Nature of the heterogeneity in mispairing of reannealed middle-repetitive fern DNA

Renaturation rate studies of a single family of interspersed repeated sequences in human deoxyribonucleic acid

We have investigated the renaturation kinetics of a single family of cloned interspersed repeated sequences isolated from human DNA. Cross-renaturation studies of individual cloned sequences reveal heterogeneity in both the renaturation rate and the thermal stability of heteroduplexes formed from members of this family of sequences. However, cloned members of this family all renature with approximately the same number of copies in the human genome, demonstrating that they are a single family of sequences by the criterion of DNA renaturation kinetics. When a single cloned member of the family is renatured with total human DNA as a function of temperature, the thermal stability of the renatured heteroduplexes is found to be independent of the renaturation temperature over the range 25 degrees C below to 4 degrees C above the melting temperature. Further, the number of genomic copies with which this cloned family member reacts is also independent of the renaturation temperature from 25 degrees C below up to the melting temperatures. These observations demonstrate a remarkable degree of homogeneity in the evolutionary sequence divergence of members of this family. These results also demonstrate that renaturation kinetics can accurately measure the number of genomic copies of interspersed repeated DNA sequences.

Evolutionary sequence divergence within repeated DNA families of higher plant genomes. II. Analysis of thermal denaturation

An assay based on derivative analysis of thermal denaturation (melting) behavior of reassociated DNA was developed in an attempt to characterize the sequence relationships in repeated DNA families according to the homogeneous or heterogeneous models of Bendich and Anderson (1977). The validity of the technique was confirmed by the use of deaminated Escherichia coli DNA models for repetitive families. The melting data for DNA reassociated at two different temperatures provided strong evidence that Pisum sativum repeated families are mostly heterogeneous, while homogeneous families predominate in Vigna radiata. These findings, together with other differences between the two genomes, suggest that the rate of sequence amplification has been higher in the evolutionary history of Pisum DNA. A general trend seems to exist for high amplification rates in large, highly repetitive plant genomes such as Pisum and lower rates in smaller plant genomes such as Vigna, as well as in the generally smaller, less repetitive genomes of most animal species.

Studies on DNA sequences in the Osmundaceae

Phylogenetic relationships of Osmunda cinnamomea, O. claytoniana, and O. regalis were explored by means of DNA sequence comparisons. Hydroxyapatite thermal elution profiles of self-reassociated repetitive DNA fragments were very similar, indicating the absence of gross differences in the amount of recent amplification or addition of repetitive DNA in any of these three genomes. Interspecific DNA sequence comparisons showed, in contrast to our earlier interpretation, that repeated DNA sequences of O. claytoniana are nearly equally diverged from those of O. cinnamomea and O. regalis. Differences between repetitive sequences of the three species can be interpreted as reflecting amplification events which occurred subsequent to speciation. The data obtained suggest that the three Osmunda species most likely arose more or less simultaneously from a common ancestor. These findings were verified in experiments with tracer DNA preparations enriched for single copy sequences. On the basis of the hydridization data presented here and of the fossil record, the rate of single copy sequence divergence in the ferns is comparable to that in the primates, although slower than that observed in other animal taxa. From this first evaluation of rates of DNA evolution in plants it would seem that the rates for plants and animals are roughly comparable. The evidence suggests that species divergence is accompanied by further reiteration of preexisting repeat sequences. The rate of addition of repetitive sequences probably is slower in ferns than in angiosperms. This difference might be attributable to the much larger effective generation time in ferns.