We report an efficient method for detecting functional RNAs. The approach, which combines comparative sequence analysis and structure prediction, already has yielded excellent results for a small number of aligned sequences and is suitable for large-scale genomic screens. It consists of two basic components: (i) a measure for RNA secondary structure conservation based on computing a consensus secondary structure, and (ii) a measure for thermodynamic stability, which, in the spirit of a z score, is normalized with respect to both sequence length and base composition but can be calculated without sampling from shuffled sequences. Functional RNA secondary structures can be identified in multiple sequence alignments with high sensitivity and high specificity. We demonstrate that this approach is not only much more accurate than previous methods but also significantly faster. The method is implemented in the program RNAZ, which can be downloaded from www.tbi.univie.ac.at͞ϳwash͞RNAz. We screened all alignments of length n > 50 in the Comparative Regulatory Genomics database, which compiles conserved noncoding elements in upstream regions of orthologous genes from human, mouse, rat, Fugu, and zebrafish. We recovered all of the known noncoding RNAs and cis-acting elements with high significance and found compelling evidence for many other conserved RNA secondary structures not described so far to our knowledge.comparative genomics ͉ conserved RNA secondary structure T raditionally, the role of RNA in the cell was considered mostly in the context of protein gene expression, limiting RNA to its function as mRNA, tRNA, and rRNA. The discovery of a diverse array of transcripts that are not translated to proteins but rather function as RNAs has changed this view profoundly (1-3). Noncoding RNAs (ncRNAs) are involved in a large variety of processes, including gene regulation (4), maturation of mRNAs, rRNAs, and tRNAs, or X-chromosome inactivation in mammals (5). In fact, a large fraction of the mouse transcriptome consists of ncRNAs (6), and about half of the transcripts from human chromosomes 21 and 22 are noncoding (7,8). Structured RNA motifs furthermore function as cis-acting regulatory elements within protein-coding genes. Also in this context, new intriguing mechanisms are being discovered (9).Hence, a comprehensive understanding of cellular processes is impossible without considering RNAs as key players. Efficient identification of functional RNAs (ncRNAs as well as cis-acting elements) in genomic sequences is, therefore, one of the major goals of current bioinformatics. Notwithstanding its utmost biological relevance, de novo prediction is still a largely unsolved issue. Unlike protein-coding genes, functional RNAs lack in their primary sequence common statistical signals that could be exploited for reliable detection algorithms. Many functional RNAs, however, depend on a defined secondary structure. In particular, evolutionary conservation of secondary structures serves as compelling evidence for biologically relevan...
