Unexpectedly slow homogenisation within a repetitive DNA family shared between two subspecies of tsetse fly

W-enriched satellite sequence in the Indian meal moth, Plodia interpunctella (Lepidoptera, Pyralidae)

The W chromosome of most lepidopteran species represents the largest heterochromatin entity in the female genome. Although satellite DNA is a typical component of constitutive heterochromatin, there are only a few known satellite DNAs (satDNAs) located on the W chromosome in moths and butterflies. In this study, we isolated and characterized new satDNA (PiSAT1) from microdissected W chromosomes of the Indian meal moth, Plodia interpunctella. Even though the PiSAT1 is mainly localized near the female-specific segment of the W chromosome, short arrays of this satDNA also occur on autosomes and/or the Z chromosome. Probably due to the predominant location in the non-recombining part of the genome, PiSAT1 exhibits a relatively large nucleotide variability in its monomers. However, at least a part of all predicted functional motifs is located in conserved regions. Moreover, we detected polyadenylated transcripts of PiSAT1 in all developmental stages and in both sexes (female and male larvae, pupae and adults). Our results suggest a potential structural and functional role of PiSAT1 in the P. interpunctella genome, which is consistent with accumulating evidence for the important role of satDNAs in eukaryotic genomes.

Molecular evolution of ubiquitin genes

Ubiquitin is a singular protein with multiple functions. It is probably the most slowly evolving protein known, is encoded by genes with a unique structure, and provides an intriguing case study for various aspects of molecular evolution. In particular, the multiple ubiquitin-coding repeats which have been characterized in man, yeast and a slime mould graphically illustrate the dynamics of concerted evolution, but cast doubts on the effectiveness of this process for unlinked arrays in this repeat family.

Characterization of a novel satellite DNA sequence from Flying Dragon (Poncirus trifoliata)

Repetitive sequences constitute a significant component of most eukaryotic genomes, and the isolation and characterization of repetitive DNA sequences provide an insight into the organization of the genome of interest. Here, we report the isolation and the molecular analysis and methylation status of a novel tandemly organized repetitive DNA sequence from the genome of Poncirus trifoliata. Digestion of P. trifoliata DNA with Afa I produced a prominent fragment of approximately 400 bp. Southern blotting analysis of genomic DNA digested with the same enzyme revealed a ladder composed of DNA fragments that are multimers of the 400-bp Afa I band, indicating that the repetitive DNA is arrayed in tandem. This suggests that Afa I isolated a novel satellite that we have called Poncirus trifoliata satellite DNA 400 (PN400). This satellite composes 25% of the genome and it is also present in lemon, sour orange and kumquat. Analysis of the methylation status demonstrated that the cytosines in CCGG sequences in this satellite were methylated.

Genetic variation in tsetse flies and implications for trypanosomiasis

The role of tsetse flies in the transmission of trypanosomes has been known for nearly 100 years, their economic and public health impact justifying much of the research. About 20 years ago, no genetic variants of tsetses were known but the discovery of six visible mutants and the application o f protein electrophoretic techniques have changed the situation. During the intervening years many techniques have been developed to study the biology of the approximately 30 known species and subspecies of Glossina. Here, Ron Gooding summarizes recent developments in the estimation o f genetic variation in tsetse populations and speculates on the implications of this variation to population structure, vectorial capacity and disease control strategies.

Evolution of satellite DNAs in a radiation of endemic Hawaiian spiders: does concerted evolution of highly repetitive sequences reflect evolutionary history?

Satellite DNAs are known for an unusual and nonuniform evolution characterized by rapid evolutionary change between species and concerted evolution leading to molecular homogeneity within species. In this paper we use satellite DNAs for phylogenetic analysis of a rapidly evolving lineage of spiders and compare the phylogeny with a hypothesis previously generated based on mitochondrial DNA and allozymes. The spiders examined include almost all species within a monophyletic clade of endemic Hawaiian Tetragnatha species, the spiny-leg clade. The phylogeny based on satellite sequences is largely congruent to those produced by mtDNA and allozymes, except that the satellite DNA yields much longer branches, with higher levels of support for any given node. Closely related species that have differentiated ecologically within an island are well resolved with satellite DNA but much less so with mtDNA. These results suggest that Tetragnatha stDNA repeats seem to be evolving gradually and cohesively during the diversification of these endemic Hawaiian spiders. The study also reveals gain-loss of satellite DNA copies during species diversification. We conclude that satellite DNA sequences may potentially be very useful for resolving relationships between rapidly evolving taxa within an adaptive radiation. In addition, satellite DNA as a nuclear marker suggests that hybridization or peripatry could play a possible role in species formation that cannot be revealed by mitochondrial markers due to its maternal inheritance.

Common origin of the satellite DNAs of the Hawaiian spiders of the genus Tetragnatha: evolutionary constraints on the length and nucleotide composition of the repeats

The present study characterizes the satellite DNA sequences of three endemic Hawaiian spiders, Tetragnatha acuta, Tetragnatha hawaiensis, and Tetragnatha quasimodo, to test the degree of conservation of these sequences within a closely related group of arthropods. The length and nucleotide composition of repeats of the three species is very similar both at intra- and inter-specific level. However, their nucleotide sequence is very divergent at the inter-specific level although conserve substantial similarity in some stretches. These results suggest a common origin of the Tetragnatha satellite DNAs and evolutionary constraint in the length and the nucleotide composition of these repeats at the inter-specific level but not in their nucleotide sequences. At the intra-specific level, the three species show a different degree of sequence identity between repeats as a result of specific historical processes. Tetragnatha hawaiensis shows a strong homogenization of the monomeric sequences. Tetragnatha quasimodo also shows strong homogenization but the actual repeats are higher-order repeats (dimers linking two divergent subfamilies of monomers). On the other hand, the existence of the three subfamilies of repeats in T. acuta, showing divergent sequence identity, both within and between subfamilies, suggests low homogenization of the repeats. Finally, evidence of gene conversion or unequal sister chromatid exchange events in T. quasimodo and T. acuta suggests that recombination is involved in the spreading and homogenization of stDNA sequences.

Polymerase chain reaction amplification of the Bag320 satellite family reveals the ancestral library and past gene conversion events in Bacillus rossius (Insecta Phasmatodea)

Polymerase chain reaction amplifications of genomic DNA in 17 individuals of bisexual and parthenogenetic populations of three subspecies of Bacillus rossius (Insecta Phasmatodea) revealed that the species still harbours the whole variability of the ancestral Bag320 satellite family, since monomers of all non-hybrid Bacillus taxa plus private sequences occur in it. Bag320 monomers had not been rescued as a major satellite component in B. rossius, but possibly represent the remnant of a set of diverging sequences present in the Bacillus ancestor. Following the library hypothesis, these monomer variants have been differently amplified along the evolutionary pathways leading to present taxa in agreement with the mitochondrial phylogeny of the genus. The putative converted tracts observed are explained as the results of past gene conversion events.

Higher-order organization and compartmentalization of satellite DNA PIM357 in species of the coleopteran genus Pimelia

The PIM357 satellite DNA family is present in 26 Pimelia taxa (Tenebrionidae, Coleoptera) with endemic congeneric species from the Canary Islands showing higher interrepeat variability than continental ones. In this paper, we compare the repetitive DNA sequences of a Canarian species that has distinct subfamilies of repeat units, P. radula ascendens, with another without such subfamilies, P. sparsa sparsa. The chromosomal localization of the repeat units and the comparison of the variability of randomly cloned monomers to the one estimated by comparing repeat units from dimers and trimers suggest the absence of satellite subfamilies in P. sparsa sparsa. Hence, the repeat units of this species seem to be uniformly and randomly distributed throughout all chromosomes out of one chromosomal pair. On the contrary, P. radula ascendens shows four divergent subfamilies of repeat units supported by several diagnostic nucleotide substitutions. These subfamilies seem to form four distinct repeat units: monomer subfamily 1, monomer subfamily 4 and two higher-order units (dimer linking subfamily 1 and 4, and dimer linking subfamily 2 and 3). Moreover, monomers of subfamily 1 are present in three chromosomal pairs only. We discuss the effect of different potential factors acting in the concerted evolution and the genomic organization of stDNA sequences in these taxa.

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.

Molecular characterization of a strain-specific repeated DNA sequence in the fall armyworm Spodoptera frugiperda (Lepidoptera: Noctuidae)

The fall armyworm moth, Spodoptera frugiperda, is a migratory species composed of sympatric corn and rice strains. The strains are indistinguishable in morphology but can be recognized by molecular markers. We have cloned and characterized seven monomer units of a repeated DNA sequence, called FR, which is found exclusively in the genome of the rice strain individuals. The 189 bp FR units are tandemly organized in arrays longer than 30 kb. Female individuals possess over 100-fold more of the FR sequence than male individuals. The repeated sequence is not methylated at GGCC sites, and shows high sequence similarity among repeat units.

Evidence for random distribution of sequence variants in Tenebrio molitor satellite DNA

Tenebrio molitor satellite DNA has been analysed in order to study sequential organization of tandemly repeated monomers, i.e. to see whether different monomer variants are distributed randomly over the whole satellite, or clustered locally. Analysed sequence variants are products of single base substitutions in a consensus satellite sequence, producing additional restriction sites. The ladder of satellite multimers obtained after digestion with restriction enzymes was compared with theoretical calculations and revealed the distribution pattern of particular monomer variants within the satellite. A defined higher order repeating structure, indicating the existence of satellite subfamilies, could not be observed. Our results show that some sequence variants are very abundant, being present in nearly 50% of the monomers, while others are very rare (0-1% of monomers). However, the distribution of either very frequent, or very rare sequence variants in T. molitor satellite DNA is always random. Monomer variants are randomly distributed in the total satellite DNA and thus spread across all chromosomes, indicating a relatively high rate of sequence homogenization among different chromosomes. Such a distribution of monomer variants represents a transient stage in the process of sequence homogenization, indicating the high rate of spreading in comparison with the rate of sequence variant amplification.

CR1 - a dispersed repeated element associated with the Cab-1 locus in tomato

Cab-1 is a complex genetic locus in tomato consisting of four clustered genes encoding chlorophyll a/b-binding polypeptide. Southern blot analysis of total tomato DNA with genomic clones corresponding to the Cab-1 locus has revealed the presence of a repetitive element in the 3 kb spacer regions between two of these genes. This repetitive element, named CR1, has been characterized via sequencing, genetic mapping and hybridization to related solanaceous species. Results indicate that there are as many as 30 copies of this element in the tomato genome and that most, if not all, are found at independent loci. Sites corresponding to 12 of the repeats have been located on different regions of chromosomes 2, 4, 5, 7, 10 and 11. A 1.6 kb PstI-EcoRI fragment from the Cab-1 locus containing the element was sequenced and found to be 75% AT-rich. No open reading frames larger than 150 bp were detected. Several imperfect inverted repeats flanked by direct repeats could be found at the ends of the element. This arrangement is reminiscent of known transposons. Southern hybridization analysis indicates that multiple copies of CR1 exist in all species of the genus Lycopersicon as well as in Solanum lycopersicoides and S. tuberosum (potato), but not in eggplant, pepper, petunia, Datura or tobacco. Melt-off experiments indicate that members of the CR1 family in the tomato genome are more closely related to one another than to homologous members in the genomes of S. lycopersicoides or S. tuberosum, suggesting some type of concerted evolution.

A novel arrangement of sequence elements surrounding the rDNA promoter and its spacer duplications in tsetse species

Variation in organization and sequence of the rDNA of six species of tsetse fly (Glossina) has been investigated. Several novel tsetse-specific features have been uncovered. Like many other species the spacer is composed of subrepeats, which in some species contain duplications of the true promoter at the spacer-ETS boundary. In tsetse, however, the first 90 base-pairs of the external transcribed spacer (ETS) (that is, +1 to +90 after transcription initiation) is the 3' end of the last subrepeat. The absence of a "unique" region between the last subrepeat and the ETS suggests that the tsetse rDNA unit may consist of multiple true promoters, that is there is no single ETS boundary. Furthermore, interspecific comparisons show that the 90 base-pair region is part of a conserved 202 base-pair region, consisting of 72 base-pairs upstream from the initiation site and a further 40 base-pairs downstream, which is shared by all promoters other than the last. In genera other than tsetse, subrepeat lengths between species are generally similar; in tsetse they differ due to (1) variation in copy-number of the subsubrepeat motif A9T6CAG, and (2) the presence of large regions flanked by direct simple repeats such as GA5 or TGGTCTC. Slippage-like mechanisms are probably responsible for (1), and recombination and subsequent excision involving the direct repeats for (2). Different structural and sequence variants are seen to be homogenized in the family and fixed in each species, reflecting continual unequal crossing-over. However, notwithstanding this process of differentiation, the available comparisons also reveal that there are two small conserved regions between Glossina and Drosophila: one is part of the promoter and the other is an ETS processing site. Such intergeneric and interspecific differences are discussed in relation to the problem of the maintenance of several essential functions within the rDNA repeating unit despite the continual differentiation of the unit into novel arrangements.

Tsetse fly rDNA: an analysis of structure and sequence

A genomic library of Glossina morsitans morsitans (tsetse fly) has been constructed in the phage vector EMBL 4 and a complete rDNA unit isolated by using a D. melanogaster rDNA clone as a probe. The overall organisation is typical of higher eukaryotes, including an intergenic spacer consisting of a subrepeating structure. Atypically, however, the 45S precursor RNA promoter was shown to lie within the last subrepeat by S1 mapping; i.e. the last subrepeat extends 90 bp into the ETS. The sequence of the spacer subrepeats, the ETS and the first 151 nucleotides of the 18S gene was determined. Comparisons with the corresponding regions of other higher eukaryotes, including insects shows that the ETS has completely diverged, raising questions concerning their functional significance and evolutionary retention; depending on the method of alignment, only two short regions of reasonable homology are shared with Drosophila species: a stretch of nucleotides around the transcription initiation site, and AACATA at the NTS-18S gene junction; and the functionally important G at -16, conserved in all other examined species, is displaced no matter what method of alignment is used. These and other features reflect continual processes of change in the rDNA family to which the several functions of the repeating unit need to adjust.