Changes in RNA in relation to growth of the fibroblast: II. The lifetime of mRNA,rRNA, and tRNA in resting and growing cells

The stabilities of the principal classes of RNA have been studied in resting and exponentially growing mouse fibroblast lines 3T6 and 3T3. Cytoplasmic mRNA, labeled with tritiated uridine and isolated by virtue of its poly A content, is equally stable in resting and growing cells, displaying a half-life of about 9 hr. We conclude that the accumulation of poly A(+) mRNA during transition from resting to growing state is due not to an increase in its stability, but to an increase in its rate of formation.The stability of cytoplasmic rRNA was measured after labeling with ³H-methyl-methionine. In agreement with the results of previous studies, we found that rRNA is stable in growing cells and unstable in resting cells. Quite unexpectedly, the 18S and 28S rRNA of resting cultures were found to differ appreciably in turnover rate. In both 3T6 and 3T3, the half-life of 28S RNA is about 50 hr, and that of 18S RNA about 72 hr. For this reason, though growing cells should synthesize the two ribosomal subunits in equal numbers, resting cells should synthesize more of the larger subunits than of the smaller. tRNA is unstable under all conditions. Its half-life is 36 hr in resting cells and about 60 hr in growing cells.     

WBSCR22/Merm1 is required for late nuclear pre-ribosomal RNA processing and mediates N7-methylation of G1639 in human 18S rRNA

Ribosomal (r)RNAs are extensively modified during ribosome synthesis and their modification is required for the fidelity and efficiency of translation. Besides numerous small nucleolar RNA-guided 2′-O methylations and pseudouridinylations, a number of individual RNA methyltransferases are involved in rRNA modification. WBSCR22/Merm1, which is affected in Williams–Beuren syndrome and has been implicated in tumorigenesis and metastasis formation, was recently shown to be involved in ribosome synthesis, but its molecular functions have remained elusive. Here we show that depletion of WBSCR22 leads to nuclear accumulation of 3′-extended 18SE pre-rRNA intermediates resulting in impaired 18S rRNA maturation. We map the 3′ ends of the 18SE pre-rRNA intermediates accumulating after depletion of WBSCR22 and in control cells using 3′-RACE and deep sequencing. Furthermore, we demonstrate that WBSCR22 is required for N⁷-methylation of G1639 in human 18S rRNA in vivo. Interestingly, the catalytic activity of WBSCR22 is not required for 18S pre-rRNA processing, suggesting that the key role of WBSCR22 in 40S subunit biogenesis is independent of its function as an RNA methyltransferase.     

ERB1, the yeast homolog of mammalian Bop1, is an essential gene required for maturation of the 25S and 5.8S ribosomal RNAs

We have recently shown that the mammalian nucleolar protein Bop1 is involved in synthesis of the 28S and 5.8S ribosomal RNAs (rRNAs) and large ribosome subunits in mouse cells. Here we have investigated the functions of the Saccharomyces cerevisiae homolog of Bop1, Erb1p, encoded by the previously uncharacterized open reading frame YMR049C. Gene disruption showed that ERB1 is essential for viability. Depletion of Erb1p resulted in a loss of 25S and 5.8S rRNAs synthesis, while causing only a moderate reduction and not a complete block in 18S rRNA formation. Processing analysis showed that Erb1p is required for synthesis of 7S pre-rRNA and mature 25S rRNA from 27SB pre-rRNA. In Erb1p-depleted cells these products of 27SB processing are largely absent and 27SB pre-rRNA is under-accumulated, apparently due to degradation. In addition, depletion of Erb1p caused delayed processing of the 35S pre-rRNA. These findings demonstrate that Erb1p, like its mammalian counterpart Bop1, is required for formation of rRNA components of the large ribosome particles. The similarities in processing defects caused by functional disruption of Erb1p and Bop1 suggest that late steps in maturation of the large ribosome subunit rRNAs employ mechanisms that are evolutionarily conserved throughout eukaryotes.     

Properties of total and poly(A) RNA from exponentially growing and from resting cultures of Tetrahymena thermophila

Total RNA was extracted from exponentially growing and resting cultures of Tetrahymena thermophila. Poly(A)-containing RNA was separated by oligo(dT) affinity chromatography. The following characteristics of both preparations were studied: the changes in sedimentation profiles of newly made RNAs as a function of time, the length of the poly(A) segment, and the capacity of polyadenylated mRNA to code for proteins in vitro. The time-dependent sedimentation profiles of both kinds of RNA changed strikingly with the modes of growth: poly(A)⁺ RNA from heterodisperse in log phase into uniformly and slowly sedimenting in stationary phase, and total RNA from typical ribosomal into heterodisperse with a maximum in the pre-rRNA region. As revealed by the temperature regime developed by Ihle et al. [1] about 80% of all poly(A) RNA molecules carried a poly(A) stretch of less than 50 nucleotides. There was a tendency of the class 0–20 nucleotides to become more frequent in the stationary phase. The polyadenylated mRNAs were translated in the reticulocyte in vitro system. At least one protein of about 26 000 D was translated only in presence of mRNA of growing cells and not with that from resting cells. Another of 3 500 D was found only with mRNA from resting cultures. Three other proteins were translated with different rates according to the culture growth rate. The results demonstrate that the RNA isolated from different phases of culture growth have different dynamic as well as coding properties related to rate of cell multiplication.     

Coevolution of ribosomal RNA expansion segment 7L and assembly factor Noc2p specializes the ribosome biogenesis pathway between Saccharomyces cerevisiae and Candida albicans

Ribosomes of different species share an evolutionarily conserved core, exhibiting flexible shells formed partially by the addition of species-specific ribosomal RNAs (rRNAs) with largely unexplored functions. In this study, we showed that by swapping the Saccharomyces cerevisiae 25S rRNA genes with non-S. cerevisiae homologs, species-specific rRNA variations caused moderate to severe pre-rRNA processing defects. Specifically, rRNA substitution by the Candida albicans caused severe growth defects and deficient pre-rRNA processing. We observed that such defects could be attributed primarily to variations in expansion segment 7L (ES7^L) and could be restored by an assembly factor Noc2p mutant (Noc2p-K384R). We showed that swapping ES7^L attenuated the incorporation of Noc2p and other proteins (Erb1p, Rrp1p, Rpl6p and Rpl7p) into pre-ribosomes, and this effect could be compensated for by Noc2p-K384R. Furthermore, replacement of Noc2p with ortholog from C. albicans could also enhance the incorporation of Noc2p and the above proteins into pre-ribosomes and consequently restore normal growth. Taken together, our findings help to elucidate the roles played by the species-specific rRNA variations in ribosomal biogenesis and further provide evidence that coevolution of rRNA expansion segments and cognate assembly factors specialized the ribosome biogenesis pathway, providing further insights into the function and evolution of ribosome.     

Identification of the binding site of Rlp7 on assembling 60S ribosomal subunits in Saccharomyces cerevisiae

Eukaryotic ribosome assembly requires over 200 assembly factors that facilitate rRNA folding, ribosomal protein binding, and pre-rRNA processing. One such factor is Rlp7, an essential RNA binding protein required for consecutive pre-rRNA processing steps for assembly of yeast 60S ribosomal subunits: exonucleolytic processing of 27SA₃ pre-rRNA to generate the 5′ end of 5.8S rRNA and endonucleolytic cleavage of the 27SB pre-rRNA to initiate removal of internal transcribed spacer 2 (ITS2). To better understand the functions of Rlp7 in 27S pre-rRNA processing steps, we identified where it crosslinks to pre-rRNA. We found that Rlp7 binds at the junction of ITS2 and the ITS2-proximal stem, between the 3′ end of 5.8S rRNA and the 5′ end of 25S rRNA. Consistent with Rlp7 binding to this neighborhood during assembly, two-hybrid and affinity copurification assays showed that Rlp7 interacts with other assembly factors that bind to or near ITS2 and the proximal stem. We used in vivo RNA structure probing to demonstrate that the proximal stem forms prior to Rlp7 binding and that Rlp7 binding induces RNA conformational changes in ITS2 that may chaperone rRNA folding and regulate 27S pre-rRNA processing. Our findings contradict the hypothesis that Rlp7 functions as a placeholder for ribosomal protein L7, from which Rlp7 is thought to have evolved in yeast. The binding site of Rlp7 is within eukaryotic-specific RNA elements, which are not found in bacteria. Thus, we propose that Rlp7 coevolved with these RNA elements to facilitate eukaryotic-specific functions in ribosome assembly and pre-rRNA processing.