Probing the conformational changes in 5.8S, 18S and 28S rRNA upon association of derived subunits into complete 80S ribosomes

Lso2 is a conserved ribosome-bound protein required for translational recovery in yeast

Ribosome-binding proteins function broadly in protein synthesis, gene regulation, and cellular homeostasis, but the complete complement of functional ribosome-bound proteins remains unknown. Using quantitative mass spectrometry, we identified late-annotated short open reading frame 2 (Lso2) as a ribosome-associated protein that is broadly conserved in eukaryotes. Genome-wide crosslinking and immunoprecipitation of Lso2 and its human ortholog coiled-coil domain containing 124 (CCDC124) recovered 25S ribosomal RNA in a region near the A site that overlaps the GTPase activation center. Consistent with this location, Lso2 also crosslinked to most tRNAs. Ribosome profiling of yeast lacking LSO2 (lso2Δ) revealed global translation defects during recovery from stationary phase with translation of most genes reduced more than 4-fold. Ribosomes accumulated at start codons, were depleted from stop codons, and showed codon-specific changes in occupancy in lso2Δ. These defects, and the conservation of the specific ribosome-binding activity of Lso2/CCDC124, indicate broadly important functions in translation and physiology.

Translation, or the production of protein from messenger RNA (mRNA), is catalyzed by a universally conserved macromolecular machine known as the ribosome. Ribosome-binding factors are also required for all substeps of translation, from initial recruitment of mRNA to peptide chain elongation to release of the mature polypeptide. However, many ribosome interactors have been identified whose effects on translation and physiology are unknown. Here, we show that the uncharacterized yeast protein late-annotated short open reading frame 2 (Lso2) crosslinks to a region of the ribosome that underlies accurate progression through all substeps of translation, the GTPase activation center. This specific binding activity is conserved in the human ortholog of Lso2, coiled-coil domain containing 124 (CCDC124). Null mutants of lso2 also show severe translation defects during recovery from extended starvation, including failure to initiate on most mRNAs and a general block to peptide chain elongation. We propose that these defects could arise from a function for Lso2 in modulating the activity or integrity of the ribosome GTPase activation center during challenging growth regimes.

Inhibition of eukaryotic translation elongation by cycloheximide and lactimidomycin

Although the protein synthesis inhibitor cycloheximide (CHX) has been known for decades, its precise mechanism of action remains incompletely understood. The glutarimide portion of CHX is seen in a family of structurally related natural products including migrastatin, isomigrastatin and lactimidomycin (LTM). We found that LTM, isomigrastatin and analogs have a potent antiproliferative effect on tumor cell lines and selectively inhibit translation. A systematic comparative study of the effects of CHX and LTM on protein synthesis revealed both similarities and differences between the two inhibitors. Both LTM and CHX were found to block the translocation step in elongation. Footprinting experiments revealed protection of a single cytidine nucleotide (C3993) in the E-site of the 60S ribosomal subunit, thus defining a common binding pocket for the two inhibitors in the ribosome. These results shed new light on the molecular mechanism of inhibition of translation elongation by both CHX and LTM.

Role of RNase L in apoptosis induced by 1-(3-C-ethynyl-beta-D-ribo-pentofuranosyl)cytosine

PURPOSE

1-(3-C-Ethynyl-beta-D: -ribo-pentofuranosyl)cytosine (ECyd), a ribonucleoside analog, has a potent cytotoxic activity against cancer cells. The present studies have been performed to elucidate the overall mechanisms of ECyd-induced apoptotic cell death.

METHODS

Cultured cells of mouse mammary carcinoma FM3A and human fibrosarcoma HT 1080 lines were used. The efficacy of RNA synthesis inhibition by ECyd was assessed by kinetic analysis using nuclei isolated from FM3A cells. RNA status in ECyd-treated cells was investigated by Northern blots, and the cleavage sites of RNA were identified by rapid amplification of 5' cDNA ends (5'-RACE). The effect of protein functions on the ECyd-induced apoptotic pathway was analyzed by siRNA and immunohistochemical techniques. Apoptotic cells were detected by TdT-mediated dUTP-biotin Nick End Labeling (TUNEL) assay.

RESULTS

ECyd induces inhibition of RNA synthesis in vitro and in vivo, which appears to be a major cause for the apoptosis. It is known that ECyd is converted inside the cell into its 5'-triphosphate (ECTP). We have now found in test-tube experiments that ECTP strongly inhibits the activity of RNA polymerase I by competing with CTP. In the absence of robust RNA synthesis, the cellular RNAs would be destined to break down. RNase L was found to be playing a role in the breakdown: thus, the 28S rRNA-fragmentation pattern observed for the ECyd-treated cells was very similar to that observable in an in vitro treatment of the 28S ribosomes with RNase L. Association of RNase L with the cytotoxic action of ECyd was confirmed by use of the siRNA-mediated suppression of the cellular RNase L. Thus, the cells in which the RNase L was knocked-down were highly resistant to the cytotoxic action of ECyd. Further events, downstream of the RNase L action that can lead to the eventual apoptosis, would conceivably involve the phosphorylation of c-jun N-terminal kinase and subsequent decrease in mitochondrial membrane-potential. Evidence to support this flow of events was obtained by siRNA-experiments.

CONCLUSION

The results from this study demonstrated that RNase L is activated after the inhibition of RNA polymerase, and induces mitochondria-dependent apoptotic pathway. We propose this new role for RNase L in the apoptotic mechanism. These findings may open up the possibility of finding new targets for anticancer agents.

Quantitative studies of ribosome conformational dynamics

The ribosome is a dynamic machine that undergoes many conformational rearrangements during the initiation of protein synthesis. Significant differences exist between the process of protein synthesis initiation in eubacteria and eukaryotes. In particular, the initiation of eukaryotic protein synthesis requires roughly an order of magnitude more initiation factors to promote efficient mRNA recruitment and ribosomal recognition of the start codon than are needed for eubacterial initiation. The mechanisms by which these initiation factors promote ribosome conformational changes during stages of initiation have been studied using cross-linking, footprinting, site-directed probing, cryo-electron microscopy, X-ray crystallography, fluorescence spectroscopy and single-molecule techniques. Here, we review how the results of these different approaches have begun to converge to yield a detailed molecular understanding of the dynamic motions that the eukaryotic ribosome cycles through during the initiation of protein synthesis.

Accessibility of 18S rRNA in human 40S subunits and 80S ribosomes at physiological magnesium ion concentrations--implications for the study of ribosome dynamics

Protein biosynthesis requires numerous conformational rearrangements within the ribosome. The structural core of the ribosome is composed of RNA and is therefore dependent on counterions such as magnesium ions for function. Many steps of translation can be compromised or inhibited if the concentration of Mg(2+) is too low or too high. Conditions previously used to probe the conformation of the mammalian ribosome in vitro used high Mg(2+) concentrations that we find completely inhibit translation in vitro. We have therefore probed the conformation of the small ribosomal subunit in low concentrations of Mg(2+) that support translation in vitro and compared it with the conformation of the 40S subunit at high Mg(2+) concentrations. In low Mg(2+) concentrations, we find significantly more changes in chemical probe accessibility in the 40S subunit due to subunit association or binding of the hepatitis C internal ribosomal entry site (HCV IRES) than had been observed before. These results suggest that the ribosome is more dynamic in its functional state than previously appreciated.

Diffusion-based transport of nascent ribosomes in the nucleus

Although the complex process of ribosome assembly in the nucleolus is beginning to be understood, little is known about how the ribosomal subunits move from the nucleolus to the nuclear membrane for transport to the cytoplasm. We show here that large ribosomal subunits move out from the nucleolus and into the nucleoplasm in all directions, with no evidence of concentrated movement along directed paths. Mobility was slowed compared with that expected in aqueous solution in a manner consistent with anomalous diffusion. Once nucleoplasmic, the subunits moved in the same random manner and also sometimes visited another nucleolus before leaving the nucleus.

Possible interaction sites of mRNA, tRNA, translation factors and the nascent peptide in 5S, 5.8S and 28S rRNA in in vivo assembled eukaryotic ribosomal complexes

We have investigated possible interaction sites for mRNA, tRNA, translation factors and the nascent peptide on 5S, 5.8S and 28S rRNA in in vivo assembled translational active mouse ribosomes by comparing the chemical footprinting patterns derived from native polysomes, salt-washed polysomes (mainly lacking translational factors) and salt-washed runoff ribosomes (lacking mRNA, tRNA and translational factors). Several ligand-induced footprints were observed in 28S rRNA while no reactivity changes were seen in 5S and 5.8S rRNA. Footprints derived from mRNA, tRNA and/or the nascent peptide chain were observed in domain I of 28S rRNA (hairpin 23), in domain II (helix 37/38 and helices 42 and 43 and in the eukaryotic expansion segment 15), in domain IV (helices 67 and 74) and in domain V (helices 94 and 96 and in the peptidyl transferase ring). Some of the protected sites were homologous to sites previously suggested to be involved in mRNA, tRNA and/or peptide binding in in vitro assembled prokaryotic complexes. Additional footprints were located in regions that have not previously been found involved in ligand binding. Part of these sites could derive from the nascent peptide in the exit channel of the ribosome.

Functional equivalence of structurally distinct ribosomes in the malaria parasite, Plasmodium berghei

Unlike most eukaryotes, many apicomplexan parasites contain only a few unlinked copies of ribosomal RNA (rRNA) genes. Based on stage-specific expression of these genes and structural differences among the rRNA molecules it has been suggested that Plasmodium spp. produce functionally different ribosomes in different developmental stages. This hypothesis was investigated through comparison of the structure of the large subunit rRNA molecules of the rodent malaria parasite, Plasmodium berghei, and by disruption of both of the rRNA gene units that are transcribed exclusively during development of this parasite in the mosquito (S-type rRNA gene units). In contrast to the human parasite, Plasmodium falciparum, we did not find evidence of structural differences in core regions of the distinct large subunit rRNAs which are known to be associated with catalytic activity including the GTPase site that varies in P. falciparum. Knockout P. berghei parasites lacking either of the S-type gene units were able to complete development in both the vertebrate and mosquito hosts. These results formally exclude the hypothesis that two functionally different ribosome types distinct from the predominantly blood stage-expressed A-type ribosomes, are required for development of all Plasmodium species in the mosquito. The maintenance of two functionally equivalent rRNA genes might now be explained as a gene dosage phenomenon.

Chemical accessibility of 18S rRNA in native ribosomal complexes: interaction sites of mRNA, tRNA and translation factors

During protein synthesis the ribosome interacts with ligands such as mRNA, tRNA and translation factors. We have studied the effect of ribosome-ligand interaction on the accessibility of 18S rRNA for single strand-specific modification in ribosomal complexes that have been assembled in vivo, i. e. native polysomes. A comparison of the modification patterns derived from programmed and non-programmed ribosomes showed that bases in the 630- and 1060-loops (530- and 790-loops in E. coli) together with two nucleotides in helices 33 and 34 were protected from chemical modification. The majority of the protected sites were homologous to sites previously suggested to be involved in mRNA and/or tRNA binding in prokaryotes and eukaryotes, implying that the interaction sites for these ligands are similar, if not identical, in naturally occurring programmed ribosomes and in in vitro assembled ribosomal complexes. Additional differences between programmed and non-programmed ribosomes were found in hairpin 8. The bases in helix 8 showed increased exposure to chemical modification in the programmed ribosomes. In addition, structural differences in helices 36 and 37 were observed between native 80S run-off ribosomes and 80S ribosomes assembled from isolated 40S and 60S subunits.

Release of ribosome-bound 5S rRNA upon cleavage of the phosphodiester bond between nucleotides A54 and A55 in 5S rRNA

Reticulocyte lysates contain ribosome-bound and free populations of 5S RNA. The free population is sensitive to nuclease cleavage in the internal loop B, at the phosphodiester bond connecting nucleotides A54 and A55. Similar cleavage sites were detected in 5S rRNA in 60S subunits and 80S ribosomes. However, 5S rRNA in reticulocyte polysomes is insensitive to cleavage unless ribosomes are salt-washed. This suggests that a translational factor protects the backbone surrounding A54 from cleavage in polysomes. Upon nuclease treatment of mouse 60S subunits or reticulocyte lysates a small population of ribosomes released its 5S rRNA together with ribosomal protein L5. Furthermore, rRNA sequences from 5.8S, 28S and 18S rRNA were released. In 18S rRNA the sequences mainly originate from the 630 loop and stem (helix 18) in the 5' domain, whereas in 28S rRNA a majority of fragments is derived from helices 47 and 81 in domains III and V, respectively. We speculate that this type of rRNA-fragmentation may mimic a ribosome degradation pathway.

Nitric oxide-dependent ribosomal RNA cleavage is associated with inhibition of ribosomal peptidyl transferase activity in ANA-1 murine macrophages

NO can regulate specific cellular functions by altering transcriptional programs and protein reactivity. With respect to global cellular processes, NO has also been demonstrated to inhibit total protein synthesis and cell proliferation. The underlying mechanisms are unknown. In a system of ANA-1 murine macrophages, iNOS expression and NO production were induced by exposure to endotoxin (LPS). In selected instances, cells were exposed to an exogenous NO donor, S-nitroso-N-acetylpenicillamine or a substrate inhibitor of NO synthesis. Cellular exposure to NO, from both endogenous and exogenous sources, was associated with a significant time-dependent decrease in total protein synthesis and cell proliferation. Gene transcription was unaltered. In parallel with decreased protein synthesis, cells exhibited a distinctive cleavage pattern of 28S and 18S rRNA that were the result of two distinct cuts in both 28S and 18S rRNA. Total levels of intact 28S rRNA, 18S rRNA, and the composite 60S ribosome were significantly decreased in the setting of cell exposure to NO. Finally, 60S ribosome-associated peptidyl transferase activity, a key enzyme for peptide chain elongation, was also significantly decreased. Our data suggest that NO-mediated cleavage of 28S and 18S rRNA results in decreased 60S ribosome associated peptidyl transferase activity and inhibition of total protein synthesis.

Nucleotides in 16S rRNA protected by the association of 30S and 50S ribosomal subunits

We have studied the interaction of 16S rRNA in 30S subunits with 50S subunits using a series of chemical probes that monitor the accessibility of the RNA bases and backbone. The probes include 1-cyclohexyl-3-(2-morpholinoethyl) carbodiimide metho-p-toluene sulfonate (CMCT; to probe U at N-3 and G at N-1), diethylpyrocarbonate (DEPC; to probe A at N-7), dimethyl sulfate (DMS; to probe A at N-1, and C at N-3), kethoxal (to probe G at N-1 and N-2), hydroxyl radicals generated by free Fe(II)-EDTA (to probe the backbone ribose groups) and Pb(II). The sites of reaction were identified by primer extension of the probed RNA. Association of the subunits protects the bases of 11 nucleotides and the ribose groups of over 90 nucleotides of 16S rRNA. The nucleotides protected from the base-specific probes are often adjacent to one another and surrounded by sugar-phosphate backbone protections; thus, the results obtained with the different probes confirmed each other. Most of the protected nucleotides occur in five extended-stem-loop structures around positions 250, 700, 790, 900, and 1408-1495. These regions are located in the platform and bottom of the subunit in the general vicinity of inter-subunit bridges that are visible in reconstructed electron micrographs. Our results provide an extensive map of the nucleotides in 16S rRNA that are likely to be involved in subunit-subunit interactions.

Nucleotides in 23S rRNA protected by the association of 30S and 50S ribosomal subunits

We have studied the effect of subunit association on the accessibility of nucleotides in 23S and 5S rRNA. Escherichia coli 50S subunits and 70S ribosomes were subjected to a combination of chemical probes and the sites of attack identified by primer extension. Since the ribose groups and all of the bases were probed, the present study provides a comprehensive map of the nucleotides that are likely to be involved in subunit-subunit interactions. Upon subunit association, the bases of 22 nucleotides and the ribose groups of more than 60 nucleotides are protected in 23S rRNA; no changes are seen in 5S rRNA. Interestingly, the bases of nucleotides A1866, A1891 and A1896, and G2505 become more reactive to chemical probes, indicating localized rearrangement of the structure of the 50S subunit upon association with the 30S subunit. Most of the protected nucleotides are located in four stem-loop structures around positions 715, 890, 1700, and 1920. In free 50S subunits, virtually all of the ribose groups in these four regions are strongly cleaved by hydroxyl radicals, suggesting that these stems protrude from the 50S subunit. When the 30S subunit is bound, most of the ribose groups in the 715, 890, 1700 and 1920 stem-loops are protected, as are many bases in and around the corresponding apical loops. Intriguingly, three of the protected regions of 23S rRNA are known to be linked via tertiary interactions to features of the peptidyl transferase center. Together with the juxtaposition of the subunit-protected regions of 16S rRNA with the small subunit tRNA binding sites, our findings suggest the existence of a communication pathway between the codon-anticodon binding sites of the 30S subunit with the peptidyl transferase center of the 50S subunit via rRNA-rRNA interactions.

A rapid in vitro method for obtaining RNA accessibility patterns for complementary DNA probes: correlation with an intracellular pattern and known RNA structures

A technique is described to identify the rare sequences within an RNA molecule that are available for efficient interaction with complementary DNA probes: the target RNA is digested by RNase H in the presence of a random pool of complementary DNA fragments generated from the same DNA preparation that was used for target RNA synthesis. The DNA region was amplified by PCR, partially digested with DNase and denatured prior to RNA binding. In the presence of single-stranded DNA fragments the RNA was digested with RNase H such that, on average, each molecule was cut once. Cleavage sites were detected by gel electrophoresis either directly with end-labeled RNA or by primer extension. The pattern of accessible sites on c- raf mRNA was determined and compared with the known profile of activity of oligonucleotides found in cells, showing the merit of the method for predicting oligonucleotides which are efficient for in vivo antisense targeting. New susceptible sites in the 3'-untranslated region of c- raf mRNA were identified. Also, four RNAs were probed to ascertain to what extent structure predicts accessibility: the P4-P6 domain of the Tetrahymena group I intron, yeast tRNAAsp, Escherichia coli tmRNA and a part of rat 18S rRNA.

Mapping of nuclease-sensitive sites in native reticulocyte ribosomes--an analysis of the accessibility of ribosomal RNA to enzymatic cleavage

Treatment of ribosomes in reticulocyte lysates with low concentrations of the calcium-dependent nuclease from Staphylococcus aureus resulted in cleavage of rRNA. The positions of the cleaved phosphodiester bonds were localised by primer extension and polyacrylamide gel electrophoresis. S. aureus nuclease-induced strand scissions were found in the 5'-domain of 18S rRNA and in domains II, IV and VI of 28S rRNA. The majority of the cleavage sites were located in eukaryote-specific expansion segments and only one cleavage site was found in a region suggested to be directly involved in ribosomal function. Treatment of the reticulocyte lysate with increasing amounts of S. aureus nuclease resulted in the introduction of new cleavage sites. However, even at the highest nuclease concentration used, large parts of the rRNAs were protected from nuclease digestion. Removal of translational components, by salt wash of isolated reticulocyte polysomes, exposed additional rRNA sequences to S. aureus nuclease cleavage. These sequences were found in the 3'-major domain of 18S rRNA and in domains II, IV, and V of 28S rRNA. These sites are located at the putative translational surface of the ribosome. The translational activity of the S. aureus nuclease-treated ribosomes, determined after addition of exogenous mRNA, was directly correlated to the extent of nuclease digestion of the ribosomes. However, the decrease in translational activity observed in lysates treated with low amounts of S. aureus nuclease was not due to a preferential exclusion of damaged ribosomes from polysome formation. This suggests that the induced cleavages were not detrimental to ribosomal function but could influence the rate of ribosomal movement along the mRNA.

Structure of 18 S ribosomal RNA in native 40 S ribosomal subunits

We have analyzed the structure of 18 S rRNA in native 40 S subunits using chemical modification followed by primer extension. The native subunits were modified using the single-stranded specific reagents dimethyl sulfate and 1-cyclohexyl-3-(2-morpholinoethyl)carbodiimide metho-p-toluenesulfonate. The modification pattern of the 18 S rRNA was compared to that obtained from derived 40 S subunits prepared by dissociation of unprogrammed 80 S ribosomes. Eighteen nucleotides showed different accessibility to the chemical probes in derived and native subunits. Half of these nucleotides were found in the central domain of the rRNA between the 1060 loop and the central pseudoknot. The remaining nucleotides were located in two clusters in the 5'- and 3'-domains of the 18 S rRNA. Derived 40 S subunits are free from non-ribosomal proteins. In contrast, native subunits are intermediates in protein synthesis initiation and contain stoichiometric amounts of initiation factor 3 (Sundkvist, I. C., and Staehelin, T. (1975) J. Mol. Biol. 99, 401-418). The possible role of this factor in altering the structure of 18 S rRNA in the native 40 S subunits is discussed.

Ribosomes and translation

The ribosome is a large multifunctional complex composed of both RNA and proteins. Biophysical methods are yielding low-resolution structures of the overall architecture of ribosomes, and high-resolution structures of individual proteins and segments of rRNA. Accumulating evidence suggests that the ribosomal RNAs play central roles in the critical ribosomal functions of tRNA selection and binding, translocation, and peptidyl transferase. Biochemical and genetic approaches have identified specific functional interactions involving conserved nucleotides in 16S and 23S rRNA. The results obtained by these quite different approaches have begun to converge and promise to yield an unprecedented view of the mechanism of translation in the coming years.

Structural features of the large subunit rRNA expressed in Plasmodium falciparum sporozoites that distinguish it from the asexually expressed subunit rRNA

The developmentally regulated transcription of at least two distinct sets of nuclear-encoded ribosomal RNAs is detected in Plasmodium species. The identification of functional differences between the two sets of rRNAs is of interest. To facilitate the search for such differences, we have identified the 5.8S and 28S rRNAs from Plasmodium falciparum that are expressed in the sporozoite stage (S gene) of the parasites' life cycle in the mosquito host and compare them to transcripts expressed in the red blood cells (A gene) of the vertebrate host. This completes the first set of A- and S-type nuclear-encoded rRNA genes for a Plasmodium species. Analysis of the predicted secondary structures of the two units reveals the majority of differences between the A- and S-type genes occur in regions previously known to be variable. However, the predicted secondary structure of both 28S rRNAs indicates 11 positions within conserved areas that are not typical of eucaryotic rRNAs. Although the A-type gene resembles almost all eucaryotes, being atypical in only 4 of the 11 positions, the S gene is variant in 8 of the 11 positions. In three of these positions, the S-type gene resembles the consensus nucleotides for the 23S rRNA from Eubacteria and/or Archaea. A few differences occur in regions associated with ribosome function, in particular the GTPase site where the S-type differs in a base pair and loop from all known sequences. Further, the identification of compensatory changes at conserved points of interactions between the 5.8S-28S rRNAs indicates that transcripts from A- and S-units should not be interchangeable.

Interaction sites of ribosome-bound eukaryotic elongation factor 2 in 18S and 28S rRNA

The involvement of ribosomal RNA in the binding of eukaryotic elongation factor eEF-2 to the ribosome was investigated. eEF-2 was complexed to empty reassociated 80S ribosomes in the presence of the nonhydrolyzable GTP analogue GuoPP[CH2]P. The formed complex was treated with dimethyl sulfate, 1-cyclohexyl-3-(2-morpholinoethyl)carbodiimide metho-p-toluenesulfonate, and micrococcus nuclease to allow specific modification at single-stranded regions of the rRNAs. The sites of modification were localized by primer extension using complementary deoxynucleotide primers and reverse transcriptase. The modification pattern was compared to that obtained from 80S ribosomes lacking bound eEF-2. Binding of the factor to the ribosome resulted in the protection of specific sites in both 18S and 28S rRNA, while the reactivity of 5.8S rRNA was unchanged. In 18S rRNA, the affected nucleotides were localized to the 5'- and 3'-domains, and in 28S rRNA the protected nucleotides were seen in domains II, IV, and V. The alpha-sarcin/ricin loop in domain VI of 28S rRNA was inaccessible for chemical modification even in the absence of bound eEF-2. However, the bound factor protected A4256, located in the alpha-sarcin/ricin loop, from ricin-induced depurination.