Dynamic conformational model for the role of ITS2 in pre-rRNA processing in yeast

A close-up view on ITS2 evolution and speciation - a case study in the Ulvophyceae (Chlorophyta, Viridiplantae)

BACKGROUND

The second Internal Transcriber Spacer (ITS2) is a fast evolving part of the nuclear-encoded rRNA operon located between the 5.8S and 28S rRNA genes. Based on crossing experiments it has been proposed that even a single Compensatory Base Change (CBC) in helices 2 and 3 of the ITS2 indicates sexual incompatibility and thus separates biological species. Taxa without any CBC in these ITS2 regions were designated as a 'CBC clade'. However, in depth comparative analyses of ITS2 secondary structures, ITS2 phylogeny, the origin of CBCs, and their relationship to biological species have rarely been performed. To gain 'close-up' insights into ITS2 evolution, (1) 86 sequences of ITS2 including secondary structures have been investigated in the green algal order Ulvales (Chlorophyta, Viridiplantae), (2) after recording all existing substitutions, CBCs and hemi-CBCs (hCBCs) were mapped upon the ITS2 phylogeny, rather than merely comparing ITS2 characters among pairs of taxa, and (3) the relation between CBCs, hCBCs, CBC clades, and the taxonomic level of organisms was investigated in detail.

RESULTS

High sequence and length conservation allowed the generation of an ITS2 consensus secondary structure, and introduction of a novel numbering system of ITS2 nucleotides and base pairs. Alignments and analyses were based on this structural information, leading to the following results: (1) in the Ulvales, the presence of a CBC is not linked to any particular taxonomic level, (2) most CBC 'clades' sensu Coleman are paraphyletic, and should rather be termed CBC grades. (3) the phenetic approach of pairwise comparison of sequences can be misleading, and thus, CBCs/hCBCs must be investigated in their evolutionary context, including homoplasy events (4) CBCs and hCBCs in ITS2 helices evolved independently, and we found no evidence for a CBC that originated via a two-fold hCBC substitution.

CONCLUSIONS

Our case study revealed several discrepancies between ITS2 evolution in the Ulvales and generally accepted assumptions underlying ITS2 evolution as e.g. the CBC clade concept. Therefore, we developed a suite of methods providing a critical 'close-up' view into ITS2 evolution by directly tracing the evolutionary history of individual positions, and we caution against a non-critical use of the ITS2 CBC clade concept for species delimitation.

A cluster of ribosome synthesis factors regulate pre-rRNA folding and 5.8S rRNA maturation by the Rat1 exonuclease

The 5'-exonuclease Rat1 degrades pre-rRNA spacer fragments and processes the 5'-ends of the 5.8S and 25S rRNAs. UV crosslinking revealed multiple Rat1-binding sites across the pre-rRNA, consistent with its known functions. The major 5.8S 5'-end is generated by Rat1 digestion of the internal transcribed spacer 1 (ITS1) spacer from cleavage site A(3). Processing from A(3) requires the 'A(3)-cluster' proteins, including Cic1, Erb1, Nop7, Nop12 and Nop15, which show interdependent pre-rRNA binding. Surprisingly, A(3)-cluster factors were not crosslinked close to site A(3), but bound sites around the 5.8S 3'- and 25S 5'-regions, which are base paired in mature ribosomes, and in the ITS2 spacer that separates these rRNAs. In contrast, Nop4, a protein required for endonucleolytic cleavage in ITS1, binds the pre-rRNA near the 5'-end of 5.8S. ITS2 was reported to undergo structural remodelling. In vivo chemical probing indicates that A(3)-cluster binding is required for this reorganization, potentially regulating the timing of processing. We predict that Nop4 and the A(3) cluster establish long-range interactions between the 5.8S and 25S rRNAs, which are subsequently maintained by ribosomal protein binding.

Nol9 is a novel polynucleotide 5'-kinase involved in ribosomal RNA processing

The production and processing of ribosomal RNA is an essential and complex process. Here, a polynucleotide 5′-kinase, Nol9, is shown to have an important function in pre-rRNA processing and 60S ribosomal subunit biogenesis.

In a cell, an enormous amount of energy is channelled into the biogenesis of ribosomal RNAs (rRNAs). In a multistep process involving a large variety of ribosomal and non-ribosomal proteins, mature rRNAs are generated from a long polycistronic precursor. Here, we show that the non-ribosomal protein Nol9 is a polynucleotide 5′-kinase that sediments primarily with the pre-60S ribosomal particles in HeLa nuclear extracts. Depletion of Nol9 leads to a severe impairment of ribosome biogenesis. In particular, the polynucleotide kinase activity of Nol9 is required for efficient generation of the 5.8S and 28S rRNAs from the 32S precursor. Upon Nol9 knockdown, we also observe a specific maturation defect at the 5′ end of the predominant 5.8S short-form rRNA (5.8S_S), possibly due to the Nol9 requirement for 5′>3′ exonucleolytic trimming. In contrast, the endonuclease-dependent generation of the 5′-extended, minor 5.8S long-form rRNA (5.8S_L) is largely unaffected. This is the first report of a nucleolar polynucleotide kinase with a role in rRNA processing.

Ribosomal protein L35 is required for 27SB pre-rRNA processing in Saccharomyces cerevisiae

Ribosome synthesis involves the concomitance of pre-rRNA processing and ribosomal protein assembly. In eukaryotes, this is a complex process that requires the participation of specific sequences and structures within the pre-rRNAs, at least 200 trans-acting factors and the ribosomal proteins. There is little information on the function of individual 60S ribosomal proteins in ribosome synthesis. Herein, we have analysed the contribution of ribosomal protein L35 in ribosome biogenesis. In vivo depletion of L35 results in a deficit in 60S ribosomal subunits and the appearance of half-mer polysomes. Pulse-chase, northern hybridization and primer extension analyses show that processing of the 27SB to 7S pre-rRNAs is strongly delayed upon L35 depletion. Most likely as a consequence of this, release of pre-60S ribosomal particles from the nucleolus to the nucleoplasm is also blocked. Deletion of RPL35A leads to similar although less pronounced phenotypes. Moreover, we show that L35 assembles in the nucleolus and binds to early pre-60S ribosomal particles. Finally, flow cytometry analysis indicated that L35-depleted cells mildly delay the G1 phase of the cell cycle. We conclude that L35 assembly is a prerequisite for the efficient cleavage of the internal transcribed spacer 2 at site C(2).

Rrp17p is a eukaryotic exonuclease required for 5' end processing of Pre-60S ribosomal RNA

Ribosomal processing requires a series of endo- and exonucleolytic steps for the production of mature ribosomes, of which most have been described. To ensure ribosome synthesis, 3′ end formation of rRNA uses multiple nucleases acting in parallel; however, a similar parallel mechanism had not been described for 5′ end maturation. Here, we identify Rrp17p as a previously unidentified 5′–3′ exonuclease essential for ribosome biogenesis, functioning with Rat1p in a parallel processing pathway analogous to that of 3′ end formation. Rrp17p is required for efficient exonuclease digestion of the mature 5′ ends of 5.8S_S and 25S rRNAs, contains a catalytic domain close to its N terminus, and is highly conserved among higher eukaryotes, being a member of a family of exonucleases. We show that Rrp17p binds late pre-60S ribosomes, accompanying them from the nucleolus to the nuclear periphery, and provide evidence for physical and functional links between late 60S subunit processing and export.

rRNA maturation in yeast cells depleted of large ribosomal subunit proteins

The structural constituents of the large eukaryotic ribosomal subunit are 3 ribosomal RNAs, namely the 25S, 5.8S and 5S rRNA and about 46 ribosomal proteins (r-proteins). They assemble and mature in a highly dynamic process that involves more than 150 proteins and 70 small RNAs. Ribosome biogenesis starts in the nucleolus, continues in the nucleoplasm and is completed after nucleo-cytoplasmic translocation of the subunits in the cytoplasm. In this work we created 26 yeast strains, each of which conditionally expresses one of the large ribosomal subunit (LSU) proteins. In vivo depletion of the analysed LSU r-proteins was lethal and led to destabilisation and degradation of the LSU and/or its precursors. Detailed steady state and metabolic pulse labelling analyses of rRNA precursors in these mutant strains showed that LSU r-proteins can be grouped according to their requirement for efficient progression of different steps of large ribosomal subunit maturation. Comparative analyses of the observed phenotypes and the nature of r-protein-rRNA interactions as predicted by current atomic LSU structure models led us to discuss working hypotheses on i) how individual r-proteins control the productive processing of the major 5' end of 5.8S rRNA precursors by exonucleases Rat1p and Xrn1p, and ii) the nature of structural characteristics of nascent LSUs that are required for cytoplasmic accumulation of nascent subunits but are nonessential for most of the nuclear LSU pre-rRNA processing events.

Evolution of rDNA ITS1 and ITS2 sequences and RNA secondary structures within members of the fungal genera Grosmannia and Leptographium

The two internal transcribed spacers (ITS) of the nuclear ribosomal (r) DNA tandem repeat were examined in ophiostomatoid fungi belonging to the genera Grosmannia and Leptographium and closely-related taxa. Although the DNA sequence of the ITS region evolves rapidly, core features of the RNA secondary structure of the ITS1 and ITS2 segments are conserved. The results demonstrate that structural conservation of GC-rich helical regions is facilitated primarily through compensatory base changes (CBCs), hemi-CBCs, and compensating insertions/deletions (indels), although slippage of the RNA strand is potentially an additional mechanism for maintaining basepairing interactions. The major conclusion of the structural analysis of both ITS segments is that two factors appear to be involved in limiting the type of changes observed: a high GC bias for both ITS1 and ITS2 and structural constraints at the RNA level.

Compensatory base changes illuminate morphologically difficult taxonomy

Compensatory base changes (CBCs) in the ribosomal RNA (rRNA) internal transcribed spacer 2 (ITS2) secondary structures have been used to successfully verify the taxonomy of closely related species. CBCs have never been used to distinguish morphologically indistinct species. Under the hypothesis that CBCs will differentiate species in higher eukaryotes, novel software for CBC analysis was applied to morphologically indistinguishable insect species in the genus Altica. The analysis was species-specific for sympatric Altica beetles collected across four ecoregions and concordant with scanning electron microscopy data. This research shows that mining for CBCs in ITS2 rRNA secondary structures is an effective method for eukaryotic taxon analysis.

5.8S-28S rRNA interaction and HMM-based ITS2 annotation

The internal transcribed spacer 2 (ITS2) of the nuclear ribosomal repeat unit is one of the most commonly applied phylogenetic markers. It is a fast evolving locus, which makes it appropriate for studies at low taxonomic levels, whereas its secondary structure is well conserved, and tree reconstructions are possible at higher taxonomic levels. However, annotation of start and end positions of the ITS2 differs markedly between studies. This is a severe shortcoming, as prediction of a correct secondary structure by standard ab initio folding programs requires accurate identification of the marker in question. Furthermore, the correct structure is essential for multiple sequence alignments based on individual structural features. The present study describes a new tool for the delimitation and identification of the ITS2. It is based on hidden Markov models (HMMs) and verifies annotations by comparison to a conserved structural motif in the 5.8S/28S rRNA regions. Our method was able to identify and delimit the ITS2 in more than 30000 entries lacking start and end annotations in GenBank. Furthermore, 45000 ITS2 sequences with a questionable annotation were re-annotated. Approximately 30000 entries from the ITS2-DB, that uses a homology-based method for structure prediction, were re-annotated. We show that the method is able to correctly annotate an ITS2 as small as 58 nt from Giardia lamblia and an ITS2 as large as 1160 nt from humans. Thus, our method should be a valuable guide during the first and crucial step in any ITS2-based phylogenetic analysis: the delineation of the correct sequence. Sequences can be submitted to the following website for HMM-based ITS2 delineation: http://its2.bioapps.biozentrum.uni-wuerzburg.de.

Is there a molecular key to the level of "biological species" in eukaryotes? A DNA guide

DNA sequences, powerful for phylogeny, have not yet proven as rewarding for taxonomic categorization purposes. However, further analyses of one locus, the second Internal Transcribed Spacer of the nuclear ribosomal gene cistron, has suggested a high degree of predictability across eukaryotes. Comparison of the secondary structure of ITS2 transcripts reveals its most conserved region, on the 5'-side of helix III. Comparison of this 5' 30 bp highly conserved region with the extent of sexual compatibility in a clade of organisms produces two useful predictions: identity of this region predicts meaningful intercrossing ability, and, difference of even one CBC pairing in this region predicts total failure of crossing. Previous to the appearance of the first CBC in the highly conserved portion, all gametic compatibility has been lost, thanks to the parallel evolutionary changes in genes controlling mating. These two landmark events help to delimit the level of interbreeding taxa.

Molecular evolution and phylogenetic utility of the internal transcribed spacer 2 (ITS2) in Calyptratae (Diptera: Brachycera)

The resolution potential of internal transcribed spacer 2 (ITS2) at deeper levels remains controversial. In this study, 105 ITS2 sequences of 55 species in Calyptratae were analyzed to examine the phylogenetic utility of the spacer above the subfamily level and to further understand its evolutionary characteristics. We predicted the secondary structure of each sequence using the minimum-energy algorithm and constructed two data matrixes for phylogenetic analysis. The ITS2 regions of Calyptratae display strong A-T bias and slight variation in length. The tandem and dispersed repeats embedded in the spacers possibly resulted from replication slippage or transposition. Most foldings conformed to the four-domain model. Sequence comparison in combination with the secondary structures revealed six conserved motifs. Covariation analysis from the conserved motifs indicated that the secondary structure restrains the sequence evolution of the spacer. The deep-level phylogeny derived from the ITS2 data largely agreed with the phylogenetic hypotheses from morphologic and other molecular evidence. Our analyses suggest that the accordant resolutions generated from different analyses can be used to infer deep-level phylogenetic relations.

Secondary structure of the rRNA ITS2 region reveals key evolutionary patterns in acroporid corals

This study investigates the ribosomal RNA transcript secondary structure in corals as confirmed by compensatory base changes in Isopora/Acropora species. These species are unique versus all other corals in the absence of a eukaryote-wide conserved structural component, the helix III in internal transcriber spacer (ITS) 2, and their variability in the 5.8S-LSU helix basal to ITS2, a helix with pairings identical among all other scleractinian corals. Furthermore, Isopora/Acropora individuals display at least two, and as many as three, ITS sequence isotypes in their genome which appear to be capable of function. From consideration of the conserved elements in ITS2 and flanking regions, it appears that there are three major groups within the IsoporaAcropora lineage: the Isopora + Acropora "longi" group, the large group including Caribbean Acropora + the Acropora "carib" types plus the bulk of the Indo-Pacific Acropora species, and the remaining enigmatic "pseudo" group found in the Pacific. Interbreeding is possible among Caribbean A. palmata and A. cervicornis and among some species of Indo-Pacific Acropora. Recombinant ITS sequences are obvious among these latter, such that morphology (as represented by species name) does not correlate with common ITS sequence. The combination of characters revealed by RNA secondary structure analyses suggests a recent past/current history of interbreeding among the Indo-Pacific Acropora species and a shared ancestry of some of these with the Caribbean Acropora. The unusual absence of helix III of ITS2 of Isopora/Acropora species may have some causative role in the equally unusual instability in the 5.8S-LSU helix basal to ITS2 of this species complex.

Phylogenetic analysis of the internal transcribed spacer (ITS) region in Menyanthaceae using predicted secondary structure

Sequences of the nuclear internal transcribed spacer (ITS) regions ITS1 and ITS2 have been used widely in molecular phylogenetic studies because of their relatively high variability and facility of amplification. For phylogenetic applications, most researchers use sequence alignments that are based on nucleotide similarity. However, confidence in the alignment often deteriorates at taxonomic levels above genus, due to increasing variability among sequences. Like ribosomal RNA (rRNA) and other RNA molecules, the ITS transcripts consist in part of conserved secondary structures ('stems' and 'loops') that can be predicted by mathematical algorithm. Researchers have long considered the evolutionary conservation of rRNA secondary structure, but until recently few phylogenetic analyses of the ITS regions specifically incorporated structural data. We outline a novel method by which to derive additional phylogenetic data from ITS secondary structure in order to evaluate support for relationships at higher taxonomic levels. To illustrate the method, we describe an example from the plant family Menyanthaceae. Using predicted ITS secondary structure data, we obtained a well-resolved and moderately supported phylogeny, in which most topological relationships were congruent with the tree constructed using ITS nucleotide sequence data. Furthermore, the explicit encoding of ITS structural data in a phylogenetic framework allowed for the reconstruction of putative ancestral states and structural evolution in the functional but highly variable ITS region.

Mouse Eri1 interacts with the ribosome and catalyzes 5.8S rRNA processing

Eri1 is a 3'-to-5' exoribonuclease conserved from fission yeast to humans. Here we show that Eri1 associates with ribosomes and ribosomal RNA (rRNA). Ribosomes from Eri1-deficient mice contain 5.8S rRNA that is aberrantly extended at its 3' end, and Eri1, but not a catalytically inactive mutant, converts this abnormal 5.8S rRNA to the wild-type form in vitro and in cells. In human and murine cells, Eri1 localizes to the cytoplasm and nucleus, with enrichment in the nucleolus, the site of preribosome biogenesis. RNA binding residues in the Eri1 SAP and linker domains promote stable association with rRNA and thereby facilitate 5.8S rRNA 3' end processing. Taken together, our findings indicate that Eri1 catalyzes the final trimming step in 5.8S rRNA processing, functionally and spatially connecting this regulator of RNAi with the basal translation machinery.

Assembly factors Rpf2 and Rrs1 recruit 5S rRNA and ribosomal proteins rpL5 and rpL11 into nascent ribosomes

More than 170 proteins are necessary for assembly of ribosomes in eukaryotes. However, cofactors that function with each of these proteins, substrates on which they act, and the precise functions of assembly factors--e.g., recruiting other molecules into preribosomes or triggering structural rearrangements of pre-rRNPs--remain mostly unknown. Here we investigated the recruitment of two ribosomal proteins and 5S ribosomal RNA (rRNA) into nascent ribosomes. We identified a ribonucleoprotein neighborhood in preribosomes that contains two yeast ribosome assembly factors, Rpf2 and Rrs1, two ribosomal proteins, rpL5 and rpL11, and 5S rRNA. Interactions between each of these four proteins have been confirmed by binding assays in vitro. These molecules assemble into 90S preribosomal particles containing 35S rRNA precursor (pre-rRNA). Rpf2 and Rrs1 are required for recruiting rpL5, rpL11, and 5S rRNA into preribosomes. In the absence of association of these molecules with pre-rRNPs, processing of 27SB pre-rRNA is blocked. Consequently, the abortive 66S pre-rRNPs are prematurely released from the nucleolus to the nucleoplasm, and cannot be exported to the cytoplasm.

Phylogenetic reconstruction using secondary structures of Internal Transcribed Spacer 2 (ITS2, rDNA): finding the molecular and morphological gap in Caribbean gorgonian corals

BACKGROUND

Most phylogenetic studies using current methods have focused on primary DNA sequence information. However, RNA secondary structures are particularly useful in systematics because they include characteristics, not found in the primary sequence, that give "morphological" information. Despite the number of recent molecular studies on octocorals, there is no consensus opinion about a region that carries enough phylogenetic resolution to solve intrageneric or close species relationships. Moreover, intrageneric morphological information by itself does not always produce accurate phylogenies; intra-species comparisons can reveal greater differences than intra-generic ones. The search for new phylogenetic approaches, such as by RNA secondary structure analysis, is therefore a priority in octocoral research.

RESULTS

Initially, twelve predicted RNA secondary structures were reconstructed to provide the basic information for phylogenetic analyses; they accorded with the 6 helicoidal ring model, also present in other groups of corals and eukaryotes. We obtained three similar topologies for nine species of the Caribbean gorgonian genus Eunicea (candelabrum corals) with two sister taxa as outgroups (genera Plexaura and Pseudoplexaura) on the basis of molecular morphometrics of ITS2 RNA secondary structures only, traditional primary sequence analyses and maximum likelihood, and a Bayesian analysis of the combined data. The latter approach allowed us to include both primary sequence and RNA molecular morphometrics; each data partition was allowed to have a different evolution rate. In addition, each helix was partitioned as if it had evolved at a distinct rate. Plexaura flexuosa was found to group within Eunicea; this was best supported by both the molecular morphometrics and combined analyses. We suggest Eunicea flexuosa (Lamouroux, 1821) comb. nov., and we present a new species description including Scanning Electron Microscopy (SEM) images of morphological characteristics (sclerites). Eunicea flexuosa, E. pallida, E. laxispica and E. mammosa formed a separate clade in the molecular phylogenies, and were reciprocally monophyletic with respect to other Eunicea (Euniceopsis subgenus, e.g. E. tourneforti and E. laciniata) in the molecular morphometrics tree, with the exception of E. fusca. Moreover, we suggest a new diagnostic character for Eunicea, also present in E. flexuosa: middle layer sclerites > 1 mm in length.

CONCLUSION

ITS2 was a reliable sequence for intrageneric studies in gorgonian octocorals because of the amount of phylogenetic signal, and was corroborated against morphological characters separating Eunicea from Plexaura. The ITS2 RNA secondary structure approach to phylogeny presented here did not rely on alignment methods such as INDELS, but provided clearly homologous characters for partition analysis and RNA molecular morphometrics. These approaches support the divergence of Eunicea flexuosa comb. nov. from the outgroup Plexaura, although it has been considered part of this outgroup for nearly two centuries because of morphological resemblance.

Phylogenetic hypotheses of gorgoniid octocorals according to ITS2 and their predicted RNA secondary structures

Gorgoniid octocorals taxonomy (Cnidaria; Octocorallia; Gorgoniidae) includes diagnostic characters not well defined at the generic level, and based on the family diagnosis some species could be classified in either Gorgoniidae or Plexauridae. In this study, we used sequences from the Internal Transcribed Spacer 2 (ITS2) and their predicted RNA secondary structure to both correct the alignment and reconstruct phylogenies using molecular morphometrics for 24 octocorals mostly from the Atlantic. ITS2 exhibited the six-helicoidal ring-model structure found in eukaryotes, and provided 38 parsimony-informative characters. The proposed phylogenies, though differing between sequence- and structure-base results, provided consistent support for several clades. Genera considered part of the polyphyletic genus Leptogorgia, such as Filigorgia, were distantly related to the former in all phylogenetic hypotheses. Main differences among the hypotheses consisted in the placement of Muriceopsis (previously considered from the Plexauridae family) and Filigorgia. Excluding Muriceopsis and an undescribed octocoral from Tobago, Plexaurella and Pterogorgia grouped together as a sister branch of Pinnigorgia spp. but long-branch attraction was evident for the grouping of Plexaurella nutans (another plexaurid) and Pterogorgia citrina. Unexpected results were the divergence between Caribbean genera, Gorgonia and Pseudopterogorgia, which were placed basal respect to Pacifigorgia and Leptogorgia (=Lophogorgia). ITS2 provided support to corroborate observations based on sclerite morphology: species with "capstan sclerites" (e.g., Pacifigorgia and Leptogorgia) were characterized by a long helix IV with one internal loop and a helix V with four internal loops; "scaphoid sclerites" had a predominantly long helix V if compared to helix IV; "asymmetric spiny sclerites" (Muriceopsis, Pinnigorgia and the undescribed octocoral) exhibited one or two lateral bulges in the V helix. Remarkably, Muriceopsis and Pinnigorgia were supported by a complete Compensatory Base Change (CBC) (A-U to G-C) in helix V. Filigorgia with simple "spindles" had a short helix IV and a large central ring. DNA sequences from the nuclear ITS2 region, including information from predicted RNA secondary structure, despite their reduced length, provided numerous characters and phylogenetic information among Gorgoniidae genera and species.

Redundant role of DEAD box proteins p68 (Ddx5) and p72/p82 (Ddx17) in ribosome biogenesis and cell proliferation

The DEAD box proteins encoded by the genes ddx5 (p68) and ddx17 (isoforms p72 and p82) are more closely related to each other than to any other member of their family. We found that p68 negatively controls p72/p82 gene expression but not vice versa. Knocking down of either gene does not affect cell proliferation, in case of p68 suppression, however, only on condition that p72/p82 overexpression was granted. In contrast, co-silencing of both genes causes perturbation of nucleolar structure and cell death. In mutant studies, the apparently redundant role(s) of p68 and p72/p82 correspond to their ability to catalyze RNA rearrangement rather than RNA unwinding reactions. In search for possible physiological targets of this RNA rearrangement activity it is shown that the nucleolytic cleavage of 32S pre-rRNA is reduced after p68 subfamily knock-down, most probably due to a failure in the structural rearrangement process within the pre-60S ribosomal subunit preceding the processing of 32S pre-rRNA.

Pan-eukaryote ITS2 homologies revealed by RNA secondary structure

For evolutionary comparisons, phylogenetics and evaluation of potential interbreeding taxa of a species, various loci have served for animals and plants and protistans. One [second internal transcribed spacer (ITS2) of the nuclear ribosomal DNA] is highly suitable for all. Its sequence is species specific. It has already been used extensively and very successfully for plants and some protistans, and a few animals (where historically, the mitochondrial genes have dominated species studies). Despite initial impressions that ITS2 is too variable, it has proven to provide useful biological information at higher taxonomic levels, even across all eukaryotes, thanks to the conserved aspects of its transcript secondary structure. The review of all eukaryote groups reveals that ITS2 is expandable, but always retains in its RNA transcript a common core structure of two helices with hallmark characteristics important for ribosomal RNA processing. This aspect of its RNA transcript secondary structure can rescue difficult alignment problems, making the ITS2 a more powerful tool for phylogenetics. Equally important, the recognition of eukaryote-wide homology regions provides extensive and detailed information to test experimental studies of ribosomal rRNA processing.

Evolution of ITS ribosomal RNA secondary structures in fungal and algal symbionts of selected species of Cladonia sect. Cladonia (Cladoniaceae, Ascomycotina)

Evolutionary studies in lichen associations follow that of the fungal symbiont (mycobiont), which is the symbiont after which the lichen is named and forms the majority of the thallus. However, evolution of the algal partner (photobiont) is important to maintain compatibility between symbionts and to optimize productivity of the lichen association. The internal transcribed spacer (ITS) regions of the nuclear ribosomal DNA (rDNA) were examined for primary DNA sequence patterns and for patterns in the secondary structure of the rRNA transcripts in both symbionts of the genus Cladonia. Fungal and algal symbionts show opposite trends in rates of evolution and fragment lengths. Both symbionts showed stronger conservation of the ITS2 structure than the ITS1 structure. Homology was evident in the secondary structures between the two highly divergent chlorophyte and ascomycete taxonomic groups. Most fungal species and all species complexes were polyphyletic. The ITS rDNA of the natural lichen algae from Manitoba and four known algal species is highly similar. The natural lichen algae segregate into highly supported clades by environmental features, suggesting that algae that are already adapted to the environment may associate with germinating fungal propagules in the genus Cladonia. Fungal plasticity may allow the mycobiont to adapt to the environment of the photobiont producing variation in lichen morphology. This might explain the incongruence of phylogenetic patterns between the algal and fungal partners tested and the polyphyly of the fungal species.

Computer simulation of chaperone effects of Archaeal C/D box sRNA binding on rRNA folding

Archaeal C/D box small RNAs (sRNAs) are homologues of eukaryotic C/D box small nucleolar RNAs (snoRNAs). Their main function is guiding 2'-O-ribose methylation of nucleotides in rRNAs. The methylation requires the pairing of an sRNA antisense element to an rRNA target site with formation of an RNA-RNA duplex. The temporary formation of such a duplex during rRNA maturation is expected to influence rRNA folding in a chaperone-like way, in particular in thermophilic Archaea, where multiple sRNAs with two binding sites are found. Here we investigate possible mechanisms of chaperone function of Archaeoglobus fulgidus and Pyrococcus abyssi C/D box sRNAs using computer simulations of rRNA secondary structure formation by genetic algorithm. The effects of sRNA binding on rRNA structure are introduced as temporary structural constraints during co-transcriptional folding. Comparisons of the final predictions with simulations without sRNA binding and with phylogenetic structures show that sRNAs with two antisense elements may significantly facilitate the correct formation of long-range interactions in rRNAs, in particular at elevated temperatures. The simulations suggest that the main mechanism of this effect is a transient restriction of folding in rRNA domains where the termini are brought together by binding to double-guide sRNAs.

Unusual compact rDNA gene arrangements within some members of the Ascomycota: evidence for molecular co-evolution between ITS1 and ITS2

The internal transcribed spacers of the ribosomal DNA tandem repeat were examined in members of the ascomycetous genus Sphaeronaemella. Species of Sphaeronaemella and its mitotic counterpart Gabarnaudia, have a compact rDNA gene arrangement due to unusually short internal transcribed spacer (ITS) regions. Examination of these regions from phylogenetically related taxa, Cornuvesica, Gondwanamyces, and Ceratocystis, showed that their ITS1 and ITS2 regions could be folded into central hairpin-like structures with the size reduction in species of Sphaeronaemella being due to length reduction of the main-hairpin and the loss of smaller hairpin-like structures that emanate from the main hairpin. A databank compilation, combined with newly obtained sequences, provided an ITS data set that includes sequences of 600 species belonging to the Ascomycota. Correlation analysis revealed that the sizes of ITS1 and ITS2 show a strong positive correlation, suggesting that the 2 rDNA regions have co-evolved. This supports biochemical evidence indicating that the ITS1 and ITS2 segments interact to facilitate the maturation of the rRNA precursor.

Rea1, a dynein-related nuclear AAA-ATPase, is involved in late rRNA processing and nuclear export of 60 S subunits

Rea1, the largest predicted protein in the yeast genome, is a member of the AAA(+) family of ATPases and is associated with pre-60 S ribosomes. Here we report that Rea1 is required for maturation and nuclear export of the pre-60 S subunit. Rea1 exhibits a predominantly nucleoplasmic localization and is present in a late pre-60 S particle together with members of the Rix1 complex. To study the role of Rea1 in ribosome biogenesis, we generated a repressible GAL::REA1 strain and temperature-sensitive rea1 alleles. In vivo depletion of Rea1 results in the significant reduction of mature 60 S subunits concomitant with defects in pre-rRNA processing and late pre-60 S ribosome stability following ITS2 cleavage and prior to the generation of mature 5.8 S rRNA. Strains depleted of the components of the Rix1 complex (Rix1, Ipi1, and Ipi3) showed similar defects. Using an in vivo 60 S subunit export assay, a strong accumulation of the large subunit reporter Rpl25-GFP (green fluorescent protein) in the nucleus and at the nuclear periphery was seen in rea1 mutants at restrictive conditions.

Importance of transient structures during post-transcriptional refolding of the pre-23S rRNA and ribosomal large subunit assembly

An important step of ribosome assembly is the folding of the rRNA into a functional structure. Despite knowledge of the folded state of rRNA in the ribosomal subunits, there is very little information on the rRNA folding pathway. We are interested in understanding how the functional structure of rRNA is formed and whether the rRNA folding intermediates have a role in ribosome assembly. To this end, transient secondary structures around both ends of pre-23S rRNA were analyzed by a chemical probing approach, using pre-23S rRNA transcripts. Metastable hairpin loop structures were found at both ends of 23S rRNA. The functional importance of the transient structures around the ends of 23S rRNA was tested by mutations that alter only the transient structure. The effect of mutations on 23S rRNA folding was tested in vitro and in vivo. It was found that both stabilization and destabilization of the transient structure around the 5' end of 23S rRNA inhibits post-transcriptional refolding in vitro and ribosome formation in vivo. The data suggest that the transient structure of rRNA has a function during 23S rRNA folding and thereby in ribosome assembly.

A conserved element in the yeast RNase MRP RNA subunit can participate in a long-range base-pairing interaction

RNase MRP is a ribonucleoprotein endoribonuclease involved in eukaryotic pre-rRNA processing. The enzyme possesses a putatively catalytic RNA subunit, structurally related to that of RNase P. A thorough structure analysis of Saccharomyces cerevisiae MRP RNA, entailing enzymatic and chemical probing, mutagenesis and thermal melting, identifies a previously unrecognised stem that occupies a position equivalent to the P7 stem of RNase P. Inclusion of this P7-like stem confers on yeast MRP RNA a greater degree of similarity to the core RNase P RNA structure than that described previously and better delimits domain 2, the proposed specificity domain. The additional stem is created by participation of a conserved sequence element (ymCR-II) in a long-range base-pairing interaction. There is potential for this base-pairing throughout the known yeast MRP RNA sequences. Formation of a P7-like stem is not required, however, for the pre-rRNA processing or essential function of RNase MRP. Mutants that can base-pair are nonetheless detrimental to RNase MRP function, indicating that the stem will form in vivo but that only the wild-type pairing is accommodated. Although the alternative MRP RNA structure described is clearly not part of the active RNase MRP enzyme, it would be the more stable structure in the absence of protein subunits and the probability that it represents a valid intermediate species in the process of yeast RNase MRP assembly is discussed.

Secondary structure models of the nuclear internal transcribed spacer regions and 5.8S rRNA in Calciodinelloideae (Peridiniaceae) and other dinoflagellates

Secondary structure models of the 5.8S rRNA and both internal transcribed spacers (ITS1 and ITS2) are proposed for Calciodinelloideae (Peridiniaceae) and are also plausible for other dinoflagellates. The secondary structure of the 5.8S rRNA corresponds to previously developed models, with two internal paired regions and at least one 5.8S rRNA-28S rRNA interaction. A general secondary structure model of ITS1 for Calciodinelloideae (and other dinoflagellates), consisting of an open multibranch loop with three major helices, is proposed. The homology of these paired regions with those found in other taxa, published in previous studies (e.g. yeast, green algae and Platyhelmithes) remains to be determined. Finally, a general secondary structure model of ITS2 for Calciodinelloideae (and other dinoflagellates) is reconstructed. Based on the 5.8S rRNA-28S rRNA interaction, it consists of a closed multibranch loop, with four major helices. At least helix III and IV have homology with paired regions found in other eukaryotic taxa (e.g. yeast, green algae and vertebrates). Since the secondary structures of both ITS regions are more conserved than the nucleotide sequences, their analysis helps in understanding molecular evolution and increases the number of structural characters. Thus, the structure models developed in this study may be generally useful for future phylogenetic analyses.