The rice psb-A chloroplast gene has a standard location

Summary The chloroplast DNA-encoded gene psbA codes for the 32 kD protein of photosystem II. It has been mapped in several monocots to a location in the large single copy segment very near to the end of one of the inverted repeats present in the chloroplast genome of most land plants. The psbA gene of rice has been located much further from the inverted repeat, suggesting that rice differs from related species in the location of this gene. Indirect evidence reported here suggests that this gene actually maps to the usual cereal location, at least in the seven varieties tested, which include representatives of three subspecies.     

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.     

Points of rearrangements between plastid chromosomes: location of protein coding regions on broad bean chloroplast DNA

Summary By using genes from spinach and tobacco chloroplast DNA as probes we have localized 22 protein genes on a refined map of Vicia faba (broad bean) chloroplast DNA. The genes are rbcL, rpoA, psaA,B, psbA–E, atpA,B,E,FH,I, pet-A,B,D, and the ribosomal protein genes rp12, rps7, rps12, and rps19. In addition, we mapped sequences homologous to a conserved open reading frame previously found in an intron of a trnK gene. The results were used to map the relative positions of rearrangements that distinguish the broad bean and spinach plastid DNAs. By hybridization with small probes several regions on both DNAs with sequence homology to more than one chromosomal position were found. Intermediate segments are rearranged in broad bean relative to spinach. A spinach chloroplast DNA fragment that functions as an autonomously replicating sequence in yeast is shown to be missing in broad bean chloroplast DNA. This ars is located at a position in spinach DNA which has been a target for rearrangement in the broad bean chromosome. These results can be interpreted by assuming that the DNAs contain short repeat sequences at some conserved positions. We suggest a model for chloroplast DNA divergence assuming that short repeats exist which are the substrate for a recombination system. The few rearrangements between chloroplast chromosomes from a variety of plants may be explained as the result of selection against short repeats.Abbreviations Kbp 10³ base-pairs - IR large inverted repeat unit     

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.     

Mitochondrial genome of the dimorphic zygomycete Mucor racemosus

Mitochondria were isolated from the dimorphic zygomycete Mucor racemosus by differential centrifugation. DNA from the organelles was purified by cesium chloride-ethidium bromide isopycnic centrifugation. Examination of the mitochondrial DNA by electron microscopy revealed a circular chromosome approximately 63.8 kbp in circumference. The chromosome was digested with restriction endonucleases and the resulting DNA fragments were separated by agarose-gel electrophoresis. Electrophoretic mobilities and stoichiometry of the fragments indicated a mixed population of mtDNA molecules each with a size of about 63.4 kbp. Physical maps were constructed from analyses of fragments generated in single and double restriction digests and from the hybridization of fragments to probes for the large and small mitochondrial rRNA genes from Saccharomyces cerevisiae. The Mucor mitochondrial chromosome was found to exist in the form of two flip-flop isomers with inverted repeat sequences encoding both rRNA genes.     

The location and possible evolutionary significance of small dispersed repeats in wheat ctDNA

Summary Low-stringency hybridisation between recombinant plasmids representing the complete T. aestivum chloroplast genome has revealed small repeated DNA segments dispersed through the molecule. Thirty-two repeated DNA segments were detected, and they could be divided into 12 unrelated sets; no repeat was detected as multiple copies. The longest of the small repeats mapped just within the large inverted repeat in spinach and mung-bean ctDNAs. It was found to have been duplicated after the divergence of a cereal progenitor to generate a third, dispensible copy, 0.2 kbp downstream of rbcL. In maize at least, this copy has also become integrated, with rbcL, in the mitochondrial genome. Another of the repeats is thought to have mediated a chloroplast DNA inversion (Howe 1985). Thus the diverse collection of small repeats probably represents some consequences and causes of past recombination events as well as a mechanism for further intramolecular ctDNA recombination. Their possible significance in the restructuring and evolution of chloroplast genomes is discussed.     

Repetitive sequence-mediated rearragements in Chlorella ellipsoidea chloroplast DNA: completion of nucleotide sequence of the large inverted repeat

Summary A 3454 base pair (bp) sequence of the large inverted repeat (IR) of chloroplast DNA (cpDNA) from the unicellular green alga Chlorella ellipsoidea has been determined. The sequence includes: (1) the boundaries between the IR and the large single copy (LSC) and the small single copy (SSC) regions, (2) the gene for psbA and (3) an approximately 1.0 kbp region between psbA and the rRNA genes which contains a variety of short dispersed repeats. The total size of the Chlorella IR was determined to be 15243 bp. The junction between the IR and the small single copy region is located close to the putative promoter of the rRNA operon (906 bp upstream of the-35 sequence on each IR). The junction between the IR and the large single copy region is also just upstream of the putative psbA promoter, 218 bp upstream from the ATG initiation codon. A few sets of unique sequences were found repeatedly around both junctions. Some of the sequences flanking the IR-LSC junction suggest a unidirectional and serial expansion of the IR within the genome. The psbA gene is located close to the LSC-side junction and codes for a protein of 352 amino acid residues. A highly conserved C-terminal Gly is absent. Unlike the psbA of Chlamydomonas species, which contains 2–4 large introns, the gene of Chlorella has no introns. The overall gene organization of the Chlorella IR is very different from that of higher plants, but a similar gene cluster of rrn-psbA is also found in the IR of Chlamydomonas species and in a single copy region of some chlorophyll a/c-containing algae, indicating a common evolutionary lineage of these cpDNAs. The origin and evolution of the IR structure are discussed in the light of these observations.     

Physical mapping of differences between the chloroplast DNAs of the interfertile algae Chlamydomonas eugametos and Chlamydomonas moewusii

Summary The chloroplast genomes from the interfertile green algae Chlamydomonas eugametos and C. moewusii have been compared in their overall sequence organization. Physical mapping of Aval, BstEII and EcoRI restriction sites on the C. moewusii chloroplast genome revealed that this 292 kilobase-pair (kbp) genome is 49 kbp larger than the C. eugametos genome. Heterologous fragment hybridizations indicated the same order of common sequence elements on the two algal genomes. Almost all of the 49 kbp size difference is accounted for by the presence of two large extra sequences in C. moewusii: a 21 kbp sequence in the inverted repeat and a 5.8 kbp sequence in the single copy-region bordering the 16S ribosomal RNA (rRNA) genes. In addition to these two major deletion/addition differences, 42 restriction site and fragment length differences (ranging from 100 to 500 base pairs) were mapped on the two algal genomes. Surprisingly, the greatest density of these differences was found to be confined within the inverted repeat, one of the most conserved regions of land plant chloroplast genomes.     

Organization and nucleotide sequence of ribosomal RNA genes on a circular 73 kbp DNA from the colourless flagellate Astasia longa

Summary Three tandemly arranged repeats (A, B, C) of 16S and 23S rDNA, and one supplementary (S) 16S rDNA adjacent to the 16S rDNA of repeat A, are present within an 18 kbp segment of a circular 73 kbp DNA from the colourless flagellate Astasia longa. The repeat units are separated by a short region containing a 5S rRNA gene and a gene for tRNA-Val (UAC). Sequence comparisons reveal 78%, 81%, and 67% identical nucleotides of the 23S rDNA (A), the 16S rDNA (B), and the 5S rDNA (A), respectively, with the corresponding genes of the Euglena gracilis chloroplast genome. As in Euglena chloroplasts, the 3-terminal protion of the 23S rDNA is homologous to the 4.5S rRNA gene of higher plant chloroplast genomes. These results are supportive of a common evolutionary origin for the Astasia 73 kbp DNA and the Euglena 145 kbp chloroplast DNA.     

Comparison of the genomes of two sympatric iridescent viruses (types 9 and 16)

Summary A map of the sites in the genome ofCostelytra zealandica iridescent virus (CzIV), using the restriction enzymesBamHI,KpnI, andPstI, showed the genome size to be 170.2 kbp in length. It was found that the genome was cyclically permuted and that 39% of the genome of CzIV contained repetitive sequence elements. The genome was found to hybridize with the genome of another iridescent virus, type 9 (WIV), in DNA-DNA hybridization experiments. A region of the WIV DNA genome (23.4 kbp) did not hybridize with CzIV DNA and this region is similar in size to the total genomic size difference between CzIV and WIV (22.4 kbp). A unique repeat sequence from iridescent virus type 6 (CIV) was shown to be present in the genome of WIV but not that of CzIV. Finally, the positions of the major capsid protein genes, VP53 and VP52, in the restriction enzyme maps for type 16 and type 9 respectively were determined.     

The chloroplast genome of the gymnosperm Pinus contorta: a physical map and a complete collection of overlapping clones

Summary Overlapping restriction fragments of chloroplast DNA from the conifer Pinus contorta were cloned. Out of a total of 49 clones, 33 comprise the minimum set required to represent the entire genome. Using the purified inserts of these clones as probes in filter hybridizations, all sites for the three restriction enzymes KpnI, HapI and SacI in the P. contorta chloroplast genome were mapped. Heterologous filter hybridizations and sequence analysis of some of the P. contorta clones were used to determine the position of 15 genes on the restriction map. The size of the genome, which lacks an inverted repeat organization, was found to be approximately 121 kilobase pairs (kbp). Unusual features of this genome are a duplication of the psbA gene and the presence of two genes, gidA and frxC, which are not found in angiosperms. The genome appeared essentially colinear with that of Pinus radiata, for which a map has previously been published. Two different restriction fragment length polymorphisms were found to be produced by variable numbers of copies of 124 bp-and 150 bp-long, tandemly repeated elements.Communicated by H. Kössel     

Physical mapping of the mitochondrial genome of the cultivated mushroom Agaricus brunnescens (= A. bisporus)

Summary Mitochondrial (mt) DNA from the commercial mushroom Agaricus brunnescens Peck [= A. bisporus (Lange) Imbach] was purified by cesium chloride/bisbenzimide gradient centrifugation. A physical map of the mtDNA fragments produced by BamHI, EcoRl, and PvuII digestion was generated by filter hybridizations with radiolabelled BamHI mtDNA probes. The A. brunnescens mtDNA was a circular molecule 136 kilo-basepairs (kbp) in length and contained an inverted repeat between 4.6 and 9.2 kbp in size. Orientational isomers of the mitochondrial genome were not detected. The positions of six genes were located on the A. brunnescens mtDNA map by heterologous hybridization. No coding function has yet been ascribed to the inverted repeat. The large rRNA gene was located on the smaller single copy region. The genes for cytochrome b, cytochrome oxidase (subunit III), ATPase (subunits 8 and 6) and the small rRNA were located on different regions of the larger single copy region.     

Localization of chloroplast ribosomal protein genes on Spirodela oligorhiza chloroplast DNA

Summary Three chloroplast ribosomal protein genes have been located on Spirodela chloroplast DNA. (1) rps14 was physically mapped at the central region of the large single copy region by heterologous hybridization with the corresponding gene of Marchantia chloroplast DNA. (2) Chloroplast ribosomal protein C-S23 was detected by immunoprecipitation with a polyspecific antiserum against 30S chloroplast ribosomal proteins among the in vitro translation products of mRNAs selected by Spirodela Pstl-D chloroplast DNA fragment. (3) We have previously reported that Spirodela BamHI-G chloroplast DNA fragment encodes a 14–15 kD 50S chloroplast ribosomal protein (Posno et al. 1985 Curr Genet 9 : 211–219). Here we show that the homologous Spinacia chloroplast DNA fragment Sa1I-9 additionally directs the synthesis of another 50S chloroplast ribosomal protein in a DNA dependent E. coli cellfree system. This was confirmed by molecular weight determination, immunoprecipitation and competition immunoprecipitation experiments. mRNA selection experiments revealed that this additional chloroplast ribosomal protein gene is present on Spirodela chloroplast DNA as well, but is not expressed in the E. coli cellfree system. The identity of this 50S chloroplast ribosomal protein could not be established unambiguously, since two-dimensional gel analysis revealed that this protein comigrated, depending on the experiment, with C-L11 (26 kD) or with C-L24 (17 kD).Abbreviations (k) bp (kilo)basepairs - cp chloroplast - IR inverted repeat - kD kilodalton - LSCR large single copy region - Mw molecular weight - r-protein ribosomal protein - RuBPCase ribulose-1,5-bisphosphate carboxylase - SDS sodium dodecyl sulphate - SSCR small single copy region     

Organization of the ribosomal RNA genes in Schistosoma mansoni

The organization of the rRNA genes of Schistosoma mansoni has been determined by Southern blot analysis of genomic DNA digested with restriction enzymes, by isolation of the entire repeat on a single fragment of about 11 kilobase pairs from a genomic DNA library constructed in bacteriophage lambda and by characterization of three cloned EcoRI fragments which span the entire repeat. The segments encoding both the large and small rRNA subunits have been identified using specific cloned yeast rDNA fragments as probes and EcoRI, HindIII and BamHI restriction enzyme maps of the rRNA genes were constructed. The ends of the RNAs have been precisely mapped on the genomic DNA by S1 protection experiments. Our data indicate that the rRNA genes are present as a tight cluster. The total length of the rDNA repeat is about 10 kilobase pairs. There appears to be no variation in the size of transcribed and non-transcribed spacer DNA. At the RNA level we have characterized and mapped a small gap in the 28S RNA molecule. The interruption causes the RNA to dissociate into two equal sized fragments when analyzed under denaturing conditions.     

Entamoeba histolytica ribosomal RNA genes are carried on palindromic circular DNA molecules

Highly abundant DNA fragments obtained after restriction enzyme digests of nuclear DNA of Entamoeba histolytica strain HM-1:IMSS have been cloned and characterized. Northern blot hybridization to E. histolytica rRNA and sequence analysis identified the abundant DNAs as ribosomal DNA containing species. Several overlapping clones containing these abundant DNAs were isolated from 4 different genomic libraries of E. histolytica. Alignment of the restriction maps was consistent with a circular molecule, about 24.6 kilobase pairs (kb) in size. Nuclease BA131 digestion provided additional evidence for the circular nature of this DNA. The ribosomal DNA molecule contains two large inverted repeat-regions, each at least 5.2 kb in length. Sequence analysis of clone R715 revealed homology to the large rRNA units of various eukaryotic organisms. This clone was located in both inverted repeats, suggesting two rRNA cistrons per molecule. The inverted repeats are flanked by stretches of DNA which contain tandemly reiterated sequences. Southern blot analysis of E. histolytica nuclear DNA revealed the presence of two populations of molecules. These molecules have identical arrangements of restriction sites, but differ in size (0.7 kb) in a fragment containing tandemly reiterated sequences. Analysis of E. histolytica nuclear DNA by electron microscopy also revealed circular molecules. These molecules are about 26.6 kb +/- 0.5 kb in size and contain structural features predicted by the restriction map of the extrachromosomal ribosomal DNA of E. histolytica.     

Localization of three chloroplast ribosomal protein genes at the left junction of the large single copy region and the inverted repeat of Spirodela oligorhiza chloroplast DNA

Summary In order to determine the localization of ribosomal protein genes on the chloroplast genome of Spirodela, we have followed two different approaches: First, antisera were prepared against purified 30S, 50S and 70S chloroplast ribosomal proteins from Spinacia. These antisera react with about two third of the chloroplast ribosomal proteins as shown by protein blot and immunoprecipitation experiments. Recombinant plasmids carrying the Spirodela BamHI-G or PstI-I cpDNA fragment both direct the synthesis of a 15 kD chloroplast ribosomal protein in a DNA dependent E. coli cell free system. This was confirmed by molecular weight determination, immunoprecipitation and competition immunoprecipitation experiments. Second, heterologous hybridization with the rps19 gene probe from Nicotiana revealed the localization of this gene on the chloroplast DNA of Spirodela within the BamHI-G fragment at the left junction of the large single copy region and the inverted repeat. Furthermore we show that the recombinant plasmid carrying Nicotiana rps19 also directs the synthesis of another chloroplast ribosomal protein in an E. coli cell free system. The identity of this protein is discussed.Abbreviations Bis-Tris 2,2(Bis(hydroxymethyl)2,2,2 nitrilotriethanol - (k)bp (kilo)base pairs - BPB bromphenol blue - cp chloroplast - IR inverted repeat - kD kilo dalton - LSCR large single copy region - Mw molecular weight - r-protein ribosomal protein - RuBPCase ribulose-1,5-bisphosphate carboxylase - SDS sodiumdodecyl sulphate     

The ribosomal RNA repeats are non-identical and directly oriented in the chloroplast genome of the red alga Porphyra purpurea

A detailed restriction map of the chloroplast genome of the red alga Porphyra purpurea has been constructed. Southern hybridization experiments with cloned or gel-purified restriction fragments and PCR products indicate that the P. purpurea chloroplast genome is approximately 188 kb in size. This circular molecule contains two rRNA-encoding repeats (approximately 4.9 kb) that separate the genome into single-copy regions of 34 kb and 144 kb. Interestingly, these repeats are arranged in a direct orientation. In addition, DNA sequencing of the ends of both repeats revealed that the two rRNA repeats are not identical. No intramolecular recombination between the repeats can be detected. We discuss the possibility that the chloroplast genome of P. purpurea is organized like that of the ancestral chloroplast.     

Presence of a 16S rRNA pseudogene in the bi-molecular plastid genome of the primitive brown alga Pylaiella littoralis. Evolutionary implications

Summary The plastid genome of the brown alga Pylaiella littoralis (L.) Kjellm. is composed of two different circular DNA molecules: the largest carries two rrn operons, and the smallest, only one copy of both 16S and 23S rDNAs. 16S rDNA copies located on both molecules have been cloned and their nucleotide sequences determined: they are 65% homologous to one another. The expression of these genes was assayed by hybridizing in vivo labelled P. littoralis rRNAs to both clones, and specific oligonucleotides to total RNA from P. littoralis. Results indicate that the 16S rDNA copy located on the small molecule is a pseudogene. Comparisons of the functional gene with other 16S rRNA genes shows that chloroplasts from green plants emerged earlier from the cyanobacterial lineage than Euglena gracilis and Pylaiella littoralis plastids.