Localization of two novel chloroplast genome functions: trans-splicing of RNA and protochlorophyllide reduction

Summary Chloroplast DNA deletions in the unicellular green alga Chlamydomonas reinhardtii localize two novel chloroplast gene functions. One of these, tscA, is required in trans for splicing, in trans, of the first and second, but not the second and third, exons of the RNA of the chloroplast gene psaA. Previously, no chloroplast genes were known to be required in trans for the splicing of chloroplast RNA. The other chloroplast gene function is required for light-independent reduction of protochlorophyllide, a key step in the algal pathway of chlorophyll biosynthesis. Both functions reside in the same 4 kbp region of chloroplast DNA.     

Two new group-II twintrons in the Euglena gracilis chloroplast are absent in basally branching Euglena species

Studies of the phylogeny and chloroplast intron content of selected Euglena species have led to insights in our understanding of the timing of intron acquisition. In the current study, two new twintrons, found in E. gracilis, have been characterized by the analysis of partially spliced pre-mRNAs. Intron 1 of atpE is a 463-nt group-II intron interrupted by a second group-II intron 320 nt long. Intron 1 of psbD is also a group-II twintron with external and internal introns of 635 nt and 463 nt, respectively. The two introns composing the psbD twintron, as well as six additional group-II introns found in the E. gracilispsbD gene, are not present in several basally branching Euglena species, including E. myxocylindracea, E. stellata and E. viridis. The distribution of psbD introns in Euglena is consistent with a late evolutionary acquisition of group-II introns in this lineage. Received: 4 March / 11 September 1996     

The trans-spliced intron 1 in the psaA gene of the Chlamydomonas chloroplast: a comparative analysis

In the secondary structure model that has been proposed for the trans-spliced intron 1 in the Chlamydomonas reinhardtii psaA gene, a third RNA species (tscA RNA) interacts with the 5 and 3 intron parts flanking the exons to reconstitute a composite structure with several features of group-II introns. To test the validity of this model, we undertook the sequencing and modelling of equivalent introns in the psaA gene from other unicellular green algae belonging to the highly diversified genus Chlamydomonas. Our comparative analysis supports the model reported for the C. reinhardtii psaA intron 1, and also indicates that the 5 end of the tscA RNA and the region downstream from the psaA exon 1 cannot be folded into a structure typical of domain I as described for most group-II introns. It is possible that a fourth RNA species, yet to be discovered, provides the parts of domain I which are apparently missing.     

Splicing of the mitochondrial group-II intron rl1: conserved intron-exon interactions diminish splicing efficiency

The mitochondrial intron rI1 is a self-splicing group-II intron of algal mitochondria that can be transferred into chloroplasts from the green alga Chlamydomonas reinhardtii for in vivo investigations (Herdenberger et al. 1994). Thus, rI1 is a suitable system to compare in vitro and in vivo RNA processing. Interestingly, rI1 shows correct RNA splicing, although typical cis-acting exon-sequences (IBS2, δ) of group-II introns are lacking. In order to examine the effect of these exon-intron interactions on splicing, we introduced the endogenous mitochondrial IBS2 sequence in order to produce optimal IBS2-EBS2 base pairing. In addition, the first nucleotide of the 3′exon (δ′) was substituted to create an optimal δ-δ′ interaction. Neither of the two mutations, nor a combination of both, had any effect on the precision of the splice-site selection. Unexpectedly, introduction of IBS2 led to a reduction in the efficiency of the second splicing step in vitro but not in vivo. These findings lead us to conclude that trans-acting factors are present in vivo to optimize splicing efficiency. The possibility is discussed that these factors may, for example, stabilize tertiary intron structures that are a prerequisite for correct RNA processing. Furthermore, our data indicate that similar trans-acting factors promote correct intron splicing in chloroplasts and mitochondria. Received: 18 October / 4 December 1997     

Expression of intron-encoded maturase-like polypeptides in potato chloroplasts

The trnK gene has been identified on a cloned plastid DNA fragment of potato (Solanum tuberosum cv Désirée). This gene codes for a tRNA-Lys and is interrupted by a 2.5-kb intron belonging to the group II organellar introns. In addition, this intervening sequence contains a long open reading frame potentially coding for a 509 amino-acid polypeptide (ORF509) related to mitochondrial intron-encoded maturases from fungi. The translational capacity of the trnK intron was first demonstrated in vitro in a prokaryotic DNA-directed expression system. In order to examine the expression of the intron in the potato plant, a synthetic peptide corresponding to the last nine amino acids of the predicted ORF509 product was used to raise antibodies. Westernblot experiments on chloroplast protein extracts, using a sensitive chemiluminescent detection system, identified polypeptides similar to in-vitro products. These results suggest that the trnK intron is expressed at the protein level in the plant. This is the first report of the in-vivo expression of an intron-encoded polypeptide in higher plant plastids.     

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

Summary 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.     

The group IIB intron from the green alga Scenedesmus obliquus mitochondrion: molecular characterization of the in vitro splicing products

Summary In the presence of high molar salt concentrations, the mitochondrial group IIB intron (rI1) from the green alga Scendesmus obliquus is capable of splicing in vitro. After establishing the optimal conditions for RNA processing the in vitro splicing products were unequivocally identified in self-splicing experiments by Northern hybridization analysis employing 3end-labelled RNAs or exon-and/or intron-specific probes. Finally, two trans-esterification products were identified by sequencing of the spliced RNA. From our data we conclude that the processing of group II introns from both algal and yeast mitochondria is preceded by identical consecutive trans-esterification steps. The predicted secondary and tertiary structure of intron rI1 of S. obliquus contains all the motifs necessary for optimal self-splicing and which are characteristic of other group IIB introns from different species.     

Splicing and editing of rps10 transcripts in potato mitochondria

The structure and expression of the potato mitochondrial gene rps10, encoding ribosomal protein S10, has been characterized. The RPS10 polypeptide of 129 amino acids is encoded by two exons of 307 bp and 80 bp respectively, which are separated by a 774-bp class-II intron. Editing of the complete rps10 coding region was studied by sequence analysis of spliced cDNAs. Four C residues are edited into U, resulting in the creation of a putative translational initiation codon, a new stop codon which eliminated ten carboxy-terminal residues, and two additional amino-acid alterations. All these changes increase the similarity between the potato and liverwort polypeptides. One additional C-to-U RNA editing event, observed in the intron sequence of unspliced cDNAs, improves the stability of the secondary structure in stem I (i) of domain I and may thus be required for the splicing reaction. All spliced cDNAs, and most unspliced cDNAs, were completely edited, suggesting that editing is an early step of rps10 mRNA processing and precedes splicing. Earlier work on potato rps10 (Zanlungo et al. 1994) is now known to comprise only a partial analysis of the gene, since the short downstream exon was not identified.     

An optional group I intron between the chloroplast small subunit rRNA genes of Chlamydomonas moewusii and C. eugametos

Summary We report the presence of a 402 by group I intron in the chloroplast small subunit (SSU) rRNA gene of Chlamydomonas moewusii. The intron is inserted within the highly conserved 530 loop, at a site corresponding to positions 531–532 of the E. coli 16rRNA. Residues surrounding the insertion site almost certainly play an important role in ribosomal proofreading function as they proved to be protected by tRNAs in E. coli 16S rRNA (Moazed and Noller 1986; Stern et al. 1986). The C. moewusii intron revealed a secondary structure model which differs substantially from those of the typical subgroup IA and IB introns. This model, however, shows striking similarities with the structures of the C. reinhardtii chloroplast 23S rRNA gene intron (Rochaix et al. 1985), the S. cerevisiae mitochondrial COB3 intron (Holl et al. 1985) and the three introns of phage T4 in the nrdB, td and sunY genes (Shub et al. 1988). The SSU rRNA gene intron is absent from C. eugametos, an alga that is interfertile with C. moewusii. The presence/absence of the intron account for a 390 by restriction fragment length polymorphism between the two algal SSU rRNA genes, a polymorphic locus that is strictly co-inherited with a tightly linked streptomycin resistance mutation (sr-2) in interspecific hybrids between the two algae.     

An intron in the 23S rRNA gene of the Chlorella chloroplasts: Complete nucleotide sequence of the 23S rRNA gene

Summary A 243 by intron was found within the 23S rRNA gene of the unicellular green alga Chlorella ellipsoidea. This intron is A+T-rich (63.7%) compared with the 23S rRNA (50.5%) and is located in domain II of the 23S rRNA. In contrast to rRNA introns so far known, this intron is considerably small and does not posses features of group I introns in spite of its possible folded secondary structure; this is a new type rRNA intron. The complete nucleotide sequence of the 23S rRNA gene (2,965 bp) was also compared with that of tobacco chloroplasts and E. coli.     

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

Summary 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 > A > G > 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. Abbreviations and notations: Gene names follow the convention of Hallick and Bottomley (1983: psaA, psaB, genes for the P₇₀₀ apoprotein; psbE an psbF, genes foe the subunits of cytochrome b ₅₅₉; orfN, open reading frame of N condons     

The chloroplast gene cluster containing psbF,psbL, petG and rps3 is conserved in Chlamydomonas

We have sequenced a 6.8-kb segment of the Chlamydomonas eugametos chloroplast DNA which contains the psbF, psbL, petG and rps3 genes. As in the distantly related green alga Chlamydomonas reinhardtii, these genes reside in this order (53) on the same DNA strand, suggesting that such a chloroplast gene cluster was present in the most recent common ancestor of all Chlamydomonas species. For each of the four genes, with the exception of rps3, the C. eugametos and C. reinhardtii coding regions were found to be identical, or very similar, in length, whereas each of the intergenic spacers is substantially longer in C. eugametos than in C. reinhardtii. The central portion of both Chlamydomonas rps3 genes features a long extra coding region relative to other rps3 sequences. We have shown that the insertion sequence in the C. eugametos rps3 is not excised at the RNA level.     

Hypothesis for the evolutionary origin of the chloroplast ribosomal protein L21 of spinach

Summary A full size cDNA clone encoding the chloroplast ribosomal protein L21 from spinach is presented. The identity of the clone and the location of the transit peptide processing site were determined by comparison with the N-terminal amino acid sequence of the spinach chloroplast protein CS-L7 previously identified. L21 r-protein sequences from spinach, Marchantia polymorpha and Escherichia coli are compared. Quite surprisingly, the data do not suggest that the rpl21 nuclear gene from spinach was derived through intracellular gene transfer from the chloroplast genome. The possibility of a mitochondrial origin for rpl21 gene of spinach is discussed.     

Organization of ribosomal protein genes rp123, rp12, rps19, rp122 and rps3 on the Euglena gracilis chloroplast genome

Summary The nucleotide sequence (4,814 bp) was determined for a cluster of five ribosomal protein genes and their DNA flanking regions from the chloroplast genome of Euglena gracilis. The genes are organized as rp123 — 150 by spacer — rpl2 — 59 by spacer —rps19 — 110 by spacer — rp122 — 630 by spacer — rps3. The genes are all of the same polarity and reside 148 bp downstream from an operon for two genes of photosystem I and four genes of photosystem II. The Euglena ribosomal protein gene cluster resembles the S-10 ribosomal protein operon of Escherichia coli in gene organization and follows the exact linear order of the analogous genes in the tobacco and liverwort chloroplast genomes. The number and positions of introns in the Euglena ribosomal protein loci are different from their higher plant counterparts. The Euglena rp123, rps19 and rps3 loci are unique in that they contain three, two and two introns, respectively, whereas rp12 and rp122 lack introns. The introns found in rpl23 (106, 99 and 103 bp), rps19 (103 and 97 bp) and rps3 intron 2 (102 bp) appear to represent either a new class of chloroplast intron found only in constitutively expressed genes, or possibly a degenerate version of Euglena chloroplast group II introns. They are deficient in bases C and G and extremely rich in base T, with a base composition of 53–76% T, 25–34% A, 3–10% G and 2–7% C in the mRNA-like strand. These six introns show minimal resemblance to group IT chloroplast introns. They have a degenerate version of the group II intron conserved boundary sequences at their 5 and 3 ends. No conserved internal secondary structures are apparent. By contrast, rps3 intron 1 (409 bp) has a potential group II core secondary structure. The five genes, rpl23 (101 codons), rpl2 (278 codons), rpsl9 (95 codons), rpl22 (114 codons) and rps3 (220 codons) encode lysine-rich polypeptides with predicted molecular weights of 12,152, 31,029, 10,880, 12,819, and 25,238, respectively. The Euglena gene products are 18–50%, and 29–58% identical in primary structure to their E. coli and higher plant counterparts, respectively. Oligonucleotide sequences corresponding to Euglena chloroplast ribosome binding sites are not apparent in the intergenic regions. Inverted repeat sequences are found in the upstream flanking region of rp123 and downstream from rps3. Abreviations: Gene names follow the convention of Hallick and Bottomley (1983): rp123, rpl2, rpl22 are, respectively, genes for the L23, L2, L22 polypeptides of the 50S ribosomal subunit; rps19 and rps3 are genes for the S19 and S3 polypeptides of the 30S ribosomal subunit     

Gene structure and expression of a novel Euglena gracilis chloroplast operon encoding cytochrome b6 and the β and ε subunits of the H+-ATP synthase complex

The genes encoding cytochrome b6 of the chloroplast cytochrome b6/f complex (petB) and the ATP synthase CF₁- subunit (atpB) and -subunit (atpE) were identified on the EcoD fragment of the Euglena gracilis chloroplast genome. The complete nucleotide sequence of these three genes was determined. The petB-atpB-atpE genes are cotranscribed as a tricistronic operon. This gene organization differs from that of land plants in which atpB-atpE form a discistronic operon, and petB is within the psbB-ycf8-psbH-petB-petD operon. Euglena cytochrome b6 and the -subunit of the chloroplast ATP synthase are very similar in derived amino acid sequence to the corresponding gene products from other organisms. The -subunit of the chloroplast ATP synthase complex is more divergent. In Euglena, the petB-atpB-atpE genes contain introns, including two twintrons, at eight different positions. All of the intron positions were confirmed by analysis of cDNAs. Two independent intercistronic RNA processing events and 11 splicing reactions lead to the accumulation of the mature petB, atpB and atpE monocistronic mRNAs.     

Inheritance of mitochondrial and chloroplast genome markers in backcrosses of Chlamydomonas eugametos x Chlamydomonas moewusii hybrids

Summary Southern blot analysis of AvaI-digested total cellular DNA from the interfertile species Chlamydomonas eugametos and Chlamydomonas moewusii with a coxI mitochondrial gene probe from Chlamydomonas reinhardtii revealed single hybridizing fragments of 5.0 and 3.5 kb, respectively. The transmission of these mitochondrial DNA physical markers along with that of chloroplast genetic markers for resistance to streptomycin and resistance to erythromycin was studied in the fourth backcrosses of F₁ hybrids to one or the other parent. Viability in these backcrosses is high in contrast to the cross C. eugametos x C. moewusii and its reciprocal which are associated with considerable meiotic product lethality. The resulting zygospores were found to transmit the mitochondrial and chloroplast genome markers uniparentally or preferentially from the mating-type-plus parent. Thus the species pair C. eugametos and C. moewusii differs from the pair Chlamydomonas reinhardtii and Chlamydomonas smithii in which mitochondrial genome markers are transmitted uniparentally by the mating-type minus parent, while the chloroplast genome markers are transmitted uniparentally by the opposite parental mating-type (Boynton et al. 1987).