The DNA polymerase genes of several HMU-bacteriophages have similar group I introns with highly divergent open reading frames.

A previous report described the discovery of a group I, self-splicing intron in the DNA polymerase gene of the Bacillus subtilis bacteriophage SPO1 (1). In this study, the DNA polymerase genes of three close relatives of SPO1: SP82, 2C and phi e, were also found to be interrupted by an intron. All of these introns have group I secondary structures that are extremely similar to one another in primary sequence. Each is interrupted by an open reading frame (ORF) that, unlike the intron core or exon sequences, are highly diverged. Unlike the relatives of Escherichia coli bacteriophage T4, most of which do not have introns (2), this intron seems to be common among the relatives of SPO1.     

Phylogenetic evidence for horizontal transmission of group I introns in the nuclear ribosomal DNA of mushroom-forming fungi

Group I introns were discovered inserted at the same position in the nuclear small-subunit ribosomal DNA (nuc-ssu-rDNA) in several species of homobasidiomycetes (mushroom-forming fungi). Based on conserved intron sequences, a pair of intron-specific primers was designed for PCR amplification and sequencing of intron-containing rDNA repeats. Using the intron-specific primers together with flanking rDNA primers, a PCR assay was conducted to determine presence or absence of introns in 39 species of homobasidiomycetes. Introns were confined to the genera Panellus, Clavicorona, and Lentinellus. Phylogenetic analyses of nuc-ssu-rDNA and mitochondrial ssu-rDNA sequences suggest that Clavicorona and Lentinellus are closely related, but that Panellus is not closely related to these. The simplest explanation for the distribution of the introns is that they have been twice independently gained via horizontal transmission, once on the lineage leading to Panellus, and once on the lineage leading to Lentinellus and Clavicorona. BLAST searches using the introns from Panellus and Lentinellus as query sequences retrieved 16 other similar group I introns of nuc-ssu-rDNA and nuclear large-subunit rDNA (nuc-lsu-rDNA) from fungal and green algal hosts. Phylogenetic analyses of intron sequences suggest that the mushroom introns are monophyletic, and are nested within a clade that contains four other introns that insert at the same position as the mushroom introns, two from different groups of fungi and two from green algae. The distribution of host lineages and insertion sites among the introns suggests that horizontal and vertical transmission, homing, and transposition have been factors in intron evolution. As distinctive, heritable features of nuclear rDNAs in certain lineages, group I introns have promise as phylogenetic markers. Nevertheless, the possibility of horizontal transmission and homing also suggest that their use poses certain pitfalls.      

Nuclear-encoded rDNA group I introns: origin and phylogenetic relationships of insertion site lineages in the green algae

Group I introns are widespread in eukaryotic organelles and nuclear- encoded ribosomal DNAs (rDNAs). The green algae are particularly rich in rDNA group I introns. To better understand the origins and phylogenetic relationships of green algal nuclear-encoded small subunit rDNA group I introns, a secondary structure-based alignment was constructed with available intron sequences and 11 new subgroup ICI and three new subgroup IB3 intron sequences determined from members of the Trebouxiophyceae (common phycobiont components of lichen) and the Ulvophyceae. Phylogenetic analyses using a weighted maximum-parsimony method showed that most group I introns form distinct lineages defined by insertion sites within the SSU rDNA. The comparison of topologies defining the phylogenetic relationships of 12 members of the 1512 group I intron insertion site lineage (position relative to the E. coli SSU rDNA coding region) with that of the host cells (i.e., SSU rDNAs) that contain these introns provided insights into the possible origin, stability, loss, and lateral transfer of ICI group I introns. The phylogenetic data were consistent with a viral origin of the 1512 group I intron in the green algae. This intron appears to have originated, minimally, within the SSU rDNA of the common ancestor of the trebouxiophytes and has subsequently been vertically inherited within this algal lineage with loss of the intron in some taxa. The phylogenetic analyses also suggested that the 1512 intron was laterally transferred among later-diverging trebouxiophytes; these algal taxa may have coexisted in a developing lichen thallus, thus facilitating cell- to-cell contact and the lateral transfer. Comparison of available group I intron sequences from the nuclear-encoded SSU rDNA of phycobiont and mycobiont components of lichens demonstrated that these sequences have independent origins and are not the result of lateral transfer from one component to the other.      

The molecular evolution and structural organization of group I introns at position 1389 in nuclear small subunit rDNA of myxomycetes

The number of nuclear group I introns from myxomycetes is rapidly increasing in GenBank as more rDNA sequences from these organisms are being sequenced. They represent an interesting and complex group of intervening sequences because several introns are mobile (or inferred to be mobile) and many contain large and unusual insertions in peripheral loops. Here we describe related group I introns at position 1389 in the small subunit rDNA of representatives from the myxomycete family Didymiaceae. Phylogenetic analyses support a common origin and mainly vertical inheritance of the intron. All S1389 introns from the Didymiaceae belong to the IC1 subclass of nuclear group I introns. The central catalytic core region of about 100 nt appears divergent in sequence composition even though the introns reside in closely related species. Furthermore, unlike the majority of group I introns from myxomycetes the S1389 introns do not self-splice as naked RNA in vitro under standard conditions, consistent with a dependence on host factors for folding or activity. Finally, the myxomycete S1389 introns are exclusively found within the family Didymiaceae, which suggests that this group I intron was acquired after the split between the families Didymiaceae and Physaraceae.     

Discovery of a group I intron in the SSU rDNA of Ploeotia costata (Euglenozoa)

The gene coding for the small ribosomal subunit RNA of Ploeotia costata contains an actively splicing group I intron (Pco.S516) which is unique among euglenozoans. Secondary structure predictions indicate that paired segments P1-P10 as well as several conserved elements typical of group I introns and of subclass IC1 in particular are present. Phylogenetic analyses of SSU rDNA sequences demonstrate a well-supported placement of Ploeotia costata within the Euglenozoa; whereas, analyses of intron data sets uncover a close phylogenetic relation of Pco.S516 to S-516 introns from Acanthamoeba, Aureoumbra lagunensis (Stramenopila) and red algae of the order Bangiales. Discrepancies between SSU rDNA and intron phylogenies suggest horizontal spread of the group I intron. Monophyly of IC1 516 introns from Ploeotia costata, A. lagunensis and rhodophytes is supported by a unique secondary structure element: helix P5b possesses an insertion of 19 nt length with a highly conserved tetraloop which is supposed to take part in tertiary interactions. Neither functional nor degenerated ORFs coding for homing endonucleases can be identified in Pco.S516. Nevertheless, degenerated ORFs with His-Cys box motifs in closely related intron sequences indicate that homing may have occurred during evolution of the investigated intron group.     

Novel Group I Introns Encoding a Putative Homing Endonuclease in the Mitochondrial <Emphasis Type="Italic">cox1</Emphasis> Gene of Scleractinian Corals

Analyses of mitochondrial sequences revealed the existence of a group I intron in the cytochrome oxidase subunit 1 (cox1) gene in 13 of 41 genera (20 out of 73 species) of corals conventionally assigned to the suborder Faviina. With one exception, phylogenies of the coral cox1 gene and its intron were concordant, suggesting at most two insertions and many subsequent losses. The coral introns were inferred to encode a putative homing endonuclease with a LAGLI-DADG motif as reported for the cox1 group I intron in the sea anemone Metridium senile. However, the coral and sea anemone cox1 group I introns differed in several aspects, such as the intron insertion site and sequence length. The coral cox1 introns most closely resemble the mitochondrial cox1 group I introns of a sponge species, which also has the same insertion site. The coral introns are also more similar to the introns of several fungal species than to that of the sea anemone (although the insertion site differs in the fungi). This suggests either a horizontal transfer between a sponge and a coral or independent transfers from a similar fungal donor (perhaps one with an identical insertion site that has not yet been discovered). The common occurrence of this intron in corals strengthens the evidence for an elevated abundance of group I introns in the mitochondria of anthozoans. [Reviewing Editor: Dr. Niles Lehman]     

A group I plant intron accumulates as circular RNA forms with extensive 5' deletions in vivo.

Analysis by a PAGE approach for detecting small circular RNAs showed the existence of one such molecular species (RNA 1) accumulating at high levels in cherimoya. Sequencing of cDNA clones of RNA 1 revealed a size of 281 nt and a sequence identical to the 3'-terminal region of the 494-nt tRNALeu(UAA) group I intron from cherimoya. Northern blot hybridizations with a probe complementary to RNA 1 showed that this RNA coexists in vivo with its corresponding linear form, with the presumed full-length intron, and with minor amounts of two additional small circular species (RNAs 2 and 3). RNAs 2 and 3 had sizes of 216 and 156 nt, respectively, and sequences identical to different moieties of the 3'-terminal region of the tRNALeu(UAA) intron. The three cyclization sites giving rise to RNAs 1, 2, and 3, located within loop 8, are preceded by CUU or UUU trinucleotides and followed by sequences capable of forming base pairing interactions with the internal guide sequence characteristic of group I introns. The good correlation observed between the stabilities of these interactions and the in vivo accumulation levels of the corresponding cherimoya circular RNAs support the hypothesis that they emerge through a common mechanism similar to that advanced previously for the generation of circular RNAs derived from other group I introns. The lack of interactions of similar stabilities in tobacco, in which no circular RNAs derived from the tRNALeu(UAA) intron were detected, is consistent with this proposal, although other factors are also probably important in the synthesis and accumulation of the small circular RNAs in cherimoya.     

Multiple acquisitions via horizontal transfer of a group I intron in the mitochondrial cox1 gene during evolution of the Araceae family.

A group I intron has recently been shown to have invaded mitochondrial cox1 genes by horizontal transfer many times during the broad course of angiosperm evolution. To investigate the frequency of acquisition of this intron within a more closely related group of plants, we determined its distribution and inferred its evolutionary history among 14 genera of the monocot family Araceae. Southern blot hybridizations showed that 6 of the 14 genera contain this intron in their cox1 genes. Nucleotide sequencing showed that these six introns are highly similar in sequence (97.7%-99.4% identity) and identical in length (966 nt). Phylogenetic evidence from parsimony reconstructions of intron distribution and phylogenetic analyses of intron sequences is consistent with a largely vertical history of intron transmission in the family; the simplest scenarios posit but one intron gain and two losses. Despite this, however, striking differences in lengths of exonic co-conversion tracts, coupled with the absence of co-conversion in intron-lacking taxa, indicate that the six intron-containing Araceae probably acquired their introns by at least three and quite possibly five separate horizontal transfers. The highly similar nature of these independently acquired introns implies a closely related set of donor organisms.     

The Agaricus bisporus cox1 gene: the longest mitochondrial gene and the largest reservoir of mitochondrial group i introns

In eukaryotes, introns are located in nuclear and organelle genes from several kingdoms. Large introns (up to 5 kbp) are frequent in mitochondrial genomes of plant and fungi but scarce in Metazoa, even if these organisms are grouped with fungi among the Opisthokonts. Mitochondrial introns are classified in two groups (I and II) according to their RNA secondary structure involved in the intron self-splicing mechanism. Most of these mitochondrial group I introns carry a "Homing Endonuclease Gene" (heg) encoding a DNA endonuclease acting in transfer and site-specific integration ("homing") and allowing intron spreading and gain after lateral transfer even between species from different kingdoms. Opposed to this gain mechanism, is another which implies that introns, which would have been abundant in the ancestral genes, would mainly evolve by loss. The importance of both mechanisms (loss and gain) is matter of debate. Here we report the sequence of the cox1 gene of the button mushroom Agaricus bisporus, the most widely cultivated mushroom in the world. This gene is both the longest mitochondrial gene (29,902 nt) and the largest group I intron reservoir reported to date with 18 group I and 1 group II. An exhaustive analysis of the group I introns available in cox1 genes shows that they are mobile genetic elements whose numerous events of loss and gain by lateral transfer combine to explain their wide and patchy distribution extending over several kingdoms. An overview of intron distribution, together with the high frequency of eroded heg, suggests that they are evolving towards loss. In this landscape of eroded and lost intron sequences, the A. bisporus cox1 gene exhibits a peculiar dynamics of intron keeping and catching, leading to the largest collection of mitochondrial group I introns reported to date in a Eukaryote.     

A structural and phylogenetic analysis of the group IC1 introns in the order Bangiales (Rhodophyta)

Our previous study of the North American biogeography of Bangia revealed the presence of two introns inserted at positions 516 and 1506 in the nuclear-encoded SSU rRNA gene. We subsequently sequenced nuclear SSU rRNA in additional representatives of this genus and the sister genus Porphyra in order to examine the distribution, phylogeny, and structural characteristics of these group I introns. The lengths of these introns varied considerably, ranging from 467 to 997 nt for intron 516 and from 509 to 1,082 nt for intron 1506. The larger introns contained large insertions in the P2 domain of intron 516 and the P1 domain of intron 1506 that correspond to open reading frames (ORFs) with His-Cys box homing endonuclease motifs. These ORFs were found on the complementary strand of the 1506 intron in Porphyra fucicola and P. umbilicalis (HG), unlike the 516 intron in P. abbottae, P. kanakaensis, P. tenera (SK), Bangia fuscopurpurea (Helgoland), and B. fuscopurpurea (MA). Frameshifts were noted in the ORFs of the 516 introns in P. kanakaensis and B. fuscopurpurea (HL), and all ORFs terminated prematurely relative to the amino acid sequence for the homing endonuclease I-Ppo I. This raises the possibility that these sequences are pseudogenes. Phylogenies generated using sequences of both introns and the 18S rRNA gene were congruent, which indicated long-term immobility and vertical inheritance of the introns followed by subsequent loss in more derived lineages. The introns within the florideophyte species Hildenbrandia rubra (position 1506) were included to determine relationships with those in the Bangiales. The two sequences of intron 1506 analyzed in Hildenbrandia were positioned on a well-supported branch associated with members of the Bangiales, indicating possible common ancestry. Structural analysis of the intron sequences revealed a signature structural feature in the P5b domain of intron 516 that is unique to all Bangialean introns in this position and not seen in intron 1506 or other group IC1 introns.     

RNA splicing in the T-even bacteriophage

Group 1 introns, first demonstrated in the nuclear large rRNA of Tetrahymena thermophila and subsequently in many yeast, fungal mitochondrial, and chloroplast precursor RNAs, are capable of intron excision and exon ligation in vitro, although this process occurs much more rapidly in vivo. The discovery and characterization of a similar intron in the T4 phage thymidylate synthase gene (td) led to the finding of additional group 1 introns in other T4 genes and in genes of the related T2 and T6 phages. Because protein factors are not required in the splicing of group 1 introns in vitro, it has been postulated that the precursor RNA can assume a critical conformation enabling it to undergo site-specific autocatalytic cleavage and ligation (self-splicing). By means of site-directed mutation, it has been shown unequivocally that several sequence elements in the Tetrahymena rRNA intron are involved in the formation of base-paired stem structures that are essential for the self-splicing process. These sequence elements have been demonstrated in other eukaryotic group 1 introns, as well as in the td intron. In this brief review we shall describe the biochemical and structural properties of the td intron in relation to other newly found phage introns. The interesting implications arising from these revelations will also be discussed.     

Evolution of rbcL group IA introns and intron open reading frames within the colonial Volvocales (Chlorophyceae)

Mobile group I introns sometimes contain an open reading frame (ORF) possibly encoding a site-specific DNA endonuclease. However, previous phylogenetic studies have not clearly deduced the evolutionary roles of the group I intron ORFs. In this paper, we examined the phylogeny of group IA2 introns inserted in the position identical to that of the chloroplast-encoded rbcL coding region (rbcL-462 introns) and their ORFs from 13 strains of five genera (Volvox, Pleodorina, Volvulina, Astrephomene, and Gonium) of the colonial Volvocales (Chlorophyceae) and a related unicellular green alga, Vitreochlamys. The rbcL-462 introns contained an intact or degenerate ORF of various sizes except for the Gonium multicoccum rbcL-462 intron. Partial amino acid sequences of some rbcL-462 intron ORFs exhibited possible homology to the endo/excinuclease amino acid terminal domain. The distribution of the rbcL-462 introns is sporadic in the phylogenetic trees of the colonial Volvocales based on the five chloroplast exon sequences (6021 bp). Phylogenetic analyses of the conserved intron sequences resolved that the G. multicoccum rbcL-462 intron had a phylogenetic position separate from those of other colonial volvocalean rbcL-462 introns, indicating the recent horizontal transmission of the intron in the G. multicoccum lineage. However, the combined data set from conserved intron sequences and ORFs from most of the rbcL-462 introns resolved robust phylogenetic relationships of the introns that were consistent with those of the host organisms. Therefore, most of the extant rbcL-462 introns may have been vertically inherited from the common ancestor of their host organisms, whereas such introns may have been lost in other lineages during evolution of the colonial Volvocales. In addition, apparently higher synonymous substitutions than nonsynonymous substitutions in the rbcL-462 intron ORFs indicated that the ORFs might evolve under functional constraint, which could result in homing of the rbcL-462 intron in cases of spontaneous intron loss. On the other hand, the presence of intact to largely degenerate ORFs of the rbcL-462 introns within the three isolates of Gonium viridistellatum and the rare occurrence of the ORF-lacking rbcL-462 intron suggested that the ORFs might degenerate to result in the spontaneous intron loss during a very short evolutionary time following the loss of the ORF function. Thus, the sporadic distribution of the rbcL-462 introns within the colonial Volvocales can be largely explained by an equilibrium between maintenance of the introns by the intron ORF and spontaneous loss of introns when the introns do not have a functional ORF.     

Molecular phylogeny of phyllopharyngean ciliates and their group I introns

We analyzed small subunit ribosomal DNA (ssu-rDNA) sequences to evaluate both the monophyly of the ciliate class Phyllopharyngea de Puytorac et al. (1974), and relationships among subclasses. Classifications based on morphology and ultrastructure divide the Phyllopharyngea into four subclasses, the Phyllopharyngia, Chonotrichia, Rhynchodia, and Suctoria. Our analyses of ssu-rDNA genealogies derived from sequence data collected from diverse members representing three of the four subclasses of Phyllopharyngea (Suctoria: Ephelota spp., Prodiscophyra collini, Acineta sp.; Phyllopharyngia: Chlamydodon exocellatus, Chlamydodon triquetrus, Dysteria sp.; and Chonotrichia: Isochona sp.) provide strong support for the monophyly of the Phyllopharyngea, and show that the Chonotrichia emerge from within the Phyllopharyngia. Based on this initial sampling, suctorian budding types are monophyletic, and exogenous budding appears to be basal to evaginative and endogenous budding. Further, we report the discovery of a group I intron at position 891 in the Suctoria Acineta sp. and Tokophrya lemnarum, and a second group I intron at position 1506 in T. lemnarum. These introns represent only the second examples of group I introns in a ciliate ribosomal gene, since the discovery of ribozymes in the LSU rRNA gene of Tetrahymena thermophila. Phylogenetic analyses of Group I introns suggest a complex evolutionary history involving either multiple loses or gains of introns within endogenously budding Suctoria.     

Group I introns as mobile genetic elements: facts and mechanistic speculations--a review

Group I introns form a structural and functional group of introns with widespread but irregular distribution among very diverse organisms and genetic systems. Evidence is now accumulating that several group I introns are mobile genetic elements with properties similar to those originally described for the omega system of Saccharomyces cerevisiae: mobile group I introns encode sequence-specific double-strand (ds) endoDNases, which recognize and cleave intronless genes to insert a copy of the intron by a ds-break repair mechanism. This mechanism results in: the efficient propagation of group I introns into their cognate sites; their maintenance at the site against spontaneous loss; and, perhaps, their transposition to different sites. The spontaneous loss of group I introns occurs with low frequency by an RNA-mediated mechanism. This mechanism eliminates introns defective for mobility and/or for RNA splicing. Mechanisms of intron acquisition and intron loss must create an equilibrium, which explains the irregular distribution of group I introns in various genetic systems. Furthermore, the observed distribution also predicts that horizontal transfer of intron sequences must occur between unrelated species, using vectors yet to be discovered.     

A Group I Intron in the Nuclear Small Subunit rRNA Gene of Cryptendoxyla hypophloia, an Ascomycetous Fungus: Evidence for a New Major Class of Group I Introns

The ascomycetous fungus Cryptendoxyla hypophloia contains an insertion of 433 base pairs in the genes encoding nuclear small subunit ribosomal RNA. Secondary structure analyses of the insert reveal characteristics indicative of a Group I intron, including elements P, Q, R, and S; however, the sequences of these conserved regions deviate significantly from recognized consensus sequences for Group I introns. Principal-components analysis, based on 79 nucleotide positions from the conserved core sequences of 93 Group I introns, identified 17 introns similar to that of C. hypophloia. This grouping, which includes inserts from phylogenetically diverse organisms, cannot readily be classified in any previously recognized major group of Group I introns. We propose the creation of a new group, IE, to accommodate these sequences, and discuss the evolutionary relationships between group IE and other major groups of Group I introns. Received: 11 January 1998 / Accepted: 12 October 1998     

A comparative database of group I intron structures.

We have created a database of comparatively derived group I intron secondary structure diagrams. This collection currently contains a broad sampling of phylogenetically and structurally similar and diverse structures from over 200 publicly available intron sequences. As more group I introns are sequenced and added to the database, we anticipate minor refinements in these secondary structure diagrams. These diagrams are directly accessible by computer as well as from the authors.     

Two group I introns with long internal open reading frames in the chloroplast psbA gene of Chlamydomonas moewusii.

We report the nucleotide sequence of the chloroplast psbA gene encoding the 32 kilodalton protein of photosystem II from Chlamydomonas moewusii. Like its land plant homologues, this green algal protein consists of 353 amino acids. The C. moewusii psbA gene is composed of three exons containing 252, 11 and 90 codons and of two group I introns containing 2363 and 1807 nucleotides. Each of the introns features an internal open reading frame (ORF) that potentially encodes a basic protein of more than 300 residues. The primary sequences of the putative intron-encoded proteins are unrelated and none of them shares conserved elements with any of the proteins predicted from the group I intron sequences published so far. The first C. moewusii intron is inserted at the same position as the fourth intron of the psbA gene from Chlamydomonas reinhardtii; the second intron lies at a novel site downstream of this position. On the basis of their RNA secondary structures, the C. moewusii introns 1 and 2 can be assigned to subgroups IA and IB, respectively. However, intron 1 is not typical of subgroup IA introns, its most unusual feature being the location of the ORF in the "loop L5" region. To our knowledge, this is the first time that an ORF is located in this region of the group I intron structure.     

EVIDENCE FOR LATERAL TRANSFER OF AN IE INTRON BETWEEN FUNGAL AND RED ALGAL SMALL SUBUNIT RRNA GENES1

A previous study of the North American biogeography of the red algal genus Hildenbrandia noted the presence of group I introns in the nuclear small subunit (SSU) rRNA gene of the marine species H. rubra (Sommerf.) Menegh. Group IC1 introns have been previously reported at positions 516 and 1506 in the nuclear SSU RNA genes in the Bangiales and Hildenbrandiales. However, the presence of an unclassified intron at position 989 in a collection of H. rubra from British Columbia was noted. This intron is a member of the IE subclass and is the first report of this intron type in the red algae. Phylogenetic analyses of the intron sequences revealed a close relationship between this IE intron inserted at position 989 and similar fungal IE introns in positions 989 and 1199. The 989 IE introns formed a moderately to well‐supported clade, whereas the 1199 IE introns are weakly supported. Unique structural helices in the P13 domain of the 989 and 1199 IE introns also point to a close relationship between these two clades and provide further evidence for the value of secondary structural characteristics in identifying homologous introns in evolutionarily divergent organisms. The absence of the 989 IE intron in all other red algal nuclear SSU rRNA genes suggests that it is unlikely that this intron was vertically inherited from the common ancestor of the red algal and fungal lineages but rather is the result of lateral transfer between fungal and red algal nuclear SSU rRNA genes.     

The evolution of homing endonuclease genes and group I introns in nuclear rDNA

Group I introns are autonomous genetic elements that can catalyze their own excision from pre-RNA. Understanding how group I introns move in nuclear ribosomal (r)DNA remains an important question in evolutionary biology. Two models are invoked to explain group I intron movement. The first is termed homing and results from the action of an intron-encoded homing endonuclease that recognizes and cleaves an intronless allele at or near the intron insertion site. Alternatively, introns can be inserted into RNA through reverse splicing. Here, we present the sequences of two large group I introns from fungal nuclear rDNA, which both encode putative full-length homing endonuclease genes (HEGs). Five remnant HEGs in different fungal species are also reported. This brings the total number of known nuclear HEGs from 15 to 22. We determined the phylogeny of all known nuclear HEGs and their associated introns. We found evidence for intron-independent HEG invasion into both homologous and heterologous introns in often distantly related lineages, as well as the "switching" of HEGs between different intron peripheral loops and between sense and antisense strands of intron DNA. These results suggest that nuclear HEGs are frequently mobilized. HEG invasion appears, however, to be limited to existing introns in the same or neighboring sites. To study the intron-HEG relationship in more detail, the S943 group I intron in fungal small-subunit rDNA was used as a model system. The S943 HEG is shown to be widely distributed as functional, inactivated, or remnant ORFs in S943 introns.