The gene coding for small ribosomal subunit RNA in the basidiomycete Ustilago maydis contains a group I intron

Ancient Mitochondrial Gene Transfer between Fungi and the Orchids

The mitochondrial genomes (mitogenomes) of plants are known to incorporate and accumulate DNA from intra- and extracellular donors. Despite the intimate relationships formed between flowing plants (angiosperms) and fungi, lengthy fungal-like sequence has not been identified in angiosperm mitogenomes to date. Here, we present multiple lines of evidence documenting horizontal gene transfer (HGT) between the mitogenomes of fungi and the ancestors of the orchids, plants that are obligate parasites of fungi during their early development. We show that the ancestor of the orchids acquired an ∼270-bp fungal mitogenomic region containing three transfer RNA genes. We propose that the short HGT was later replaced by a second HGT event transferring >8 kb and 14 genes from a fungal mitogenome to that of the ancestor of the largest orchid subfamily, Epidendroideae. Our results represent the first evidence of genomic-scale HGT between fungal and angiosperm mitogenomes and demonstrate that the length intergenic spacer regions of angiosperm mitogenomes can effectively fossilize the genomic remains of ancient, nonplant organisms.

Integrated evolution of ribosomal RNAs, introns, and intron nurseries

The initial components of ribosomes first appeared more than 3.8 billion years ago during a time when many types of RNAs were evolving. While modern ribosomes are complex molecular machines consisting of rRNAs and proteins, they were assembled during early evolution by the association and joining of small functional RNA units. Introns may have provided the means to ligate many of these pieces together. All four classes of introns (group I, group II, spliceosomal, and archaeal) are present in many rRNA gene loci over a broad phylogenetic range. A survey of rRNA intron sequences across the three major life domains suggests that some of the classes of introns may have diverged from one another within rRNA gene loci. Analyses of rRNA sequences revealed self-splicing group I and group II introns are present in ancestral regions of the SSU (small subunit) and LSU (large subunit), whereas spliceosomal and archaeal introns appeared in sections of the rRNA that evolved later. Most classes of introns increased in number for approximately 1 billion years. However, their frequencies are low in the most recently evolved regions added to the SSU and LSU rRNAs. Furthermore, many of the introns appear to have been in the same locations for billions of years, suggesting an ancient origin for these sequences. In this Perspectives paper, I reviewed and analyzed rRNA intron sequences, locations, structural characteristics, and splicing mechanisms; and suggest that rRNA gene loci may have served as evolutionary nurseries for intron formation and diversification.

Splicing and evolution of an unusually small group I intron

Introns are common in the rRNA gene loci of fungal genomes, but biochemical studies to investigate splicing are rare. Here, self-splicing of a very small (67 nucleotide) group I intron is demonstrated. The PaSSU intron (located within the rRNA small subunit gene of Phialophora americana) splices in vitro under group I intron conditions. Most group I ribozymes contain pairing regions P1-P10, with a conserved G.U pair at the 5' splice site, and a G at the 3' intron border. The PaSSU intron contains only P1, P7, and P10. While it contains the G.U pair at the 5' splice, a U is found at the 3' end of the intron instead of a G. Phylogenetic analysis places it within subgroup IC1, whose members are found in the nuclear rRNA genes of fungi. The structural elements are similar to those in the centermost regions of other group I introns. Its size can be explained by a single large deletion that removed P2 through much of P9. Part of the original P9 region has assumed the function of P7. Its small size and genealogy makes it an excellent model to study RNA catalysis and evolution.

Patterns of group I intron presence in nuclear SSU rDNA of the Lichen family Parmeliaceae

Group I introns are commonly reported within nuclear SSU ribosomal DNA of eukaryotic micro-organisms, especially in lichen-forming fungi. We have studied the primary and secondary structure of 70 new nuclear SSU rDNA group I introns of Parmeliaceae (Ascomycota: Lecanorales) and compared them with those available in databases, covering more than 60 species. The analyzed samples of Parmeliaceae fell into two groups, one having an intron at the 1506 site and another lacking this one but having another at the 1516 or 1521 position. Introns at the 1521 position seem to be transposed from 1516 sites. Introns at the 1516 position were similar in structure to ones previously reported at this site and known from other lecanoralean fungi, while those at the 1506 position showed structural differences and no similar introns are known from related fungi. The study of the distribution of group I introns within a large monophyletic ensemble of fungi has revealed an unexpected correlation between intron types and ecological and geographical parameters. The introns at the 1516 position occurred in mainly arctic, boreal, and temperate lichens, while those at position 1506 were present in mainly tropical and subtropical to oceanic mild-temperate taxa. Further, the 1516 introns occurred in genera with few distributed species that could represent older taxa, while the 1506 ones were mainly in species-rich genera that could be of recent speciation, as many species have wide distribution areas. The transition between two different environments has been accompanied by a change in introns gained and lost.

Multiple group I introns detected in the nuclear small subunit rDNA of the autosporic green alga Selenastrum capricornutum

A phylogenetic investigation of the autosporic chlorophycean alga species Selenastrum capricornutum using the small subunit (SSU) rRNA gene revealed the unusual presence of six group IC1 introns. Previous studies showed that numerous green algal taxa contain group IC1 introns. However, whereas some algal species harbor multiple introns in a single ribosomal gene, none have contained as many as S. capricornutum. Three of the S. capricornutum introns are located at conserved algal intron sites and the remaining three are located at novel eukaryotic positions. The SSU rRNA genes and their introns have been sequenced and putative secondary structures are proposed for the introns. Also, their similarity to other group IC1 introns from algal, fungal, and viral sources is investigated. Results suggest the initial presence of introns at conserved locations, followed by duplication and insertion to novel positions within the SSU rRNA gene.

Mitosis in the yeast phase of the basidiomycetes Bensingtonia yuccicola and Stilbum vulgare and its phylogenetic implications

Phylogenetic studies of yeasts rely on an extensive molecular and biochemical data set, but structural characters are scarce. Details of mitosis in yeasts have been studied with transmission electron microscopy and immunofluorescence. Of these two methods immunofluorescence is faster and easier and yields sufficient detail for cytological comparisons. Only three basidiomycetous yeasts have been studied thus far with immunofluorescence. Mitosis in budding cells of ascomycetous yeasts occurs in the parent, while in basidiomycetous yeasts, except in Agaricostilbum pulcherrimum, it occurs in the bud. Mitosis in additional yeasts in the Agaricostilbomycetidae of the Urediniomycetes was observed using immunofluorescence localization of freeze-substituted material. In Stilbum vulgare, mitosis occurred in the parent, but in Bensingtonia yuccicola it occurred in the bud as in most other basidiomycetous yeasts. Stilbum vulgare also had predominantly binucleate yeast cells. Nuclear small subunit rDNA sequence data showed that A. pulcherrimum and S. vulgare are more closely related to each other than to B. yuccicola within the Agaricostilbomycetidae. Based on the few taxa examined, mitotic and cytoskeletal characters provide phylogenetic information.

Nuclear large subunit rDNA group I intron distribution in a population of Beauveria bassiana strains: phylogenetic implications

Four group I introns, designated Bb1, Bb2, Bb3 and Bb4, were identified in the entomopathogenic hyphomycete Beauveria bassiana. Sequence analyses of these introns verified that they were invariably inserted at specific target sequences after conserved positions Ec2563, Ec2449, Ec2066 and Ec1921 of the large nuclear subunit (LSU) rDNA 3'-end. Secondary structure modelling confirmed that Bb1 and Bb3 belonged to subgroup IE while Bb2 and Bb4 belonged to subgroup IC1. Intron presence, distribution and size-variation were studied in a population of 125 B. bassiana strains using site-specific primers. Nucleotide sequences and secondary structures were compared and showed considerable variations usually at P1, P6 and P9 helices, but concomitantly, high homology between members of the same site-specific group. Intron distribution studies revealed that few (7.2%) strains were intron-less, most contained one (28%), two (48%) or three (16%) introns, while only one strain contained all four introns. Bb4-like introns (Ec1921) were the most abundant (86.4%), whereas the other three introns were evenly represented (ca 30%) in the B. bassiana population. Analysis of intron genotype distribution indicated a tenuous dependence upon geographic origin or insect host species. Phylogenetic analysis of all B. bassiana LSU introns and their close relatives from other entomopathogenic fungi showed a strong correlation between specific insertion sites and intron subgroups, fully supported by corresponding clades, suggesting common ancestry of the site specific LSU introns.

Identification of group-I introns at three different positions within the 28S rDNA gene of the entomopathogenic fungus Metarhizium anisopliae var. anisopliae

Using a set of heterologous primers designed from the 3'-end of the 28S rRNA gene of Verticillium dahliae the corresponding gene region of 30 isolates of the entomopathogenic fungus Metarhizium anisopliae var. anisopliae was amplified. The polymerase chain reaction products obtained could be classified into four groups varying in size from 1.0 to 2.2 kb. Sequence analyses of representative PCR products revealed the presence of five distinct introns, positioned in three different insertion sites. Fungal isolates 316 and 11 both harbored one intron each (374 and 337 bp in size, respectively), whereas isolate 33 harbored three introns (436, 334, and 412 bp) within the relevant 28S rRNA region. All five introns shared the conserved P, Q, R, S elements and all the other characteristic features of group-I introns in their deduced secondary structure; three (316-int, 33-int1, and 33-int3) belong to subgroup IC1 and two (33-int2 and 11-int) belong to subgroup IE. Further, reverse transcription polymerase chain reactions indicated that all these introns were absent from the mature RNA molecules. The appearance of the five introns at identical positions with those from other organisms belonging to various phyla is discussed.

Sequence insertions and ITS data provide congruent information on Roccella canariensis and R. tuberculata (Arthoniales, Euascomycetes) phylogeny

Four Roccella species, R. canariensis, R. fimbriata, R. montagnei, and R. tuberculata, were found to possess sequence insertions in up to four locations in the first half of the SSU rDNA. Insertions from one of these positions have been classified as group I introns, while the others may represent degenerative forms of group I introns or messenger RNA introns. Two of the insertion-containing taxa, R. canariensis and R. tuberculata, differ only in their dispersal strategy: R. canariensis is sexual, producing only fruiting bodies and R. tuberculata is sterile, producing only vegetative propagules, i.e., soredia. Because insertions occurred in specimens of both taxa, they were used to examine the phylogenetic relationships between and within the two species. The sequence insertions from each of the four positions were aligned and cladistically analyzed separately. Internal transcribed spacers (ITS) were additionally sequenced to study the phylogeny of all R. canariensis and R. tuberculata specimens. Three other Roccella species (R. babingtonii, R. fimbriata, and R. montagnei) and Dirina catalinariae were used as outgroups in this parsimony analysis. Sequence insertions were found to be potentially useful in phylogenetic studies, although due to the sequence dissimilarity, homology relations were difficult to establish above the species level and in some cases even within the species. The phylogenies obtained from the insertion matrices were totally consistent with the ITS data and the insertions were concluded to have been inherited. When the insertion and ITS data were combined for total evidence, R. canariensis and R. tuberculata did not form distinct lineages in the phylogenetic tree, but appeared mixed in well-supported groups containing both sorediate and fertile specimens.

Ribosomal genes of Histoplasma capsulatum var. duboisii and var. farciminosum

A total of 1704 basepairs of the 18S rDNA of Histoplasma capsulatum var. duboisii (HCD, strain CBS175.57) and H. capsulatum var. farciminosum (HCF, strain CBS478.64) were sequenced (EMBL accession no. Z75306 and no. Z75307). The 18S rDNA of HCD was 100% identical to a published sequence of H. capsulatum var. capsulatum (HCC). The 18S rDNA of HCF showed one transversional point mutation at the nucleotide position 114 (ref. Saccharomyces cerevisiae). Hybridization confirmed that, in the 18S rDNA of two out of five strains of HCF, guanine was substituted for cytosine at the nucleotide position 114. Furthermore, identical group 1C1 introns (403 bp) were found to be inserted after position 1165 in four out of five strains of HCF, including the two strains with point mutations in the 18S rDNA, and a slightly different group 1C1 intron (408 bp) was detected in one strain of HCC without this point mutation. Intraspecific sequence variability in the highly conserved 18S rDNA because of occurrence of introns and mutations as a possible source of error in molecular diagnostics is discussed. In addition, internal transcribed spacer regions between the 18S rDNA and the 5.8S rDNA (ITS1) of three strains of HCF, and one strain each of HCC and HCD showed significant sequence variability between varieties and strains of H. capsulatum.

Use of SSU rDNA group-I intron to distinguish Monilinia fructicola from M. laxa and M. fructigena

Monilinia fructicola, M. laxa and M. fructigena are the causal agents of brown rot of pome and stone fruits. M. fructicola is not present in Europe and is classed as a quarantine pathogen in EU countries. A 418-bp group-I intron has been located in the small subunit (SSU) rDNA gene of M. fructicola which is absent from M. laxa and M. fructigena. PCR primers specific to the 3'-region of the intron together with the SSU rDNA primer NS5 were able to amplify a 444-bp product from M. fructicola and fruit tissue infected with M. fructicola but not from the other two species. This allows for the rapid and sensitive detection of this pathogen in planta.

A phylogenetic analysis of three group I introns found in the nuclear small subunit ribosomal RNA gene of the ballistoconidiogenous anamorphic yeast-like fungus Tilletiopsis flava

There are three group I introns in the nuclear small subunit ribosomal RNA gene (SSU rDNA) of the ballistoconidiogenous anamorphic yeast-like fungus Tilletiopsis flava JCM 5186. The size of these sequences were 325 nt (position 516), 335 nt (position 1199) and 437 nt (position 1506), respectively. The introns at position 516 (T.flav516) and position 1199 (T.flav1199) belonged to subgroup IB3, and that of position 1506 (T.flav1506) belonged to subgroup IC1. The results of comparison with other group I introns found in SSU rDNA of eucaryotes showed that the positions 516 and 1199 were common positions to IB3 group I introns of fungi and green algae, and that positions 943, 1506 and 1512 were those to IC1 group I introns of fungi, and green and red algae. It is indicated that the insertion position of introns have close relationship with the nature of the subgroup to which they belonged. For phylogenetic analysis, we employed 9 IB3 introns, in which 7 were at position 516 and 2 were at position 1199, and 25 IC1 introns. The maximum likelihood tree based on the conserved region alignment showed that group I introns of subgroup IB3 were phylogenetically distant from those of subgroup IC1. T.flav516 (basidiomycete) constituted a subcluster with R.dacr516 (basidiomycete) and M.albo516 (ascomycete). T. flav1199 was located at the closer position of C.chlo1199 (green alga) than other IB3 introns at position 516. T.flav1506 was located at the subcluster, which was constituted by the 1506 introns found in SSU rDNA of fungi (B.yama1506, P.cari1506, and P.inou1506) and those of green algae (C.elli1506, C.mira1506, G.spir1506, and M.sacl1506) with IC1 introns at the position 1512 (D.parv1512 and C.sacc1512). The analysis of flanking regions showed that both 5' and 3' flanking sequences were well conserved in each insertion site, and indicated that the ancestors of the intron at different site had been inherited from the different origin. Therefore, the two IB3 introns found positions 516 and 1199, T.flav516 and T.flav1199, were supposed to have the independent ancestors. Our results supported the theory of the diversity of group I introns that group I introns had been transferred horizontally to the distinct insertion site, and were inherited and diverged vertically.

Characterization of a flatworm ribosomal RNA-encoding gene: promoter sequence and small subunit rRNA secondary structure

The transcription start point (tsp) of a ribosomal RNA (rRNA)-encoding gene (rDNA) from Echinococcus granulosus has been mapped at a position located 1.1 kb upstream from the small subunit (SSU) rRNA coding sequence. As expected from the analysis of the putative promoter sequence (-200 to +50), no homology was found with rDNA promoters from other organisms. Nevertheless, some interesting motifs were found. There is a d(T)11 track flanked by an inverted repeat (IR) centered at position -32, which is analogous to the position of the TATA box in promoters transcribed by RNA polymerase II. Two other IR were observed that are also present in the Trypanosoma cruzi rDNA promoter. We have also determined the SSU rDNA sequence and established a secondary structure model. The analysis of the secondary structure strongly suggests that this gene encodes a functional SSU rRNA. The fact that both the promoter and the rRNA coding sequence are derived from the same rDNA repeat indicates that the promoter is also functional.

Group-I intron family in the nuclear ribosomal RNA small subunit genes of Cenococcum geophilum isolates

A family of optional group-I introns was found near the 3' end of the nuclear small subunit rRNA genes in 61 out of 70 isolates of the deuteromycete mycorrhizal fungus Cenococcum geophilum. DNA sequence polymorphisms among the introns (termed CgSSU introns) from ten of the isolates were studied. The sequences, ranging in size from 488 to 514 nucleotides, were from 93.2% to 99.6% similar to each other. Mutations were less common in predicted base-paired regions (33% of all mutations) than in free-standing regions (67%). The introns were self-spliced in vitro and were closest to subgroup IC1 according to sequence and predicted secondary structure. Group-I intron pairing regions P1 through P10, including core regions P, Q, R and S, were present in all ten CgSSU introns studied. No lengthy open reading frames were found in any of the introns, indicating that the introns do not encode a protein, and therefore may not be mobile. It is likely that a single intron entered a progenote of C. geophilum and changed as the species evolved.

Phylogenetic position of yeastlike endosymbionts of anobiid beetles

The Anobiid beetles Stegobium paniceum and Lasioderma serricorne possess the intracellular yeastlike symbionts Symbiotaphrina buchneri and Symbiotaphrina kochii, respectively, in the mycetome between the foregut and midgut. The nucleotide sequences of the small-subunit rRNA-encoding genes of the symbionts were determined for phylogenetic analysis. Five group I introns were found in the small-subunit rRNA-encoding genes of S. buchneri, but S. kochii lacked introns. The phylogenetic position of both symbionts was close to the class Discomycetes, which is a paraphyletic group. The two symbionts formed a monophyletic group distinct from the other major lineages. Both appear to have parted from other filamentous fungi during the early radiation of the euascomycetes and to have later become obligatory partners of the beetles.

Phylogenetic analysis of ten black yeast species using nuclear small subunit rRNA gene sequences

The nuclear small subunit rRNA genes of authentic strains of the black yeasts Exophiala dermatitidis, Wangiella dermatitidis, Sarcinomyces phaemuriformis, Capronia mansonii, Nadsoniella nigra var. hesuelica, Phaeoannellomyces elegans, Phaeococcomyces exophialae, Exophiala jeanselmei var. jeanselmei and E. castellanii were amplified by PCR and directly sequenced. A putative secondary structure of the nuclear small subunit rRNA of Exophiala dermatitidis was predicted from the sequence data. Alignment with corresponding sequences from Neurospora crassa and Aureobasidium pullulans was performed and a phylogenetic tree was constructed using the neighbor-joining method. The obtained topology of the tree was confirmed by bootstrap analysis. Based upon this analysis all fungi studied formed a well-supported monophyletic group clustering as a sister group to one group of the Plectomycetes (Trichocomaceae and Onygenales). The analysis confirmed the close relationship postulated between Exophiala dermatitidis, Wangiella dermatitidis and Sarcinomyces phaeomuriformis. This monophyletic clade also contains the telemorph species Capronia mansonii thus confirming the concept of a teleomorph connection of the genus Exophiala to a member of the herpotrichiellaceae. However, Exophiala castellanii did not belong to this clade. Therefore, this species is not the anamorph of Capronia mansonii as it was postulated.

The origin of land plants: phylogenetic relationships among charophytes, bryophytes, and vascular plants inferred from complete small-subunit ribosomal RNA gene sequences

Complete nuclear-encoded small-subunit 18S rRNA (= SSU rRNA) gene sequences were determined for the prasinophyte green alga Mantoniella squamata; the charophycean green algae Chara foetida, Coleochaete scutata, Klebsormidium flaccidum, and Mougeotia scalaris; the bryophytes Marchantia polymorpha, Fossombronia pusilla, and Funaria hygrometrica; and the lycopod Selaginella galleottii to get a better insight into the sequential evolution from green algae to land plants. The sequences were aligned with several previously published SSU rRNA sequences from chlorophytic and charophytic algae as well as from land plants to infer the evolutionary relationships for major evolutionary lineages within the Chlorobionta by distance matrix, maximum parsimony, and maximum likelihood analyses. Phylogenetic trees created by the different methods consistently placed the Charophyceae on the branch leading to the land plants. The Charophyceae were shown to be polyphyletic with the Charales ("charalean" algae) diverging earlier than the Coleochaetales, Klebsormidiales, Chlorokybales, and Zygnematales ("charophycean" algae) which branch from a point closer to the land plants in most analyses. Maximum parsimony and maximum likelihood analyses imply a successive evolution from "charophycean" algae, particularly Coleochaetales, to bryophytes, lycopods, and seed plants. In contrast, distance matrix methods group the bryophytes together with the "charophycean" algae, suggesting a separate evolution of these organisms compared with the club moss and the seed plants.

Sequence and putative secondary structure of group I introns in the nuclear-encoded ribosomal RNA genes of the fungus Hymenoscyphus ericae

Two putative group I introns in the nuclear ribosomal RNA genes of Hymenoscyphus ericae are described. One is in the small subunit gene about 30 nucleotides upstream of the 3' end of the gene at a site common to several other group I introns. The other is in the large subunit gene approx. 930 bp downstream of the 5' end of the gene. This is the only report of an intron at this location.

A group-I intron in the mitochondrial small subunit ribosomal RNA gene of Sclerotinia sclerotiorum

A 1,380-bp intervening sequence within the mitochondrial small subunit ribosomal RNA (mt SSU rRNA) gene of the fungus Sclerotinia sclerotiorum has been sequenced and identified as a group-I intron. This is the first report of an intron in the mt SSU rRNA gene. The intron shows close similarity in secondary structure to the subgroup-IC2 introns from Podospora (ND3i1, ND5i2, and COIi5) and Neurospora (ND5i1). The intron has an open reading frame (ORF) that encodes a putative protein of 420 amino acids which contains two copies of the LAGLI-DADG motif. The ORF belongs to a family of ORFs identified in Podospora (ND3i1, ND4Li1, ND4Li2, ND5i2, and COIi5) and Neurospora (ND5i1). The putative 420-aa polypeptide is also similar to a site-specific endonuclease in the chloroplast large subunit ribosomal RNA (LSU rRNA) gene of the green alga Chlamydomonas eugametos. In each clone of S. sclerotiorum examined, including several clones which were sampled over a 3-year period from geographically separated sites, all isolates either had the intron or lacked the intron within the mt SSU rRNA gene. Screening by means of Southern hybridization and PCR amplification detected the intron in the mt SSU rRNA genes of S. minor, S. trifoliorum and Sclerotium cepivorum, but not in other members of the Sclerotiniaceae, such as Botrytis anamorphs of Botryotinia spp., or in other ascomycetous and basidiomycetous fungi.

Identification of group-I introns in the 28s rDNA of the entomopathogenic fungus Beauveria brongniartii

The length of the 28s ribosomal DNA differs significantly between two strains (Bt102 and Bt114) of the entomopathogenic fungus Beauveria brongniartii. RFLP analysis on PCR products revealed the presence of three insertional elements of 350-450 bp in strain Bt114. One of the insertions has been cloned and sequenced and shown to possess all the characteristic sequences and secondary structures of a group-IC intron. Its length is 428 bp and it is devoid of any long open reading frame. The distribution of this intron elsewhere in the genome of Bt114, as well as in the chromosomal ribosomal DNA, was studied. It seems to be present as seven copies in different genes not corresponding to the mitochondrial DNA. The presence of the intron in other strains of B. brongniartii was examined by the hybridization method. Some of them seemed to possess introns with a similar core although others presented no homology with the cloned fragment.

Nucleolar introns from Physarum flavicomum contain insertion elements that may explain how mobile group I introns gained their open reading frames

Comparison of two group I intron sequences in the nucleolar genome of the myxomycete Physarum flavicomum to their homologs in the closely related Physarum polycephalum revealed insertion-like elements. One of the insertion-like elements consists of two repetitive sequence motifs of 11 and 101 bp in five and three copies, respectively. The smaller motif, which flanks the larger, resembles a target duplication and indicates a relationship to transposons or retroelements. The insertion-like elements are found in the peripheral loops of the RNA structure; the positions occupied by the ORFs of mobile nucleolar group I introns. The P. flavicomum introns are 1184 and 637 bp in size, located in the large subunit ribosomal RNA gene, and can be folded into group I intron structures at the RNA level. However, the intron 2s from both P. flavicomum and P. polycephalum contain an unusual core region that lacks the P8 segment. None of the introns are able to self-splice in vitro. Southern analysis of different isolates indicates that the introns are not optional in myxomycetes.

Evidence for the ancestral origin of group I introns in the SSUrDNA of Naegleria spp

The sequence variation within the group I intron in five Naegleria spp. was studied and compared with the sequence variation within the flanking small subunit ribosomal DNA. Considerable sequence divergence was observed in the introns as well as in the rDNA. In the intron deletions and insertions are only detected in the sequence contributing to the secondary structure, not in the open reading frame. Most of the sequence variation is detected in the unpaired loops. In the case of nucleotide substitution in helices, compensating base pair changes were observed. The sequence variation does not induce variation in the secondary structure model. The phylogenetic tree based on the intron sequences is similar to the tree based on the flanking rDNA sequences. This observation indicates that the intron might have been acquired at an early stage in evolution, and lost in the majority of Naegleria spp.

Comparison of ribosomal DNA length and restriction site polymorphisms in Gremmeniella and Ascocalyx isolates

The small subunit (SSU) and the internal transcribed spacer (ITS) of nuclear ribosomal DNA genes from 27 specimens of the fungal genera Gremmeniella and Ascocalyx were amplified by PCR. Length polymorphisms were observed in the SSU and allowed the differentiation of four groups among the isolates tested: (i) Ascocalyx abietis; (ii) Gremmeniella isolates from Picea spp.; (iii) Gremmeniella isolates from Abies balsamea; and (iv) Gremmeniella isolates from Abies sacchalinensis, Larix spp., and Pinus spp. The amplified ITS was the same length for all Gremmeniella specimens and was 60 bp longer in A. abietis. Phylogenetic analysis of length polymorphisms and of 24 restriction sites in the SSU and ITS showed that Gremmeniella isolates were more related to each other than to the Ascocalyx isolate. Furthermore, seven groups were evident within the genus Gremmeniella. Our results confirm that Gremmeniella and Ascocalyx should be kept as different taxa and suggest that the taxonomy of the former could be revised to consider isolates from Abies balsamea and from Picea spp. to be two different varieties while incorporating Gremmeniella laricina into G. abietina, as a new variety.

Discovery of group I introns in the nuclear small subunit ribosomal RNA genes of Acanthamoeba

The discovery of group I introns in small subunit nuclear rDNA (nsrDNA) is becoming more common as the effort to generate phylogenies based upon nsrDNA sequences grows. In this paper we describe the discovery of the first two group I introns in the nsrDNA from the genus Acanthamoeba. The introns are in different locations in the genes, and have no significant primary sequence similarity to each other. They are identified as group I introns by the conserved P, Q, R and S sequences (1), and the ability to fit the sequences to a consensus secondary structure model for the group I introns (1, 2). Both introns are absent from the mature srRNA. A BLAST search (3) of nucleic acid sequences present in GenBank and EMBL revealed that the A. griffini intron was most similar to the nsrDNA group I intron of the green alga Dunaliella parva. A similar search found that the A. lenticulata intron was not similar to any of the other reported group I introns.

An intron in the nuclear ribosomal DNA of Didymium iridis codes for a group I ribozyme and a novel ribozyme that cooperate in self-splicing

We have discovered a unique group I intron-like insertion (DiSSU) in the nuclear small subunit ribosomal RNA gene of the myxomycete Didymium iridis. By sequence, DiSSU consists of a group I ribozyme at the 5' end, an open reading frame (ORF) in the middle, and a novel element at the 3' end. Intron RNA self-splices in vitro to yield ten major processed RNAs, including a full-length circle. The group I ribozyme can efficiently cleave at an internal processing site, which separates the group I ribozyme from the ORF. Surprisingly, deletion that remove the entire group I ribozyme do not impair cleavage at the 3' splice site, implying that the 3' element itself is a catalytic RNA. Deletions that remove portions of the 3' element prevent utilization of the 5' splice site, suggesting that this element cooperates with the upstream group I ribozyme in splicing. DiSSU appears to be the first example for the cooperative interaction of distinct ribozymes in RNA splicing.

Small subunit rDNA variation in a population of lichen fungi due to optional group-I introns

A natural population of the lichen-forming ascomycetous fungus, Cladonia chlorophaea, contained individuals with small subunit ribosomal DNA (SSU rDNA) of at least four different size classes and nine restriction-site patterns. The source of these differences was the variable occurrence of 200-400-nucleotide insertions, previously identified as small group-I introns, at five different positions within the SSU coding region. By specific amplification of the sequences flanking these five intron positions with the polymerase chain reaction (PCR), a minimum of nine types of rDNA repeats were defined that differ in number, position, restriction pattern and size of introns. The positions of the introns were verified by sequence analysis. The variable distribution of these introns suggests that they are currently mobile--either by intron insertion, deletion or both--within this species complex.

Group I introns interrupt the chloroplast psaB and psbC and the mitochondrial rrnL gene in Chlamydomonas

The polymerase chain reaction was used to identify novel IAI subgroup introns in cpDNA-enriched preparations from the interfertile green algae Chlamydomonas eugametos and Chlamydomonas moewusii. These experiments along with sequence analysis disclosed the presence, in both green algae, of a single IA1 intron in the psaB gene and of two group I introns (IA2 and IA1) in the psbC gene. In addition, two group I introns (IA1 and IB4) were found in the peptidyltransferase region of the mitochondrial large subunit rRNA gene at the same positions as previously reported Chlamydomonas chloroplast introns. The 188 bp segment preceding the first mitochondrial intron revealed extensive sequence similarity to the distantly spaced rRNA-coding modules L7 and L8 in the Chlamydomonas reinhardtii mitochondrial DNA, indicating that these two modules have undergone rearrangements in Chlamydomonas. The IA1 introns in psaB and psbC were found to be related in sequence to the first intron in the C. moewusii chloroplast psbA gene. The similarity between the former introns extends to the immediate 5' flanking exon sequence, suggesting that group I intron transposition occurred from one of the two genes to the other through reverse splicing.

The higher fungus Protomyces inouyei has two group I introns in the 18S rRNA gene

The nucleotide sequence of the small-subunit rRNA (18S rRNA) coding gene in the higher fungus Protomyces inouyei contains two group I introns. This is the first report of two group I introns in the 18S rRNA coding region. Based on the comparison of the two introns of Protomyces inouyei with those of the green alga Ankistrodesmus stipitatus, and the other two higher fungi Pneumocystis carinii and Ustilago maydis, the Protomyces introns are group I introns containing the highly conserved sequence elements P, Q, R, and S. Intron A of Protomyces inouyei is located in the same position as in Pneumocystis carinii while intron B shares the location with that in Ustilago maydis. The phylogenetic relationships strongly support horizontal transfer of these group I introns.

Variation and in vitro splicing of group I introns in rRNA genes of Pneumocystis carinii

The sequences of the rRNA genes of Pneumocystis carinii from rat and human sources demonstrate three distinct genotypes based on the group I introns present in these genes. One rat isolate (Pc1) contains such introns in its 16S and 26S rRNA genes, while another rat isolate (Pc2) and a human isolate (Pc3) only contain an intron in the 26S rRNA gene. The four introns all catalyze their own excision from RNA transcripts, and this reaction is inhibited by the anti-pneumocystis drug pentamidine and its analogues. Although they differ in sequence, they are more similar to one another than to group I introns found in other eukaryotic microbes.

A group I intron in the SSUrDNA of some Naegleria spp. demonstrated by polymerase chain reaction amplification

The small subunit ribosomal DNA (SSUrDNA) of all described Naegleria spp. was amplified by polymerase chain reaction with universal primers. In all strains of N. andersoni andersoni, N. andersoni jamiesoni, N. australiensis italica and two related strains, and one out of four clusters of N. gruberi, a band of approximately 3.3 kb was obtained. All other strains displayed a band with the expected DNA length of 2.0 kb. This means the former have a 1.3 kb intron in the SSUrDNA. Restriction analysis demonstrated that the intron is between two conserved Pst I sites at the 5' end of the SSUrDNA. It also suggested the introns might not be identical in each species or subspecies. The Pst I fragment of SSUrDNA containing the 1.3 kb insert in N. andersoni andersoni was cloned and sequenced. The 1,296-nucleotide insert is situated in helix 19 of the SSUrDNA, which is an area of conserved primary and secondary structure. Sequence and secondary structure analyses of the insert revealed it it is a group I intron. This group I intron is very large and contains an open reading frame that could serve to encode a polypeptide of 139 amino acids in size.

A mobile group I intron from Physarum polycephalum can insert itself and induce point mutations in the nuclear ribosomal DNA of saccharomyces cerevisiae

Pp LSU3 is a mobile group I intron in the extrachromosomal nuclear ribosomal DNA (rDNA) of Physarum polycephalum. As found for other mobile introns, Pp LSU3 encodes a site-specific endonuclease, I-Ppo, which mediates "homing" to unoccupied target sites in Physarum rDNA. The recognition sequence for this enzyme is conserved in all eucaryotic nuclear rDNAs. We have introduced this intron into a heterologous species, Saccharomyces cerevisiae, in which nuclear group I introns have not been detected. The expression of Pp LSU3, under control of the inducible GAL10 promoter, was found to be lethal as a consequence of double-strand breaks in the rDNA. However, surviving colonies that are resistant to the lethal effects of I-Ppo because of alterations in the rDNA at the cleavage site were recovered readily. These survivors are of two classes. The first comprises cells that acquired one of three types of point mutations. The second comprises cells in which Pp LSU3 became inserted into the rDNA. In both cases, each resistant survivor appears to carry the same alterations in all approximately 150 rDNA repeats. When it is embedded in yeast rDNA, Pp LSU3 leads to the synthesis of I-Ppo and appears to be mobile in appropriate genetic crosses. The existence of yeast cells carrying a mobile intron should allow dissection of the steps that allow expression of the highly unusual I-Ppo gene.

A mobile group I intron from Physarum polycephalum can insert itself and induce point mutations in the nuclear ribosomal DNA of saccharomyces cerevisiae

Pp LSU3 is a mobile group I intron in the extrachromosomal nuclear ribosomal DNA (rDNA) of Physarum polycephalum. As found for other mobile introns, Pp LSU3 encodes a site-specific endonuclease, I-Ppo, which mediates "homing" to unoccupied target sites in Physarum rDNA. The recognition sequence for this enzyme is conserved in all eucaryotic nuclear rDNAs. We have introduced this intron into a heterologous species, Saccharomyces cerevisiae, in which nuclear group I introns have not been detected. The expression of Pp LSU3, under control of the inducible GAL10 promoter, was found to be lethal as a consequence of double-strand breaks in the rDNA. However, surviving colonies that are resistant to the lethal effects of I-Ppo because of alterations in the rDNA at the cleavage site were recovered readily. These survivors are of two classes. The first comprises cells that acquired one of three types of point mutations. The second comprises cells in which Pp LSU3 became inserted into the rDNA. In both cases, each resistant survivor appears to carry the same alterations in all approximately 150 rDNA repeats. When it is embedded in yeast rDNA, Pp LSU3 leads to the synthesis of I-Ppo and appears to be mobile in appropriate genetic crosses. The existence of yeast cells carrying a mobile intron should allow dissection of the steps that allow expression of the highly unusual I-Ppo gene.

Phylogenetic analysis of basidiomycetous yeasts by means of 18S ribosomal RNA sequences: relationship of Erythrobasidium hasegawianum and other basidiomycetous yeast taxa

The basidiomycetous yeast genus Erythrobasidium Hamamoto, Sugiyama & Komagata, based on the type species E. hasegawianum Hamamoto et al., is characterized by filobasidiaceous basidia and the Q-10 (H2) system as its major ubiquinone. It is tentatively placed in the Filobasidiaceae. The molecular characterization is based on 18S ribosomal RNA sequence comparisons among the basidiomycetous yeasts, and the ultrastructural characterization on the cell wall and hyphal septal pores in E. hasegawianum clearly indicate a close relationship with the teliospore-forming yeasts Rhodosporidium toruloides and Leucosporidium scottii. Our molecular phylogeny with statistical analysis suggests that the existing taxonomic system of basidiomycetous yeasts, based primarily on the morphology of basidia including the teliospores (probasidia), should be revised.