The intron landscape of the mtDNA cytb gene among the Ascomycota: introns and intron-encoded open reading frames.

Fungal mitochondrial genes are frequently noted for the presence of introns. These introns are self-splicing and can be assigned to either group I or II introns and they can encode open reading frames (ORFs). This study examines the introns present within the cytochrome b (cytb) gene of ascomycetes fungi. Cytochrome b gene sequences were sampled from GenBank and supplemented with our own data for species of Leptographium and Ophiostoma. Group I introns were encountered most frequently, many encoding either LAGLIDADG or GIY-YIG homing endonucleases (HEs). Numerous examples of different intron/ORF arrangements were observed including nested ORFs, multiple ORFs within a single intron and intron ORFs at various stages of erosion due to the accumulation of mutations. In addition, we noted one example of a nested intron and one complex group II intron that could potentially allow for alternative splicing. Documenting the distribution of introns within the same gene across a range of species allows for a better understanding of the evolution of introns and intronic ORFs. Intron landscapes also are a resource that can help in annotating genes and in bioprospecting for potentially active HEs, which are rare-cutting DNA endonucleases with applications in biotechnology.

The complexity of human ribosome biogenesis revealed by systematic nucleolar screening of Pre-rRNA processing factors.

Mature ribosomal RNAs (rRNAs) are produced from polycistronic precursors following complex processing. Precursor (pre)-rRNA processing has been extensively characterized in yeast and was assumed to be conserved in humans. We functionally characterized 625 nucleolar proteins in HeLa cells and identified 286 required for processing, including 74 without a yeast homolog. For selected candidates, we demonstrated that pre-rRNA processing defects are conserved in different cell types (including primary cells), defects are not due to activation of a p53-dependent nucleolar tumor surveillance pathway, and they precede cell-cycle arrest and apoptosis. We also investigated the exosome's role in processing internal transcribed spacers (ITSs) and report that 3' end maturation of 18S rRNA involves EXOSC10/Rrp6, a yeast ITS2 processing factor. We conclude that human cells adopt unique strategies and recruit distinct trans-acting factors to carry out essential processing steps, posing fundamental implications for understanding ribosomopathies at the molecular level and developing effective therapeutic agents.

Where no RNA polymerase has gone before: novel functional transcripts derived from the ribosomal intergenic spacer.

The nucleolus is organized around a scaffolding of rDNA tandem repeats. These repeats, known as ribosomal cassettes, are each composed of ribosomal RNA (rRNA) genes preceding a long intergenic spacer (IGS) that has been classically perceived to be transcriptionally silent. Recent study of the IGS has contradicted the dogma that these spacers are merely inert regions of the genome, instead suggesting they are biologically significant, complex and plurifunctional transcriptional units that appear central to proper cellular functioning. Through the timely induction of various ribosomal IGS noncoding RNA (IGS RNA) transcripts, the cell is capable of both regulating rRNA synthesis and sequestering large numbers of proteins, thereby modulating essential molecular networks. Here we discuss our current understanding of the organization and function of the IGS.

Mapping the cleavage sites on mammalian pre-rRNAs: where do we stand?

Ribosomal RNAs are produced as lengthy polycistronic precursors containing coding and non-coding sequences, implying that extensive pre-rRNA processing is necessary for the removal of non-coding spacers. Remarkably, this feature is conserved in all three kingdoms of life and pre-rRNA processing has even become more complex during the course of evolution. While the need for such extensive processing remains unclear, it likely offers increased opportunities to finely regulate ribosome synthesis and to temporally and spatially integrate the various components of ribosome synthesis. In this review we discuss our current understanding of pre-rRNA processing pathways in mammals (human and mouse), with a particular focus on the known and putative cleavage sites, and we compare it to budding yeast, the best eukaryotic model, thus far, regarding ribosome synthesis. Based on the emerging research, we suggest that there are likely more pre-rRNA processing sites and alternative processing pathways still to be identified in humans and that a certain level of functional redundancy can be found in the trans-acting factors involved. These features might have been selected because they increase the robustness of pre-rRNA processing by acting as "back-up" mechanisms to ensure the proper maturation of rRNA.

Identification of group I introns within the SSU rDNA gene in species of Ceratocystiopsis and related taxa.

During a recent phylogenetic study, group I introns were noted that interrupt the nuclear small subunit ribosomal RNA (SSU rDNA) gene in species of Ceratocystiopsis. Group I introns were found to be inserted at the following rDNA positions: S943, S989, and S1199. The introns have been characterized and phylogenetic analysis of the host gene and the corresponding intron data suggest that for S943 vertical transfer and frequent loss appear to be the most parsimonious explanation for the distribution of nuclear SSU rDNA introns among species of Ceratocystiopsis. The SSU rDNA data do suggest that a recent proposal of segregating the genus Ophiostoma sensu lato into Ophiostoma sensu stricto, Grosmannia, and Ceratocystiopsis has some merit but may need further amendments, as the SSU rDNA suggests that Ophiostoma s. str. may now represent a paraphyletic grouping.

Evolutionary dynamics of the mS952 intron: a novel mitochondrial group II intron encoding a LAGLIDADG homing endonuclease gene.

Examination of the mitochondrial small subunit ribosomal RNA (rns) gene of five species of the fungal genus Leptographium revealed that the gene has been invaded at least once at position 952 by a group II intron encoding a LAGLIDADG homing endonuclease gene. Phylogenetic analyses of the intron and homing endonuclease sequences indicated that each element in Leptographium species forms a single clade and is closely related to the group II intron/homing endonuclease gene composite element previously reported at position 952 of the mitochondrial rns gene of Cordyceps species and of Cryphonectria parasitica. The results of an intron survey of the mt rns gene of Leptographium species superimposed onto the phylogenetic analysis of the host organisms suggest that the composite element was transmitted vertically in Leptographium lundbergii. However, its stochastic distribution among strains of L. wingfieldii, L. terebrantis, and L. truncatum suggests that it has been horizontally transmitted by lateral gene transfer among these species, although the random presence of the intron may reflect multiple random loss events. A model is proposed describing the initial invasion of the group II intron in the rns gene of L. lundbergii by a LAGLIDADG homing endonuclease gene and subsequent evolution of this gene to recognize a novel DNA target site, which may now promote the mobility of the intron and homing endonuclease gene as a composite element.

A group II intron encodes a functional LAGLIDADG homing endonuclease and self-splices under moderate temperature and ionic conditions.

A group II intron encoding a protein belonging to the LAGLIDADG family of homing endonucleases was identified in the mitochondrial rns gene of the filamentous fungus Leptographium truncatum, and the catalytic activities of both the intron and its encoded protein were characterized. A model of the RNA secondary structure indicates that the intron is a member of the IIB1 subclass and the open reading frame is inserted in ribozyme domain III. In vitro assays carried out with two versions of the intron, one in which the open reading frame was removed and the other in which it was present, demonstrate that both versions of the intron readily self-splice at 37 degrees C and at a concentration of MgCl(2) as low as 6 mM. The open reading frame encodes a functional LAGLIDADG homing endonuclease that cleaves 2 (top strand) and 6 (bottom strand) nucleotides (nt) upstream of the intron insertion site, generating 4 nt 3' OH overhangs. In vitro splicing assays carried out in the absence and presence of the intron-encoded protein indicate that the protein does not enhance intron splicing, and RNA-binding assays show that the protein does not appear to bind to the intron RNA precursor transcript. These findings raise intriguing questions concerning the functional and evolutionary relationships of the two components of this unique composite element.