Concerted evolution of sequence repeats inDrosophila mitochondrial DNA

Summary In the eightDrosophila species of themelanogaster subgroup, the mitochondrial DNA (mtDNA) contains an A+T-rich region in which replication originates. The length of this region, in contrast with that of the coding part of the genome, varies extensively among these species. The A+T-rich region ranges from about 1kbp inD. yakuba, D. teissieri, D. erecta, andD. orena to 5 kbp inD. melanogaster, D. simulans, D. mauritiana, andD. sechellia. The difference in size is due in part to the amplification, in the species with long genomes, of a 470-bp sequence that is present only once in each of the four species with short genomes.Usually three to six repeats of this sequence occur in direct tandem repetition in the species with long genomes. The sequence is characterized by the relative positions of the Hpa I and Acc I cleavage sites. Comparative study of the genomes found in the species with long mtDNA molecules reveals relative homogeneity of the repeat units within a given genome, which contrasts with the variability found among the repeats of different genomes. This result is suggestive of a process of a concerted evolution.The examination of heteroplasmic flies of three species (D. simulans, D. mauritiana, andD. sechellia) has shed light on this process. In most cases the molecular types of mtDNA present in a heteroplasmic individual differ by one repeat unit. Addition or deletion of this sequence appears to be the original mutational event generating transient heteroplasmy. Cycles of addition or deletion may consequently maintain the intragenomic homogeneity of the repeats.Finally, we have analyzed an exceptional isofemale line in which three molecular lengths of mtDNA are found (molecules with four, five, and six repeats, respectively). Individual offspring of this line carry from one to three of the molecular types, in all combinations. This indicates that the remodeling of the mitochondrial genome occurs through a mechanism that is at present unknown, but that is site specific and rather frequent.Presented at the FEBS Symposium on Genome Organization and Evolution, held in Crete, Greece, September 1–5, 1986     

Differential homogenization and amplification of two satellite DNAs in the genus Cucurbita (Cucurbitaceae)

Two different satellite DNAs exist in the genus Cucurbita which are different with respect to repeat length (350 by and 170 bp), array size, and sequence homogenization. Whereas the 350-bp satellite DNA is prominent and very homogeneous in all species investigated except for C. maxima and C. lundelliana, the 170-bp satellite is rather evenly distributed in all species. In C. maxima and C. lundelliana the 350-bp satellite is present only in small amounts, but detectable by the sensitive PCR method. These repeats are also very homogeneous, reflecting a silent stage of satellite DNA. In contrast, the 170-bp satellite DNA is intra- and interspecifically heterogeneous. It is striking that the species with no detectable amount of 350-bp satellite contain 170-bp satellite DNA clusters with the highest degree of homogeneity. The evolution of satellite DNA repeats within cultivated and wild species in the genus Cucurbita is elucidated using the sequence data of both satellite DNAs from all species investigated. The value of satellite DNA for phylogenetic analysis between closely related species is discussed. Correspondence to: V. Hemleben     

Related satellite DNA's in the genus Mus

Several Thailand species from the genus Mus have been shown to contain satellite DNA's able to cross-reassociate with the Mus musculus satellite. One species, Mus caroli, contains at least three discrete but related light satellite DNA's. All the related Mus satellites band on the light side of the major band in neutral CsCl gradients, separate into complementary strands in alkaline CsCl gradients, and have a relatively low affinity for Ag⁺. Three of the Mus satellite DNA's have been purified: taken separately, they show very sharp thermal transitions and reassociate at similar rates to give well-matched duplexes.     

Concerted evolution of satellite DNA in Sarcocapnos: a matter of time

SarkOne is a genus-specific satellite-DNA family, isolated from the genomes of the species of the genus Sarcocapnos. This satellite DNA is composed of repeats with a consensus length of 855 bp and a mean G+C content of 52.5%. We have sequenced a total of 189 SarkOne monomeric repeats belonging to a total of seven species of the genus Sarcocapnos. The comparative analysis of these sequences both at the intraspecific and the interspecific levels have revealed divergence patterns between species are proportional to between-species divergence according to the phylogeny of the genus. Our study demonstrates that the molecular drive leading to the concerted-evolution pattern of this satellite DNA is a time-dependent process by which new mutations are spreading through genomes and populations at a gradual pace. However, time is a limiting factor in the observation of concerted evolution in some pairwise comparisons. Thus, pairwise comparisons of species sharing a recent common ancestor did not reveal nucleotide sites in transitional stages higher than stage III according to the Strachan's model. By contrast, there was a gradation in the percentage of upper transition stages (IV, V, VI) the more phylogenetically distant the species were. In addition, closely related species shared a high number of polymorphic sites, but these types of sites were not common when comparing more distant species. All these data are discussed in the light of current life-cycle models of satellite-DNA evolution.     

Molecular evolution of satellite DNA repeats and speciation of lizards of the genus Darevskia (Sauria: Lacertidae).

Satellite DNA repeats were studied in Caucasian populations of 18 rock lizard species of the genus Darevskia. Four subfamilies (Caucasian Lacerta satellites (CLsat)I-IV) were identified, which shared 70%-75% sequence similarity. The distribution of CLsat subfamilies among the species was studied. All the species could be divided into at least 3 clades, depending on the content of CLsat subfamilies in each genome: "saxicola", "rudis", and "mixta" lizards. CLsatI was found in all studied species, but in very different quantities; the "saxicola" group contained this subfamily predominantly. The "rudis" group also contained CLsatIII, and the "mixta" group carried considerable amounts of CLsatII. The highest concentrations of CLsatI and CLsatII were detected in 2 ground lizards--D. derjugini and D. praticola, respectively. D. parvula predominantly carried CLsatIII. CLsatIV was found only in the Crimean species D. lindholmi. The distribution patterns of satellite subfamilies show possible postglacial speciation within the genus Darevskia. A hybrid origin of species that possess 2 or 3 CLsat subfamilies and important clarifications to the systematics of the genus are proposed.     

Biochemical diversity and evolution in the genus Mus

Thirteen biochemical groups of wild mice from Europe, Asia, and Africa belonging to the genus Mus are analyzed at 22–42 protein loci. Phylogenetic trees are proposed and patterns of biochemical evolution are discussed, as well as the possible contribution of wild mice to the genetic diversity of laboratory stocks.     

Structural organization and evolution of t-complex in Mus genus

Modern data on the structure and evolution of the t complex are discussed. The t complex is a series of inversions in the proximal region of murine chromosome 17; it contains a set of genes that determine its predominant transmission to the offspring of heterozygous males. Variants of structural organization of this genetic system (t haplotypes) have been found in wild populations of four species of genus Mus (M. domesticus, M. musculus, M. molossinus, and M. castaneus), but not in representatives of other, evolutionarily remote species of this genus. The so-called vertical, horizontal, and introgressive hypotheses are discussed of the origin and evolution of the t complex. Based on population genetic studies and molecular analysis a new hypothesis on the origin of the t-complex is put forward. This hypothesis is a synthesis between the vertical and horizontal models and assumes that all known t haplotypes had a common ancestral chromosome 17 carrying a proximal inversion.     

Concerted evolution in protists: Recent homogenization of a polyubiquitin gene in Trichomonas vaginalis

Ubiquitin is a 76-amino-acid protein with a remarkably high degree of conservation between all known sequences. Ubiquitin genes are almost always multicopy in eukaryotes, and often are found as polyubiquitin genes—fused tandem repeats which are coexpressed. Seventeen ubiquitin sequences from the amitochondrial protist Trichomonas vaginalis have been examined here, including an 11-repeat fragment of a polyubiquitin gene. These sequences reveal a number of interesting features that are not seen in other eukaryotes. The predicted amino acid sequences lack several universally conserved residues, and individual units do not always encode identical peptides as is usually the case. On the nucleotide level, these repeats are in general highly variable, but one region in the polyubiquitin is extremely homogeneous, with seven repeats absolutely identical. Such extended stretches of homogeneity have never been observed in ubiquitin genes and since substitutions are common in other coding units, it is likely that these repeats are the product of a very recent homogenization or amplification. Correspondence to: P.J. Keeling     

Sequence and evolution of related bovine and caprine satellite DNAs: Identification of a short DNA sequence potentially involved in satellite DNA amplification

The satellite II DNAs of the domestic ox Bos taurus and sheep Ovis aries have been sequenced, and that of the domestic goat Capra hircus partially sequenced. All three are related, and consist of repeat units of about 700 base-pairs. There is no evidence of internal repetition within these repeat units. When matched for maximum homology, the goat and sheep sequences show 83% homology, whereas the ox and sheep sequences share only 70% homology. Factors contributing to the uncertainty of the exact homology between these sequences are discussed, but the results are nevertheless consistent with their progenitor sequence being present in the common ancestor of cattle and sheep. Goat satellite II DNA is shown to contain another, unrelated, tandemly repeated sequence, which is composed of 22 base-pair repeat units. Both this sequence and a region of ox satellite II share good homology with the 11 base-pair progenitor sequence of ox 1.706 g/cm³ satellite DNA. It is suggested that this shared sequence could play a role in bovine satellite DNA amplification.     

The formation and evolution of centromeric satellite repeats in Saccharum species

Centromeres in eukaryotes are composed of tandem DNAs and retrotransposons. However, centromeric repeats exhibit considerable diversity, even among closely related species, and their origin and evolution are largely unknown. We conducted a genome-wide characterization of the centromeric sequences in sugarcane (Saccharum officinarum). Four centromeric tandem repeat sequences, So1, So103, So137 and So119, were isolated. So1 has a monomeric length of 137 bp, typical of a centromeric satellite, and has evolved four variants. However, these So1 variants had distinct centromere distributions and some were unique to an individual centromere. The distributions of the So1 variants were unexpectedly consistent among the Saccharum species that had different basic chromosome numbers or ploidy levels, thus suggesting evolutionary stability for approximately 7 million years in sugarcane. So103, So137 and So119 had unusually longer monomeric lengths that ranged from 327 to 1371 bp and lacked translational phasing on the CENH3 nucleosomes. Moreover, So103, So137 and So119 seemed to be highly similar to retrotransposons, which suggests that they originated from these mobile elements. Notably, all three repeats were flanked by direct repeats, and formed extrachromosomal circular DNAs (eccDNAs). The presence of circular molecules for these retrotransposon-derived centromeric satellites suggests an eccDNA-mediated centromeric satellite formation pathway in sugarcane.     

Concerted evolution of primate alpha satellite DNA. Evidence for an ancestral sequence shared by gorilla and human X chromosome alpha satellite

To understand evolutionary events in the formation of higher-order repeat units in alpha satellite DNA, we have examined gorilla sequences homologous to human X chromosome alpha satellite. In humans, alpha satellite on the X chromosome is organized as a tandemly repeated, 2.0 x 10(3) base-pairs (bp) higher-order repeat unit, operationally defined by the restriction enzyme BamHI. Each higher-order repeat unit is composed of 12 tandem approximately 171 base-pair monomer units that have been classified into five distinct sequence homology groups. BamHI-digested gorilla genomic DNA hybridized with the cloned human 2 x 10(3) bp X alpha satellite repeat reveals three bands of sizes approximately 3.2 x 10(3), 2.7 x 10(3) and 2 x 10(3) bp. Multiple copies of all three repeat lengths have been isolated and mapped to the centromeric region of the gorilla X chromosome by fluorescence in situ hybridization. Long-range restriction mapping using pulsed-field gel electrophoresis shows that the 2.7 x 10(3) and 3.2 x 10(3) bp repeat arrays exist as separate but likely neighboring arrays on the gorilla X, each ranging in size from approximately 200 x 10(3) to 500 x 10(3) bp, considerably smaller than the approximately 2000 x 10(3) to 4000 x 10(3) bp array found on human X chromosomes. Nucleotide sequence analysis has revealed that monomers within all three gorilla repeat units can be classified into the same five sequence homology groups as monomers located within the higher-order repeat unit on the human X chromosome, suggesting that the formation of the five distinct monomer types predates the divergence of the lineages of contemporary humans and gorillas. The order of 12 monomers within the 2 x 10(3) and 2.7 x 10(3) bp repeat units from the gorilla X chromosome is identical with that of the 2 x 10(3) bp repeat unit from the human X chromosome, suggesting an ancestral linear arrangement and supporting hypotheses about events largely restricted to single chromosome types in the formation of alpha satellite higher-order repeat units.     

Centromeric alpha satellite DNA amplification and translocation in an unusually large chromosome 14p+ variant

Summary We report cytogenetic and molecular studies on a family that carries, in the father, an unusually large chromosome 14p+ variant [WSi-var(14)(p+)] and, in one of his children, a translocation [DSi-der(14)] involving the variant chromosome. Increase in the size of WSi-var(14)(p+) was estimated to be approximately 35% that of a normal chromosome 14. Presence of extra chromosomal material in this variant chromosome was demonstrated by G-banding using trypsin and staining with Leishman, G-banding using bromodeoxyuridine (BrdU) and Giemsa, and R-banding using BrdU and Giemsa. This material was positive using C-banding with BaOH and staining with Giemsa and negative in DAPI/distamycin staining, suggesting that it contained repetitive DNA but probably not of the types found in the heterochromatic regions of chromosomes 1, 9, 15, 16, and Y. Staining of the nucleolus organiser region (NOR) with AgNO₃ indicated the retention of the NOR in WSi-var(14)(p+) but not in DSi-der(14). In situ hybridisation of metaphase cells with an alpha satellite DNA probe specific for human acrocentric chromosomes demonstrated a significantly increased amount of centromeric alpha sequences in WSi-var(14)(p+). Most or all of the extra alpha sequences were retained in DSi-der(14), indicating translocation near the very distal end of the enlarged region. The extra alpha satellite DNA material may have originated through amplification of some centromeric segments. The possible role of the amplified DNA in chromosomal translocations is discussed.     

Concerted evolution,a slow process for ant satellite DNA: study of the satellite DNA in the <Emphasis Type="Italic">Aphaenogaster</Emphasis> genus (Hymenoptera,Formicidae)

A family of satellite DNA is analyzed in seven ant species from the genus Aphaenogaster. This satellite DNA is organized as tandemly repeated sequences with a consensus sequence of 160 bp in length. The sampled sequences show a high similarity and belong to the same family of satellite DNA. However in Aphaenogaster spinosa, two types of repeat clearly differentiated have been found. Phylogenetic analyses using satellite DNA show that sequences do not cluster in a species-specific way, with one exception. Concretely, the second type of repeats of A. spinosa (APSP-II) which constitutes a new satellite DNA subfamily. The obtained results with satellite DNA are compared with those obtained using mitochondrial and nuclear DNA to determine the correlation between evolution of satellite DNA and phylogenetic relationships among the analyzed ants. The high interspecific similarity for the satellite DNA seems not to be in concordance with the concerted evolution pattern, commonly accepted to explain the evolution of satellite DNA. However, the accumulated data suggest that evolution of satellite DNA in ants follows the concerted evolution pattern but that this process is slow in relation with other organisms, probably due to the eusociality and haplodiploidy of these insects.     

Molecular evolution of a Y-chromosomal repetitive sequence family in the genus Mus

A 522-base-long Y-chromosomal sequence was isolated from a BALB/c genomic library and was designated "BF046." It is repeated about 200 times in the male genome, and a difference was detected between the Mus musculus musculus and the M. m. domesticus type Y chromosomes. BF046- related sequences were present over the entire length of the Y chromosome as visualized by in situ hybridization. Southern blot analysis against DNAs isolated from eight species in the genus Mus showed that BF046-related sequences were amplified in the Y chromosomes of three closely related species: M. musculus, M. spicilegus, and M. spretus. To gain insight into the stability of the BF046 sequence family, we isolated 18 additional clones from these three mouse species and compared their sequences. The M. musculus sequences differed from the M. spicilegus and M. spretus sequences by two indels. The remaining parts of the sequences were very similar, but both parsimony and distance-based analytical methods divided the sequences into the same four subgroups, with each species having its own subgroup(s). Thus, the Y chromosomes of M. musculus, M. spicilegus, and M. spretus can be distinguished from one another.      

DNA evolution in the genus Gossypium

Measurements of relative DNA contents in the genus Gossypium reveal more than a two-fold difference between the lowest and the highest values among diploid species with the same chromosome number. An experiment designed to detect intra-specific variation in DNA content is described. Phylogenetic implications, including the origin of amphiploids are discussed briefly.     

Distribution and evolution of two satellite DNAs in the genus Beta

Summary EcoRI monomers of a highly repetitive DNA family of Beta vulgaris have been cloned. Sequence analysis revealed that the repeat length varies between 157–160 bp. The percentage of AT-residues is 62% on average. The basic repeat does not show significant homology to the BamHI sequence family of B. vulgaris that was analyzed by us earlier. Both the EcoRI and BamHI sequences are investigated and compared to each other with respect to their genomic organization in the genus Beta. Both repeats were found to be tandemly arranged in the genome of B. vulgaris in a satellite-like manner. The EcoRI satellite DNA is present in three sections (Beta, Corollinae and Nanae) of the genus, whereas the BamHI satellite DNA exists only in the section Beta. The distribution of the EcoRI and BamHI satellite families in the genus is discussed with respect to their evolution.