Are the tryptophanyl-tRNA synthetase and the peptide-chain-release factor from higher eukaryotes one and the same protein?

Pseudorabies virus manipulates mitochondrial tryptophanyl-tRNA synthetase 2 for viral replication

The pseudorabies virus (PRV) is identified as a double-helical DNA virus responsible for causing Aujeszky's disease, which results in considerable economic impacts globally. The enzyme tryptophanyl-tRNA synthetase 2 (WARS2), a mitochondrial protein involved in protein synthesis, is recognized for its broad expression and vital role in the translation process. The findings of our study showed an increase in both mRNA and protein levels of WARS2 following PRV infection in both cell cultures and animal models. Suppressing WARS2 expression via RNA interference in PK-15 ​cells led to a reduction in PRV infection rates, whereas enhancing WARS2 expression resulted in increased infection rates. Furthermore, the activation of WARS2 in response to PRV was found to be reliant on the cGAS/STING/TBK1/IRF3 signaling pathway and the interferon-alpha receptor-1, highlighting its regulation via the type I interferon signaling pathway. Further analysis revealed that reducing WARS2 levels hindered PRV's ability to promote protein and lipid synthesis. Our research provides novel evidence that WARS2 facilitates PRV infection through its management of protein and lipid levels, presenting new avenues for developing preventative and therapeutic measures against PRV infections.

RNA-protein interactions at the initial and terminal stages of protein biosynthesis as investigated by Lev Kisselev (on the occasion of his 70th anniversary)

This review highlights studies by Lev L. Kisselev and his colleagues on the initial and terminal stages of protein biosynthesis, which cover the period of the last 45 years (1961-2006). They investigated spatial structure of tRNAs, structure and functions of aminoacyl-tRNA-synthetases of higher organisms, and the final step of protein synthesis, termination of translation. L. Kisselev and his team have made three major contributions to these fields of molecular biology; (i) they proposed the hypothesis on the role of anticodon triplet of tRNA in recognition by cognate aminoacyl-tRNA synthetase, which has been experimentally confirmed and is now included in textbooks; (ii) identified primary structures and functions of two eukaryotic protein factors (eRF1 and eRF3) playing a pivotal role in translation termination; (iii) characterized a structural basis for stop codon recognition by eRF1 within the ribosome and discovered the negative structural elements of eRF1, limiting its recognition of one or two stop-codons.

Alternative processing of the tryptophanyl-tRNA synthetase mRNA from interferon-treated human cells

We have analysed the structure of mRNA isoforms of the human gene encoding tryptophanyl-tRNA synthetase (Trp-tRNA synthetase) expressed in the epithelial CaOv cells and MT-4 lymphocytes. The Trp-tRNA synthetase gene is induced by interferon-gamma in both lines and, in MT-4 lymphocytes, also by interferon-alpha. Four Trp-tRNA synthetase mRNA isoforms have different combinations of the first exons IA, IB and II. Two transcription initiation sites (P1 and P2) were detected 90 bp from each other. Processing of the primary transcript initiated from the P1 start site generates the mRNA isoform where exon IA joins to exon II. The other three isoforms are produced by alternative splicing of the primary transcript produced from the P2 start site. Isoform 2 has a 3'-end fragment of exon IA joined to exon II. Isoform 3 contains exons IA and IB. Isoform 4 contains exon IA and exon III and lacks exon II encoding the N-terminus of the Trp-tRNA synthetase. Therefore, the two primary transcripts of the Trp-tRNA synthetase gene differ only in the 5' flank sequence between P1 and P2, and this fragment regulates their processing. Both interferon-alpha and interferon-gamma induce exon IA-containing and exon IB-containing isoforms of the Trp-tRNA synthetase mRNA.

Termination of translation in eukaryotes

Termination of translation is governed in ribosomes by polypeptide chain release factors (pRF and eRF in prokaryotes and eukaryotes, respectively). In prokaryotes, three pRF have been indentified and sequenced, while in eukaryotes, only a single eRF has been identified to date. Recently, we have characterized a highly conserved protein family called eRF1. At least, human and Xenopus laevis proteins from this family are active as eRFs in the in vitro assay with any of the three stop codons. No structural similarity has been revealed between any of the three pRFs and eRF1 family. Furthermore, GTP-binding motifs have not been revealed, although translation termination in eukaryotes is a GTP-dependent process. We have demonstrated that in eukaryotes a second eRF exists in addition to eRF1, called eRF3. The eRF3 family has two features in common: presence of GTP-binding motifs and high conservation of the C-terminal domain structure. The C-terminal domain of the X. laevis eRF3 has no RF activity although it stimulates the eRF1 activity considerably at low concentration of the stop codons, conferring GTP dependence to the termination reaction. Without eRF3, the eRF1 activity is entirely GTP independent. Some features of X. laevis eRF3 (C-terminal domain) resemble those of pRF3. The newly identified eRF1 and eRF3 are structurally conserved and distinct from the respective pRF1/2 and pRF3 proteins, pointing to the possibility of different evolution of translation termination machinery in prokaryotes and eukaryotes. Bipartition of the translation termination apparatus probably provides high rate and accuracy of translation termination.

Transcriptional regulation of the interferon-gamma-inducible tryptophanyl-tRNA synthetase includes alternative splicing

We have investigated the transcriptional control elements of the human interferon (IFN)-gamma-induced tryptophanyl-tRNA synthetase (hWRS) gene and characterized the transcripts. Transcription leads to a series of mRNAs with different combinations of the first exons. The full-length mRNA codes for a 55-kDa protein (hWRS), but a mRNA lacking exon II is present in almost as high amounts as the full-length transcript. This alternatively spliced mRNA is probably translated into a 48-kDa protein starting from Met48 in exon III. The predicted 48-kDa protein corresponds exactly to an IFN-gamma-inducible protein previously detected by two-dimensional gel electrophoresis. By isolation of genomic clones and construction of plasmids containing hWRS promoter fragments fused to the secreted alkaline phosphatase reporter gene we have mapped a promoter region essential for IFN-mediated gene activation. This region contains IFN-stimulated response elements (ISRE) as well as a Y-box and a gamma-activated sequence (GAS) element. IFN-gamma inducibility of hWRS depends on ongoing protein synthesis, suggesting that so far undescribed transcription factors apart from the latent GAS-binding protein p91 contribute to gene activation. This could be interferon-regulatory factor-1, which binds ISRE elements.

Polypeptide chain termination in Saccharomyces cerevisiae

The study of translational termination in yeast has been approached largely through the identification of a range of mutations which either increase or decrease the efficiency of stop-codon recognition. Subsequent cloning of the genes encoding these factors has identified a number of proteins important for maintaining the fidelity of termination, including at least three ribosomal proteins (S5, S13, S28). Other non-ribosomal proteins have been identified by mutations which produce gross termination-accuracy defects, namely the SUP35 and SUP45 gene products which have closely-related higher eukaryote homologues (GST1-h and SUP45-h respectively) and which can complement the corresponding defective yeast proteins, implying that the yeast ribosome may be a good model for the termination apparatus existing in higher translation systems. While the yeast mitochondrial release factor has been cloned (Pel et al. 1992), the corresponding cytosolic RF has not yet been identified. It seems likely, however, that the identification of the gene encoding eRF could be achieved using a multicopy antisuppressor screen such as that employed to clone the E. coli prfA gene (Weiss et al. 1984). Identification of the yeast eRF and an investigation of its interaction with other components of the yeast translational machinery will no doubt further the definition of the translational termination process. While a large number of mutations have been isolated in which the efficiency of termination-codon recognition is impaired, it seems probable that a proportion of mutations within this class will comprise those where the accuracy of 'A' site codon-anticodon interaction is compromised: such defects would also have an effect on termination-codon suppression, allowing mis- or non-cognate tRNAs to bind stop-codons, causing nonsense suppression. The remainder of mutations affecting termination fidelity should represent mutations in genes coding for components of the termination apparatus, including the eRF: these mutations reduce the efficiency of termination, allowing nonsense suppression by low-efficiency natural suppressor tRNAs. Elucidation of the mechanism of termination in yeast will require discrimination between these two classes of mutations, thus allowing definition of termination-specific gene products.

Termination of protein synthesis

One of three mRNA codons--UAA, UAG and UGA--is used to signal to the elongating ribosome that translation should be terminated at this point. Upon the arrival of the stop codon at the ribosomal acceptor(A)-site, a protein release factor (RF) binds to the ribosome resulting in the peptidyl transferase centre of the ribosome switching to a hydrolytic function to remove the completed polypeptide chain from the peptidyl-tRNA bound at the adjacent ribosomal peptidyl(P)-site. In this review recent advances in our understanding of the mechanism of termination in the bacterium Escherichia coli will be summarised, paying particular attention to the roles of 16S ribosomal RNA and the release factors RF-1, RF-2 and RF-3 in stop codon recognition. Our understanding of the translation termination process in eukaryotes is much more rudimentary with the identity of the single eukaryotic release factor (eRF) still remaining elusive. Finally, several examples of how the termination mechanism can be subverted either to expand the genetic code (e.g. selenocysteine insertion at UGA codons) or to regulate the expression of mammalian retroviral or plant viral genomes will be discussed.

The "eRF" clone corresponds to tryptophanyl-tRNA synthetase, not mammalian release factor

To study the similarity between a putative cloned mammalian release factor (RF) and tryptophanyl-tRNA synthetase (TRS), a recombinant rabbit RF fusion protein was expressed from prokaryotic expression vectors. Purified fractions of the fusion proteins were tested for TRS and RF activities. Addition of the fusion protein to a TRS assay increased the binding of tryptophan to tRNA(Trp). However, in an assay for RF activity, the addition of the fusion protein resulted in release of only 1-3% of formylmethionine from an fMet-tRNA-AUG-ribosome intermediate that had been provided with UAAA as message. To confirm this result, the coding region of the putative eukaryotic RF clone "eRF" was used for in vitro transcription and translation in a rabbit reticulocyte lysate system, resulting in the synthesis of a single 56-kDa protein. The influence of this 56-kDa protein on the termination of translation directed by tobacco mosaic virus was studied. Tobacco mosaic virus RNA produced a major 126-kDa protein and a minor 184-kDa readthrough protein in an in vitro translation system. The protein generated from the "eRF" coding region did not inhibit biosynthesis of the 184-kDa readthrough virus protein. Instead, it increased the yield of both viral proteins. This increase was presumably due to its TRS activity. Chromatography of proteins derived from human lymphoblasts separated RF from TRS activity. Thus, our results indicate that the previously cloned "eRF" clone encodes TRS and that rabbit reticulocyte RF activity lies in a different protein.

Interferon inducibility of mammalian tryptophanyl-tRNA synthetase: new perspectives

Mammalian aminoacyl-tRNA synthetases are indispensible components of the cell's protein-synthesizing machinery. Surprisingly, recent experiments have demonstrated that synthesis of tryptophanyl-tRNA synthetase (WRS) is markedly enhanced after incubation of human cells with interferons. Why is this housekeeping enzyme interferon-inducible? Several hypotheses have been suggested. One hypothesis, that premature termination of protein synthesis was involved, was boosted by the discovery that the deduced amino acid sequence of the mammalian peptide chain release factor (RF) closely resembled that of WRS. Further investigation, however, suggests that the DNA encoding RF was wrongly identified and in fact encodes a rabbit WRS subunit. Other hypotheses on the interferon-inducibility of WRS, including the possibility that the protein performs other, regulatory functions in addition to its core enzymic activity, remain to be explored.

Mammalian tryptophanyl-tRNA synthetases

Aminoacyl-tRNA synthetases of higher organisms are far less studied compared to their prokaryotic and unicellular eukaryotic counterparts. However, many aminoacyl-tRNA synthetases from multi-cellular organisms exhibit certain features not yet described for the same enzymes of bacteria or yeast. Tryptophanyl-tRNA synthetases (TrpRS) are among the most thoroughly studied mammalian enzymes of this group. TrpRS are Zn(2+)-dependent, dimeric, class I aminoacyl-tRNA synthetases with known amino acid sequence for four different mammalian orders. TrpRS is not associated in a stable multi-synthetase complex, although it exhibits a long N-terminal extension absent from bacterial TrpRS. The human gene encoding TrpRS belongs to the interferon-responsive gene family and TrpRS activity drastically increases after interferon gamma induction. For unknown reasons TrpRS is overproduced in pancreas of Ruminantia. Other data on TrpRS available so far are summarized and briefly discussed here.