In vitro analysis of the pea chloroplast 16S rRNA gene promoter

The two RNA polymerases encoded by the nuclear and the plastid compartments transcribe distinct groups of genes in tobacco plastids

The plastid genome in photosynthetic higher plants encodes subunits of an Escherichia coli-like RNA polymerase (PEP) which initiates transcription from E.coli sigma70-type promoters. We have previously established the existence of a second nuclear-encoded plastid RNA polymerase (NEP) in photosynthetic higher plants. We report here that many plastid genes and operons have at least one promoter each for PEP and NEP (Class II transcription unit). However, a subset of plastid genes, including photosystem I and II genes, are transcribed from PEP promoters only (Class I genes), while in some instances (e.g. accD) genes are transcribed exclusively by NEP (Class III genes). Sequence alignment identified a 10 nucleotide NEP promoter consensus around the transcription initiation site. Distinct NEP and PEP promoters reported here provide a general mechanism for group-specific gene expression through recognition by the two RNA polymerases.

Activity of the Chlamydomonas chloroplast rbcL gene promoter is enhanced by a remote sequence element

The chloroplast gene rbcL encodes the large subunit of ribulose bisphosphate carboxylase. In Chlamydomonas reinhardtii, this gene is transcribed more actively than any other protein-encoding chloroplast gene studied to date. To delineate the rbcL gene promoter, chimeric reporter genes containing fragments of the 5' region of the rbcL gene fused to the coding sequence of the bacterial uidA gene, encoding beta-glucuronidase, were stably introduced into the chloroplast genome of Chlamydomonas by microprojectile bombardment. The relative transcription rates of endogenous and introduced genes were determined in transgenic cell lines in vivo. The basic rbcL promoter is located within the region of the gene extending from positions -18 to +63, taking position +1 as the site of initiation of transcription. A chimeric reporter gene containing only the basic promoter is transcribed only 1-15% as actively as the endogenous rbcL gene, depending on the conditions under which cells are grown and tested. However, a chimeric gene containing rbcL sequences extending to position +170 or beyond is transcribed at about the same rate as the endogenous gene. Deletion of the sequence between positions +170 and +126, well within the protein-encoding region, reduces the rate of transcription to that of reporter genes with the basic promoter alone.

High-frequency plastid transformation in tobacco by selection for a chimeric aadA gene

We report here a 100-fold increased frequency of plastid transformation in tobacco by selection for a chimeric aadA gene encoding aminoglycoside 3"-adenylyltransferase, as compared with that obtained with mutant 16S rRNA genes. Expression of aadA confers resistance to spectinomycin and streptomycin. In transforming plasmid pZS197, a chimeric aadA is cloned between rbcL and open reading frame ORF512 plastid gene sequences. Selection was for spectinomycin resistance after biolistic delivery of pZS197 DNA into leaf cells. DNA gel-blot analysis confirmed incorporation of the chimeric aadA gene into the plastid genome by two homologous recombination events via the flanking plastid gene sequences. The chimeric gene became homoplasmic in the recipient cells and is uniformly transmitted to the maternal seed progeny. The ability to transform routinely plastids of land plants opens the way to manipulate the process of photosynthesis and to incorporate novel genes into the plastid genome of crops.

Two distinct transcriptional activities of pea (Pisum sativum) chloroplasts share immunochemically related functional polypeptides

An RNA polymerase activity has been purified from pea (Pisum sativum) chloroplast extracts with a distinct transcriptional specificity for a chloroplast messenger gene. This activity (ms-RNA pol) differs from the pea RNA polymerase preparation reported by Sun, Shapiro, Wu & Tewari [(1986) Plant Mol. Biol. 6, 429-439], which specifically transcribes only the rRNA gene (rb-RNA pol). The specificity of transcription has been assessed by the synthesis in vitro of discrete transcripts of predicted sizes using cloned promoter regions of the chloroplast psbA and 16 S rRNA genes. The ms-RNA pol preparation, with polypeptides ranging in apparent molecular mass from 22 to 180 kDa, correctly initiates transcription from recombinant plasmids containing the psbA promoter and does not support 16 S rRNA promoter-directed transcription. The two activities differ also in their response to Mn2+ ions. To investigate whether the two transcriptional activities share common functional polypeptides, monoclonal antibodies were developed against the rb-RNA pol preparation. Three clones were selected on the basis of their ability to inhibit transcription in vitro of the 16 S rRNA gene by rb-RNA pol. The antibodies from these clones independently recognized three polypeptides with molecular masses of 27, 90 and 95 kDa on immunoblots. Antibodies cross-reacting with the 90 kDa polypeptide completely eliminated the specific retardation of an end-labelled 16 S rRNA promoter fragment in a mobility-shift assay, whereas the antibodies against the 95 kDa polypeptide resulted in the formation of a ternary complex (enzyme-DNA-antibody). The antibodies cross-reacting with the 27 kDa polypeptide, however, did not alter the mobility of the retarded DNA-enzyme complex on the gel. These antibodies also inhibited transcription in vitro of the psbA gene by ms-RNA pol and recognized polypeptides of identical molecular masses in the ms-RNA pol. These results show that the three polypeptides are functional components of the chloroplast transcriptional complex and appear to be involved in the transcription of both rRNA and mRNA genes. Transcriptional specificity is probably conferred by ancillary transcription factor(s) which remain to be identified.

Two types of chloroplast gene promoters in Chlamydomonas reinhardtii

Structures of the promoters of Chlamydomonas reinhardtii plastid atpB and 16S rRNA-encoding genes were analyzed in vivo. Chimeric constructs, containing the Chlamydomonas chloroplast atpB or 16S rRNA-encoding gene promoter coupled to the Escherichia coli uidA (beta-glucuronidase, GUS) reporter gene and bordered by C. reinhardtii chloroplast sequences, were stably introduced into the chloroplast of Chlamydomonas by microprojectile bombardment. Activity of the promoters in the chloroplast of GUS gene-positive transformants was assayed by measuring the abundance of GUS transcripts and determining the relative rates of GUS transcription in vivo. Deletion analyses of the 16S rRNA gene and atpB promoter fragments showed that the two promoters differ structurally. The 16S rRNA gene promoter resembles the bacterial sigma 70 type with typical -10 and -35 elements. The atpB promoter, on the other hand, lacks a conserved motif in the -35 region but contains, in the -10 region, a characteristic octameric palindrome (TATAATAT) that is conserved in the promoter sequences of some other C. reinhardtii chloroplast genes. For maximum activity, the atpB promoter requires sequences of approximately 22 base pairs upstream and approximately 60 base pairs downstream of the transcription start site.

Identification of the template binding polypeptide in the pea chloroplast transcriptional complex

We have identified the template-binding polypeptide in the pea chloroplast transcriptional complex by photoaffinity labelling. This polypeptide has an apparent molecular weight of about 150 kDa and binds to both, chloroplast ribosomal (16S rRNA) and messenger (psbA) promoters. The 16S rRNA and psbA promoters were amplified from chloroplast DNA by the polymerase chain reaction and labelled with a photoactive analogue of TTP, 5-bromodeoxy UTP, as well as with alpha-32P-dCTP. Using the filter-binding assay, the conditions for binding of the RNA polymerase complex to chloroplast promoters were optimized. The polypeptide directly interacting with the template was photo-crosslinked to it and resolved by denaturing gel electrophoresis. The photoaffinity labelling of the 150 kDa polypeptide was dependent on photoactivation by UV irradiation, and the presence of chloroplast promoters. Competition experiments showed that the protein formed a strong interaction with the plastid promoters which could not be displaced by lambda-phage DNA or synthetic polynucleotides. The photo-crosslinked and nuclease-treated promoter-polypeptide complex was resistant to further digestion with DNase and RNase, but could be hydrolyzed by Proteinase K. Binding of the promoters by the 150 kDa polypeptide could not be surpressed by transcription inhibitors like rifampicin and alpha-amanitin. However, heparin (0.001%) inhibited the formation of the enzyme-promoter complex, and interfered with the photoaffinity labelling of the 150 kDa polypeptide. The extent of photoaffinity labelling of 150 kDa polypeptide exhibits some degree of correlation to total transcriptional activity under various salt concentrations. The results demonstrate that the 150 kDa polypeptide is a functional template binding polypeptide of the pea chloroplast transcription complex.

Photoaffinity labelling of the pea chloroplast transcriptional complex by nascent RNA in vitro

We have used photoaffinity labelling to examine the chloroplast RNA polymerase components which come into contact with nascent transcripts during the in vitro transcription of plastid DNA. The transcripts were synthesized in the presence of a photoactive analogue (4-thio UTP) and alpha-32P-ATP, using enriched pea chloroplast RNA polymerase preparation and a recombinant plasmid containing the plastid 16S rRNA promoter. Brief irradiation of the transcriptional complex crosslinked the photoactive nascent RNA to proximal proteins. Labelling of the transcriptional complex was dependent on 4-thio UTP and template DNA. Two polypeptides of 51 and 54 kDa were consistently crosslinked to the nascent transcripts; about 60% of the total radioactivity of the crosslinked RNA was associated with these polypeptides. In some experiments, two additional polypeptides of 38 and 75 kDa were also found to be associated with about 13% and 17% of the total crosslinked RNA radioactivity, respectively. The UV-crosslinked transcriptional complexes were stable to either DNase or S1 nuclease hydrolysis but partially sensitive to RNase T1. Insensitivity of the complex to hydrolysis with RNase H suggested that the nascent transcripts were not crosslinked to the template. The complexes could also be hydrolysed by proteinase K and thermolysin. No crosslinkage was observed when labelled RNA molecules containing 4-thio UMP residues were added after synthesis to the polymerase preparation. This suggested that the method identified only those polypeptides which came into close contact with the transcript during its synthesis. Antibodies raised against the RNA-protein complex confirmed the presence of the polypeptides in the chloroplast RNA polymerase preparation on Western blots. Preincubation of these antibodies with the chloroplast RNA polymerase inhibited plastid DNA transcription. These data showed that the transcript-binding polypeptides were functional components of the chloroplast transcriptional complex.

Characterization of a protein binding sequence in the promoter region of the 16S rRNA gene of the spinach chloroplast genome

By means of mobility-shift assays and Exonuclease III mapping we have determined a 14 bp sequence (named CDF2 binding site) located in front of the 16S rRNA initiation start site which is protected by a spinach chloroplast extract. This region does not include neither one of the two '-35' nor of the two '-10' E. coli-like promoter elements which are recognised by E. coli RNA polymerase in vitro. The CDF2 binding site is specifically recognized by two small polypeptides which migrate corresponding to 35 and 33 kDa respectively as shown by UV cross-linking experiments. In vivo transcription initiation of the 16S rRNA gene occurs 13 nucleotides downstream of the 14 bp sequence and is different from the transcription start site which is used by E.coli polymerase in vitro.