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Endoribonuclease III (RNase III) plays an important role in the processing of rRNA and mRNAs. It is timely to summarize the most relevant insights obtained during the last years stemming from RNase III. With this aim, the present mini-review provides a wealth of new information focusing on the distribution and architecture of RNase III, substrate recognition, cleavage mechanisms and regulation of gene expression.
J Mol Microbiol Biotechnol 2004
PMID:The continuing story of endoribonuclease III. 1617 96

Abundant approximately 28-nucleotide RNAs that are thought to direct histone H3 lysine 9 (H3K9) methylation and promote the elimination of nearly 15 Mbp of DNA from the developing somatic genome are generated during Tetrahymena thermophila conjugation. To identify the protein(s) that generates these small RNAs, we studied three Dicer-related genes encoded within the Tetrahymena genome, two that contain both RNase III and RNA helicase motifs, Dicer 1 (DCR1) and DCR2, and a third that lacks the helicase domain, Dicer-like 1 (DCL1). DCL1 is expressed upon the initiation of conjugation, and the protein localizes to meiotic micronuclei when bidirectional germ line transcription occurs and small RNAs begin to accumulate. Cells in which we disrupted the DCL1 gene (DeltaDCL1) grew normally and initiated conjugation as wild-type cells but arrested near the end of development and eventually died, unable to resume vegetative growth. These DeltaDCL1 cells failed to generate the abundant small RNAs but instead accumulated germ line-limited transcripts. Together, our findings demonstrate that these transcripts are the precursors of the small RNAs and that DCL1 performs RNA processing within the micronucleus. Postconjugation DeltaDCL1 cells die without eliminating the germ line-limited DNA sequences from their newly formed somatic macronuclei, a result that shows that this Dicer-related gene is required for programmed DNA rearrangements. Surprisingly, DeltaDCL1 cells were not deficient in overall H3K9 methylation, but this modification was not enriched on germ line-limited sequences as it is in wild-type cells, which clearly demonstrates that these small RNAs are essential for its targeting to specific loci.
Mol Cell Biol 2005 Oct
PMID:Germ line transcripts are processed by a Dicer-like protein that is essential for developmentally programmed genome rearrangements of Tetrahymena thermophila. 1619 90

RNA editing in Trypanosoma brucei inserts and deletes uridines in mitochondrial mRNAs by a series of enzymatic steps that are catalyzed by a multiprotein complex, the editosome. KREPB1 and two related editosome proteins KREPB2 and KREPB3 contain motifs that suggest endonuclease and RNA/protein interaction functions. Repression of KREPB1 expression in procyclic forms by RNAi inhibited growth, in vivo editing, and in vitro endoribonucleolytic cleavage of deletion substrates. However, cleavage of insertion substrates and the exoUase, TUTase, and ligase catalytic activities of editing were retained by 20S editosomes. Repression of expression of an ectopic KREPB1 allele in bloodstream forms lacking both endogenous alleles or exclusive expression of KREPB1 with point mutations in the putative RNase III catalytic domain also blocked growth, in vivo editing, and abolished cleavage of deletion substrates, without affecting the other editing steps. These data indicate that KREPB1 is an endoribonuclease that is specific for RNA editing deletion sites.
Mol Cell 2005 Nov 11
PMID:A deletion site editing endonuclease in Trypanosoma brucei. 1628 22

Despite the large differences in their length and nucleotide composition, comparative analyses of the internal transcribed spacer 1 (ITS1) of widely divergent eukaryotes have suggested a simple core structure consisting of a central extended hairpin and lesser hairpin structures at the maturing junctions [Lalev, A. I., and Nazar, R. N. (1998) J. Mol. Biol. 284, 1341-1351]. In this study, the ITS1 in the pre-rRNA transcripts of Schizosaccharomyces pombe cells was examined with respect to structural features that underlie rRNA maturation. When plasmid-associated rRNA genes were expressed in vivo, a deletion of any major hairpin structure significantly reduced or eliminated both small and large subunit RNAs. Only changes in the central extended hairpin or junction regions, however, entirely eliminated plasmid-derived RNAs or resulted in elevated precursor levels. Structure-disrupting base substitutions within the RAC protein complex binding site in the extended hairpin indicated that the secondary structure was critical for rRNA maturation; composition or other changes with respect to the binding site had only modest effects. A similar disruption at the junction with the 18S rRNA also had striking effects on rRNA maturation, including a highly elevated level of unprocessed precursor and a surprisingly critical effect on 5.8S rRNA production. As previously observed with the 3' external transcribed spacer, the results are consistent with a maturation mechanism in which an initial cleavage in the 5' junction region may be directed by the RAC protein complex. Although not critical to rRNA processing, analyses of termini based on S1 nuclease protection as well as cleavage studies, in vitro, with Pac1 ribonuclease raise the possibility that in eukaryotes, as previously observed in bacteria, the RNase III homologues normally initiate the separation of the subunit RNAs.
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PMID:Parallels in rRNA processing: conserved features in the processing of the internal transcribed spacer 1 in the pre-rRNA from Schizosaccharomyces pombe. 1636 11

Adenosine deaminases acting on RNA (ADARs) are involved in editing of adenosine residues to inosine in double-stranded RNA (dsRNA). Although this editing recodes and alters functions of several mammalian genes, its most common targets are noncoding repeat sequences, indicating the involvement of this editing system in currently unknown functions other than recoding of protein sequences. Here we show that specific adenosine residues of certain microRNA (miRNA) precursors are edited by ADAR1 and ADAR2. Editing of pri-miR-142, the precursor of miRNA-142, expressed in hematopoietic tissues, resulted in suppression of its processing by Drosha. The edited pri-miR-142 was degraded by Tudor-SN, a component of RISC and also a ribonuclease specific to inosine-containing dsRNAs. Consequently, mature miRNA-142 expression levels increased substantially in ADAR1 null or ADAR2 null mice. Our results demonstrate a new function of RNA editing in the control of miRNA biogenesis.
Nat Struct Mol Biol 2006 Jan
PMID:Modulation of microRNA processing and expression through RNA editing by ADAR deaminases. 1639 13

We report the first cDNA-sequencing project of the entomopathogenic nematode, Heterorhabditis bacteriophora. A total of 1246 expressed sequence tags (ESTs) were generated by random sequencing of clones from a cDNA library of the infective juvenile stage. The ESTs were annotated resulting in 1072 useful ESTs that were categorized into functional categories according to Kyoto Encyclopedia of Genes and Genomes. Approximately 459 of 1072 ESTs (43%) had significant similarities to annotated sequences in GenBank. Of these, 417 had significant similarities to the free-living nematode Caenorhanditis elegans proteins. Most ESTs (18%) belonged to the genetic information processing category followed by metabolism (15% ESTs) and environmental information processing (15%) pathways. Several interesting ESTs were found that may have roles in the infectivity and survival of infective juveniles. These included proteases, dauer pathway genes (akt-1, pdk-1 & daf-7) and aging and stress resistance genes such as superoxide dismutase (sod-4), heat shock genes (hsp-4 & hsp-6), and eat genes, and signaling proteins like G-protein coupled receptors, regulators of G-protein signaling (rgs), and serine/threonine kinases. Other interesting ESTs include systemic RNAi defective protein (sid-1), ribonuclease III family members (rnh-2 &rnc) and transposase gene (Tc3A). About 67% of the ESTs did not find matches in any of the searched databases suggesting potentially novel genes in this enomopathogenic nematode. Note: Sequences described in this paper have been deposited in Genbank under the accessions DN 152655-DN 152999, and DN 153000-DN 153726.
Mol Biochem Parasitol 2006 Feb
PMID:Comparative analysis of the expressed genome of the infective juvenile entomopathogenic nematode, Heterorhabditis bacteriophora. 1641 68

RNA silencing pathways are conserved gene regulation mechanisms that elicit decay and/or translational repression of mRNAs complementary to short interfering RNAs and microRNAs (miRNAs). The fraction of the transcriptome regulated by these pathways is not known, but it is thought that each miRNA may have hundreds of targets. To identify transcripts regulated by silencing pathways at the genomic level, we examined mRNA expression profiles in Drosophila melanogaster cells depleted of four Argonaute paralogs (i.e., AGO1, AGO2, PIWI, or Aubergine) that play essential roles in RNA silencing. We also profiled cells depleted of the miRNA-processing enzyme Drosha. The results reveal that transcripts differentially expressed in Drosha-depleted cells have highly correlated expression in the AGO1 knockdown and are significantly enriched in predicted and validated miRNA targets. The levels of a subset of miRNA targets are also regulated by AGO2. Moreover, AGO1 and AGO2 silence the expression of a common set of mobile genetic elements. Together, these results indicate that the functional overlap between AGO1 and AGO2 in Drosophila is more important than previously thought.
Mol Cell Biol 2006 Apr
PMID:Genome-wide analysis of mRNAs regulated by Drosha and Argonaute proteins in Drosophila melanogaster. 1658 72

The recently discovered microRNAs (miRNAs) are a large family of small regulatory RNAs that have been implicated in controlling diverse pathways in a variety of organisms (1, 2). For posttranscriptional gene silencing, one strand of the miRNA is used to guide components of the RNA interference machinery, including Argonaute 2, to messenger RNAs (mRNAs) with complementary sequences (3, 4). Thus, targeted mRNAs are either cleaved by the endonuclease Argonaute 2 (5, 6), or protein synthesis is blocked by an as yet uncharacterized mechanism (7, 8). Genes encoding miRNAs are transcribed as long primary miRNAs (pri-miRNAs) that are sequentially processed by components of the nucleus and cytoplasm to yield a mature, approx 22-nucleotide (nt)-long miRNA (9). Two members of the ribonuclease (RNase) III endonuclease protein family, Drosha and Dicer, have been implicated in this two-step processing (10-13). To further our understanding of miRNA biogenesis and function it will be essential to identify the protein complexes involved. We were interested in defining the proteins required for the initial nuclear processing of pri-miRNAs to the approx 60- to 70-nt stem-loop intermediates known as precursor miRNAs (pre-miRNAs) (9, 10). This led to our identification of a protein complex we termed Microprocessor, which is necessary and sufficient for processing pri-miRNA to premiRNAs (14). The Microprocessor complex comprises Drosha and the double-stranded RNAbinding protein DiGeorge syndrome critical region 8 gene (DGCR8), which is deleted in DiGeorge syndrome (15, 16). In this chapter, we detail the methods used for the biochemical isolation and identification of the Microprocessor complex from human cells. We include a protocol for the in vitro analysis of pri-miRNA processing activity of the purified Microprocessor complex.
Methods Mol Biol 2006
PMID:MicroRNA biogenesis: isolation and characterization of the microprocessor complex. 1695 65

Prediction of microRNA (miRNA) candidates using computer programming has identified hundreds and hundreds of genomic hairpin sequences, of which, the functions remain to be determined. Because direct transfection of hairpin-like miRNA precursors (pre)-miRNAs in mammalian cells is not always sufficient to trigger effective RNA-induced gene-silencing complex (RISC) assembly, a key step for RNA interference (RNAi)-related gene silencing, we developed an intronic miRNA-expressing system to overcome this problem, and successfully increased the efficiency and effectiveness of miRNA-associated RNAi induction in vitro and in vivo. By insertion of a hairpin-like pre-miRNA structure into the intron region of a gene, this intronic miRNA biogenesis system has been found to depend on a coupled interaction of nascent precursor messenger RNA transcription and intron excision within a specific nuclear region proximal to genomic perichromatin fibrils. The intronic miRNA was transcribed by RNA type II polymerases, coexpressed with a primary gene transcript, and excised out of its encoding gene transcript by intracellular RNA splicing and processing mechanisms. Currently, some ribonuclease III endonucleases have been found to be involved in the processing of spliced introns and probably facilitating the intronic miRNA maturation. Using this miRNA-expressing system, we have shown for the first time that the intron-derived miRNAs were able to induce strong RNAi effects in not only human and mouse cells but also zebrafish, chicken embryos, and adult mice. Based on the strand complementarity between the designed miRNA and its target gene sequence, we have also developed a miRNA isolation protocol to purify and identify the mature miRNAs generated by the intronic miRNA-expressing system. Several intronic miRNA identities and structures are currently confirmed to be active in vitro and in vivo. According to this proof- of-principle method, we now have the knowledge to design pre-miRNA inserts that are more efficient and effective for the intronic miRNA-expressing system.
Methods Mol Biol 2006
PMID:Isolation and identification of gene-specific microRNAs. 1695 85

RNase III enzymes form a conserved family of proteins that specifically cleave double-stranded (dsRNA). These proteins are involved in a variety of cellular functions, including the processing of many non-coding RNAs, mRNA decay, and RNA interference. Yeast RNase III (Rnt1p) selects its substrate by recognizing the structure generated by a conserved NGNN tetraloop (G2-loop). Mutations of the invariant guanosine stringently inhibit binding and cleavage of all known Rnt1p substrates. Surprisingly, we have found that the 5' end of small nucleolar RNA 48 is processed by Rnt1p in the absence of a G2-loop. Instead, biochemical and structural analyses revealed that cleavage, in this case, is directed by a hairpin capped with an AAGU tetraloop, with a preferred adenosine in the first position (A1-loop). Chemical probing indicated that A1-loops adopt a distinct structure that varies at the 3' end where Rnt1p interacts with G2-loops. Consistently, chemical footprinting and chemical interference assays indicate that Rnt1p binds to G2 and A1-loops using different sets of nucleotides. Also, cleavage and binding assays showed that the N-terminal domain of Rnt1p aids selection of A1-capped hairpins. Together, the results suggest that Rnt1p recognizes at least two distinct classes of tetraloops using flexible protein RNA interactions. This underscores the capacity of double-stranded RNA binding proteins to use several recognition motifs for substrate identification.
J Mol Biol 2006 Oct 20
PMID:Characterization of the reactivity determinants of a novel hairpin substrate of yeast RNase III. 1696 33

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