High transmission of paternal plastid DNA in alfalfa plants demonstrated by restriction fragment polymorphic analysis

Summary A high frequency of paternal plastid transmission occurred in progeny from crosses among normal green alfalfa plants. Plastid transmission was analyzed by hybridization of radiolabeled alfalfa plastid DNA (cpDNA) probes to Southern blots of restriction digests of the progeny DNA. Each probe revealed a specific polymorphism differentiating the parental plastid genomes. Of 212 progeny, 34 were heteroplastidic, with their cpDNAs ranging from predominantly paternal to predominantly maternal. Regrowth of shoots from heteroplasmic plants following removal of top growth revealed the persistence of mixed plastids in a given plant. However, different shoots within a green heteroplasmic plant exhibited paternal, maternal, or mixed cpDNAs. Evidence of maternal nuclear genomic influence on the frequency of paternal plastid transmission was observed in some reciprocal crosses. A few tetraploid F₁ progeny were obtained from tetraploid (2n=4x=32) Medicago sativa ssp. sativa x diploid (2n=2x=16) M. sativa ssp. falcata crosses, and resulted from unreduced gametes. Here more than the maternal genome alone apparently functioned in controlling plastid transmission. Considering all crosses, only 5 of 212 progeny cpDNAs lacked evidence of a definitive paternal plastid fragment.Contribution No. 89-524-J from the Kansas Agricultural Experiment Station, Kansas State University, Manhattan     

Rapid evolution of the plastid translational apparatus in a nonphotosynthetic plant: Loss or accelerated sequence evolution of tRNA and ribosomal protein genes

Summary The vestigial plastid genome of Epifagus virginiana (beechdrops), a nonphotosynthetic parasitic flowering plant, is functional but lacks six ribosomal protein and 13 tRNA genes found in the chloroplast DNAs of photosynthetic flowering plants. Import of nuclear gene products is hypothesized to compensate for many of these losses. Codon usage and amino acid usage patterns in Epifagus plastic genes have not been affected by the tRNA gene losses, though a small shift in the base composition of the whole genome (toward A + T -richness) is apparent. The ribosomal protein and tRNA genes that remain have had a high rate of molecular evolution, perhaps due to relaxation of constraints on the translational apparatus. Despite the compactness and extensive gene loss, one translational gene (infA, encoding initiation factor 1) that is a pseudogene in tobacco has been maintained intact in Epifagus.Offprint requests to: J.D. Palmer     

Functional loss of all ndh genes in an otherwise relatively unaltered plastid genome of the holoparasitic flowering plant Cuscuta reflexa

We have cloned and sequenced an area of about 9.0 kb of the plastid DNA (ptDNA) from the holoparasitic flowering plant Cuscuta reflexa to investigate the evolutionary response of plastid genes to a reduced selective pressure. The region contains genes for the 16S rRNA, a subunit of a plastid NAD(P)H dehydrogenase (ndhB), three transfer RNAs (trnA, trnI, trnV) as well as the gene coding for the ribosomal protein S7 (rps7). While the other genes are strongly conserved in C. reflexa, the ndhB gene is a pseudogene due to many frameshift mutations. In addition we used heterologous gene probes to identify the other ndh genes encoded by the plastid genome in higher plants. No hybridization signals could be obtained, suggesting that these genes are either lost or strongly altered in the ptDNA of C. reflexa. Together with evidence of deleted genes in the ptDNA of C. reflexa, the plastid genome can be grouped into four classes reflecting a different evolutionary rate in each case. The phylogenetic position of Cuscuta and the significance of ndh genes in the plastid genome of higher plants are discussed.     

In vitro and in vivo analysis of transcription within the replication region of plasmid pIP501

Summary The tobacco (Nicotiana tabacum) nuclear genome contains long tracts of DNA (i.e. in excess of 18 kb) with high sequence homology to the tobacco plastid genome. Five lambda clones containing these nuclear DNA sequences encompass more than one-third of the tobacco plastid genome. The absolute size of these five integrants is unknown but potentially includes uninterrupted sequences that are as large as the plastid genome itself. An additional sequence was cloned consisting of both nuclear and plastid-derived DNA sequences. The nuclear component of the clone is part of a family of repeats, which are present in about 400 locations in the nuclear genome. The homologous sequences present in chromosomal DNA were very similar to those of the corresponding sequences in the plastid genome. However significant sequence divergence, including base substitutions, insertions and deletions of up to 41 bp, was observed between these nuclear sequences and the plastid genome. Associated with the larger deletions were sequence motifs suggesting that processes such as DNA replication slippage and excision of hairpin loops may have been involved in deletion formation.     

Pollen-derived rice calli that have large deletions in plastid DNA do not require protein synthesis in plastids for growth

Summary Albino rice plants derived from pollen contain plastid genomes that have suffered large-scale deletions. From the roots of albino plants, we obtained several calli containing homogeneous plastid DNA differing in the size and position of the deletion. Southern blotting and pulsed field gel electrophoresis experiments revealed that the DNAs were linear molecules having a hairpin structure at both termini, existing as monomers (19 kb) or dimers, trimers and tetramers linked to form head-to-head and tail-to-tail multimers. This characteristic form is similar to that of the vaccinia virus, in which the replication origin is thought to lie at or near the hairpin termini. Furthermore, polymerase chain reaction experiments revealed complete loss of the ribosomal RNA genes of the plastid DNA. The results suggest that plant cells can grow without translation occurring in plastids. All of the deleted plastid DNAs commonly retained the region containing the tRNA^Glu gene (trnE), which is essential for biosynthesis of porphyrin. As porphyrin is the precursor of heme for mitochondria and other organelles, it is considered thattrnE on the remnant plastid genome may be transcribed by an RNA polymerase encoded on nuclear DNA.     

Homology-dependent DNA Transfer from Plants to a Soil Bacterium Under Laboratory Conditions: Implications in Evolution and Horizontal Gene Transfer

DNA transfer was demonstrated from six species of donor plants to the soil bacterium, Acinetobacter spp. BD413, using neomycin phosphotransferase (nptII) as a marker for homologous recombination. These laboratory results are compatible with, but do not prove, DNA transfer in nature. In tobacco carrying a plastid insertion of nptII, transfer was detected with 0.1 g of disrupted leaves and in oilseed rape carrying a nuclear insertion with a similar quantity of roots. Transfer from disrupted leaves occurred in sterile soil and water, without the addition of nutrients. It was detected using intact tobacco leaves and intact tobacco and Arabidopsis plants in vitro. Transfer was dose-dependent and sensitive to DNase, and mutations in the plant nptII were recovered in receptor bacteria. DNA transfer using intact roots and plants in vitro was easily demonstrated, but with greater variability. Transfer varied with plant genome size and the number of repeats of the marker DNA in the donor plant. Transfer was not detected in the absence of a homologous nptII in the receptor bacteria. We discuss these results with reference to non-coding DNA in plant genomes (e.g., introns, transposons and junk DNA) and the possibility that DNA transfer could occur in nature.     

Identification of functional lox sites in the plastid genome

Our objective was to test whether or not cyclization recombination (CRE), the P1 phage site-specific recombinase, induces genome rearrangements in plastids. Testing was carried out in tobacco plants in which a DNA sequence, located between two inversely oriented locus of X-over of P1 (loxP) sites, underwent repeated cycles of inversions as a means of monitoring CRE activity. We report here that CRE mediates deletions between loxP sites and plastid DNA sequences in the 3'rps12 gene leader (lox-rps12) or in the psbA promoter core (lox-psbA). We also observed deletions between two directly oriented lox-psbA sites, but not between lox-rps12 sites. Deletion via duplicated rRNA operon promoter (Prrn) sequences was also frequent in CRE-active plants. However, CRE-mediated recombination is probably not directly involved, as no recombination junction between loxP and Prrn could be observed. Tobacco plants carrying deleted genomes as a minor fraction of the plastid genome population were fertile and phenotypically normal, suggesting that the absence of deleted genome segments was compensated by gene expression from wild-type copies. The deleted plastid genomes disappeared in the seed progeny lacking CRE. Observed plastid genome rearrangements are specific to engineered plastid genomes, which contain at least one loxP site or duplicated psbA promoter sequences. The wild-type plastid genome is expected to be stable, even if CRE is present in the plastid.     

Plastid genome sequencing,comparative genomics,and phylogenomics: Current status and prospects

Abstract More than 190 plastid genomes have been completely sequenced during the past two decades due to advances in DNA sequencing technologies. Based on this unprecedented abundance of data, extensive genomic changes have been revealed in the plastid genomes. Inversion is the most common mechanism that leads to gene order changes. Several inversion events have been recognized as informative phylogenetic markers, such as a 30‐kb inversion found in all living vascular plants minus lycopsids and two short inversions putatively shared by all ferns. Gene loss is a common event throughout plastid genome evolution. Many genes were independently lost or transferred to the nuclear genome in multiple plant lineages. The trnR‐CCG gene was lost in some clades of lycophytes, ferns, and seed plants, and all the ndh genes were absent in parasitic plants, gnetophytes, Pinaceae, and the Taiwan moth orchid. Certain parasitic plants have, in particular, lost plastid genes related to photosynthesis because of the relaxation of functional constraint. The dramatic growth of plastid genome sequences has also promoted the use of whole plastid sequences and genomic features to solve phylogenetic problems. Chloroplast phylogenomics has provided additional evidence for deep‐level phylogenetic relationships as well as increased phylogenetic resolutions at low taxonomic levels. However, chloroplast phylogenomics is still in its infant stage and rigorous analysis methodology has yet to be developed.     

Plastid marker gene excision by the phiC31 phage site-specific recombinase

Marker genes are essential for selective amplification of rare transformed plastid genome copies to obtain genetically stable transplastomic plants. However, the marker gene becomes dispensable when homoplastomic plants are obtained. Here we report excision of plastid marker genes by the phiC31 phage site-specific integrase (Int) that mediates recombination between bacterial (attB) and phage (attP) attachment sites. We tested marker gene excision in a two-step process. First we transformed the tobacco plastid genome with the pCK2 vector in which the spectinomycin resistance (aadA) marker gene is flanked with suitably oriented attB and attP sites. The transformed plastid genomes were stable in the absence of Int. We then transformed the nucleus with a gene encoding a plastid-targeted Int that led to efficient marker gene excision. The aadA marker free Nt-pCK2-Int plants were resistant to phosphinothricin herbicides since the pCK2 plastid vector also carried a bar herbicide resistance gene that, due to the choice of its promoter, causes a yellowish-golden (aurea) phenotype. Int-mediated marker excision reported here is an alternative to the currently used CRE/loxP plastid marker excision system and expands the repertoire of the tools available for the manipulation of the plastid genome.     

The Discriminatory Transfer Routes of tRNA Genes Among Organellar and Nuclear Genomes in Flowering Plants: A Genome-Wide Investigation of <Emphasis Type="Italic">indica</Emphasis> Rice

The transfer and integration of tRNA genes from organellar genomes to the nuclear genome and between organellar genomes occur extensively in flowering plants. The routes of the genetic materials flowing from one genome to another are biased, limited largely by compatibility of DNA replication and repair systems differing among the organelles and nucleus. After thoroughly surveying the tRNA gene transfer among organellar genomes and the nuclear genome of a domesticated rice (Oryza sativa L. ssp. indica), we found that (i) 15 mitochondrial tRNA genes originate from the plastid; (ii) 43 and 80 nuclear tRNA genes are mitochondrion-like and plastid-like, respectively; and (iii) 32 nuclear tRNA genes have both mitochondrial and plastid counterparts. Besides the native (or genuine) tRNA gene sets, the nuclear genome contains organelle-like tRNA genes that make up a complete set of tRNA species capable of transferring all amino acids. More than 97% of these organelle-like nuclear tRNA genes flank organelle-like sequences over 20 bp. Nearly 40% of them colocalize with two or more other organelle-like tRNA genes. Twelve of the 15 plastid-like mitochondrial tRNA genes possess 5′- and 3′-flanking sequences over 20 bp, and they are highly similar to their plastid counterparts. Phylogenetic analyses of the migrated tRNA genes and their original copies suggest that intergenomic tRNA gene transfer is an ongoing process with noticeable discriminatory routes among genomes in flowering plants. Electronic Supplementary Material Electronic Supplementary material is available for this article at and accessible for authorised users. Reviewing Editor: Dr. David Guttman     

Efficient and Stable Transformation of Lactuca sativa L. cv. Cisco (lettuce) Plastids

Transgenic plastids offer unique advantages in plant biotechnology, including high-level foreign protein expression. However, broad application of plastid genome engineering in biotechnology has been largely hampered by the lack of plastid transformation systems for major crops. Here we describe the development of a plastid transformation system for lettuce, Lactuca sativa L. cv. Cisco. The transforming DNA carries a spectinomycin-resistance gene (aadA) under the control of lettuce chloroplast regulatory expression elements, flanked by two adjacent lettuce plastid genome sequences allowing its targeted insertion between the rbcL and accD genes. On average, we obtained 1 transplastomic lettuce plant per bombardment. We show that lettuce leaf chloroplasts can express transgene-encoded GFP to ~36% of the total soluble protein. All transplastomic T0 plants were fertile and the T1 progeny uniformly showed stability of the transgene in the chloroplast genome. This system will open up new possibilities for the efficient production of edible vaccines, pharmaceuticals, and antibodies in plants.     

Glutamate synthase is plastid-encoded in a red alga: implications for the evolution of glutamate synthases

An actively transcribed gene (glsF) encoding for ferredoxin-dependent glutamate synthase (Fd-GOGAT) was found on the plastid genome of the multicellular red alga Antithamnion sp. Fd-GOGAT is not plastid-encoded in chlorophytic plants, demonstrating that red algal plastid genomes encode for additional functions when compared to those known from green chloroplasts. Moreover, our results suggest that the plant Fd-GOGAT has an endosymbiotic origin. The same may not be true for NADPH-dependent GOGAT. In Antithamnion glsF is flanked upstream by cpcBA and downstream by psaC and is transcribed monocistronically. Implications of these results for the evolution of GOGAT enzymes and the plastid genome are discussed.     

Extensive Reorganization of the Plastid Genome of <Emphasis Type="Italic">Trifolium subterraneum</Emphasis> (Fabaceae) Is Associated with Numerous Repeated Sequences and Novel DNA Insertions

The plastid genome of Trifolium subterraneum is 144,763 bp, about 20 kb longer than those of closely related legumes, which also lost one copy of the large inverted repeat (IR). The genome has undergone extensive genomic reconfiguration, including the loss of six genes (accD, infA, rpl22, rps16, rps18, and ycf1) and two introns (clpP and rps12) and numerous gene order changes, attributable to 14–18 inversions. All endpoints of rearranged gene clusters are flanked by repeated sequences, tRNAs, or pseudogenes. One unusual feature of the Trifolium subterraneum genome is the large number of dispersed repeats, which comprise 19.5% (ca. 28 kb) of the genome (versus about 4% for other angiosperms) and account for part of the increase in genome size. Nine genes (psbT, rbcL, clpP, rps3, rpl23, atpB, psbN, trnI-cau, and ycf3) have also been duplicated either partially or completely. rpl23 is the most highly duplicated gene, with portions of this gene duplicated six times. Comparisons of the Trifolium plastid genome with the Plant Repeat Database and searches for flanking inverted repeats suggest that the high incidence of dispersed repeats and rearrangements is not likely the result of transposition. Trifolium has 19.5 kb of unique DNA distributed among 160 fragments ranging in size from 30 to 494 bp, greatly surpassing the other five sequenced legume plastid genomes in novel DNA content. At least some of this unique DNA may represent horizontal transfer from bacterial genomes. These unusual features provide direction for the development of more complex models of plastid genome evolution. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Constancy of organellar genome copy numbers during leaf development and senescence in higher plants

In higher plants, plastid and mitochondrial genomes occur at high copy numbers per cell. Several recent publications have suggested that, in higher plants like Arabidopsis and maize, chloroplast DNA is virtually absent in mature and old leaves. This conclusion was mainly based on DAPI staining of isolated chloroplasts. If correct, the finding that chloroplasts in mature leaves lack DNA would change dramatically our understanding of gene expression, mRNA stability and protein stability in chloroplasts. In view of the wide implications that the disposal of chloroplast DNA during leaf development would have, we have reinvestigated the age dependency of genome copy numbers in chloroplasts and, in addition, tested for possible changes in mitochondrial genome copy number during plant development. Analyzing chloroplast and mitochondrial DNA amounts in Arabidopsis and tobacco plants, we find that organellar genome copy numbers remain remarkably constant during leaf development and are present in essentially unchanged numbers even in the senescing leaves. We conclude that, during leaf development, organellar gene expression in higher plants is not significantly regulated at the level of genome copy number and we discuss possible explanations for the failure to detect DNA in isolated chloroplasts stained with DAPI.     

Patterns of Genomic Integration of Nuclear Chloroplast DNA Fragments in Plant Species

The transfer of organelle DNA fragments to the nuclear genome is frequently observed in eukaryotes. These transfers are thought to play an important role in gene and genome evolution of eukaryotes. In plants, such transfers occur from plastid to nuclear [nuclear plastid DNAs (NUPTs)] and mitochondrial to nuclear (nuclear mitochondrial DNAs) genomes. The amount and genomic organization of organelle DNA fragments have been studied in model plant species, such as Arabidopsis thaliana and rice. At present, publicly available genomic data can be used to conduct such studies in non-model plants. In this study, we analysed the amount and genomic organization of NUPTs in 17 plant species for which genome sequences are available. The amount and distribution of NUPTs varied among the species. We also estimated the distribution of NUPTs according to the time of integration (relative age) by conducting sequence similarity analysis between NUPTs and the plastid genome. The age distributions suggested that the present genomic constitutions of NUPTs could be explained by the combination of the rapidly eliminated deleterious parts and few but constantly existing less deleterious parts.