Ribosomal protein S7 from Escherichia coli uses the same determinants to bind 16S ribosomal RNA and its messenger RNA

Ribosomal protein S7 from Escherichia coli binds to the lower half of the 3′ major domain of 16S rRNA and initiates its folding. It also binds to its own mRNA, the str mRNA, and represses its translation. Using filter binding assays, we show in this study that the same mutations that interfere with S7 binding to 16S rRNA also weaken its affinity for its mRNA. This suggests that the same protein regions are responsible for mRNA and rRNA binding affinities, and that S7 recognizes identical sequence elements within the two RNA targets, although they have dissimilar secondary structures. Overexpression of S7 is known to inhibit bacterial growth. This phenotypic growth defect was relieved in cells overexpressing S7 mutants that bind poorly the str mRNA, confirming that growth impairment is controlled by the binding of S7 to its mRNA. Interestingly, a mutant with a short deletion at the C-terminus of S7 was more detrimental to cell growth than wild-type S7. This suggests that the C-terminal portion of S7 plays an important role in ribosome function, which is perturbed by the deletion.     

Ribosomal proteins Rps0 and Rps21 of Saccharomyces cerevisiae have overlapping functions in the maturation of the 3' end of 18S rRNA

The Rps0 proteins of Saccharomyces cerevisiae are components of the 40S ribosomal subunit required for maturation of the 3′ end of 18S rRNA. Drosophila and human homologs of the Rps0 proteins physically interact with Rps21 proteins, and decreased expression of both proteins in Drosophila impairs control of cellular proliferation in hematopoietic organs during larval development. Here, we characterize the yeast RPS21A/B genes and show that strains where both genes are disrupted are not viable. Relative to the wild type, cells with disrupted RPS21A or RPS21B genes exhibit a reduction in growth rate, a decrease in free 40S subunits, an increase in the amount of free 60S subunits, and a decrease in polysome size. Ribosomal RNA processing studies reveal RPS21 and RPS0 mutants have virtually identical processing defects. The pattern of processing defects observed in RPS0 and RPS21 mutants is not a general characteristic of strains with suboptimal levels of small subunit ribosomal proteins, since disruption of the RPS18A or RPS18B genes results in related but distinct processing defects. Together, these data link the Rps0 and Rps21 proteins together functionally in promoting maturation of the 3′ end of 18S rRNA and formation of active 40S ribosomal subunits.     

Human ribosomal protein S13 regulates expression of its own gene at the splicing step by a feedback mechanism

The expression of ribosomal protein (rp) genes is regulated at multiple levels. In yeast, two genes are autoregulated by feedback effects of the protein on pre-mRNA splicing. Here, we have investigated whether similar mechanisms occur in eukaryotes with more complicated and highly regulated splicing patterns. Comparisons of the sequences of ribosomal protein S13 gene (RPS13) among mammals and birds revealed that intron 1 is more conserved than the other introns. Transfection of HEK 293 cells with a minigene-expressing ribosomal protein S13 showed that the presence of intron 1 reduced expression by a factor of four. Ribosomal protein S13 was found to inhibit excision of intron 1 from rpS13 pre-mRNA fragment in vitro. This protein was shown to be able to specifically bind the fragment and to confer protection against ribonuclease cleavage at sequences near the 5′ and 3′ splice sites. The results suggest that overproduction of rpS13 in mammalian cells interferes with splicing of its own pre-mRNA by a feedback mechanism.     

Interaction of Human Ribosomal Protein S26 with Fragments of Its Own mRNA and Pre-mRNA in Nuclear Extract of HeLa Cells

As shown by nitrocellulose filtration assays with RNA fragments transcribed from various regions of the human ribosomal protein (rp) S26 gene, recombinant rpS26 binds to the first intron of the rpS26 pre-mRNA (apparent association constant (K _a) 5.0 · 10⁷ M^–1) and, to a lesser extent, to the rpS26 mRNA (K _a 2.0 · 10⁷ M^–1). The binding was specific, since human rpS19 had an order of magnitude lower K _a with the first intron and did not bind with the rpS26 mRNA. Immunoassays with specific antibodies showed that rpS26 contained in the nuclear extract of HeLa cells binds to the first intron of its pre-mRNA and, less efficiently, to its mRNA. In either case, RNA binding substantially increased in the presence of recombinant rpS26. Along with other (48K, 59K) nuclear proteins, rpS26 was assumed to form complexes, the functional role of which is storage of pre-mRNAs inactive in splicing.     

Purification of 30S ribosomal subunit by streptavidin affinity chromatography

Preparation of pure ribosomal subunits carrying lethal mutations is necessary for studying every essential functional region of ribosomal RNA. Affinity purification via a tag, inserted into rRNA proved to be procedure of choice for purification of such ribosomal subunits. Here we describe fast and simple purification method for the 30S ribosomal subunits using affinity chromatography. Streptavidin-binding tag was inserted into functionally neutral helix 33a of the 16 S rRNA from Escherichia coli. Tagged ribosomal subunits were shown to be expressed in E. coli and could be purified. Purified subunits with affinity tag behave similarly to the wild type subunits in association with the 50S subunits, toe-printing and tRNA binding assays. Tagged 30S subunits could support cell growth in the strain lacking wild type 30S subunits and only marginally change the growth rate of bacteria. The presented purification method is thus suitable for further use in purification of 30S subunits carrying any lethal mutations.     

Interaction of human S26 ribosomal protein with fragments of mRNA and pre-mRNA for this protein in Hela nuclear cell extracts

As shown by nitrocellulose filtration assays with RNA fragments transcribed from various regions of the human ribosomal protein (rp) S26 gene, recombinant rpS26 binds to the first intron of the rpS26 pre-mRNA (apparent association constant (Ka) approximately 5.0 x 10(7) M-1) and, to a lesser extent, to the rpS26 mRNA (Ka approximately 2.0 x 10(7) M-1). The binding was specific, since human rpS19 had an order of magnitude lower Ka with the first intron and did not bind with the rpS26 mRNA. Immunoassays with specific antibodies showed that rpS26 contained in the nuclear extract of HeLa cells binds to the first intron of its pre-mRNA and, less efficiently, to its mRNA. In either case, RNA binding substantially increased in the presence of recombinant rpS26. Along with other (48 K, 59 K) nuclear proteins, rpS26 was assumed to form complexes, the functional role of which is storage of pre-mRNAs inactive in splicing.     

Ribosomal Protein Binding with the First Intron of the Human rpS26 Pre-mRNA Stimulates Its Interaction with Proteins Extracted from HeLa Cells

As shown by nitrocellulose filtration assays with RNA fragments transcribed from various regions of the human ribosomal protein (rp) S26 gene, proteins of the 40S ribosome subunit bind to the first intron of the rpS26 pre-mRNA. The binding involved mostly S23, S26 and, to a lesser extent, S13/16. Negligible binding was observed for S2/3a, S6, S8, S10, S11, and S20. Small-subunit proteins did not affect the efficiency of in vitro splicing of a pre-mRNA fragment corresponding to the first intron, second exon, second intron, and a part of the third exon of the rpS26 gene. However, ribosomal proteins substantially increased UV-induced adduction of the pre-mRNA fragments with nuclear extract proteins of HeLa cells. The same set of HeLa proteins was observed with each pre-mRNA fragment. Ribosomal proteins formed adducts only in the absence of HeLa proteins.     

Human ribosomal protein S13 inhibits splicing of the own pre-mRNA

Recombinant human ribosomal protein S13 (rpS 13) is shown to bind specifically a fragment of its own pre-mRNA that includes exons 1 and 2, intron 1, and part of intron 2, and to inhibit the splicing of that fragment in vitro. The weaker binding of other recombinant human ribosomal proteins, S10 and S16, to this pre-mRNA fragment indicated that the binding of rpS 13 was specific. Besides, poly(AU) and adenovirus pre-mRNA fragment affected poorly the binding of rpS 13 to S13 pre-mRNA, providing another evidence that the interaction was specific. RpS 13 specifically inhibited the pre-mRNA splicing whereas recombinant rpS10 and rpS16 did not affect excision of intron from S13 pre-mRNA fragment in contrast to rpS 13. Those positions in S13 pre-mRNA that were protected by rpS13 protein against cleavage by RNases T1, T2 and V1 were found to be located closely to the 5' and 3' splice sites in the pre-mRNA. Intron 1 in S13 pre-mRNA is more highly conserved within mammals than the other introns in S13 pre-mRNA, which supports the possibility of an important role for intron 1 in the regulation of expression of rpS13 gene in mammals.     

Ribosomal protein binding with the first intron of the human ribosomal protein S26 pre-mRNA stimulates its interaction with proteins extracted from Hela cells

As shown by nitrocellulose filtration assays with RNA fragments transcribed from various regions of the human ribosomal protein (rp) S26 gene, proteins of the 40S ribosome subunit bind to the first intron of the rpS26 pre-mRNA. The binding involved mostly S23, S26 and, to a lesser extent, S13/16. Negligible binding was observed for S2/3a, S6, S8, S10, S11, and S20. Small-subunit proteins did not affect the efficiency of in vitro splicing of a pre-mRNA fragment corresponding to the first intron, second exon, second intron, and a part of the third exon of the rpS26 gene. However, ribosomal proteins substantially increased UV-induced adduction of the pre-mRNA fragments with nuclear extract proteins of HeLa cells. The same set of HeLa proteins was observed with each pre-mRNA fragment. Ribosomal proteins formed adducts only in the absence of HeLa proteins.     

Human ribosomal protein S16 inhibits excision of the first intron from its own pre-mRNA

Recombinant human ribosomal protein S16 (rpS16) is shown to bind specifically to a fragment of its own pre-mRNA that includes exons 1 and 2, intron 1, and part of intron 2, and to inhibit the splicing of the fragment in vitro. The weaker binding of other recombinant human ribosomal proteins, S10 and S13, to this pre-mRNA fragment indicated that the binding of rpS16 was specific. Besides, the poly(AU) and rpS16 mRNA fragment insignificantly affected the binding of rpS16 to its pre-mRNA, providing another evidence that the interaction was specific. rpS16 specifically inhibited the splicing of the pre-mRNA fragment, whereas recombinant rpS10 and rpS13 did not affect intron excision from this pre-mRNA fragment in contrast to rpS16. Those positions in rpS16 pre-mRNA fragment that were protected by rpS16 from cleavage by RNases T1, T2, and V1 were found to be located closely to the branch point and 3’ splice site in the pre-mRNA. The obtained results suggest the possibility of the autoregulation of rpS13 pre-mRNA splicing through the feedback mechanism.     

The carboxy-terminal extension of yeast ribosomal protein S14 is necessary for maturation of 43S preribosomes

Eukaryotic ribosomal proteins are required for production of stable ribosome assembly intermediates and mature ribosomes, but more specific roles for these proteins in biogenesis of ribosomes are not known. Here we demonstrate a particular function for yeast ribosomal protein rpS14 in late steps of 40S ribosomal subunit maturation and pre-rRNA processing. Extraordinary amounts of 43S preribosomes containing 20S pre-rRNA accumulate in the cytoplasm of certain rps14 mutants. These mutations not only reveal a more precise function for rpS14 in ribosome biogenesis but also uncover a role in ribosome assembly for the extended tails found in many ribosomal proteins. These studies are one of the first to relate the structure of eukaryotic ribosomes to their assembly pathway-the carboxy-terminal extension of rpS14 is located in the 40S subunit near the 3' end of 18S rRNA, consistent with a role for rpS14 in 3' end processing of 20S pre-rRNA.     

Identification of the Rps28 binding motif from yeast Edc3 involved in the autoregulatory feedback loop controlling RPS28B mRNA decay

In the yeast Saccharomyces cerevisiae, the Edc3 protein was previously reported to participate in the auto-regulatory feedback loop controlling the level of the RPS28B messenger RNA (mRNA). We show here that Edc3 binds directly and tightly to the globular core of Rps28 ribosomal protein. This binding occurs through a motif that is present exclusively in Edc3 proteins from yeast belonging to the Saccharomycetaceae phylum. Functional analyses indicate that the ability of Edc3 to interact with Rps28 is not required for its general function and for its role in the regulation of the YRA1 pre-mRNA decay. In contrast, this interaction appears to be exclusively required for the auto-regulatory mechanism controlling the RPS28B mRNA decay. These observations suggest a plausible model for the evolutionary appearance of a Rps28 binding motif in Edc3.     

RNA aptamers that specifically bind to a 16S ribosomal RNA decoding region construct

RNA–RNA recognition is a critical process in controlling many key biological events, such as translation and ribozyme functions. The recognition process governing RNA–RNA interactions can involve complementary Watson–Crick (WC) base pair binding, or can involve binding through tertiary structural interaction. Hence, it is of interest to determine which of the RNA–RNA binding events might emerge through an in vitro selection process. The A-site of the 16S rRNA decoding region was chosen as the target, both because it possesses several different RNA structural motifs, and because it is the rRNA site where codon/anticodon recognition occurs requiring recognition of both mRNA and tRNA. It is shown here that a single family of RNA molecules can be readily selected from two different sizes of RNA library. The tightest binding aptamer to the A-site 16S rRNA construct, 109.2-3, has its consensus sequences confined to a stem–loop region, which contains three nucleotides complementary to three of the four nucleotides in the stem–loop region of the A-site 16S rRNA. Point mutations on each of the three nucleotides on the stem–loop of the aptamer abolish its binding capacity. These studies suggest that the RNA aptamer 109.2-3 interacts with the simple 27 nt A-site decoding region of 16S rRNA through their respective stem–loops. The most probable mode of interaction is through complementary WC base pairing, commonly referred to as a loop–loop ‘kissing’ motif. High affinity binding to the other structural motifs in the decoding region were not observed.     

Antibiotic stress-induced modulation of the endoribonucleolytic activity of RNase III and RNase G confers resistance to aminoglycoside antibiotics in Escherichia coli

Here, we report a resistance mechanism that is induced through the modulation of 16S ribosomal RNA (rRNA) processing on the exposure of Escherichia coli cells to aminoglycoside antibiotics. We observed decreased expression levels of RNase G associated with increased RNase III activity on rng mRNA in a subgroup of E. coli isolates that transiently acquired resistance to low levels of kanamycin or streptomycin. Analyses of 16S rRNA from the aminoglycoside-resistant E. coli cells, in addition to mutagenesis studies, demonstrated that the accumulation of 16S rRNA precursors containing 3–8 extra nucleotides at the 5’ terminus, which results from incomplete processing by RNase G, is responsible for the observed aminoglycoside resistance. Chemical protection, mass spectrometry analysis and cell-free translation assays revealed that the ribosomes from rng-deleted E. coli have decreased binding capacity for, and diminished sensitivity to, streptomycin and neomycin, compared with wild-type cells. It was observed that the deletion of rng had similar effects in Salmonella enterica serovar Typhimurium strain SL1344. Our findings suggest that modulation of the endoribonucleolytic activity of RNase III and RNase G constitutes a previously uncharacterized regulatory pathway for adaptive resistance in E. coli and related gram-negative bacteria to aminoglycoside antibiotics.     

Mutual induced fit binding of Xenopus ribosomal protein L5 to 5S rRNA

A library of random mutations in Xenopus ribosomal protein L5 was generated by error-prone PCR and used to delineate the binding domain for 5S rRNA. All but one of the amino acid substitutions that affected binding affinity are clustered in the central region of the protein. Several of the mutations are conservative substitutions of non-polar amino acid residues that are unlikely to form energetically significant contacts to the RNA. Thermal denaturation, monitored by circular dichroism (CD), indicates that L5 is not fully structured and association with 5S rRNA increases the t(m) of the protein by 16 degrees C. L5 induces changes in the CD spectrum of 5S rRNA, establishing that the complex forms by a mutual induced fit mechanism. Deuterium exchange reveals that a considerable amount of L5 is unstructured in the absence of 5S rRNA. The fluorescence emission of W266 provides evidence for structural changes in the C-terminal region of L5 upon binding to 5S rRNA; whereas, protection experiments demonstrate that the N terminus remains highly sensitive to protease digestion in the complex. Analysis of the amino acid sequence of L5 by the program PONDR predicts that the N and C-terminal regions of L5 are intrinsically disordered, but that the central region, which contains three essential tyrosine residues and other residues important for binding to 5S rRNA, is likely to be structured. Initial interaction of the protein with 5S rRNA likely occurs through this region, followed by induced folding of the C-terminal region. The persistent disorder in the N-terminal domain is possibly exploited for interactions between the L5-5S rRNA complex and other proteins.