Translation termination in eukaryotes: polypeptide release factor eRF1 is composed of functionally and structurally distinct domains.

Class-1 polypeptide chain release factors (RFs) trigger hydrolysis of peptidyl-tRNA at the ribosomal peptidyl transferase center mediated by one of the three termination codons. In eukaryotes, apart from catalyzing the translation termination reaction, eRF1 binds to and activates another factor, eRF3, which is a ribosome-dependent and eRF1-dependent GTPase. Because peptidyl-tRNA hydrolysis and GTP hydrolysis could be uncoupled in vitro, we suggest that the two main functions of eRF1 are associated with different domains of the eRF1 protein. We show here by deletion analysis that human eRF1 is composed of two physically separated and functionally distinct domains. The "core" domain is fully competent in ribosome binding and termination-codon-dependent peptidyl-tRNA hydrolysis, and encompasses the N-terminal and middle parts of the polypeptide chain. The C-terminal one-third of eRF1 binds to eRF3 in vivo in the absence of the core domain, but both domains are required to activate eRF3 GTPase in the ribosome. The calculated isoelectric points of the core and C domains are 9.74 and 4.23, respectively. This highly uneven charge distribution between the two domains implies that electrostatic interdomain interaction may affect the eRF1 binding to the ribosome and eRF3, its activity in the termination reaction and activation of eRF3 GTPase. The positively charged core of eRF1 may interact with negatively charged rRNA and peptidyl-tRNA phosphate backbones at the ribosomal eRF1 binding site and exhibit RNA-binding ability. The structural and functional dissimilarity of the core and eRF3-binding domains implies that evolutionarily eRF1 originated as a product of gene fusion.

Mutations in the highly conserved GGQ motif of class 1 polypeptide release factors abolish ability of human eRF1 to trigger peptidyl-tRNA hydrolysis.

Although the primary structures of class 1 polypeptide release factors (RF1 and RF2 in prokaryotes, eRF1 in eukaryotes) are known, the molecular basis by which they function in translational termination remains obscure. Because all class 1 RFs promote a stop-codon-dependent and ribosome-dependent hydrolysis of peptidyl-tRNAs, one may anticipate that this common function relies on a common structural motif(s). We have compared amino acid sequences of the available class 1 RFs and found a novel, common, unique, and strictly conserved GGQ motif that should be in a loop (coil) conformation as deduced by programs predicting protein secondary structure. Site-directed mutagenesis of the human eRF1 as a representative of class 1 RFs shows that substitution of both glycyl residues in this motif, G183 and G184, causes complete inactivation of the protein as a release factor toward all three stop codons, whereas two adjacent amino acid residues, G181 and R182, are functionally nonessential. Inactive human eRF1 mutants compete in release assays with wild-type eRF1 and strongly inhibit their release activity. Mutations of the glycyl residues in this motif do not affect another function, the ability of eRF1 together with the ribosome to induce GTPase activity of human eRF3, a class 2 RF. We assume that the novel highly conserved GGQ motif is implicated directly or indirectly in the activity of class 1 RFs in translation termination.

Termination of translation in eukaryotes: new results and new hypotheses.

Important new results obtained in studies of prokaryotic and eukaryotic translation termination during 1994-1998 are reviewed. Properties of the newly discovered factors RF3, eRF1, and eRF3 are described. Similarity and difference between prokaryotic and eukaryotic systems of translation termination and recent models of molecular mechanisms of protein synthesis at the termination stage are discussed. Hypotheses concerning the biological role of eRF3 are formulated and discussed.

C-terminal domains of human translation termination factors eRF1 and eRF3 mediate their in vivo interaction.

At the termination step of protein synthesis, hydrolysis of the peptidyl-tRNA is jointly catalysed at the ribosome by the termination codon and the polypeptide release factor (eRF1 in eukaryotes). eRF1 forms in vivo and in vitro a stable complex with release factor eRF3, an eRF1-dependent and ribosome-dependent GTPase. The role of the eRF1-eRF3 complex in translation remains unclear. We have undertaken a systematic analysis of the interactions between the human eRF1 and eRF3 employing a yeast two-hybrid assay. We show that the N-terminal parts of eRF1 (positions 1-280) and of eRF3 (positions 1477) are either not involved or non-essential for binding. Two regions in each factor are critical for mutual binding: positions 478-530 and 628-637 of eRF3 and positions 281-305 and 411-415 of eRF1. The GTP binding domain of eRF3 is not involved in complex formation with eRF1. The GILRY pentamer (positions 411-415) conserved in eukaryotes and archaebacteria is critical for eRF1's ability to stimulate eRF3 GTPase. The human eRF1 lacking 22 C-terminal amino acids remains active as a release factor and promotes an eRF3 GTPase activity whereas C-terminally truncated eRF3 is inactive as a GTPase.

Functional expression of eukaryotic polypeptide chain release factors 1 and 3 by means of baculovirus/insect cells and complex formation between the factors.

Translation termination in eukaryotes is governed by termination codons in mRNA and two release factors, eRF1 and eRF3. In this work, human eRF1 and eRF3 have been produced in insect cells using a recombinant baculovirus expression system for the corresponding human cDNAs. Purification of eRF1 has led to a homogeneous 50-kDa protein active in promoting ribosome-dependent and termination-codon-dependent hydrolysis of formylmethionyl-tRNAf(Met). Purification of eRF3 yielded a full-length protein and shorter polypeptides. Microsequencing of the N-terminus of the shortest form detected a site of proteolytic cleavage between Arg91 and Gly92, probably due to exposed region(s) hypersensitive to proteolysis. The mixture of full-length and truncated forms of eRF3 as well as bacterially expressed eRF3 lacking 138 N-terminal amino acids (eRF3Cp) are active as an eRF1-dependent and ribosome-dependent GTPase and in stimulating the GTP-dependent release activity of eRF1. Complex formation between eRF1 and eRF3Cp was demonstrated by affinity and gel-filtration chromatographies and by native-gel electrophoresis. An abnormal electrophoretic mobility observed for eRF1 as compared with the complex points to a significant conformational change of either eRF1 or both factors in the complex. Co-expression of both factors in baculovirus-infected insect cells and a yeast two-hybrid assay were applied to monitor complex formation in vivo. In yeast cells, both eRF1 and eRF3 are either in a monomeric or in a heterodimeric but not in a homodimeric state.

Diadenosine oligophosphates (Ap(n)A), a novel class of signalling molecules?

The diadenosine oligophosphates (Ap(n)A) were discovered in the mid-sixties in the course of studies on aminoacyl-tRNA synthetases (aaRS). Now, more than 30 years later, about 300 papers have been published around these substances in attempt to decipher their role in cells. Recently, Ap(n)A have emerged as intracellular and extracellular signalling molecules implicated in the maintenance and regulation of vital cellular functions and become considered as second messengers. Great variety of physiological and pathological effects in mammalian cells was found to be associated with alterations of Ap(n)A levels (n from 2 to 6) and Ap3A/Ap4A ratio. Cell differentiation and apoptosis have substantial and opposite effects on Ap3A/Ap4A ratio in cultured cells. A human Ap3A hydrolase, Fhit, appeared to be involved in protection of cells against tumourigenesis. Ap3A is synthesised by mammalian u synthetase (TrpRS) which in contrast to most other aaRS is unable to synthesise Ap4A and is an interferon-inducible protein. Moreover, Ap3A appeared to be a preferred substrate for 2-5A synthetase, also interferon-inducible, priming the synthesis of 2' adenylated derivatives of Ap3A, which in turn may serve as substrates of Fhit. Tumour suppressor activity of Fhit is assumed to be associated with involvement of the Fhit.Ap3A complex in cytokine signalling pathway(s) controlling cell proliferation. The Ap(n)A family is potentially a novel class of signal-transducing molecules whose functions are yet to be determined.

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.

The human gene encoding tryptophanyl-tRNA synthetase: interferon-response elements and exon-intron organization.

Recently, we cloned and sequenced the cDNA encoding human tryptophanyl-tRNA synthetase (hWRS) [Frolova et al., Gene 109 (1991) 291-296]. Independently, it has been shown that this protein is induced by interferons (IFN) gamma and alpha [Fleckner et al., Proc. Natl. Acad. Sci. USA 88 (1991) 11520-11524; Rubin et al., J. Biol. Chem. 266 (1991) 24245-24248]. This unusual feature of a housekeeping enzyme raises the problem of how the gene is regulated. Since at present the genomic structure of hWRS is unknown, this issue remains unsolved. Here, the exon-intron organization of hWRS has been deciphered. This gene consists of at least 12 exons that span more than 35 kb of DNA. At least two alternative noncoding exons precede ten coding exons. Upstream from the first exon, two GGAAAN(N/-)GAAA sequences, which are considered to be IFN-stimulating response elements (ISRE), have been revealed. The same consensus was also found in the intron region in close vicinity to the 5' end of the second exon. Thus, the IFN-stimulated synthesis of hWRS is presumably due to gene activation at the transcriptional level. Alignment of hWRS amino acid sequences has shown that exons V to XI of hWRS encode regions of structural similarity with bacterial WRS, whereas the N-terminal portion of the protein encoded by exons II to IV exhibits no homology with bacterial WRS.(ABSTRACT TRUNCATED AT 250 WORDS)

Reverse transcription of phage RNA and its fragment directed by synthetic heteropolymeric primers.

DNA synthesis catalysed by RNA-directed DNA-polymerase (reverse transcriptase) was found to proceed on the RNA template of an MS2 phage in the presence of heteropolymeric synthetic octa- and nonadeoxyribonucleotide primers complementary to the intercistronic region (coat protein binding site) and the region of the coat protein cistron, respectively. The product of synthesis consists of discrete DNA fractions of different length, including transcripts longer than 1,000 nucleotides. The coat protein inhibits DNA synthesis if it is initiated at its binding site, but has no effect on DNA synthesis initiated at the coat protein cistron. It has been suggested that, in this system, the initiation of DNA synthesis by synthetic primers is topographically specific. The MS2 coat protein binding site (an RNA fragment of 59 nucleotides) serves as a template for polydeoxyribonucleotide synthesis in the presence of octanucleotide primer and reverse transcriptase. The product of synthesis is homogenous and its length corresponds to the length of the template. The effective and complete copying of the fragment having a distinct secondary structure proves that the secondary structure does not interfere, in principle, with RNA being a template in the system of reverse transcription.

DNA-polymerase inhibitors. Rifamycin derivatives.

Ten new derivatives of the antibiotic rifamycin with variable side chains at position 3 were synthesized. The inhibitory activity of these derivatives against DNA-polymerases isolated from avian myeloblastosis virus, E. coli and calf thymus were studied at various conditions. 3-(2,4,6-trinitrophenylhydrazone-(methyl) rifamycin SV is a strong inhibitor for all the polymerases tested and belongs to the C class inhibitors of reverse transcriptase. 3-(monoallylhydrazone-(methyl) rifamycin SV possesses a selective action on polymerases: at 0.1 mg/ml concentration it almost completely inhibits the reverse transcriptase and less than half of the bacterial and eukaryotic enzymes. A drug is found which strongly inhibits the DNA-polymerases from E. coli and calf thymus and weakly the viral enzyme. The inhibitory effect on reverse transcriptase is independent of the choice of template-primer; it could be overcome by the addition of excess enzyme but not of excess template-primer; the inhibition could be completely reversed by dilution of the drug-enzyme mixture. From Lineweaver-Burk analysis, the inhibition is noncompetitive with respect to the template-primer and, thus the drugs bind to the site different from the active site for the template-primer. From protective action of the template-primer and other data it might be suggested that the rifamycin derivatives act at an early step(s) in DNA synthesis catalyzed by reverse transcriptase. The obtained data are in agreement with the results for other derivatives of rifamycin SV described in literature.

Dimensions of homo- and heteropolymeric sections of DNA synthesized by reverse transcription from globin mRNA matrices.

The lengths of globin messenger RNAs, isolated from rabbit and pigeon reticulocytes, and single-stranded complementary DNAs, synthesized from mRNA in presence of RNA-directed DNA-polymerase and oligo(dt) have been investigated by polyacrylamide gel electrophoresis under denaturing conditions. The cDNA preparations contained a fraction which corresponded in length to the alpha and beta chains of the mRNA used as a matrix. The lengthwise distribution of poly(A) sequences, isolated from globin mRNAs, corresponded to a statistical distribution, with a maximum at 75-80 nucleotides and with a maximum length of approximately 150 nucleotides. The lengthwise distribution of poly(dt) sequences, isolated from cDNA, corresponded to the poly(A) sequence distribution. It was concluded that: 1) cDNA is heterogeneous with respect to the length of poly(dt) sequences located at the 5' end of the molecule; 2) there was no selective use as primer of only that oligo(dt) which was located within the complex formed with the 5' end of the mRNA poly(A) sequence; 3) the heterogeneity of poly(DT) corresponded qualitatively to two models of template-primer interaction: selective use as a true primer of the oligonucleotide located in the complex formed with the 3' end of mRNA, and a statistical distribution of primer along the poly(A) sequence; and 4) the heterogeneity of the homopolymeric section of the cDNA may affect the kinetics of hybridization with mRNA, which possibly explains the previously observed [1] anomalous dependence of the hybridization rate on time.

Stepwise dissociation of high molecular weight avian myeloblastosis virus RNA: 30-40S RNA subunits--the best natural template-primer for viral reverse transcriptase.

Controlled disruption of 60S AMV RNA with formamide was used to prepare 50-55S and 30-40S RNAS. When the activities of these RNAs as templates for AMV reverse transcriptase were compared it was found that 50-55S RNA was 1-5 times and 30-40S RNA 2 to 3 times more active than 60S RNA. The 30-40S RNA produced by heating, instead of formamide disruption, was inactive as a template but activity was restored by addition of oligo(dT). 40% of the 4S RNA initially associated with the 60S RNA remained associated with all the RNA species obtained by formamide treatment but was lost on heating. It is concluded that this RNA acts as resident primer whereas the other 60% of the 4S RNA is less firmly bound and appears to have little or no primer activity. Removal of the less firmly bound 4S RNA increases the template activity of the viral RNA.

Hybridization of pigeon globin messenger RNA with complementary DNA synthesized in vitro by reverse transcription: influence of the homopolymeric regions.

The kinetics of hybridization of pigeon globin messenger RNA with complementary cDNA synthesized by means of AMV reverse transcriptase is complex. Addition of poly A or poly U in excess to the reaction mixture normalized the kinetics. It is concluded that association of the complementary homopolymeric regions of mRNA and cDNA accelerates the complex formation between heteropolymeric sequences in a fraction of the molecules.