Comparative genomics of Listeria species.

Listeria monocytogenes is a food-borne pathogen with a high mortality rate that has also emerged as a paradigm for intracellular parasitism. We present and compare the genome sequences of L. monocytogenes (2,944,528 base pairs) and a nonpathogenic species, L. innocua (3,011,209 base pairs). We found a large number of predicted genes encoding surface and secreted proteins, transporters, and transcriptional regulators, consistent with the ability of both species to adapt to diverse environments. The presence of 270 L. monocytogenes and 149 L. innocua strain-specific genes (clustered in 100 and 63 islets, respectively) suggests that virulence in Listeria results from multiple gene acquisition and deletion events.

The yeast Saccharomyces cerevisiae YDL112w ORF encodes the putative 2'-O-ribose methyltransferase catalyzing the formation of Gm18 in tRNAs.

The protein sequences of three known RNA 2'-O-ribose methylases were used as probes for detecting putative homologs through iterative searches of genomic databases. We have identified 45 new positive Open Reading Frames (ORFs), mostly in prokaryotic genomes. Five complete eukaryotic ORFs were also detected, among which was a single ORF (YDL112w) in the yeast Saccharomyces cerevisiae genome. After genetic depletion of YDL112w, we observed a specific defect in tRNA ribose methylation, with the complete disappearance of Gm18 in all tRNAs that naturally contain this modification, whereas other tRNA ribose methylations and the complex pattern of rRNA ribose methylations were not affected. The tRNA G18 methylation defect was suppressed by transformation of the disrupted strain with a plasmid allowing expression of YDL112wp. The formation of Gm18 on an in vitro transcript of a yeast tRNASer naturally containing this methylation, which was efficiently catalyzed by cell-free extracts from the wild-type yeast strain, did not occur with extracts from the disrupted strain. The protein encoded by the YDL112w ORF, termed Trm3 (tRNA methylation), is therefore likely to be the tRNA (Gm18) ribose methylase. In in vitro assays, its activity is strongly dependent on tRNA architecture. Trm3p, the first putative tRNA ribose methylase identified in an eukaryotic organism, is considerably larger than its Escherichia coli functional homolog spoU (1,436 amino acids vs. 229 amino acids), or any known or putative prokaryotic RNA ribose methyltransferase. Homologs found in human (TRP-185 protein), Caenorhabditis elegans and Arabidopsis thaliana also exhibit a very long N-terminal extension not related to any protein sequence in databases.

ESSA: an integrated and interactive computer tool for analysing RNA secondary structure.

With ESSA, we propose an approach of RNA secondary structure analysis based on extensive viewing within a friendly graphical interface. This computer program is organized around the display of folding models produced by two complementary methods suitable to draw long RNA molecules. Any feature of interest can be managed directly on the display and highlighted by a rich combination of colours and symbols with emphasis given to structural probe accessibilities. ESSA also includes a word searching procedure allowing easy visual identification of structural features even complex and degenerated. Analysis functions make it possible to calculate the thermodynamic stability of any part of a folding using several models and compare homologous aligned RNA both in primary and secondary structure. The predictive capacities of ESSA which brings together the experimental, thermodynamic and comparative methods, are increased by coupling it with a program dedicated to RNA folding prediction based on constraints management and propagation. The potentialities of ESSA are illustrated by the identification of a possible tertiary motif in the LSU rRNA and the visualization of a pseudoknot in S15 mRNA.

RNA-d2: a computer program for editing and display of RNA secondary structures.

RNA-d2 is a user-friendly program developed for interactively generating aesthetic and non-overlapping drawings of RNA secondary structures. It designed so that the drawings can be edited in a very natural and intuitive way, in order to emphasize structural homologies between several molecules, as well as the foldings themselves to update the base-pair sets according to new data. The program automatically produces a polygonal display in which the unpaired nucleotides are regularly positioned on circles and the stems harmoniously distributed on their periphery. RNA secondary structures can be encoded via the keyboard, but the program also automatically draws output files from thermodynamic prediction programs. The user interacts directly on different screen displays according to the editing functions. Rotation/translation of any subdomain and deletion of stems are performed on a coloured backbone view to make easier the identification of structural features, whereas addition of new base-pairings and numbering manipulation are realized on a complete polygonal view. Each modification is displayed in real time on the screen. When the display is obscured by numerous overlaps despite the colour code of the backbone view, an automatic function progressively straightens the subdomains which are highly compacted by very dissymmetric internal loops. RNA-d2 allows easy untangling and editing of RNA molecules > 1000 nucleotides long.