We have discovered a large and highly conserved RNA motif that typically resides in a noncoding section of a multigene messenger RNA in extremophilic Gram-positive eubacteria. RNAs of this class adopt an ornate secondary structure, are large compared with most other noncoding RNAs, and have been identified only in certain extremophilic bacteria. These ornate, large, extremophilic (OLE) RNAs have a length of Ϸ610 nucleotides, and the 35 representatives examined exhibit extraordinary conservation of nucleotide sequence and base pairing. Structural probing of the OLE RNA from Bacillus halodurans corroborates a complex secondary structure model predicted from comparative sequence analysis. The patterns of structural conservation, and its unique phylogenetic distribution, suggest that OLE RNA carries out a complex and critical function only in certain extremophilic bacteria.isoprenoid ͉ riboswitch ͉ ribozyme ͉ superoperon I n recent years, a large number of small noncoding RNAs (1-3) have been identified in eubacteria (4), archaea (5), and eukaryotes (6). In many instances, novel noncoding RNAs in bacteria have been discovered by using bioinformatics search strategies (e.g., refs. 7-13) that take advantage of the conserved nucleotide sequences and secondary structures of these functional RNAs. Another productive way to identify numerous noncoding RNAs from bacteria is by cloning and sequencing small RNAs isolated from cell extracts (e.g., refs. 13-16), and this approach is useful particularly for those examples that are not well conserved through evolution.RNAs such as tRNAs, rRNAs, and some ribozymes have noncoding functions that have long been known to be central to RNA processing and protein synthesis mechanisms. However, it seems possible that additional noncoding RNAs will be found that perform fundamental biochemical tasks that to date have been assumed to be the exclusive province of protein factors. A number of noncoding RNAs discovered recently have proven to participate as the key components of gene regulation systems (e.g., refs. 17-19). Additional examples of widespread noncoding RNAs in bacteria, such as 6S RNA (20-22), the dual-function tmRNA (23), and noncoding portions of messenger RNAs such as T-Box elements (24) and riboswitches (25-27) perform important gene control and molecular sensing tasks that are critical for cells to function normally. The existence of so many RNAs with atypical functions implies that some newly discovered noncoding RNAs might perform surprising and important roles in fundamental cellular processes. In this article, we describe features of a noncoding RNA element whose size, structural sophistication, and unique phylogenetic distribution are suggestive of a complex biological function.
ResultsIdentifying Ornate, Large, Extremophilic (OLE) RNAs by Using Bioinformatics. We have previously used computer-aided search strategies that employ comparative sequence analysis (e.g., refs. 11 and 28-30) to identify noncoding RNAs whose nucleotide sequences and secondary structures are c...
