Two promoters within the psbK-psbI-trnG gene cluster in tobacco chloroplast DNA

PALE CRESS binds to plastid RNAs and facilitates the biogenesis of the 50S ribosomal subunit

The plant-specific PALE CRESS (PAC) protein has previously been shown to be essential for photoautotrophic growth. Here we further investigated the molecular function of the PAC protein. PAC localizes to plastid nucleoids and forms large proteinaceous and RNA-containing megadalton complexes. It co-immunoprecipitates with a specific subset of chloroplast RNAs including psbK-psbI, ndhF, ndhD, and 23S ribosomal RNA (rRNA), as demonstrated by RNA immunoprecipitation in combination with high throughput RNA sequencing (RIP-seq) analyses. Furthermore, it co-migrates with premature 50S ribosomal particles and specifically binds to 23S rRNA in vitro. This coincides with severely reduced levels of 23S rRNA in pac leading to translational deficiencies and related alterations of plastid transcript patterns and abundance similar to plants treated with the translation inhibitor lincomycin. Thus, we conclude that deficiency in plastid ribosomes accounts for the pac phenotype. Moreover, the absence or reduction of PAC levels in the corresponding mutants induces structural changes of the 23S rRNA, as demonstrated by in vivo RNA structure probing. Our results indicate that PAC binds to the 23S rRNA to promote the biogenesis of the 50S subunit.

Reverse protection assay: a tool to analyze transcriptional rates from individual promoters

Transcriptional activity of entire genes in chloroplasts is usually assayed by run-on analyses. To determine not only the overall intensity of transcription of a gene, but also the rate of transcription from a particular promoter, we created the Reverse RNase Protection Assay (RePro): in-organello run-on transcription coupled to RNase protection to define distinct transcript ends during transcription. We demonstrate successful application of RePro in plastid promoter analysis and transcript 3' end processing.

Plastid transcriptomics and translatomics of tomato fruit development and chloroplast-to-chromoplast differentiation: chromoplast gene expression largely serves the production of a single protein

Plastid genes are expressed at high levels in photosynthetically active chloroplasts but are generally believed to be drastically downregulated in nongreen plastids. The genome-wide changes in the expression patterns of plastid genes during the development of nongreen plastid types as well as the contributions of transcriptional versus translational regulation are largely unknown. We report here a systematic transcriptomics and translatomics analysis of the tomato (Solanum lycopersicum) plastid genome during fruit development and chloroplast-to-chromoplast conversion. At the level of RNA accumulation, most but not all plastid genes are strongly downregulated in fruits compared with leaves. By contrast, chloroplast-to-chromoplast differentiation during fruit ripening is surprisingly not accompanied by large changes in plastid RNA accumulation. However, most plastid genes are translationally downregulated during chromoplast development. Both transcriptional and translational downregulation are more pronounced for photosynthesis-related genes than for genes involved in gene expression, indicating that some low-level plastid gene expression must be sustained in chromoplasts. High-level expression during chromoplast development identifies accD, the only plastid-encoded gene involved in fatty acid biosynthesis, as the target gene for which gene expression activity in chromoplasts is maintained. In addition, we have determined the developmental patterns of plastid RNA polymerase activities, intron splicing, and RNA editing and report specific developmental changes in the splicing and editing patterns of plastid transcripts.

The peach latent mosaic viroid replication initiation site is located at a universal position that appears to be defined by a conserved sequence

Viroids replicate through a rolling circle mechanism that is exclusively RNA dependent. In this study, we initially revisited the determination of the replication initiation sites of peach latent mosaic viroid (PLMVd). A universal initiation site for each of the PLMVd polarities (position A50/C51 and U284 for the plus and minus strands, respectively) that is shared by a relatively wide repertoire of viroid variants was identified, in agreement with a previous report based on a different methodology. Subsequently, an in vitro selection procedure based on a model rolling circle replication assay was developed. This latter experiment led to the identification of a highly conserved CAGACG box which is reminiscent of the sequence found in the vicinity of the PLMVd initiation sites. The conserved sequence contributes to delineating the initiation site and provides an explanation for the presence of a specific universal initiation site on the PLMVd molecule.

Complete DNA sequences of the plastid genomes of two parasitic flowering plant species, Cuscuta reflexa and Cuscuta gronovii

BACKGROUND

The holoparasitic plant genus Cuscuta comprises species with photosynthetic capacity and functional chloroplasts as well as achlorophyllous and intermediate forms with restricted photosynthetic activity and degenerated chloroplasts. Previous data indicated significant differences with respect to the plastid genome coding capacity in different Cuscuta species that could correlate with their photosynthetic activity. In order to shed light on the molecular changes accompanying the parasitic lifestyle, we sequenced the plastid chromosomes of the two species Cuscuta reflexa and Cuscuta gronovii. Both species are capable of performing photosynthesis, albeit with varying efficiencies. Together with the plastid genome of Epifagus virginiana, an achlorophyllous parasitic plant whose plastid genome has been sequenced, these species represent a series of progression towards total dependency on the host plant, ranging from reduced levels of photosynthesis in C. reflexa to a restricted photosynthetic activity and degenerated chloroplasts in C. gronovii to an achlorophyllous state in E. virginiana.

RESULTS

The newly sequenced plastid genomes of C. reflexa and C. gronovii reveal that the chromosome structures are generally very similar to that of non-parasitic plants, although a number of species-specific insertions, deletions (indels) and sequence inversions were identified. However, we observed a gradual adaptation of the plastid genome to the different degrees of parasitism. The changes are particularly evident in C. gronovii and include (a) the parallel losses of genes for the subunits of the plastid-encoded RNA polymerase and the corresponding promoters from the plastid genome, (b) the first documented loss of the gene for a putative splicing factor, MatK, from the plastid genome and (c) a significant reduction of RNA editing.

CONCLUSION

Overall, the comparative genomic analysis of plastid DNA from parasitic plants indicates a bias towards a simplification of the plastid gene expression machinery as a consequence of an increasing dependency on the host plant. A tentative assignment of the successive events in the adaptation of the plastid genomes to parasitism can be inferred from the current data set. This includes (1) a loss of non-coding regions in photosynthetic Cuscuta species that has resulted in a condensation of the plastid genome, (2) the simplification of plastid gene expression in species with largely impaired photosynthetic capacity and (3) the deletion of a significant part of the genetic information, including the information for the photosynthetic apparatus, in non-photosynthetic parasitic plants.

Eukaryotic transcription factors in plastids--Bioinformatic assessment and implications for the evolution of gene expression machineries in plants

The expression of genes in higher plant chloroplasts includes a complex transcriptional regulation which can be explained only in part with the action of the actually known components of the transcriptional machinery. This suggests the existence of still unknown important regulatory factors which influence chloroplast transcription. In order to test if such factors could exist we performed in silico analyses of Arabidopsis genes encoding putative transcription factors looking for putative N-terminal chloroplast transit peptides in the amino acid sequences. Our results suggest that 48 (and maybe up to 100) transcription factors of eukaryotic origin are likely to be imported into plastids. None of them has been described yet. This set of transcription factors highly expands the actually known regulation capacity of the chloroplast transcription machinery and provides a possible explanation for the complex initiation patterns of chloroplast transcripts. As consequence of a massive import of eukaryotic transcription factors a comprehensive reconstruction of the ancient prokaryotic gene expression machinery must be assumed resulting in a novel compatible combination of eukaryotic and prokaryotic protein components. In turn, the opposite process has been induced in the nucleus by the integration of prokaryotic components of the plastid ancestor via its loss of genes during endosymbiosis. Thus, a mutual exchange of regulatory factors, i.e. transcription factors occurred which resulted in the unique signalling network of today's plants. An evolutionary model of how this could have emerged during endosymbiosis in a timely coordinated manner is proposed.

The CaTin1 (Capsicum annuum TMV-induced clone 1) and CaTin1-2 genes are linked head-to-head and share a bidirectional promoter

CaTin1 was expressed relatively early in the TMV-inoculated leaves of hot pepper which is resistant to TMV-P(0) infection. Interestingly, there was another homologous gene (CaTin1-2) located in front of CaTin1 in a head-to-head fashion and they shared a single promoter. The expression profile of the CaTin1-2 was very similar to CaTin1 in all the treatments except the slower induction time compared to CaTin1 upon TMV-P(0) inoculation. The promoter analysis of CaTin1 and CaTin1-2 revealed bidirectionality both in cis-elements and activity. The CaTin1-2 promoter had two TATA-boxes, four GCC-boxes, the root responsive element, and a W1-box. The ethylene-inducible promoter activity depended on GCC-boxes and TMV-inducible activity of the CaTin1-2 promoter reached its highest activity when this promoter had a W1-box.

Chloroplast ribonucleoproteins are associated with both mRNAs and intron-containing precursor tRNAs

Tobacco chloroplasts possess five conserved ribonucleoproteins (cpRNPs). To elucidate the function of cpRNPs we analyzed their localization and target nucleic acid molecules in chloroplasts. Immunoprecipitation of the stromal extract and Northern analysis revealed that cpRNPs are associated in vivo with not only various species of chloroplast mRNAs but also intron-containing precursor (pre-) tRNAs. This observation strongly suggests that cpRNPs are involved in RNA processing, including mRNA stability and pre-tRNA splicing.

A ribosomal protein gene (rpl32) from tobacco chloroplast DNA is transcribed from alternative promoters: similarities in promoter region organization in plastid housekeeping genes

Multiple transcriptional start sites have been identified in the tobacco plastid ribosomal protein gene rpl32 by RNA mapping and in vitro capping techniques. A promotor with a canonical -10 Pribnow Box (P1) produces a major transcript in leaf chloroplasts. Transcription is also driven from additional promoters in non-photosynthetic plastids from heterotrophically cultured cells (BY2 line). Among them, a second promoter located downstream (P2) generates the most prominent transcript in this type of cell. The absence of typical plastid promoter motifs upstream of this site and the higher steady-state level of the P2-derived transcript in BY2 cells suggest a distinct modulation of transcription. Mobility shift experiments also seem to indicate the existence of differences in protein-DNA binding between both kinds of plastids with respect to a DNA fragment including the sequence upstream from the P2 starting site. The structure of the rpl32 promoter region is discussed in relation to that of other plastid housekeeping genes encoding elements of the genetic machinery.

Chloroplast rRNA transcription from structurally different tandem promoters: an additional novel-type promoter

Identification of transcription initiation sites in the promoter region of the tobacco chloroplast rRNA operon has been carried out by ribonuclease protection of in vitro capped RNAs and primer extension experiments. A promoter with typical chloroplast -10 and -35 motifs (P1) drives initiation of transcription from position -116 relative to the mature 16s rRNA sequence. In addition, we have found that a second primary transcript starts at position -64. This proximal promoter (P2) lacks any elements similar to those reported so far in chloroplast promoter regions, and hence P2 represents a novel-type promoter. Both transcripts are present in chloroplasts from green leaves and in non-photosynthetic proplastids from heterotrophically cultured cells (BY2), but their relative amounts appear to differ. The steady state level of the P2 transcript, with respect to P1, is higher in BY2 proplastids than in leaf chloroplasts.

The rps3-rpl16-nad3-rps12 gene cluster in rice mitochondrial DNA is transcribed from alternative promoters

The two gene clusters rps3-rpl16 and nad3-rps12 are separated from each other in the mitochondrial genome and are expressed as the individual transcription units in many plants. In rice mitochondrial DNA (mtDNA), the four genes rps3, rpl16, nad3 and rps12 are located within a region of 6 kbp. Northern-blot analysis revealed that a large transcript (6.6 kb) hybridized to both the rps3-rpl16 and the nad3-rps12 gene clusters. Using RT-PCR, we amplified a fragment of anticipated size (790 bp) from two primers that corresponded to sequences in the coding regions of rpl16 and nad3, demonstrating that at least two of the four genes, namely rpl16 and nad3, were co-transcribed. These results together indicated that all four genes, namely, rps3, rpl16, nad3 and rps12, were co-transcribed in rice mitochondria. Transcription initiation sites were determined by an in vitro capping/ribonuclease protection assay and primer extension analysis. Two initiation sites were identified in the rps3-rpl16-nad3-rps12 gene cluster: one was located upstream of rps3 and the other was located between rpl16 and nad3. This evidence indicates that the rps3-rpl16-nad3-rps12 gene cluster is transcribed from two alternative promoters.

Structure and expression characteristics of the chloroplast DNA region containing the split gene for tRNA(Gly) (UCC) from mustard (Sinapis alba L.)

The mustard chloroplast gene trnG-UCC is split by a 717-bp group-II intron. Northern hybridization and RNase protection experiments suggest cotranscription with the upstream psbK-psbI operon, but not with the downstream trnR-UCU gene. The ends of most RNase-protected fragments between psbI and trnG correlate with the position of two potential stem-loop structures in this region, which could act as RNA processing elements. However, one RNA 5' end, approximately 75 bp upstream of the trnG 5' exon, does not so correlate and is preceded by prokaryotic-type '-10' and '-35' sequence elements. This suggests the possibility that a fraction of the trnG transcripts is initiated here. All precursor transcripts spanning the trnG region seem to have a common 3' end, which was located 117 bp downstream from the 3' exon, immediately after a stem-loop region. During seedling development, the major 0.8-0.9-kb trnG precursor transcripts show a transient maximum level at around 48 h after sowing, at a time when the mature tRNA begins to accumulate to constant levels. No significant differences in transcript patterns were observed either in the light or in darkness.

An atpE-specific promoter within the coding region of the atpB gene in tobacco chloroplast DNA

The atpB and atpE genes encode beta and epsilon subunits, respectively, of chloroplast ATP synthase and are co-transcribed in the plant species so far studied. In tobacco, an atpB gene-specific probe hybridizes to 2.7- and 2.3-kb transcripts. In addition to these, a probe from the atpE coding region hybridizes also to a 1.0-kb transcript. The 5' end of the atpE-specific transcript has been mapped 430/431 nt upstream of the atpE translation initiation site, within the coding region of the atpB gene. In-vitro capping revealed that this transcript results from a primary transcriptional event and is also characterized by -10 and -35 canonical sequences in the 5' region. It has been found to share a common 3' end with the bi-cistronic transcripts that has been mapped within the coding region of the divergently transcribed trnM gene, approximately 236 nt downstream from the atpE termination codon. Interestingly, this transcript accumulates only in leaves and not in proplastid-containing cultured (BY-2) cells, indicating that, unless it is preferentially degraded in BY-2 cells, its expression might be transcriptionally controlled.

A transcription map of the chloroplast genome from rice (Oryza sativa)

The complete nucleotide sequence (134,525 bp) of the chloroplast genome from rice (Oryza sativa L.) contains four rRNA genes, 30 tRNA genes, and over 100 genes that encode proteins. However, expression of only a few of these genes, namely psbA, rbcL, and atpB/E, has been detected. We constructed the complete transcription map of rice chloroplast DNA by Northern hybridization of total RNA from rice seedlings, using subclones from a clone bank of rice chloroplast DNA as probes. Approximately 90% of the chloroplast genome was transcribed, as detected by a non-radioactive hybridization system. Most of the genes on the chloroplast DNA are organized as clusters and are co-transcribed as long primary transcripts. We identified 16 polycistronic transcripts from the rice chloroplast genome. Furthermore, the genes for components of photosystems I and II, the gene for the large subunit of RuBisCO, the genes for ATPase, the genes for components of the cytochrome complex, and the rRNA genes were expressed at the highest levels.

Characterization of the psbK locus of Synechocystis sp. PCC 6803 in terms of Photosystem II function

The psbK gene encodes a small protein of Photosystem II. The gene has previously been cloned and sequenced in Synechocystis sp. PCC 6803. Our new results, presented here, confirm the conclusions of Ikeuchi et al. Based on Northern hybridization and primer extension analyses, we show that psbK is transcribed as a monocistronic message in this cyanobacterium. Analysis of DNA sequence immediately upstream of the transcription start site revealed an E. coli-like-10 consensus sequence. A deletion mutant was constructed where the psbK gene was replaced by a kanamycin resistant cartridge. In situ complementation experiments, as well as Southern and Northern hybridization analyses, confirmed that the mutant strain contains a lesion in psbK. The psbK-less mutant could grow photoautotrophically as well as photoheterotrophically both in liquid culture and on agar plates. The rate of growth was slightly less compared with the wild-type as clearly observed by in situ complementation experiments. Although the mutant showed correspondingly lower rates of electron transport, thermoluminescence, oxygen flash yield and chlorophyll a fluorescence measurements did not detect any significant modification of the reactions of PS II. Moreover, the mutant was no more susceptible to excess light than the wild-type. It is, therefore, concluded that the product of the psbK gene is not crucial for PS II activity and possibly plays some other role in the metabolism of Synechocystis.

Combination of in vitro capping and ribonuclease protection improves the detection of transcription start sites in chloroplasts

A primary transcript from the chloroplast rpl32 gene was labelled at its 5' end using a capping enzyme and [alpha-32P]GTP followed by hybridization to a cold RNA probe. A RNase protection assay gave a clear protected band and its initiation site of transcription could thus be estimated, which had not been possible by using DNA probes. The combination of in vitro capping and RNase protection is an excellent method for mapping transcription initiation sites on the chloroplast genome and shows a high improvement relative to the DNA-employing strategies.

Active transcription from a promoter positioned within the coding region of a divergently oriented gene: the tobacco chloroplast rpl32 gene

A new transcription unit has been identified and characterized in the small single-copy region of tobacco chloroplast DNA. A primary transcript (1550 nucleotides) spanning the entire transcription unit contains no significant open reading frames (ORFs), other than ORF55, recently identified as the gene encoding the ribosomal protein CL32 (rpl32). The leader sequence extends 1101 nucleotides from the rpl32 initiation codon. Primer extension and in vitro capping experiments in combination with ribonuclease protection assays, revealed a promoter situated more than 322 bp inside the coding region of ndhF, which is divergently oriented with respect to rpl32. A canonical Pribnow-box is found just upstream of the transcription start site, but a typical -35 motif was not detected. This is the first internal divergent promoter to be characterized in the chloroplast genome.