Active site in RrmJ,a heat shock-induced methyltransferase

The heat shock protein RrmJ (FtsJ), highly conserved from eubacteria to eukarya, is responsible for the 2'-O-ribose methylation of the universally conserved base U2552 in the A-loop of the 23 S rRNA. Absence of this methylation, which occurs late in the maturation process of the ribosome, appears to cause the destabilization and premature dissociation of the 50 S ribosomal subunit. To understand the mechanism of 2'-O-ribose methyltransfer reactions, we characterized the enzymatic parameters of RrmJ and conducted site-specific mutagenesis of RrmJ. A structure based sequence alignment with VP39, a structurally related 2'-O-methyltransferase from vaccinia virus, guided our mutagenesis studies. We analyzed the function of our RrmJ mutants in vivo and characterized the methyltransfer reaction of the purified proteins in vitro. The active site of RrmJ appears to be formed by a catalytic triad consisting of two lysine residues, Lys-38 and Lys-164, and the negatively charged residue Asp-124. Another highly conserved residue, Glu-199, that is present in the active site of RrmJ and VP39 appears to play only a minor role in the methyltransfer reaction in vivo. Based on these results, a reaction mechanism for the methyltransfer activity of RrmJ is proposed.     

Interference probing of rRNA with snoRNPs: a novel approach for functional mapping of RNA in vivo

Synthesis of eukaryotic ribosomal RNAs (rRNAs) includes methylation of scores of nucleotides at the 2'-O-ribose position (Nm) by small nucleolar RNP complexes (snoRNPs). Sequence specificity is provided by the snoRNA component through base-pairing of a guide sequence with rRNA. Here, we report that methylation snoRNPs can be targeted to many new sites in yeast rRNA, by providing the snoRNA with a novel guide sequence, and that in some cases growth and translation activity are strongly impaired. Novel snoRNAs can be expressed individually or by a unique library strategy that yields guide sequences specific for a large target region. Interference effects were observed for sites in both the small and large subunits, including the reaction center region. Targeting guide RNAs to nucleotides flanking the sensitive sites caused little or no defect, indicating that methylation is responsible for the interference rather than a simple antisense effect or misguided chaperone function. To our knowledge, this is the only approach that has been used to mutagenize the backbone of rRNA in vivo.     

A paradigm for local conformational control of function in the ribosome: binding of ribosomal protein S19 to Escherichia coli 16S rRNA in the presence of S7 is required for methylation of m2G966 and blocks methylation of m5C967 by their respective methyltransferases.

We have partially purified two 16S rRNA-specific methyltransferases, one of which forms m2G966 (m2G MT), while the other one makes m5C967 (m5C MT). The m2G MT uses unmethylated 30S subunits as a substrate, but not free unmethylated 16S rRNA, while the m5C MT functions reciprocally, using free rRNA but not 30S subunits (Nègre, D., Weitzmann, C. and Ofengand, J. (1990) UCLA Symposium: Nucleic Acid Methylation (Alan Liss, New York), pp. 1-17). We have now determined the basis for this unusual inverse specificity at adjacent nucleotides. Binding of ribosomal proteins S7, S9, and S19 to unmodified 16S rRNA individually and in all possible combinations showed that S7 plus S19 were sufficient to block methylation by the m5C MT, while simultaneously inducing methylation by the m2G MT. A purified complex containing stoichiometric amounts of proteins S7, S9, and S19 bound to 16S rRNA was isolated and shown to possess the same methylation properties as 30S subunits, that is, the ability to be methylated by the m2G MT but not by the m5C MT. Since binding of S19 requires prior binding of S7, which had no effect on methylation when bound alone, we attribute the switch in methylase specificity solely to the presence of RNA-bound S19. Single-omission reconstitution of 30S subunits deficient in S19 resulted in particles that could not be efficiently methylated by either enzyme. Thus while binding of S19 is both necessary and sufficient to convert 16S rRNA into a substrate of the m2G MT, binding of either S19 alone or some other protein or combination of proteins to the 16S rRNA can abolish activity of the m5C MT. Binding of S19 to 16S rRNA is known to cause local conformational changes in the 960-975 stem-loop structure surrounding the two methylated nucleotides (Powers, T., Changchien, L.-M., Craven, G. and Noller, H.F. (1988) J. Mol. Biol. 200, 309-319). Our results show that the two ribosomal RNA MTs studied in this work are exquisitely sensitive to this small but nevertheless functionally important structural change.     

Purification and properties of a ribosomal protein methylase from Eschericha coli Q13.

Ribosomal protein methylase has been purified from Escherichia coli strain Q13 using methyl-deficient 50S subunits as substrates. The purified enzyme (or enzyme complex) which is devoid of rRNA methylating activity is quite stable and has a pH optimum around 8.0. The Km for S-adenosyl-L-methionine is 3.2 muM. The molecular weight of the enzyme is 3.1 X 10(4); minor methylating activity was also detected for protein peaks with molecular weights of 1.7 X 10(4) and 5.6 X 10(4). Protein L11 is the major protein methylated by the purified enzyme. Product analysis revealed the presence of N epislon-trimethyllysine, a methylated neutral amino acid(s) previously observed in protein L11 and N epislon-monomethyllysine. Free ribosomal proteins were much better substrates for the methylation, indicating that methylation of 50S ribosomal proteins can occur before the complete assembly of the 50S ribosomal subunit.     

Exploration of pairing constraints identifies a 9 base-pair core within box C/D snoRNA-rRNA duplexes

2'-O-ribose methylation of eukaryotic ribosomal RNAs is guided by RNA duplexes consisting of rRNA and box C/D small nucleolar (sno)RNA sequences, the methylated sites invariably mapping five positions apart from the D box. Here we have analyzed the RNA duplex pairing constraints by investigating the features of 415 duplexes from the fungus, plant and animal kingdoms, and the evolution of those duplexes within the 124 sets they group into. The D-box upstream 1st and >or=15th positions consist of Watson-Crick base-pairs, G:U base-pairs and mismatched bases with ratios close to random assortments; these positions display single base differences in >60% of the RNA duplex sets. The D-box upstream 2nd to 11th positions have >90% Watson-Crick base-pairs; they display single base mutations with a U-shaped distribution of lower values of 0% and 1.6% at the methylated site 5th and 4th positions, and double compensatory mutations leading to new Watson-Crick base-pairs with an inverted U-shaped distribution of higher values at the 8th to 11th positions. Half of the single mutations at the 3rd to 11th positions resulted in G:U base-pairing, mainly through A-->G mutations in the rRNA strands and C-->T mutations in the snoRNA strands. Double compensatory mutations at the 3rd to 11th positions are extremely frequent, representing 36% of all mutations; they frequently arose from an A-->G mutation in the rRNA strands followed by a T-->C mutation in the snoRNA strands. Differences in the mutational pathways through which the rRNA and snoRNA strand evolved must be related to differences in the rRNA and snoRNA copy number and gene organization. Altogether these data identify the D-box upstream 3rd to 11th positions as box C/D snoRNA-rRNA duplex cores. The impact of the pairing constraints on the evolution of the 9 base-pair RNA duplex cores is discussed.     

Nop2p is required for pre-rRNA processing and 60S ribosome subunit synthesis in yeast.

To investigate the function of the nucleolar protein Nop2p in Saccharomyces cerevisiae, we constructed a strain in which NOP2 is under the control of a repressible promoter. Repression of NOP2 expression lengthens the doubling time of this strain about fivefold and reduces steady-state levels of 60S ribosomal subunits, 80S ribosomes, and polysomes. Levels of 40S subunits increase as the free pool of 60S subunits is reduced. Nop2p depletion impairs processing of the 35S pre-rRNA and inhibits processing of 27S pre-rRNA, which results in lower steady-state levels of 25S rRNA and 5.8S rRNA. Processing of 20S pre-rRNA to 18S rRNA is not significantly affected. Processing at sites A2, A3, B1L, and B1S and the generation of 5' termini of different pre-rRNA intermediates appear to be normal after Nop2p depletion. Sequence comparisons suggest that Nop2p may function as a methyltransferase. 2'-O-ribose methylation of the conserved site UmGm psi UC2922 is known to take place during processing of 27S pre-rRNA. Although Nop2p depletion lengthens the half-life of 27S pre-RNA, methylation of UmGm psi UC2922 in 27S pre-rRNA is low during Nop2p depletion. However, methylation of UmGm psi UC2922 in mature 25S rRNA appears normal. These findings provide evidence for a close interconnection between methylation at this conserved site and the processing step that yields the 25S rRNA.     

Substrate binding analysis of the 23S rRNA methyltransferase RrmJ

The 23S rRNA methyltransferase RrmJ (FtsJ) is responsible for the 2'-O methylation of the universally conserved U2552 in the A loop of 23S rRNA. This 23S rRNA modification appears to be critical for ribosome stability, because the absence of functional RrmJ causes the cellular accumulation of the individual ribosomal subunits at the expense of the functional 70S ribosomes. To gain insight into the mechanism of substrate recognition for RrmJ, we performed extensive site-directed mutagenesis of the residues conserved in RrmJ and characterized the mutant proteins both in vivo and in vitro. We identified a positively charged, highly conserved ridge in RrmJ that appears to play a significant role in 23S rRNA binding and methylation. We provide a structural model of how the A loop of the 23S rRNA binds to RrmJ. Based on these modeling studies and the structure of the 50S ribosome, we propose a two-step model where the A loop undocks from the tightly packed 50S ribosomal subunit, allowing RrmJ to gain access to the substrate nucleotide U2552, and where U2552 undergoes base flipping, allowing the enzyme to methylate the 2'-O position of the ribose.     

Hyper-expression of small nucleolar RNAs (snoRNAs) in female inflorescences of hazelnut (Corylus avellana L.) supports rRNA aggregation in vitro

Under certain in vitro (salt and temperature) conditions rRNA aggregation occurs in female inflorescences but not in leaves or pollen RNA preparations from hazelnut (Corylus avellana L.), a species of economic interest. This paper describes experiments addressing an explanation of this phenomenon. The experiments demonstrate that: (i) trans-acting factors induce rRNA aggregate formation in female inflorescences RNA preparations; (ii) these factors support aggregation also of heterologous rRNA; (iii) aggregation is a function of temperature pre-treatment of rRNA and not of source 18S rRNA; (iv) the factors inducing rRNA aggregates are sensitive to RNase; (v) antisense small nucleolar RNAs (snoRNAs) participate in rRNA aggregate formation. snoRNAs are involved in pre-rRNA spacer cleavages, and are required for the two most common types of rRNA modifications: 2'-O-ribose methylation and pseudouridylation. Even though it is questionable whether rRNA aggregation really happens in female inflorescence in vivo, the phenomenon observed in vitro may reflect the abundance of snoRNAs in these reproductive structures. In fact the level of accumulation of three tested snoRNAs, R1, U14 and U3, is much higher in female inflorescence than in leaves or pollen of hazelnut. This finding opens the possibility of studying the role of snoRNAs in tissue development in plants.     

A cluster of methylations in the domain IV of 25S rRNA is required for ribosome stability

In all three domains of life ribosomal RNAs are extensively modified at functionally important sites of the ribosome. These modifications are believed to fine-tune the ribosome structure for optimal translation. However, the precise mechanistic effect of modifications on ribosome function remains largely unknown. Here we show that a cluster of methylated nucleotides in domain IV of 25S rRNA is critical for integrity of the large ribosomal subunit. We identified the elusive cytosine-5 methyltransferase for C2278 in yeast as Rcm1 and found that a combined loss of cytosine-5 methylation at C2278 and ribose methylation at G2288 caused dramatic ribosome instability, resulting in loss of 60S ribosomal subunits. Structural and biochemical analyses revealed that this instability was caused by changes in the structure of 25S rRNA and a consequent loss of multiple ribosomal proteins from the large ribosomal subunit. Our data demonstrate that individual RNA modifications can strongly affect structure of large ribonucleoprotein complexes.     

Methyltransferase that modifies guanine 966 of the 16 S rRNA: functional identification and tertiary structure

N(2)-Methylguanine 966 is located in the loop of Escherichia coli 16 S rRNA helix 31, forming a part of the P-site tRNA-binding pocket. We found yhhF to be a gene encoding for m(2)G966 specific 16 S rRNA methyltransferase. Disruption of the yhhF gene by kanamycin resistance marker leads to a loss of modification at G966. The modification could be rescued by expression of recombinant protein from the plasmid carrying the yhhF gene. Moreover, purified m(2)G966 methyltransferase, in the presence of S-adenosylomethionine (AdoMet), is able to methylate 30 S ribosomal subunits that were purified from yhhF knock-out strain in vitro. The methylation is specific for G966 base of the 16 S rRNA. The m(2)G966 methyltransferase was crystallized, and its structure has been determined and refined to 2.05A(.) The structure closely resembles RsmC rRNA methyltransferase, specific for m(2)G1207 of the 16 S rRNA. Structural comparisons and analysis of the enzyme active site suggest modes for binding AdoMet and rRNA to m(2)G966 methyltransferase. Based on the experimental data and current nomenclature the protein expressed from the yhhF gene was renamed to RsmD. A model for interaction of RsmD with ribosome has been proposed.     

Ribosomal RNA guanine-(N2)-methyltransferases and their targets

Five nearly universal methylated guanine-(N2) residues are present in bacterial rRNA in the ribosome. To date four out of five ribosomal RNA guanine-(N2)-methyltransferases are described. RsmC(YjjT) methylates G1207 of the 16S rRNA. RlmG(YgjO) and RlmL(YcbY) are responsible for the 23S rRNA m²G1835 and m²G2445 formation, correspondingly. RsmD(YhhF) is necessary for methylation of G966 residue of 16S rRNA. Structure of Escherichia coli RsmD(YhhF) methyltransferase and the structure of the Methanococcus jannaschii RsmC ortholog were determined. All ribosomal guanine-(N2)-methyltransferases have similar AdoMet-binding sites. In relation to the ribosomal substrate recognition, two enzymes that recognize assembled subunits are relatively small single domain proteins and two enzymes that recognize naked rRNA are larger proteins containing separate methyltransferase- and RNA-binding domains. The model for recognition of specific target nucleotide is proposed. The hypothetical role of the m²G residues in rRNA is discussed.     

The 2'-O-ribose methyltransferase for cap 1 of spliced leader RNA and U1 small nuclear RNA in Trypanosoma brucei

mRNA cap 1 2'-O-ribose methylation is a widespread modification that is implicated in processing, trafficking, and translational control in eukaryotic systems. The eukaryotic enzyme has yet to be identified. In kinetoplastid flagellates trans-splicing of spliced leader (SL) to polycistronic precursors conveys a hypermethylated cap 4, including a cap 0 m7G and seven additional methylations on the first 4 nucleotides, to all nuclear mRNAs. We report the first eukaryotic cap 1 2'-O-ribose methyltransferase, TbMTr1, a member of a conserved family of viral and eukaryotic enzymes. Recombinant TbMTr1 methylates the ribose of the first nucleotide of an m7G-capped substrate. Knockdowns and null mutants of TbMTr1 in Trypanosoma brucei grow normally, with loss of 2'-O-ribose methylation at cap 1 on substrate SL RNA and U1 small nuclear RNA. TbMTr1-null cells have an accumulation of cap 0 substrate without further methylation, while spliced mRNA is modified efficiently at position 4 in the absence of 2'-O-ribose methylation at position 1; downstream cap 4 methylations are independent of cap 1. Based on TbMTr1-green fluorescent protein localization, 2'-O-ribose methylation at position 1 occurs in the nucleus. Accumulation of 3'-extended SL RNA substrate indicates a delay in processing and suggests a synergistic role for cap 1 in maturation.     

Neurospora crassa cytoplasmic ribosomes: cold-sensitive mutant defective in ribosomal ribonucleic acid synthesis.

Experiments were conducted to characterize further the biochemical defects of crib-1 (PJ30201), a coldsensitive mutant strain of Neurospora crassa with a defect in ribosome biosynthesis. The results are as follows. (i) The critical temperature for the expression of the mutant growth and ribosome phenotypes is in the range of 18 to 20 C. (ii) No preferential breakdown of 37S cytoplasmic ribosomal subunits synthesized by crib-1 at 25 C occurs after a shift to 10 C. (iii) Ribosomal subunits synthesized by crib-1 at 25 C function normally in in vivo protein synthesis at 10 C. (iv) Whereas wild type synthesizes both ribosomal subunits in a coordinate manner after either a temperature shift-down (25 to 10 C) of a shift-up (10 to 25 C), noncoordinate synthesis of ribosomal subunits owing to underproduction of 37S subunits occurs in the crib-1 strain immediately after a temperature shift-down. (v) After a shift from 10 to 25 C crib-1 exhibits a 12-h lag before the growth rate and the rate of synthesis of 37S subunits begin to increase significantly. (vi) At 10 C crib-1 synthesizes unequal amounts of 25S and 17S ribosomal ribonucleic acid (rRNA) molecules, resulting from a greatly reduced accumulation of stable 17S rRNA. The mutant phenotypes of crib-1 are proposed to be the result of a defect in rRNA processing.     

Isolation of active polyribosomes from the cytoplasm, mitochondria and chloroplasts of Euglena gracilis

1. A procedure is described for the isolation of intact polyribosomes from the cytoplasm, chloroplasts and mitochondria of Euglena gracilis. 2. All three polyribosomal preparations incorporated labelled amino acids in a system in vitro. The cytoplasmic system was inhibited by chcloheximide but not by chloramphenicol. Both the chloroplast and the mitochondrial systems, however, were inhibited by chloramphenicol but not by cycloheximide. It is shown that mitochondrial polyribosomes, like the polyribosomes from cytoplasm and chloroplasts, can participate directly in protein synthesis without supplementary mRNA being added to the synthesizing system, as in previously reported instances. 3. Sedimentation coefficients were measured for the ribosomes, ribosomal subunits, and rRNA of the cytoplasm, chloroplasts and mitochondria. 4. The G+C content was 55% for cytoplasmic rRNA, 50% for chloroplast rRNA, and 29% for mitochondrial rRNA. 5. The cytoplasmic ribosomal subunits contained a ribonuclease activity that was inhibited by heparin.