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.

The 62-kb upstream region of Bombyx mori fibroin heavy chain gene is clustered of repetitive elements and candidate matrix association regions.

We sequenced an 80 kb DNA region containing the complete sequence of the silkworm Bombyx mori fibroin gene and its flanking, especially the upstream, regions (-62 kb). About 30% of the 62 kb upstream region is composed of repetitive elements including short interspersed elements Bm1, long interspersed elements L1Bm and mariner-like elements Bmmar1 which are widespread over the silkworm genome. This 62 kb region is also enriched of commonly considered matrix association region (MAR) motifs. A total of 25 individual MAR recognition signatures (MRSs) were identified, with 24 at the upstream and one at the downstream region. Combining two newly developed MAR prediction programs (MAR-finder and Chrclass), ten candidate MARs were predicted, with five containing MRS and seven related to the repetitive elements. The wide distribution of nested repetitive elements, candidate MARs, DNase I hypersensitive sites and other potential regulatory factors recognition sites indicates this region is probably a unique huge cis-acting element contributing to the regulation of the spatial and temporal specificity and efficiency of fibroin gene expression.

Myb genes in ciliates: a common origin with the myb protooncogene?

In animals, the protooncogene myb family is characterized by a DNA-binding domain (so-called MYB domain), which consists of 3 imperfect tandem repeats of a helix-turn-helix motif. Homologous genes have been characterized in plants and also in Dictyostelium discoideum. However, in plants, the myb family is more diverse and displays 2 types of MYB domains: the animal-like 3 repeats (MYB-3R) and the 2 repeats (MYB-2R) domains. The question is therefore raised as to the putative existence of genes with MYB-3R and/or MYB-2R domains in their last common unicellular ancestor. Here, we present evidence that in ciliates like in plants, both types of domain exist. A gene having a MYB-3R domain has been identified in the oxytrichid Sterkiella histriomuscorum and a gene having a MYB-2R domain has been identified in the euplotid Euplotes aediculatus. Both genes are expressed during the vegetative growth of the cells. A conserved intron exists in the gene of Sterkiella and phylogenetical analyses show that the 2 ciliate genes belong to the myb protooncogene family as deeply split lineages. This is the first report of a myb homolog in a ciliated protist, thus, confirming its origin in strict unicellular eukaryotes.