Properties of H. volcanii tRNA intron endonuclease reveal a relationship between the archaeal and eucaryal tRNA intron processing systems

Introns in protein-coding genes in Archaea

Introns in protein-coding genes are ubiquitous in eukaryotic cells, but pre-mRNA splicing has yet to be reported in archaeal and its viral genomes. We present evidence of introns in genes encoding a homolog of eukaryotic Cbf5p (centromere-binding factor 5; a subunit of a small nucleolar ribonucleoprotein) in three Archaea; Aeropyrum pernix, Sulfolobus solfataricus and Sulfolobus tokodaii. Splicing of pre-mRNAs in vivo was demonstrated by reverse transcriptase-mediated polymerase chain reaction. The exon-intron boundaries of these genes are predicted to be folded into a structure similar to the bulge-helix-bulge motif, suggesting that splicing of these pre-mRNAs probably depends on the splicing system elucidated for archaeal pre-tRNAs and rRNAs.

This is the end: processing, editing and repair at the tRNA 3'-terminus

The generation of a mature tRNA 3'-end is an important step in the processing pathways leading to functional tRNA molecules. While 5'-end processing by RNase P is similar in all organisms, generation of the mature 3'-terminus seems to be more variable and complex. The first step in this reaction is the removal of 3'-trailer sequences. In bacteria, this is a multistep process performed by endo- and exonucleases. In contrast, the majority of eukaryotes generate the mature tRNA 3'-end in a single step reaction, which consists of an endonucleolytic cut at the tRNA terminus. After removal of the 3'-trailer, a terminal CCA triplet has to be added to allow charging of the tRNA with its cognate amino acid. The enzyme catalyzing this reaction is tRNA nucleotidyltransferase, homologs of which have been found in representatives of all three kingdoms. Furthermore, in metazoan mitochondria, some genes encode 3'-terminally truncated tRNAs, which are restored in an editing reaction in order to yield functional tRNAs. Interestingly, this reaction is not restricted to distinct tRNAs, but seems to act on a variety of tRNA molecules and represents therefore a more general tRNA repair mechanism than a specialized editing reaction. In this review, the current knowledge about these crucial reactions is summarized.

In vitro processing of the 16S rRNA of the thermophilic archaeon Sulfolobus solfataricus

In this paper we have analyzed the processing in vitro of the 16S rRNA of the thermophilic archaeon Sulfolobus solfataricus, using pre-rRNA substrates transcribed in vitro and different protein preparations as the source of processing enzymes. We show that the 5' external transcribed spacer of the S. solfataricus pre-rRNA transcript contains a target site for a specific endonuclease, which recognizes a conserved sequence also existing in the early A0 and 0 processing sites of Saccharomyces cerevisiae and vertebrates. This site is present in other members of the kingdom Crenarchaeota but apparently not in the Euryarchaeota. Furthermore, S. solfataricus pre-16S RNA is processed within the double-helical stem formed by the inverted repeats flanking the 16S RNA sequence, in correspondence with a bulge-helix-bulge motif. The endonuclease responsible for this cleavage is present in both the Crenarchaeota and the Euryarchaeota. The processing pattern remained the same when the substrate was a 30S ribonucleoprotein particle instead of the naked RNA. Maturation of either the 5' or the 3' end of the 16S RNA molecule was not observed, suggesting either that maturation requires conditions not easily reproducible in vitro or that the responsible endonucleases are scarcely represented in cell extracts.

Identification of two catalytic subunits of tRNA splicing endonuclease from Arabidopsis thaliana

tRNA splicing endonuclease is essential for the correct removal of introns from precursor tRNA molecules of Archaea and Eucarya. The only well-characterized eucaryotic enzyme until now is the endonuclease from yeast (Saccharomyces cerevisiae). This protein has a heterotetrameric structure. Two of the four subunits, i.e. Sen34 and Sen44, contain the active sites for cleavage at the 3'- and 5'-splice sites, respectively. We have identified three novel genes from Arabidopsis thaliana, encoding putative subunits of tRNA splicing endonuclease. They are designated as AtSen1, AtSen2, and AtpsSen1. Both genes AtSen1 and AtSen2 seem to be functionally active, as deduced from corresponding cDNA sequences. Comparison of the amino acid sequences of the these two Arabidopsis proteins revealed 72% identity. However, AtpsSen1 is more similar to AtSen1, but is very likely a pseudogene, as concluded from extended stretches of deletions and the presence of in-frame stop codons. All putative proteins contain a conserved domain at their C-terminus common to counterparts from other organisms. Interestingly, they are more similar to the yeast catalytic subunit Sen44 than to Sen34. Southern analysis with various probes revealed that each gene is present as single copies in the nuclear genome. The evolutionary implications of these findings are discussed.

Crystal structure of a dimeric archaeal splicing endonuclease

The splicing endonuclease from Archaeoglobus fulgidus (AF) belongs to the homodimeric family of splicing endonucleases, thought to have evolved from the homotetrameric endonucleases. We report here the crystal structure of the AF endonuclease determined at 2.8 A. The crystal structure of the full-length AF endonuclease contains a homodimer, with each monomer consisting of two homologous repeats joined together by an extended polypeptide chain of ten amino acid residues. The C-terminal repeat has a strong homology to that of a single subunit of the previously determined homotetrameric tRNA splicing endonuclease from Methanococcus jannaschii (MJ), indicating its role in catalysis. The N-terminal repeat is a more degenerate form of the MJ enzyme. Thus the N-terminal repeat is a "non-active" endonuclease fold evolved from the "active" one. By detailed comparison of the structures of the N-terminal and the C-terminal repeats, the binding region for RNA substrates containing a bulge-helix-bulge motif can be identified. Based on the identified RNA-binding region, a cation-pi interaction is suggested to be responsible for coordinating activities between the two active sites. In addition, the full-length AF endonuclease can adopt a higher-ordered fibrous structure in solution, as revealed by the unusual crystallographic packing interactions and other biochemical analysis. This 4(3)-fold fibrous structure adopted by the full-length enzyme is inaccessible to the RNA substrate and is largely stabilized by the first 60 amino acid residues. A mutated form of AF endonuclease with its first 60 residues removed catalyzes the cleavage reaction at a significantly higher rate. Whether there is any role in vivo for this structure-mediated modulation of activity remains to be determined.

RNA bulges as architectural and recognition motifs

RNA bulges constitute versatile structural motifs in the assembly of RNA architectures. Three-dimensional structures of RNA molecules and their complexes reveal the role of bulges in RNA architectures and illustrate the molecular mechanisms by which they confer intramolecular interactions and intermolecular recognition.

Substrate requirements for a novel archaeal endonuclease that cleaves within the 5' external transcribed spacer of Sulfolobus acidocaldarius precursor rRNA

During ribosome biogenesis in the hyperthermophilic archaeon Sulfolobus acidocaldarius, at least three separate precursor endonucleolytic cleavages occur within the 144-nucleotide-long 5' external transcribed spacer (5' ETS) region of the rRNA operon primary transcript. The 5' ETS sequence contains three regions of very stable helical structure. One cleavage (5' to position -98) is in the single-stranded region between the 5' and the central helical domains; a second cleavage (5' to position -31) is in the single-stranded region between the central and the 3' helical domains; and a third cleavage is at the 5' ETS-16S junction (5' to position +1). The three sites share a common consensus sequence around the position of cleavage. We have used an in vitro pre-RNA processing assay to define some of the sequence and structural recognition elements necessary for the two precursor cleavages 5' to positions -98 and -31. Surprisingly, none of the three predominant helical domains are required for recognition or targeting of the cleavages, although their removal reduces the rate of cleavage site utilization. We show that the sequence AAG downward arrow (CA)UU encompassing each site contains at least some of the essential features for recognition and efficient targeting of the cleavages. Cleavage depends on the presence of a purine 5' and a uracil two nucleotides 3' to the scissile phosphodiester bond. Mutations to other bases at these critical positions are either not cleaved or cleaved very poorly. Finally, on the basis of intermediates that are produced during a processing reaction, we can conclude that the cleavages at positions 98 and 31 are not ordered in vitro.

An unspliced group I intron in 23S rRNA links Chlamydiales, chloroplasts, and mitochondria

Chlamydia was the only genus in the order Chlamydiales until the recent characterization of Simkania negevensis Z(T) and Parachlamydia acanthamoebae strains. The present study of Chlamydiales 23S ribosomal DNA (rDNA) focuses on a naturally occurring group I intron in the I-CpaI target site of 23S rDNA from S. negevensis. The intron, SnLSU. 1, belonged to the IB4 structural subgroup and was most closely related to large ribosomal subunit introns that express single-motif, LAGLIDADG endonucleases in chloroplasts of algae and in mitochondria of amoebae. RT-PCR and electrophoresis of in vivo rRNA indicated that the intron was not spliced out of the 23S rRNA. The unspliced 658-nt intron is the first group I intron to be found in bacterial rDNA or rRNA, and it may delay the S. negevensis developmental replication cycle by affecting ribosomal function.

Mechanism of non-spliceosomal mRNA splicing in the unfolded protein response pathway

The unfolded protein response is an intracellular signaling pathway that, in response to accumulation of misfolded proteins in the lumen of the endoplasmic reticulum (ER), upregulates transcription of ER resident chaperones. A key step in this pathway is the non-conventional, regulated splicing of the mRNA encoding the positive transcriptional regulator Hac1p. In the yeast Saccharomyces cerevisiae, the bifunctional transmembrane kinase/endoribonuclease Ire1p cleaves HAC1 mRNA at both splice junctions and tRNA ligase joins the two exons together. We have reconstituted HAC1 mRNA splicing in an efficient in vitro reaction and show that, in many ways, the mechanism of HAC1 mRNA splicing resembles that of pre-tRNA splicing. In particular, Ire1p endonucleolytic cleavage leaves 2', 3'-cyclic phosphates, the excised exons remain associated by base pairing, and exon ligation by tRNA ligase follows the same chemical steps as for pre-tRNA splicing. To date, this mechanism of RNA processing is unprecedented for a messenger RNA. In contrast to the striking similarities to tRNA splicing, the structural features of the splice junctions recognized by Ire1p differ from those recognized by tRNA endonuclease. We show that small stem-loop structures predicted to form at both splice junctions of HAC1 mRNA are required and sufficient for Ire1p cleavage.

Function, mechanism and regulation of bacterial ribonucleases

The maturation and degradation of RNA molecules are essential features of the mechanism of gene expression, and provide the two main points for post-transcriptional regulation. Cells employ a functionally diverse array of nucleases to carry out RNA maturation and turnover. Viruses also employ cellular ribonucleases, or even use their own in their reproductive cycles. Studies on bacterial ribonucleases, and in particular those from Escherichia coli, are providing insight into ribonuclease structure, mechanism, and regulation. Ongoing biochemical and genetic analyses are revealing that many ribonucleases are phylogenetically conserved, and exhibit overlapping functional roles and perhaps common catalytic mechanisms. This article reviews the salient features of bacterial ribonucleases, with a focus on those of E. coli, and in particular, ribonuclease III. RNase III participates in a number of RNA maturation and RNA decay pathways, and is regulated by phosphorylation in the T7 phage-infected cell. Plasmid and phage RNAs, in addition to cellular transcripts, are RNase III targets. RNase III orthologues occur in eukaryotic cells, and play key functional roles. As such, RNase III provides an important model with which to understand mechanisms of RNA maturation, RNA decay, and gene regulation.

Transient ADP-ribosylation of a 2'-phosphate implicated in its removal from ligated tRNA during splicing in yeast

The last step of tRNA splicing in yeast is catalyzed by Tpt1 protein, which transfers the 2'-phosphate from ligated tRNA to NAD to produce ADP-ribose 1"-2"-cyclic phosphate (Appr>p). Structural and functional TPT1 homologs are found widely in eukaryotes and, surprisingly, also in Escherichia coli, which does not have this class of tRNA splicing. To understand the possible roles of the Tpt1 enzymes as well as the unusual use of NAD, the reaction mechanism of the E. coli homolog KptA was investigated. We show here that KptA protein removes the 2'-phosphate from RNA via an intermediate in which the phosphate is ADP-ribosylated followed by a presumed transesterification to release the RNA and generate Appr>p. The intermediate was characterized by analysis of its components and their linkages, using various labeled substrates and cofactors. Because the yeast and mouse Tpt1 proteins, like KptA protein, can catalyze the conversion of the KptA-generated intermediate to both product and the original substrate, these enzymes likely use the same reaction mechanism. Step 1 of this reaction is strikingly similar to the ADP-ribosylation of proteins catalyzed by a number of bacterial toxins.

Intracellular signaling from the endoplasmic reticulum to the nucleus

Cells respond to an accumulation of unfolded proteins in the endoplasmic reticulum (ER) by increasing transcription of genes encoding ER resident proteins. The information is transmitted from the ER lumen to the nucleus by an intracellular signaling pathway called the unfolded protein response (UPR). Recent work has shown that this signaling pathway utilizes several novel mechanisms, including translational attenuation and a regulated mRNA splicing step. In this review we aim to integrate these recent advances with current knowledge about maintenance of ER composition and abundance.

A functional homolog of a yeast tRNA splicing enzyme is conserved in higher eukaryotes and in Escherichia coli

tRNA splicing in the yeast Saccharomyces cerevisiae requires an endonuclease to excise the intron, tRNA ligase to join the tRNA half-molecules, and 2'-phosphotransferase to transfer the splice junction 2'-phosphate from ligated tRNA to NAD, producing ADP ribose 1"-2" cyclic phosphate (Appr>p). We show here that functional 2'-phosphotransferases are found throughout eukaryotes, occurring in two widely divergent yeasts (Candida albicans and Schizosaccharomyces pombe), a plant (Arabidopsis thaliana), and mammals (Mus musculus); this finding is consistent with a role for the enzyme, acting in concert with ligase, to splice tRNA or other RNA molecules. Surprisingly, functional 2'-phosphotransferase is found also in the bacterium Escherichia coli, which does not have any known introns of this class, and does not appear to have a ligase that generates junctions with a 2'-phosphate. Analysis of the database shows that likely members of the 2'-phosphotransferase family are found also in one other bacterium (Pseudomonas aeruginosa) and two archaeal species (Archaeoglobus fulgidus and Pyrococcus horikoshii). Phylogenetic analysis reveals no evidence for recent horizontal transfer of the 2'-phosphotransferase into Eubacteria, suggesting that the 2'-phosphotransferase has been present there since close to the time that the three kingdoms diverged. Although 2'-phosphotransferase is not present in all Eubacteria, and a gene disruption experiment demonstrates that the protein is not essential in E. coli, the continued presence of 2'-phosphotransferase in Eubacteria over large evolutionary times argues for an important role for the protein.

Transcription analysis of two disparate rRNA operons in the halophilic archaeon Haloarcula marismortui

The genome of the halophilic archaeon Haloarcula marismortui contains two rRNA operons designated rrnA and rrnB. Genomic clones of the two operons and their flanking regions have been sequenced, and primary transcripts and processing intermediates derived from each operon have been characterized. The 16S, 23S, and 5S genes from the two operons were found to differ at 74 of 1,472 positions, 39 of 2,922 positions, and 2 of 122 positions, respectively. This degree of sequence divergence for multicopy (paralogous) rRNA genes was 10- to 50-fold or more higher than anticipated. The two operons exhibit other profound differences that include (i) the presence in rrnA and the absence in rrnB of tRNAAla and tRNACys genes in the intergenic and distal regions, respectively, (ii) divergent 5' flanking sequences, and (iii) distinct pathways for processing and maturation of 16S rRNA. Processing and maturation of 16S and 23S rRNA from rrnA operon transcripts and of 23S rRNA from rrnB operon transcripts follow the canonical halophilic pathway, whereas maturation of 16S rRNA from rrnB operon transcripts follows an unusual and different pathway that is apparently devoid of any 5' processing intermediate.

The tRNA(guanine-26,N2-N2) methyltransferase (Trm1) from the hyperthermophilic archaeon Pyrococcus furiosus: cloning, sequencing of the gene and its expression in Escherichia coli

The structural gene pfTRM1 (GenBank accession no. AF051912), encoding tRNA(guanine-26, N 2- N 2) methyltransferase (EC 2.1.1.32) of the strictly anaerobic hyperthermophilic archaeon Pyrococcus furiosus, has been identified by sequence similarity to the TRM1 gene of Saccharomyces cerevisiae (YDR120c). The pfTRM1 gene in a 3.0 kb restriction DNA fragment of P.furiosus genomic DNA has been cloned by library screening using a PCR probe to the 5'-part of the corresponding ORF. Sequence analysis revealed an entire ORF of 1143 bp encoding a polypeptide of 381 residues (calculated molecular mass 43.3 kDa). The deduced amino acid sequence of this newly identified gene shares significant similarity with the TRM1- like genes of three other archaea (Methanococcus jannaschii, Methanobacterium thermoautotrophicum and Archaeoglobus fulgidus), one eukaryon (Caenorhabditis elegans) and one hyperthermophilic eubacterium (Aquifex aeolicus). Two short consensus motifs for S-adenosyl-l-methionine binding are detected in the sequence of pfTrm1p. Cloning of the P.furiosus TRM1 gene in an Escherichia coli expression vector allowed expression of the recombinant protein (pfTrm1p) with an apparent molecular mass of 42 kDa. A protein extract from the transformed E.coli cells shows enzymatic activity for the quantitative formation of N 2, N 2-dimethylguanosine at position 26 in a transcript of yeast tRNAPhe used as substrate. The recombinant enzyme was also shown to modify bulk E.coli tRNAs in vivo.

Molecular characterization and postsplicing fate of three introns within the single rRNA operon of the hyperthermophilic archaeon Aeropyrum pernix K1

The single rRNA operon (arnS-arnL) of the hyperthermophilic archaeon Aeropyrum pernix K1 was sequenced. The DNA sequence data and detailed RNA analyses disclosed an unusual feature: the presence of three introns at hitherto undescribed insertion positions within the rRNA genes. The 699-nucleotide (nt) intron Ialpha was located at position 908 (Escherichia coli numbering [H. F. Noller, Annu. Rev. Biochem. 53:119-162, 1984]) of the 16S rRNA, while the 202-nt intron Ibeta and 575-nt intron Igamma were located at positions 1085 and 1927 (E. coli numbering), respectively, of the 23S rRNA. They were located within highly conserved sites which have been implicated as crucial for rRNA function in E. coli. All three introns were remarkably AT rich (41.5 to 43.1 mol% G+C) compared with the mature rRNAs (67.7 and 69.2 mol% G+C for 16S and 23S rRNAs, respectively). No obvious primary sequence similarities were detected among them. After splicing from rRNA transcripts in vivo, a large quantity of intronic RNAs were stably retained in the linear monomeric form, whereas a trace of topoisomeric RNA molecules also appeared, as characterized by their behavior in two-dimensional gel electrophoresis. Secondary structural models of the Ialpha-, Ibeta-, and Igamma-containing rRNA precursors agree with the bulge-helix-bulge motif. Two of the introns, Ialpha and Igamma, contained open reading frames whose protein translation exhibited no overall similarity with proteins reported so far. However, both share a LAGLI-DADG motif characteristic of homing endonucleases.

Archaea and the prokaryote-to-eukaryote transition

Since the late 1970s, determining the phylogenetic relationships among the contemporary domains of life, the Archaea (archaebacteria), Bacteria (eubacteria), and Eucarya (eukaryotes), has been central to the study of early cellular evolution. The two salient issues surrounding the universal tree of life are whether all three domains are monophyletic (i.e., all equivalent in taxanomic rank) and where the root of the universal tree lies. Evaluation of the status of the Archaea has become key to answering these questions. This review considers our cumulative knowledge about the Archaea in relationship to the Bacteria and Eucarya. Particular attention is paid to the recent use of molecular phylogenetic approaches to reconstructing the tree of life. In this regard, the phylogenetic analyses of more than 60 proteins are reviewed and presented in the context of their participation in major biochemical pathways. Although many gene trees are incongruent, the majority do suggest a sisterhood between Archaea and Eucarya. Altering this general pattern of gene evolution are two kinds of potential interdomain gene transferrals. One horizontal gene exchange might have involved the gram-positive Bacteria and the Archaea, while the other might have occurred between proteobacteria and eukaryotes and might have been mediated by endosymbiosis.

Archaea: what can we learn from their sequences?

Gene-by-gene and traditional biochemical approaches continue to reveal surprising molecular features in the archaeal domain. In addition, the complete sequencing of several archaeal genomes has further confirmed the phenotypic coherence of these micro-organisms at the molecular level. Nevertheless, the phylogeny of Archaea and the nature of the last universal common ancestor are still matters for debate.

Complete genome sequence of Methanobacterium thermoautotrophicum deltaH: functional analysis and comparative genomics

The complete 1,751,377-bp sequence of the genome of the thermophilic archaeon Methanobacterium thermoautotrophicum deltaH has been determined by a whole-genome shotgun sequencing approach. A total of 1,855 open reading frames (ORFs) have been identified that appear to encode polypeptides, 844 (46%) of which have been assigned putative functions based on their similarities to database sequences with assigned functions. A total of 514 (28%) of the ORF-encoded polypeptides are related to sequences with unknown functions, and 496 (27%) have little or no homology to sequences in public databases. Comparisons with Eucarya-, Bacteria-, and Archaea-specific databases reveal that 1,013 of the putative gene products (54%) are most similar to polypeptide sequences described previously for other organisms in the domain Archaea. Comparisons with the Methanococcus jannaschii genome data underline the extensive divergence that has occurred between these two methanogens; only 352 (19%) of M. thermoautotrophicum ORFs encode sequences that are >50% identical to M. jannaschii polypeptides, and there is little conservation in the relative locations of orthologous genes. When the M. thermoautotrophicum ORFs are compared to sequences from only the eucaryal and bacterial domains, 786 (42%) are more similar to bacterial sequences and 241 (13%) are more similar to eucaryal sequences. The bacterial domain-like gene products include the majority of those predicted to be involved in cofactor and small molecule biosyntheses, intermediary metabolism, transport, nitrogen fixation, regulatory functions, and interactions with the environment. Most proteins predicted to be involved in DNA metabolism, transcription, and translation are more similar to eucaryal sequences. Gene structure and organization have features that are typical of the Bacteria, including genes that encode polypeptides closely related to eucaryal proteins. There are 24 polypeptides that could form two-component sensor kinase-response regulator systems and homologs of the bacterial Hsp70-response proteins DnaK and DnaJ, which are notably absent in M. jannaschii. DNA replication initiation and chromosome packaging in M. thermoautotrophicum are predicted to have eucaryal features, based on the presence of two Cdc6 homologs and three histones; however, the presence of an ftsZ gene indicates a bacterial type of cell division initiation. The DNA polymerases include an X-family repair type and an unusual archaeal B type formed by two separate polypeptides. The DNA-dependent RNA polymerase (RNAP) subunits A', A", B', B" and H are encoded in a typical archaeal RNAP operon, although a second A' subunit-encoding gene is present at a remote location. There are two rRNA operons, and 39 tRNA genes are dispersed around the genome, although most of these occur in clusters. Three of the tRNA genes have introns, including the tRNAPro (GGG) gene, which contains a second intron at an unprecedented location. There is no selenocysteinyl-tRNA gene nor evidence for classically organized IS elements, prophages, or plasmids. The genome contains one intein and two extended repeats (3.6 and 8.6 kb) that are members of a family with 18 representatives in the M. jannaschii genome.

RNA-protein interactions of an archaeal homotetrameric splicing endoribonuclease with an exceptional evolutionary history

The splicing endoribonuclease from Methanococcus jannaschii, a member of a recently defined family of enzymes involved in splicing of archaeal introns and eukaryotic nuclear tRNA introns, was isolated and shown by cross-linking studies to form a homotetramer in solution. A non-cleavable substrate analogue was synthesized by incorporating 2'-deoxyuridines at the two cleavage sites and complexed to the splicing enzyme. The complex was subjected to protein footprinting and the results implicated an RNP1-like sequence and a sequence region immediately N-terminal to a putative leucine zipper in substrate binding. In addition, a histidine residue (His125), positioned within a third RNA binding region, was shown to be involved in catalysis by mutagenesis. The splicing enzyme was localized on the central helix and the two 3 nt bulges of the conserved archaeal 'bulge-helix-bulge' substrate motif by RNA footprinting. Sequence comparison with the dimeric splicing enzyme from Halobacterium volcanii demonstrates that the latter is a tandemly repeated duplication of the former, where alternating segments within each protein half degenerated after the duplication event. Another duplication event, in the eukaryotic domain, produced two different homologues of the M.jannaschii-type enzyme structure. The data provide strong evidence that the tetrameric M.jannaschii enzyme consists of two isologously associated dimers, each similar to one H.volcanii monomer and each consisting of two monomers, where one face of monomer 1 and the opposite face of monomer 2 are involved in RNA binding.

The transmembrane kinase Ire1p is a site-specific endonuclease that initiates mRNA splicing in the unfolded protein response

The endoplasmic reticulum (ER) communicates with the nucleus through the unfolded protein response (UPR), which senses accumulation of unfolded proteins in the ER lumen and leads to increased transcription of genes encoding ER-resident chaperones. As a key regulatory step in this signaling pathway, the mRNA encoding the UPR-specific transcription factor Hac1p becomes spliced by a unique mechanism that requires tRNA ligase but not the spliceosome. Splicing is initiated upon activation of Ire1p, a transmembrane kinase that lies in the ER and/or inner nuclear membrane. We show that Ire1p is a bifunctional enzyme: in addition to being a kinase, it is a site-specific endoribonuclease that cleaves HAC1 mRNA specifically at both splice junctions. The addition of purified tRNA ligase completes splicing; we therefore have reconstituted HAC1 mRNA splicing in vitro from purified components.

RNA splicing ligase activity in the archaeon Haloferax volcanii

At least two separate enzymes, an endonuclease and a ligase, appear to be involved in tRNA splicing in halophilic archaea. We have identified and partially characterized a splicing ligase activity in cell extracts of Haloferax volcanii that can ligate deproteinized exon products generated in a separate endonuclease reaction. As in vitro transcribed partial intron-deleted derivative of H. volcanii elongator tRNA(Met) is used as substrate for the endonuclease. The ligase can also join the two exons that are independently eluted from the gels. This ligase activity is observed at a range (50 mM to 2.8 M) of monovalent cations in the assays, but is abolished when the enzyme preparations are depleted of the monovalent cations. In contrast, H. volcanii splicing endonuclease has been reported to require divalent cations and is inhibited by monovalent cations. Our endonuclease assays confirm these reports, and also show that the endonuclease is not permanently inactivated even in high monovalent cation containing extracts. The ligase activity in the extracts does not appear to require any divalent cation or exogenously added source of energy or phosphate.

Splicing of intron-containing tRNATrp by the archaeon Haloferax volcanii occurs independent of mature tRNA structure

We have investigated the requirements for mature tRNA structure in the in vivo splicing of the Haloferax volcanii, intron-containing tRNATrp RNA. A partial tRNATrp gene, which contained only the anticodon stem-loop region of the mature tRNA, was fused to a carrier yeast tRNA gene for expression in H. volcanii. Transcripts from this hybrid gene were found to be processed by endonuclease and ligase at the tRNATrp exon-intron boundaries. These results verify that the substrate recognition properties of the halobacterial endonuclease observed in vitro reflect the properties of this enzyme in vivo, namely that mature tRNA structure is not essential for recognition by the endonuclease. The independence of these reactions on mature tRNA provides further support for a relationship between archaeal tRNA and rRNA intron-processing systems and highlight a difference in the substrate recognition properties between the archaeal and eucaryal processing systems. The significance of these differences is discussed in light of the observation that the tRNA endonucleases of these organisms are related.