- Research article
- Open Access
The evolution of core proteins involved in microRNA biogenesis
© Murphy et al; licensee BioMed Central Ltd. 2008
Received: 22 February 2007
Accepted: 25 March 2008
Published: 25 March 2008
MicroRNAs (miRNAs) are a recently discovered class of non-coding RNAs (ncRNAs) which play important roles in eukaryotic gene regulation. miRNA biogenesis and activation is a complex process involving multiple protein catalysts and involves the large macromolecular RNAi Silencing Complex or RISC. While phylogenetic analyses of miRNA genes have been previously published, the evolution of miRNA biogenesis itself has been little studied. In order to better understand the origin of miRNA processing in animals and plants, we determined the phyletic occurrences and evolutionary relationships of four major miRNA pathway protein components; Dicer, Argonaute, RISC RNA-binding proteins, and Exportin-5.
Phylogenetic analyses show that all four miRNA pathway proteins were derived from large multiple protein families. As an example, vertebrate and invertebrate Argonaute (Ago) proteins diverged from a larger family of PIWI/Argonaute proteins found throughout eukaryotes. Further gene duplications among vertebrates after the evolution of chordates from urochordates but prior to the emergence of fishes lead to the evolution of four Ago paralogues. Invertebrate RISC RNA-binding proteins R2D2 and Loquacious are related to other RNA-binding protein families such as Staufens as well as vertebrate-specific TAR (HIV trans-activator RNA) RNA-binding protein (TRBP) and protein kinase R-activating protein (PACT). Export of small RNAs from the nucleus, including miRNA, is facilitated by three closely related karyopherin-related nuclear transporters, Exportin-5, Exportin-1 and Exportin-T. While all three exportins have direct orthologues in deutrostomes, missing exportins in arthropods (Exportin-T) and nematodes (Exportin-5) are likely compensated by dual specificities of one of the other exportin paralogues.
Co-opting particular isoforms from large, diverse protein families seems to be a common theme in the evolution of miRNA biogenesis. Human miRNA biogenesis proteins have direct, orthologues in cold-blooded fishes and, in some cases, urochordates and deutrostomes. However, lineage specific expansions of Dicer in plants and invertebrates as well as Argonaute and RNA-binding proteins in vertebrates suggests that novel ncRNA regulatory mechanisms can evolve in relatively short evolutionary timeframes. The occurrence of multiple homologues to RNA-binding and Argonaute/PIWI proteins also suggests the possible existence of further pathways for additional types of ncRNAs.
Recent studies have unveiled the critical roles that RNA interference (RNAi) mediated by small noncoding RNAs (ncRNAs) plays in the regulation of eukaryotic genes. One particular important ncRNA class is microRNA (miRNA), single-stranded, 19–25 nucleotide long RNAs that repress translation by binding to specific mRNA target sites. miRNAs differ from short interfering RNAs (siRNA), in that they are derived from single-stranded rather double-stranded RNA precursors. Yet like siRNAs, miRNAs can under some circumstances also effect mRNA degradation and generally share a common route to biogenesis. Computational predictions of miRNA genes and their target sites suggest that most metazoan and plant genomes encode at least several hundred if not thousands of miRNA genes and, that a large proportion of protein-coding genes have putative miRNA regulatory binding sites (reviewed in ).
The regulatory roles of miRNAs in both plants and animals have been reviewed in-depth elsewhere (see [2, 3]). Briefly, plant miRNAs have been shown to be key regulators of tissue morphogenesis and stem development as well as mediating responses to environmental conditions . In normal animal tissue, miRNA gene expression has been shown to modulate a wide variety of functions including skeletal and muscle development  and various metabolic pathways . The abnormal expression of miRNAs has been also linked to various disease pathologies [7, 8]. In cancer, miRNAs can act as either tumor suppressors or oncogenes depending upon the miRNA gene and the type of tumor [9, 10]. Comparative analyses of miRNA expression profiles suggest they have potential as clinical biomarkers for the classification of tumor types . Gene expression during cardiac and skeletal muscle development is also regulated by certain miRNAs which opens new opportunities for understanding muscle-related diseases [12, 13]. Double stranded DNA viruses including herpes viruses, polyomaviruses and retroviruses encode their own specific miRNAs as well as interact with host miRNAs [14–16]. The differential expression of miRNAs is seen in human cells infected with viruses including HIV . Their important role in disease has lead to serious consideration of miRNAs as a pharmacological target [18, 19]. In agriculture, the introduction of artificial miRNAs might be a strategy for improving the resistance of crop plants to certain viruses .
Evolutionary analyses of miRNA gene families have revealed a combination of older ancestral relationships and recent lineage-specific diversification. The human genome itself likely encodes for a few hundred miRNAs, many of which have recognizable homologues to miRNA genes in different species (orthology) as well as amongst themselves (paralogy) . Several families of miRNA genes, such as let-7, are highly conserved amongst different vertebrate and invertebrate species . In addition, genomic organization of miRNA genes is often recognizable across diverse species such as the mir-196 and mir-10 gene families that likely co-evolved with Hox proteins  and the mir-17 gene cluster which has apparently undergone a complex series of gene duplication and loss in vertebrates . However, miRNAs can also have restrictive taxonomic distribution such as the Early Embryonic microRNA Cluster (EEmiRC) locus of six pre-miRNA precursors restricted to placental (eutherian) mammals . Many miRNA genes found in primates, including humans, are absent in other mammals [21, 26]. Similar patterns of conservation and diversification have been observed for miRNAs in across plant species .
While the genomic distribution and phylogeny of miRNAs has been extensively studied, the evolution of the enabling miRNA biosynthetic pathway has received less attention. The biogenesis of a functional miRNA from its expressed gene product involves several steps and multiple proteins (for reviews see [28–31].) In animals, miRNA biogenesis begins with expression of a primary, ~1000 nt miRNA transcript, termed the pri-miRNA. From the pri-miRNA, a multi-protein complex called the Microprocessor cleaves out a ~60–70 nucleotide precursors, termed pre-miRNAs, that can fold into an imperfect stem-loop structures. There are two main components of the Microprocessor. One is called Drosha, a universal RNase III endonuclease named RNASEN in humans. The other component is a double-stranded RNA binding protein known in invertebrates as Pasha or Partner of Drosha while a similar function in vertebrates is performed by DiGeorge syndrome critical region gene 8 or DGCR8 . After the pre-miRNA is cleaved from the pri-miRNA, it is transported into the cytoplasm by Exportin-5, a known transporter of RNA and protein-RNA complexes . In the cytosol, the pre-miRNAs are further processed into an imperfect double stranded RNA (dsRNA) duplex by another endonuclease RNase III enzyme, Dicer [32, 34].
Dicer loads mature miRNA strand into the RNA-induced silencing complex or RISC while the complementary strand, miRNA*, is degraded. Both RISC and Dicer are also known activators of siRNA. Recently, additional protein partners for Dicer and RISC have been found. The protein TRBP (human immunodeficiency virus [HIV-1] transactivating response binding protein) has been identified as a RISC partner of human Dicer [35, 36] and in Drosophila, Loquacious, a TRBP homologue binds to Dcr1, one of two Dicer isoforms present in that species .
Cellular active RISC contains at least one member of the Argonaute or AGO, a large family of PIWI/PAZ domain containing proteins . Structure and mutation studies suggest that in mammals, Ago2 is specifically responsible for RISC cleavage activity [39, 40]. Several other proteins have also been co-purified from the RISC including RNA binding proteins VIG (Vasa Intronic Gene), Fragile X-related protein , nuclease Tudor-SN  and various helicases, like Gemin-3 and Gemin-4 .
While miRNA biogenesis proteins have motifs or functional domains which are conserved throughout unicellular and multicellular organisms , miRNA genes themselves seem to be mostly limited to metazoans and plants . miRNAs have not been reported for fungi and are absent from most unicellular species including Schizosaccharomyces pombe and Tetrahymena thermophila which have known RNA silencing mechanisms [45, 46]. Recently, the first occurrence of miRNAs in a unicellular organisms was reported for the single-cell algae, Chlamydomonas reinhardtii . However, none of the C. reinhardtii miRNAs have any sequence homology to known plant or animal miRNAs which suggests a unique lineage-specific evolutionary occurrence – at least until further examples of miRNAs in unicellular species are found . Certain double-stranded DNA viruses also have miRNAs but these were likely obtained from animal hosts via horizontal gene transfer . Interestingly, the miRNA biogenesis pathway shares several proteins with the siRNA processing pathway which is found throughout both unicellular and multicellular eukaryotes .
Among those capable species, there are some subtle yet significant differences in miRNA function. For example, plant miRNAs are exactly complementary to their target sequence while animal miRNA are tolerant of certain base-pair mismatches [29, 30]. In addition, the kinds and numbers of miRNA biogenesis proteins differ amongst various animal and plant species. Vertebrates have a single Dicer gene while the fruitfly, Drosophila melanogaster, has two genes, Dicer-1 (Dcr1) and Dicer-2 (Dcr2), the former of which is essential for miRNA processing . Thus, there is evidence for differential evolution of miRNA biogenesis and activation pathways.
In this study, we determined the phyletic occurrences and evolutionary relationships of four main families of miRNA processing proteins: Dicer, Argonaute, double-stranded RNA-binding proteins and Exportin-5. The goal of this work was to determine whether these key miRNA proteins descended from a common early ancestor or if these genes evolved from multiple events of emergence, specialization and adaptation in specific lineages. We show that the latter scenario as the most common evolutionary theme in miRNA biogenesis. With increasing evidence that most of the vertebrate genome, including so-called junk DNA, is actively transcribed, understanding the potential for additional classes of regulatory ncRNAs is of growing importance. Thus another aim of our evolutionary analysis is to suggest the existence of other candidate ncRNA processing proteins by virtue of their relationship to known miRNA pathway proteins.
Results and Discussion
RNaseIII enzymes are categorized into three classes, all of which contain at least one catalytic domain. Class I, found in bacteria and yeast, is the simplest having only a single RNaseIII domain and a double-stranded RNA (dsRNA) binding domain. Class II and Class III enzymes commonly have a second RNaseIII domain but are distinguishable from each other by specific auxiliary N-terminal domains. Drosha, a Class II enzyme, has proline-rich and arginine-serine (RS) domains while Dicer, a Class III enzyme, has helicase and PAZ (Piwi/Argonaute/Zwille) domains. As the name indicates, the PAZ domain is also found in Argonaute proteins, another essential group of RNAi processing enzymes.
In animals, the evolutionary situation is a little more complicated. Single Dicer genes occur in mammals and cold-blooded vertebrates which have direct orthologues in urochordates (represented in Fig. 1 by the tunicate, Ciona intestinalis) and deutrostomes (represented by the sea urchin, Strongylocentrotus purpuratus). Among protostomes, nematodes (Caenorhabditis sp.) have a single Dicer gene while Drosophila species, mosquito (Anopheles gambiae and Aedes aegypti) and possibly all arthropods, have two Dicer genes, Dcr1 and Dcr2. Unlike the situation for plants, insect Dicer gene duplications do not correspond with the divergence of arthropods from other metazoans since nematode Dicer splits the insect clade in the phylogenetic tree with significant bootstrap support (Fig. 1). Rather, DCR2 seems to be a more divergent group of RNaseIII enzymes which, in our tree, is basal to all other metazoan Dicer proteins. Drosophila and other insects have three RNaseIII enzymes, DCR1, DCR2 and Drosha. Mutational studies have shown that the Dcr1 gene is essential for miRNA in fruitfly , but not dsRNA processing. The converse is true for the Dcr2 gene where mutants have normal miRNA levels but have abnormal processing of dsRNAs. Drosophila Dicer is just one example of lineage-specific gene duplication and specialization in miRNA biogenesis over the course of eukaryotic evolution.
At the core of the RISC is Argonaute (AGO), highly basic ~100 kD proteins characterized by PAZ and PIWI domains. The N-terminal PAZ domain, also found in Dicer, is about 130 amino acids in length and is thought to function in protein-protein interactions (see review ). The C-terminal PIWI domain is approximately 300 amino acids in length. The exact functioning of these domains in miRNA processing is unknown although some clues have been revealed in recent structures of a PIWI-domain protein (AfPiwi) from the thermophilic Archaea, Archaeoglobus fulgidus, in complex with a small siRNA-like duplex [53, 54]. The miRNA seed region, comprised of nucleotides 2–8, is critical for target recognition . In the AfPiwi structure, the first nucleotide of the siRNA-like substrate is also unbound to the target sequence and locked into the protein binding pocket. The AfPiwi is an imperfect model for eukaryotic AGO because it lacks a PAZ domain. However, other evidence suggests that PAZ domains bind to 3' OH terminal ends of RNA or duplexes with 3' overhang . Therefore, PAZ and PIWI likely serve to align and stabilize small RNAs to their respective mRNA target sequences. The stabilized duplex with mRNA is subsequently either cleaved by siRNA or translationally repressed by miRNA.
In Drosophila, four AGO-like proteins have been identified which are dPiwi, dAubergine, dAGO1 and dAGO2 . dPiwi and dAubergine are expressed in embryos and appear to affect germline development. Phylogenetic analysis places dPiwi and dAubergine with other arthropod PIWI proteins which is the outgroup to vertebrate PIWI/MIWI proteins (Fig. 2). Both dAGO1 and dAGO2 are RISC components but with different small RNA specificities. Okamura et al. showed that Drosophila embryos lacking dAGO2 were siRNA-directed RNAi-defective but still capable of miRNA-directed target RNA cleavage. In contrast, dAGO1 deficient mutants were incapable of producing mature miRNAs while siRNA-directed target RNA cleavage was intact. Consistent with their findings, our phylogenetic analysis shows that of the four Drosophila Argonaute homologues, dAGO1 is most closely related to RISC associated AGO proteins involved with miRNA processing in vertebrates while dAGO2 is highly divergent. Nematodes also have multiple PIWI/Argonaute proteins of which two, Alg1 and Alg2, are the immediate outgroup to insect and vertebrate AGO proteins (Fig. 2 &3). The different roles of these proteins is unknown although indirect evidence suggests Alg1 might be recruited into the miRNA RISC .
Humans have eight Argonaute-like proteins , four of which fall into the wider PIWI family while the remainder are AGO proteins with orthologues in other mammals and vertebrates (Fig. 2). Homologues in insects and nematodes are clearly outgroups to all four vertebrate AGO isoforms (Fig. 3). All four mammalian genes AGO1–4 (EIF2C1–4) have orthologues in cold-blooded vertebrates (i.e. fish and amphibians). The urochordates (C. intestinalis) and deutrostomes (S. purpuratus), have only single AGO copies which appear ancestral to all vertebrate AGOs. In summary, phylogenetic analysis suggests that there was an early chordate radiation of the Argonaute gene family, possibly with the miRNA component AGO2 as the ancestor to the other three AGO proteins. In humans, AGO1, AGO3 and AGO4 are closely clustered together on chromosome 1 which also suggests their common evolution from a series of concurrent gene duplications.
The existence of other Argonaute/PIWI proteins leads to speculation that additional RISC-like ncRNA processing complexes might be found. Indeed, two recent reports describe a novel class of small RNAs isolated from mouse testis libraries which bind to two PIWI proteins, MIWI  and MILI  (see Fig 2 for the tentative phylogenetic position of vertebrate PIWI/MIWI proteins). These "PIWI-interacting RNAs" called piRNAs, might number in the thousands and appear to be encoded by specific genomic regions that are also conserved in rat and human. The biochemical processing of piRNAs as well as their putative regulatory functions are presently not well understood.
It should be noted that a fifth mammalian Argonaute gene called mAgo5 (GenBank accession no. AAN75582) has been reported for the mouse. This protein was identified through a homology search of the initial mouse genomic sequence made available by subscription from the company, Celera . The mAgo5 open reading frame (ORF) is fragmented with some regions being either highly divergent or deleted relative to other Argonaute proteins. Our phylogenetic analysis of the entire Argonaute/PIWI protein positions mAgo5 as a particularly long branch within the AGO2 cluster, close to the confirmed mouse AGO2 protein (Fig. 2). However, in a phylogenetic analysis restricted to metazoan Argonaute proteins, mAgo5 was the most divergent sequence and landed as the outgroup to both vertebrates and invertebrates (not shown) which suggests that its position in the full Argonauete/PIWI tree is an artifact. Our sequence database searches failed to reveal any mAgo5 orthologue in other mammals or cold-blooded vertebrates. Therefore, we suggest that unless confirmed by re-sequencing of genomic DNA, mAgo5 is likely an artifact from homology searches of incomplete DNA sequence assemblies of the Celera mouse genome.
Evolution of TRBP, Loquacious and Other RNA-binding Proteins
Our phylogenetic tree shows that Drosophila Loquacious, also found in other insects, is ancestral to both TRBP and PACT. Sea urchin and tunicate have single genes which appear to be evolutionary intermediates between invertebrate Loquacious and vertebrate TRBP/PACT. However, bootstrap and posterior probability support for this branching order is low which might reflect either the available partial amino acid sequences (at the time of manuscript submission, both sea urchin and tunicate genomes were incomplete) or the need for more extensive taxonomic sampling. Regardless, TRBP and PACT genes likely diverged in very early chordates since cold-blooded vertebrates, the fishes and amphibians, as well as mammalians have full complements of these genes. As suggested by its evolutionary relationships, PACT has been recently implicated in small RNA processing in partnership with TRBP and dicer .
Sequence database searches using TRBP revealed other related dsRNA binding proteins. As mentioned above, Drosophila R2D2 and C. elegans RDE-4, both known participants in RNAi processing, are distantly related to Loquacious, TRBP and PACT. Other evolutionary related dsRNA binding proteins are the Staufens, a family of proteins with a tubulin-binding domain which likely serve to transport mRNAs intra-cellularly using microtubules. There are two families of Staufens in mammals, Stau1 and Stau2, which seem to have specific functions in mRNA transport in neurons . In Drosophila, Staufens have been associated with a number of neurological functions including neurodegeneration  and long-term memory formation . Like miRNA precursors, Staufen-dsRNA complexes are transported out of the nucleus by Exportin-5 . Although Staufens have not been previously linked with ncRNAs, their similarity to three known dsRNA binding protein families in the miRNA pathway suggests that further study about their potential role in small RNA transport might be warranted. Recent studies suggest that Staufen-containing neuronal granules share several protein components, such as Me31B, with cytoplasmic P-bodies which are thought to be the sites for translational regulation by miRNA [75, 76].
Evolution of Exportin-5
The transfer of RNAs and proteins between the nucleus and the cytoplasm is facilitated by shuttling transporters which have specificity for various cargoes (reviewed in [77–79]). The importin-β family is a large group of karyopherin-related nuclear transporters, which includes proteins that facilitate both nuclear import (importins) and nuclear export (exportins). The directionality of transport in the importin-β family is determined by interactions with the small nuclear GTPase, Ran.
Aside from fungal Mtr10P, the three remaining exportins have an unusual phyletic occurrence. Exportin-1, Exportin-T and Exportin-5, are all encoded by the genomes of plants, cold-blooded vertebrates and mammals as well as fungi. Partial sequences corresponding to all three exportins were also found in the urochordate, Ciona intestinalis, although the lengths of contiguous sequences were too short for phylogenetic reconstruction (data not shown). Moreover, orthologues of all three exportins were identified in the sea urchin suggesting commonality across deutrostomes. In Arabidopsis, the Exportin-5 protein Hasty has been shown to transport miRNA  while the Exportin-T-like transporter, Paused facilitates tRNA export from the nucleus .
However, among protostome invertebrates there are some notable examples of missing exportins and shifts in RNA specificity. Drosophila exportin-5 also transports tRNAs which might compensate for the lack of exportin-T across arthropods . The nematodes, C. elegans and C. briggsae, lack Exportin-5 but have orthologues to Exportin-T and Exportin-1, the latter also called IMB-4 (Fig. 5). It is presently unclear how nematodes actually export miRNAs from the nucleus without Exportin-5, but IMB-4 or Exportin-T are possible candidates for this function .
Not surprisingly, putative Exportin-T and Exportin-1 homologues which function to shuttle other small RNAs besides miRNAs were also found in protists, such as species of Plasmodium, Trypanosomes and Leishmania. Other components of the RNA-silencing pathway have been detected in these species. However, no plausible miRNA gene orthologues have been detected outside of the metazoan  except for the unicellular algae, Chlamydomonas reinhardtii  Interestingly, our database search shows that fungi, which have regulation by siRNA but not miRNA, have genes encoding for Exportin-5, Exportin-1, and Exportin-T.
Discussion – Something Borrowed; Something New
There are many additional proteins involved in miRNA biogenesis and a thorough evolutionary analysis of all is beyond the scope of this report. However, preliminary phylogenetic trees for several other components (data not shown) show similarly diverse evolutionary patterns as Argonaute, Dicer, dsRNA-binding proteins and Exportin-5. Gemin4, Gemin5, and Tudor-SN are other examples where particular members of multi-protein families have specific roles in miRNA and siRNA processing and activation. In contrast, Drosophila Pasha and vertebrate DGCR8 are direct orthologues, without any lineage-specific gene duplications.
Different natural selection pressures between and within species might have also played a role in the occurrence of miRNA pathway genes and their levels of sequence divergence. Obbard et al.  recently showed that the siRNA pathway genes Dcr2, R2D2 and Ago2 are evolving rapidly in Drosophila which they provocatively suggest might a consequence of an antiviral "arms-race". Conversely, they demonstrate that the rates of amino acid substitutions were not elevated in miRNA associated genes, Ago2 and Dcr1 which might be due to constraints associated with the essential regulatory roles of miRNAs in many cellular functions.
The components of siRNA processing are ancient as evident from proteins with distant but recognizable motifs found in single-cell eukaryotes and, the case of Dicer, even bacteria and archaea have similar RNaseIII domains . However, genes encoding proteins specific for miRNA biogenesis seem to be more recent innovations. The diversity of miRNA pathway genes in plants, as well as metazoan protostomes, and deutrostomes, suggests that these three lineages had specific adaptations (Fig. 7). Two reports [45, 87] noted that further expansions of miRNA gene families themselves might have coincided with the emergence of bilaterians, vertebrates and mammals.
Our comparative genomic analyses show that urochordates (represented by the tunicate, C. intestinalis) and early deutrostomes (represented by the purple sea urchin, S. purpuratus) have single copies of vertebrate-like miRNA processing proteins. Provisional that no further gene copies are found once their entire genomes are completely sequenced, these species may represent the ancestral state of the deutrostome/chordate miRNA pathway which subsequently underwent specialization via gene duplications in early vertebrates. According to robust Bayesian phylogenetic analysis of multiple proteins concurrently calibrated with the fossil record, echinoderms (sea urchins and seastars) and protochordates (cephalochordates) diverged about 896 million years ago (MYA). Chordates and urochordates split more recently, about 794 MYA. In the most recent release of miRBASE (Sanger Center, release 10.1), there are no miRNAs reported for either urochordates or echinoderms. However, Hertel et al.  identified by homology searches, 40 new miRNA genes in S. purpuratus and 9 miRNA genes in two species of tunicates C. intestinalis and C. savignyii. Collectively with our analyses showing that miRNA biogenesis proteins are found in tunicates and sea urchins, these species probably do have rudimentary miRNA regulatory networks. The potential simplicity yet close vertebrate similarity of these species suggests that they might be intriguing systems to study the structure, function and evolution of miRNAs. Moreover, as genomic data is generated for intermediate groups between urochordates and jawed-fishes such as the jawless fishes (i.e. hagfish and lampreys), we might gain more insight into the specific stages in the evolution of the vertebrate miRNA pathway.
Finally, our study suggests that there are several other candidate proteins for processing small, ncRNAs. Indeed, divergent homologues to miRNA processing AGO2, the PIWI proteins, MIWI and MILI, have been recently shown to process a novel class of ncRNAs, the "PIWI-interacting RNAs" or piRNAs. Our study suggests that there are multiple Argonaute/PIWI as well as double-stranded RNA-binding proteins and exportins which, by evolutionary associations, are hypothesized to participate in the processing of additional classes of ncRNAs and might warrant further experimental investigation.
Protein (amino acid) sequences were retrieved from GenBank Nonredundant and species-specific databases (Ciona intestinalis [tunicate – urochordate] and Strongylocentrotus purpuratus [sea urchin – early deutrostome]) via BLASTP (default settings) searches using human miRNA pathway genes as the initial queries . As necessary, sequences from other species or additional paralogues (i.e. such as Exportin-T) were used to obtain a full set of homologues. Homology cut-offs were E-values ≤ 10e-10.
Initial multiple sequence alignments were performed using the program CLUSTALW v1.7  with default settings and subsequently, refined manually using the program SEQLAB of the GCG Wisconsin Package v11.0 software package (Accelrys, San Diego, CA, USA). We removed regions with residues that could not be unambiguously aligned or that contained insertions or deletions. Multiple sequence alignments are included as Additional files 1, 2, 3, 4, 5, 6. For each file, the first row titled "Analysis_1", marks with an "*" the columns of amino acids retained in the edited multiple sequence alignments for phylogenetic analysis.
We constructed phylogenetic trees using distance neighbor-joining (NJ), maximum parsimony (MP), and Bayesian posterior probabilities (BP). NJ trees were based on pair wise distances between amino acid sequences using the programs NEIGHBOR and PROTDIST (Dayhoff option) of the PHYLIP 3.6 package . The programs SEQBOOT and CONSENSE were used to estimate the confidence limits of branching points from 1000 bootstrap replications. MP analysis was performed using PAUP4.0b5 software  where the number and lengths of minimal trees were estimated from 100 random sequence additions, while confidence limits of branch points were estimated by 1000 bootstrap replications. BP trees were constructed using the software MrBayes v3.0B4 [93, 94]. Bayesian analysis used the mixed model of sequence evolution with random starting trees. Markov chains were run for 106 generations, burn-in values were set for 104 generations, and trees sampled every 100 generations. All trees were visualized using the program TREEVIEW v1.6.6 . Subsets of Argonaute and Exportin protein family members that were known to be involved in miRNA biogenesis were also re-aligned and subjected to separate phylogenetic analysis.
The Dicer phylogeny shown in Fig. 1 was based on an edited alignment of 926 amino acids. One minimal length MP trees were recovered, 3020 steps in length with a consistency index (CI) of 0.6907 and a retention index (RI) of 0.6629. The Argonaute/PIWI phylogeny shown in Fig. 2 was based on an edited alignment of 288 amino acids. MP analysis recovered 214 minimal length trees, 6035 steps in length with a consistency index (CI) of 0.3934 and a retention index (RI) of 0.6699. The variable branch arrangements were among certain terminal nodes within of the each AGO protein.
The animal Argonaute phylogeny shown in Fig. 3 was based on an edited alignment of 834 amino acids. MP analysis recovered 200 minimal length trees, 2538 steps in length with a consistency index (CI) of 0.7281 and a retention index (RI) of 0.8938. The variable branch arrangements were among certain terminal nodes (mammals) within of the each vertebrate Ago families, Ago1–4. However, separate monophyly of each Ago family was strongly supported by all phylogenetic methods. The double-stranded RNA-binding protein tree shown in Fig. 4 was based on an edited alignment of 156 amino acids. MP analysis recovered 34 minimal length trees, 1334 steps in length with a consistency index (CI) of 0.6402 and a retention index (RI) of 0.8294. The variable branch arrangements were among certain terminal nodes within vertebrate clades of Staufens, PACT and TRBP which did not affect the central findings. The Exportin/Mtr10P phylogeny shown in Fig. 5 was based on an edited alignment of 392 amino acids. MP analysis recovered 20025 minimal length trees, 10368 steps in length with a consistency index (CI) of 0.4169 and a retention index (RI) of 0.7567. The variable branching concerned terminal branches which did not affect the main observations of this tree. The Exportin 5 phylogeny Fig. 6 was based on an edited alignment of 809 amino acids. MP analysis recovered four minimal length trees, 6186 steps in length with a consistency index (CI) of 0.7118 and a retention index (RI) of 0.8110. The variable branching concerned the two fish Exportin 5 proteins relative to each other which, also, did not affect the central findings.
For Fig. 2, the species (with abbreviations) included in the tree are Anopheles gambiae (ANGA), Apis mellifera (APIS), Arabidopsis thaliana (ARTH), Aspergillus nidulans (ASNI), Blumeria graminis (BLGR), Candida albicans (CAAL), Bos taurus (COW), Cryptococcus neoformans (CRNE), Danio rerio (DARE), Drosophila melanogaster (DRME), Takifugu ribripes (FUGU), Gallus gallus (GAGA), Gibberella zeae (GIZE), Homo sapiens (HOSA), Magnaporthe grisea (MAGR), Mus musculus (MUS), Neurospora crassa (NECR), Oryza sativa (ORSA), Podocoryne carnea (POCA), Oryctolagus cuniculus (RABBIT), Rattus norvegicus (RAT), Schizosaccharomyces pombe (SCPO), Stylonychia lemnae (STLE), Strongylocentrotus purpuratus (STPU), Tetraodon nigroviridis (TENI), Xenopus laevis (XELA), and Xenopus tropicalis (XETR).
For Fig. 5, species (and abbreviations) included in the tree are Aedes aegypti (AEAE), Anopheles gambiae (ANGA), Apis mellifera (APIS), Arabidopsis thaliana (ARTH), Aspergillus clavatus (ASCL), Aspergillus fumigatus (ASFU), Ashbya gossypii (ASGO), Aspergillus nidulans (ASNI), Aspergillus oryzae (ASOR), Aspergillus terreus (ASTE), Candida albicans (CAAL), Candida glabrata (CAGL), Chaetomium globosum (CHGL), Chironomus tentans (CHTE), Bos taurus (COW), Coprinopsis cinerea (COCI), Coccidioides immitis (COIM), Cryptococcus neoformans (CRNE), Danio rerio (DARE), Debaryomyces hansenii (DEHA), Dictyostelium discoideum (DIDI), Canis lupus familiaris (DOG), Drosophila erecta (DRER), Drosophila melanogaster (DRME), Drosophila pseudoobscura (DRPS), Drosophila simulans (DRSI), Drosophila yakuba (DRYA), Emericella nidulans (EMNI), Ashbya gossypii [Eremothecium gossypii] (ERGO), Gallus gallus (GAGA), Gibberella zeae (GIZE), Homo sapiens (HOSA), Kluyveromyces lactis (KLLA), Leishmania major (LEMA), Macaca mulatta (MAMU), Magnaporthe grisea (MAGR), Medicago truncatula (METR), Mus musculus (MUS), Neosartorya fischeri (NEFI), Neurospora crassa (NECR), Oryza sativa (ORSA), Ostreococcus tauri (OSTA), Pan troglodytes (PATR), Phaeosphaeria nodorum (PHNP), Plasmodium berghei (PLBE), Plasmodium falciparum (PLFA), Podospora anserine (POAN), Pongo pygmaeus (POPY), Rattus norvegicus (RAT), Saccharomyces cerevisiae (SACE), Schizosaccharomyces pombe (SCPO), Strongylocentrotus purpuratus (STPU), Tetraodon nigroviridis (TENI), Tetrahymena thermophila (TETH), Trypanosoma brucei (TRBU), Tribolium castaneum (TRCA), Trypanosoma cruzi (TRCU), Ustilago maydis (USMA), Xenopus laevis (XELA), Xenopus tropicalis (XETR), and Yarrowia lipolytica (YALI).
This work was supported by Bioinformatics, Molecular Discovery Research, GlaxoSmithKline. We wish to thank Philippe Sanseau and two anonymous reviewers for their comments on this manuscript.
- Brown JR, Sanseau P: A computational view of microRNAs and their targets. Drug Discov Today. 2005, 10: 595-601. 10.1016/S1359-6446(05)03399-4.View ArticlePubMedGoogle Scholar
- Bushati N, Cohen SM: microRNA Functions. Annu Rev Cell Dev Biol. 2007Google Scholar
- Zhang B, Wang Q, Pan X: MicroRNAs and their regulatory roles in animals and plants. J Cell Physiol. 2007, 210: 279-289. 10.1002/jcp.20869.View ArticlePubMedGoogle Scholar
- Sunkar R, Chinnusamy V, Zhu J, Zhu JK: Small RNAs as big players in plant abiotic stress responses and nutrient deprivation. Trends Plant Sci. 2007, 12: 301-309. 10.1016/j.tplants.2007.05.001.View ArticlePubMedGoogle Scholar
- Cobb J, Duboule D: Tracing microRNA patterns in mice. Nat Genet. 2004, 36: 1033-1034. 10.1038/ng1004-1033.View ArticlePubMedGoogle Scholar
- Mersey BD, Jin P, Danner DJ: Human microRNA (miR29b) expression controls the amount of branched chain alpha-ketoacid dehydrogenase complex in a cell. Hum Mol Genet. 2005, 14: 3371-3377. 10.1093/hmg/ddi368.View ArticlePubMedGoogle Scholar
- Perera RJ, Ray A: MicroRNAs in the search for understanding human diseases. BioDrugs. 2007, 21: 97-104. 10.2165/00063030-200721020-00004.View ArticlePubMedGoogle Scholar
- Chang TC, Mendell JT: The Roles of microRNAs in Vertebrate Physiology and Human Disease. Annu Rev Genomics Hum Genet. 2007Google Scholar
- Croce CM, Calin GA: miRNAs, cancer, and stem cell division. Cell. 2005, 122: 6-7. 10.1016/j.cell.2005.06.036.View ArticlePubMedGoogle Scholar
- Esquela-Kerscher A, Slack FJ: Oncomirs - microRNAs with a role in cancer. Nat Rev Cancer. 2006, 6: 259-269. 10.1038/nrc1840.View ArticlePubMedGoogle Scholar
- Jay C, Nemunaitis J, Chen P, Fulgham P, Tong AW: miRNA profiling for diagnosis and prognosis of human cancer. DNA Cell Biol. 2007, 26: 293-300. 10.1089/dna.2006.0554.View ArticlePubMedGoogle Scholar
- Callis TE, Chen JF, Wang DZ: MicroRNAs in skeletal and cardiac muscle development. DNA Cell Biol. 2007, 26: 219-225. 10.1089/dna.2006.0556.View ArticlePubMedGoogle Scholar
- Care A, Catalucci D, Felicetti F, Bonci D, Addario A, Gallo P, Bang ML, Segnalini P, Gu Y, Dalton ND, Elia L, Latronico MV, Hoydal M, Autore C, Russo MA, Dorn GW, Ellingsen O, Ruiz-Lozano P, Peterson KL, Croce CM, Peschle C, Condorelli G: MicroRNA-133 controls cardiac hypertrophy. Nat Med. 2007, 13: 613-618. 10.1038/nm1582.View ArticlePubMedGoogle Scholar
- Pfeffer S, Sewer A, Lagos-Quintana M, Sheridan R, Sander C, Grasser FA, van Dyk LF, Ho CK, Shuman S, Chien M, Russo JJ, Ju J, Randall G, Lindenbach BD, Rice CM, Simon V, Ho DD, Zavolan M, Tuschl T: Identification of microRNAs of the herpesvirus family. Nat Methods. 2005, 2: 269-276. 10.1038/nmeth746.View ArticlePubMedGoogle Scholar
- Grey F, Antoniewicz A, Allen E, Saugstad J, McShea A, Carrington JC, Nelson J: Identification and characterization of human cytomegalovirus-encoded microRNAs. J Virol. 2005, 79: 12095-12099. 10.1128/JVI.79.18.12095-12099.2005.PubMed CentralView ArticlePubMedGoogle Scholar
- Sullivan CS, Ganem D: MicroRNAs and viral infection. Mol Cell. 2005, 20: 3-7. 10.1016/j.molcel.2005.09.012.View ArticlePubMedGoogle Scholar
- Yeung ML, Bennasser Y, Myers TG, Jiang G, Benkirane M, Jeang KT: Changes in microRNA expression profiles in HIV-1-transfected human cells. Retrovirology. 2005, 2: 81-10.1186/1742-4690-2-81.PubMed CentralView ArticlePubMedGoogle Scholar
- Weiler J, Hunziker J, Hall J: Anti-miRNA oligonucleotides (AMOs): ammunition to target miRNAs implicated in human disease?. Gene Ther. 2006, 13: 496-502. 10.1038/sj.gt.3302654.View ArticlePubMedGoogle Scholar
- Esau CC, Monia BP: Therapeutic potential for microRNAs. Adv Drug Deliv Rev. 2007, 59: 101-114. 10.1016/j.addr.2007.03.007.View ArticlePubMedGoogle Scholar
- Qu J, Ye J, Fang R: Artificial microRNA-mediated virus resistance in plants. J Virol. 2007, 81: 6690-6699. 10.1128/JVI.02457-06.PubMed CentralView ArticlePubMedGoogle Scholar
- Bentwich I, Avniel A, Karov Y, Aharonov R, Gilad S, Barad O, Barzilai A, Einat P, Einav U, Meiri E, Sharon E, Spector Y, Bentwich Z: Identification of hundreds of conserved and nonconserved human microRNAs. Nat Genet. 2005, 37: 766-770. 10.1038/ng1590.View ArticlePubMedGoogle Scholar
- Lim LP, Lau NC, Weinstein EG, Abdelhakim A, Yekta S, Rhoades MW, Burge CB, Bartel DP: The microRNAs of Caenorhabditis elegans. Genes Dev. 2003, 17: 991-1008. 10.1101/gad.1074403.PubMed CentralView ArticlePubMedGoogle Scholar
- Tanzer A, Amemiya CT, Kim CB, Stadler PF: Evolution of microRNAs located within Hox gene clusters. J Exp Zoolog B Mol Dev Evol. 2005, 304: 75-85. 10.1002/jez.b.21021.View ArticleGoogle Scholar
- Tanzer A, Stadler PF: Molecular evolution of a microRNA cluster. J Mol Biol. 2004, 339: 327-335. 10.1016/j.jmb.2004.03.065.View ArticlePubMedGoogle Scholar
- Houbaviy HB, Dennis L, Jaenisch R, Sharp PA: Characterization of a highly variable eutherian microRNA gene. RNA. 2005, 11: 1245-1257. 10.1261/rna.2890305.PubMed CentralView ArticlePubMedGoogle Scholar
- Berezikov E, Thuemmler F, van Laake LW, Kondova I, Bontrop R, Cuppen E, Plasterk RH: Diversity of microRNAs in human and chimpanzee brain. Nat Genet. 2006, 38: 1375-1377. 10.1038/ng1914.View ArticlePubMedGoogle Scholar
- Zhang B, Pan X, Cannon CH, Cobb GP, Anderson TA: Conservation and divergence of plant microRNA genes. Plant J. 2006, 46: 243-259. 10.1111/j.1365-313X.2006.02697.x.View ArticlePubMedGoogle Scholar
- He L, Hannon GJ: MicroRNAs: small RNAs with a big role in gene regulation. Nat Rev Genet. 2004, 5: 522-531. 10.1038/nrg1379.View ArticlePubMedGoogle Scholar
- Ambros V: The functions of animal microRNAs. Nature. 2004, 431: 350-355. 10.1038/nature02871.View ArticlePubMedGoogle Scholar
- Baulcombe D: RNA silencing in plants. Nature. 2004, 431: 356-363. 10.1038/nature02874.View ArticlePubMedGoogle Scholar
- Hammond SM: Dicing and slicing: the core machinery of the RNA interference pathway. FEBS Lett. 2005, 579: 5822-5829. 10.1016/j.febslet.2005.08.079.View ArticlePubMedGoogle Scholar
- Denli AM, Tops BB, Plasterk RH, Ketting RF, Hannon GJ: Processing of primary microRNAs by the Microprocessor complex. Nature. 2004, 432: 231-235. 10.1038/nature03049.View ArticlePubMedGoogle Scholar
- Lund E, Guttinger S, Calado A, Dahlberg JE, Kutay U: Nuclear export of microRNA precursors. Science. 2004, 303: 95-98. 10.1126/science.1090599.View ArticlePubMedGoogle Scholar
- Ketting RF, Fischer SE, Bernstein E, Sijen T, Hannon GJ, Plasterk RH: Dicer functions in RNA interference and in synthesis of small RNA involved in developmental timing in C. elegans. Genes Dev. 2001, 15: 2654-2659. 10.1101/gad.927801.PubMed CentralView ArticlePubMedGoogle Scholar
- Chendrimada TP, Gregory RI, Kumaraswamy E, Norman J, Cooch N, Nishikura K, Shiekhattar R: TRBP recruits the Dicer complex to Ago2 for microRNA processing and gene silencing. Nature. 2005, 436: 740-744. 10.1038/nature03868.PubMed CentralView ArticlePubMedGoogle Scholar
- Haase AD, Jaskiewicz L, Zhang H, Laine S, Sack R, Gatignol A, Filipowicz W: TRBP, a regulator of cellular PKR and HIV-1 virus expression, interacts with Dicer and functions in RNA silencing. EMBO Rep. 2005, 6: 961-967. 10.1038/sj.embor.7400509.PubMed CentralView ArticlePubMedGoogle Scholar
- Forstemann K, Tomari Y, Du T, Vagin VV, Denli AM, Bratu DP, Klattenhoff C, Theurkauf WE, Zamore PD: Normal microRNA maturation and germ-line stem cell maintenance requires Loquacious, a double-stranded RNA-binding domain protein. PLoS Biol. 2005, 3: e236-10.1371/journal.pbio.0030236.PubMed CentralView ArticlePubMedGoogle Scholar
- Carmell MA, Xuan Z, Zhang MQ, Hannon GJ: The Argonaute family: tentacles that reach into RNAi, developmental control, stem cell maintenance, and tumorigenesis. Genes Dev. 2002, 16: 2733-2742. 10.1101/gad.1026102.View ArticlePubMedGoogle Scholar
- Meister G, Landthaler M, Patkaniowska A, Dorsett Y, Teng G, Tuschl T: Human Argonaute2 mediates RNA cleavage targeted by miRNAs and siRNAs. Mol Cell. 2004, 15: 185-197. 10.1016/j.molcel.2004.07.007.View ArticlePubMedGoogle Scholar
- Liu J, Carmell MA, Rivas FV, Marsden CG, Thomson JM, Song JJ, Hammond SM, Joshua-Tor L, Hannon GJ: Argonaute2 is the catalytic engine of mammalian RNAi. Science. 2004, 305: 1437-1441. 10.1126/science.1102513.View ArticlePubMedGoogle Scholar
- Caudy AA, Myers M, Hannon GJ, Hammond SM: Fragile X-related protein and VIG associate with the RNA interference machinery. Genes Dev. 2002, 16: 2491-2496. 10.1101/gad.1025202.PubMed CentralView ArticlePubMedGoogle Scholar
- Caudy AA, Ketting RF, Hammond SM, Denli AM, Bathoorn AM, Tops BB, Silva JM, Myers MM, Hannon GJ, Plasterk RH: A micrococcal nuclease homologue in RNAi effector complexes. Nature. 2003, 425: 411-414. 10.1038/nature01956.View ArticlePubMedGoogle Scholar
- Zhang H, Kolb FA, Jaskiewicz L, Westhof E, Filipowicz W: Single processing center models for human Dicer and bacterial RNase III. Cell. 2004, 118: 57-68. 10.1016/j.cell.2004.06.017.View ArticlePubMedGoogle Scholar
- Berezikov E, Plasterk RH: Camels and zebrafish, viruses and cancer: a microRNA update. Hum Mol Genet. 2005, 14 Spec No. 2: R183-R190. 10.1093/hmg/ddi271.View ArticlePubMedGoogle Scholar
- Hertel J, Lindemeyer M, Missal K, Fried C, Tanzer A, Flamm C, Hofacker IL, Stadler PF: The expansion of the metazoan microRNA repertoire. BMC Genomics. 2006, 7: 25-10.1186/1471-2164-7-25.PubMed CentralView ArticlePubMedGoogle Scholar
- Cerutti H, Casas-Mollano JA: On the origin and functions of RNA-mediated silencing: from protists to man. Curr Genet. 2006, 50: 81-99. 10.1007/s00294-006-0078-x.PubMed CentralView ArticlePubMedGoogle Scholar
- Molnar A, Schwach F, Studholme DJ, Thuenemann EC, Baulcombe DC: miRNAs control gene expression in the single-cell alga Chlamydomonas reinhardtii. Nature. 2007, 447: 1126-1129. 10.1038/nature05903.View ArticlePubMedGoogle Scholar
- Siomi H, Siomi MC: Expanding RNA physiology: microRNAs in a unicellular organism. Genes Dev. 2007, 21: 1153-1156. 10.1101/gad.1559707.View ArticlePubMedGoogle Scholar
- Lee YS, Nakahara K, Pham JW, Kim K, He Z, Sontheimer EJ, Carthew RW: Distinct roles for Drosophila Dicer-1 and Dicer-2 in the siRNA/miRNA silencing pathways. Cell. 2004, 117: 69-81. 10.1016/S0092-8674(04)00261-2.View ArticlePubMedGoogle Scholar
- Mochizuki K, Gorovsky MA: A Dicer-like protein in Tetrahymena has distinct functions in genome rearrangement, chromosome segregation, and meiotic prophase. Genes Dev. 2005, 19: 77-89. 10.1101/gad.1265105.PubMed CentralView ArticlePubMedGoogle Scholar
- Xie Z, Allen E, Wilken A, Carrington JC: DICER-LIKE 4 functions in trans-acting small interfering RNA biogenesis and vegetative phase change in Arabidopsis thaliana. Proc Natl Acad Sci U S A. 2005, 102: 12984-12989. 10.1073/pnas.0506426102.PubMed CentralView ArticlePubMedGoogle Scholar
- Blevins T, Rajeswaran R, Shivaprasad PV, Beknazariants D, Si-Ammour A, Park HS, Vazquez F, Robertson D, Meins F, Hohn T, Pooggin MM: Four plant Dicers mediate viral small RNA biogenesis and DNA virus induced silencing. Nucleic Acids Res. 2006, 34: 6233-6246. 10.1093/nar/gkl886.PubMed CentralView ArticlePubMedGoogle Scholar
- Parker JS, Roe SM, Barford D: Structural insights into mRNA recognition from a PIWI domain-siRNA guide complex. Nature. 2005, 434: 663-666. 10.1038/nature03462.PubMed CentralView ArticlePubMedGoogle Scholar
- Ma JB, Yuan YR, Meister G, Pei Y, Tuschl T, Patel DJ: Structural basis for 5'-end-specific recognition of guide RNA by the A. fulgidus Piwi protein. Nature. 2005, 434: 666-670. 10.1038/nature03514.View ArticlePubMedGoogle Scholar
- Lai EC: miRNAs: whys and wherefores of miRNA-mediated regulation. Curr Biol. 2005, 15: R458-R460. 10.1016/j.cub.2005.06.015.View ArticlePubMedGoogle Scholar
- Hall TM: Structure and function of argonaute proteins. Structure. 2005, 13: 1403-1408. 10.1016/j.str.2005.08.005.View ArticlePubMedGoogle Scholar
- Cikaluk DE, Tahbaz N, Hendricks LC, DiMattia GE, Hansen D, Pilgrim D, Hobman TC: GERp95, a membrane-associated protein that belongs to a family of proteins involved in stem cell differentiation. Mol Biol Cell. 1999, 10: 3357-3372.PubMed CentralView ArticlePubMedGoogle Scholar
- Sen GL, Blau HM: Argonaute 2/RISC resides in sites of mammalian mRNA decay known as cytoplasmic bodies. Nat Cell Biol. 2005, 7: 633-636. 10.1038/ncb1265.View ArticlePubMedGoogle Scholar
- Hengst U, Cox LJ, Macosko EZ, Jaffrey SR: Functional and selective RNA interference in developing axons and growth cones. J Neurosci. 2006, 26: 5727-5732. 10.1523/JNEUROSCI.5229-05.2006.View ArticlePubMedGoogle Scholar
- Okamura K, Ishizuka A, Siomi H, Siomi MC: Distinct roles for Argonaute proteins in small RNA-directed RNA cleavage pathways. Genes Dev. 2004, 18: 1655-1666. 10.1101/gad.1210204.PubMed CentralView ArticlePubMedGoogle Scholar
- Ding L, Spencer A, Morita K, Han M: The developmental timing regulator AIN-1 interacts with miRISCs and may target the argonaute protein ALG-1 to cytoplasmic P bodies in C. elegans. Mol Cell. 2005, 19: 437-447. 10.1016/j.molcel.2005.07.013.View ArticlePubMedGoogle Scholar
- Sasaki T, Shiohama A, Minoshima S, Shimizu N: Identification of eight members of the Argonaute family in the human genome small star, filled. Genomics. 2003, 82: 323-330. 10.1016/S0888-7543(03)00129-0.View ArticlePubMedGoogle Scholar
- Girard A, Sachidanandam R, Hannon GJ, Carmell MA: A germline-specific class of small RNAs binds mammalian Piwi proteins. Nature. 2006, 442: 199-202.PubMedGoogle Scholar
- Aravin A, Gaidatzis D, Pfeffer S, Lagos-Quintana M, Landgraf P, Iovino N, Morris P, Brownstein MJ, Kuramochi-Miyagawa S, Nakano T, Chien M, Russo JJ, Ju J, Sheridan R, Sander C, Zavolan M, Tuschl T: A novel class of small RNAs bind to MILI protein in mouse testes. Nature. 2006, 442: 203-207.PubMedGoogle Scholar
- Liu Q, Rand TA, Kalidas S, Du F, Kim HE, Smith DP, Wang X: R2D2, a bridge between the initiation and effector steps of the Drosophila RNAi pathway. Science. 2003, 301: 1921-1925. 10.1126/science.1088710.View ArticlePubMedGoogle Scholar
- Tabara H, Yigit E, Siomi H, Mello CC: The dsRNA binding protein RDE-4 interacts with RDE-1, DCR-1, and a DExH-box helicase to direct RNAi in C. elegans. Cell. 2002, 109: 861-871. 10.1016/S0092-8674(02)00793-6.View ArticlePubMedGoogle Scholar
- Rossi JJ: Mammalian Dicer finds a partner. EMBO Rep. 2005, 6: 927-929. 10.1038/sj.embor.7400531.PubMed CentralView ArticlePubMedGoogle Scholar
- Gupta V, Huang X, Patel RC: The carboxy-terminal, M3 motifs of PACT and TRBP have opposite effects on PKR activity. Virology. 2003, 315: 283-291. 10.1016/S0042-6822(03)00589-0.View ArticlePubMedGoogle Scholar
- Dorin D, Bonnet MC, Bannwarth S, Gatignol A, Meurs EF, Vaquero C: The TAR RNA-binding protein, TRBP, stimulates the expression of TAR-containing RNAs in vitro and in vivo independently of its ability to inhibit the dsRNA-dependent kinase PKR. J Biol Chem. 2003, 278: 4440-4448. 10.1074/jbc.M208954200.View ArticlePubMedGoogle Scholar
- Kok KH, Ng MH, Ching YP, Jin DY: Human TRBP and PACT directly interact with each other and associate with dicer to facilitate the production of small interfering RNA. J Biol Chem. 2007, 282: 17649-17657. 10.1074/jbc.M611768200.View ArticlePubMedGoogle Scholar
- Duchaine TF, Hemraj I, Furic L, Deitinghoff A, Kiebler MA, DesGroseillers L: Staufen2 isoforms localize to the somatodendritic domain of neurons and interact with different organelles. J Cell Sci. 2002, 115: 3285-3295.PubMedGoogle Scholar
- Mutsuddi M, Marshall CM, Benzow KA, Koob MD, Rebay I: The spinocerebellar ataxia 8 noncoding RNA causes neurodegeneration and associates with staufen in Drosophila. Curr Biol. 2004, 14: 302-308.View ArticlePubMedGoogle Scholar
- Dubnau J, Chiang AS, Grady L, Barditch J, Gossweiler S, McNeil J, Smith P, Buldoc F, Scott R, Certa U, Broger C, Tully T: The staufen/pumilio pathway is involved in Drosophila long-term memory. Curr Biol. 2003, 13: 286-296. 10.1016/S0960-9822(03)00064-2.View ArticlePubMedGoogle Scholar
- Macchi P, Brownawell AM, Grunewald B, DesGroseillers L, Macara IG, Kiebler MA: The brain-specific double-stranded RNA-binding protein Staufen2: nucleolar accumulation and isoform-specific exportin-5-dependent export. J Biol Chem. 2004, 279: 31440-31444. 10.1074/jbc.C400226200.View ArticlePubMedGoogle Scholar
- Barbee SA, Estes PS, Cziko AM, Hillebrand J, Luedeman RA, Coller JM, Johnson N, Howlett IC, Geng C, Ueda R, Brand AH, Newbury SF, Wilhelm JE, Levine RB, Nakamura A, Parker R, Ramaswami M: Staufen- and FMRP-containing neuronal RNPs are structurally and functionally related to somatic P bodies. Neuron. 2006, 52: 997-1009. 10.1016/j.neuron.2006.10.028.PubMed CentralView ArticlePubMedGoogle Scholar
- Hillebrand J, Barbee SA, Ramaswami M: P-body components, microRNA regulation, and synaptic plasticity. ScientificWorldJournal. 2007, 7: 178-190.View ArticlePubMedGoogle Scholar
- Chook YM, Blobel G: Karyopherins and nuclear import. Curr Opin Struct Biol. 2001, 11: 703-715. 10.1016/S0959-440X(01)00264-0.View ArticlePubMedGoogle Scholar
- Kuersten S, Ohno M, Mattaj IW: Nucleocytoplasmic transport: Ran, beta and beyond. Trends Cell Biol. 2001, 11: 497-503. 10.1016/S0962-8924(01)02144-4.View ArticlePubMedGoogle Scholar
- Weis K: Nucleocytoplasmic transport: cargo trafficking across the border. Curr Opin Cell Biol. 2002, 14: 328-335. 10.1016/S0955-0674(02)00337-X.View ArticlePubMedGoogle Scholar
- Gwizdek C, Ossareh-Nazari B, Brownawell AM, Evers S, Macara IG, Dargemont C: Minihelix-containing RNAs mediate exportin-5-dependent nuclear export of the double-stranded RNA-binding protein ILF3. J Biol Chem. 2004, 279: 884-891. 10.1074/jbc.M306808200.View ArticlePubMedGoogle Scholar
- Chen T, Brownawell AM, Macara IG: Nucleocytoplasmic shuttling of JAZ, a new cargo protein for exportin-5. Mol Cell Biol. 2004, 24: 6608-6619. 10.1128/MCB.24.15.6608-6619.2004.PubMed CentralView ArticlePubMedGoogle Scholar
- Park MY, Wu G, Gonzalez-Sulser A, Vaucheret H, Poethig RS: Nuclear processing and export of microRNAs in Arabidopsis. Proc Natl Acad Sci U S A. 2005, 102: 3691-3696. 10.1073/pnas.0405570102.PubMed CentralView ArticlePubMedGoogle Scholar
- Hunter CA, Aukerman MJ, Sun H, Fokina M, Poethig RS: PAUSED encodes the Arabidopsis exportin-t ortholog. Plant Physiol. 2003, 132: 2135-2143. 10.1104/pp.103.023309.PubMed CentralView ArticlePubMedGoogle Scholar
- Shibata S, Sasaki M, Miki T, Shimamoto A, Furuichi Y, Katahira J, Yoneda Y: Exportin-5 orthologues are functionally divergent among species. Nucleic Acids Res. 2006, 34: 4711-4721. 10.1093/nar/gkl663.PubMed CentralView ArticlePubMedGoogle Scholar
- Bohnsack MT, Czaplinski K, Gorlich D: Exportin 5 is a RanGTP-dependent dsRNA-binding protein that mediates nuclear export of pre-miRNAs. RNA. 2004, 10: 185-191. 10.1261/rna.5167604.PubMed CentralView ArticlePubMedGoogle Scholar
- Obbard DJ, Jiggins FM, Halligan DL, Little TJ: Natural selection drives extremely rapid evolution in antiviral RNAi genes. Curr Biol. 2006, 16: 580-585. 10.1016/j.cub.2006.01.065.View ArticlePubMedGoogle Scholar
- Prochnik SE, Rokhsar DS, Aboobaker AA: Evidence for a microRNA expansion in the bilaterian ancestor. Dev Genes Evol. 2007, 217: 73-77. 10.1007/s00427-006-0116-1.View ArticlePubMedGoogle Scholar
- Blair JE, Hedges SB: Molecular phylogeny and divergence times of deuterostome animals. Mol Biol Evol. 2005, 22: 2275-2284. 10.1093/molbev/msi225.View ArticlePubMedGoogle Scholar
- Altschul SF, Madden TL, Schaffer AA, Zhang J, Zhang Z, Miller W, Lipman DJ: Gapped BLAST and PSI-BLAST: a new generation of protein database search programs. Nucleic Acids Res. 1997, 25: 3389-3402. 10.1093/nar/25.17.3389.PubMed CentralView ArticlePubMedGoogle Scholar
- Thompson JD, Higgins DG, Gibson TJ: CLUSTAL W: improving the sensitivity of progressive multiple sequence alignment through sequence weighting, position-specific gap penalties and weight matrix choice. Nucleic Acids Res. 1994, 22: 4673-4680. 10.1093/nar/22.22.4673.PubMed CentralView ArticlePubMedGoogle Scholar
- Felsentein J: PHYLIP (Phylogenetic Inference Package). 2000, Seattle, Department of Genetics, University of WashingtonGoogle Scholar
- Swofford DL: PAUP*. Phylogenetic Analysis Using Parsimony (*and Other Methods). 1999, Sunderland, Massachusetts, Sinauer AssociatesGoogle Scholar
- Huelsenbeck JP, Ronquist F: MRBAYES: Bayesian inference of phylogenetic trees. Bioinformatics. 2001, 17: 754-755. 10.1093/bioinformatics/17.8.754.View ArticlePubMedGoogle Scholar
- Ronquist F, Huelsenbeck JP: MrBayes 3: Bayesian phylogenetic inference under mixed models. Bioinformatics. 2003, 19: 1572-1574. 10.1093/bioinformatics/btg180.View ArticlePubMedGoogle Scholar
- Page RD: TreeView: an application to display phylogenetic trees on personal computers. Comput Appl Biosci. 1996, 12: 357-358.PubMedGoogle Scholar
- Maddison DR, Schulz KS: The Tree of Life Web Project http://tolweb.org. Edited by: Maddison DR and Schulz KS. 2007, [http://tolweb.org]Google Scholar
This article is published under license to BioMed Central Ltd. This is an Open Access article distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/2.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.