The introns of the Euglena gracilis chloroplast gene which codes for the 32-kDa protein of photosystem II

Mitogenome of a stink worm (Annelida: Travisiidae) includes degenerate group II intron that is also found in five congeneric species

Mitogenomes are useful for inferring phylogenetic relationships between organisms. Although the mitogenomes of Annelida, one of the most morphologically and ecologically diverse metazoan groups have been well sequenced, those of several families remain unexamined. This study determined the first mitogenome from the family Travisiidae (Travisia sanrikuensis), analyzed its mitogenomic features, and reconstructed a phylogeny of Sedentaria. The monophyly of the Terebellida + Arenicolida + Travisiidae clade is supported by molecular phylogenetic analysis. The placement of Travisiidae is unclear because of the lack of mitogenomes from closely related lineages. An unexpected intron appeared within the cox1 gene of T. sanrikuensis and in the same positions of five undescribed Travisia spp. Although the introns are shorter (790–1386 bp) than other group II introns, they can be considered degenerate group II introns due to type II intron maturase open reading frames, found in two of the examined species, and motifs characteristic of group II introns. This is likely the first known case in metazoans where mitochondrial group II introns obtained by a common ancestor are conserved in several descendants. Insufficient evolutionary time for intron loss in Travisiidae, or undetermined mechanisms may have helped maintain the degenerate introns.

A group III intron is formed from domains of two individual group II introns

A 1352-nucleotide intron within the Euglena gracilis chloroplast ycf8 gene has been characterized as a complex twintron with overlapping internal introns and alternative splicing pathways. Partially spliced pre-mRNAs were characterized by a combination of cDNA cloning and sequencing, Northern hybridization, and S1 nuclease protection analyses. In the predominant pathway, two internal group II introns (601 and 392 nucleotides) are spliced from subdomain ID of an external group II intron (359 nucleotides). In an alternative pathway, following excision of the 601-nucleotide intron, splicing of a group III intron occurs. This group III intron is recruited from sequences of the external intron and the 392-nucleotide intron. This is the first evidence that a group III intron can be derived from portions of existing group II introns. The mechanism of group III intron formation may also be relevant to the evolution of nuclear introns from putative group II intron ancestors.

Exons--original building blocks of proteins?

In a recent paper, Walter Gilbert's group has estimated the number of original exons from which all extant proteins might have been constructed. The approach used is subjected to a critical analysis here. It is shown that there are flawed assumptions about both the mechanism and generality of exon-shuffling and in the sequence comparison procedures employed, the latter failing to distinguish chance similarity from similarity due to common ancestry. These methodological errors lead to the omission of many known cases of exon-shuffling and the inclusion of others which may not be genuine. In consequence, the analysis from the Gilbert group cannot give a reliable estimate of those modules that actually participated in exon-shuffling and provides no information on the number of protein archetypes that did not participate in these processes.

Comparative and functional anatomy of group II catalytic introns--a review

The 70 published sequences of group II introns from fungal and plant mitochondria and plant chloroplasts are analyzed for conservation of primary sequence, secondary structure and three-dimensional base pairings. Emphasis is put on structural elements with known or suspected functional significance with respect to self-splicing: the exon-binding and intron-binding sites, the bulging A residue involved in lariat formation, structural domain V and two isolated base pairs, one of them involving the last intron nucleotide and the other one, the first nt of the 3' exon. Separate sections are devoted to the 29 group II-like introns from Euglena chloroplasts and to the possible relationship of catalytic group II introns to nuclear premessenger introns. Alignments of all available sequences of group II introns are provided in the APPENDIX.

The relationship between RNA catalytic processes

Proposals that an RNA-based genetic system preceded DNA, stem from the ability of RNA to store genetic information and to promote simple catalysis. However, to be a valid basis for the RNA world, RNA catalysis must demonstrate or be related to intrinsic chemical properties which could have existed in primordial times. We analyze this question by first classifying RNA catalysis and related processes according to their mechanism. We define: (A) the disjunct nucleophile class which leads to 5'-phosphates. These include Group I and II intron splicing, nuclear mRNA splicing and RNase P reactions. Although Group I introns and its excision mechanism is likely to have existed in primordial times, present-day examples have arisen independently in different phyla much more recently. Comparative methodology indicates that RNase P catalysis originated before the divergence of the major kingdoms. In addition, all disjunct nucleophile reactions can be interrelated by a proposed mechanism involving a distant 2-OH nucleophile. (B) the conjunct nucleophile class leading to 3'-phosphates. This class is composed of self-cleaving RNAs found in plant viruses and the newt. We propose that tRNA splicing is related to this mechanism rather than the previous one. The presence of introns in tRNA genes of eukaryotes and archaebacteria supports the idea that tRNA splicing predates the divergence of these cell types.

Ordered processing and splicing in a polycistronic transcript in liverwort chloroplasts

From the complete sequence of the chloroplast DNA in a liverwort, Marchantia polymorpha, an unidentified open reading frame, ORF203, was found between the psbB and rps12' (trans-split) genes. ORF203 was a split gene consisting of three exons and two group II introns. Multiple transcripts for ORF203 were detected on Northern blots of the chloroplast RNA preparation. The ORF203 locus was primarily co-transcribed with the downstream genes rps12' and rpl20, and then processed into a monomeric precursor. S1 nuclease mapping gave the transcription initiation site 52 nucleotides upstream from the coding sequence of ORF203. The spliced RNA molecules were identified, as predicted, by the use of synthetic oligodeoxyribonucleotide probes specific to ligated exon sequences. The splicing reaction proceeded successively from the 5' to 3' direction. These results indicate that ordered RNA processing occurs in the chloroplast of land plants. Trans-membrane analysis by a computer indicated that ORF203 gene product could be associated with a chloroplast membrane.

Introns in chloroplast protein-coding genes of land plants

Several protein-coding genes from land plant chloroplasts have been shown to contain introns. The majority of these introns resemble the fungal mitochondrial group II introns due to considerable nucleotide sequence homology at their 5' and 3' ends and they can readily be folded to form six hairpins characteristic of the predicted secondary structure of the mitochondrial group II introns. Recently it has been demonstrated that some mitochondrial group II introns are capable of self-splicing in vitro in the absence of protein co-factors. However evidence presented in this overview suggests that this is probably not the case for chloroplast introns and that trans-acting factors are almost certainly involved in their processing reactions.

The two genes for the P700 chlorophyll a apoproteins on the Euglena gracilis chloroplast genome contain multiple introns

We have determined the complete nucleotide sequence of the two genes encoding the P700 chlorophyll a apoproteins of the photosystem I reaction center of the Euglena gracilis chloroplast genome. The two genes are separated by 77 bp, are of the same polarity, and span a region which is greater than 9.0 kbp. The psaA gene (751 codons) is interrupted by three introns and the psaB gene (734 codons) by six introns. The introns range in size from 361 to 590 bp, whereas the exons range in size from 42 to 1,194 bp. The introns are extremely AT rich with a pronounced base bias of T greater than A greater than G greater than C in the RNA-like strand. Like other interrupted protein genes in the Euglena chloroplast genome, the psaA and psaB introns are similar to mitochondrial group II introns in having the splice junction consensus sequence, 5' GTGCGNTTCG ..... INTRON ..... TTAATTTTAT 3' and conserved secondary structural features. Except for the placement of the first intron, the intron-exon organization of these two highly homologous genes is not conserved. The other introns fall at or near putative surface domains of the predicted gene products. The psaA and psaB gene products are 74% homologous to one another and 93% and 95% homologous, respectively, to the psaA and psaB gene products of higher plant chloroplasts. The predicted secondary structure derived from the primary amino acid sequence has 11 potential membrane-spanning domains.

Self-splicing of group II introns in vitro: lariat formation and 3' splice site selection in mutant RNAs

Deletion or substitution of the branch A residue in group II intron bl1 significantly reduces splicing activity; yet, residual exon ligation is correct, and lariats have their branch points at the normal distance from the 3' end of the intron. Mutations in the sequence facing the branch point also allow residual lariat formation; however, free 3' exons are generated with false 5' termini, all of which are within a UCACA consensus sequence located upstream or downstream of the normal 3' splice site. These results indicate that both the conserved 3' splice site APy and the spatial arrangements in stem 6 are crucial for correct 3' splice site selection.

Multiple exon-binding sites in class II self-splicing introns

Partial deletion of the exon 5' to S. cerevisiae intron a5, a self-splicing mitochondrial class II intron, reveals the existence of several sites of intron-exon interaction. We have identified two of the corresponding exon-binding sites in intron a5 by comparative sequence analysis and RNAase H digestion of the intron complexed to a DNA version of its 5' exon. Introduction of mutations in either the intronic sites or the complementary exonic sequences affects splicing in vitro, whereas double mutants in which intron-exon pairings have been restored show normal activity. Some of the mutants accumulate a product that was shown to be the intron-3' exon lariat, a postulated splicing intermediate. The possible role of one of the intronic sites in aligning exons for the ligation step is discussed.

The maize plastid psbB-psbF-petB-petD gene cluster: spliced and unspliced petB and petD RNAs encode alternative products

The chloroplast psbB, psbF, petB, and petD genes are cotranscribed and give rise to many overlapping RNAs. The mechanism and significance of this mode of expression are of interest, particularly because the accumulation of the psb and pet gene products respond differently to both light and, in C4 species such as maize, developmental signals. We present an analysis of the maize psbB, psbF, petB, and petD genes and intergenic regions. The genes are organized similarly in maize (a C4 species) and in several C3 species. Functional class II-like introns interrupt the 5' ends of petB and petD. Both spliced and unspliced RNAs accumulate; these encode alternative forms of the petB and petD proteins, differing at their N-termini. Promoter-like elements between psbF and petB, and biased codon usage suggest that the differential regulation of the psb and pet genes might be achieved at both the transcriptional and translational levels.

Evidence for in vivo trans splicing of pre-mRNAs in tobacco chloroplasts

The rps12 gene codes for chloroplast ribosomal protein S12. In the tobacco chloroplast genome (156 kbp circular DNA), exons II and III of this gene are separated by an intron of 536 bases and are present in two copies in the inverted repeat region, while exon I is located in the large single copy region at a distance of 90 kb and 126 kb from the two copies of exons II and III. These three exons were artificially combined in cloned DNA fragments and hybridized with tobacco chloroplast RNA. Electron microscopic analysis of RNA-DNA hybrids showed that exon I is transcribed as part of a polycistronic RNA containing upstream and downstream sequences; the same is true for exons II and III. Exon I is shown to be transcribed separately from exons II and III. In the most abundant class of the hybridized RNA molecules, exon I was covalently linked to exon II. In these molecules the sequences downstream of exon I and upstream of exon II are not present. These data indicate that maturation of rps12 pre-mRNAs in chloroplasts of tobacco involves trans splicing.

The chloroplast tRNALys(UUU) gene from mustard (Sinapis alba) contains a class II intron potentially coding for a maturase-related polypeptide

The trnK gene endocing the tRNALys(UUU) has been located on mustard (Sinapis alba) chloroplast DNA, 263 bp upstream of the psbA gene on the same strand. The nucleotide sequence of the trnK gene and its flanking regions as well as the putative transcription start and termination sites are shown. The 5' end of the transcript lies 121 bp upstream of the 5' tRNA coding region and is preceded by procaryotic-type "-10" and "-35" sequence elements, while the 3' end maps 2.77 kb downstream to a DNA region with possible stemloop secondary structure. The anticodon loop of the tRNALys is interrupted by a 2,574 bp intron containing a long open reading frame, which codes for 524 amino acids. Based on conserved stem and loop structures, this intron has characteristic features of a class II intron. A region near the carboxyl terminus of the derived polypeptide appears structurally related to maturases.

Euglena gracilis chloroplast DNA: analysis of a 1.6 kb intron of the psb C gene containing an open reading frame of 458 codons

We retrieved a 1.6 kbp intron separating two exons of the psb C gene which codes for the 44 kDa reaction center protein of photosystem II. This intron is 3 to 4 times the size of all previously sequenced Euglena gracilis chloroplast introns. It contains an open reading frame of 458 codons potentially coding for a basic protein of 54 kDa of yet unknown function. The intron boundaries follow consensus sequences established for chloroplast introns related to class II and nuclear pre-mRNA introns. Its 3'-terminal segment has structural features similar to class II mitochondrial introns with an invariant base A as possible branch point for lariat formation.

Relationship of viroids and certain other plant pathogenic nucleic acids to group I and II introns

The nucleotide sequences of viroids contain features believed to be essential for the splicing of group I introns. Common sequence elements include a 16-nucleotide consensus sequence and three pairs of short sequences arranged in the same sequential order in both types of RNAs. The calculated probability of finding sequences resembling the 16-nucleotide consensus sequence in random nucleotide chains showed that at low fidelity (up to 5 mismatched nucleotides), the number of such sequences in viroids, plant viral satellite RNAs, plant viral RNAs and one plant viral DNA, group I introns and flanking exons does not significantly differ from the number expected at random. As the degree of fidelity is increased, the number in both introns and viroids, but not in exons or the other plant pathogens examined, greatly exceeds that expected in random chains. These findings suggest that viroids may have evolved from group I introns and/or that processing of viroid oligomers to monomers may have structural requirements similar to those of group I introns. The nucleotide sequences of viroids do not show close homology with two conserved regions of group II introns, the 14-base pair consensus region and the 5' terminal segment. However, close homology does exist between the conserved sequence of the 3' terminal segment of group II introns and viroids thus suggesting a possible evolutionary or functional relationship.

Excised group II introns in yeast mitochondria are lariats and can be formed by self-splicing in vitro

Excised group II introns in yeast mitochondria appear as covalently closed circles under the electron microscope. We show that these circular molecules are branched and resemble the lariats arising through splicing of nuclear pre-mRNAs in yeast and higher eukaryotes. One member of this intron class (aI5c in the gene for cytochrome c oxidase subunit I) is capable of self-splicing in vitro, giving correct exon-exon ligation and resulting in the appearance of both linear and lariat forms of the excised intron. Nuclease digestion of the latter molecules reveals the presence of a complex oligonucleotide with the probable structure AGU, which thus resembles the branch point formed in the spliceosome-dependent reactions undergone by nuclear pre-mRNAs. Unlike group I introns, this group II intron is not demonstrably dependent on GTP for self-splicing and circularization of the isolated, linear intron is not observed. A model accounting for these observations is presented.

A self-splicing RNA excises an intron lariat

We have investigated the in vitro self-splicing of a class II mitochondrial intron. A model pre-mRNA containing intron 5 gamma of the oxi 3 gene of yeast mitochondrial DNA undergoes an efficient intramolecular rearrangement reaction in vitro. This reaction proceeds under conditions distinct from those optimal for self-splicing of class I introns, such as the Tetrahymena nuclear rRNA intron. Intron 5 gamma is excised as a nonlinear RNA indistinguishable from the in vivo excised intron product by gel electrophoresis and primer extension analysis. Studies of the in vitro excised intron product strongly indicate that it is a branched RNA with a circular component joined by a linkage other than a 3'-5' phosphodiester. Two other products, the spliced exons and the broken form of the lariat, were also characterized. These results show that the class II intron products are similar to those of nuclear pre-mRNA splicing.

Analysis of class I introns in a mitochondrial plasmid associated with senescence of Podospora anserina reveals extraordinary resemblance to the Tetrahymena ribosomal intron

Recently, the nucleotide sequences for three "mitochondrial plasmids" associated with senescence of Podospora anserina were determined (Cummings et al. 1985). One of these sequences, corresponding to the plasmid termed epsilon senDNA, contains three class I introns, all within a protein coding sequence equivalent to the mammalian "URF1" gene. Here, we present primary and secondary structure analyses for two of these introns as well as a partial analysis for the third, which extends beyond the DNA sequence determined. With regard to both primary and secondary structure, the closest known relative of intron 1 is the self-splicing intron in the large ribosomal RNA gene of Tetrahymena. One secondary structure domain at the periphery of intron 1 and Tetrahymena models is also present in intron 2. The latter intron is the longest known class I member and contains remnants of two protein-coding sequences, one of which is split by the other. Evolutionary processes that might be responsible for the unusual structure of introns 1 and 2 are discussed.