Brankica Mravinac

Centromere identity from the DNA point of view

The centromere is a chromosomal locus responsible for the faithful segregation of genetic material during cell division. It has become evident that centromeres can be established literally on any DNA sequence, and the possible synergy between DNA sequences and the most prominent centromere identifiers, protein components, and epigenetic marks remains uncertain. However, some evolutionary preferences seem to exist, and long-term established centromeres are frequently formed on long arrays of satellite DNAs and/or transposable elements. Recent progress in understanding functional centromere sequences is based largely on the high-resolution DNA mapping of sequences that interact with the centromere-specific histone H3 variant, the most reliable marker of active centromeres. In addition, sequence assembly and mapping of large repetitive centromeric regions, as well as comparative genome analyses offer insight into their complex organization and evolution. The rapidly advancing field of transcription in centromere regions highlights the functional importance of centromeric transcripts. Here, we comprehensively review the current state of knowledge on the composition and functionality of DNA sequences underlying active centromeres and discuss their contribution to the functioning of different centromere types in higher eukaryotes.

Sequence of PRAT Satellite DNA "Frozen" in Some Coleopteran Species

Abstract. The intriguing diversity of highly abundant satellite repeats found even among closely related species can result from processes leading to dramatic changes in copy number of a particular sequence in the genome and not from rapid accumulation of mutations. To test this hypothesis, we investigated the distribution of the PRAT satellite DNA family, a highly abundant major satellite in the coleopteran species Palorus ratzeburgii, in eight species belonging to the related genera (Tribolium, Tenebrio, Latheticus), the subfamily (Pimeliinae), and the family (Chrysomelidae). Dot blot analysis and PCR assay followed by Southern hybridization revealed that the PRAT satellite, in the form of low-copy number repeats, was present in all tested species. The PRAT satellite detected in the species Pimelia elevata has been sequenced, and compared with previously cloned PRAT monomers from Palorus ratzeburgii and Palorus subdepressus. Although the two Palorus species diverged at least 7 Myr ago, and the subfamily Pimeliinae separated from the genus Palorus 50–60 Myr ago, all PRAT clones exhibit high mutual homology, with average variability relative to the common consensus sequence of 1.3%. The presence of ancestral mutations found in PRAT clones from all three species as well as the absence of species diagnostic mutations illustrate extremely slow sequence evolution. This unexpectedly high conservation of PRAT satellite DNA sequence might be induced by a small bias of turnover mechanisms favoring the ancestral sequence in the process of molecular drive.

Preservation and High Sequence Conservation of Satellite DNAs Suggest Functional Constraints

Due to a high evolutionary turnover many satellite DNAs are restricted to a group of closely related species. Here we demonstrate that the satellite DNA family PSUB, abundant in the beetle Palorus subdepressus, is distributed in a low number of copies among diverse taxa of Coleoptera (Insecta), some of them separated for an evolutionary period of up to 60 Myr. Comparison of PSUB cloned from the species Tribolium brevicornis with the PSUB family previously characterized in Palorussubdepressus revealed high sequence conservation and absence of fixed species-specific mutations. The most polymorphic sites are those with ancestral mutations shared among clones of both species. Since the ancestral mutations contribute significantly to overall diversity, it could be proposed that a similar mutational profile already existed in an ancestral species. The pattern of variability along the satellite monomer is characterized by the presence of conserved and variable regions. The nonrandom pattern of variability as well as the absence of sequence divergence is also discerned for PRAT satellite DNA, cloned previously from two Palorus species and a distantly related Pimelia elevata. Since PRAT and PSUB are present in parallel in diverse taxa of Coleoptera, we propose that their long evolutionary preservation suggests a possible functional significance. This indication is additionally supported not only by the high evolutionary conservation of the sequences, but also by the presence of significantly conserved and variable regions along the monomers.

TCAGG, an alternative telomeric sequence in insects.

The TTAGG repeat, the only determined telomerase-dependent sequence in the Insecta, is generally reputed to be the canonical telomeric motif within the class. By studying the distribution of telomeric DNAs in 30 coleopteran beetles using Southern hybridization, BAL 31 DNA end-degradation assay and fluorescence in situ hybridization, we showed that arrays built of a TCAGG repeat substitute for (TTAGG)n sequences in all tested species within the superfamily Tenebrionoidea. We also provided the experimental evidence that (TCAGG)n repeats represent the terminal sequences on all chromosomes of the model species Tribolium castaneum. (TCAGG)n repeats are therefore promoted as the first sequence-motif alternative to TTAGG-type chromosome ends in insects. Detection of species negative for both TTAGG and TCAGG reveals that, although widespread, these motifs are not ubiquitous telomeric sequences within the order Coleoptera. In addition, Timarcha balearica proved to be a species that harbors (TTAGG)n repeats, but not at telomeric positions, thus further increasing the complexity of telomeric DNAs. Our experiments discarded CTAGG, CTGGG, TTGGG, and TTAGGG variants as potential replacements in TTAGG/TCAGG-negative species, indicating that chromosome termini of these beetles comprise other form(s) of telomeric sequences and telomere maintenance mechanisms.

Parallelism in Evolution of Highly Repetitive DNAs in Sibling Species

Characterization of heterochromatin in the flour beetle Tribolium audax revealed two highly repetitive DNA families, named TAUD1 and TAUD2, which together constitute almost 60% of the whole genome. Both families originated from a common ancestral approximately 110-bp repeating unit. Tandem arrangement of these elements in TAUD1 is typical for satellite DNAs, whereas TAUD2 represents a dispersed family based on 1412-bp complex higher-order repeats composed of inversely oriented approximately 110 bp units. Comparison with repetitive DNAs in the sibling species Tribolium madens showed similarities in nucleotide sequence and length of basic repeating units and also revealed structural and organizational parallelism in tandem and dispersed families assembled from these elements. In both Tribolium species, one tandem and one dispersed family build equivalent distribution patterns in the pericentromeric heterochromatin of all chromosomes including supernumeraries. Differences in the nucleotide sequence and in the complexity of higher-order structures between families of the same type suggest a scenario according to which rearranged variants of the corresponding ancestral families were formed and distributed in genomes during or after the speciation event, following the same principles independently in each descendant species. We assume that random effects of sequence dynamics should be constrained by organizational and structural features of repeating units and possible requirements for spatial distribution of particular sequence elements. An interspersed pattern of repetitive families also points to the intensive recombination events in heterochromatin. Synergy between the meiotic bouquet stage and satellite DNA sequence dynamics could make a positive feedback loop that promotes the observed genome-wide distribution. At the same time, considering the abundance of these DNAs in heterochromatin spanning the (peri)centromeric chromosomal segments, we speculate that diverged repetitive sequences might represent the DNA basis of reproductive barrier between the two sibling species.

Long inversely oriented subunits form a complex monomer of Tribolium brevicornis satellite DNA.

Highly abundant satellite DNA named TBREV is detected and characterized in the beetle Triboliumbrevicornis (Insecta: Coleoptera). An outstanding peculiarity of the TBREV satellite monomer is its complex structure based on the two ∼470-bp-long subunits, inversely oriented within a 1061-bp-long monomer sequence. The proposed evolutionary history demonstrates a clear trend toward increased complexity and length of the TBREV satellite monomer. This tendency has been observed on three levels: first as direct and inverted duplications of short sequence motifs, then by inverse duplication of the ∼470-bp sequence segment, and, finally, by spread of inversely duplicated elements in a higher-order register and formation of extant monomers. Inversely oriented subunits share a similarity of 82% and have a high capacity to form a thermodynamically stable dyad structure that is, to our knowledge, the longest ever described in any satellite monomer. Analysis of divergences between inversely oriented subunits shows a tendency to a further reduction in similarity between them. Except in its centromeric localization, the TBREV satellite does not show similarity to other known Tribolium satellites, either in nucleotide sequence or in monomer length and complexity. However, TBREV shares common features of other Tribolium satellites that might be under functional constraints: nonconstant rate of evolution along the monomer sequence, short inverted repeats in the vicinity of an A+T tract, nonrandom distribution of A or T ≥3 tracts, and CENP-B box-like motifs. Although long inverted subunits might reinforce structural characteristics of the satellite monomer, their nucleotide sequence does not seem to be under constraints in order to preserve the dyad structure.

Methylation profile of a satellite DNA constituting the intercalary G+C-rich heterochromatin of the cut trough shell Spisula subtruncata (Bivalvia, Mactridae)

Tandemly repeated DNAs usually constitute significant portions of eukaryotic genomes. In bivalves, however, repetitive DNAs are habitually not widespread. In our search for abundant repetitive DNAs in trough shells, we discovered a novel satellite DNA, SSUsat, which constitutes at least 1.3% of the genome of Spisula subtruncata. As foreseen by the satellite DNA library hypothesis, we confirmed that this satellite DNA is also present in two other Mactridae species, showing a highly conserved nucleotide sequence together with a dramatic diminution in the number of repeats. Predominantly located at the G + C-rich intercalary heterochromatin of S. subtruncata, SSUsat displays several DNA methylation peculiarities. The level of methylation of SSUsat is high (3.38%) in comparison with bivalve standards and triplicates the mean of the S. subtruncata genome (1.13%). Methylation affects not only the cytosines in CpG dinucleotides but also those in CHH and CHG trinucleotides, a feature common in plants but scarce and without any clear known relevance in animals. SSUsat segments enriched in methylated cytosines partly overlap those showing higher sequence conservation. The presence of a chromosome pair showing an accumulation of markedly under-methylated SSUsat monomers additionally indicates that the methylation processes that shape repetitive genome compartments are quite complex.