Chloroplast transformation in Euglena gracilis: splicing of a group III twintron transcribed from a transgenic psbK operon.

The Escherichia coli aadA gene product, which confers resistance to spectinomycin and streptomycin, has been widely used as a dominant selectable marker for chloroplast transformation of Chlamydomonas and tobacco. An aadA transformation cassette was adapted for expression in Euglena gracilis chloroplasts by replacing the Chlamydomonas promoter and 3' untranslated region (UTR) with the E. gracilis psbA promoter and 3' UTR. Transgenic DNA was introduced into E. gracilis chloroplasts by biolistic transformation. Streptomycin- and spectinomycin-resistant colonies were obtained, which screened positively for the presence of the transforming vector by PCR amplification. Although integration of the transforming DNA into the chloroplast genome was not detected, transforming DNA was stably maintained in the chloroplast as an episomal element during continuous selection on antibiotics. The aadA cassette was also inserted into a transformation vector which contained the independently expressed psbK operon from either E. gracilis or a closely related species, E. stellata. The psbK operon contained at least two group III introns and a group III twintron, was highly expressed, and was only 1.5 kb in length. In transgenic E. gracilis chloroplasts, a truncated E. stellata psbK operon was transcribed, and the resultant pre-mRNA was accurately spliced. This system should allow the first direct analysis of group II and group III intron-splicing mechanisms. In addition, it could prove useful in the study of many other Euglena transcription and processing events.

Comparison of psbK operon organization and group III intron content in chloroplast genomes of 12 Euglenoid species.

A novel mixed operon has been identified in the photosynthetic protist E. gracilis. The genes for psbK, ycf12, psaM, and trnR are co-transcribed. The resulting tetracistronic transcripts are processed through endonucleolytic cleavage of the intergenic spacers and intron splicing to form three mature monocistronic mRNAs and a tRNA. A group III twintron and a group III intron are located in psbK. Another group III intron is found in ycf12. The psbK operon has been cloned by PCR amplification from nine related Euglenoid species. In each species, the gene order and content of the psbK operon is conserved. The psbK operons contain phylogenetically conserved eubacterial promoter, translational, and 3' processing elements. Intron content varies significantly from species to species. Based on a comparison of the intron content with the results of phylogenetic analysis, group III intron evolution within the Euglenoid lineage is much more complex than previously believed.

Evidence for the late origin of introns in chloroplast genes from an evolutionary analysis of the genus Euglena.

The origin of present day introns is a subject of spirited debate. Any intron evolution theory must account for not only nuclear spliceosomal introns but also their antecedents. The evolution of group II introns is fundamental to this debate, since group II introns are the proposed progenitors of nuclear spliceosomal introns and are found in ancient genes from modern organisms. We have studied the evolution of chloroplast introns and twintrons (introns within introns) in the genus Euglena. Our hypothesis is that Euglena chloroplast introns arose late in the evolution of this lineage and that twintrons were formed by the insertion of one or more introns into existing introns. In the present study we find that 22 out of 26 introns surveyed in six different photosynthesis-related genes from the plastid DNA of Euglena gracilis are not present in one or more basally branching Euglena spp. These results are supportive of a late origin for Euglena chloroplast group II introns. The psbT gene in Euglena viridis, a basally branching Euglena species, contains a single intron in the identical position to a psbT twintron from E.gracilis, a derived species. The E.viridis intron, when compared with 99 other Euglena group II introns, is most similar to the external intron of the E.gracilis psbT twintron. Based on these data, the addition of introns to the ancestral psbT intron in the common ancester of E.viridis and E.gracilis gave rise to the psbT twintron in E.gracilis.

Complete sequence of Euglena gracilis chloroplast DNA.

We report the complete DNA sequence of the Euglena gracilis, Pringsheim strain Z chloroplast genome. This circular DNA is 143,170 bp, counting only one copy of a 54 bp tandem repeat sequence that is present in variable copy number within a single culture. The overall organization of the genome involves a tandem array of three complete and one partial ribosomal RNA operons, and a large single copy region. There are genes for the 16S, 5S, and 23S rRNAs of the 70S chloroplast ribosomes, 27 different tRNA species, 21 ribosomal proteins plus the gene for elongation factor EF-Tu, three RNA polymerase subunits, and 27 known photosynthesis-related polypeptides. Several putative genes of unknown function have also been identified, including five within large introns, and five with amino acid sequence similarity to genes in other organisms. This genome contains at least 149 introns. There are 72 individual group II introns, 46 individual group III introns, 10 group II introns and 18 group III introns that are components of twintrons (introns-within-introns), and three additional introns suspected to be twintrons composed of multiple group II and/or group III introns, but not yet characterized. At least 54,804 bp, or 38.3% of the total DNA content is represented by introns.