Pea chloroplast DNA primase: characterization and role in initiation of replication

Plant Organelle Genome Replication

Mitochondria and chloroplasts perform essential functions in respiration, ATP production, and photosynthesis, and both organelles contain genomes that encode only some of the proteins that are required for these functions. The proteins and mechanisms for organelle DNA replication are very similar to bacterial or phage systems. The minimal replisome may consist of DNA polymerase, a primase/helicase, and a single-stranded DNA binding protein (SSB), similar to that found in bacteriophage T7. In Arabidopsis, there are two genes for organellar DNA polymerases and multiple potential genes for SSB, but there is only one known primase/helicase protein to date. Genome copy number varies widely between type and age of plant tissues. Replication mechanisms are only poorly understood at present, and may involve multiple processes, including recombination-dependent replication (RDR) in plant mitochondria and perhaps also in chloroplasts. There are still important questions remaining as to how the genomes are maintained in new organelles, and how genome copy number is determined. This review summarizes our current understanding of these processes.

The Dictyostelium discoideum homologue of Twinkle, Twm1, is a mitochondrial DNA helicase, an active primase and promotes mitochondrial DNA replication

BACKGROUND

DNA replication requires contributions from various proteins, such as DNA helicases; in mitochondria Twinkle is important for maintaining and replicating mitochondrial DNA. Twinkle helicases are predicted to also possess primase activity, as has been shown in plants; however this activity appears to have been lost in metazoans. Given this, the study of Twinkle in other organisms is required to better understand the evolution of this family and the roles it performs within mitochondria.

RESULTS

Here we describe the characterization of a Twinkle homologue, Twm1, in the amoeba Dictyostelium discoideum, a model organism for mitochondrial genetics and disease. We show that Twm1 is important for mitochondrial function as it maintains mitochondrial DNA copy number in vivo. Twm1 is a helicase which unwinds DNA resembling open forks, although it can act upon substrates with a single 3' overhang, albeit less efficiently. Furthermore, unlike human Twinkle, Twm1 has primase activity in vitro. Finally, using a novel in bacterio approach, we demonstrated that Twm1 promotes DNA replication.

CONCLUSIONS

We conclude that Twm1 is a replicative mitochondrial DNA helicase which is capable of priming DNA for replication. Our results also suggest that non-metazoan Twinkle could function in the initiation of mitochondrial DNA replication. While further work is required, this study has illuminated several alternative processes of mitochondrial DNA maintenance which might also be performed by the Twinkle family of helicases.

The Arabidopsis At1g30680 gene encodes a homologue to the phage T7 gp4 protein that has both DNA primase and DNA helicase activities

BACKGROUND

The Arabidopsis thaliana genome encodes a homologue of the full-length bacteriophage T7 gp4 protein, which is also homologous to the eukaryotic Twinkle protein. While the phage protein has both DNA primase and DNA helicase activities, in animal cells Twinkle is localized to mitochondria and has only DNA helicase activity due to sequence changes in the DNA primase domain. However, Arabidopsis and other plant Twinkle homologues retain sequence homology for both functional domains of the phage protein. The Arabidopsis Twinkle homologue has been shown by others to be dual targeted to mitochondria and chloroplasts.

RESULTS

To determine the functional activity of the Arabidopsis protein we obtained the gene for the full-length Arabidopsis protein and expressed it in bacteria. The purified protein was shown to have both DNA primase and DNA helicase activities. Western blot and qRT-PCR analysis indicated that the Arabidopsis gene is expressed most abundantly in young leaves and shoot apex tissue, as expected if this protein plays a role in organelle DNA replication. This expression is closely correlated with the expression of organelle-localized DNA polymerase in the same tissues. Homologues from other plant species show close similarity by phylogenetic analysis.

CONCLUSIONS

The results presented here indicate that the Arabidopsis phage T7 gp4/Twinkle homologue has both DNA primase and DNA helicase activities and may provide these functions for organelle DNA replication.

Biochemical properties of a plastidial DNA polymerase of rice

Plastids are organelles unique to plant cells and are responsible for photosynthesis and other metabolic functions. Despite their important cellular roles, relatively little is known about the mechanism of plastidial DNA replication and repair. Recently, we identified a novel DNA polymerase in Oryza Sativa L. (OsPOLP1, formerly termed OsPolI-like) that is homologous to prokaryotic DNA polymerase Is (PolIs), and suggested that this polymerase might be involved in plastidial DNA replication and repair. Here, we propose to rename the plant PolI homologs as DNA polymerase pi (POLP), and investigate the biochemical properties of full-length OsPOLP1. The purified OsPOLP1 elongated both DNA and RNA primer hybridized to a DNA template, and possessed a 3' exonuclease activity. Moreover, OsPOLP1 displayed high processivity and fidelity, indicating that this polymerase has the biochemical characteristics appropriate for DNA replication. We found that POLPs have two extra sequences in the polymerase domain that are absent in prokaryotic PolIs. Deletion of either insert from OsPOLP1 caused a decrease in DNA synthetic activity, processivity, and DNA binding activity. In addition, OsPOLP1 efficiently catalyzed strand displacement on nicked DNA with a 5'-deoxyribose phosphate, suggesting that this enzyme might be involved in a repair pathway similar to long-patch base excision repair. These results provide insights into the possible role of POLPs in plastidial DNA replication and repair.

Multiple functions of DNA polymerases

The primary role of DNA polymerases is to accurately and efficiently replicate the genome in order to ensure the maintenance of the genetic information and its faithful transmission through generations. This is not a simple task considering the size of the genome and its constant exposure to endogenous and environmental DNA damaging agents. Thus, a number of DNA repair pathways operate in cells to protect the integrity of the genome. In addition to their role in replication, DNA polymerases play a central role in most of these pathways. Given the multitude and the complexity of DNA transactions that depend on DNA polymerase activity, it is not surprising that cells in all organisms contain multiple highly specialized DNA polymerases, the majority of which have only recently been discovered. Five DNA polymerases are now recognized in Escherichia coli, 8 in Saccharomyces cerevisiae, and at least 15 in humans. While polymerases in bacteria, yeast and mammalian cells have been extensively studied much less is known about their counterparts in plants. For example, the plant model organism Arabidopsis thaliana is thought to contain 12 DNA polymerases, whose functions are mostly unknown. Here we review the properties and functions of DNA polymerases focusing on yeast and mammalian cells but paying special attention to the plant enzymes and the special circumstances of replication and repair in plant cells.

Organization, Developmental Dynamics, and Evolution of Plastid Nucleoids

The plastid is a semiautonomous organelle essential in photosynthesis and other metabolic activities of plants and algae. Plastid DNA is organized into the nucleoid with various proteins and RNA, and the nucleoid is subject to dynamic changes during the development of plant cells. Characterization of the major DNA-binding proteins of nucleoids revealed essential differences in the two lineages of photosynthetic eukaryotes, namely nucleoids of green plants contain sulfite reductase as a major DNA-binding protein that represses the genomic activity, whereas the prokaryotic DNA-binding protein HU is abundant in plastid nucleoids of the rhodophyte lineage. In addition, current knowledge on DNA-binding proteins, as well as the replication and transcription systems of plastids, is reviewed from comparative and evolutionary points of view. A revised hypothesis on the discontinuous evolution of plastid genomic machinery is presented: despite the cyanobacterial origin of plastids, the genomic machinery of the plastid genome is fundamentally different from its counterpart in cyanobacteria.

Temporal and spatial coordination of cells with their plastid component

Careful coordination of cell multiplication with plastid multiplication and partition at cytokinesis is required to maintain the universal presence of plastids in the major photosynthetic lines of evolution. However, no cell cycle control points are known that might underlie this coordination. We review common properties, and their variants, of plastids and plastid DNA in germline, multiplying, and mature cells of phyla capable of photosynthesis. These suggest a basic level of control dictated perhaps by the same mechanisms that coordinate cell size with the nuclear ploidy level. No protein synthesis within the plastid appears to be necessary for this system to operate successfully at the level that maintains the presence of plastids in cells. A second, and superimposed, level of controls dictates expansion of the plastid in both size and number in response to signals associated with differentiation and with the environment. We also compare the germane properties of plastids with those of mitochondria. With the advent of genomics and new cell and molecular techniques, the players in these control mechanisms should now be identifiable.

The functional role of a DNA primase in chloroplast DNA replication in Chlamydomonas reinhardtii

A complementation experiment was developed to identify the protein component that is essential for the in vitro replication of a cloned template containing a chloroplast DNA replication origin of Chlamydomonas reinhardtii. Using this method, we have identified a DNA primase activity that copurified with DNA polymerase from the crude protein mixture. The primase catalyzed the synthesis of short RNA primers on single-stranded DNA templates. Among the synthetic templates, the order of preference was poly(dA), poly(dT), and poly(dC). The primer size range for these templates was 11-18, 5-12, and 3-11 nucleotides, respectively. On a single-stranded template containing the chloroplast DNA replication origin, the primer length range reached 19 to 27 nucleotides, indicating a better processtivity. Several initiation sites were mapped on both strands of the cloned replication origin. Some preferential initiation sites were located on A tracks spaced at one helical turn apart within the bending locus. Primase improved the template specificity of the in vitro DNA replication system and enhanced the incorporation of radioactive dATP into the supercoiled template containing the core sequences of the chloroplast DNA replication origin.

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.

A chloroplast DNA helicase II from pea that prefers fork-like replication structures

A DNA helicase, called chloroplast DNA (ctDNA) helicase II, was purified to apparent homogeneity from pea (Pisum sativum). The enzyme contained intrinsic, single-stranded, DNA-dependent ATPase activity and an apparent molecular mass of 78 kD on sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The DNA helicase was markedly stimulated by DNA substrates with fork-like replication structures. A 5'-tailed fork was more active than the 3'-tailed fork, which itself was more active than substrates without a fork. The direction of unwinding was 3' to 5' along the bound strand, and it failed to unwind blunt-ended duplex DNA. DNA helicase activity required only ATP or dATP hydrolysis. The enzyme also required a divalent cation (Mg2+>Mn2+>Ca2+) for its unwinding activity and was inhibited at 200 mM KCl or NaCl. This enzyme could be involved in the replication of ctDNA. The DNA major groove-intercalating ligands nogalamycin and daunorubicin were inhibitory to unwinding (Ki approximately 0.85 &mgr;M and 2.2 &mgr;M, respectively) and ATPase (Ki approximately 1.3 &mgr;M and 3.0 &mgr;M, respectively) activities of pea ctDNA helicase II, whereas ellipticine, etoposide (VP-16), and camptothecin had no effect on the enzyme activity. These ligands may be useful in further studies of the mechanisms of chloroplast helicase activities.

Fine mapping of replication origins (ori A and ori B) in Nicotiana tabacum chloroplast DNA

Using a partially purified replication complex from tobacco chloroplasts, replication origins have been localized to minimal sequences of 82 (pKN8, positions 137 683-137 764) and 243 bp (pKN3, positions 130 513-130 755) for ori A and ori B respectively. Analysis of in vitro replication products by two-dimensional agarose gel electrophoresis showed simple Y patterns for single ori sequence-containing clones, indicative of rolling circle replication. Double Y patterns were observed when a chloroplast DNA template containing both ori s (pKN9) was tested. Dpn I analysis and control assays with Escherichia coli DNA polymerase provide a clear method to distinguish between true replication and DNA repair synthesis. These controls also support the reliability of this in vitro chloroplast DNA replication system. EM analysis of in vitro replicated products showed rolling circle replication intermediates for single ori clones (ori A or ori B), whereas D loops were observed for a clone (pKN9) containing both ori s. The minimal ori regions contain sequences which are capable of forming stem-loop structures with relatively high free energy and other sequences which interact with specific protein(s) from the chloroplast replication fraction. Apparently the minimal ori sequences reported here contain all the necessary elements for support of chloroplast DNA replication in vitro.

Characterization of replication origins flanking the 23S rRNA gene in tobacco chloroplast DNA

Using 5' end-labeled nascent strands of tobacco chloroplast DNA (ctDNA) as a probe, replication displacement loop (D-loop) regions were identified. The strongest hybridization was observed with restriction fragments containing the rRNA genes from the inverted repeat region. Two-dimensional gel analysis of various digests of tobacco ctDNA suggested that a replication origin is located near each end of the 7.1 kb BamHI fragment containing part of the rRNA operon. Analysis of in vitro replication products indicated that templates from either of the origin regions supported replication, while the vector alone or ctDNA clones from other regions of the genome did not support in vitro replication. Sequences from both sides of the BamHI site in the rRNA spacer region were required for optimal in vitro DNA replication activity. Primer extension was used for the first time to identify the start site of DNA synthesis for the D-loop in the rRNA spacer region. The major 5' end of the D-loop was localized to the base of a stem-loop structure which contains the rRNA spacer BamHI site. Primer extension products were insensitive to both alkali and RNase treatment, suggesting that RNA primers had already been removed from the 5' end of nascent DNA. Location of an origin in the rRNA spacer region of ctDNA from tobacco, pea and Oenothera suggests that ctDNA replication origins may be conserved in higher plants.

Purification and characterization of a DNA helicase from pea chloroplast that translocates in the 3'-to-5' direction

An ATP-dependent DNA helicase has been purified to near homogeneity from pea chloroplasts. The enzyme is a homodimer of 68-kDa subunits. The purified enzyme shows DNA-dependent ATPase activity and is devoid of DNA polymerase, DNA topoisomerase, DNA ligase or nuclease activities. The enzyme requires Mg2+ or Mn2+ for its maximum activity. ATP is the most favoured cofactor for this enzyme while other NTP or dNTP are poorly utilized. Pea chloroplast DNA helicase can unwind a 17-bp duplex whether it has unpaired single-stranded tails at both the 5' end and 3' end, at the 5' end or at the 3' end only, or at neither end. However, it fails to act on a blunt-ended 17-bp duplex DNA. The enzyme moves unidirectionally from 3' to 5' along the bound strand. The unwinding activity is inhibited by the intercalating drugs nogalamycin and daunorubicine.

Characterisation and mode of in vitro replication of pea chloroplast OriA sequences

A partially purified replicative system of pea chloroplast that replicates recombinant DNAs containing pea chloroplast origin sequences has been characterised. Polymerisation by this system is very fast and insensitive to chain terminators like dideoxynucleotides, arabinosylcytosine 5'-triphosphate, etc. Both strands of template DNA are synthesized and single-stranded DNA templates undergo more than one round of replication. When sequences of either of the two chloroplast origins of replication (OriA or OriB) are used as templates, the replicative intermediates are found to have sigma structures. Electron microscopic analysis of the sigma structures restricted with various enzymes reveals that the initiation site of in vitro replication maps near the displacement-loop regions where replication initiates also in vivo. Although the observed replication initiation in the OriA recombinant template is chloroplast-DNA-specific, the mode of replication is different from that observed in vivo with intact ctDNA. However, when the template DNA contains both the OriA and OriB sequences, the in vitro replication proceeds in the theta mode, the mode of replication usually observed in vivo.

Nascent transcript-binding protein of the pea chloroplast transcriptionally active chromosome

This study describes the nascent RNA-binding protein of the pea chloroplast transcriptional complex. The protein has been identified by photoaffinity labelling of the transcriptionally active chromosome (TAC) which utilizes the endogenous plastid DNA as template. UV irradiation of lysed chloroplast or the isolated TAC under conditions optimized for transcription photocross-links nascent radiolabelled transcripts (up to 250 nucleotides in length) to a 48 kDa protein. The photoaffinity labelling of the transcript-binding protein is dependent on UV irradiation, is maximal after about 30 min of irradiation, and is completely dependent on transcriptional activity; no cross-linkage has been observed with pre-synthesized RNA. Cross-linkage is influenced by salts and inhibitors in accordance with their effects on transcription. The photoconjugate is composed of protein and RNA moieties, and can be hydrolysed by several proteases. However, the cross-linked transcript is protected from nucleases until the protein is removed. Manganese enhances photoaffinity labelling of the transcript-binding protein, and this is paralleled by an increase in total transcriptional activity of TAC. This protein was isolated by 2-dimensional polyacrylamide gel electrophoresis and the sequence of 15 amino acid residues at the amino terminus was determined. The nascent transcript-binding protein appears to be involved in the transcription of all three classes of chloroplast genes. We also found a polypeptide of identical molecular weight to get cross-linked to nascent transcripts in chloroplasts isolated from other legumes such as Cicer arietenum, Vigna radiata and Phaseolus vulgaris, and monocots like Zea mays, Oryza sativa and Pennisetum americanum.

The 110-kDa polypeptide of spinach plastid DNA-dependent RNA polymerase: single-subunit enzyme or catalytic core of multimeric enzyme complexes?

Highly purified RNA polymerase preparations from spinach chloroplasts contain seven major polypeptides of 150, 145, 110, 102, 80, 75, and 38 kDa. I find that RNA polymerase activity can be separated under defined conditions into three different fractions by heparin-Sepharose chromatography. Immunological analysis has shown that the first fraction contains RNA polymerase activity associated with all seven major polypeptides, and other studies have shown that some of these polypeptides (150, 145, 80, and 38 kDa) are associated with an RNA polymerase similar to the Escherichia coli enzyme. However, similar analyses of the remaining fractions show activity associated only with the 110-kDa polypeptide, suggesting the existence of a second kind of chloroplast RNA polymerase. Samples of this 110-kDa polypeptide purified by SDS/PAGE actively synthesize RNA in a reaction dependent on a supercoiled DNA template and the four ribonucleoside triphosphates. Hence, this polypeptide has all of the properties expected of a single-subunit RNA polymerase of the T7 bacteriophage type.

DNA replication in chloroplasts

Chloroplasts contain multiple copies of a DNA molecule (the plastome) that encodes many of the gene products required to perform photosynthesis. The plastome is replicated by nuclear-encoded proteins and its copy number seems to be highly regulated by the cell in a tissue-specific and developmental manner. Our understanding of the biochemical mechanism by which the plastome is replicated and the molecular basis for its regulation is limited. In this commentary we review our present understanding of chloroplast DNA replication and examine current efforts to elucidate its mechanism at a molecular level.