DNA-dependent RNA polymerase of spinach chloroplasts: Characterization of α-like and σ-like polypeptides

Plastid RNA polymerases: orchestration of enzymes with different evolutionary origins controls chloroplast biogenesis during the plant life cycle

Chloroplasts are the sunlight-collecting organelles of photosynthetic eukaryotes that energetically drive the biosphere of our planet. They are the base for all major food webs by providing essential photosynthates to all heterotrophic organisms including humans. Recent research has focused largely on an understanding of the function of these organelles, but knowledge about the biogenesis of chloroplasts is rather limited. It is known that chloroplasts develop from undifferentiated precursor plastids, the proplastids, in meristematic cells. This review focuses on the activation and action of plastid RNA polymerases, which play a key role in the development of new chloroplasts from proplastids. Evolutionarily, plastids emerged from the endosymbiosis of a cyanobacterium-like ancestor into a heterotrophic eukaryote. As an evolutionary remnant of this process, they possess their own genome, which is expressed by two types of plastid RNA polymerase, phage-type and prokaryotic-type RNA polymerase. The protein subunits of these polymerases are encoded in both the nuclear and plastid genomes. Their activation and action therefore require a highly sophisticated regulation that controls and coordinates the expression of the components encoded in the plastid and nucleus. Stoichiometric expression and correct assembly of RNA polymerase complexes is achieved by a combination of developmental and environmentally induced programmes. This review highlights the current knowledge about the functional coordination between the different types of plastid RNA polymerases and provides working models of their sequential expression and function for future investigations.

Plastid sigma factors: Their individual functions and regulation in transcription

Sigma factors are the predominant factors involved in transcription regulation in bacteria. These factors can recruit the core RNA polymerase to promoters with specific DNA sequences and initiate gene transcription. The plastids of higher plants originating from an ancestral cyanobacterial endosymbiont also contain sigma factors that are encoded by a small family of nuclear genes. Although all plastid sigma factors contain sequences conserved in bacterial sigma factors, a considerable number of distinct traits have been acquired during evolution. The present review summarises recent advances concerning the regulation of the structure, function and activity of plastid sigma factors since their discovery nearly 40 years ago. We highlight the specialised roles and overlapping redundant functions of plastid sigma factors according to their promoter selectivity. We also focus on the mechanisms that modulate the activity of sigma factors to optimise plastid function in response to developmental cues and environmental signals. This article is part of a Special Issue entitled: Chloroplast Biogenesis.

Nucleus-encoded plastid sigma factor SIG3 transcribes specifically the psbN gene in plastids

We have investigated the function of one of the six plastid sigma-like transcription factors, sigma 3 (SIG3), by analysing two different Arabidopsis T-DNA insertion lines having disrupted SIG3 genes. Hybridization of wild-type and sig3 plant RNA to a plastid specific microarray revealed a strong reduction of the plastid psbN mRNA. The microarray result has been confirmed by northern blot analysis. The SIG3-specific promoter region has been localized on the DNA by primer extension and mRNA capping experiments. Results suggest tight regulation of psbN gene expression by a SIG3-PEP holoenzyme. The psbN gene is localized on the opposite strand of the psbB operon, between the psbT and psbH genes, and the SIG3-dependent psbN transcription produces antisense RNA to the psbT-psbH intergenic region. We show that this antisense RNA is not limited to the intergenic region, i.e. it does not terminate at the end of the psbN gene but extends as antisense transcript to cover the whole psbT coding region. Thus, by specific transcription initiation at the psbN gene promoter, SIG3-PEP holoenzyme could also influence the expression of the psbB operon by producing psbT antisense RNA.

Building up of the plastid transcriptional machinery during germination and early plant development

The plastid genome is transcribed by three different RNA polymerases, one is called plastid-encoded RNA polymerase (PEP) and two are called nucleus-encoded RNA polymerases (NEPs). PEP transcribes preferentially photosynthesis-related genes in mature chloroplasts while NEP transcribes preferentially housekeeping genes during early phases of plant development, and it was generally thought that during plastid differentiation the building up of the NEP transcription system precedes the building up of the PEP transcription system. We have now analyzed in detail the establishment of the two different transcription systems, NEP and PEP, during germination and early seedling development on the mRNA and protein level. Experiments have been performed with two different plant species, Arabidopsis (Arabidopsis thaliana) and spinach (Spinacia oleracea). Results show that the building up of the two different transcription systems is different in the two species. However, in both species NEP as well as PEP are already present in seeds, and results using Tagetin as a specific inhibitor of PEP activity demonstrate that PEP is important for efficient germination, i.e. PEP is already active in not yet photosynthetically active seed plastids.

Plastid RNA polymerases, promoters, and transcription regulators in higher plants

Plastids are semiautonomous plant organelles exhibiting their own transcription-translation systems that originated from a cyanobacteria-related endosymbiotic prokaryote. As a consequence of massive gene transfer to nuclei and gene disappearance during evolution, the extant plastid genome is a small circular DNA encoding only ca. 120 genes (less than 5% of cyanobacterial genes). Therefore, it was assumed that plastids have a simple transcription-regulatory system. Later, however, it was revealed that plastid transcription is a multistep gene regulation system and plays a crucial role in developmental and environmental regulation of plastid gene expression. Recent molecular and genetic approaches have identified several new players involved in transcriptional regulation in plastids, such as multiple RNA polymerases, plastid sigma factors, transcription regulators, nucleoid proteins, and various signaling factors. They have provided novel insights into the molecular basis of plastid transcription in higher plants. This review summarizes state-of-the-art knowledge of molecular mechanisms that regulate plastid transcription in higher plants.

The role of sigma factors in plastid transcription

Expression of plastid genes is controlled at both transcriptional and post-transcriptional levels in response to developmental and environmental signals. In many cases this regulation is mediated by nuclear-encoded proteins acting in concert with the endogenous plastid gene expression machinery. Transcription in plastids is accomplished by two distinct RNA polymerase enzymes, one of which resembles eubacterial RNA polymerases in both subunit structure and promoter recognition properties. The holoenzyme contains a catalytic core composed of plastid-encoded subunits, assembled with a nuclear-encoded promoter-specificity factor, sigma. Based on examples of transcriptional regulation in bacteria, it is proposed that differential activation of sigma factors may provide the nucleus with a mechanism to control expression of groups of plastid genes. Hence, much effort has focused on identifying and characterizing sigma-like factors in plants. While fractionation studies had identified several candidate sigma factors in purified RNA polymerase preparations, it was only 4 years ago that the first sigma factor genes were cloned from two photosynthetic eukaryotes, both of which were red algae. More recently this achievement has extended to the identification of families of sigma-like factor genes from several species of vascular plants. Now, efforts in the field are directed at understanding the roles in plastid transcription of each member of the rapidly expanding plant sigma factor gene family. Recent results suggest that accumulation of individual sigma-like factors is controlled by light, by plastid type and/or by a particular stage of chloroplast development. These data mesh nicely with accumulating evidence that the core sigma-binding regions of plastid promoters mediate regulated transcription in response to light-regime and plastid type or developmental state. In this review I will outline progress made to date in identifying and characterizing the sigma-like factors of plants, and in dissecting their potential roles in chloroplast gene expression.

Evolutionary conservation of C-terminal domains of primary sigma(70)-type transcription factors between plants and bacteria

Three different cDNAs coding for putative plant plastid sigma(70)-type transcription initiation factors have recently been cloned and sequenced from Arabidopsis thaliana. We have analyzed the evolutionary conservation of function(s) of the N-terminal and C-terminal halves of these three sigma factors by in vitro transcription studies using heterologous transcription systems and by complementation assays using Escherichia coli thermosensitive rpoD mutants. Our results indicate differences and similarities of the three plant factors and their prokaryotic ancestors. The functions of the N-terminal parts of the plant sigma factors are considerably different from the function of the N-terminal part of the principal sigma(70) factor of E. coli. On the other hand, the C-terminal parts have kept at least two characteristics when compared with their prokaryotic ancestors: 1) they can distinguish between different promoter structures, and 2) one of them is capable of fully complementing E. coli rpoD mutants, i.e. recognizing all essential E. coli promoters that are used by the E. coli principal sigma(70) factor. This shows for the first time in vivo a strong evolutionary conservation of cis- and trans-acting elements between the prokaryotic and the plant plastid transcriptional machinery.

Targeted disruption of the plastid RNA polymerase genes rpoA, B and C1: molecular biology, biochemistry and ultrastructure

The plastid encoded RNA polymerase subunit genes rpoA, B and C1 of tobacco were disrupted individually by PEG-mediated plastid transformation. The resulting off-white mutant phenotype is identical for inactivation of the different genes. The mutants pass through a normal ontogenetic cycle including flower formation and production of fertile seeds. Their plastids reveal a poorly developed internal membrane system consisting of large vesicles and, occasionally, flattened membranes, reminiscent of stacked thylakoids. The rpo- material is capable of synthesising pigments and lipids, similar in composition but at lower amounts than the wild-type. Western analysis demonstrates that plastids contain nuclear-coded stroma and thylakoid polypeptides including terminally processed lumenal components of the Sec but not of the DeltapH thylakoid translocation machineries. Components using the latter route accumulate as intermediates. In striking contrast, polypeptides involved in photosynthesis encoded by plastid genes could not be detected by Western analysis, although transcription of plastid genes, including the rrn operon, by the plastid RNA polymerase of nuclear origin is found as expected. Remarkably, ultrastructural, sedimentation and Northern analyses as well as pulse experiments suggest that rpo- plastids contain functional ribosomes. The detection of the plastid-encoded ribosomal protein Rpl2 is consistent with these results. The findings demonstrate that the consequences of rpo gene disruption, and implicitly the integration of the two plastid polymerase types into the entire cellular context, are considerably more complex than presently assumed.

Organellar RNA polymerases of higher plants

The nuclear genome of the model plant Arabidopsis thaliana contains a small gene family consisting of three genes encoding RNA polymerases of the single-subunit bacteriophage type. There is evidence that similar gene families also exist in other plants. Two of these RNA polymerases are putative mitochondrial enzymes, whereas the third one may represent the nuclear-encoded RNA polymerase (NEP) active in plastids. In addition, plastid genes are transcribed from another, entirely different multisubunit eubacterial-type RNA polymerase, the core subunits of which are encoded by plastid genes [plastid-encoded RNA polymerase (PEP)]. This core enzyme is complemented by one of several nuclear-encoded sigma-like factors. The development of photosynthetically active chloroplasts requires both PEP and NEP. Most NEP promoters show certain similarities to mitochondrial promoters in that they include the sequence motif 5'-YRTA-3' near the transcription initiation site. PEP promoters are similar to bacterial promoters of the -10/-35 sigma 70 type.

Tissue-specific and light-dependent expression within a family of nuclear-encoded sigma-like factors from Zea mays

The principal transcription machinery functioning in chloroplasts of higher plants is encoded in two subcellular compartments. Subunits of the RNA polymerase catalytic core are plastid encoded, while sigma factors required for promoter recognition are encoded in the nucleus. We have isolated nuclear-encoded cDNAs, sig1, sig2, and sig3, specifying three sigma factors from maize (Zea mays). The three deduced polypeptides have extensive sequence identity with the principal sigma factors of eubacteria. Two of the maize cDNAs, sig1 and sig3, encode NH2-terminal transit peptides which direct the uptake of a heterologous protein into chloroplasts in vitro. Transcripts for the sig3 gene were more abundant in green leaves than in roots and in light-treated seedlings than in dark-grown seedlings. In contrast, sig1 transcripts were readily detectable in all tissues examined. Thus, at least two promoter-selectivity factors function with the maize chloroplast RNA polymerase, one of which is constitutively expressed and the other is light activated.

NUCLEAR CONTROL OF PLASTID AND MITOCHONDRIAL DEVELOPMENT IN HIGHER PLANTS

The nucleus must coordinate organelle biogenesis and function on a cell and tissue-specific basis throughout plant development. The vast majority of plastid and mitochondrial proteins and components involved in organelle biogenesis are encoded by nuclear genes. Molecular characterization of nuclear mutants has illuminated chloroplast development and function. Fewer mutants exist that affect mitochondria, but molecular and biochemical approaches have contributed to a greater understanding of this organelle. Similarities between organelles and prokaryotic regulatory molecules have been found, supporting the prokaryotic origin of chloroplasts and mitochondria. A striking characteristic for both mitochondria and chloroplast is that most regulation is posttranscriptional.

Two types of differentially photo-regulated nuclear genes that encode sigma factors for chloroplast RNA polymerase in the red alga Cyanidium caldarium strain RK-1

A nuclear gene, sigA, that encodes a sigma factor for chloroplast RNA polymerase has previously been identified and characterized in the primitive red alga Cyanidium caldarium strain RK-1. Southern hybridization analysis indicated the presence of two additional sigma factor genes, which have now been cloned and shown to encode virtually identical proteins that are homologous to eubacterial sigma factors. These genes, which are also present in the nuclear genome, have therefore been named sigB and sigC. The substantial sequence similarity of sigB and sigC to sigA of the same strain as well as to cyanobacterial principal sigma factors and other chloroplast sigma factors strongly suggests that the nuclear genome of C. caldarium contains three genes that encode two types of chloroplast sigma factors. Each of the three recombinant Sig proteins showed sigma factor activity in vitro when combined with the Escherichia coli RNA polymerase core enzyme. Northern blot analysis revealed that, whereas the overall abundance of sigA transcripts was not affected by light, the amount of sigB and sigC mRNAs was greater in the light than in the dark. Thus, multiple sigma factors appear to contribute to light-regulated gene expression in the chloroplast.

The nuclear RPL4 gene encodes a chloroplast protein that co-purifies with the T7-like transcription complex as well as plastid ribosomes

We have cloned and sequenced the cDNA and the gene coding for plastid ribosomal protein L4 (RPL4) from two higher plant species, spinach and Arabidopsis thaliana. Ribosomal protein L4 is one of the ribosomal proteins for which extraribosomal functions in transcriptional regulation has been demonstrated in prokaryotes. Sequence comparison of the two plant cDNAs and genes shows that the RPL4 gene has acquired a remarkable 3' extension during evolutionary transfer to the nuclear genome. This extension harbors an intron and codes for a glutamic and aspartic acid-rich amino acid sequence that resembles highly acidic C-terminal tails of some transcription factors. Co-purification of ribosomal protein L4 with plastid RNA polymerase and transcription factor CDF2 using different purification protocols as well as the surprising amino acid sequence of the L4 protein make it a likely candidate to play a role in plastid transcriptional regulation.

Leaf-specifically expressed genes for polypeptides destined for chloroplasts with domains of sigma70 factors of bacterial RNA polymerases in Arabidopsis thaliana

Genes for sigma-like factors of bacterial-type RNA polymerase have not been characterized from any multicellular eukaryotes, although they probably play a crucial role in the expression of plastid photosynthesis genes. We have cloned three distinct cDNAs, designated SIG1, SIG2, and SIG3, for polypeptides possessing amino acid sequences for domains conserved in sigma70 factors of bacterial RNA polymerases from the higher plant Arabidopsis thaliana. Each gene is present as one copy per haploid genome without any additional sequences hybridized in the genome. Transient expression assays using green fluorescent protein demonstrated that N-terminal regions of the SIG2 and SIG3 ORFs could function as transit peptides for import into chloroplasts. Transcripts for all three SIG genes were detected in leaves but not in roots, and were induced in leaves of dark-adapted plants in rapid response to light illumination. Together with results of our previous analysis of tissue-specific regulation of transcription of plastid photosynthesis genes, these results indicate that expressed levels of the genes may influence transcription by regulating RNA polymerase activity in a green tissue-specific manner.

Coordination of nuclear and chloroplast gene expression in plant cells

Plastid proteins are encoded in two genomes, one in the nucleus and the other in the organelle. The expression of genes in these two compartments in coordinated during development and in response to environmental parameters such as light. Two converging approaches reveal features of this coordination: the biochemical analysis of proteins involved in gene expression, and the genetic analysis of mutants affected in plastid function or development. Because the majority of proteins implicated in plastid gene expression are encoded in the nucleus, regulatory processes in the nucleus and in the cytoplasm control plastid gene expression, in particular during development. Many nucleus-encoded factors involved in transcriptional and posttranscriptional steps of plastid gene expression have been characterized. We are also beginning to understand whether and how certain developmental or environmental signals perceived in one compartment may be transduced to the other.

Organ-specific transcription of the rrn operon in spinach plastids

The spinach rrn operon is used as a model system to study transcriptional regulation in higher plant photosynthetic and non-photosynthetic plastids. We performed capping experiments to determine whether P1, PC, or P2 promoters are employed for rrn transcription start sites in cotyledon and root tissues. By using a new method of analysis of capped RNA we demonstrate for the first time that 1) in both organs the rrn operon is expressed in a constitutive manner by cotranscription with the preceding tRNA(GAC)Val gene, and 2) the PC transcription start site is used only in cotyledons and leaves, i.e. we demonstrate the organ-specific usage of a plastid promoter. Both start sites, PC and that of the tRNA(GAC)Val cotranscript, lack Escherichia coli-like consensus sequences. The cotranscript is initiated 457 base pairs upstream of the tRNA(GAC)Val gene. The PC-specific DNA-binding factor, CDF2, is not detectable in root tissues confirming its regulatory role in PC-initiated rrn expression and the organ specificity of PC expression. Furthermore, our results show that rrn operon expression patterns differ in spinach and tobacco indicating species-specific transcriptional regulation of plant plastid gene expression.

Regulation of gene expression in chloroplasts of higher plants

Chloroplasts contain their own genetic system which has a number of prokaryotic as well as some eukaryotic features. Most chloroplast genes of higher plants are organized in clusters and are cotranscribed as polycistronic pre-RNAs which are generally processes into many shorter overlapping RNA species, each of which accumulates of steady-state RNA levels. This indicates that posttranscriptional RNA processing of primary transcripts is an important step in the control of chloroplast gene expression. Chloroplast RNA processing steps include RNA cleavage/trimming, RNA splicing, ENA editing and RNA stabilization. Several chloroplast genes are interrupted by introns and therefore require processing for gene function. In tobacco chloroplasts, 18 genes contain introns, six for tRNA genes and 12 for protein-encoding genes. A number of specific proteins and RNA factors are believed to be involved in splicing and maturation of pre-RNAs in chloroplasts. Processing enzymes and RNA-binding proteins which could be involved in posttranscriptional steps have been identified in the last several years. Our current knowledge of the regulation of gene expression in chloroplasts of higher plants is overviewed and further studies on this matter are also considered.

Nuclear encoding of a chloroplast RNA polymerase sigma subunit in a red alga

A chloroplast RNA polymerase sigma factor is encoded by a nuclear gene, sigA, in the red alga Cyanidium caldarium RK-1. The encoded protein functions as an RNA polymerase sigma factor in vitro and it is localized to the chloroplast in vivo. SigA shows high sequence similarity to the sigma factors of cyanobacteria, which is indicative of the ancestral endosymbiotic event and subsequent transfer of the sigA gene to the nuclear genome.

Mitochondrial transcription initiation: promoter structures and RNA polymerases

A diversity of promoter structures. It is evident that tremendous diversity exists between the modes of mitochondrial transcription initiation in the different eukaryotic kingdoms, at least in terms of promoter structures. Within vertebrates, a single promoter for each strand exists, which may be unidirectional or bidirectional. In fungi and plants, multiple promoters are found, and in each case, both the extent and the primary sequences of promoters are distinct. Promoter multiplicity in fungi, plants and trypanosomes reflects the larger genome size and scattering of genes relative to animals. However, the dual roles of certain promoters in transcription and replication, at least in yeast, raises the interesting question of how the relative amounts of RNA versus DNA synthesis are regulated, possibly via cis-elements downstream from the promoters. Mitochondrial RNA polymerases. With respect to mitochondrial RNA polymerases, characterization of human, mouse, Xenopus and yeast enzymes suggests a marked degree of conservation in their behavior and protein composition. In general, these systems consist of a relatively non-selective core enzyme, which itself is unable to recognize promoters, and at least one dissociable specificity factor, which confers selectivity to the core subunit. In most of these systems, components of the RNA polymerase have been shown to induce a conformational change in their respective promoters and have also been assigned the role of a primase in the replication of mtDNA. While studies of the yeast RNA polymerase have suggested it has both eubacterial (mtTFB) and bacteriophage (RPO41) origins, it is not yet clear whether these characteristics will be conserved in the mitochondrial RNA polymerases of all eukaryotes. mtTFA-mtTFB; conserved but dissimilar functions. With respect to transcription factors, mtTFA has been found in both vertebrates and yeast, and may be a ubiquitous protein in mitochondria. However, the divergence in non-HMG portions of the proteins, combined with differences in promoter structure, has apparently relegated mtTFA to alternative, or at least non-identical, physiological roles in vertebrates and fungi. The relative ease with which mtTFA can be purified (Fisher et al. 1991) suggests that, where present, it should be facile to detect. mtTFB may represent a eubacterial sigma factor adapted for interaction with the mitochondrial RNA polymerase.(ABSTRACT TRUNCATED AT 400 WORDS)

The chloroplast genome

The chloroplast genome consists of homogeneous circular DNA molecules. To date, the entire nucleotide sequences (120-190 kbp) of chloroplast genomes have been determined from eight plant species. The chloroplast genomes of land plants and green algae contain about 110 different genes, which can be classified into two main groups: genes involved in gene expression and those related to photosynthesis. The red alga Porphyra chloroplast genome has 70 additional genes, one-third of which are related to biosynthesis of amino acids and other low molecular mass compounds. Chloroplast genes contain at least three structurally distinct promoters and transcribe two or more classes of RNA polymerase. Two chloroplast genes, rps12 of land plants and psaA of Chlamydomonas, are divided into two to three pieces and scattered over the genome. Each portion is transcribed separately, and two to three separate transcripts are joined together to yield a functional mRNA by trans-splicing. RNA editing (C to U base changes) occurs in some of the chloroplast transcripts. Most edited codons are functionally significant, creating start and stop codons and changing codons to retain conserved amino acids.

Regulation of rDNA transcription in chloroplasts: promoter exclusion by constitutive repression

Spinach chloroplasts contain two types of RNA polymerases. One is multimeric and Escherichia coli-like. The other one is not E. coli-like and might represent a monomeric enzyme of 110 kD. The quantitative relation of the two polymerases changes during plant development. This raises the question, how are plastid genes transcribed that contain E. coli-like and non-E. coli-like promoter elements during developmental phases when both enzymes are present? Transcription of the spinach plastid rrn operon promoter is initiated at three sites: P1, PC, and P2. P1 and P2 are preceded by E. coli-like promoter elements that are recognized by E. coli RNA polymerase in vitro. However, in vivo, transcription starts exclusively at PC. We analyzed different promoter constructions using in vitro transcription and gel mobility-shift studies to understand why P1 and P2 are not used in vivo. Our results suggest that the sequence-specific DNA-binding factor CDF2 functions as a repressor for transcription initiation of the E. coli-like enzyme at P1 and P2. We propose a mechanism of constitutive repression to keep the rrn operon in all developmental phases under the transcriptional control of the non-E. coli-like RNA polymerase.

Separation of two classes of plastid DNA-dependent RNA polymerases that are differentially expressed in mustard (Sinapis alba L.) seedlings

Chloroplast and etioplast in vitro transcription systems from mustard have different functional properties, which is reflected in differences in phosphorylation status. Here we report another transcription control mechanism, which involves two plastid DNA-dependent RNA polymerases designated as peak A and peak B enzymes. Both are large multi-subunit complexes, but differ in their native molecular mass (> 700 kDa for peak A and ca. 420 kDa for peak B) and in their polypeptide composition. The A enzyme is composed of at least 13 polypeptides, while the B enzyme contains only four putative subunits. Peak B activity is inhibited by rifampicin, whereas that of peak A is resistant. RNA polymerase activity was compared for plastids from cotyledons of 4-day-old seedlings that were grown either under continuous light (chloroplasts) or in darkness (etioplasts), or were first dark-grown and then transferred to light for 16 h ('intermediate-type' plastids). While the total activity was approximately the same in all three cases, enzyme B was the predominant activity obtained from etioplasts and enzyme A that obtained from chloroplasts. Both had equal activity in preparations from the 'intermediate-type' plastid form. Both activation/inactivation and differential gene expression seem to play a role in the regulation of the plastid transcription machinery.

Sigma-like transcription factors from mustard (Sinapis alba L.) etioplast are similar in size to, but functionally distinct from, their chloroplast counterparts

Three proteins resembling bacterial sigma factors were previously isolated from mustard chloroplasts (K. Tiller, A. Eisermann and G. Link, Eur J Biochem 198: 93-99, 1991). These sigma-like factors (SLFs) confer DNA-binding and transcription specificity to a system consisting of Escherichia coli core RNA polymerase and cloned DNA regions that carry a chloroplast promoter. Sigma-like activity was now isolated also from etioplasts and could be assigned to three polypeptides of M(r) 67,000 (SLF67), 52,000 (SLF52) and 29,000 (SLF29), i.e. the same sizes as for the chloroplast SLFs. The purification scheme for the factors from either plastid type included an initial heparin-Sepharose and a final gel filtration step. For the etioplast factors, however, an additional phosphocellulose step was required to release these polypeptides from the RNA polymerase. The etioplast SLFs have similar, but not identical, salt requirements for DNA binding as compared to their chloroplast counterparts. Under conditions of maximum binding activity there is overall preference of etioplast SLFs for the psbA promoter over the trnQ and rps16 promoters.

Expression of the Chlamydomonas reinhardtii chloroplast tRNA(Glu) gene in a homologous in vitro transcription system is independent of upstream promoter elements

Chloroplast tRNA(Glu) is a bifunctional molecule involved in both the early steps of chlorophyll synthesis and chloroplast protein biosynthesis. Recently the enzymes involved in these processes have been characterized from the green alga Chlamydomonas reinhardtii. In order to investigate whether transcription of the gene for the tRNA(Glu) cofactor would be a possible point of regulation for the biosynthesis of chlorophyll, a homologous in vitro transcription system for C. reinhardtii chloroplast RNA polymerase was developed. The enzymatic activity was partially purified by ion-exchange chromatography to separate it from nuclear RNA polymerases. The highest rate of synthesis was found at pH 7.9, 40 mM KCl, 9 mM MgCl2 and with 25 micrograms plasmid DNA containing the chloroplast tRNA gene per milliliter. The activity was not sensitive to high amounts of alpha-amanitin (500 micrograms/ml) and rifampicin, but was clearly inhibited by heparin. This system was used to undertake a promoter analysis of one of the two identical tRNA(Glu) gene copies found in the C. reinhardtii chloroplast genome (trnE1). The analyzed tRNA gene behaved like a single transcription unit driven by its own promoter. The transcript terminated in a run of four consecutive T residues downstream of the gene. The nucleotide sequence in the 5' region of the gene revealed several potential promoter elements with homology to known chloroplast promoters of the "-10 and -35 region" and the "Euglena promoter" types. Surprisingly, deletion of the complete 5' region did not affect in vitro transcription, while partial deletions of the 5' and 3' coding region totally abolished transcription. This indicates the presence of an internal control region previously found for genes transcribed by nuclear RNA polymerase III. Protein binding studies with the coding region of trnE1 using gel retardation assays demonstrated the formation of two differently sized complexes. In vitro transcription of the tRNA(Glu) gene in extracts prepared from light and dark grown algae failed to demonstrate any significant influence of light on the transcription reaction.

Purification of the DNA-dependent RNA polymerase from the myxobacterium Stigmatella aurantiaca

The DNA-dependent RNA polymerase (EC 2.7.7.6) of the myxobacterium Stigmatella aurantiaca has been purified. It shows three main polypeptide bands with apparent molecular weights of 146,000, 105,000, and 40,000 in sodium dodecyl sulfate-polyacrylamide gel electrophoresis. beta and beta' subunits of the S. aurantiaca polymerase were shown to migrate in the 146,000-molecular-weight polypeptide band and the main sigma factor was shown to migrate in the 105,000-molecular-weight band by using heterologous antisera.

The chloroplast transcription apparatus from mustard (Sinapis alba L.). Evidence for three different transcription factors which resemble bacterial sigma factors

A chloroplast protein fraction with sigma-like activity [Bülow, S. & Link, G. (1988) Plant Mol. Biol. 10, 349-357], was further purified and characterized. Chromatography on heparin-Sepharose, DEAE-Sepharose and Sephacryl S-300 led to the separation of three sigma-like factors (SLF) polypeptides with Mr 67,000 (SLF67), 52,000 (SLF52) and 29,000 (SLF29). None of these polypeptides bind to DNA itself, but each one confers enhanced binding and transcriptional activity when added to Escherichia coli RNA-polymerase core enzyme and DNA fragments carrying a chloroplast promoter. SLF67, SLF52, and SLF29 differ in their ionic-strength requirements for activity. They each mediate the binding to promoters of the chloroplast genes psbA, trnQ, and rps16, with different efficiencies. It is suggested that chloroplast transcription in vivo might be controlled at least in part by these functionally distinct factors.

Highly purified pea chloroplast RNA polymerase transcribes both rRNA and mRNA genes

Pea chloroplast RNA polymerase has been obtained with about 2000-fold purification using DEAE-cellulose and phosphocellulose chromatography. The purified enzyme contained ten prominent polypeptides of 150, 130, 115, 110, 95, 85, 75, 48, 44 and 39 kDa and four other minor polypeptides of 90, 34, 32 and 27 kDa. Purification of this enzyme using chloroplast 16S rDNA promoter affinity column chromatography also yielded an enzyme with similar polypeptides. Purified polyclonal antibodies against the purified chloroplast RNA polymerase were found to recognize most of the polypeptides of the enzyme in Western blot experiments. Primary mobility shift of the 16S rRNA gene and ribulose-1,5-bisphosphate carboxylase large subunit (rbc-L) gene promoters observed with the chloroplast RNA polymerase was abolished by these antibodies. The specific in vitro transcription of these rRNA and mRNA genes was also inhibited by these antibodies. The transcription of the rRNA and mRNA genes was also abolished by tagetitoxin, a specific inhibitor of chloroplast RNA polymerase. The chloroplast RNA polymerase was found to bind specifically to the chloroplast 16S rRNA gene promoter region as visualized in electron microscopy. The presence of the polypeptides of 130, 110, 75-95 and 48 kDa in the DNA-enzyme complex was confirmed by a novel approach using immunogold labeling with the respective antibodies. The polypeptides of this purified RNA polymerase were found to be localized in chloroplasts by an indirect immunofluorescence.

The plastid rpoA gene encoding a protein homologous to the bacterial RNA polymerase alpha subunit is expressed in pea chloroplasts

The gene rpoA, encoding a protein homologous to the alpha subunit of RNA polymerase from Escherichia coli has been located in pea chloroplast DNA downstream of the petD gene for subunit IV of the cytochrome b-f complex. Nucleotide sequence analysis has revealed that rpoA encodes a polypeptide of 334 amino acid residues with a molecular weight of 38916. Northern blot analysis has shown that rpoA is co-transcribed with the gene for ribosomal protein S11. A lacZ-rpoA gene-fusion has been constructed and expressed in E. coli. Antibodies raised against the fusion protein have been employed to demonstrate the synthesis of the rpoA gene product in isolated pea chloroplasts. Western blot analysis using these antibodies and antibodies against the RNA polymerase core enzyme from the cyanobacterium, Anabaena 7120, has revealed the presence of the gene product in a crude RNA polymerase preparation from pea chloroplasts.

Transcriptional interaction between the promoters of the maize chloroplast genes which encode the beta subunit of ATP synthase and the large subunit of ribulose 1,5-bisphosphate carboxylase

The genes encoding the beta subunit of ATP synthase and the large subunit of ribulose 1,5-bisphosphate carboxylase are located on opposite strands of the maize chloroplast genome. Their transcription start sites are separated by a 159 bp sequence that includes the promoters for both genes. The effects of deleting or modifying one of the two promoters on transcription from the adjacent, unaltered promoter were assessed in vitro using maize chloroplast extracts to transcribe cloned maize DNA templates. When the atpB promoter was disrupted by an 8 bp insertion, rbcL transcription was not altered. When the rbcL promoter was disrupted by a 2 bp insertion, atpB transcription decreased, whereas when the rbcL promoter region was deleted, atpB transcription increased. Activity of the atpB promoter was also reduced when the + 2 bp-rbcL promoter template was transcribed in vitro by Escherichia coli RNA polymerase. The changes in atpB transcriptional efficiency were only seen when the atpB and rbcL promoters were closely spaced on the same template molecule. These results established that the atpB and rbcL promoters interact in vitro in a cis and spacing dependent manner. The interaction may have physiological relevance in vivo.