A uniquely conserved regulatory signal is found around the translation initiation site in three different collagen genes

We have determined the nucleotide sequence of the 5' untranslated region and the sequence encoding the signal peptide for mRNAs of the chick alpha 1 type I and alpha 1 type III collagen. These sequences were obtained by synthesizing the corresponding cDNAs using as primers either a synthetic oligonucleotide to prime alpha 1 type I cDNA or a DNA fragment isolated from a genomic clone coding for alpha 1 type III collagen to prime the cognate cDNA. Both primers were selected so that the resulting cDNAs would be short and would contain sequence information for the 5' untranslated region and the signal peptide of the proteins. The nucleotide sequences of these cDNAs were compared with the corresponding sequence of alpha 2 type I collagen. In each mRNA the 5' untranslated segment is approximately 130 nucleotides and contains two or more AUG triplets preceding the AUG which serves as a translation initiation codon. A sequence of about 50 nucleotides surrounding the translation initiation codon is remarkably conserved in all three mRNAs, whereas the sequences preceding and following this segment diverge markedly. This homologous sequence contains an almost identical inverted repeat sequence which could form a stable stem-loop structure. The initiation codon and the AUG which precedes it are found at the same place within this symmetrical sequence and the distance between them is invariant. The rest of the conserved sequence shows a less perfect symmetry. This conserved sequence has not been found in other genes. Our data suggest that these three and perhaps other collagen genes contain an identical regulatory signal that may play a role in determining the level of expression of these genes by modulating translational efficiency.     

Probable involvement of 3'-terminal segment of 18S rRNA in translation initiation of uncapped mRNAs in plants

A possibility of involvement of 3'-terminal 18S rRNA segment in the cap-independent initiation of translation on plant ribosomes was studied. It was shown that 3-terminal segment (nucleotides 1777-1811) of 18S rRNA including the last hairpin 45 is accessible for complementary interactions in 40S ribosomal subunits. Oligonucleotides complementary to this segment of rRNA when added to wheat germ cell-free protein synthesizing system were found to specifically inhibit translation of uncapped reporter mRNA coding for beta-glucuronidase, which bears in the 5'-untranslated region (UTR) a leader sequence of potato virus Y (PVY) genomic RNA possessing fragments complementary to the region 1777-1811. It was shown that a sequence corresponding to nucleotides 291-316 of PVY, which is complementary to a major portion of the 3-terminal 18S rRNA segment 1777-1808, when placed into 5'-UTR, is able to enhance translational efficiency of the reporter mRNAs. The results obtained suggest that complementary interactions between mRNA 5'-UTR and 18S rRNA 3'-terminal segment can take place in the course of cap-independent translation initiation.     

HIV-2 genomic RNA contains a novel type of IRES located downstream of its initiation codon

Eukaryotic translation initiation begins with assembly of a 48S ribosomal complex at the 5' cap structure or at an internal ribosomal entry segment (IRES). In both cases, ribosomal positioning at the AUG codon requires a 5' untranslated region upstream from the initiation site. Here, we report that translation of the genomic RNA of human immunodeficiency virus type 2 takes place by attachment of the 48S ribosomal preinitiation complex to the coding region, with no need for an upstream 5' untranslated RNA sequence. This unusual mechanism is mediated by an RNA sequence that has features of an IRES with the unique ability to recruit ribosomes upstream from its core domain. A combination of translation assays and structural studies reveal that sequences located 50 nucleotides downstream of the AUG codon are crucial for IRES activity.     

Putative implication of 3′-terminal segment of 18S rRNA in translation initiation of uncapped mRNAs in plants

A putative implication 3′-terminal 18S rRNA segment in the cap-independent initiation of translation on plant ribosomes was studied. It was shown that 3′-terminal segment (nucleotides 1777–1811) of 18S rRNA including the last hairpin 45 was accessible for complementary interactions within 40S ribosomal subunits. Oligonucleotides complementary to this segment of rRNA, when added to wheat germ cell-free protein synthesizing system, specifically inhibited translation of uncapped reporter mRNA encoding β-glucuronidase. In the 5′-untranslated region (UTR), the reporter mRNA contained a leader sequence of potato virus Y (PVY) genomic RNA with fragments complementary to the region 1777–1811. A sequence corresponding to nucleotides 291–316 of PVY, which was complementary to most of the 3′-terminal 18S rRNA segment 1777–1808, was shown to enhance translational efficiency of the reporter mRNAs when placed into 5′-UTR. The obtained results suggest that complementary interactions between 5′-UTR of mRNA and 3′-terminal segment of 18S rRNA can take place during cap-independent translation initiation.     

A regulatory cis element and a specific binding factor involved in the mitogenic control of murine ribosomal protein L32 translation.

The mRNA encoding ribosomal protein L32 redistributes from untranslated subribosomal particles into polysomes after mitogenic activation of quiescent T-lymphocytes and fibroblasts. To identify the regions of the L32 mRNA which are important in regulating its cytoplasmic location we constructed a plasmid containing the murine L32 cDNA under the control of the Rous sarcoma virus (RSV) long terminal repeat promoter and introduced this construct into murine 3T3 fibroblasts. The mRNA transcribed from the RSV-L32 construct redistributed from subribosomal particles into polysomes in response to mitogenic activation in a manner similar to endogenous L32 mRNA. A conserved polypyrimidine region present at the 5' terminus of all ribosomal protein mRNAs is required for translational regulation of L32 mRNA since deletion of this sequence resulted in a mRNA that was not sequestered in subribosomal particles in quiescent cells. A radioactive RNA probe containing the first 34 nucleotides of the L32 5'-untranslated region, including the polypyrimidine region, specifically interacted with a protein of about 56 kDa. This protein did not bind detectably to RNA probes lacking the polypyrimidine sequence. Binding activity was similar in protein extracts made from resting and activated cells, suggesting that binding of the 56-kDa protein as measured in this assay is not regulated. This protein is a member of what may be an emerging family of polyribopyrimidine-binding proteins with diverse biochemical functions.     

Coordinate regulation of the levels of type III and type I collagen mRNA in most but not all mouse fibroblasts

A mouse genomic clone was isolated by cross-hybridization with a DNA fragment which codes for the NH2-propeptide of chick alpha1(III) collagen. The region of cross-hybridization within the mouse clone was localized, its sequence determined, and an exon coding for the NH2-propeptide of mouse alpha1(III) collagen was identified. This DNA fragment hybridizes to an RNA species of approximately 5300 nucleotides, slightly larger than the major alpha2(I) collagen RNA species. The mouse type III collagen probe was used to examine the effect of transformation on alpha1(III) collagen RNA levels in mouse fibroblasts. The levels of type III and type I collagen mRNA levels were compared in control and sarcoma virus-transformed murine cell lines, as well as in NIH 3T3 cells transformed by members of the human ras oncogenes. The levels of type III RNA decreased about 10-15-fold in Moloney sarcoma virus-transformed cells and in a cell line transformed with a v-mos-containing plasmid, but showed only a 50% decrease in a Kirsten murine sarcoma virus-transformed BALB 3T3 cell line, and increased 4-fold in a Rous sarcoma virus (RSV)-transformed BALB 3T3 cell line. In contrast, the levels of alpha2(I) collagen mRNA are 8- to 10-fold lower in all these cell lines when compared to untransformed cells. NIH 3T3 cells transformed with two human ras oncogenes showed decreased levels of alpha2(I) and alpha1(III) mRNAs. In contrast to the RSV-transformed mouse cell line, RSV-transformed chick embryo fibroblasts contained much smaller amounts of type III RNA than control chick embryo fibroblasts. We conclude that the levels of alpha1(III) and alpha2(I) collagen mRNA are often but not necessarily coordinately regulated by transformation in mouse cells.     

Eukaryotic start and stop translation sites.

Sequences flanking translational initiation and termination sites have been compiled and statistically analyzed for various eukaryotic taxonomic groups. A few key similarities between taxonomic groups support conserved mechanisms of initiation and termination. However, a high degree of sequence variation at these sites within and between various eukaryotic groups suggest that translation may be modulated for many mRNAs. Multipositional analysis of di-, tri-, and quadrinucleotide sequences flanking start/stop sites indicate significant biases. In particular, strong tri-nucleotide biases are observed at the -3, -2, and -1 positions upstream of the start codon. These biases and the interspecific variation in nucleotide preferences at these three positions have lead us to propose a revised model of the interaction of the 18S ribosomal RNA with the mRNA at the site of translation initiation. Unusually strong biases against the CG dinucleotide immediately downstream of termination codons suggest that they may lead to faulty termination and/or failure of the ribosome to disassociate from the mRNA.     

Similarities between Argonautes and the alpha-sarcin-like ribotoxins: Implications for microRNA action

We report structural, functional, and biochemical similarities between Argonautes, the effector proteins of RNA‐induced silencing complexes (RISCs), and alpha‐sarcin‐like ribotoxins. At the structural level, regions of similarity in the amino acid sequence are located in protein loops both in the ribotoxins and in the Argonautes. In ribotoxins, these protein loops confer specificity for a highly conserved segment of ribosomal RNA, the Sarcin‐Ricin‐Loop (SRL) that undergoes cleavage by the ribotoxin ribonuclease. This leads to suppression of translation. In addition to the structural similarity with ribotoxins, the Argonaute proteins (Ago) show both functional and biochemical parallels. Like the ribotoxins, the Agos exhibit ribonuclease activity and like the ribotoxins, translational suppression mediated by miRISC‐resident Ago is accompanied by intact polysomes. Furthermore, in both translationally suppressed systems, the puromycin reaction, reflecting correct translocation and peptidyl‐transferase activities, is unharmed. These findings support a mechanism for Ago‐miRISCs whereby regulated cleavage of ribosomal RNA leads to translational suppression.     

Modulation of ribosomal recruitment to 5'-terminal start codons by translation initiation factors IF2 and IF3

Sequence determinants and structural features of the RNA govern mRNA-ribosome interaction in bacteria. However, ribosomal recruitment to leaderless mRNAs, which start directly with the AUG start codon and do not bear a Shine-Dalgarno sequence like canonical mRNAs, does not appear to rely on 16S rRNA-mRNA interactions. Here, we have studied the effects of translation initiation factors IF2 and IF3 on 30S initiation at a 5'-terminal AUG and at a competing downstream canonical ribosome binding site. We show that IF2 affects the forward kinetics of 30S initiation complex formation at the 5'-terminal AUG as well as the stability of these complexes. Moreover, the IF2:IF3 molar ratio was found to play a decisive role in translation initiation of a leaderless mRNA both in vitro and in vivo indicating that the translational efficiency of an mRNA is not only intrinsically determined but can be altered depending on the availability of components of the translational machinery.     

Heterogeneous Nuclear Ribonucleoprotein L Interacts with the 3′ Border of the Internal Ribosomal Entry Site of Hepatitis C Virus

Translation initiation of hepatitis C virus (HCV) RNA occurs by internal entry of a ribosome into the 5′ nontranslated region in a cap-independent manner. The HCV RNA sequence from about nucleotide 40 up to the N terminus of the coding sequence of the core protein is required for efficient internal initiation of translation, though the precise border of the HCV internal ribosomal entry site (IRES) has yet to be determined. Several cellular proteins have been proposed to direct HCV IRES-dependent translation by binding to the HCV IRES. Here we report on a novel cellular protein that specifically interacts with the 3′ border of the HCV IRES in the core-coding sequence. This protein with an apparent molecular mass of 68 kDa turned out to be heterogeneous nuclear ribonucleoprotein L (hnRNP L). The binding of hnRNP L to the HCV IRES correlates with the translational efficiencies of corresponding mRNAs. This finding suggests that hnRNP L may play an important role in the translation of HCV mRNA through the IRES element.     

Functional importance of RNA interactions in selection of translation initiation codons

RNA base pairing between the initiation codon and anticodon loop of initiator tRNA is essential but not sufficient for the selection of the 'correct' mRNA translational start site by ribosomes. In prokaryotes, additional RNA interactions between small ribosomal subunit RNA and mRNA sequences just upstream of the start codon can efficiently direct the ribosome to the initiation site. Although there is presently no proof for a similar important ribosomal RNA interaction in eukaryotes, the 5' non-coding regions of their mRNAs and 'consensus sequences' surrounding initiation codons have been shown to be strong determinants for initiation-site selection, but the exact mechanisms are not yet understood. Intramolecular base pairing in mRNA and participation of translation initiation factors can strongly influence the formation of mRNA–small ribosomal subunit–initiator tRNA complexes and modulate translational activities in both prokaryotes and eukaryotes. Only recently has it been appreciated that alternative mechanisms may also contribute to the selection of initiation codons in all organisms. Although direct proof is currently lacking, there is accumulating evidence that additional cis -acting mRNA elements and trans -acting proteins may form specific 'bridging' interactions with ribosomes during translation initiation.     

Translational accuracy of a tethered ribosome

Ribosomes are evolutionary conserved ribonucleoprotein complexes that function as two separate subunits in all kingdoms. During translation initiation, the two subunits assemble to form the mature ribosome, which is responsible for translating the messenger RNA. When the ribosome reaches a stop codon, release factors promote translation termination and peptide release, and recycling factors then dissociate the two subunits, ready for use in a new round of translation. A tethered ribosome, called Ribo-T, in which the two subunits are covalently linked to form a single entity, was recently described in Escherichia coli. A hybrid ribosomal RNA (rRNA) consisting of both the small and large subunit rRNA sequences was engineered. The ribosome with inseparable subunits generated in this way was shown to be functional and to sustain cell growth. Here, we investigated the translational properties of Ribo-T. We analyzed its behavior during amino acid misincorporation, −1 or +1 frameshifting, stop codon readthrough, and internal translation initiation. Our data indicate that covalent attachment of the two subunits modifies the properties of the ribosome, altering its ability to initiate and terminate translation correctly.     

5' stem-loop of collagen alpha 1(I) mRNA inhibits translation in vitro but is required for triple helical collagen synthesis in vivo

The 5' stem-loop is a conserved sequence element found around the translation initiation site of three collagen mRNAs, alpha1(I), alpha2(I), and alpha1(III). We show here that the 5' stem-loop of collagen alpha1(I) mRNA is inhibitory to translation in vitro. The sequence 5' to the translation initiation codon, as a part of the 5' stem-loop, is also not efficient in initiating translation under competitive conditions. This suggests that collagen alpha1(I) mRNA may not be a good substrate for translation. Since the 5' stem-loop binds protein factors in collagen-producing cells, this binding may regulate its translation in vivo. We studied in vivo translation of collagen alpha1(I) mRNA after transfecting collagen alpha1(I) genes with and without the 5' stem-loop into Mov 13 fibroblasts. The mRNA with the alpha1(I) 5' stem-loop was translated into pepsin-resistant collagen, which was secreted into the cellular medium. This mRNA also produced more disulfide-bonded high molecular weight collagen found intracellularly. The mRNA in which the 5' stem-loop was mutated, but without affecting the coding region of the gene, was translated into pepsin-sensitive collagen and produced only trace amounts of disulfide-bonded collagen. This suggests that the 5' stem-loop is required for proper folding or stabilization of the collagen triple helix. To our knowledge this is the first example that an RNA element located in the 5'-untranslated region is involved in synthesis of a secreted multisubunit protein. We suggest that 5' stem-loop, with its cognate binding proteins, targets collagen mRNAs for coordinate translation and couples translation apparatus to the rest of the collagen biosynthetic pathway.     

Wheat eukaryotic initiation factor 4B organizes assembly of RNA and eIFiso4G, eIF4A, and poly(A)-binding protein

The eukaryotic translation initiation factor (eIF) 4B promotes the RNA-dependent ATP hydrolysis activity and ATP-dependent RNA helicase activity of eIF4A and eIF4F during translation initiation. Although this function is conserved among plants, animals, and yeast, eIF4B is one of the least conserved of initiation factors at the sequence level. To gain insight into its functional conservation, the organization of the functional domains of eIF4B from wheat has been investigated. Plant eIF4B contains three RNA binding domains, one more than reported for mammalian or yeast eIF4B, and each domain exhibits a preference for purine-rich RNA. In addition to a conserved RNA recognition motif and a C-terminal RNA binding domain, wheat eIF4B contains a novel N-terminal RNA binding domain that requires a short, lysine-rich containing sequence. Both the lysine-rich motif and an adjacent, C-proximal motif are conserved with an N-proximal sequence in human and yeast eIF4B. The C-proximal motif within the N-terminal RNA binding domain in wheat eIF4B is required for interaction with eIFiso4G, an interaction not reported for other eIF4B proteins. Moreover, each RNA binding domain requires dimerization for binding activity. Two binding sites for the poly(A)-binding protein were mapped to a region within each of two conserved 41-amino acid repeat domains on either side of the C-terminal RNA binding domain. eIF4A bound to an adjacent region within each repeat, supporting a central role for these conserved eIF4B domains in facilitating interaction with other components of the translational machinery. These results support the notion that eIF4B functions by organizing multiple components of the translation initiation machinery and RNA.     

Effect of T4 infection on initiation of protein synthesis and messenger specificity of initiation factor 3

No alteration in the messenger specificity of initiation factor 3 (IF-3) is observed upon T4 phage infection of several strains of Escherichia coli. IF-3 present in the 1.0 m NH₄Cl washes of ribosomes from T4-infected cells supports the translation of f2 RNA and T4 late mRNA with the same degree of efficiency as the IF-3 in the ribosomal washes obtained from uninfected cells. At high concentrations the ribosomal washes obtained from T4-infected cells are more inhibitory for both f2 RNA- and T4 late mRNA-directed protein synthesis than the ribosomal washes from uninfected cells. Furthermore, this increased inhibition is also observed in the poly(U)-directed synthesis of polyphenylalanine. These data suggest that translational controls exerted at the level of IF-3 probably do not account for the alterations in protein synthesis observed upon T4 infection.