The ubiquity of satellite DNA (satDNA) sequences has raised much controversy over the abundance of divergent monomer variants and the long-time nucleotide sequence stability observed for many satDNA families. In this work, we describe the satDNA BIV160, characterized in nine species of the three main bivalve clades (Protobranchia, Pteriomorphia and Heteroconchia). BIV160 monomers are similar in repeat size and nucleotide sequence to satDNAs described earlier in oysters and in the clam Donax trunculus. The broad distribution of BIV160 satDNA indicates that similar variants existed in the ancestral bivalve species that lived about 540 million years ago; this makes BIV160 the most ancient satDNA described so far. In the species examined, monomer variants are distributed in quite a complex pattern. This pattern includes (i) species characterized by a specific group of variants, (ii) species that share distinct group(s) of variants and (iii) species with both specific and shared types. The evolutionary scenario suggested by these data reconciles sequence uniformity in homogenization-maintained satDNA arrays with the genomic richness of divergent monomer variants formed by diversification of the same ancestral satDNA sequence. Diversified repeats can continue to evolve in a non-concerted manner and behave as independent amplification-contraction units in the framework of a 'library of satDNA variants' representing a permanent source of monomers that can be amplified into novel homogeneous satDNA arrays. On the whole, diversification of satDNA monomers and copy number fluctuations provide a highly dynamic genomic environment able to form and displace satDNA sequence variants rapidly in evolution.
We characterized the DTF2 satellite DNA family of the clam Donaxtrunculus and compared its chromosomal localization with cytogenetic data revealed by fluorochrome banding, C-banding, and 28S rDNA FISH. In contrast to the other satellites detected previously in this species, DTF2 is an abundant (2%) GC-rich satellite that exhibits CpG methylation. Sequence characteristics of DTF2 indicate that its evolution is not affected by constraints that might indicate some functional interactions. Fluorescence in situ hybridization revealed subtelomeric location of this satellite on a subset of 14 out of 19 D. trunculus chromosome pairs. The chromomycin A3 (CMA) staining of GC-rich regions on D. trunculus chromosomes revealed a complex banding pattern that overlaps completely with C-bands. In total, only three bands show subtelomeric location, while 13 bands are located interstitially, one of them being coincident with the 28S rDNA hybridization signal. No bands, either CMA positive (GC-rich) or DAPI positive (AT-rich) were detected at centromeric chromosomal positions. Only two of the CMA-positive bands co-localize with the DTF2 satellite, showing a) the presence of small islands of GC-rich repetitive sequences that remained undetected by CMA/C-banding and b) the abundance of DTF2-divergent GC-rich sequences at interstitial chromosomal locations.
Cytogenetic deletions are almost always associated with phenotypic abnormality and are very rarely transmitted. We have located a hitherto undescribed, familial deletion involving the region 11q14.3→q21 in five individuals in a three-generation kindred. Four of the deletion carriers show no phenotypic abnormality; the other, who is the proband, was investigated for short stature and poor academic progress. In view of the apparent innocuous nature of this genetic imbalance, the deletion was investigated in detail to determine its size (3.6 Mb) and location with reference to molecular markers and genetic content. The deleted region is described by a contig of 37 BACS including the flanking regions, which we have assembled. Several possible contributory factors are considered, which might explain the lack of clinical significance of this large deletion. It is notable that there are few genes in this region and none have known functions. All most likely have copies elsewhere in the genome and a number of other hypothetical genes appear to be members of certain gene families, i.e. none is unique. Part of the region (1 Mb) is also duplicated at the pericentromeric region 11p11. Given the very low proportion of the genome occupied by single copy genes and their uneven distribution, regions such as this, which appear to be functionally haplosufficient, may be more common than hitherto recognised.
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