Functional analysis of the invariant residue G791 of Escherichia coli 16S rRNA

The nucleotide at position 791(G791) of E. coli 16S rRNA was previously identified as an invariant residue for ribosomal function. In order to characterize the functional role of G791, base substitutions were introduced at this position, and mutant ribosomes were analyzed with regard to their protein synthesis ability, via the use of a specialized ribosome system. These ribosomal RNA mutations attenuated the ability of ribosomes to conduct protein synthesis by more than 65%. A transition mutation (G to A) exerted a moderate effect on ribosomal function, whereas a transversion mutation (G to C or U) resulted in a loss of protein synthesis ability of more than 90%. The sucrose gradient profiles of ribosomes and primer extension analysis showed that the loss of protein-synthesis ability of mutant ribosomes harboring a base substitution from G to U at position 791 stems partially from its inability to form 70S ribosomes. These findings show the involvement of the nucleotide at position 791 in the association of ribosomal subunits and protein synthesis steps after 70S formation, as well as the possibility of using 16S rRNA mutated at position 791 for the selection of second-site revertants in order to identify ligands that interact with G791 in protein synthesis.     

Isolation of ribosomal subparticles from human placenta containing intact rRNA and determination of the functional activity of the 80S ribosome

The method for isolation of human placenta ribosomal subunits containing intact rRNA has been determined. The method uses fresh unfrozen placenta. Activity of 80S ribosomes obtained via reassociation of 40S and 60S subunits in non-enzymatic poly(U)-mediated Phe-tRNAPhe binding, was near 75% (maximal [14C]Phe-tRNA(Phe) binding was 1.5 mol Phe-tRNA(Phe) per mol of 80S ribosomes). Activity of 80S ribosomes with damaged rRNA isolated from frozen placenta was 2 times lower (the maximum level of poly(U)-dependent Phe-tRNA(Phe) binding was 0.7 mol per mol of ribosomes). The activity 80S ribosomes in poly(U)-mediated synthesis of polyphenylalanine was determined by using fractionated ("ribosomeless") protein synthesising system from rabbit reticulocytes. In this system up to the 50 mol of Phe residues per mol of 80S ribosomes are incorporated in acid insoluble fraction in 1 hour, at 37 degrees C. The obtained level of [14C]phenylalanine incorporation is three times as much as the amount of Phe residues observed for the ribosomal subunits, isolated from frozen placenta.     

30S ribosomal subunits with fragmented 16S RNA: a new approach for structure and function study of ribosomes.

A new approach for function and structure study of ribosomes based on oligodeoxyribonucleotide-directed cleavage of rRNA with RNase H and subsequent reconstitution of ribosomal subunits from fragmented RNA has been developed. The E coli 16S rRNA was cleaved at 9 regions belonging to different RNA domains. The deletion of 2 large regions was also produced by cleaving 16S rRNA in the presence of 2 or 3 oligonucleotides complementary to different RNA sites. Fragmented and deleted RNA were shown to be efficiently assembled with total ribosomal protein into 30S-like particles. The capacity to form 70S ribosomes and translate both synthetic and natural mRNA of 30S subunits reconstituted from intact and fragmented 16S mRNA was compared. All 30S subunits assembled with fragmented 16S rRNA revealed very different activity: the fragmentation of RNA at the 781-800 and 1392-1408 regions led to the complete inactivation of ribosomes, whereas the RNA fragmentation at the regions 296-305, 913-925, 990-998, 1043-1049, 1207-1215, 1499-1506, 1530-1539 did not significantly influence the ribosome protein synthesis activity, although it was also reduced. These findings are mainly in accordance with the data on the functional activity of some 16S rRNA sites obtained by other methods. The relations between different 16S RNA functional sites are discussed.     

Replacement of the L11 binding region within E.coli 23S ribosomal RNA with its homologue from yeast: in vivo and in vitro analysis of hybrid ribosomes altered in the GTPase centre.

Replacement of the protein L11 binding domain within Escherichia coli 23S ribosomal RNA (rRNA) by the equivalent region from yeast 26S rRNA appeared to have no effect on the growth rate of E.coli cells harbouring a plasmid carrying the mutated rrnB operon. The hybrid rRNA was correctly processed and assembled into ribosomes, which accumulated normally in polyribosomes. Of the total ribosomal population, < 25% contained wild-type, chromosomally encoded rRNA; the remainder were mutant. The hybrid ribosomes supported GTP hydrolysis dependent upon E.coli elongation factor G, although at a somewhat reduced rate compared with wild-type particles, and were sensitive to the antibiotic, thiostrepton, a potent inhibitor of ribosomal GTPase activity that binds to 23S rRNA within the L11 binding domain. That thiostrepton could indeed bind to the mutant ribosomes, although at a reduced level relative to that seen with wild-type ribosomes, was confirmed in a non-equilibrium assay. The rationale for the ability of the hybrid ribosomes to bind the antibiotic, given that yeast ribosomes do not, was provided when yeast rRNA was shown by equilibrium dialysis to bind thiostrepton only 10-fold less tightly than did E.coli rRNA. The extreme conservation of secondary, but not primary, structure in this region between E.coli and yeast rRNAs allows the hybrid ribosomes to function competently in protein synthesis and also preserves the interaction with thiostrepton.     

The mechanism of action of trichosanthin on eukaryotic ribosomes--RNA N-glycosidase activity of the cytotoxin.

Trichosanthin is a ribosome-inactivating protein from root tubers of Trichosanthes kirilowii Maxim. In this paper, the mechanism of action of trichosanthin on eukaryotic ribosomes was studied. A fragment of about 450 nucleotides was released from 28S ribosomal RNA after treatment of rat liver ribosome with trichosanthin and its isolated ribosomal RNAs were treated with aniline. Analysis of nucleotide sequence of 5' terminus of this fragment revealed that the aniline-sensitive site of the phosphodiester bond was between positions A4324 and G4325 in the 28S rRNA. Adenine was recovered by ion-exchange column chromatography from the 50% ethanol soluble fraction of the reaction mixture in which rat liver ribosomes were treated with trichosanthin. Thin-layer chromatographic analysis indicated that 1 mol of adenine was released from 1 mol of ribosomes. When the ribosomes were incubated with trichosanthin in the presence of inorganic [32P]phosphate, little incorporation of radioactivity into 28S rRNA was observed, indicating that the release of adenine was not mediated by phosphorolysis. These results demonstrate that trichosanthin inactivates the ribosomes by cleaving the N-C glycosidic bond of adenylic acid at 4324 of 28S rRNA in a hydrolytic fashion.     

The mechanism of action of the cytotoxic lectin from Phoradendron californicum: the RNA N-glycosidase activity of the protein

A toxic lectin from Phoradendron californicum (PCL) was found to inactivate catalytically 60 S ribosomal subunits of rabbit reticulocytes, resulting in the inhibition of protein synthesis. To study the mechanism of action of PCL, rat liver ribosomes were treated with the toxin and the extracted rRNA was treated with aniline. A fragment containing about 450 nucleotides was released from the 28 S rRNA. Analysis of the nucleotide sequence of the fragment revealed that the aniline-sensitive phosphodiester bond was between A4324 and G4325 of the 28 S rRNA. These results indicate that PCL inactivates the ribosomes by cleaving an N-glycosidic bond at A4324 of 28 S rRNA in the ribosomes as does ricin A-chain.     

A study of the thermal stability of ribosomes and biologically active subribosomal particles

1. The ability of Escherichia coli ribosomes to function in poly(U)-directed protein synthesis was measured at elevated temperatures by using thermostable supernatant factors from Bacillus stearothermophilus. The amount of polyphenylalanine synthesized at 55 degrees C was about the same as at 37 degrees C, but the rate of synthesis was increased approximately fivefold. At 60 degrees C the activity of the ribosomes was halved. 2. E. coli ribosomes can sustain the loss of approx. 10% of the double-helical secondary structure of RNA without losing activity. 3. Within the active ribosome the double-helical secondary structure of the rRNA moiety is stabilized compared with isolated rRNA, as judged by enzymic hydrolysis and by measurements of E(260). 4. The main products, over the range 0-55 degrees C, of ribonuclease T(1) digestion of the smaller subribosomal particle of E. coli were two fragments (s(0) (20,w) 15S and 25.3S) of approximately one-quarter and three-quarters of the size of the intact molecule, revealing the presence of a ;weak spot' where intramolecular bonds appear insufficient to hold the fragments together. 5. Subribosomal particles of B. stearothermophilus were more stable to heating, by approx. 10 degrees C, than those of E. coli, and the stabilization of double-helical secondary structure of the RNA moiety was more striking. 6. Rabbit reticulocyte ribosomes were active in poly(U)-directed protein synthesis at 45 degrees C, and half the activity was lost after heating to 53 degrees C. Active subribosomal particles of rabbit reticulocytes and of oocytes of Xenopus laevis, like the bacterial subribosomal particles, underwent a conformational change to a slower-sedimenting form on heating. The temperature range of the transition depended on the species. 7. Slower-sedimenting particles, whether produced by EDTA treatment or by heating, had different ;melting' profiles compared with active subribosomal particles, providing another indication of conformational differences. 8. Comparison of the properties of the various subribosomal particles revealed greater variation in the secondary structure of the protein moieties (judged by measurement of circular dichroism) than in the secondary structure of the RNA moieties, which appeared to have features in common.     

Stoichiometry and structure of a complex of acidic ribosomal proteins

The acidic proteins B-L13 (homologous to Escherichia coli protein L7/L12) and B-L8, from the 50 S subunit of Bacillus stearothermophilus ribosomes, form a stable complex. Trypsin digestion of ribosomes generates an N-terminal fragment of B-L13 (approximately residues 1 to 47) which can associate with B-L8, displacing intact B-L13, and bind to B-L13-deficient ribosomes. Displacement of B-L13 from the B-L8 · B-L13 complex by the B-L13 N-terminal fragment causes a change in gel electrophoretic mobility of the complex, and titration of the complex with fragment indicates unambiguously that it contains four molecules of B-L13. Evidence is presented that B-L13 forms a dimer in solution, and that the dimer associates intact with B-L8. Reconstituted 50 S subunits in which B-L13 is replaced by its N-terminal fragment have the same functional properties as 50 S subunits missing B-L13 altogether: polypeptide synthesis is reduced but not abolished; ability to bind elongation factor EF-G and GTP is severely reduced; and peptidyl transferase activity and ability to associate with a 30 S subunit · Phe-tRNA · poly(U) complex are unaffected (relative to intact 50 S subunits).     

Mechanism and site of action of a ribosome-inactivating protein type 1 from Dianthus barbatus which inactivates Escherichia coli ribosomes.

A single chain ribosome-inactivating protein with RNA N-glycosidase activity, here named Dianthin 29, was isolated from leaves of Dianthus barbatus L. Incubation of intact Escherichia coli ribosomes with Dianthin 29 and subsequent aniline treatment of the isolated rRNA releases a rRNA fragment of 243 nucleotides from 23 S rRNA. Nucleotide sequence studies showed that the site of N-glycosidic bond cleavage is at A-2660 within the universally conserved sequence 5'-AGUACGAGAGGA-3' near the 3'-end of 23/28 S rRNAs. To our knowledge, Dianthin 29 is the first ribosome-inactivating protein which is shown to inactivate intact prokaryotic ribosomes in the same manner as eukaryotic ribosomes.     

Functional analysis of the residues C770 and G771 of E. coli 16S rRNA implicated in forming the intersubunit bridge B2c of the ribosome

Structural analyses have shown that nucleotides at the positions 770 and 771 of Escherichia coli 16S rRNA are implicated in forming one of highly conserved intersubunit bridges of the ribosome, B2c. To examine a functional role of these residues, base substitutions were introduced at these positions and mutant ribosomes were analyzed for their protein synthesis ability using a specialized ribosome system. The results showed requirement of a pyrimidine at the position 770 for ribosome function regardless of the nucleotide identity at the position 771. Sucrose gradient profiles of ribosomes revealed that the loss of protein-synthesis ability of mutant ribosome bearing a base substitution from C to G at the position 770 stems from its inability to form 70S ribosomes. These findings indicate involvement of nucleotide at the position 770, not 771, in ribosomal subunit association and provide a useful rRNA mutation that can be used as a target to investigate the physical interaction between 16S and 23S rRNA.     

Insights into the Mechanism of Ribosomal Incorporation of Mammalian L13a Protein during Ribosome Biogenesis

In contrast to prokaryotes, the precise mechanism of incorporation of ribosomal proteins into ribosomes in eukaryotes is not well understood. For the majority of eukaryotic ribosomal proteins, residues critical for rRNA binding, a key step in the hierarchical assembly of ribosomes, have not been well defined. In this study, we used the mammalian ribosomal protein L13a as a model to investigate the mechanism(s) underlying eukaryotic ribosomal protein incorporation into ribosomes. This work identified the arginine residue at position 68 of L13a as being essential for L13a binding to rRNA and incorporation into ribosomes. We also demonstrated that incorporation of L13a takes place during maturation of the 90S preribosome in the nucleolus, but that translocation of L13a into the nucleolus is not sufficient for its incorporation into ribosomes. Incorporation of L13a into the 90S preribosome was required for rRNA methylation within the 90S complex. However, mutations abolishing ribosomal incorporation of L13a did not affect its ability to be phosphorylated or its extraribosomal function in GAIT element-mediated translational silencing. These results provide new insights into the mechanism of ribosomal incorporation of L13a and will be useful in guiding future studies aimed at fully deciphering mammalian ribosome biogenesis.     

Cytoplasmic p53 polypeptide is associated with ribosomes.

Our previous finding that the tumor suppressor p53 is covalently linked to 5.8S rRNA suggested functional association of p53 polypeptide with ribosomes. p53 polypeptide is expressed at low basal levels in the cytoplasm of normal growing cells in the G1 phase of the cell cycle. We report here that cytoplasmic wild-type p53 polypeptide from both rat embryo fibroblasts and MCF7 cells and the A135V transforming mutant p53 polypeptide were found associated with ribosomes to various extents. Treatment of cytoplasmic extracts with RNase or puromycin in the presence of high salt, both of which are known to disrupt ribosomal function, dissociated p53 polypeptide from the ribosomes. In immunoprecipitates of p53 polypeptide-associated ribosomes, 5.8S rRNA was detectable only after proteinase K treatment, indicating all of the 5.8S rRNA in p53-associated ribosomes is covalently linked to protein. While 5.8S rRNA linked to protein was found in the immunoprecipitates of either wild-type or A135V mutant p53 polypeptide associated with ribosomes, little 5.8S rRNA was found in the immunoprecipitates of the slowly sedimenting p53 polypeptide, which was not associated with ribosomes. In contrast, 5.8S rRNA was liberated from bulk ribosomes by 1% sodium dodecyl sulfate, without digestion with proteinase K, indicating that these ribosomes contain 5.8S rRNA, which is not linked to protein. Immunoprecipitation of p53 polypeptide coprecipitated a small fraction of ribosomes. p53 mRNA immunoprecipitated with cytoplasmic p53 polypeptide, while GAPDH mRNA did not. These results show that cytoplasmic p53 polypeptide is associated with a subset of ribosomes, having covalently modified 5.8S rRNA.     

Ribosome metabolism in hormone-treated Jerusalem artichoke tuber slices in the absence and presence of 5-fluorouracil

In order to examine the relation of protein synthesis to the onset of growth, changes in ribosome content and activity were compared in aged, metabolically active Jerusalem artichoke (Helianthus tuberosus L.) slices incubated in water or 2,4-dichlorophenoxyacetic acid+kinetin. In water, cells do not grow or divide and rRNA and protein levels remain constant. The percentage membrane-bound (mb) ribosomes drops from 25% to 16% during 24h. At the same time the proportion of ribosomes active in protein synthesis in both free and mb populations declines from about 69% to 54%. In auxin+kinetin, cell expansion occurs and is accompanied by a 3-fold increase in rRNA and a 50% increase in total protein content. The percentage mb ribosomes remains at 25% throughout 48 h of growth. During the first 24h of growth 70% of ribosomes in both free and mb populations are active; this value declines to near water levels at 48 h. Considering the large increase in total ribosomes the number of synthetically active ribosomes is substantially increased during growth. 5-Fluorouracil (5-FU) does not inhibit hormone induced growth but does depress total rRNA content by about one-third. It also reduces [³H]uridine incorporation into ribosomes by 70% and the newly made ribosomes are mostly inactive in protein synthesis. On the other hand, the inhibitor does not significantly affect the proportion of total ribosomes active in protein synthesis and only partially reduces protein accumulation during the second 24 h of growth. It is suggested that while ribosome production is reduced in 5-FU, ribosome turnover is also retarded resulting in retention of near normal capacity for protein synthesis and growth.     

Ribosomal RNA synthesis in haploid and diploid loach embryos]

rRNA synthesis was compared in the loach haploid (In) and diploid (2n) embryos. The relative intensity of synthesis was evaluated by 14C-uridine incorporation in 27S and 18S rRNA isolated from ribosomes taking into account label incorporation into total acid-soluble fraction and phosphrylated uridine derivatives. Label incorporation into rRNA, in reference with DNA content in 1n and 2n embryos, suggests that the level of rRNA synthesis per DNA unit in haploids is twice that in diploids whereas, in reference per cell, the same amount of ribosomes is synthesized both in haploids and diploids. The data obtained show that the amount of rRNAs synthesized in the loach embryogenesis does not depend on ploidy.     

Hormonal stimulation of ribosomal RNA synthesis in Achlya ambisexualis.

The experiments reported show that one of the early effects of the steroid sex hormone antheridiol is on the synthesis of rRNA and ribosomes. This is demonstrated in hormone treated cultures of Achlya ambisexualis (strain E87) by an enhancement of the incorporation of [3H]uridine into 26S and 18S rRNA and by an increase in measurable amounts of ribosomes per milligram dry weight of mycelium. Furthermore, since the hormone does not significantly alter the pool size or the specific activity of uridine triphosphate, this effect appears to represent an increased rate of RNA synthesis.     

Effect of food deprivation and hypophysectomy on in vitro protein synthesis by membrain-bound and free hepatic ribosomes.

The protein synthetic activities of membrane-bound and free hepatic ribosomes isolated from intact rats fed ad libitum, and normal rats subjected to food restriction to match that of hypophysectomised (Hx) rats were compared to the in vitro protein synthetic capacity of hepatic ribosomes isolated from Hx rats. Hypophysectomy resulted in decreased protein synthetic ability of bound ribosomes, whether protein synthesis was directed by endogenous messenger RNA (mRNA) (p less than 0.05) or by polyuridylic acid (polyU) (p less than 0.01). In contrast, the protein synthetic activity of free hepatic ribosomes from Hx rats was reduced when protein synthesis was directed by endogenous mRNA (p less than 0.05) but, when polyU was substituted as the messenger, the protein synthetic activity of these free ribosomes was equal to that of control rats. On the other hand the effects of food restriction on hepatic ribosomal function could be clearly differentiated from the effects observed following hypophysectomy. Thus, the reduced protein synthetic activity of hepatic bound ribosomes isolated from food restricted normal rats was not demonstrable, when polyU was used to direct protein synthesis. Further, food restriction had no effect on the protein synthetic activity of free hepatic ribosomes, and this was true when protein synthesis was directed by either endogenous or artificial messenger. It is concluded that hypophysectomy reduces the protein synthetic ability of both bound and free hepatic ribosomes, and this change of ribosomal function of Hx rats cannot be attributed to their decreased food intake.     

An essential function of ribosomal protein S1 in messenger ribonucleic acid translation

A gentle and efficient method for selectively removing S1 from ribosomes was developed: the S1-free translation system prepared from such ribosomes is stimulated 10-20-fold (depending on the mRNA) by a stoichiometric amount of added purified S1. With this system, we examined the activity of mono- and di-N-ethylmaleimide derivatives of S1 in protein synthesis using synthetic and natural mRNAs and electrophoretic analysis of the translation products. The results show that ribosomes containing such modified S1's are functionally active although at a somewhat lower level (50-80% activity). Since treatment of S1 with N-ethylmaleimide abolishes the helix-destabilizing ability of S1, we conclude that this ability is not primarily responsible for S1's biological function. A new model for the role of S1 is proposed on the basis of the physical, structural, and RNA-binding properties of S1.