Analysis of divergence of Alphitobius diaperinus satellite DNA--roles of recombination, replication slippage and gene conversion

Variable Rates of Simple Satellite Gains across the Drosophila Phylogeny

Simple satellites are tandemly repeating short DNA motifs that can span megabases in eukaryotic genomes. Because they can cause genomic instability through nonallelic homologous exchange, they are primarily found in the repressive heterochromatin near centromeres and telomeres where recombination is minimal, and on the Y chromosome, where they accumulate as the chromosome degenerates. Interestingly, the types and abundances of simple satellites often vary dramatically between closely related species, suggesting that they turn over rapidly. However, limited sampling has prevented detailed understanding of their evolutionary dynamics. Here, we characterize simple satellites from whole-genome sequences generated from males and females of nine Drosophila species, spanning 40 Ma of evolution. We show that PCR-free library preparation and postsequencing GC-correction better capture satellite quantities than conventional methods. We find that over half of the 207 simple satellites identified are species-specific, consistent with previous descriptions of their rapid evolution. Based on a maximum parsimony framework, we determined that most interspecific differences are due to lineage-specific gains. Simple satellites gained within a species are typically a single mutation away from abundant existing satellites, suggesting that they likely emerge from existing satellites, especially in the genomes of satellite-rich species. Interestingly, unlike most of the other lineages which experience various degrees of gains, the lineage leading up to the satellite-poor D. pseudoobscura and D. persimilis appears to be recalcitrant to gains, providing a counterpoint to the notion that simple satellites are universally rapidly evolving.

Satellite DNA: An Evolving Topic

Satellite DNA represents one of the most fascinating parts of the repetitive fraction of the eukaryotic genome. Since the discovery of highly repetitive tandem DNA in the 1960s, a lot of literature has extensively covered various topics related to the structure, organization, function, and evolution of such sequences. Today, with the advent of genomic tools, the study of satellite DNA has regained a great interest. Thus, Next-Generation Sequencing (NGS), together with high-throughput in silico analysis of the information contained in NGS reads, has revolutionized the analysis of the repetitive fraction of the eukaryotic genomes. The whole of the historical and current approaches to the topic gives us a broad view of the function and evolution of satellite DNA and its role in chromosomal evolution. Currently, we have extensive information on the molecular, chromosomal, biological, and population factors that affect the evolutionary fate of satellite DNA, knowledge that gives rise to a series of hypotheses that get on well with each other about the origin, spreading, and evolution of satellite DNA. In this paper, I review these hypotheses from a methodological, conceptual, and historical perspective and frame them in the context of chromosomal organization and evolution.

Satellite-DNA diversification and the evolution of major lineages in Cardueae (Carduoideae Asteraceae)

In a previous work, we characterized the HinfI satellite DNA family in the subtribe Centaureinae (Cardueae) demonstrating that a "library" of eight HinfI subfamilies would exist in the common ancestor of all Centaureinae, which were differentially amplified in different lineages. Now, we extend our study by analyzing a total of 219 additional repeats from fifteen species belonging to Carlininae, Echinopsinae and Carduinae, and comparing them to those of Centaureinae. Most HinfI sequences belonged to the subfamily II, although a few sequences of other subfamilies were detected in some species. Additionally, a new subfamily characteristic of several Carduinae species was discovered. Although phylogenetic trees grouped sequences by subfamily affinity instead of species provenance, when comparing repeats of the same subfamily, the degree of divergence between any pair of sequences was related to the evolutionary distance between the species compared in most cases. Exceptions were in comparisons between sequences of some Centaureinae species, and between sequences of some Carduinae species and those of Centaureinae. Our results demonstrate that: (1) At least nine HinfI subfamilies would exist in the common ancestor of Cardueae, each one differentially amplified in different lineages; (2) After differential spreading, sequences of each subfamily evolved concertedly through molecular drive, resulting in the gradual divergence of repeats between different species; (3) The rate to which concerted evolution occurred was different between lineages according to the evolutionary history of each one.

Genomic organization and evolution of the 5S ribosomal DNA in the ancient fish sturgeon

Ribosomal DNA in sturgeon is informative when analyzed at the molecular level because it bears unique characteristics that are, to a certain extent, ancestral within vertebrates. In this paper, we examine the structure and the molecular evolution of the 5S ribosomal DNA (rDNA) region in 13 sturgeon species, comparing both the 5S ribosomal RNA (rRNA) genes and the non-transcribed spacer (NTS) sequences between the coding regions. We have found that different NTS and 5S gene variants are intermixed in the 5S rDNA arrays of the different sturgeon species and that all variants are ancestral, having been maintained over many millions of years. Using predictive models, we have found similar levels of sequence diversity in the coding regions, as well as in the non-coding region, but fixed interspecific differences are underrepresented for 5S genes. However, contrary to the expectations, we have not found fixed differences between NTS sequences when comparing many pairs of species. Specifically, when they belong to the same phylogeographic clade of the four into which the sturgeon is divided, but fixation of mutations and divergence is found between species belonging to different phylogeographic clades. Our results suggest that the evolution of the two parts of the 5S rDNA region cannot be explained exclusively as the outcome of a balance between mutational, homogenizing (i.e., gene conversion as a predominant force in sturgeon), and selective forces. Rather, they suggest that other factors (i.e., hybridization) might be superimposed over those forces and thus could to some extent be masking their effects.

New satellite DNA in Lacerta s. str. lizards (Sauria: Lacertidae): evolutionary pathways and phylogenetic impact

A new tandemly repeated (satellite) DNA family namely Agi160, from Lacerta agilis and Lacerta strigata (Lacerta sensu stricto (s. str.), Linnaeus 1758) have been cloned and sequenced. Agi160 is found in the above two species, as well as two other representatives of the same genus, L. viridis and L. media. DNA hybridization did not reveal it in Darevskia, Podarcis, Zootoca, Eremias, Ophisops, and Gallotia - the other genera of the family Lacertidae. The results suggest that Agi160 is a Lacerta s. str. specific family of tandem DNA repeats. However, a comparison between sequences of Agi160 and CLsat repeat units revealed 60 bp regions 62-74% identical. The latter is a satellite DNA family typical for Darevskia (syn. "L. saxicola complex") (Grechko et al., Molecular-genetic classification and phylogenetic relatedness of some species of Lacertidae lizards by taxonoprint data. Mol Biol 32:172-183, 1988.). Both Agi160 and CLsat tandem repeats share several common features (e.g., the same AT content and distribution of multiple short A-T runs, internal structure of repeated units, the presence of conservative regions). These data are indicative of their common origin and a possibly strong selective pressure upon conserving both satellites. A comparative analysis of structure, organization, and abundance of these two families of satDNA reveals evolutionary pathways that led to their formation and divergence. The data are consistent with the hypotheses of the concerted evolution of satellite DNA families. The possibility of use of Agi160 as a phylogenetic tool, defining relationships within Lacerta s. str., as well as within the whole family of Lacertidae is discussed.

Uniform distribution of satellite DNA variants on the chromosomes of tenebrionid species Alphitobius diaperinus and Tenebrio molitor

The chromosomes of tenebrionid species Alphitobius diaperinus contain large blocks of pericentromerically located constitutive heterochromatin, as revealed by C-banding procedure. As previously reported, satellite DNA of this species is composed of two related monomeric units organized in three satellite subfamilies. In order to analyze the chromosomal location of the satellite DNA and the distribution of monomeric variants within it, and compare it with the distribution of monomer variants in Tenebrio molitor satellite DNA, the methods of in situ hybridization and restriction enzyme/nick translation were performed. Fluorescent in situ hybridization with the entire satellite DNA reveals the pericentromerically located signals on all chromosomes of the complement, coinciding with heterochromatic blocks. Results of fluorescent in situ hybridization with particular monomeric variants and of in situ restriction enzyme/nick translation show that monomeric variants are homogeneously dispersed within the entire satellite DNA. The spreading of satellite monomeric variants of the related species T. molitor within the pericentromeric heterochromatin of the entire complement, is demonstrated using the method of in situ restriction enzyme/nick translation. Although the complexity of organization of satellite DNAs is quite distinct in these two species, obtained results suggest similar efficiency of mechanisms of spreading and homogenization resulting in random chromosomal distribution of their satellite variants.

Evolutionary dynamics of satellite DNA family PIM357 in species of the genus Pimelia (Tenebrionidae, Coleoptera)

A large number of repeats of a satellite DNA (stDNA) family have been cloned and sequenced from species and populations of the genus Pimelia (Tenebrionidae, Coleoptera). The beetles were collected in the Canary Islands, Morocco, the Iberian Peninsula, and the Balearic Islands in order to analyze the evolutionary forces and processes acting on abundant stDNAs conserved at the genus level. This repetitive family is composed of an abundant A-T-rich stDNA, with basic units of 357 bp. All the sequences obtained showed similarity to the 22 repeat units of the PIM357 stDNA family described previously for six Iberian Pimelia species (Pons et al. 1997 ). An analysis based on similarity shows the presence of three different groups of sequences clearly in accordance with their geographical origin. One is composed of satellite sequences from Iberian and Balearic species, a second group from the Moroccan taxa, whereas the third one is from the Pimelia species endemic to the Canary Islands. The latter group shows higher nucleotide diversities for their stDNA sequences and a lack of relationship between transition stages to fixation and sequence divergence. Phylogeographic data of Canarian Pimelia show that the PIM357 stDNA family has persisted for more than 8 Myr and could probably be traced to the origin of the lineage. The data suggest that distinct demographic and phylogenetic patterns related to the colonization of the volcanic Canarian island chain account for particular evolutionary dynamics of the repeat DNA family in this group.

Characterization of a complex satellite DNA in the mollusc Donax trunculus: analysis of sequence variations and divergence

A highly repetitive sequence in the genomic DNA of the bivalve mollusc Donax trunculus (Dt) has been identified upon restriction with EcoRV. During the time-course of DNA digestion, genomic fragments resolved electrophoretically into a ladder-like banding pattern revealing a tandem arrangement of the repeated elements, thus representing satellite DNA sequences. Cloning and sequence analysis unraveled the presence of two groups of monomer units which can be considered distinctive satellite subfamilies. Each subclass is distinguishable by the presence of 17 evenly spread diagnostic nucleotides (nt). The respective consensus sequences are 155 bp in length and differ by 11%, while relevant internal substructures were not observed. The two satellite subfamilies constitute 0.23 and 0.09% of the Dt genome, corresponding to 20 000 and 7600 copies per haploid complement, respectively. Sequence mutations often appear to be shared between two or more monomer variants, indicating a high degree of homogenization as opposed to that of random mutational events. Shared mutations among variants appear either as single changes or in long stretches. This pattern may arise from gene conversion mechanisms acting at different levels, such as the spread of nt sequences of a similar length to the monomer repeat itself, and the diffusion of short tracts a few bp long. Subfamilies might have evolved from the occasional amplification and spreading of a monomer variant effected by gene conversion events.

Characterization of two abundant satellite DNAs from the mealworm Tenebrio obscurus

Two highly abundant satellite DNAs comprise 36% of the Tenebrio obscurus (Tenebrionidae, Coleoptera) genome. They are designated as satellite I and satellite II with the monomer length of 344 and 142 base pairs (bp), respectively. Both satellites differ in their nucleotide (nt) sequences, but the frequency of point mutations, well-conserved length of monomer variants, stretches of shared mutations characteristic for the process of gene conversion, and distribution of both satellites in regions of centromeric heterochromatin of all chromosomes indicate that the same evolutionary processes act on both of them with the same, or similar, rate. While satellite I shares no sequence similarity with any other known nt sequence, satellite II is 79.7% homologous with the highly abundant satellite from closely related Tenebrio molitor. Difference in the frequency of point mutations and absence of shared mutations indicating gene conversion strongly suggest that in these two closely related species mutational processes affecting satellite DNAs seem to be changed. Retarded electrophoretic mobility, due to sequence-induced curvature of DNA helix axis, was observed for T. obscurus satellite II, but not for satellite I. Although evolutionary processes act with different rates in T. obscurus and T. molitor satellites the monomer length and sequence-induced curvature are well preserved in both 142-bp satellites, as well as in, at the nt sequence level completely divergent, Palorus ratzeburgii (Tenebrionidae) satellite, indicating potential importance of these parameters in their evolution.