Highly repeated DNA sequences in birds: The structure and evolution of an abundant, tandemly repeated 190-bp DNA fragment in parrots

Department of Immunology and Medical Microbiology, University of Florida, Gainesville 32610.
Genomics (Impact Factor: 2.28). 10/1992; 14(2):462-9. DOI: 10.1016/S0888-7543(05)80242-3
Source: PubMed


Up to 6.8% of the parrot (Psittaciformes) genome consists of a tandemly repeated, 190-bp sequence (P1) located in the centromere of many if not all chromosomes. Monomer repeats from 10 different psittacine species representing four subfamilies were isolated and cloned. The intraspecific sequence variation ranged from 1.5 to 7%. The interspecific sequence variation ranged from less than 3% between two species of cockatoos to approximately 45% between cockatoos and other parrots. The monomer sequences of all 10 parrot species contained several conserved (> 90%) sequence elements at identical locations within the repeat. A comparison with tandemly repeated DNA sequences in other avian species showed that several of these conserved elements were also present at similar locations within the 184-bp repeat of the Chilean flamingo (Phoenicopterus chilensis), suggesting a great antiquity of the repeat. One of the elements was also found in the tandemly repeated sequences of the crane (Gruidae) and falcon (Falconidae) families. The data were used for the construction of a partial most parsimonious relationship that supports a regional subdivision of the Psittaciformes.

5 Reads
  • [Show abstract] [Hide abstract]
    ABSTRACT: The approximately 190-bp centromeric repeat monomers of the spur-winged lapwing (Vanellus spinosus, Charadriidae), the Chilean flamingo (Phoenicopterus chilensis, Phoenicopteridae), the sarus crane (Grus antigone, Gruidae), parrots (Psittacidae), waterfowl (Anatidae), and the merlin (Falco columbarius, Falconidae) contain elements that are interspecifically highly variable, as well as elements (trinucleotides and higher order oligonucleotides) that are highly conserved in sequence and relative location within the repeat. Such conservation suggests that the centromeric repeats of these avian species have evolved from a common ancestral sequence that may date from very early stages of avian radiation.
    Genome 07/1994; 37(3):351-5. DOI:10.1139/g94-050 · 1.42 Impact Factor
  • Source
    [Show abstract] [Hide abstract]
    ABSTRACT: A large fraction, sometimes the largest fraction, of a eukaryotic genome consists of repeated DNA sequences. Copy numbers range from several thousand to millions per diploid genome. All classes of repetitive DNA sequences examined to date exhibit apparently general, but little studied, patterns of "concerted evolution." Historically, concerted evolution has been defined as the nonindependent evolution of repetitive DNA sequences, resulting in a sequence similarity of repeating units that is greater within than among species. This intraspecific homogenization of repetitive sequence arrays is said to take place via the poorly understood mechanisms of "molecular drive." The evolutionary population dynamics of molecular drive remains largely unstudied in natural populations, and thus the potential significance of these evolutionary dynamics for population differentiation is unknown. This review attempts to demonstrate the potential importance of the mechanisms responsible for concerted evolution in the differentiation of populations. It contends that any natural grouping that is characterized by reproductive isolation and limited gene flow is capable of exhibiting concerted evolution of repetitive DNA arrays. Such effects are known to occur in protein and RNA-coding repetitive sequences, as well as in so-called "junk DNA," and thus have important implications for the differentiation and discrimination of natural populations.
    The Quarterly Review of Biology 10/1995; 70(3):297-320. DOI:10.1086/419073 · 4.89 Impact Factor
  • [Show abstract] [Hide abstract]
    ABSTRACT: A highly repeated DNA sequence composed of closely related subunits that ranged from 171 to 176 base pairs has been cloned and characterized in the king vulture (Sarcoramphus papa). Related sequences were also isolated in the black vulture (Coragyps atratus). This new family of avian repetitive DNA elements is here termed the "HaeIII family." Genomic DNAs from a number of avian species were probed with one of the king vulture restriction fragments. In the cathartids, the hybridization patterns showed no individual or sexual variations. A strong HaeIII ladder was present in the two aforementioned species as well as in the Andean condor (Vultur gryphus), but in the black vulture the bands of the ladder alternated in intensity. Weaker hybridization signals were obtained in two ciconids, the jabiru stork (Jabiru mycteria) and the white stork (Ciconia ciconia). The HaeIII repeat was not detected in accipitrid birds of prey, a Polyborinae falconid, pelecanids, and psittacids.
    Genome 03/1996; 39(1):31-9. DOI:10.1139/g96-005 · 1.42 Impact Factor
Show more