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.     

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.     

Substitution of uridine in vivo by the intrinsic photoactivable probe 4-thiouridine in Escherichia coli RNA. Its use for E. coli ribosome structural analysis

In vivo incorporation of the uridine-photoactivable analogue, 4-thiouridine, into the ribosomal RNA of an Escherichia coli pyrD strain has been demonstrated. It is highly dependent on the exogenous uridine and 4-thiouridine concentrations as well as on temperature. We have defined conditions allowing the substitution of 13 +/- 2% of the uridine residues in bulk RNA by 4-thiouridine. On a high-Mg2+ sucrose gradient, 33 +/- 3% of ribonucleic particles sediment as 70S ribosomes, the remaining being in the form of non-associated 50S and 30S particles containing immature rRNA. The thiolated 70S ribosomes tolerate a 4-5% substitution level (40 thiouridine molecules/particle). Surprisingly, 3-4% of ribosomal proteins, about two protein molecules/particle, were spontaneously covalently bound to 4-thiouridine-substituted rRNA. Specific 366-nm photoactivation increased this proportion to 10-12%, i.e. up to six or seven ribosomal protein molecules/particle. The photochemical cross-linking proceeds with apparent first-order kinetics with a quantum yield close to 5 X 10(-3). Although extensive photodynamic breakage of rRNA occurs under aerobic conditions, both the kinetics and yield of ribosomal protein cross-linking were independent of oxygenation conditions. The thiolated (4.5%) 70S ribosomes allowed the poly(U)-directed poly(Phe)synthesis at 48% the control rate. Photoactivation decreased this activity to 28% and 10% when performed under nitrogen and in aerated conditions, respectively.     

The role of ribosomal ribonucleic acid in the structure and function of mammalian brain ribosomes

In order to resolve the functional role of intact rRNA in polypeptide chain elongation mouse brain ribosomes were treated with dilute pancreatic or T(1) RNAase (ribonuclease). After RNAase treatment, several physical-chemical properties as well as the functional activity of the ribosomes were measured. RNAase treatment resulted in the extensive hydrolysis of both 18S and 28S rRNA; however, the sedimentation properties of mono-ribosomes were unaltered and more than 90% of the relatively low-molecular-weight RNA fragments remained associated with ribosome particles. Analysis of the ability of RNAase-treated ribosomes to participate in cell-free protein synthesis showed that ribosomes with less than 2% intact rRNA retained more than 85% of their activity in polyphenylalanine incorporation. Proof that the incorporation of phenylalanine by ribosomes with hydrolysed rRNA actually represented active translocation was obtained by the effective inhibition of incorporation by diphtheria toxin. In addition, the oligopeptide products of protein synthesis could be identified by BD (benzoylated diethylaminoethyl)-cellulose column chromatography. Analysis of the size distribution of oligopeptides synthesized by normal and RNAase-treated ribosomes showed no significant differences which indicated that there was no change in the proportion of ribosomes engaged in protein synthesis. Thus strong RNA-protein and protein-protein interactions must serve to maintain the functional integrity of ribosomes even when the rRNA is extensively degraded. The ability of the enzyme-treated ribosomes to efficiently incorporate amino acids clearly demonstrated that ;intact' rRNA is not required for protein-synthetic activity.     

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.     

Topography of 5.8 S rRNA in rat liver ribosomes. Identification of diethyl pyrocarbonate-reactive sites

The topography of 5.8 rRNA in rat liver ribosomes has been examined by comparing diethyl pyrocarbonate-reactive sites in free 5.8 S RNA, the 5.8 S-28 rRNA complex, 60 S subunits, and whole ribosomes. The ribosomal components were treated with diethyl pyrocarbonate under salt and temperature conditions which allow cell-free protein synthesis; the 5.8 S rRNA was extracted, labeled in vitro, chemically cleaved with aniline, and the fragments were analyzed by rapid gel-sequencing techniques. Differences in the cleavage patterns of free and 28 S or ribosome-associated 5.8 S rRNA suggest that conformational changes occur when this molecule is assembled into ribosomes. In whole ribosomes, the reactive sites were largely restricted to the "AU-rich" stem and an increased reactivity at some of the nucleotides suggested that a major change occurs in this region when the RNA interacts with ribosomal proteins. The reactivity was generally much less restricted in 60 S subunits but increased reactivity in some residues was also observed. The results further indicate that in rat ribosomes, the two -G-A-A-C- sequences, putative binding sites for tRNA, are accessible in 60 S subunits but not in whole ribosomes and suggest that part of the molecule may be located in the ribosomal interface. When compared to 5 S rRNA, the free 5.8 S RNA molecule appears to be generally more reactive with diethyl pyrocarbonate and the cleavage patterns suggest that the 5 S RNA molecule is completely restricted or buried in whole ribosomes.     

The ribosomal A site-bound sense and stop codons are similarly positioned towards the A1823-A1824 dinucleotide of the 18S ribosomal RNA

Positioning of the mRNA codon towards the 18S ribosomal RNA in the A site of human 80S ribosomes has been studied applying short mRNA analogs containing either the stop codon UAA or the sense codon UCA with a perfluoroaryl azide group at the uridine residue. Bound to the ribosomal A site, a modified codon crosslinks exclusively to the 40S subunits under mild UV irradiation. This result is inconsistent with the hypothesis [Ivanov et al. (2001) RNA 7, 1683-1692] which requires direct contact between the large rRNA and the stop codon of the mRNA as recognition step at translation termination. Both sense and stop codons crosslink to the same A1823/A1824 invariant dinucleotide in helix 44 of 18S rRNA. The data point to the resemblance between the ternary complexes formed at elongation (sense codon.aminoacyl-tRNA.AA dinucleotide of 18S rRNA) and termination (stop codon.eRF1.AA dinucleotide of 18S rRNA) steps of protein synthesis and support the view that eRF1 may be considered as a functional mimic of aminoacyl-tRNA.     

The kinetics of the incorporation of newly synthesized ribonucleic acid and protein into the ribosomes of the uterus of the oestrogen-stimulated immature rat.

The kinetics of the synthesis of the components of polyribosomes was investigated in the uterus of the immature rat responding to the administration of oestradiol-17 beta. The hormone brings about a rapid stimulation of the association of newly synthesized mRNA with uterine ribosomes, which is maximal 2-4 h after oestradiol administration and causes the aggregation of pre-existing ribosomes into polyribosomes. Despite the striking stimulation of rRNA synthesis 2-4 h after hormone treatment [Knowler & Smellie (1971) Biochem. J. 125, 605-614], the accumulation of new rRNA into ribosomes does not reach a peak until 12 h after administration. At this time, the incorporation of new ribosomal protein is also maximal. A second peak of incorporation of newly synthesized mRNA into polyribosomes follows the peak of ribosome synthesis and coincides with the oestrogen-activated synthesis of DNA.     

The conserved 5 S rRNA complement to tRNA is not required for translation of natural mRNA

We have tested a putative base-paired interaction between the conserved GT psi C sequence of tRNA and the conserved GAAC47 sequence of 5 S ribosomal RNA by in vitro protein synthesis using ribosomes containing deletions in this region of 5 S rRNA. Ribosomes reconstituted with 5 S rRNA possessing a single break between residues 41 and 42, deletion of residues 42-46, or deletion of residues 42-52 were tested for their ability to translate phage MS2 RNA. Initiator tRNA binding, aminoacyl-tRNA binding, ppGpp synthesis, and miscoding were also tested. All of the measured functions could be carried out by ribosomes carrying the deleted 5 S rRNAs. The sizes and relative amounts of the polypeptides synthesized by MS2 RNA-programmed ribosomes were identical whether or not the 5 S RNA contained deletions. Aminoacyl-tRNA binding and miscoding were essentially unaffected. Significant reduction in ApUpG (but not poly(A,U,G) or MS2 RNA)-directed fMet-tRNA binding and ppGpp synthesis were observed, particularly in the case of the larger (residues 42-52) deletion. We conclude that if tRNA and 5 S rRNA interact in this fashion, it is not an obligatory step in protein synthesis.     

Wasting of 18 S ribosomal RNA by human myeloma cells cultured in adenosine.

When human myeloma cells are pulsed for one hour with 3H-uridine and chased for six hours in fresh medium containing unlabeled uridine, the processing of 45 S rRNA precursor into the stable 28 S and 18 S rRNA components can be followed. However, when the cells are chased in exogenous adenosine instead of uridine, the accumulation of 18 S rRNA is selectively inhibited. Cells pulsed with 3H-adenosine and chased in the absence of exogenous nucleosides exhibit normal rRNA precursor processing, while cells pulsed simultaneously with 3H-uridine and 3H-adenosine and chased with uridine and adenosine are deficient in labeled 18 S rRNA. Consequently, the inhibition of 18 S rRNA accumulation by adenosine is not an artifact of labeling nor is it relieved by an equal molar concentration of uridine. The wasting of 18 S rRNA in human myeloma cells is similar to that reported to occur in normal lymphocytes during the quiescent state.     

Uridine 5'-phosphate photohydrate formation in irradiated Escherichia coli 30S ribosomes: photochemistry and relation to ribonucleic acid-protein cross-linking

Irradiation of aqueous buffered solutions of Escherichia coli 30S ribosomes with doses of 254-nm radiation greater than 10(19) quanta causes formation of uridine 5'-phosphate (UMP) photohydrates in ribosomal 16S RNA (rRNA). The number of molecules of UMP photohydrate formed at doses less than 2 x 10(20) quanta is linearly dependent on dose of absorbed 254-nm radiation. Maximum UMP photohydrate formation is dependent on initial ribosome concentration. When solutions containing 1 A260 unit of 30S ribosomes/mL were irradiated with greater than 2 x 10(20) quanta of 254-nm radiation, maximum photohydrate formation was equal to 47 residues/ribosome. Irradiation of solutions containing 2 A260 units/mL with greater than 7 x 10(20) quanta caused formation of 102 UMP photohydrates/ribosome. These values correspond to conversion of either 15 or 33%, respectively, of the total UMP content of 30S ribosome 16S rRNA to photohydrates. Target theory analysis of UMP photohydration in 30S ribosomes showed that UMP photohydrates are formed by single-hit kinetics from two photochemically distinct precursors. Of the total 16S rRNA UMP residues, 10% was included in the most rapidly (low dose) reacting fraction. The respective photohydration cross sections are 0.014 (low dose) and 0.0095 cm2/muEinstein (high dose) for ribosome solutions containing 2 A260 units/mL. UMP photohydrate content of irradiated 30S ribosomes was compared with that of previous data for the extent of RNA-protein cross-linking at equivalent doses of absorbed 254-nm radiation. This comparison showed that at least two UMP photohydrates form per RNA-protein cross-linking event in 30S ribosomes irradiated with a dose of 254-nm radiation (1.5 x 10(19) quanta), which causes cross-linking of only three ribosomal proteins to 16S rRNA.     

Feedback regulation of rRNA synthesis. A mutational alteration in the anti-Shine-Dalgarno region of the 16 S rRNA gene abolishes regulation

It was shown that induction of rRNA (and ribosome) synthesis from the lambda PL promoter/operator by temperature shift-up causes a repression of rRNA and tRNA synthesis from chromosomal genes. We have carried out experiments using a similar conditional rRNA gene expression system in which a mutational alteration was introduced in the anti-Shine-Dalgarno region at the 3'-end of the 16 S rRNA gene. It was found that the repression observed with the wild-type gene was largely abolished by the mutation. It appears that ribosomes inefficient in translational initiation are unable to cause feedback regulation of rRNA synthesis. It is suggested that the cell regulates rRNA (and tRNA) synthesis by monitoring the production of ribosomes, and that this monitoring is apparently carried out through their activity in the initiation (and perhaps subsequent steps) of translation.     

Post-transcriptional regulation of ribosome accumulation during myoblast differentiation

The synthesis, accumulation and stability of rRNA were examined in embryonic quail myoblasts differentiating in cell culture. Quail myoblasts initially divide rapidly in culture, and accumulate 28S and 18S rRNA and ribosomes at a rate which maintains a constant ribosome content during cell division. After these myoblasts fuse, cell division ceases and ribosomes accumulate in fibers, but at a reduced rate which is only one fourth that in dividing myoblasts. Measurements of rRNA stability by 3H-methyl-methionine pulse-chase analysis show that 28S and 18S rRNA formed by fibers turn over with half-lives of 45 hr, and rRNA formed by myoblasts remains stable until fusion and then also turns over in fibers. Turnover of rRNA in fibers accounts for only half the reduction in ribosome accumulation following myoblast fusion. Measurements of the incorporation of 3H-adenosine into rRNA and ATP pools show that the rates of synthesis of rRNA precursor do not decrease after myoblast fuse, but half the rRNA molecules synthesized by fibers are degraded during processing. Degradation of rRNA during processing reduces the rate of formation of 28S and 18S rRNA, and together with rRNA turnover quantitatively accounts for the reduced rate of ribosome accumulation in fibers.     

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.     

Structure of the ribosome-associated 5.8 S ribosomal RNA

The structure of the 5.8 S ribosomal RNA in rat liver ribosomes was probed by comparing dimethyl sulfate-reactive sites in whole ribosomes, 60 S subunits, the 5.8 S-28 S rRNA complex and the free 5.8 S rRNA under conditions of salt and temperature that permit protein synthesis in vitro. Differences in reactive sites between the free and both the 28 S rRNA and 60 S subunit-associated 5.8 S rRNA show that significant conformational changes occur when the molecule interacts with its cognate 28 S rRNA and as the complex is further integrated into the ribosomal structure. These results indicate that, as previously suggested by phylogenetic comparisons of the secondary structure, only the "G + C-rich" stem may remain unaltered and a universal structure is probably present only in the whole ribosome or 60 S subunit. Further comparisons with the ribosome-associated molecule indicate that while the 5.8 S rRNA may be partly localized in the ribosomal interface, four cytidylic acid residues, C56, C100, C127 and C128, remain reactive even in whole ribosomes. In contrast, the cytidylic acid residues in the 5 S rRNA are not accessible in either the 60 S subunit or the intact ribosome. The nature of the structural rearrangements and potential sites of interaction with the 28 S rRNA and ribosomal proteins are discussed.     

Template Location on the Human Ribosome: Environment of the mRNA Nucleotide Adjacent to the A-Site Codon on the 3′-Side

The 18S rRNA nucleotides close to the template nucleotide adjacent to the 80S ribosomal A-site codon on the 3′-end (i.e., the nucleotide in position +7 relative to the first nucleotide of the P-site codon) were identified using the affinity crosslinking approach. For this purpose, the photoreactive mRNA analogues with a perfluorophenylazide group attached through various linkers to the uridine C5, 3′-terminal phosphate or guanosine N7 were used. The position of the mRNA analogues on the ribosome was preset using tRNA^Phe, which recognized the phenylalanine codon directed to the P-site. An analysis of the rRNAs isolated from the irradiated complexes of 80S ribosomes showed that all the analogues are almost equally crosslinked to the 18S rRNA nucleotides we attributed to the A-site codon environment: namely, to nucleotides A1823, A1824, and A1825 of the 3′-minidomain and to the 620–630 fragment of the 18S rRNA 5′-domain. In addition, we identified a new component of the mRNA binding site of human ribosomes, nucleotide C1698, belonging to the 18S rRNA 3′-minidomain, using analogues bearing a perfluorophenylazide group on uridine and guanine residues.__________Translated from Bioorganicheskaya Khimiya, Vol. 31, No. 3, 2005, pp. 295–302.Original Russian Text Copyright © 2005 by Demeshkina, Styazhkina, Bulygin, Repkova, Ven’yaminova, Karpova.     

The exosome subunit Rrp43p is required for the efficient maturation of 5.8S, 18S and 25S rRNA.

The Saccharomyces cerevisiae protein Rrp43p co-purifies with four other 3'-->5' exoribonucleases in a complex that has been termed the exosome. Rrp43p itself is similar to prokaryotic RNase PH. Individual exosome subunits have been implicated in the 3' maturation of the 5.8S rRNA found in 60S ribosomes and the 3' degradation of mRNAs. However, instead of being deficient in 60S ribosomes, Rrp43p-depleted cells were deficient in 40S ribosomes. Pulse-chase and steady-state northern analyses of pre-RNA and rRNA levels revealed a significant delay in the synthesis of both 25S and 18S rRNAs, accompanied by the stable accumulation of 35S and 27S pre-rRNAs and the under-accumulation of 20S pre-rRNA. In addition, Rrp43p-depleted cells accumulated a 23S aberrant pre-rRNA and a fragment excised from the 5' ETS. Therefore, in addition to the maturation of 5.8S rRNA, Rrp43p is required for the maturation 18S and 25S rRNA.