Recombination of Chlamydomonas chloroplast DNA occurs more frequently in the large inverted repeat sequence than in the single-copy regions

Summary It is well documented that chloroplast DNA (cpDNA) recombination occurs at a relatively high frequency during sexual reproduction of unicellular green algae from the Chlamydomonas genus. Like the cpDNAs of most land plants, those of Chlamydomonas species are divided into two single-copy regions by a large inverted repeat sequence, part of which encodes the chloroplast rRNA genes. In the present study, we scored the inheritance of polymorphic loci spanning the entire chloroplast genome in hybrids recovered from reciprocal interspecific and F₁ crosses between Chlamydomonas eugametes and C. moewusii, and from these data, estimated the density of recombination junctions within each region of recombinant cpDNAs. Our results indicate that recombination junctions occur at highly variable frequencies across the three main domains of the chloroplast genome. The large inverted repeat sequence was found to exhibit at least a five-fold higher density of recombination junctions compared to one of the singlecopy regions, whereas junctions in the latter region were five-fold more abundant relative to those in the other single-copy region. This marked difference in the densities of recombination junctions implies that the extent of genetic linkage between two given chloroplast loci will depend not only on their physical distance, but also on their locations within the genome.     

Structure and evolution of junctions between inverted repeat and small single copy regions of chloroplast genome in non-core Caryophyllales

The structure of the junction between inverted repeat (IR) and small single copy (SSC) regions of the chloroplast genome in the representatives of non-core Caryophyllales is investigated in this work. It was found that for two families—Polygonaceae and Plumbaginaceae—the extension of inverted region is characteristic. This extension is due to the duplication of the part of the ycf1 gene that is partly located in the small single copy region in plants with typical structure of IR/SSC junctions. Comparison of the position of IR/SSC junctions in different species of Polygonaceae has shown that their exact position is not correlated with the affinity of these species inferred from molecular and morphological data. Possible mechanisms leading to the change in position of IR/SSC junctions observed in this work are discussed.     

Ebb and flow of the chloroplast inverted repeat

The endpoints of the large inverted repeat (IR) of chloroplast DNA in flowering plants differ by small amounts between species. To quantify the extent of this movement and define a possible mechanism for IR expansion, DNA sequences across the IR—large single-copy (IR-LSC) junctions were compared among 13Nicotiana species and other dicots. In mostNicotiana species the IR terminates just upstream of, or somewhere within, the 5 portion of therps19 gene. The truncated copy of this gene,rps19, varies in length even between closely related species but is of constant size within a single species. InNicotiana, six differentrps19 structures were found. A phylogenetic tree ofNicotiana species based on restriction site data shows that the IR has both expanded and contracted during the evolution of this genus. Gene conversion is proposed to account for these small and apparently random IR expansions. A large IR expansion of over 12 kb has occurred inNicotiana acuminata. The new IR-LSC junction in this species lies within intron 1 of theclpP gene. This rearrangement occurred via a double-strand DNA break and recombination between poly (A) tracts inclpP intron 1 and upstream ofrps19. Nicotiana acuminata chloroplast DNA contains a molecular fossil of the IR-LSC junction that existed prior to this dramatic rearrangement.     

Nucleotide substitution rates in legume chloroplast DNA depend on the presence of the inverted repeat

The chloroplast genomes of some species of legumes lack the large inverted repeat (IR) that is a trademark of most land-plant chloroplasts. Our analysis of chloroplast genes in legume species that have an IR shows that the synonymous (silent) substitution rate in IR genes is 2.3-fold lower than in single-copy (SC) genes, which is largely in agreement with earlier findings. Given that all genes in species that lack the IR are single-copy, what level of synonymous substitution exists in these genes? We report a uniform substitution rate in IR-less genomes, and moreover, we find this rate to be at the level otherwise reserved for SC genes. In other words, the synonymous substitution rate has accelerated in the remaining copy of the duplicate region. We propose that this acceleration is a direct result of the decrease in the copy number of the sequence, rather than an intrinsic property of the genes normally located in the IR.     

Chloroplast DNA rearrangements are more frequent when a large inverted repeat sequence is lost

We examined the arrangement of sequences common to seven angiosperm chloroplast genomes. The chloroplast DNAs of spinach, petunia and cucumber are essentially colinear. They share with the corn chloroplast genome a large inversion of approximately 50 kb relative to the genomes of three legumes--mung bean, pea and broad bean. There is one additional rearrangement, a second, smaller inversion within the 50 kb inversion, which is specific to the corn genome. These two changes are the only detectable rearrangements that have occurred during the evolution of the species examined (corn, spinach, petunia, cucumber and mung bean) whose chloroplast genomes contain a large inverted repeat sequence of 22-25 kb. In contrast, we find extensive sequence rearrangements in comparing the pea and broad bean genomes, both of which have deleted one entire segment of the inverted repeat, and also in comparing each of these to the mung bean genome. Thus there is a relatively stable arrangement of sequences in those genomes with the inverted repeat and a much more dynamic arrangement in those that have lost it. We discuss several explanations for this correlation, including the possibility that the inverted repeat may play a direct role in maintaining a conserved arrangement of chloroplast DNA sequences.     

Coordinated expression of clustered cancer/testis genes encoded in a large inverted repeat DNA structure

Cancer/testis antigens (CTA) are expressed in cancers and testis or placenta only and, therefore are considered promising targets for cancer immunotherapy and diagnosis. One family of CTA is the MAGEA family which comprises 13 members and was shown to be expressed synchronously with members from the CSAG (TRAG-3) family of CTA. The MAGEA genes are arranged in 4 subclusters located on the X chromosome. Subcluster III exposes a remarkable gene organization with an inverted repeat (IR) DNA structure of a triplicated couplet of a MAGEA gene and a CSAG gene. Analyzing the mRNA expression pattern of all genes of the MAGEA and CSAG family of cancer/testis genes, we show that the MAGEA and CSAG genes encoded in the large IR are expressed coordinately and independent from the MAGEAs encoded outside the IR. These results reinforce our hypothesis that the large MAGEA/CSAG-IR DNA structure has an impact on the regulation of gene expression.     

Dynamics and evolution of the inverted repeat-large single copy junctions in the chloroplast genomes of monocots

Background  

Various expansions or contractions of inverted repeats (IRs) in chloroplast genomes led to fluxes in the IR-LSC (large single copy) junctions. Previous studies revealed that some monocot IRs contain a trnH-rps19 gene cluster, and it has been speculated that this may be an evidence of a duplication event prior to the divergence of monocot lineages. Therefore, we compared the organizations of genes flanking two IR-LSC junctions in 123 angiosperm representatives to uncover the evolutionary dynamics of IR-LSC junctions in basal angiosperms and monocots.     

Sequence characteristics of a cervid DNA repeat family

The (G + C) distribution and the presence and amounts of repetitive sequence families in the white-tailed deer (Odocoileus virginianus) have been examined. The distribution ranges from 20 to 70% (G + C) and shows four distinct repeat families. A 0.7-kb family, DII, corresponds to satellite II in domestic bovids—ox, sheep, and goat—and was singled out for detailed characterization. DII has a prototypic repeat of 67% (G + C), consists of 25,000 tandem copies, and contributes 1.7% to the genomic DNA. Sequencing and electrophoretic analysis indicate a repeat length of 691 bp. These characteristics are similar to those of the bovid satellite II families as well as to those of other cervids that we have examined. The intraspecific sequence divergence within this family has a variance of only 2.5 ± 0.3%.Present address: ICRP, Room 533, Lincoln's Inn Fields, London WC2A 3PX, England.Correspondence to: R.D. Blake     

Analysis of inverted repeat DNA in the genome of Rhodomicrobium vannielii

The DNA of Rhodomicrobium vannielii was analysed for the presence of inverted repeat sequences (IR DNA) by S1 nuclease digestion. Approximately 7% of chromosomal DNA was found to be IR DNA which comprised two size classes. The large IR DNA was heterogeneous and contained species in the size range 100-700 bp. The smaller size class contained species of 17 and 27 bp. Both size classes of IR DNA hybridized to many chromosomal restriction fragments, suggesting that these IR DNA sequences are dispersed throughout the genome. Hybridization studies also indicated sequence homology between the two classes of IR DNA and suggested that the 17 and 27 bp IR DNA sequences may exist in clusters.     

Zea mays chloroplast ribosomal RNA genes are part of a 22,000 base pair inverted repeat

Zea mays chloroplast rDNA exists in two identical units. Each unit contains one sequence for the 16, 23 and 5S rRNAs in the order given. The 16 and 23S sequences in each unit are separated by a 2100 base pair (bp) spacer. The DNA sequence for 5S RNA is closely linked to that for the 23S RNA. Within the above unit, the three RNAs are transcribed from a single DNA strand. The two rDNA units on the circular chloroplast DNA molecule are separated from each other by 18,500 bp in one direction and by 106,100 bp in the other direction. The two rDNA units have an inverted orientation with respect to each other. Each rDNA unit is part of a 22,000 bp sequence which is repeated with inverted orientation.     

Sequence analysis of Vicia faba repeated DNA, the FokI repeat element

A type of highly repeated DNA sequences present in the genome of Vicia faba was detected by digestion its nuclear DNA with FokI endonuclease and fractionating the digests on polyacrylamide gels. Four fragments of 59, 108, 177 and 246 bp of the FokI repeated sequences were collected from the gels and their primary structures were determined by the method of Maxam and Gilbert. These repeated DNA sequences were shown to be a multiple tandem array of a 59 bp sequence element. And its nucleotide sequence was almost completely conserved among all the sequence members of each the size class and also among these classes. This sequence element consists of a duplet of an about the duplet has an incomplete dyad symmetrical structure.     

Sequence variation of non-coding regions of chloroplast DNA of soybean and related wild species and its implications for the evolution of different chloroplast haplotypes

Soybean chloroplast DNAs (cpDNAs) are classified into three types (I, II and III) based on RFLP profiles. Type I is mainly observed in cultivated soybean (Glycine max), while type II and type III are frequently found in both cultivated and wild soybean (Glycine soja), although type III is predominant in wild soybean. In order to evaluate the diversity of cpDNA and to determine the phylogenetic relationship among different chloroplast types, we sequenced nine non-coding regions of cpDNA for seven cultivated and 12 wild soybean accessions with different cpDNA types. Eleven single-base substitutions and a deletion of five bases were detected in a total of 3849 bases identified. Five mutations distinguished the accessions with types I and II from those with type III, and seven were found in the accessions with type III, independently of their taxa. Four species of the subgenus Glycine shared bases that were identical to those with types I and II at two of the five mutation sites and shared bases that were identical to those with type III at the remaining three sites. Therefore, the different cpDNA types may not have originated monophyletically, but rather may have differentiated from a common ancestor in different evolutionary directions. A neighbor-joining tree resulting from the sequence data revealed that the subgenus Soja connected with Glycine microphylla which formed a distinct clade from Clycine clandestina and the tetraploid cytotypes of Glycine tabacina and Glycine tomentella. Several informative length mutations of 54 to 202 bases, due to insertions or deletions, were also detected among the species of the genus Glycine. Received: 16 December 1999 / Accepted: 12 February 2000     

Interarm interaction of DNA cruciform forming at a short inverted repeat sequence

A novel interarm interaction of DNA cruciform forming at inverted repeat sequence was characterized using an S1 nuclease digestion, permanganate oxidation, and microscopic imaging. An inverted repeat consisting of 17 bp complementary sequences was isolated from the bluegill sunfish Lepomis macrochirus (Perciformes) and subcloned into the pUC19 plasmid, after which the supercoiled recombinant plasmid was subjected to enzymatic and chemical modification. In high salt conditions (200 mM NaCl, or 100-200 mM KCl), S1 nuclease cut supercoiled DNA at the center of palindromic symmetry, suggesting the formation of DNA cruciform. On the other hand, S1 nuclease in the presence of 150 mM NaCl or less cleaved mainly the 3'-half of the repeat, thereby forming an unusual structure in which the 3'-half of the inverted repeat, but not the 5'-half, was retained as an unpaired strand. Permanganate oxidation profiles also supported the presence of single-stranded part in the 3'-half of the inverted repeat in addition to the center of the symmetry. Both electron microscopy and atomic force microscopy have detected a thick protrusion on the supercoiled DNA harboring the inverted repeat. We hypothesize that the cruciform hairpins at conditions favoring triplex formation adopt a parallel side-by-side orientation of the arms allowing the interaction between them supposedly stabilized by hydrogen bonding of base triads.     

Single nucleotide sequence analysis: a cost- and time-effective protocol for the analysis of microsatellite- and indel-rich chloroplast DNA regions

We present a simple method to screen for DNA sequence variation in microsatellite- and indel-rich regions of the chloroplast genome. The single nucleotide sequence (SNS) analysis provides a trade-off between the time- and cost-effective, but less informative and homoplasy-sensitive electrophoretic detection of microsatellite and indel size variation on the one hand, and more costly, but also more accurate methods like DNA sequencing on the other. The principle of the SNS method is to sequence one instead of all four nucleotides of a target region amplified by polymerase chain reaction. By careful selection of the respective nucleotide, almost the same amount of information can be retrieved from these partial sequences as could be from complete sequences; however, only a third to a fourth of the money and time resources are needed.