Comparative analysis of the mitochondrial genomes of Chlamydomonas eugametos and Chlamydomonas moewusii

Summary We report the cloning and physical mapping of the mitochondrial genome of Chlamydomonas eugametos together with a comparison of the overall sequence structure of this DNA with the mitochondrial genome of Chlamydomonas moewusii, its closely related and interfertile relative. The C. eugametos mitochondrial DNA (mtDNA) has a 24 kb circular map and is thus 2 kb larger than the 22 kb circular mitochondrial genome of C. moewusii. Restriction mapping and heterologous fragment hybridization experiments indicate that the C. eugametos and C. moewusii mtDNAs are colinear. Nine cross-hybridizing restriction fragments common to the C. eugametos and C. moewusii mtDNAs, and spanning the entirety of these genomes, show length differences between homologous fragments which vary from 0.1 to 2.3 kb. A 600 bp subfragment of C. moewusii mtDNA, within one of these conserved fragments, showed no hybridization with the C. eugametos mtDNA. Of the 73 restriction sites identified in the C. eugametos and C. moewusii mtDNAs, five are specific to C. moewusii, eight are specific to C. eugametos and 30 are common to both species. Hybridization experiments with gene probes derived from protein-coding and ribosomal RNA-coding regions of wheat and Chlamydomonas reinhardtii mtDNAs support the view that the small and large subunit ribosomal RNA-coding regions of the C. eugametos and C. moewusii mtDNAs are interrupted and interspersed with each other and with protein-coding regions, as are the ribosomal RNA-coding regions of C. reinhardtii mtDNA; however, the specific arrangement of these coding elements in the C. eugametos and C. moewusii mtDNAs appears different from that of C. reinhardtii mtDNA.     

The endpoints of an inversion in wheat chloroplast DNA are associated with short repeated sequences containing homology toatt-lambda

Summary The physical mapping of Aval, BstEII and EcoR1 restriction sites on the chloroplast genome of the green alga Chlamydomonas eugametos is presented. The circular map, with a size of 243 kilobase pairs, is the largest yet reported for a chloroplast genome. It features a large inverted repeat sequence, part of which encodes the 16S and 23S ribosomal RNAs (rRNAs), the large subunit of ribulose-1,5-bisphosphate carboxylase-oxygenase (rbcL) and the 32-kdodalton thylakoid membrane protein (psbA). Such an rRNA-encoding inverted repeat sequence is also found in the chloroplast genomes of Chlamydomonas reinhardtii and most land plants. These genomes, however, differ from that of C. eugametos by the absence of the rbcL gene from the inverted repeat sequence of C. reinhardtii and by the absence of both the rbcL and psbA genes from the inverted repeat sequence of land plants. Possible evolutionary implications of these differences are discussed.Abbrevations cpDNA chloroplast DNA - kbp kilobase pairs - psbA 32 kilodalton thylakoid membrane protein gene - rbcL ribulose-1,5-bisphosphate carboxylase-oxygenase large subunit gene - rRNA ribosomal RNA     

Extensive sequence rearrangements in the chloroplast genomes of the green algaeChlamydomonas eugametos andChlamydomonas reinhardtii

Summary We have compared the overall sequence organization of chloroplast DNA (cpDNA) from the unicellular green algaeChlamydomonas eugametos andChlamydomonas reinhardtii. Cloned restriction fragments whose locations are known on the chloroplast genome of one or the other alga were hybridized to Southern blots of cpDNA digests from both algae and the positions of hybridization signals were used to align the two algal cpDNA restriction maps. In agreement with the important biological differences reported betweenC. eugametos andC. reinhardtii, we found extensive sequence rearrangements and low overall sequence homology between the two cpDNAs. To explain the striking contrast between our results and the remarkable conservation reported for the sequence and the organization of angiosperm cpDNAs containing inverted repeats, we suggest that the divergence between theC. eugametos andC. reinhardtii chloroplast genomes simply reflects a longer time of separate evolution relative to the angiosperm lineages. However, we cannot exclude the possibility that the algal cpDNAs rearranged faster than angiosperm cpDNAs.     

Inheritance of mitochondrial and chloroplast genome markers in backcrosses of Chlamydomonas eugametos x Chlamydomonas moewusii hybrids

Summary Southern blot analysis of AvaI-digested total cellular DNA from the interfertile species Chlamydomonas eugametos and Chlamydomonas moewusii with a coxI mitochondrial gene probe from Chlamydomonas reinhardtii revealed single hybridizing fragments of 5.0 and 3.5 kb, respectively. The transmission of these mitochondrial DNA physical markers along with that of chloroplast genetic markers for resistance to streptomycin and resistance to erythromycin was studied in the fourth backcrosses of F₁ hybrids to one or the other parent. Viability in these backcrosses is high in contrast to the cross C. eugametos x C. moewusii and its reciprocal which are associated with considerable meiotic product lethality. The resulting zygospores were found to transmit the mitochondrial and chloroplast genome markers uniparentally or preferentially from the mating-type-plus parent. Thus the species pair C. eugametos and C. moewusii differs from the pair Chlamydomonas reinhardtii and Chlamydomonas smithii in which mitochondrial genome markers are transmitted uniparentally by the mating-type minus parent, while the chloroplast genome markers are transmitted uniparentally by the opposite parental mating-type (Boynton et al. 1987).     

Characterization of chloroplast DNA in Chlamydomonas eugametos and C. moewusii and its inheritance in hybrid progeny

Summary The density, molecular weight, and cellular repetition of DNA molecules associated with the -DNA satellite of the interfertile algae Chlamydomonas eugametos and C. moewusii are reported. The similarities between these values and those for the chloroplast DNA (cpDNA) in the related alga Chlamydomonas reinhardtii indicate that these satellites represent cpDNA. The buoyant densities of C. eugametos and C. moewusii cpDNAs are indistinguishable from one another, as are those of their respective nuclear DNAs. These densities differ slightly from the densities of the homologous components of C. reinhardtii whole cell DNA. All three species differ with respect to additional minor satellite DNAs and low molecular weight DNAs of unknown cellular location.Differences in the Aval and Smal restriction endonuclease fragmentation patterns of C. eugametos and C. moewusii cpDNAs were employed to study the inheritance of cpDNA in an F1 hybrid which had inherited a non-Mendelian streptomycin resistance marker (sr-2) from the C. eugametos mating-type plus (mt ⁺) parent and in two homoplasmic mitotic segregants from a B 1 hybrid (F₁ × C. moewusii) which had been initially heteroplasmic for the resistance marker. Although the cpDNA patterns in the F1 hybrid were similar to those of the C. eugametos ml ¹ parent, important differences were noted which suggest that recombination between C. eugametos and C. moewusii cpDNA had occurred. Homoplasmic streptomycin resistant and sensitive mitotic segregants recovered from the B1 hybrid product reveal Aval restriction patterns similar to those of the respective resistant and sensitive parents. These data are consistent with the hypothesis that the sr-2 marker is located in cpDNA and that C. eugametos and C. moewusii cpDNA sequences can coexist in the same chloroplast and, at least sometimes, segregate without extensive recombination. The transmission of low molecular weight DNAs characteristic of C. moewusii but of unknown cellular origin shows no direct correlation with the transmission of the sr-2 marker.     

Uniparental inheritance of chloroplast DNA sequences in interspecific hybrids of Chlamydomonas

Summary The meiotic transmission of chloroplast DNA (cpDNA) was studied in crosses between two species of Chlamydomonas (C. moewusii and C. eugametos) which have substantial differences in cpDNA restriction patterns. The results provide a direct demonstration that cpDNA can be inherited in a uniparental pattern, paralleling the transmission of a uniparentally inherited antibiotic resistance marker. Thus, cpDNA could carry the uniparental genes of these species, but other extrachromosomal DNAs are not excluded as possible carriers. For example, C. moewusii was found to contain a set of low molecular weight (LMW) DNA species which cannot be detected in C. eugametos. These LMW DNA species are also transmitted uniparentally in the tetrads studied. Uniparentai transmission may not be an exclusive property of cpDNA in Chlamydomonas species.     

Physical evidence for recombination of chloroplast dna in hybrid progeny of Chlamydomonas eugametos and C. moewusii

Summary Differences in the restriction endonuclease fragmentation patterns of chloroplast DNA (cpDNA) from C. eugametos and C. moewusii have been used to study the inheritance of these DNAs in interspecific hybrids. Analysis of the cpDNAs from ten randomly selected F₁ hybrids, in each case revealed cpDNA to be recombinant for AvaI and BstEII restriction sites, although fragments characteristic of C. eugametos, the mt+ parent, were typically found in excess of those for C. moewusii, the mt– parent. In backcrosses between an F ₁ mt+ hybrid and C. moewusii mt–, seven randomly selected B₁ hybrids showed cpDNA restriction patterns either identical to or highly similar to that of the mt+ parent. We propose that cpDNA molecules are predominantly transmitted by the mt+ parent in both F₁ and B₁ generations but that selection favors survival of F₁ progeny with recombinant chloroplast genomes which avoid interspecific incompatibilities. On the surface, the inheritance of recombinant cpDNA contrasts with the simultaneous uniparental inheritance of two putative chloroplast markers (sr-2 and er-nM1 ⁺). However, it may be that these two markers are by chance associated with cpDNA sequences of the mt+ parent which were selected in all F₁ hybrids.     

An optional group I intron between the chloroplast small subunit rRNA genes of Chlamydomonas moewusii and C. eugametos

Summary We report the presence of a 402 by group I intron in the chloroplast small subunit (SSU) rRNA gene of Chlamydomonas moewusii. The intron is inserted within the highly conserved 530 loop, at a site corresponding to positions 531–532 of the E. coli 16rRNA. Residues surrounding the insertion site almost certainly play an important role in ribosomal proofreading function as they proved to be protected by tRNAs in E. coli 16S rRNA (Moazed and Noller 1986; Stern et al. 1986). The C. moewusii intron revealed a secondary structure model which differs substantially from those of the typical subgroup IA and IB introns. This model, however, shows striking similarities with the structures of the C. reinhardtii chloroplast 23S rRNA gene intron (Rochaix et al. 1985), the S. cerevisiae mitochondrial COB3 intron (Holl et al. 1985) and the three introns of phage T4 in the nrdB, td and sunY genes (Shub et al. 1988). The SSU rRNA gene intron is absent from C. eugametos, an alga that is interfertile with C. moewusii. The presence/absence of the intron account for a 390 by restriction fragment length polymorphism between the two algal SSU rRNA genes, a polymorphic locus that is strictly co-inherited with a tightly linked streptomycin resistance mutation (sr-2) in interspecific hybrids between the two algae.     

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     

A group I intron in the chloroplast large subunit rRNA gene of Chlamydomonas eugametos encodes a double-strand endonuclease that cleaves the homing site of this intron

Summary During interspecific crosses between Chlamydomonas eugametos and Chlamydomonas moewusii, an optional group I intron of 955 base pairs (CeLSU· 5) in the C. eugametos chloroplast large subunit rRNA gene undergoes a duplicative transposition event which is associated with frequent co-conversion of flanking cpDNA sequences. In the present study, we show that the basic protein of 218 amino acids encoded by CeLSU· 5 could mediate the phenomenon of intron transposition, also called intron homing. We overexpressed the ORF specifying this protein in E. coli using expression vectors that contain a C. moewusii cpDNA sequence encompassing the intron homing site. The expression product was found to exhibit a double-strand DNA endonuclease activity that is specific for the homing site. This activity was detected in vivo by self-linearization of the expression plasmids.     

Structural evolution and flip-flop recombination of chloroplast DNA in the fern genus Osmunda

Summary The evolution and recombination of chloroplast genome structure in the fern genus Osmunda were studied by comparative restriction site mapping and filter hybridization of chloroplast DNAs (cpDNAs) from three species — 0. cinnamomea, 0. claytoniana and 0. regalis. The three 144 kb circular genomes were found to be colinear in organization, indicating that no major inversions or transpositions had occurred during the approximately 70 million years since their radiation from a common ancestor. Although overall size and sequence arrangement are highly conserved in the three genomes, they differ by an extensive series of small deletions and insertions, ranging in size from 50 bp to 350 by and scattered more or less at random throughout the circular chromosomes. All three chloroplast genomes contain a large inverted repeat of approximately 10 kb in size. However, hybridizations using cloned fragments from the 0. cinnamomea and 0. regalis genomes revealed the absence of any dispersed repeats in at least 50% of the genome. Analysis with restriction enzymes that fail to cleave the 10 kb inverted repeat indicated that each of the three fern chloroplast genomes exists as an equimolar population of two isomeric circles differing only in the relative orientation of their two single copy regions. These two inversion isomers are inferred to result from high frequency intramolecular recombination between paired inverted repeat segments. In all aspects of their general organization, recombinational heterogeneity, and extent of structural rearrangement and length mutation, these fern chloroplast genomes resemble very closely the chloroplast genomes of most angiosperms.     

Recombination within the inverted repeat sequences of the Chlamydomonas reinhardii chloroplast genome produces two orientation isomers

Summary Two orientations of the Chlamydomonas reinhardii chloroplast (ct) genome are shown to be produced by recombination within the inverted repeat (IR) sequences that separate the two single copy (SC) regions. SC region 1 is bounded on its two ends by EeoRI restriction endonuclease fragments of 3.2 and 4.7 kilobase pairs (kb) (Rochaix 1978). The 3.2 kb EeoRI fragment overlaps a 51.3 kb BglII fragment spanning one of the 19.7 kb IR sequences, and the 4.7 kb EcoRI fragment overlaps a 42.1 kb BglII fragment spanning the other 19.7 kb IR sequence. We have shown by hybridization analysis that the 3.2 kb fragment also overlaps a BgIII fragment with a predicted size of 52.3 kb, and that the 4.7 kb fragment also overlaps a BglII fragment of a predicted size of 41.1 kb. The second set of BglII fragments are isomers produced by recombination localized to the IR region. The two isomers are present in approximately equimolar ratio. Knowledge of the isomeric composition of the C. reinhardii ctDNA is essential for establishing a correlation between genetic and physical maps of the ct genome.     

Organisation of the chloroplast genome of kiwifruit (Actinidia deliciosa)

Summary A restriction map of the chloroplast genome has been determined for kiwifruit, Actinidia deliciosa. Single and multiple enzyme digests of kiwifruit chloroplast DNA were hybridised to a set of Brassica chloroplast probes, and the kiwifruit bands aligned with the known Brassica map. The chloroplast DNA of kiwifruit is typical of the majority of angiosperm chloroplast genomes; it is 160 kb in size, contains a 15–34 kb inverted repeat, and its gene content and gene order are similar to those of the Brassica chloroplast genome.     

Optional elements in the chloroplast DNAs of Chlamydomonas eugametos and C. moewusii: unidirectional gene conversion and co-conversion of adjacent markers in high-viability crossses

Unlike most polymorphic markers in the Chlamydomonas eugametos and Chlamydomonas moewusii chloroplast DNAs (cpDNAs), the C. moewusii 6- and 21-kb extra sequences and the C. eugametos-specific CeLSU ⋅ 5 intron are transmitted to all of the few viable progeny in reciprocal crosses between the two green algae. To determine whether this unidirectional transmission pattern is due to gene conversion or to selection for F1 hybrid survival, we followed the inheritance of the parental alleles at the loci featuring these three deletions/additions and at several other polymorphic cpDNA loci in zygospore clones derived from high-viability crosses. The great majority of the zygospore clones examined inherited exclusively the long alleles from the mt ^– parent at the loci containing the three optional cpDNA elements, but as expected, they preferentially inherited the markers from the mt ⁺ parent at most other loci. Our results therefore indicate that all three optional cpDNA sequences propagate themselves very efficiently by gene conversion in crosses between strains differing by the presence of these elements. The co-conversion tracts associated with these sequences are longer (>3 kb) than those previously reported for mobile elements spreading by gene conversion. Our results also revealed that less efficient gene conversion events occurred at two other cpDNA loci. Received: 12 February / 14 May 1996     

Chloroplast DNA from lettuce and Barnadesia (Asteraceae): structure,gene localization,and characterization of a large inversion

Summary We have cloned into plasmids 17 of 18 lettuce chloroplast DNA SacI fragments covering 96% of the genome. The cloned fragments were used to construct cleavage maps for 10 restriction enzymes for the chloroplast genomes of lettuce (Lactuca sativa) and Barnadesia caryophylla, two distantly related species in the sunflower family (Asteraceae). Both genomes are approximately 151 kb in size and contain a 25 kb inverted repeat. We also mapped the position and orientation of 37 chloroplast DNA genes. The mapping studies reveal that chloroplast DNAs of lettuce and Barnadesia differ by a 22 kb inversion in the large single copy region. Barnadesia has retained the primitive land plant genome arrangement, while the inversion has occurred in a lettuce lineage. The endpoints of the derived lettuce inversion were located by comparison to the well-characterized spinach and tobacco genomes. Both endpoints are located in intergenic spacers within tRNA gene clusters; one cluster being located downstream from the atpA gene and the other upstream from the psbD gene. The endpoint near the atpA gene is very close to one endpoint of a 20 kb inversion in wheat (Howe et al. 1983; Quigley and Weil 1985). Comparison of the restriction site maps gives an estimated sequence divergence of 3.7% for the lettuce and Barnadesia genomes. This value is relatively low compared to previous estimates for other angiosperm groups, suggesting a high degree of sequence conservation in the Asteraceae.     

Expansion of the IR in the chloroplast genomes of buckwheat species is due to incorporation of an SSC sequence that could be mediated by an inversion

The chloroplast genomes in buckwheat species contain large inverted repeats which are at least 4 kbp longer than the majority of those in land plants. The length of the buckwheat inverted repeats was attributable to an additional region located adjacent to the borders of the small single-copy region. We have cloned and sequenced a 5.2-kbp SmaI fragment corresponding to this extra region in the inverted repeats. A homology search revealed that the sequence of the SmaI fragment is highly homologous to one side of the small single-copy region of the inverted repeats in dicot chloroplast DNAs such as tobacco and beechdrops. Interestingly, a 3.7-kbp segment in the middle of the SmaI fragment is inserted in the opposite orientation relative to those of the other dicot species, and 17-bp direct repeats are found located at both the ends of the additional region. These results suggest that expansion of the inverted repeats in buckwheat chloroplast DNA might have been associated with an inversion. Received: 6 May / 1 November 1996     

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.     

Identification and mapping of origins of DNA replication within the DNA sequences of the genome of insect iridescent virus type 6

The origins of DNA replication of the genome (209 kbp) of Chilo iridescent virus (CIV), which is circularly permuted and terminally redundant, were identified. The defined genomic library of CIV, which represents 100% of DNA sequences of the viral genome (e.g., all 32EcoRI CIV DNA fragments), was used for transfection ofChoristoneura fumiferana insect cell cultures (CF-124) that were previously infected with CIV. The plasmid rescue experiments were carried out to select those recombinant plasmids that were amplified during viral replication in CIV-infected cell cultures. It was found that six recombinant plasmids harboring theEcoRI DNA fragments C [13.5 kbp, 0.909-0.974 map units (m.u.)], H (9.8 kbp, 0.535–0.582 m.u.), M (7.25 kbp, 0.310–0.345 m.u.), O (6.5 kbp, 0.196–0.228 m.u.), Q (5.9 kbp, 0.603–0.631 m.u.), and Y (2.0 kbp, 0.381–0.391 m.u.) were able to be amplified under the conditions used. This indicates that the CIV genome possesses six DNA replication origins. Subclones of theEcoRI CIV DNA fragments C and H were screened under the same conditions. It was found that DNA sequences within theEcoRI DNA fragments C and H at the genome coordinates 0.924–0.930 and 0.535–0.548, respectively, contain origins of viral DNA replication. The DNA nucleotide sequences of theEcoRI CIV DNA fragment Y (1986 bp) were determined for identifying the DNA sequence of the corresponding origin of DNA replication. The computer-aided analysis revealed the presence of a 15-mer inverted repeat at nucleotide positions 661–675 and 677–691 (661-TAAATTTAATGAGAA-G-TTCTCATTAAATTTA-692). The analysis of the DNA sequence of theEcoRI DNA fragment H corresponding to the particular region at the genome coordinates 0.535–0.548 (1) showed that this region contains a 16-mer inverted repeat at the nucleotide positions 1315 and 1332 (1315-TAAATTTTAATGGTTA-A-TAACCATTAAAATTTA-1347), which is very similar to the inverted repetition found within theEcoRI DNA fragment Y. The successful recognition and amplification of the single-stranded synthetic DNA sequences of both strands of CIV-ori-Y (nucleotide position 661–691) using phage M13 system in CIV-infected cells is strong evidence that the CIV-ori-Y is bidirectionally active, and this DNA sequence is considered to be the origin of DNA replication within theEcoRI CIV DNA fragment Y.     

Characterization of a large inversion in the spinach chloroplast genome relative to Marchantia: a possible transposon-mediated origin

Summary A 7,022 by BamHI-EcoRI fragment, located in the inverted repeat of spinach chloroplast, has been sequenced. It contains a 2131 codon open reading frame (ORF) homologous to both tobacco ORFs 581 and 1708, and to Marchantia ORF 2136. Relative to the Marchantia chloroplast genome, spinach ORF 2131 is located at the end of a large inversion; the other end point is close to trnL, the position of which is the same in Marchantia, tobacco and spinach. In Marchantia, two 8 by direct repeats flanking two 10 by indirect repeats are present near the end points of the inversion. These repeats may result from a transposon-mediated insertion which would have facilitated the subsequent inversion. From a comparison of the gene organization of the spinach, tobacco, and Marchantia genomes in this region, we propose a step-wise process to explain the expansion of the inverted repeat from a Marchantia-like genome to the spinach/tobacco genome.     

The Euglena gracilis chloroplast genome: structural features of a DNA region possibly carrying the single origin of DNA replication

Summary We sequenced a Bg1II-HindIII DNA fragment of the Euglena gracilis chloroplast genome which most likely carries the single origin of DNA replication according to recent electronmicroscopic mapping studies (Koller and Delius 1982a; Ravel-Chapuis et al. 1982). This DNA fragment contains a polymorphic region (Schlunegger et al. 1983) which is composed, as will be shown, of multiple tandem repeats (54 bp, 87% A+T). Furthermore we located on this DNA fragment a short inverted repeat element (96 positions) observed in the electronmicroscopic studies (Koller and Delius 1982b). Between the borders of the polymorphic region and the nearby inverted repeat (distance of 179 positions) we retrieved an exact copy of parts of the rDNA leader (105 positions) including 49 positions of the chloroplast trnW gene. A computer search for bacterial type Ori-regions did not reveal any significant sequence homology. However, the polymorphic region and its immediate vicinity have the capacity to form multiple stem and loop structures which may be involved in DNA replication initiation.