Identification of features in 5' terminal fragments from reovirus mRNA which are important for ribosome binding

Four types of experiments were carried out with reovirus messenger RNAs or with 5′ terminal fragments of known sequence to identify features in mRNA which appear to be important for formation of initiation complexes with ribosomes. With a number of reovirus mRNAs, 40S initiation complexes had been previously shown to protect a significantly larger segment of the RNA (including the 5′ terminal m7G) than that protected by 80S initiation complexes. Each 80S-protected sequence had an AUG codon and was a subset of the 40S-protected sequence from the same message. When 40S- and 80S-protected fragments were tested for ability to rebind to ribosomes, the 80S-protected fragments showed considerably lower binding ability, implying that the “extra” sequences protected by 40S initiation complexes contribute to ribosome attachment. Nevertheless, wheat germ ribosomes select the same 5′ terminal initiation site in each reovirus mRNA, irrespective of the presence or absence of m7G on the message. This was demonstrated by comparing fingerprints of the ribosome-protected regions obtained with methylated versus unmethylated RNA. The contribution of m7G to formation of initiation complexes is therefore quantitative rather than qualitative. Limited T1 RNAase digestion of isolated 5′ terminal fragments from several reovirus messages generated a series of smaller fragments which were analyzed for ability to rebind to ribosomes. Partial digestion products up to 30 nucleotides in length which retained the 5′ cap but not the AUG codon were unable to associate stably with ribosomes, whereas every AUG-containing fragment that was analyzed was able to form initiation complexes. The efficiency of binding of certain AUG-containing fragments, however, was reduced by removal of either the 5′ terminal region, including the cap, or of sequences comprising the beginning of the coding region, on the 3′ side of the AUG. Complex formation between messenger RNA and ribosomes was inhibited by the trinucleotide AUG, but not by various other oligonucleotides. Although the inhibition was specific, a vast excess of trinucleotide was required for moderate inhibition of 80S complex formation, and the same concentration of AUG failed to inhibit formation of 40S initiation complexes.     

Structure of methemerythrin at 5 A resolution.

Rabbit globin messenger RNA was labelled in vitro with ¹²⁵I to specific activities in the range 20 to 200 × 10⁶ cts/min per μg. This ¹²⁵I-labelled mRNA bound to rabbit reticulocyte ribosomes with the kinetics and sensitivity to inhibitors expected from its participation in the normal process of the initiation of protein synthesis. Furthermore, when modified in 25% of its cytidine residues with unlabelled iodide, the mRNA coded for the same series of initiation peptides as did the unmodified mRNA. Using the techniques of RNA fingerprinting, the binding reaction was shown to select against contaminants and against “globin mRNA” molecules which lack a particular oligonucleotide implicated in the initiation process. When the ¹²⁵I-labelled mRNA was bound to ribosomes, both the initiating 40 S subunits and the 80 S ribosomes protected a fraction of the mRNA from digestion by pancreatic ribonuclease. Fingerprint analysis showed that highly specific regions of the mRNA were protected by the 40 S subunits and 80 S ribosomes and that these two protected regions were not identical.     

Purification of globin messenger RNA from dimethylsulfoxide-induced friend cells and detection of a putative globin messenger RNA precursor

Procedures are described that permit the detection and isolation of a specific messenger RNA as well as its precursor from total cell extracts. DNA complementary to the mRNA was elongated by the addition of dCMP residues and annealed with labeled cell RNA. The elongated DNA with RNA hybridized to it was isolated by chromatography on a poly(I)-Sephadex column. The method was used to isolate ³²P-labeled globin mRNA from labeled Friend cells, a mouse erythroleukaemic cell line, induced with dimethylsulfoxide to synthesize hemoglobin. ³²P-labeled globin mRNA isolated by this procedure was estimated to be 80% pure by hybridization analysis and sedimented as a single peak at 10 S. Partial sequences were determined for 16 oligonucleotides derived from the purified ³²P-labeled globin mRNA by RNAase T₁ digestion. The partial sequences for nine oligonucleotides corresponded to those predicted from the amino acid sequences of α and β globin; the other oligonucleotides were presumably derived from non-translated regions.In order to detect a possible precursor to globin mRNA, RNA from induced Friend cells pulse-labeled with [³²P]phosphate for 20 minutes was centrifuged through a sucrose gradient and the resulting fractions were analyzed for globinspecific sequences. Two peaks of globin-specific RNA were detected, a larger one at 10 S, the position of mature globin mRNA, and a smaller one at 15 S.     

The regulatory region of MS2 phage RNA replicase cistron. IV. Functional activity of specific MS2 RNA fragments in formation of the 70 S initiation complex of protein biosynthesis.

The initiation region of the MS2 replicase cistron can be isolated as a fragment 59 bases in length protected from RNAase by the binding of the coat protein which serves as a translational repressor. This fragment MS2 R(-53 leads to 6) starts 53 bases before the initiation codon and retains full activity in binding ribosomes. We have investigated the functional activity in initiation of a series of fragments from this region variously shortened from the 5'-end. Ribosome protected fragments starting 17 or 21 bases before the AUG are unable to rebind to ribosomes. The shortest fragment which has this activity was produced by partial S1 nuclease digestion and starts 33 to 35 bases before the AUG. The initiation signal comprises some nucleotides between 21 and 33 bases before the initiation codon and the regulatory region responsible for initiation is longer than that protected by the ribosome in the final initiation complex.     

Mechanism of inhibition of eukaryotic translational initiation by the trinucleotide ApUpG

ApUpG, the oligoribonucleotide homologous to the initiation codon, as well as the tetranucleotides ApUpGpA and ApUpGpG block initiation of protein synthesis in the rabbit reticulocyte lysate. These oligonucleotides are recognized as translational initiation sites by the ribosomes, leading to a very large accumulation of complete, but inactive, 80 S initiation complexes, containing methionylated initiator tRNA and ApUpG in a 1:1 stoichiometry. ApUpG appears to inhibit by competing with endogenous globin mRNA for 80 S ribosomal couples, since the inhibition of protein synthesis by ApUpG can be largely relieved by increasing the globin mRNA. The 80 S · Met-tRNA_i^Met · ApUpG complexes are not formed in the absence of hemin, demonstrating that their formation requires the active recycling of eukaryotic initiation factor 2. In addition the trinucleotide correctly directs the Met-tRNA_i^Met into the ribosomal donor site, since the methionyl residue is puromycin-reactive.     

Characterization of 10S RNA: a new stable rna molecule from Escherichia coli.

Summary When cells of Escherichia coli are labeled with ³²P_i for long periods of time and the cell content is subjected to electrophoresis in polyacrylamide gels, an RNA band appears which is about 10S in size. This band seems to contain three conformers. After treatment with formamide only a single band appears in this region of the gel, which contains 550 nucleotides as determined from its mobility. The complexity of the fingerprint of this material, after digestion with T₁-RNase, is in agreement with the size as determined by the mobility, this confirming that indeed it is a single molecule. Composition of the T₁-oligonucleotides was determined by digesting the T₁-generated oligonucleotides with pancreatic RNase and T₂-RNase. The quantitative and qualitative analysis of these digestions suggests that 10S RNA contains 609 nucleotides. The molecule contains, besides the four regular bases, one copy per molecule of the modified base pseudouridine.10S RNA cannot be processed by cell extracts to tRNA-sized molecules and does not bind significantly to ribosomes, hence it is unlikely to be a tRNA precursor or an mRNA.     

Antisense oligodeoxynucleotides provide insight into mechanism of translation initiation of two Sendai virus mRNAs

Translation of Sendai virus nucleocapsid protein (NP) and phosphoprotein (P/C) mRNAs in rabbit reticulocyte lysates in the presence of antisense oligodeoxynucleotides (15-20-mers) showed that oligonucleotides having complementarity within the 5' noncoding region of the mRNAs blocked translation, oligonucleotides having complementarity within 20 nucleotides upstream from the initiator codon blocked translation only partially, and oligonucleotides complementary to the coding region of mRNA had no effect on translation. The results suggest the possibility that the 80 S initiation complex may form about 20 bases upstream from the initiator codon. Alternatively, the 40 S preinitiation complex may recognize an initiator codon at least 20 nucleotides upstream from the codon, activating a helix-destabilizing process.     

Inhibition of protein synthesis by double-stranded RNA in reticulocyte lysates: evidence for activation of an endoribonuclease.

Double-stranded RNA is a potent inhibitor of protein synthesis in rabbit reticulocyte lysates. Three lines of evidence suggest that at least part of this inhibitory activity is due to activation of a nuclease which degrades mRNA: (1) In the presence of emetine reticulocyte polysomes are partially degraded to structures containing 1–3 ribosomes; (2) 34S Mengo-virus RNA is degraded to fragments sedimenting at less than 18S; (3) The template activity of globin mRNA extracted from the lysates is reduced by 90% when compared to appropriate controls. The ability of double-stranded RNA to activate a nuclease in the reticulocyte system is very similar to that observed in extracts from interferon treated cells and probably involves formation of the unusual oligonucleotide pppA^2′ p^5′ A^2′ p^5′ A.     

Vaccinia viral core inhibits Met-tRNAf·40S initiation complex formation with physiological mRNAs

Vaccinia viral core inhibits protein synthesis in reticulocyte lysates. In partial reactions using micrococcal nuclease treated reticulocyte lysates, the viral core inhibits Met-tRNA_f binding to 40S ribosomes in response to physiological mRNAs such as globin mRNA, cowpea mosaic viral RNA, and brome mosaic viral RNA but not in response to a trinucleotide codon, AUG. The core has also no effect on Met-tRNA_f binding to 40S ribosomes in a partial reaction using partially purified peptide chain initiation factors and AUG codon.The present observation of preferential inhibition by vaccinia viral core of Met-tRNA_f·40S initiation complex formation with physiological mRNAs and not with an artificial mRNA such as AUG codon, suggests that the viral core inhibits some step(s) in peptide chain initiation involved in the recognition of structural feature(s) unique to physiological mRNAs.     

Binding of wheat germ ribosomes to bisulfite-modified reovirus messenger RNA: Evidence for a scanning mechanism

A scanning mechanism has been proposed (Kozak, 1978) to explain how eukaryotic ribosomes select the correct AUG codon for initiation of protein synthesis. The hypothesis is that a 40 S ribosomal subunit binds initially at or near the 5′-terminus of a message and subsequently migrates toward the interior of the messenger RNA, stopping when it encounters the first AUG codon, at which point a 60 S subunit joins and peptide bond formation begins. The scanning mechanism predicts that if a message were modified by introduction of a new AUG triplet upstream of the existing initiator codon, the adventitious AUG should be the preferred site for formation of an 80 S initiation complex. This prediction has been confirmed in the present studies with two reovirus messenger RNAs, in which sodium bisulfite was used to convert an ACG sequence (located in the 5′ untranslated region of each message) to AUG. Analysis of the ribosome-protected mRNA fragments recovered from sparsomycin-blocked 80 S initiation complexes revealed that a high percentage of wheat germ ribosomes were centered around the “unnatural” 5′-proximal AUG created by the bisulfite treatment, although some ribosomes were also positioned at the second (normal) initiator codon. The bisulfite modification was carried out in 7 m-urea at 37 °C. resulting in quantitative conversion of cytosine to uracil. Thus, both the primary and secondary structure of the message were drastically altered. These perturbations did not impair the efficiency of ribosome binding, nor did the highly unfolded state of the mRNA permit ribosomes to attach to spurious sites in the interior of the message. The data support a mechanism in which the initiator codon is selected by virtue of its position in a message (i.e. closest to the 5′-terminus), without regard to either the primary or secondary structure of the flanking regions.     

Initiation of Reovirus mRNA Synthesis <Emphasis Type="Italic">in vitro</Emphasis>

The ten mRNA species synthesized in vitro by reovirus-associated RNA polymerase contain the diphosphate, ppG, at the 5′-termini. The enzyme re-initiates continuously and digestion of the products with pancreatic RNAase releases predominantly ppGpUp from the 5′-ends.     

Two adenovirus mRNAs have a common 5′ terminal leader sequence encoded at least 10 kb upstream from their main coding regions

The messenger RNAs encoding two late adenovirus serotype 2 (Ad2) proteins, fiber and 100K, were purified by hybridization to restriction endonuclease fragments of Ad2 DNA followed by electrophoresis on polyacrylamide gels containing 98% formamide. The 5′ terminal oligonucleotides generated by RNAase T1 digestion of the messengers were selected by dihydroxyboryl-cellulose chromatography. Both mRNAs gave an identical 5′-undecanucleotide with the general structure 7mG^5′ppp^5′A^mC^(m)U(C₄,U₃)G. This undecanucleotide could be removed by mild RNAase treatment from the mRNA after hybridization to DNA fragments containing the main coding sequence of the messenger. In contrast, a small region defined by Bal I-E (14.7–21) protects this undecanucleotide from RNase. A second region contained within both Hind III-B (17–31.5) and Hpa I-F (25.5–27.9), although unable to protect the undecanucleotide, hybridizes to both fiber and 100K mRNAs and protects a similar sequence of 100–150 nucleotides. These observations suggest that both mRNAs contain a long common sequence, complementary to at least two different sites on the Ad2 genome remote from the start of these two genes. The implications of these findings are discussed, and a general mechanism is presented for the biosynthesis of mRNAs from larger precursor molecules, based on intramolecular ligation.     

Protein synthesis in yeast Saccharomyces cerevisiae. Purification of Co-eIF-2A and 'mRNA-binding factor(s)' and studies of their roles in Met-tRNAf.40S.mRNA complex formation

Antibodies prepared against a homogeneous preparation of Co-eIF-2A20 [Ahmad et al. (1985) J. Biol. Chem. 260, 6955-6959] reacted with several polypeptides including an 80-kDa polypeptide present in a crude yeast ribosomal salt wash. This 80-kDa polypeptide, containing Co-eIF-2A (Co-eIF-2A80) activity, has been extensively purified using a two-step purification procedure involving an immunoaffinity column chromatograph prepared using antibodies against Co-eIF-2A20 (fraction II) and hydroxyapatite chromatography (fraction III). The factors, eIF-2 + homogeneous Co-eIF-2A80 (fraction III) promoted Met-tRNAf.40S complex formation with an AUG codon but not with a physiological mRNA or a polyribonucleotide messenger poly(U,G) whereas eIF-2 + a partially purified Co-eIF-2A80 preparation (fraction II) promoted Met-tRNAf.40S complex formation with an AUG codon as well as with globin mRNA and poly(U,G) messenger. This factor-promoted Met-tRNAf binding to 40S ribosomes depends absolutely on the presence of a polyribonucleotide messenger containing an initiation codon (such as AUG or GUG). Other polyribonucleotide messengers tested, such as poly(U), poly(A) and poly(A,C) were completely ineffective in this binding reaction. This result indicates that the Met-tRNAf.40S.mRNA complex is formed by a direct interaction between Met-tRNAf, 40S ribosomes and the initiation site in mRNA. A mechanism has been proposed for Met-tRNAf.40S.mRNA complex formation in yeast.     

Synthesis of rabbit globin in a cell-free protein synthesis system utilizing sea urchin egg and zygote ribosomes

Reports of the reduced ability of sea urchin egg ribosomes to participate in synthetic mRNA-directed protein synthesis have fostered the suggestion that the low protein synthesis rate of eggs is due to ribosome-associated inhibitors. To test this hypothesis with a natural message, we have isolated 80S ribosomes and microsomal ribosomes of sea urchin eggs and zygotes and compared their activity at synthesizing protein from rabbit α and β globin mRNA in a Krebs II ascites tumor cell-free system. Both egg and zygote 80S ribosomes responded to added mRNA and were shown to synthesize complete α and β globin chains by CM-cellulose chromatography. In most cases, the activity of the egg ribosomes was in comparable instances higher than the zygote ribosomes. Attempts to determine the cause of this difference indicated that it was not a function of K⁺ or Mg²⁺ concentration, type of tRNA used, or ribosomal wash proteins. From these studies it is apparent that sea urchin egg ribosomes are functional at a level equivalent to or better than zygote ribosomes, and it appears that the lack of protein synthetic activity in unfertilized eggs is not due to the presence of a population of inhibited ribosomes.     

Isolation of specific ribosome binding sites from single-stranded DNA.

The ability of Escherichia coli ribosomes to protect small specific regions of single-stranded bacteriophage DNA from digestion by pancreatic DNAase has been investigated. A procedure is described by which ribosome-protected fragments can be isolated from the DNA of bacteriophage f1 and φX174. Size determination by polyacrylamide gel electrophoresis or thin layer homochromatography together with fingerprinting analysis following chemical depurination or digestion with E. coli endonuclease IV were employed to show that these fragments represent a small specific portion of these DNAs. The protection reaction is largely dependent upon components necessary for ribosome binding to mRNA, including GTP, formylmethionyl-tRNA, and initiation factors. Thus, ribosomal binding to DNA mimics the ribosome-mRNA interaction. Furthermore, the regions in f1 and φX174 DNA which are protected differ in sequence from each other.When E. coli endonuclease IV is substituted for pancreatic DNAase in the ribosome protection reaction, a fragment of φX174 DNA is obtained about 150 bases in length which contains all of the pyrimidine tracts in the shorter 50-base fragment obtained with pancreatic DNAase, and a number of additional polypyrimidines.Double-stranded DNAs such as φX174 replicative form do not bind at all to ribosomes in their native state. Heat denaturation of such double-stranded DNAs allows ribosome binding. Protection of the same specific regions as those protected in single-stranded φX174 DNA was observed. A similar specific protection was observed following heat denaturation and ribosome binding with DNA from polyoma virus.     

Translation of maternal messenger ribonucleoprotein particles from sea urchin in a cell-free system from unfertilized eggs and product analysis

Maternal mRNP particles were isolated from the postribosomal supernatant fluid of unfertilized sea urchin eggs. They were translated in a cell-free system derived from unfertilized eggs. The translation of these particles required the presence of 12 mM MgCl₂, which is considered very high. The same high Mg²⁺ requirement was observed when mRNP particles were translated in a cell-free system from morula embryos. In contrast, mRNA extracted from mRNP particles is translated at 3 mM MgCl₂. This concentration of Mg²⁺ is known to be optimal for initiation of mRNA translation. Likewise, a rabbit globin mRNA is faithfully translated into α and β globin chains in a cell-free system from eggs at 3, but not at 12, mM MgCl₂. The translational products directed by mRNP or by mRNA derived from mRNP were examined in two gel systems and were found to be very similar. In both cases, histones were identified as part of the translational product. This indicated that the translation of mRNP in high Mg²⁺ is not due to nonspecific binding of these particles to ribosomes. The rates of globin synthesis in a cell-free system derived from eggs is comparable to that of morula ribosomes and to that reported for translation of globin with mouse liver and reticulocyte ribosomes, indicating that unfertilized sea urchin egg ribosomes do not possess a translational inhibitor and that no deficiency in initiation factors for mRNA translation could explain the low rate of protein synthesis in unfertilized sea urchin eggs.     

Genomic RNA of mengovirus V. Recognition of common features by ribosomes and eucaryotic initiation factor 2.

Binding of ribosomes to the 32P-labeled genomic RNA of mengovirus was studied in lysates of mouse L929 and Krebs ascites cells under conditions for initiation of translation. Upon total digestion with RNase T1, the 32P-labeled RNA protected in either 40S or 80S initiation complexes yielded four unique, large oligonucleotides. Each of these oligonucleotides occurred once in the viral RNA molecule. The same four oligonucleotides were recovered from 80S initiation complexes formed in lysates in which unlabeled mengovirus RNA had been translated extensively, indicating that recognition by ribosomes was not modulated detectably by a viral translation product. The recognition of intact, 32P-labeled mengovirus RNA by eucaryotic initiation factor 2 (eIF-2) was examined by direct complex formation. Fingerprint analysis of the RNA protected by eIF-2 against RNase T1 digestion yielded three T1 oligonucleotides that were identical to three of the four oligonucleotides protected in either 40S or 80S initiation complexes. A physical map of the large T1 oligonucleotides of the mengovirus RNA molecule was constructed, and the four protected oligonucleotides were found to map internally, within the region between the polycytidylate tract and the 3' end. For either ribosomes or eIF-2, the protected oligonucleotides could not be arranged in a continuous sequence, suggesting that they constitute at least two widely separated domains. These results show that ribosomes recognize and blind to more than a single sequence in mengovirus RNA, located internally in regions that are far removed from the 5' end of the molecule. eIF-2 itself binds with high specificity to mengovirus RNA, recognizing apparently three of the four sequences recognized by ribosomes.