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.     

Nuclear genes that promote splicing of group I introns in the chloroplast 23S rRNA and psbA genes in Chlamydomonas reinhardtii

Defence against pathogens in Arabidopsis is orchestrated by at least three signalling molecules: salicylic acid (SA), jasmonic acid (JA) and ethylene (ET). The hrl1 (hypersensitive response-like lesions 1) mutant of Arabidopsis is characterized by spontaneous necrotic lesions, accumulation of reactive oxygen species, constitutive expression of SA- and ET/JA-responsive defence genes, and enhanced resistance to virulent bacterial and oomycete pathogens. Epistasis analyses of hrl1 with npr1, etr1, coi1 and SA-depleted nahG plants revealed novel interactions between SA and ET/JA signalling pathways in regulating defence gene expression and cell death. RNA gel-blot analysis of RNA isolated separately from the lesion+ and the lesion- leaves of double mutants of hrl1 revealed different signalling requirements for the expression of defence genes in these tissues. Expression of the ET/JA-responsive PDF1.2 gene was markedly reduced in hrl1 npr1 and in SA-depleted hrl1 nahG plants. In hrl1 nahG plants, expression of PDF1.2 was regulated by benzathiadiazole in a concentration-dependent manner: induced at low concentration and suppressed at high concentration. The hrl1 etr1 plants lacked systemic PR-1 expression, and exhibited compromised resistance to virulent Pseudomonas syringae and Peronospora parasitica. Inhibiting JA responses in hrl1 coi1 plants lead to exaggerated cell death and severe stunting of plants. Finally, the hrl1 mutation lead to elevated expression of AtrbohD, which encodes a major subunit of the NADPH oxidase complex. Our results indicate that defence gene expression and resistance against pathogens in hrl1 is regulated synergistically by SA and ET/JA defence pathways.     

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.     

Self-splicing introns as a source for transposable genetic elements

Previous theories have suggested that some introns with the ability to self-splice are derived from transposable elements. However, an interpretation is given here that suggests retrotransposons and retroviruses (transposable elements which move via RNA intermediates) have evolved from self-splicing introns. This is based on the involvement of RNA intermediates, the ancestral nature of the self-splicing reaction, and the assumed presence of introns in an RNA world. Conserved sequences within the introns, essential for splicing, and their wide phylogenetic distribution also make it unlikely that they are descended from transposable elements. Mitochondrial plasmids of Neurospora species containing features of both introns and retrotransposons have a central role in the resolution of the problem and are considered here to support the view that introns are, or have been, sources of mobile elements. The possibility of other transposable elements arising from introns is also considered.     

Light affects the structure of Chlamydomonas chloroplast chromosomes.

We have analyzed changes in the structure of chloroplast chromosomes in response to light in growing Chlamydomonas cells using a crosslinking assay based on the intercalation of HMT (4'-hydroxymethyl-4,5',8-trimethylpsoralen) into DNA. Our results show that the structure of chloroplast chromosomes in at least three widely separated regions is different in light-grown vs. dark-grown cells. Structural changes in chloroplast chromosomes occur within 3 hrs after exposure to light or darkness, respectively. The response to light is not inhibited by atrazine and can be elicited by dim blue light incapable of evolving O2, indicating that it does not require photosynthesis. Inhibition of cytoplasmic protein synthesis with cycloheximide prevents this response to light, indicating that it depends, at least in part, on proteins imported from the cytoplasm.     

Free and membrane-bound chloroplast polyribosomes Chlamydomonas reinhardtii.

Over half of the chloroplast ribosomes isolated from growing cultures of Chlamydomonas reinhardtii are bound to chloroplast thylakoid membranes if completion of nascent polypeptide chains is prevented by chloramphenicol. The free chloroplast ribosomes are recovered in homogenate supernatants, and presumably originate from the chloroplast stroma. Only about 10% of these free chloroplast ribosomes are polyribosomes, even under conditions when 70% of free cytoplasm ribosomes are recovered as polyribosomes. The nonionic detergent Nonidet P-40 liberates atypical polyribosomes (Type I), from membranes, which require both ribonuclease and proteases for complete conversion to monomeric ribosomes. Thus Type I particles are held together by mRNA but are also held together by peptide bonds. These Type I polyribosomes probably are not bound to intact membrane, but might be bound to some protein-containing sub-membrane particle. The Type I polyribosomes are dissociated to ribosomal subunits by puromycin and high salt, and contained 0.2 to 1 nascent chain per ribosome. If membranes are treated with Nonidet and proteases at the same time, polyribosomes which are digested to monomeric ribosomes by ribonuclease alone (Type II) are obtained. Type II polyribosomes are smaller than Type I, and probably represent the true size distribution of polyribosomes on the membranes. At least 50% of the membrane-bound ribosomes are polyribosomes, since that much membrane bound chloroplast RNA is recovered as Type I or Type II polyribosomes.     

Sedimentation behavior of chloroplast ribosomes from Chlamydomonas reinhardtii.

The identity of peaks generated by chloroplast ribosomes of Chlamydomonas reinhardtii were determined by zone velocity sedimentation on sucrose density gradients, and analysis of distribution of ribosomal RNAs in the gradients. The sedimentagion coefficient of the principal peak was 66-70 S (usually 69 S), in good agreement with previously reported values for chloroplast ribosomes of C. reinhardtii, and other organisms. The fast sedimenting side of the 69 S peak contained an excess of chloroplast large subunit. When ribosome dissociation was prevented by sedimentation at low velocity, by aldehyde fixation, or by the presence of nascent polypeptide chains, the principal peak had a sedimentation coefficient of about 75 S. Thus the 69 S peak was an artifact caused by dissociation during centrifugation. Peaks that contained chloroplast ribosomal RNAs were also observed at '60 S' and '45 S' when chloroplast ribosomes were centrifuged unfixed at high velocity. The amounts of '60 S' and '45 S' components were decreased by centrifugation at low speed, or fixation, but sedimentation coefficients remained unchanged. The '60 S', and '45 S' components were identified as large, and small subunits of chloroplast ribosomes, respectively. The artifacts produced by centrifugation of chloroplast ribosomes, are similar to the artifacts produced by centrifuging ribosomes of Escherichia coli. Similar explanations appear to apply to both. We concluded that the 69 S chloroplast ribosome peak occurs because of dissociation of 'tight' couples, and incomplete separation of subunits. Subunit peaks (60 S and 45 S) arise from free subunits, and/or from dissociation of 'loose' couples.     

Characterization of protein-binding to the spinach chloroplast psbA mRNA 5' untranslated region.

RNA-binding proteins play a major role in regulating mRNA metabolism in chloroplasts. In this work we characterized two proteins, of 43 and 47 kDa, which bind to the spinach psbA mRNA 5' untranslated region (psbA encoding the D1 protein of photosystem II). The 43 kDa protein, which is present in the stroma and in membranes, co-sediments with a complex of 68S. It was purified, and the N-terminal sequence was determined. Upon homology search it was identified as the chloroplast homologue of the Escherichia coli ribosomal protein S1. The 47 kDa protein, which, in contrast with the 43 kDa protein, sediments with a small sedimentation coefficient, is only detected in the stromal fraction. It is soluble in an uncomplexed form. By deletion analysis, an element within the psbA mRNA 5' untranslated region was identified that is necessary but not sufficient for binding of stromal proteins. The 'central protein binding element' ranges from nucleotide -49 to -9 of the psbA mRNA 5' untranslated region. It comprises the Shine-Dalgarno-like GGAG motif and, 7 nucleotides upstream, an endonucleolytic cleavage site involved in psbA mRNA degradation in vitro . The mechanistic impacts of this region in relation to RNA-binding proteins are discussed.     

Targeted disruption of chloroplast genes in Chlamydomonas reinhardtii.

Summary We have developed an efficient procedure for the disruption of Chlamydomonas chloroplast genes. Wild-type C. reinhardtii cells were bombarded with microprojectiles coated with a mixture of two plasmids, one encoding selectable, antibiotic-resistance mutations in the 16S ribosomal RNA gene and the other containing either the atpB or rbcL photosynthetic gene inactivated by an insertion of 0.48 kb of yeast DNA in the coding sequence. Antibiotic-resistant transformants were selected under conditions permissive for growth of nonphotosynthetic mutants. Approximately half of these transformants were initially heteroplasmic for copies of the disrupted atpB or rbcL genes integrated into the recipient chloroplast genome but still retained photosynthetic competence. A small fraction of the transformants (1.1% for atpB; 4.3% for rbcL) were nonphotosynthetic and homoplasmic for the disrupted gene at the time they were isolated. Single cell cloning of the initially heteroplasmic transformants also yielded nonphotosynthetic segregants that were homoplasmic for the disrupted gene. Polypeptide products of the disrupted atpB and rbcL genes could not be detected using immunoblotting techniques. We believe that any nonessential Chlamydomonas chloroplast gene, such as those involved in photosynthesis, should be amenable to gene disruption by cotransformation. The method should prove useful for the introduction of site-specific mutations into chloroplast genes and flanking regulatory sequences with a view to elucidating their function.