Purine N7 groups that are crucial to the interaction of Escherichia coli rnase P RNA with tRNA.

We have detected by nucleotide analog interference mapping (NAIM) purine N7 functional groups in Escherichia coli RNase P RNA that are important for tRNA binding under moderate salt conditions (0.1 M Mg2+, 0.1 M NH4+). The majority of identified positions represent highly or universally conserved nucleotides. Our assay system allowed us, for the first time, to identify c7-deaza interference effects at two G residues (G292, G306). Several c7-deazaadenine interference effects (A62, A65, A136, A249, A334, A351) have also been identified in other studies performed at very different salt concentrations, either selecting for substrate binding in the presence of 0.025 M Ca2+ and 1 M NH4+ or self-cleavage of a ptRNA-RNase P RNA conjugate in the presence of 3 M NH4+ or Na+. This indicates that these N7 functional groups play a key role in the structural organization of ribozyme-substrate and -product complexes. We further observed that a c7-deaza modification at A76 of tRNA interferes with tRNA binding to and ptRNA processing by E. coli RNase P RNA. This finding combined with the strong c7-deaza interference at G292 of RNase P RNA supports a model in which substrate and product binding to E. coli RNase P RNA involves the formation of intermolecular base triples (A258-G292-C75 and G291-G259-A76).

Exploring the minimal substrate requirements for trans-cleavage by RNase P holoenzymes from Escherichia coli and Bacillus subtilis.

We analysed the processing of small bipartite model substrates by Escherichia coli and Bacillus subtilis RNase P and corresponding hybrid enzymes. We demonstrate specific trans-cleavage of a model substrate with a 4 bp stem and a 1 nucleotide (nt) 5' flank, representing to date the smallest mimic of a natural RNase P substrate that could be processed in trans at the canonical RNase P cleavage site. Processing efficiencies decreased up to 5000-fold when the 5' flank was shortened from 3 to 1 nt. Reduction of the 5' flank to 1 nt was more deleterious than reducing the stem from 7 to 4 bp, although the 4 bp duplex formed only transiently, in contrast to the stable 7 bp duplex. These results indicate that the crucial contribution of nt -2 in the single-stranded 5' flank to productive interaction is a general feature of A- and B-type bacterial RNase P enzymes. We also showed that an Rp-phosphorothioate modification at nt -2 interferes with processing. Bacterial RNase P holoenzymes are also capable of cleaving single-stranded RNA oligonucleotides as short as 5 nt, yielding RNase P-specific 5'-phosphate and 3'-OH termini, with measured turnover rates of up to 0.7 min-1. All cleavage sites were at least 2 nt away from the 5' and 3' ends of the oligonucleotides. Some cleavage site preferences were observed dependent on the identity of the RNase P RNA subunit.

Distinct modes of mature and precursor tRNA binding to Escherichia coli RNase P RNA revealed by NAIM analyses.

We have analyzed by nucleotide analog interference mapping (NAIM) pools of precursor or mature tRNA molecules, carrying a low level of Rp-RMPalphaS (R = A, G, I) or Rp-c7-deaza-RMPalphaS (R = A, G) modifications, to identify functional groups that contribute to the specific interaction with and processing efficiency by Escherichia coli RNase P RNA. The majority of interferences were found in the acceptor stem, T arm, and D arm, including the strongest effects observed at positions G19, G53, A58, and G71. In some cases (interferences at G5, G18, and G71), the affected functional groups are candidates for direct contacts with RNase P RNA. Several modifications disrupt intramolecular tertiary contacts known to stabilize the authentic tRNA fold. Such indirect interference effects were informative as well, because they allowed us to compare the structural constraints required for ptRNA processing versus product binding. Our ptRNA processing and mature tRNA binding NAIM analyses revealed overlapping but nonidentical patterns of interference effects, suggesting that substrate binding and cleavage involves binding modes or conformational states distinct from the binding mode of mature tRNA, the product of the reaction.

Direct linkage of str-, S10- and spc-related gene clusters in Thermus thermophilus HB8, and sequences of ribosomal proteins L4 and S10.

We have analyzed the genomic region harboring str-S10-spc-related gene clusters in the thermophilic bacterium, Thermus thermophilus (Tt) HB8. This study was initiated for the purpose of isolating the gene encoding ribosomal (r-) protein S10 which is assumed to be involved in the antitermination of transcription at the rRNA-encoding genes in Bacteria. The S10-related gene cluster encodes the same set of r-proteins as in Escherichia coli. However, the gene coding for elongation factor Tu (the last gene of the str operon in E. coli) is separated by only eight nucleotides (nt) from the gene encoding r-protein S10 (the first gene of the S10 operon in E. coli), and the genes encoding r-protein S17 (the last gene of the S10 operon in E. coli) and L14 (the first gene of the spc operon in E. coli) overlap. This suggests that all three gene clusters are cotranscribed from a single promoter preceding the str-related operon. In addition, we determined the complete nt sequences of the Tt genes encoding r-proteins L4 and S10. Tt L4 shows the lowest degree of conservation among the known L4 r-proteins from Bacteria. Tt S10 has the highest proportion of basic amino acids (aa) and the lowest number of acidic aa, as compared with its homologues from Bacteria and Archaea, which might be related to its possible role in binding to the boxA RNA of nascent rRNA transcripts at high temperatures.