A.J. Kool

A Petunia hybrida chloroplast DNA region, close to one of the inverted repeats, shows sequence homology with the Euglena gracilis chloroplast DNA region that carries the putative replication origin

SummaryThree distinct chloroplast (cp) DNA fragments from Petunia hybrida, which promote autonomous replication in yeast, were mapped on the chloroplast genome. Sequence analysis revealed that these fragments (called ARS A, B and C) have a high AT content, numerous short direct and inverted repeats and at least one yeast ARS consensus sequence 5′A/TTTTATPuTTTA/T, essential for yeast ARS activity. ARS A and B also showed the presence of (semi-)conserved sequences, present in all Chlamydomanas reinhardii cpDNA regions that promote autonomous replication in yeast (ARS sequences) or in C. reinhardii (ARC sequences). A 431 bp BamHI/EcoRI fragment, close to one of the inverted repeats and adjacent to the ARS B subfragment contains an AT-rich stretch of about 100 nucleotides that show extensive homology with an Euglena gracilis cpDNA fragment which is part of the replication origin region. This conserved region contains direct and inverted repeats, stem-and-loop structures can be folded and it contains an ARS consensus sequence. In the near vicinity a GC-rich block is present. All these features make this cpDNA region the best candidate for being the origin of replication of P. hybrida cpDNA.

Light and benzylaminopurine induce changes in ultrastructure and gene expression in plastids of Petunia hybrida cell cultures.

SummaryThe regulatory effect of light and the cytokinin 6-benzylaminopurine (BA) on the plastid ultrastructure and plastid DNA gene expression is studied in white and mutant green cell suspension cultures of Petunia hybrida. By electron microscopy we show that both light and 6-benzylaminopurine induce the formation of thylakoid membranes and grana structures in plastids of the green cultures. For membrane formation in plastids of white cultures, light in combination with BA is required. Light and benzylaminopurine also influence the plastid DNA gene expression. By in-organello protein synthesis with isolated plastids we show that light as well as benzylaminopurine affects the synthesis of plastid DNA encoded proteins. A characteristic effect of benzylaminopurine on plastids from white and green cultures is the reduction in the synthesis of the CFI subunits of 55,000 and 57,000 D, and the reduction in the synthesis of large polypeptides with a molecular weight higher than 67,000 D. In contrast to benzylaminopurine, light only affects the DNA gene expression of plastids from white cell cultures, that are in a very early stage of plastid development. Light stimulates the synthesis of polypeptides with a molecular weight of 84,000, 70,000 and 46,000 D which are encoded by cpDNA in these white culture plastids. In green cell cultures both plastids with a etioplast-like phenotype and with a chloroplast like morphology synthesize similar polypeptides, resulting in the same polypeptide pattern. Our results indicate that qualitative differences in plastid DNA gene expression as an effect of light do occur but only in plastids at very early stages of chloroplast development. We observe a gradual reduction in the number of high molecular weight polypeptides at later stages of chloroplast development. This suggests that these large polypeptides are characteristic for plastids at an early developmental stage.

Cloning of Petunia hybrida chloroplast DNA sequences capable of autonomous replication in yeast

SummarySequences from Petunia hybrida chloroplast DNA which have the property to promote autonomous replication in Saccharomyces cerevisiae were cloned in vector YIp5. Seven cloned chloroplast DNA fragments are localized at one of two different sites on the chloroplast genome. One site, arsA was mapped on a 1.8 Kb fragment at position 27.0–28.8 Kb on the P. hybrida chloroplast genome. The plasmids containing this arsA are stable both in yeast and E. coli. The other site, arsB, was shown to be very unstable and is located either in the small single copy region close to the inverted repeat or just in the inverted repeat. The functioning of these sequences as a possible origin of replication in vivo is discussed.

Isolation and physicochemical characterization of mitochondrial DNA from cultured cells ofPetunia hybrida.

SummaryMitochondrial DNA ofPetunia hybrida was purified from cell suspension cultures. Up to 50% of the DNA could be isolated as supercoiled DNA molecules by CsCl-ethidium bromide density gradient centrifugation. The DNA purified from DNase-treated mitochondria bands at a single buoyant density of 1.760 gcm−3 in neutral density gradients and runs on agarose gels as a single band with an apparent molecular weight exceeding 30 megadaltons (Md). Summing of the restriction endonuclease fragment lengths indicates a mitochondrial genome size of at least 190 Md. Electron microscopic analysis reveals the presence of a heterogeneous population of circular DNA molecules, up to 60 Md in size. Small circular DNA molecules, ranging in size from 2–30 Md are present, but unlike in cultured cells of other plant species they do not form discrete size classes and furthermore, they constitute less than 5% of the total DNA content of the mitochondria. The restriction endonuclease patterns of mitochondrial DNA do not qualitatively alter upon prolonged culture periods (up to at least two years).

Two potential Petunia hybrida mitochondrial DNA replication origins show structural and in vitro functional homology with the animal mitochondrial DNA heavy and light strand replication origins

SummaryFour Petunia hybrida mitochondrial (mt) DNA fragments have been isolated, sequenced, localized on the physical map and analyzed for their ability to initiate specific DNA synthesis. When all four mtDNA fragments were tested as templates in an in vitro DNA synthesizing lysate system, developed from purified P. hybrida mitochondria, specific initiation of DNA synthesis could only be observed starting within two framents, oriA and oriB. When DNA synthesis incubations were performed with DNA templates consisting of both the A and B origins in the same plasmid in complementary strands, DNA synthesis first initiates in the A-origin, proceeds in the direction of the B-origin after which replication is also initiated in the B-origin. Based on these observations, a replication model for the P. hybrida mitochondrial genome is presented.

Characterization of DNA synthesis and chloroplast DNA replication initiation in a Petunia hybrida chloroplast lysate system

SummaryAn in vitro chloroplast DNA synthesizing lysate system prepared from purified chloroplasts of Petunia hybrida leaves has been developed. Both co-isolated endogeneous chloroplast (cp)DNA and externally added DNA can be used as DNA templates in the system. The system contains a γ-like DNA polymerase as determined by using DNA polymerase-specific inhibitors and synthetic templates. The molecular weight of this enzyme is about 85 kd. Part of the DNA synthesizing activity is repair synthesis. When a chimaeric plasmid containing a fragment with a potential cpDNA replication origin is used as a template (pPCY62), specific initiation of DNA synthesis is observed on this fragment which strongly suggests that the in vitro chloroplast lysate system is also capable of replication initiation.

Physical mapping, nucleotide sequencing and expression in E. coli minicells of the gene for the large subunit of ribulose bisphosphate carboxylase from Petunia hybrida

SummaryThe Petunia hybrida rbcL gene was identified and located on the physical map within the Sall S9 fragment of the Petunia hybrida cpDNA by heterologous hybridization with the cloned rbcL gene of spinach (pSoc3BE148). In E. coli minicells harbouring the S9 fragment inserted into pBR322, the rbcL polypeptide is synthesized as was shown by molecular weight determination, immunoprecipitation and proteolytic digestion. However, the size of the rbcL polypeptide synthesized in minicells appeared to be dependent on the orientation of the S9 fragment in pBR322. In minicells harbouring the S9 fragment inserted into pBR322 in the clockwise orientation the molecular weight of the rbcL polypeptide is approximately 53 kD, whereas in minicells harbouring the S9 fragment in the opposite orientation, the rbcL polypeptide synthesized has a molecular weight of 52 kD. The difference in molecular weight of the two rbcL polypeptides is the result of transcription and translation into the flanking pBR322 sequences. This is due to the absence of the terminal part (6 codons), including the translation stop codon, of the rbcL gene on the cloned S9 fragment as was determined by nucleotide sequencing. The observed expression of the cloned part of the rbcL gene of Petunia hybrida indicates that the E. coli minicell system can be used as a suitable and convenient system for the identification and physical mapping of chloroplast genes.Comparison of the sequence of the untranslated 3′-end of the rbcL gene of Petunia hybrida with that of Nicotiana tabacum revealed a striking similarity of the region in which stem and loop structures can be formed that are most likely involved in termination of transcription of the rbcL gene. This region appears to be highly conserved in the rbcL genes of P. hybrida, N. tabacum, S. oleracea and Z. mays.

Physical mapping of genes for chloroplast DNA encoded subunit polypeptides of the ATPsynthase complex from Petunia hybrida

SummaryEscherichia coli minicells harbouring the cloned restriction fragment Sall S9 from P. hybrida chloroplast DNA synthesize the beta and epsilon polypeptide subunits of the CF1 component of the chloroplast ATPsynthase complex. The polypeptides were identified by molecular weight determination and immunoprecipitation. The position of the atpB and the atpE gene, encoding respectively the beta and epsilon subunit, on the Sall S9 fragment was determined in more detail by studying polypeptide synthesis directed by subclones of the S9 fragment in E. coli minicells. The atpB and atpE genes are located close to the rbcL gene, the distance between the rbcL gene and atpB gene being approximately 770 bp. Analysis of the expression of subclones of the S9 fragment in E. coli minicells also revealed that the atpE gene can be transcribed and translated independently of the expression of the atpB gene.The location of the genes coding for the alpha subunit (atpA gene) and the proteolipid subunit III of CF0 (atpH) of the ATPsynthase complex on the physical map of P. hybrida cpDNA was determined by hybridization of restriction enzyme digests of petunia cpDNA with cloned cpDNA fragments from Spirodela and wheat, containing internal parts of respectively the atpA and the atpH gene. The two genes map close together within a region of 5.2 kbp on the physical map of P. hybrida cpDNA. The distance between the atpA gene and the atpB and atpE genes is approximately 42 kbp.

Plastid gene expression in a yellow-green leaf mutant of Petunia hybrida

We have analyzed the morphology and gene expression in plastids of a yellow-green leaf mutant of Petunia hybrida (E 5059). Under normal light intensities (20,000 lx), yellow-green leaves develop with a typical proplastid morphology (few membranes, incomplete stacking). When such plants are grown under low light intensities (3,000 lx), the newly formed leaves are green. The plastids in these green leaves have a wild-type like chloroplast morphology (thylakoids and grana structure). Pre-existing green leaves remain green in 20,000 lx, indicating that chlorophyll is not degraded. An analysis of polypeptides synthesized in isolated plastids from the yellow-green and green leaves of this mutant plant shows several differences. In the yellow-green leaf plastids only a very small amount of the large subunit of ribulose-1,5-bisphosphate carboxylase (RuBPCase) is present, while in green plastids this polypeptide is present in much higher amounts. Hybridization experiments indicated that in plastids from the yellow-green leaves the mRNA coding for the large subunit polypeptide is present in much lower amounts than in plastids from the 3,000 lx green leaves of this mutant or in chloroplasts from wild type plants. These results indicate regulation at the mRNA level. Furthermore, in yellow-green leaf plastids eleven polypeptides are present with high molecular wieght (higher than 67,000 d). Five of them are synthesized by the yellow-green leaf plastid itself. Such high molecular weight polypeptides are also synthesized by proplastids isolated from white petunia cell suspension cultures, but are not synthesized by 3,000 lx green leaf plastids, or by isolated normal leaf chloroplasts. These results indicate that the synthesis of these polypeptides is specific for the proplastid stage of chloroplast biogenesis.