The last RNA-binding repeat of the Escherichia coli ribosomal protein S1 is specifically involved in autogenous control

The ssyF29 mutation, originally selected as an extragenic suppressor of a protein export defect, has been mapped within the rpsA gene encoding ribosomal protein S1. Here, we examine the nature of this mutation and its effect on translation. Sequencing of the rpsA gene from the ssyF mutant has revealed that, due to an IS10R insertion, its product lacks the last 92 residues of the wild-type S1 protein corresponding to one of the four homologous repeats of the RNA-binding domain. To investigate how this truncation affects translation, we have created two series of Escherichia coli strains (rpsA(+) and ssyF) bearing various translation initiation regions (TIRs) fused to the chromosomal lacZ gene. Using a beta-galactosidase assay, we show that none of these TIRs differ in activity between ssyF and rpsA(+) cells, except for the rpsA TIR: the latter is stimulated threefold in ssyF cells, provided it retains at least ca. 90 nucleotides upstream of the start codon. Similarly, the activity of this TIR can be severely repressed in trans by excess S1, again provided it retains the same minimal upstream sequence. Thus, the ssyF stimulation requires the presence of the rpsA translational autogenous operator. As an interpretation, we propose that the ssyF mutation relieves the residual repression caused by normal supply of S1 (i.e., that it impairs autogenous control). Thus, the C-terminal repeat of the S1 RNA-binding domain appears to be required for autoregulation, but not for overall mRNA recognition.     

Non-canonical mechanism for translational control in bacteria: synthesis of ribosomal protein S1

Translation initiation region (TIR) of the rpsA mRNA encoding ribosomal protein S1 is one of the most efficient in Escherichia coli despite the absence of a canonical Shine-Dalgarno-element. Its high efficiency is under strong negative autogenous control, a puzzling phenomenon as S1 has no strict sequence specificity. To define sequence and structural elements responsible for translational efficiency and autoregulation of the rpsA mRNA, a series of rpsA'-'lacZ chromosomal fusions bearing various mutations in the rpsA TIR was created and tested for beta-galactosidase activity in the absence and presence of excess S1. These in vivo results, as well as data obtained by in vitro techniques and phylogenetic comparison, allow us to propose a model for the structural and functional organization of the rpsA TIR specific for proteobacteria related to E.coli. According to the model, the high efficiency of translation initiation is provided by a specific fold of the rpsA leader forming a non-contiguous ribosome entry site, which is destroyed upon binding of free S1 when it acts as an autogenous repressor.     

Inability of Agrobacterium tumefaciens ribosomes to translate in vivo mRNAs containing non-Shine-Dalgarno translational initiators

Numerous data accumulated during the last decade have shown that the Shine-Dalgarno (SD) sequence is not a unique initiator of translation for Escherichia coli. Several other sequences, mostly of viral origin, have demonstrated their capability of either enhancing or initiating translation in vivo. A phage T7 gene 10 sequence, called "epsilon" (epsilon), has shown its high enhancing activity on translation in both Escherichia coli and Agrobacterium tumefaciens cells. In this study the epsilon, together with three other nucleotide sequences derived from the 5' non-translated regions of tobacco mosaic virus (TMV), papaya mosaic virus (PMV) and clover yellow mosaic virus (CYMV) RNAs are tested for translation initiation activity in A. tumefaciens cells. The obtained results indicate that none of them was capable of initiating translation in vivo of chloramphenicol acetyltransferase (CAT) mRNA. To determine whether their inactivity was related with structural differences in the ribosomal protein S1, the rpsA gene (coding for S1 protein in E. coli) was co-expressed in A. tumefaciens together with the cat gene placed under the translational control of the above sequences. Our results showed that the rpsA gene product did not make any of the four viral enhancers active in A. tumefaciens cells. The inability of A. tumefaciens ribosomes to translate mRNAs devoid of SD sequences indicates for a substantial difference in the ribosome structure of the two Gram negative bacteria E. coli and A. tumefaciens.     

The adenovirus type 5 i-leader open reading frame functions in cis to reduce the half-life of L1 mRNAs.

The 440-nucleotide adenovirus type 5 i-leader sequence, encoding a 13.6-kilodalton protein, is located between the second and third components of the tripartite leader sequence. It appears primarily on the L1 family of mRNAs. To study its function, we constructed two point mutations within the i leader. pm382 lacks the wild-type i-leader splice acceptor and failed to splice the leader onto L1 mRNAs. pm383 lacks the ATG used for translation of the i-leader protein; it synthesized i-leader-containing mRNAs, but failed to produce detectable levels of the polypeptide. Both mutants exhibited modestly reduced yields in some but not all cell lines tested and accumulated slightly elevated levels of L1 mRNA and L1 52- and 55-kilodalton proteins in infected cells. Mutant phenotypes were consistently more pronounced in pm382- than in pm383-infected cells. In wild-type virus-infected cells, L1 mRNAs lacking the i leader displayed a half-life of about 26 h, whereas L1 mRNAs containing the leader were much less stable, with a half-life of less than 4 h. In pm383-infected cells (ATG mutant), L1 mRNAs containing the i leader exhibited a half-life of 26 h. The abnormally long half-life of pm383-encoded L1 mRNAs containing a mutant i leader was not reduced by coinfection with wild-type virus, suggesting that synthesis of the i-leader protein leads to destabilization of the i-leader-containing L1 mRNA undergoing translation.     

The functional role of the eukaryote-specific motif YxxPKxYxK of the human ribosomal protein eS26 in translation

The protein eS26 is a structural component of the eukaryotic small ribosomal subunit involved in the formation of the mRNA binding channel in the region of the exit site. By applying site-directed cross-linking to mammalian 80S ribosomes, it has been shown that the same mRNA nucleotide residues are implicated in the interaction with both eS26 and translation initiation factor 3 (eIF3) and that contacts of the protein with mRNAs are mediated by its eukaryote-specific motif YxxPKxYxK. To examine the role of eS26 in translation, we transfected HEK293T cells with plasmid constructs encoding the wild-type FLAG-labeled protein (wt-eS26^FLAG) or its forms with either a single substitution of any conserved amino acid residue in the above motif, or a simultaneous replacement of all the five ones (5A). The western blot analysis of fractions of polysome profiles from the transfected cells revealed no effects of the single mutations in eS26, but showed that the replacement of the five conserved residues led to the increased share of the light polysome fraction compared to that detected with control, wt-eS26^FLAG-producing cells. In addition, the above fraction exhibited the enhanced content of the eIF3e subunit that is known to promote selective translation. These findings, together with real-time PCR data on the relative contents of specific mRNAs in light and heavy polysomes from cells producing the mutant 5A compared to those from control cells, suggest a possible involvement of the YxxPKxYxK motif of eS26 in the fine regulation of translation to maintain the required balance of synthesized proteins.     

Drosha mediates destabilization of Lin28 mRNA targets

Lin28 plays important roles in development, stem cell maintenance, oncogenesis and metabolism. As an RNA-binding protein, it blocks the biogenesis primarily of let-7 family miRNAs and also promotes translation of a cohort of mRNAs involved in cell growth, metabolism and pluripotency, likely through recognition of distinct sequence and structural motifs within mRNAs. Here, we show that one such motif, shared by multiple Lin28-responsive elements (LREs) present in Lin28 mRNA targets also participates in a Drosha-dependent regulation and may contribute to destabilization of its cognate mRNAs. We further show that the same mutations in the LREs known to abolish Lin28 binding and stimulation of translation also abrogate Drosha-dependent mRNA destabilization, and that this effect is independent of miRNAs, uncovering a previously unsuspected coupling between Drosha-dependent destabilization and Lin28-mediated regulation. Thus, Lin28-dependent stimulation of translation of target mRNAs may, in part, serve to compensate for their intrinsic instability, thereby ensuring optimal levels of expression of genes critical for cell viability, metabolism and pluripotency.     

Drosha mediates destabilization of Lin28 mRNA targets

Lin28 plays important roles in development, stem cell maintenance, oncogenesis and metabolism. As an RNA-binding protein, it blocks the biogenesis primarily of let-7 family miRNAs and also promotes translation of a cohort of mRNAs involved in cell growth, metabolism and pluripotency, likely through recognition of distinct sequence and structural motifs within mRNAs. Here, we show that one such motif, shared by multiple Lin28-responsive elements (LREs) present in Lin28 mRNA targets also participates in a Drosha-dependent regulation and may contribute to destabilization of its cognate mRNAs. We further show that the same mutations in the LREs known to abolish Lin28 binding and stimulation of translation also abrogate Drosha-dependent mRNA destabilization, and that this effect is independent of miRNAs, uncovering a previously unsuspected coupling between Drosha-dependent destabilization and Lin28-mediated regulation. Thus, Lin28-dependent stimulation of translation of target mRNAs may, in part, serve to compensate for their intrinsic instability, thereby ensuring optimal levels of expression of genes critical for cell viability, metabolism and pluripotency.     

Analysis of herpes simplex virus-induced mRNA destabilizing activity using an in vitro mRNA decay system.

Most host mRNAs are degraded soon after infection of cells with herpes simplex virus type 1 (HSV-1). This early shutoff or early destabilization response is induced by a virion component, the virion host shutoff (vhs) protein. HSV-1 mutants, vhs1 and vhs-delta Sma, which produce defective or inactive vhs protein, fail to induce early shutoff. We have used an in vitro mRNA decay system to analyze the destabilization process. Polysomes from uninfected human erythroleukemia cells, used as a source of target mRNAs, were mixed with polysomes or with post-polysomal supernatant (S130) from HSV-1- or mock-infected murine erythroleukemia cells. Normally stable gamma-globin mRNA was destabilized by approximately 15-fold with S130 from wild-type virus-infected cells but was not destabilized with S130 from mock-infected cells or from cells infected with either of the two HSV mutants. The virus-induced destabilizing activity had no significant effect on the in vitro half-lives of two normally unstable mRNAs, histone and c-myc. No destabilizing activity was detected in polysomes from infected cells. We conclude that a virus-induced destabilizer activity can function in vitro, is located in the S130 of infected cells, and accelerates the decay rates of some, but not all, polysome-associated host mRNAs.     

Autoregulation of tubulin expression is achieved through specific degradation of polysomal tubulin mRNAs

We have utilized protein synthesis inhibitors to investigate the autoregulatory mechanism that uses the concentration of unpolymerized tubulin subunits to specify tubulin mRNA content in animal cells. Puromycin and pactamycin, both of which remove RNAs from polysomes, completely unlink tubulin RNA content from the level of free subunits, whereas pretreatment of cells with cycloheximide, which traps mRNAs onto stalled polyribosomes, enhances the specific degradation of tubulin RNAs in response to increases in the subunit content. Moreover, in the absence of protein synthesis inhibitors, the tubulin RNAs that are lost from cells with elevated free tubulin subunit levels are those that are associated with polyribosomes. Further, beta-tubulin mRNAs encoding a truncated translation product of only 26 amino acids (and that cannot be polyribosomal) are not substrates for autoregulation. We conclude that autoregulation of tubulin synthesis is achieved by specifically altering the stability of tubulin RNAs that are bound to polyribosomes.     

Suppressors of the secY24 mutation: identification and characterization of additional ssy genes in Escherichia coli

We previously reported (Shiba et al., J. Bacteriol. 160:696-701, 1984) the isolation and characterization of the mutation (ssy) that suppresses the protein export defect due to the secY24(Ts) mutation and causes cold-sensitive growth of Escherichia coli. This report describes more systematic isolation of ssy mutations. Among temperature-resistant revertants of the secY24 mutant, 65 mutants were found to be cold sensitive. These cold-sensitive mutations have been classified by genetic mapping. Twenty-two mutations fell into the ssyA class previously described. The remaining mutations were located at five new loci: ssyB at 9.5 min between tsx and lon; ssyD around 3 min; ssyE at 72.5 min near secY; ssyF at 20.5 min within rpsA; and ssyG at 69.0 min near argG. Two predominant classes, ssyA and ssyB, are probably affected in protein synthesis at the elongation step, whereas the ssyF mutant contained an altered form of ribosomal protein S1 (the gene product of rpsA). These cold-sensitive ssy mutations which suppress secY24 may define genes whose function is somehow involved in the secY-dependent protein secretion mechanism. However, the existence of multiple suppressor loci makes it unlikely that all of these genes specify additional components of the export machinery. A delicate balance may exist between the systems for synthesizing and exporting proteins.     

Binding of the La autoantigen to the 5' untranslated region of a chimeric human translation elongation factor 1A reporter mRNA inhibits translation in vitro.

Human translation elongation factor 1A (EF1A) is a member of a large class of mRNAs, including ribosomal proteins and other translation elongation factors, which are coordinately translationally regulated under various conditions. Each of these mRNAs contains a terminal oligopyrimidine tract (TOP) that is required for translational control. A human growth hormone (hGH) expression construct containing the promoter region and 5' untranslated region (UTR) of EF1A linked to the hGH coding region (EF1A/hGH) was translationally repressed following rapamycin treatment in similar fashion to endogenous EF1A in human B lymphocytes. Mutation of two nucleotides in the TOP motif abolished the translational regulation. Gel mobility shift assays showed that both La protein from human B lymphocyte cytoplasmic extracts as well as purified recombinant La protein specifically bind to an in vitro-synthesized RNA containing the 5' UTR of EF1A mRNA. Moreover, extracts prepared from rapamycin-treated cells showed increased binding activity to the EF1A 5' UTR RNA, which correlates with TOP mRNA translational repression. In an in vitro translation system, recombinant La dramatically decreased the expression of EF1A/hGH construct mRNA, but not mRNAs lacking an intact TOP element. These results indicate that TOP mRNA translation may be modulated through La binding to the TOP element.     

Selective destabilization of short-lived mRNAs with the granulocyte-macrophage colony-stimulating factor AU-rich 3'' noncoding region is mediated by a cotranslational mechanism.

The 3' noncoding region element (AUUUA)n specifically targets many short-lived mRNAs for degradation. Although the mechanism by which this sequence functions is not yet understood, a potential link between facilitated mRNA turnover and translation has been implied by the stabilization of cellular mRNAs in the presence of protein synthesis inhibitors. We therefore directly investigated the role of translation on mRNA stability. We demonstrate that mRNAs which are poorly translated through the introduction of stable secondary structure in the 5' noncoding region are not efficiently targeted for selective destabilization by the (AUUUA)n element. These results suggest that AUUUA-mediated degradation involves either a 5'-->3' exonuclease or is coupled to ongoing translation of the mRNA. To distinguish between these two possibilities, we inserted the poliovirus internal ribosome entry site, which promotes internal ribosome initiation, downstream of the 5' secondary structure. Translation directed by internal ribosome binding was found to fully restore targeted destabilization of AUUUA-containing mRNAs despite the presence of 5' secondary structure. This study therefore demonstrates that selective degradation mediated by the (AUUUA)n element is coupled to ribosome binding or ongoing translation of the mRNA and does not involve 5'-to-3' exonuclease activity.     

A retrovirus-like zinc domain is essential for translational repression of bacteriophage T4 gene 32

Gene 32 protein (gp32), a single-stranded DNA-binding protein from bacteriophage T4, contains a zinc-binding subdomain with sequence homologies to the 3-cysteine/1-histidine zinc-binding motif found in a variety of retroviruses and plant viruses. In vitro studies suggest that autoregulation of gp32 occurs at the level of translation by gp32 specifically binding gene 32 mRNA at an unusual stem-loop structure that can be modeled as an RNA pseudoknot. Nucleation of gp32 binding via this pseudoknot is thought to be needed to facilitate cooperative binding of gp32 through a largely unstructured region that overlaps the ribosome binding site (McPheeters, D. S., Stormo, G. D., and Gold, L. (1988) J. Mol. Biol. 201, 517-535). Removal of Zn(II) from gp32 results in a protein that retains the ability to bind single-stranded RNA with high affinity but is unable to specifically autoregulate itself at the level of translation. Deletion of the pseudoknot sequences from the gene 32 autoregulatory region results in an mRNA that cannot be repressed by gp32. These results suggest that the zinc-binding subdomain of gp32 plays an essential role in autoregulation by providing a critical element necessary for nucleating cooperative binding at the gene 32 mRNA pseudoknot.     

Fragile X mental retardation protein (FMRP) binds specifically to the brain cytoplasmic RNAs BC1/BC200 via a novel RNA-binding motif

Fragile X mental retardation protein (FMRP), the protein responsible for the fragile X syndrome, is an RNA-binding protein involved in localization and translation of neuronal mRNAs. One of the RNAs known to interact with FMRP is the dendritic non-translatable brain cytoplasmic RNA 1 BC1 RNA that works as an adaptor molecule linking FMRP and some of its regulated mRNAs. Here, we showed that the N terminus of FMRP binds strongly and specifically to BC1 and to its potential human analog BC200. This region does not contain a motif known to specifically recognize RNA and thus constitutes a new RNA-binding motif. We further demonstrated that FMRP recognition involves the 5' stem loop of BC1 and that this is the region that exhibits complementarity to FMRP target mRNAs, raising the possibility that FMRP plays a direct role in BC1/mRNA annealing.     

hnRNP C increases amyloid precursor protein (APP) production by stabilizing APP mRNA.

We have previously shown that heterogeneous nuclear ribonucleoprotein C (hnRNP C) and nucleolin bound specifically to a 29 nt sequence in the 3'-untranslated region of amyloid precursor protein (APP) mRNA. Upon activation of peripheral blood mononuclear cells, hnRNP C and nucleolin acquired APP mRNA binding activity, concurrent with APP mRNA stabilization. These data suggested that the regulated interaction of hnRNP C and nucleolin with APP mRNA controlled its stability. Here we have directly examined the role of the cis element and trans factors in the turnover and translation of APP mRNA in vitro . In a rabbit reticulocyte lysate (RRL) translation system, a mutant APP mRNA lacking the 29 nt element was 3-4-fold more stable and synthesized 2-4-fold more APP as wild-type APP mRNA. Therefore, the 29 nt element functioned as an APP mRNA destabilizer. RNA gel mobility shift assays with the RRL suggested the presence of endogenous nucleolin, but failed to show hnRNP C binding activity. However, wild-type APP mRNA was stabilized and coded for 6-fold more APP when translated in an RRL system supplemented with exogenous active hnRNP C. Control mRNAs lacking the 29 nt element were unaffected by hnRNP C supplementation. Therefore, occupancy of the 29 nt element by hnRNP C stabilized APP mRNA and enhanced its translation.     

A novel screening system for self-mRNA targeting proteins

Here we describe the application of an in vitro translation system for genetic screening, to identify RNA-binding proteins that bind to their own mRNAs. It is a relatively novel system designed using an advanced cell-free translation system reconstructed with purified translational components. Due to the absence of nucleases and proteases, the complex of mRNA and nascent polypeptide synthesized in this system is expected to exhibit high stability ensuring the following efficient selection toward the protein. Escherichia coli ribosomal protein S15, which is known to bind to its own mRNA, was employed as a model molecule to evaluate the system. Wild-type S15 mRNA specifically isolated from a mutant mRNA lacking the secondary structure responsible for binding the S15 protein accumulated markedly after several rounds of selection-amplification. The success of this selection demonstrates the potentiality of the systematic screening of self-mRNA targeting proteins through direct and functional selection. This strategy as a method to identify peptides or proteins that bind to their own mRNAs, is of general interest and has different potential applications, such as, the identification of new regulatory proteins or peptide motifs for RNA recognition, the study of self-mRNA-protein interactions, etc.     

Cloning, restriction endonuclease mapping and post-transcriptional regulation of rpsA, the structural gene for ribosomal protein S1

Transducing lambda phages have been isolated that carry segments of the Escherichia coli chromosome in the aspC region, 20.5 min on the E. coli map. One of these phages, lambda aspC2, carries rpsA, the structural gene for the ribosomal protein S1. A three kilobase fragment from this phage, cloned into either the plasmid pACYC184 or the plasmid pBR322, was found to express S1. In cells carrying the rpsA gene on the high copy number plasmid pBR322 the rate of rpsA mRNA synthesis was increased 40-fold, whereas the rate of protein S1 synthesis was doubled, in comparison with these rates in an rpsA haploid.     

Polysome distribution of phospholipid hydroperoxide glutathione peroxidase mRNA: evidence for a block in elongation at the UGA/selenocysteine codon

The translation of mammalian selenoprotein mRNAs requires the 3' untranslated region that contains a selenocysteine insertion sequence (SECIS) element necessary for decoding an in-frame UGA codon as selenocysteine (Sec). Selenoprotein biosynthesis is inefficient, which may be due to competition between Sec insertion and termination at the UGA/Sec codon. We analyzed the polysome distribution of phospholipid hydroperoxide glutathione peroxidase (PHGPx) mRNA, a member of the glutathione peroxidase family of selenoproteins, in rat hepatoma cell and mouse liver extracts. In linear sucrose gradients, the sedimentation velocity of PHGPx mRNA was impeded compared to CuZn superoxide dismutase (SOD) mRNA, which has a coding region of similar size. Selenium supplementation increased the loading of ribosomes onto PHGPx mRNA, but not CuZn SOD mRNA. To determine whether the slow sedimentation velocity of PHGPx mRNA is due to a block in elongation, we analyzed the polysome distribution of wild-type and mutant mRNAs translated in vitro. Mutation of the UGA/Sec codon to UGU/cysteine increased ribosome loading and protein synthesis. When UGA/Sec was replaced with UAA or when the SECIS element core was deleted, the distribution of the mutant mRNAs was similar to the wild-type mRNA. Addition of SECIS-binding protein SBP2, which is essential for Sec insertion, increased ribosome loading and translation of wild-type PHGPx mRNA, but had no effect on the mutant mRNAs. These results suggest that elongation is impeded at UGA/Sec, and that selenium and SBP2 alleviate this block by promoting Sec incorporation instead of termination.