Maize BMS cultured cell lines survive with massive plastid gene loss

As part of developing an ex planta model system for the study of maize plastid and mitochondrial gene expression, a series of established Black Mexican Sweet (BMS) suspension cell lines was characterized. Although the initial assumption was that their organelle biochemistry would be similar enough to normal in planta cells to facilitate future work, each of the three lines was found to have plastid DNA (ptDNA) differing from control maize plants, in one case lacking as much as 70% of the genome. The other two BMS lines possessed either near-wild-type ptDNA or displayed an intermediate state of gene loss, suggesting that these clonal lines are rapidly evolving. Gene expression profiles of BMS cells varied dramatically from those in maize leaf chloroplasts, but resembled those of albino plants lacking plastid ribosomes. In spite of lacking most plastid gene expression and apparently mature rRNAs, BMS cells appear to import proteins from the cytoplasm in a normal manner. The regions retained in BMS ptDNAs point to a set of tRNA genes universally preserved among even highly reduced plastid genomes, whereas the other preserved regions may illuminate which plastid genes are truly indispensable for plant cell survival.Communicated by F.-A. Wollman     

Plastid inheritance in Epilobium

Summary Interspecific hybrids of various Epilobium species have been produced in order to analyse plastid inheritance using restriction fragment polymorphisms of plastid DNA as markers. This analysis reveals that interspecific hybrids exhibit only the fragment pattern of the maternal plastome. Southern hybridization experiments using cloned species-specific plastid DNA fragments as markers confirm the maternal type of plastid inheritance in Epilobium, while providing at least a tenfold increase of sensitivity to detect restriction polymorphisms. Within the limit of detection even young seedlings contain no plastid DNA from the paternal parent. However, investigations of plastomes of large populations have provided evidence that a very low frequency of paternal plastid transmission can occur. Thus, the mechanism which ensures the elimination of paternal plastids is not 100% efficient. This suggestion is also supported by intraspecific reciprocal crosses between plants carrying mutant white and normal green plastids. While the offspring usually exhibit the maternal plastid type, a few cases indicate an apparent paternal plastid transmission.Abbreviations kbp kilobase pairs - ptDNA plastid DNA     

The gene encoding <Emphasis Type="Italic">Arabidopsis thaliana</Emphasis> mitochondrial ribosomal protein S13 is a recent duplication of the gene encoding plastid S13

A gene encoding mitochondrial S13 is generally present in the mitochondrial genome of higher plants, but is lacking from the Arabidopsis thaliana mitochondrial genome. Previous research has failed to identify a nuclear gene capable of encoding a mitochondrial S13 protein or the protein itself. Doubts have even been raised as to whether a mitochondrial S13 exists in Arabidopsis. Here, we show that the nuclear gene encoding the plastid S13 has been partially duplicated in A. thaliana, such that the copy has lost the exon encoding the plastid transit peptide and acquired a sequence capable of encoding a mitochondrial targeting sequence. The two S13 sequences were fused to green fluorescent protein and shown to be targeted to plastids and mitochondria respectively.     

Evidence for tissue-specific cytosine-methylation of plastid DNA from Zea mays

Summary Total DNA isolated from leaves, etiolated seedlings, roots, endosperm or embryos of Zea mays was digested separately with each of the restriction enzymes HpaII, MspI and HhaI, and the resulting fragment patterns, which were specific for the plastid rRNA operon, were analyzed by Southern hybridization. While most of the fragment patterns were consistent with previously established physical maps, the partial resistance shown by one HpaII site and one HhaI site, both of which reside in the 16S/23S rDNA spacer region, was observed in DNA isolated from embryo, root tissue and endosperm. The partially resistant HpaII site was susceptible to cleavage with restriction enzyme MspI. From this and from the known inhibition of restriction enzyme Hhal at methylated HhaI sites, we conclude that the partial resistance of the two sites is caused by C-specific methylation of plastid DNA in the respective tissues. The tissue specificity of this DNA methylation is likely to reflect a differential expression of plastome encoded genes.     

Plastid DNA from Pyrenomonas salina (Cryptophyceae): physical map,genes, and evolutionary implications

Summary Cryptomonads are thought to have arisen from a symbiotic association between a eukaryotic flagellated host and a eukaryotic algal symbiont, presumably related to red algae. As organellar DNAs have proven to be useful tools in elucidating phylogenetic relationships, the plastid (pt) DNA of the cryptomonad alga Pyrenomonas salina has been characterized in some detail. A restriction map of the circular 127 kb ptDNA from Pyrenomonas salina was established. An inverted repeat (IR) region of about 5 kb separates two single-copy regions of 15 and 102 kb, respectively. It contains the genes for the small and large subunit of rRNA. Ten protein genes, coding for the large subunit of ribulose-1,5-bisphosphate carboxylase, the 47 kDa, 43 kDa and 32 kDa proteins of photosystem II, the ribosomal proteins L2, S7 and S11, the elongation factor Tu, as well as the - and -subunits of ATP synthase, have been localized on the restriction map either by hybridization of heterologous gene probes or by sequence homologies. The gene for the plastidal small subunit (SSUr) RNA has been sequenced and compared to homologous SSU regions from the cyanobacterium Anacystis nidulans and plastids from rhodophytes, chromophytes, euglenoids, chlorophytes, and land plants. A phylogenetic tree constructed with the neighborliness method and indicating a relationship of cryptomonad plastids with those of red algae is presented.     

Structure of the rubisco operon from the multicellular red alga Antithamnion spec.

Summary In the multicellular red alga Antithamnion spec. both rubisco genes (rbcL and rbcS) are encoded on the plastid DNA (ptDNA). Both genes are separated by a short A/T-rich spacer of 100 bp and are cotranscribed into an mRNA of approximately 2.7 kb. These findings are in extensive agreement with those obtained from two unicellular red algae (Porphyridium aerugineum and Cyanidium caldarium). The large subunit (LSU) of rubisco shows an amino acid homology of 82–87% with the LSUs from the two unicellular red algae and only about 55% to LSUs from green algae, higher plants and two cyanobacteria. The small subunit (SSU) of rubisco is more similar to those from the unicellular red algae and two algae which are members of the Chromophyta (about 60% homology) than to cyanobacterial and higher plant proteins (27–36% homology). These data indicate that rhodoplasts originated independently from the chloroplast line. The plastids of chromophytes and rhodophytes appear to be closely related.     

Genes for components of the chloroplast translational apparatus are conserved in the reduced 73-kb plastid DNA of the nonphotosynthetic euglenoid flagellate Astasia longa

The colourless, nonphotosynthetic protist Astasia longa is phylogenetically related to Euglena gracilis. The 73-kb plastid DNA (ptDNA) of A. longa is about half the size of most chloroplast DNAs (cpDNAs). More than 38 kb of the Astasia ptDNA sequence has been determined. No genes for photosynthetic function have been found except for rbcL. Identified genes include rpoB, tufA, and genes coding for three rRNAs, 17 tRNAs, and 13 ribosomal proteins. Not only is the nucleotide sequence of these genes highly conserved between A. longa and E. gracilis, but a number of these genes are clustered in a similar fashion and have introns in the same positions in both species. The results further support the idea that photosynthetic genes normally encoded in cpDNA have been preferentially lost in Astasia, but that the chloroplast genes coding for components of the plastid translational apparatus have been maintained. This apparatus might be needed for the expression of rbcL and also for that of still unidentified nonphotosynthetic genes of Astasia ptDNA.These sequence data will appear in the EMBL/Gen Bank/DDBJ nucleotide sequence data base under accession numbers X75651, X75652 and X75653     

rps10, unreported for plastid DNAs,is located on the cyanelle genome of Cyanophora paradoxa and is contranscribed with the str operon genes

Summary rps10, encoding the plastid ribosomal protein S10, is a nuclear gene in higher plants and green algae, and is missing from the large ribosomal protein gene cluster of chlorophyll b-type plastids that contains components of the prokaryotic S10, spc and alpha operons. The cyanelle genome of Cyanophora paradoxa is shown to harbor rps10 as another specific feature of its organization. However, this novel plastid gene is not contiguous with the genes of the S10 operon, but is adjacent to, and cotranscribed with, the str operon, a trait also found in archaebacteria.     

Restriction map and clone bank of tomato plastid DNA

Summary Tomato plastid DNA has been isolated from leaf chloroplasts andPst1 fragments cloned in the plasmid vector pUC8. Recombinant plasmids containing all but the largestPst1 fragment were identified by colony hybridisation. A restriction map of the plastid DNA for four restriction endonucleases was generated by digestion of the clonedPst1 fragments and by hybridisation to Southern blots. The plastid DNA is a circular molecule of 156.6–159.4 kbp with a large inverted repeat, and shows high conservation of restriction sites with plastid DNA from tobacco andPetunia.     

A circular 73 kb DNA from the colourless flagellate Astasia longa that resembles the chloroplast DNA of Euglena: restriction and gene map

Summary A 73 kbp circular DNA was isolated from the colourless euglenoid flagellate Astasia longa. Restriction sites of 12 restriction endonucleases were mapped on this DNA. Southern hybridization using plastid gene probes from Euglena, spinach and tobacco revealed sequence homologies to the genes coding for 16S and 23S ribosomal RNAs, elongation factor Tu (tufA) and the large subunit of ribulose-1,5-bisphosphate carboxylase (rbcL). The locations of these sequences on the restriction map were determined. Sequences homologous to chloroplast genes psaA, psbA, psbD, psbE and atpA are not present. The ribosomal RNA genes are organized in three tandem repeats, each containing one 23S and one 16S rRNA gene. In addition, there is one extra 16S rRNA gene. These results indicate the presence of a truncated form of a plastid DNA in Astasia.     

A large deletion in the plastid DNA of the holoparasitic flowering plant Cuscuta reflexa concerning two ribosomal proteins (rpl2, rpl23), one transfer RNA (trnI) and an ORF 2280 homologue

We have determined the nucleotide sequence of a 5.3-kb region of the plastid DNA (ptDNA) from the heterotrophic holoparasitic plant Cuscuta reflexa. The cloned area contains genes for the D1-protein (32-kDa protein; psbA), tRNA^His (trnH), ORF 740 (homologous to ORF 2280 from Nicotiana tabacum), ORF 77 (homologous to ORF 70), tRNA^Leu (trnL) and a hypothetical ORF 55 which has no homology to any known gene among higher plants. This 5.3-kb area is colinear with a 12.4-kb region of tobacco ptDNA and has therefore undergone several deletions totalling 7.1 kb. Most of the missing nucleotides belong to one large deletion in the ptDNA of C. reflexa of approximately 6.5 kb. This deletion involves two ribosomal protein genes, rpl2 and rpl23, as well as the transfer RNA for Isoleucin (trnI) and a region encoding 1540 amino-acid residues of an ORF 2280 homologue, as compared to tobacco chloroplast DNA. This is remarkable since the remaining genes, especially the psbA gene, are highly conserved in C. reflexa. Furthermore, we found that the expression of the psbA gene is in the same range as in the autotrophic Ipomoea purpurea which belongs to the same family as Cuscuta (Convolvulaceae). Here we hypothesize a total loss of rpl2 and rpl23 in the entire genome of C. reflexa. The phylogenetic position of, and the evolutionary change of ptDNA from, Cuscuta are discussed.     

Short inverted repeats function as hotspots of intermolecular recombination giving rise to oligomers of deleted plastid DNAs (ptDNAs)

We have determined the nucleotide sequences around the junction points of oligomeric-deleted ptDNAs possessing a head-to-head or tail-to-tail configuration from long-term cultured cell lines and albino plants. It was shown that DNA rearrangement occurred by direct fusion of deleted ptDNAs in an inverted orientation, which was linked by an asymmetrical sequence of 254–698 bp derived from either of the ptDNAs joined. It is notable that inverted repeats of 7–14 bp flank the asymmetrical sequences at each of the junction points. These features of the DNA sequence around the junction points are commonly observed in oligomeric ptDNA with a large-scale deletion regardless of the cell lines employed. It is suggested that the short inverted repeats are involved in the intermolecular recombination of ptDNA. Received: 1 July / 21 October 1996     

Plastid DNA is not detectable in the male gametes and pollen tubes of an angiosperm (Antirrhinum majus) that is maternal for plastid inheritance

Summary Prior cytological observations using DAPI/epifluorescence microscopy have suggested that the method could be used to rapidly screen plant species for their potential mode of plastid DNA transmission. Cytoplasmic DAPI-DNA aggregates were observed in generative cells of germinated pollen of Medicago sativa (alfalfa), a species known genetically to display biparental transmission, but not in Antirrhinum majus (snapdragon), a species known to be maternal for plastid transmission. If, as suggested, these aggregates are plastid DNA nucleoids, then M. sativa pollen should contain plastid DNA detectable by molecular biology methods and A. majus pollen should not. Total DNA was isolated from germinated pollen and analyzed by Southern blot hybridization. A clone containing part of the rbcL gene from the garden pea plastome was used as a probe for plastid DNA. This probe hybridized with a restriction fragment from M. sativa pollen DNA, but not detectably with A. majus pollen DNA, thereby corroborating the identification of the cytoplasmic DAPI-DNA aggregates in M. sativa pollen as plastid DNA, and confirming the cytologically determined absence of plastic DNA in A. majus pollen.     

Plastid inheritance in Oenothera: paternal input may influence transmission patterns

Summary Prior genetic analysis of Oenothera to assess the mechanism(s) controlling differential (biparental) plastid transmission patterns have indicated that the plastome plays an integral role. However, the influence of putative variation in paternal plastid input remains unclear. Pollen collected from Oenothera hookeri plants containing one of four different plastome types (I–IV) in a constant nuclear background (A₁A₁) was examined cytologically by DAPI/ epifluorescence microscopy. The number of plastid DNA aggregates per pollen generative cell was found to differ significantly. Plants containing plastome types I or II displayed an average of about ten plastid DNA aggregates per generative cell whereas plants containing types III or IV displayed, on average, 15 plastid DNA aggregates. The potential paternal plastid contribution to the egg cell at syngamy (III=IV>I=II) differs from the previously determined survival frequencies of the same four plastid types (I>III>II>IV) progeny.Scientific article no. A-5036, contribution no. 8084 of the Maryland Agricultural Experimental Station     

Molecular phylogenetics of eimeriid coccidia (Eimeriidae,Eimeriorina, Apicomplexa,Alveolata): A preliminary multi-gene and multi-genome approach

Coccidia possess three distinct genomes: nuclear, mitochondrial, and plastid. Sequences from five genes located on these three genomes were used to reconstruct the phylogenetic relationships of members of the phylum Apicomplexa: 18S rDNA sequences from the nuclear (nu) genome, partial cytochrome c oxidase subunit I sequences from the mitochondrial (mt) genome, and partial 16S and 23S rDNA sequences and RNA polymerase B sequences from plastid (pl) genomes. Maximum parsimony, maximum likelihood, and Bayesian inference were used in conjunction with nuclear substitution models generated from data subsets in the analyses. Major groups within the Apicomplexa were well supported with the mitochondrial, nuclear, and a combination of mitochondrial, nuclear and concatenated plastid gene sequences. However, the genus Eimeria was paraphyletic in phylogenetic trees based on the nuclear gene. Analyses using the individual genes (18S rDNA and cytochrome c oxidase subunit I) resolved the various apicomplexan groups with high Bayesian posterior probabilities. The multi-gene, multi-genome analyses based on concatenated nu 18S rDNA, pl 16S, pl 23S, pl rPoB, pl rPoB1, and mt COI sequences appeared useful in resolving phylogenetic relationships within the phylum Apicomplexa. Genus-level relationships, or higher, appear best supported by 18S rDNA analyses, and species-level analyses are best investigated using mt COI sequences; for parasites for which both loci are available, nuclear 18S rDNA sequences combined with mitochondrial COI sequences provide a compact and informative molecular dataset for inferring the evolutionary relationships taxa in the Apicomplexa.