apparent gene control elements brought in with the endonuclease gene. A newly predicted homing endonuclease family, related to very-short patch repair (Vsr) endonucleases, was found in half of the loci. These putative homing endonucleases also appear in group-I introns, and as stand-alone inserts in the absence of surrounding intervening sequences. The new fractured genes organization appears to be present mainly in phage, shows how endonucleases can integrate into inteins, and may represent a missing link in the evolution of gene breaking in general, and in the creation of split-inteins in particular.

Crystallographic and mutational studies of Mycobacterium tuberculosis recA mini-inteins suggest a pivotal role for a highly conserved aspartate residue

The 440 amino acid Mtu recA intein consists of independent protein-splicing and endonuclease domains. Previously, removal of the central endonuclease domain of the intein, and selection for function, generated a 168 residue mini-intein, DeltaI-SM, that had splicing activity similar to that of the full-length, wild-type protein. A D422G mutation (DeltaI-CM) increased C-terminal cleavage activity. Using the DeltaI-SM mini-intein structure (presented here) as a guide, we previously generated a highly active 139 residue mini-intein, DeltaDeltaI(hh)-SM, by replacing 36 amino acid residues in the residual endonuclease loop with a seven-residue beta-turn from the autoprocessing domain of Hedgehog protein. The three-dimensional structures of DeltaI-SM, DeltaDeltaI(hh)-SM, and two variants, DeltaDeltaI(hh)-CM and DeltaDeltaI(hh), have been determined to evaluate the effects of the minimization on intein integrity and to investigate the structural and functional consequences of the D422G mutation. These structural studies show that Asp422 is capable of interacting with both the N and C termini. These interactions are lacking in the CM variant, but are replaced by contacts with water molecules. Accordingly, additional mutagenesis of residue 422, combined with mutations that isolate N-terminal and C-terminal cleavage, showed that the side-chain of Asp422 plays a role in both N and C-terminal cleavage, thereby suggesting that this highly conserved residue regulates the balance between the two reactions.

Minimization and stabilization of the Mycobacterium tuberculosis recA intein

Many naturally occurring inteins consist of two functionally independent domains, a protein-splicing domain and an endonuclease domain. In a previous study, a 168 amino acid residue mini-intein was generated by removal of the central endonuclease domain of the 440 residue Mycobacterium tuberculosis (Mtu) recA intein. In addition, directed evolution experiments identified a mutation, V67L, that improved the activity of the mini-intein significantly. A recent crystal structure shows that the loop connecting two beta-strands from the N-terminal and C-terminal intein subdomains of the mini-intein is disordered. The goals of the present study were to generate smaller mini-intein derivatives and to understand the basis for reversal of the splicing defect by the V67L mutation. Guided by the structural information, we generated a number of derivatives 135 to 152 residues in length, with V67 or L67. All of the new minimal inteins are functional in splicing. In vivo selection experiments for function showed that by removal of the loop region, 137 residues may be the lower limit for full protein-splicing activity. In addition, the activation effect of the V67L mutation was observed to be universal for mini-inteins longer than 137 residues. Structural and functional analyses indicate that the role of the mutation is in stabilization of the mini-intein core.

Posttranslational protein modification in Archaea

One of the first hurdles to be negotiated in the postgenomic era involves the description of the entire protein content of the cell, the proteome. Such efforts are presently complicated by the various posttranslational modifications that proteins can experience, including glycosylation, lipid attachment, phosphorylation, methylation, disulfide bond formation, and proteolytic cleavage. Whereas these and other posttranslational protein modifications have been well characterized in Eucarya and Bacteria, posttranslational modification in Archaea has received far less attention. Although archaeal proteins can undergo posttranslational modifications reminiscent of what their eucaryal and bacterial counterparts experience, examination of archaeal posttranslational modification often reveals aspects not previously observed in the other two domains of life. In some cases, posttranslational modification allows a protein to survive the extreme conditions often encountered by Archaea. The various posttranslational modifications experienced by archaeal proteins, the molecular steps leading to these modifications, and the role played by posttranslational modification in Archaea form the focus of this review.

Development of a Tandem Protein Trans-Splicing System Based on Native and Engineered Split Inteins

Protein trans-splicing involving naturally or artificially split inteins results in two polypeptides being linked together by a peptide bond. While this phenomenon has found a variety of applications in chemical biology and biotechnology, precious little is known about the molecular recognition events governing the initial fragment association step. In this study, fluorescence approaches have been used to measure the dissociation constant for the Ssp DnaE split intein interaction and to determine the on and off rates of fragment association. The DnaE fragments bind with low nanomolar affinity, and our data suggest that electrostatics make an important contribution to the very rapid association of the fragments at physiological pH. This information was used to develop a tandem trans-splicing system based on native and engineered split inteins. This novel system allows the one-pot assembly of three polypeptides under native conditions and can be performed in crude cell lysates. The technology should provide a convenient approach to the segmental isotopic or fluorogenic labeling of specific domains within the context of large multidomain proteins.

Diversity of structure and function of DNA polymerase (gp43) of T4-related bacteriophages

The replication DNA polymerase (gp43) of the bacteriophage T4 is a member of the pol B family of DNA polymerases, which are found in all divisions of life in the biosphere. The enzyme is a modularly organized protein that has several activities in one polypeptide chain (approximately 900 amino acid residues). These include two catalytic functions, POL (polymerase) and EXO (3 -exonuclease), and specific binding activities to DNA, the mRNA for gp43, deoxyribonucleotides (dNTPs), and other T4 replication proteins. The gene for this multifunctional enzyme (gene 43) has been preserved in evolution of the diverse group of T4-like phages in nature, but has diverged in sequence, organization, and specificity of the binding functions of the gene product. We describe here examples of T4-like phages where DNA rearrangements have created split forms of gene 43 consisting of two cistrons instead of one. These gene 43 variants specify separate gp43A (N-terminal) and gp43B (C-terminal) subunits of a split form of gp43. Compared to the monocistronic form, the interruption in contiguity of the gene 43 reading frame maps in a highly diverged sequence separating the code for essential components of two major modules of this pol B enzyme, the FINGERS and PALM domains, which contain the dNTP binding pocket and POL catalytic residues of the enzyme. We discuss the biological implications of these gp43 splits and compare them to other types of pol B splits in nature. Our studies suggest that DNA mobile elements may allow genetic information for pol B modules to be exchanged between organisms.

Distribution of split DnaE inteins in cyanobacteria

Inteins are genetic elements found inside the coding regions of different host proteins and are translated in frame with them. The intein‐encoded protein region is removed by an autocatalytic protein‐splicing reaction that ligates the host protein flanks with a peptide bond. This reaction can also occur in trans with the intein and host protein split in two. After translation of the two genes, the two intein parts ligate their flanking protein parts to each other, producing the mature protein. Naturally split inteins are only known in the DNA polymerase III alpha subunit (polC or dnaE gene) of a few cyanobacteria. Analysing the phylogenetic distribution and probable genetic propagation mode of these split inteins, we conclude that they are genetically fixed in several large cyanobacterial lineages. To test our hypothesis, we sequenced parts of the dnaE genes from five diverse cyanobacteria and found all species to have the same type of split intein. Our results suggest the occurrence of a genetic rearrangement in the ancestor of a large division of cyanobacteria. This event fixed the dnaE gene in a unique two‐genes one‐protein configuration in the progenitor of many cyanobacteria. Our hypothesis, findings and the cloning procedure that we established allow the identification and acquisition of many naturally split inteins. Having a large and diverse repertoire of these unique inteins will enable studies of their distinct activity and enhance their use in biotechnology.

Inteins: structure, function, and evolution

Inteins are genetic elements that disrupt the coding sequence of genes. However, in contrast to introns, inteins are transcribed and translated together with their host protein. Inteins appear most frequently in Archaea, but they are found in organisms belonging to all three domains of life and in viral and phage proteins. Most inteins consist of two domains: One is involved in autocatalytic splicing, and the other is an endonuclease that is important in the spread of inteins. This review focuses on the evolution and technical application of inteins and only briefly summarizes recent advances in the study of the catalytic activities and structures of inteins. In particular, this review considers inteins as selfish or parasitic genetic elements, a point of view that explains many otherwise puzzling aspects of inteins.

A nuclear-encoded intein in the fungal pathogen Cryptococcus neoformans

We have used comparative sequence analysis to identify an intein-like sequence (protein splicing element) present in Cryptococcus neoformans, a fungal pathogen of humans. The sequence encoding this element is present in the C. neoformans PRP8 gene, as an in-frame insertion relative to the PRP8 genes of other organisms. It contains sequences similar to those of the protein-splicing domains of two previously described yeast inteins (in Saccharomyces cerevisiae and Candida tropicalis), although it lacks any recognizable internal endonuclease domain. The Cryptococcus neoformans intein (Cne PRP8) is only the second to be found in a eukaryote nuclear genome; the previously described yeast inteins occur at the same site in the VMA gene homologues of S. cerevisiae and C. tropicalis. The host gene of the Cryptococcus intein, PRP8, encodes a highly conserved mRNA splicing protein found as part of the spliceosome. The Cne PRP8 intein may be a useful drug target in addressing the cryptococcal infections so prevalent in AIDS patients.

Homing endonucleases: structural and functional insight into the catalysts of intron/intein mobility

Homing endonucleases confer mobility to their host intervening sequence, either an intron or intein, by catalyzing a highly specific double-strand break in a cognate allele lacking the intervening sequence. These proteins are characterized by their ability to bind long DNA target sites (14-40 bp) and their tolerance of minor sequence changes in these sites. A wealth of biochemical and structural data has been generated for these enzymes over the past few years. Herein we review our current understanding of homing endonucleases, including their diversity and evolution, DNA-binding and catalytic mechanisms, and attempts to engineer them to bind novel DNA substrates.

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

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

Inteins as enzymes

The term "self-catalyzed" as applied to protein processing reactions might be considered a contradiction, since catalysis implies that the catalyst is regenerated without change. However, as our understanding of protein autoprocessing reactions such as protein splicing advances, it is becoming clear that they have many of the hallmarks of enzymatic reactions. In this review, we will examine the properties of protein splicing elements, or inteins, and show how these can be understood in terms of enzyme catalysis, both with respect to substrate specificity and the stabilization of reactive intermediates.

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.

Genome of the extremely radiation-resistant bacterium Deinococcus radiodurans viewed from the perspective of comparative genomics

The bacterium Deinococcus radiodurans shows remarkable resistance to a range of damage caused by ionizing radiation, desiccation, UV radiation, oxidizing agents, and electrophilic mutagens. D. radiodurans is best known for its extreme resistance to ionizing radiation; not only can it grow continuously in the presence of chronic radiation (6 kilorads/h), but also it can survive acute exposures to gamma radiation exceeding 1,500 kilorads without dying or undergoing induced mutation. These characteristics were the impetus for sequencing the genome of D. radiodurans and the ongoing development of its use for bioremediation of radioactive wastes. Although it is known that these multiple resistance phenotypes stem from efficient DNA repair processes, the mechanisms underlying these extraordinary repair capabilities remain poorly understood. In this work we present an extensive comparative sequence analysis of the Deinococcus genome. Deinococcus is the first representative with a completely sequenced genome from a distinct bacterial lineage of extremophiles, the Thermus-Deinococcus group. Phylogenetic tree analysis, combined with the identification of several synapomorphies between Thermus and Deinococcus, supports the hypothesis that it is an ancient group with no clear affinities to any of the other known bacterial lineages. Distinctive features of the Deinococcus genome as well as features shared with other free-living bacteria were revealed by comparison of its proteome to the collection of clusters of orthologous groups of proteins. Analysis of paralogs in Deinococcus has revealed several unique protein families. In addition, specific expansions of several other families including phosphatases, proteases, acyltransferases, and Nudix family pyrophosphohydrolases were detected. Genes that potentially affect DNA repair and recombination and stress responses were investigated in detail. Some proteins appear to have been horizontally transferred from eukaryotes and are not present in other bacteria. For example, three proteins homologous to plant desiccation resistance proteins were identified, and these are particularly interesting because of the correlation between desiccation and radiation resistance. Compared to other bacteria, the D. radiodurans genome is enriched in repetitive sequences, namely, IS-like transposons and small intergenic repeats. In combination, these observations suggest that several different biological mechanisms contribute to the multiple DNA repair-dependent phenotypes of this organism.

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.

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.

Invasion of a multitude of genetic niches by mobile endonuclease genes

Persistence of a mobile DNA element in a population reflects a balance between the ability of the host to eliminate the element and the ability of the element to survive and to disseminate to other individuals. In each of the three biological kingdoms, several families of a mobile DNA element have been identified which encode a single protein that acts on nucleic acids. Collectively termed homing endonuclease genes (HEGs), these elements employ varied strategies to ensure their survival. Some members of the HEG families have a minimal impact on host fitness because they associate with genes having self-splicing introns or inteins that remove the HEGs at the RNA or protein level. The HEG and the intron/intein gene spread throughout the population by a gene conversion process initiated by the HEG-encoded endonuclease called 'homing' in which the HEG and intron/intein genes are copied to cognate alleles that lack them. The endonuclease activity also contributes to a high frequency of lateral transmission of HEGs between species as has been documented in plants and other systems. Other HEGs have positive selection value because the proteins have evolved activities that benefit their host organisms. The success of HEGs in colonizing diverse genetic niches results from the flexibility of the encoded endonucleases in adopting new specificities.

Intronic GIY-YIG endonuclease gene in the mitochondrial genome of Podospora curvicolla: evidence for mobility

Endonuclease genes encoded in invasive introns are themselves supposed to be mobile elements which, during evolution, have colonized pre-existing introns converting them into invasive elements. This hypothesis is supported by numerous data concerning the LAGLI-DADG subclass of intronic endonucleases. Less is known about the GIY-YIG ORFs which constitute another family of endonucleases. In this paper we describe the presence of one optional GIY-YIG ORF in the second intron of the mitochondrial cytochrome b gene in the fungus Podospora curvicolla. We show that this GIY-YIG ORF is efficiently transferred from an ORF-containing intron to an ORF-less allele. We also show that the products of both the GIY-YIG ORF and the non-canonical LAGLI-DADG-GIY-YIG ORF, which is generated by its integration, have endonuclease activities which recognize and cut the insertion site of the optional sequence. This constitutes the first direct evidence for potential mobility of an intronic GIY-YIG endonuclease. We discuss the role that such a mobile sequence could have played during evolution.

InBase, the Intein Database

InBase, the Intein Database (http://www.neb.com/neb/inteins.html ), is a comprehensive on-line resource that includes the Intein Registry. Inteins are protein splicing elements that mediate a self-catalytic protein splicing reaction. InBase presents general information as well as detailed data for each intein, including tabu-lated comparisons and a comprehensive bibliography.

Isolation and characterization of a split B-type DNA polymerase from the archaeon Methanobacterium thermoautotrophicum deltaH

We describe here the isolation and characterization of a B-type DNA polymerase (PolB) from the archaeon Methanobacterium thermoautotrophicum DeltaH. Uniquely, the catalytic domains of M. thermoautotrophicum PolB are encoded from two different genes, a feature that has not been observed as yet in other polymerases. The two genes were cloned, and the proteins were overexpressed in Escherichia coli and purified individually and as a complex. We demonstrate that both polypeptides are needed to form the active polymerase. Similar to other polymerases constituting the B-type family, PolB possesses both polymerase and 3'-5' exonuclease activities. We found that a homolog of replication protein A from M. thermoautotrophicum inhibits the PolB activity. The inhibition of DNA synthesis by replication protein A from M. thermoautotrophicum can be relieved by the addition of M. thermoautotrophicum homologs of replication factor C and proliferating cell nuclear antigen. The possible roles of PolB in M. thermoautotrophicum replication are discussed.

Putting protein splicing to work

Several protein processing events that involve related chemical mechanisms have been observed in nature. Now, new methods have been developed, based on the same chemical reactions, that permit proteins to be modified in ways that were not previously possible.

Protein trans-splicing by a split intein encoded in a split DnaE gene of Synechocystis sp. PCC6803

A split intein capable of protein trans-splicing is identified in a DnaE protein of the cyanobacterium Synechocystis sp. strain PCC6803. The N- and C-terminal halves of DnaE (catalytic subunit alpha of DNA polymerase III) are encoded by two separate genes, dnaE-n and dnaE-c, respectively. These two genes are located 745,226 bp apart in the genome and on opposite DNA strands. The dnaE-n product consists of a N-extein sequence followed by a 123-aa intein sequence, whereas the dnaE-c product consists of a 36-aa intein sequence followed by a C-extein sequence. The N- and C-extein sequences together reconstitute a complete DnaE sequence that is interrupted by the intein sequences inside the beta- and tau-binding domains. The two intein sequences together reconstitute a split mini-intein that not only has intein-like sequence features but also exhibited protein trans-splicing activity when tested in Escherichia coli cells.